an 4 FRANKLIN INSTITUTE » ‘ Pe owe ae, PHILADELI Book. aseeee ZA Class.. ~* Paper Testing Methods Microscopical, Chemical and Physical Processes and Apparatus Employed Prepared by the Committee on Paper Testing TAPPI Price — $3 Published for the Technical Association of the Pulp and Paper Industry 18 East 41st Street, New York, N. Y. by the LOCKWOOD TRADE JOURNAL COMPANY if EAST 39TH SLREET, MEW YORK NY, 7 Copyright, 1928 By the Technical. Association of the Pulp and ite | . Sora hel SUI BRARY of So a. | “FRANKLIN 2 a x09) TINSTELUTE? ae ‘ : : : 4 24 Kt i ; - 7 ; . | : 4 5 iM ' PREFACE The chief functions of the Paper..Testing Committee of the Technical Association of the Pulp and Paper Industry are to develop and to standardize paper testing methods. The early work of the committee dealt entirely with development of methods. Many valuable test methods were developed and these, together with considerable related information, were pub- lished:in committee reports. This pioneering work in development of American standards for paper testing was directed by Frederick . C: Clark, chairman of the committee. In 1920 the information so far developed was published by the Association in a pamphlet by Mr. Clark. A revised: edition was published .in 1922. After Mr. Clark’s resignation from the committee, the direction of the development of .methods was continued by Frederick A. Curtis. The committee under Mr. Curtis’s direction added a con- siderable number of new: methods required as a result of new developments in the industry and contributed considerable addi- tional information in general to the technique of paper testing. When the present chairman was appointed in 1925, a survey of the existing situation showed that the.development of test methods required to determine the quality of paper, aside from tests related to special uses of paper, had been quite adequately covered. It seemed advisable, therefore, to undertake a revision of the existing methods with a view to writing them in a standard form and hav- ing them adopted by the Association as its official standards. This program involved more adequate specification of conditions of test- ing, development of uniform nomenclature, statement of tolerances and methods of expressing results. The plan was approved at a meeting of the committee held at the Bureau of Standards, July 27, 1925, and the following method of procedure was formulated: “MeTHOD OF PROCEDURE FOR ADOPTION OF OFFICIAL PAPER TESTING Meraops ; by the Technical Association of the Pulp and Paper Industry. The work on standardization of paper testing methods will be divided as follows: Microscopical Physical Chemical Optical Tests for Special Uses of .Paper “The chairman of the Paper Testing Committee will appoint sub-committees dealing with each division of work, the chairman 4 PREFACE of the sub-committees constituting the Paper Testing Committee. The program of work for the various sub-committees will be formulated by the Paper Testing Committee. After a test method specification has received the approval of the majority of the sub-committee, it shall be forwarded to the chairman of the Paper Testing Committee for the approval of this committee. When this is received it shall be forwarded to the secretary of the Tech- nical Association for mail ballot of all Members of the Associa- tion in respect to adoption or rejection. The majority approval of those voting shall be required for adoption. Revision of official methods shall follow the same procedure as adoption of new methods.” The procedure was approved by the Executive Committee of the Technical Association. ~A number of official methods have been adopted and these are included in this edition of Pager Testing Methods. Attempt has been made to have this revised edition as complete as possible. A number of new proposed methods and testing in- struments are described, and much of the text has been rewritten wherever found necessary as a result of developments since the previous edition. B. W. Scrispner, Chairman, Paper Testing Committee, TAPP]. Members of Paper Testing Committee, 1927-1928: ALLEN ABRAMS Ci 10 Uses G. R. ALDEN C.-L. burein A. L. ALLEN G. J. Manson A. E. BACHMANN F. A. Miran T. C. BENTZEN J. E. Minor E. A. BERGHOLTz A. T. RANDALL H. E. Brakewoop E. O. REED O. W. CALLIGHAN W. O. Roe M. L. Caust R. H. Savace T. L. CrossLey R. H. Stmmons O. S. Ecan H. A. SmitH W. N. ENGLER R. H. Stevens T. H. Grant Epwi1n SUTERMEISTER R. C. GrirFin Cy Reolare E. G. Ham D. D. Uonc 1s Gas & a a C. D. VierGiver H. U. Kier P. F. WEHMER Contents ee A oe og aly oils G/ai ke Soe ad KOS elalb @ hak ew Oe 3 TURIN TRA TION So). oi s5ic bes ie fe oe ois lny 6 vite Conn d vans sauce 9 MOET IN FORMATION icc. Cece ec cece ened vcs vieceecadncdes 1] NR IN aM IS rs fo eka ona Kas cials cde > alvcia's Viv ee SW 86 bay 11 iar operer urchase pecifications ... os... cee eee eta 11 smistours ot -viethods 35..6...5.5 Peel toners te Warne SNe os Gi; 12 NU MINCDONS oc ocr vushcisle sn seis Saleen ko he asa nwa i2 eeeepiies tricia) Method © oesc 2. he ee ce la eee eee 12 SR EEC ae, Fg AE eo Gok wave aks 40S Ha hep ee Uae a nee 13 MIME ROSCOPICALLIUXAMINATION .ooce0 cae ewis ere cee evaleies 16 meeccimination of Hiber Composition .......5......6. 6. 16 ARIEL H Oy 98 Tociscy’ Pa. oh oe Sade N si elev odes 16 PE MUmIVICHnOd ( LeTtative). 6. oie ds «. kale oe cuca bee 21 Me erative gyLGtNOUS© oo. van he os ge nae 3 nls Seeib eae es 22 Pmeeuceussion of Wanipulation®... ..c.chck Teeth eee cen 23 Nee a Edt 1S Bis ee ne ee Uk wb atarvid os wis Lad Gs om 24 pee assication of Papermaking Fibers. .............0008. 25 ret CAI Foy os Sus te eh oe soba ON NS oe ees 35 eR Se tei FP ADCT o,f be nan 6 on nwa cau shed ss ones 35 Nee MN ei es ste da pa Po aoe hg wee Os b Blac 37 IE rere UEGTING | 0 os ce ve ed nnle han Cob R eee Cas Poe des 38 Mee rotcosoL tLiygrometric State .2 2.0.5 eps et ks wee as 38 a. Temperature and Humidity (Absolute and Relative) 38 meontnl ot Relative Humidity 2.02.0 e052) .04 kk. 39 c. Effects Produced by Changes in Hygrometric State. 40 Peromcial Conditioning ‘Method “ic... fees bak oa 43 Zoeeaacnine Uirection, Oficial Method -..........05...42. 44 ei ete CoO GAS CF aRO iS Ae ce 45 NRE oh ACT pon fists Sa ay Sic ice wines sew dig Aleta «) slew 08 45 PUR NOR create conv ake te Ng Coats vpn a al is ue Gace 8 45 Pe IRE eta tl Cal On nie ce sid aneead SRE G eso kee 49 MT Ot OVONI Ee ACtOL Se ah. Wi cg ov Ris ew Lone e sa be 50 REE EAL CNIO CN. 5) en ot, os ictal wales 308 b Shape ans Klee 52 Ne 1LR Fi hte nen anak ys ea ys BE Lida vn VS 52 USCS VIPS 9 Ye Mller eg Aime ape a mar ra Pa 53 MH Ce MMMM PT ENG 4 WY SMR E scale ASS Ge picked aed eae S ede 55 PAPER TESTING METHODS 6. Thickness, Official Method *.. 05.2. 303. >>» ae eee 55 7. Balko 2. oe ee Re OA 56 8. Folding Endurance 2.2... 2. cabs sneo ae 58 a. General. Information. <0) .u.. daa» oe eee 58 b. Official, Method « oil. .4ao ss ese ee 58 c. Calibration. 2a). 6 es des comm seo os eee 62 d. M.LT.Folding Tester .....6.. «3 nos: « 1 ee 62 9. Tensile Breaking Strength ..../:+.,+.+-+> see 64 24. Description ise te 0 adieu bee ale hres ke see 64 b: Official Method ......000. 58 £455 Soe 66 c.-Wet Tensile Strength .... 5.00... 0 ~« 68 10. Tearing Strength, Official Method ....25), 97a eee 68 11, Wet Rub ooh. .04 hs oe ce a 72 12, Air Resistance or Porosity. /J.. 1.4 0s fo: 13. Degree of Sizing 9. ooh 0) i dsaes a se 76 a. Degree of. Internal: Sizing ..\....2:2 eee 76 b. Degree of Surface Sizing... 15. 9es eee 2a eee 14, Water Resistance «13.34 20.0. 53 1 ee 81 a. Definition... sein ds Ws Oa eee ee ee 81 b. Bureau of Standards Ground Glass Method ....... 82 c. Method of A. R. Harvey <. y..3 4 eee 83 15. Grease Resistance... 6: 73.200 2s 85 16. Penescope -...004. 500. pe csew cues s A en 4288 17. Absorption 2.6.5 00... 0. 5.0bees bene Gea eee 89 A. Strip. wie basa cdlgw Go als kim ie © fan ee 89 b. Pipette. 0. 6s eck bee pie a's be 90 c. Total Absorption ©... i. <.<5 fuss tee oR d. Blotting Test 2.2... 0. ..42 ss sec 9D 18... Opacity: ... sie ic Yew ERs ads ee ee eae 92 19, Gloss (i .aa ves) ey ea ea ciel alee ae /94 20. Surface Texture i. ou, .D A aes ne rf 96 21.. Volumetric Composition’... ..> «5.4.05 45: one .. % 22.. Conducting “Particles sc) vai van y oe ee Ge a! 7 23. Extractor and Friction. Cleaner 72.22.20. ae Pee 24. Retention of Filler ..... 5.2.6... 2.20 ee 25. Expansion and Contraction of Paper ........, Mae GR Re 102 a. Schopper Expansion Tester .. :.... 1. s.snsetae ne 102 b. Davis’s: DeScription i... i..... +0. 5 ee 102 c. A Simple Procedure ).¢. 0.4.2. 2052.5 oe 102 d. Expansion of Boards... .:2....4. sae 103 26. COLO asi sys wos diate 5 | ns aba 0m mie ee ee 104 27. Stiffness core eeecdan eee eee aes & 8 6 He & Ob Se fe 6 6 60! oe) we eee heen PAPER TESTING METHODS 7 DE MA CN ALY STS 005 occ gored os o's win he dian utters ale Delores » 106 1. Official Method for Quantitative Determination of Mois- MM ACE LO Rs tM at, sue Bins Fy va Ok nae Stats 106 2. Official Method for Quantitative Determination of Ash er Ge oe aay alesis a dig nfo Wa wane > veld woe 106 3. Official Method for Analysis of Mineral Filler In Paper 107 4. Official Method for Analysis of Mineral Coating of PE OU ies tr ge LL dg tc abe, vhs ave nce ae Me hig 108 5. Official Method for Determination of Amount of Coat- micemrenimera) Coated Paper .. 0. seve cee ees baer eee 109 6. Official Method for Qualitative Determination of Casein re er nig een woe Vo ke eee whe 110 7. Official Method for Qualitative Determination of Rosin Hi ELSA Sea lice, One eee A ROAR ee le ner ar we re a 110 8. Official Method for Quantitative Determination of Resin J TESS SSS 50 ey inlets en aa eC aver 110 9. Official Method for Qualitative Determination of Nitro- @-nous Proteimaceous Materials in Paper..............- 2 10. Official Method for Quantitative Determination of Pro- Pere OUS SO NELTOGEN 1) APETN... Gy fakes «spies ble oe ne en 2 11. Official Method for Qualitative Determination of Starch PR et ee dna st ian eh Pianos «5k ace de 2 113 12. Official Method for Quantitative Determination of rN ORT Me ck 05 cd et Wa cS Pts oa via Rd os cw ER 114 13. Official Method for Quantitative Determination of Ac- Pea Mire er eh eo yc bil tow he sae oud hn os 8 LES 14. Official Method for Quantitative Determination of Pewesoite viet aramned Paper |... iia. ci. ecco vow oh eee. 116 emcee rig Matter, oie. 6. Seen eet a ay al awe oe 7 Pemeectareorespecial: Materials (50.0.6 cds ee oa os oe 117 Met CNN 11) EP ADET nce occ eas hoe eek tea c visnn ne wadgelts 119 List of Illustrations Figure Title Page ME TR ECORT (CARD (toch oe ef since tcslck ce oat Seas cco eee 14-15 REPRO PH AKER Ac Grud oy Cxiwome Ph FieT alae oie wleeos ly DIITOUREREFOR WIICROSCOPE. SLIDES) 2.0... .4 cule d oe wk te a ee 18 PESO IE AS NITCROSCOPE }2 05025 fawilds pedal Fes sa eb ee dvds 19 5. CLASSIFICATION AND CHARACTERISTICS OF THE More Com- MON VEGETABLE FiRers USED IN THE INDUSTRY ....... 26-27 6. PHOTOMICROGRAPHS OF PAPERMAKING FrBers (x 100) ...28-32 7. PHOTOMICROGRAPHS OF CoTTON RaG FIBERS SHOWING PrRo- GRESSIVE CHANGE IN STRUCTURE WITH BEATING (x 100) 33-34 8. VARIATION IN PHYSICAL PROPERTIES OF PAPER WITH ete eI UMIDITY Wi Cs sGe rence bh ad webs 42 9.. PAPER WEIGHING DEVICES: eS, UII CUNEATE Ee a 8 Gna pa gee I OS 46 ESOT E Al ANCE rae oc we Oh Sian rece de ae eee 47 Este ay CUETt SCAlC RG re ass keer ie ba deel sant als 48 Puc weal bealh, SCAle Gc AM owe kee eae cape oe 49 10. Burstinc STRENGTH TESTERS: ee eae ooh te eet oe oh phe ho Seecue acc aoe liavaiel Huela 51 ie, cle EE 2 Ai Eel dis as a a oO eM I eta a 51 NTS OCG Pe ee a. ER od hs Cha ake eek « 52 er eraser ea ek OE eS oe eget ce bivhintn CoP es 33 IAC PICK NESS. MICROMETER i. 5624 cas ec dee oom 55 Ne APRA Bitsy, cacy sd wk wid a anid ig Wiese de woaktiels wane we Yale 57. Toa SeCMOPrER FOLDING ENDURANCE TESTER ......:.00 00: s004) 58 14. Beti-CrANK LEVER FOR CALIBRATING SCHOPPER FOLDING RNC MeL ESTERS Mo oie mae ke ei oh Me oa we we « 61 Peete ee OLDING EENDURANCE LESTER... 2.0: cis- csc eens 63 16. TENSILE BREAKING STRENGTH TESTERS: CIE ge ae Re cate ota Uae te Sak cote Shes Ob 65 MPS Cette eet et et nt dks Peo S28 ac OD PE MOG ETI Sr eS ahaa re gon asia Gi eee sete re tue eet oA 66 CE SCIOTO Si ieran Oe duis reece ah eed we eae EE oe 67 PP EMENDORE | HARING: LESTER ... vids ce ee dees Wea vee tenses 69 18. BureAvu oF STANDARDS MODIFICATION OF THE ELMENDORF TEARING TESTER FOR INCREASING ITS CAPACITY ....... 71 Pe OL RS TER ool sede Cae «ce k a tacts oe ee yeas 72 20. Arr RESISTANCE TESTERS: Rta OS LIE Ys LEM SOITICLOTS y's wet tra, soe ts ie ge ike aha winte 73 10 PAPER TESTING METHODS 20b. Schopper: Densometer) .)..5. 33... 2 ee 74 20c. Emanueli Porosimeter <..........1.2 9. 75 212 VattEY Size TESTER: 2.00. «<5 on oe 77 22.'> Curt Sizinc® TESTER, ..24..5. 0s vn ek eee 78 23. Dry-INbDIcAToR SIZING, TEST: METHOD ... )225) 0s eee 80 24. Grounp GLass WATER RESISTANCE TEST METHOD ....... 82 25. Harvey WATER RESISTANCE TEST METHOD ............. 83-85 26. APPARATUS FOR GREASE RESISTANCE TEST ..:.........--- 86 27. THE PENESCOPE, AN APPARATUS FOR TESTING RESISTANCE TO. LIQUIDS 6d 4s 4 doen Sy ws led el abd oe 87 28a. ABSORPTION TEST; KLEMM METHOD ........ 0.3 88 28b. DaLen BuoTrinG Paper TESTER +... .-241, see 91 29. OPACITY TESTER ..50.. cee 00s 0s pee os eee 92 30. INGERSOLL GLARIMETER <2... 00.012 des eee 95 31. APPARATUS FOR DETECTING CONDUCTING PARTICLES ...... 98 32. EXTRACTOR AND FRICTION CLEANSER.,)....csape oe 99 ‘33. SCHOPPER EXPANSION TESTER 2.5.4 55. Gu eee 101 34. GRIFFIN "EXPANSION ‘TESTER [V2 4:5. .... 0 eeuoe ee 103 BOARDS oe Ove na decd pwnd es eae 104 PAPER TESTING METHODS I. GENERAL INFORMATION 1. Purpose The testing of paper is usually performed for one of four reasons and it is possible that methods suitable for one purpose may not be suitable for another. These purposes are: (a) To study the manufacturing processes respecting their im- provement or improvement in the quality of the paper. (b) To maintain a predetermined quality. (c) To determine whether the quality is equal to a predetermined standard or specification. (d) To. determine whether the paper is suitable for a given purpose. The manufacturer is einterested hae 3 in (a) and (b), eure the user or buyer is interested in (c) and (d), when paper is bought on specification. Methods may be developed for local use in mills for specific purposes related to manufacturing processes which are satisfactory for those purposes. There is obviously no possibility of standardizing such methods and no need of attempting this. However, to permit comparison of manufacturing and research data and to obtain comparable results in testing for compliance with specifications of quality, it is necessary to establish standard testing procedure. One of the main objects of this publication is to promote such standardization. Considerable progress has been made in this direction. The Paper Testing Committee of the Technical Association has developed a large number of testing methods in definitely specified form and these, which cover the requirements of ordinary testing practice, have been adopted as standard by the Association. Such methods are termed “official” methods and are so designated in this publication. 2. Paper Purchase Specifications oe merchandising any commodity it is becoming generally recog- nized that definite test basis for purchase is the most satisfactory system. This tends to prevent delays, legal litigation and other annoying and expensive experiences common to transactions based on-the personal judgment of the parties involved. With develop- ment of adequate test methods the use of paper purchase specifica- tions embracing requirements as to certain tests the paper must meet adequately, has become quite common. This publication con- 11 12 GENERAL INFORMATION tains standardized testing methods sufficient for general purchase requirements. A number of commercial paper testing laboratories are completely equipped for making all tests commonly required. A very complete list of the paper specifications in use in this country is given in a Directory of Specifications issued by the United States Bureau of Standards. The same bureau has issued Directory of Commercial Testing and College Research Labora- tories which lists all known laboratories that do commercial paper testing. 3. Groups of Methods For convenience, the various methods of testing are grouped into three classes: microscopical, physical and chemical. 4. Records and Reports Complete laboratory records of all tests should be maintained and reports should be made in a systematic manner. Original test data should be recorded directly on a test record card which should be filed and kept as a permanent record. Printed report forms are of assistance in minimizing clerical work and in systematizing re- port procedure. The accompanying 5 by 8 inch record card, with both sides reproduced (Fig. 1), is offered as a suggestion. Indi- vidual requirements, of course, may necessitate modifications in this. 5. Sampling Extreme care should be taken in sampling to make certain that the sample is truly representative of the lot of paper to be tested, that the sample is adequate for the tests desired, and that the samples reach the testing laboratory in good condition. The Tech- nical Association of the Pulp and Paper Industry official method follows: OrriciAL METHOD OF SAMPLING PAPER FOR TESTING I. Test Sample: The test sample, unless otherwise specified, shall consist of sheets at least 11 x 11 inches in size, and having a total area of not less than 1500 square inches. The sample sheets shall be kept flat, free from wrinkles and folds, and protected from ex- posure to liquids, direct sunlight and other harmful influences. II, Methods of Sampling: Not less than 10 per cent of the total number of units, (rolls, cases, frames or bundles, etc.), composing a lot of paper, shall be sampled if the lot consists of not more than 100 units. If the lot consists of more than 100 units, not less than 5 per cent of the total number of units shall be sampled. The sample sheets shall be so selected from the different units that they will be rep- resentative of the entire lot of paper. TOLERANCES 13 The samples shall be taken as follows: 1. From rolls—The sample sheets shall be taken from the first unharmed layer of each roll. 2. From cases, frames and bundles.—The sample sheets shall be taken from the top and center of each case, frame or bundle sampled. The sample sheets shall be so cut that their edges are exactly parallel with the machine and cross direction of the paper. III, Resampling: In case of necessity for resampling a lot of paper, the samples shall be taken as described above, except that the sample sheets shall be taken from different units than those previously sam- pled. If the identity of the original units is lost, and the paper is not in rolls, cases, frames, or bundles, the whole lot shall be so sampled that all the different components of it will be rep- resented by the test sample. 6. Tolerances In considering test results, tolerances must be allowed for un- avoidable variations caused by the inherent non-uniformity of paper and by errors inherent in the testing methods. The extent of permissible tolerance varies with the nature of the paper and of the test used and must be determined for each particular case with consideration of these factors. O10 ONILNIGd LNZAWELA0® sé6sz—It auo0ry Isa], atdVg ; Aq peyoeqD a x x a fe a haan 4q poyodey ot ee ee cA Ree er ei oe 74319 MA HOWAMKWOO AO LNINLUVAI -SHAVANAA sso[y sues F010 07Tp STIR Ur SSOIDY 1I0]OD SUIeIS ree ee ee ey mT ae rE kyrnedo :yj8ueljs Suesy ; = Gig po ip MT een BORSOTIp SUIGIUUL BoOsTy ye we ee eae ee et, ae a esp: OU ae Tar SUISOY > Worjesuo0ly qsVv CON rs ae ee EY | OO TE a ee Ba ce eee ee eee Coes = ee eee Wu Sg] Jod ‘q}3ueljs ofisuey ely UOMISIIP sUIqIVUI SSOIIV — aqnf pus Bpue_y WOT}IAIIp oUTYIV snonpieq :Sp]oj ayqnop ‘aduvinpus ZuIpjog Snolojiuo0y Of te ee eens eke a ELON ME q}Zuseljs Zujsing poo punolyg *s}d poo yeormrdsy,y qour. ‘ssouyogL , Bey ES Ea a ee ee ) 44310 : UOT}ISOdu0d JOqiy qaaUuva “ON JOplog WOM hore re eS poyloday pears.0y RO sete NT cee a (00S ‘OF X SZ) 74319 M 14 'TEARING n 3 7) =) ELONGATION Cross TENSILE FOLDING THICKNESS BURSTING STRENGTH ‘oes | HILAL Sd ld Ma al =a] )s]els)@/ ole) af 1S 11—7898 GOVERNMENT PRINTING OFFICE 1 Fic. Test Record Card. II. MICROSCOPICAL EXAMINATION 1. Determination of Fiber Composition a. OFFICIAL METHOD Following is the official Association method for determining the fiber composition of paper: I. Apparatus: A microscope capable of giving not less than 100 diameters magnification is necessary for determination of fiber composition. It should be of the compound type and have a mechanical stage. IT, Specimen: 1. Composition—-The specimen for test shall consist of pieces having a total area of not less than 6 square centimeters (1 square inch) cut from different portions of the test sample, so as to be representative of it. 2. Preparation for Examination—Place the specimen in a small beaker and completely cover it with a 0.5 per cent caustic soda or caustic potash solution, heat to boiling, transfer the contents of the beaker to a small 200 mesh metal sieve and wash thorough- ly with water. Roll the moist pieces of paper into a ball and work between the fingers to loosen the fibers. Transfer to a test tube and shake until the fibers are completely separated. Pour a portion of the mixture into a second test tube and di- lute to a fiber concentration of about 0.1 per cent. Transfer the fibers to a microscope slide by means of a dropper consists- ing of a glass tube 20 cm: (6 inches) long and 6 mm. (% inch) in- ternal diameter, fitted at one end with a rubber bulb. Thorough- ly mix the fibers and water, quickly insert the dropper into the mixture 5 cm. (2 inches) below the surface, expel two bubbles of air from the dropper, then fill the tube to a distance of about 13 mm. (% inch). Transfer the contents of the dropper into the slide, making 4 drops, completely emptying it. Repeat this procedure until the slide is uniformly covered with drops of the mixture, then place the slide in an air-bath until dry. Add stain as specified in Section III-2 to the dried fibers and press down on them a second slide or large cover glass. Remove excess moisture from the edges of the slides with absorbent paper. One slide shall be sufficient for ordinary determinations. In case of dispute not less than 3 slides, shall be examined. III. Method: 1 Method of Observation. The prepared slide shall be examined microscopically observations being made at vari- ous points in a straight line, twice lengthwise and four times crosswise of the slide, each line of the observation starting at a 16 FIBER COMPOSITION 17 Pion 2: Test Tube Shaker Devised by M. B. Shaw, Bureau of Standards, For Defibering Micro Test Specimens, different point. A magnification of-not” less than 100 diameters shall be used. A magnification of 100 diameters is desirable as with lower magnification it is difficult to observe the character- istic structure and shape of the fibers, both of which aid materi- ally, in addition to the color developed by the stain, in identify- 18 MICROSCOPICAL EXAMINATION ing the fibers. The number of each kind of fiber present in at least 25 different fields and a total of not less than 200 fibers shall be counted, using the diameter of the: field as observed through the microscope as the unit of measurement. The amount of each kind of fiber present shall be computed as a percentage of the total fiber composition. 2.- Stains. For all purposes except as specified below, either the Herzberg or the Sutermeister stain shall be used. These shall be prepared and used as follows: Herzberg-—Prepare the following solutions: (A) An aqueous solution of C. P. zinc chloride saturated at 70 degrees F. (B) 0.25 grams of C. P. iodine and 5.25 grams C. P. potas- sium iodide dissolved in 12.5 cc. of distilled water. Mix 25 cc. of solution (A) measured at 70 degrees F. with solu- tion (B). Pour into a narrow cylinder and allow to stand until clear. Decant the supernatant liquid into an amber colored, glass- stoppered bottle and add a small piece of iodine to the solution. Thoroughly moisten the fibers with this solution and remove the excess with blotting paper. The solution should be tested with known fibers and readjusted if necessary by addition of either zinc chloride or iodine. The following colors are developed by this stain: Tobie for there See Holder: Pres) Holder for Microscope Slides. (Bureau of Standards, Washington, D. C.). FIBER COMPOSITION 19 Fic. 4. Binocular Microscope. Red—Linen, cotton, bleached manila hemp. Blue—Chemically prepared fibers low in lignocellulose, from. wood, straw and esparto. ~Yellow—Fibers high in lignocellulose such as groundwood, jute, and unbleached manila hemp. Sutermeister—Prepare the following solutions : (A) 1.3 grams iodine and 1.8 grams potassium iodide dis- solved in 100 cc. of water. (B) A clear, practically saturated solution ‘of calcium chloride. In using this stain, apply solution (A) after moistening the fibers with water, allow to remain about one minute, remove the excess by blotting and then add solution (B). The colors developed by the Sutermeister stain are, in general: Red or brownish red—Cotton, linen, hemp, ramie. Dark blue—Bleached soda pulps from deciduous woods. Bluish or reddish violet—Bleached sulphite fibers and thoroughly cooked unbleached sulphite fibers. - Greenish—Jute, manila hemp and the more (eae fibers in unbleached -sulphite. Yellow—Groundwood. Lofton-Merritt—This stain shall be used for differentiating 20) MICROSCOPICAL EXAMINATION between unbleached sulphate (kraft) and unbleached sulphite fibers. It shall be prepared as follows: (A) Malachite green, 2 grams. Water, 100 cc. (B) Basic fuchsine, 1 gram. Water, 100 cc. These shall be mixed in the proportion of 1 part (A) to 2 parts (B). As dyes from different sources vary it is necessary to test them by staining known fibers. Unbleached sulphate fibers are stained blue or blue-green and unbleached sulphite fibers purple or lavender. If any purple fibers appear in un- bleached sulphate fibers, this indicates there is too much fuch- sine present and more malachite green solution must be added. The opposite is indicated if some unbleached sulphite fibers de- velop a green or blue color. The Lofton-Merritt stain shall be used as follows: Add the compound stain to the fibers and allow to remain 2 minutes. Re- move excess stain by means of a hard filter paper and add a few drops of 0.1 per cent hydrochloric acid. After about 30 seconds remove the excess acid. Next add a few drops of dis- tilled water and remove the excess. Bright Stain—This stain shall be used for differentiating between bleached and unbleached fibers. The solutions required are: (A) 2.7 grams ferric chloride (FeCl;s6H2O) per 100 cc. dis- tilled water. (B) 3.29 grams potassium ferricyanide (K;Fe (CN).«) per 100 ce. distilled water. (C) 3 grams of crude (not treated with sodium carbonate) substantive red dye per 500 cc. of distilled water. The dye used shall be DuPont Purpurine 4 B. Concentrated, ° or its equivalent. These solutions must all be made with cold water. Filter solutions (A) and (B) and keep in separate stock bottles at a temperature not exceeding 20 degrees C. Make solution (C) fresh each day it is used. For staining use tall narrow beakers suspending the microscopic slides in the beakers from clamps. Mix 10 cc. each of solutions (A) and (B) in one beaker and add an equivalent amount of solution (C) to another beaker. Set the beakers in a water bath, the temperature of which must be maintained constantly within + 1 degree of 20 degrees C. Place a thermometer in the stains. When their temperature is 20 degrees C.. dip the slide containing the dry fibers in distilled water to moisten it uniformly (so that no air bubbles will be formed when_ it is stained), then place the slide in stain (A-B) and allow it to remain 20 minutes. Wash by dipping in distilled water six times, then renew the water and repeat the washing process. Dry the contents of the slide and repeat the processes of moistening, stain- FIBER COMPOSITION 21 ing, washing and drying, using the (C) stain. It is desirable to fix the top glass on the fibers with a drop of balsam. The colors developed by the Bright stain are: Red—Bleached fibers or fibers practically free from lignocellu- lose. Blue—Unbleached fibers or fibers containing lignocellulose. IV. Report: The proportion of the various fibers found shall be reported in terms of percentages of the total fiber composition, to the nearest 5 per cent. The following nomenclature which covers the fibers commonly dealt with shall be used in reporting re- sults: Chemical wood fiber; chemical deciduous wood fiber; chemical coniferous wood fiber; groundwood fiber; manila fiber; jute fiber; rag fiber; linen fiber; cotton fiber; esparto fiber; straw fiber. 7 V. References: “Microscopic Paper Fiber Analysis.”’—G. K. Spence and J. M. Krauss. Paper 20. No, 11, 11) (May 23, 1917). Paper Priifung, Wilhelm Herzberg. Chemistry of Pulp and Paper Making.—I, Sutermeister, page 390. “Method for Differentiating and Estimating Unbleached Sulphite and Sul- phate Pulps in Paper.’’—R. E. Lofton and M. F. Merritt, Technologic Paper No. 189, U. S. Bureau of Standards. “ “Microscopy of Paper Fiber.”,—C. G. Bright. Paper 20, No. 25, 11 (Aug. 29, 1917). As modified by the author, b. Dor MErHop (TENTATIVE) | To avoid the undesirable personal equation involved in estimating the relative sizes of the fibers, the following method of counting is recommended for trial with the view to future adoption as the official method if found satisfactory. This is known as the dot - method, a disk containing a dot or point being placed on the diaphragm of the eyepiece, and the fibers being counted as they pass under the dot. It is possible to construct a satisfactory cross line disk by the use of two silk fibers, approximately 0.01 mm. in diameter obtained by untwisting silk thread. The fibers are drawn across the center of a round cover glass 18 mm. in diameter at right angles to each other. They are cemented to the edges of the glass with paraffin or other adhesive and the protruding ends cut off. The cover glass is then placed, with the fibers on the underside, on the diaphragm of the microscope eyepiece. The cover glass is then centered on the diaphragm of the eyepiece of the microscope and cemented in this position with a drop of paraffin. A graticule or crossline disk is carried in stock by many manufacturers of optical equipment. It consists of a round thick disk of optical glass on which are engraved two lines at right angles to each other, both lines running completely across the disk and intersecting at the center. Place the crossline disk on the diaphragm of the eyepiece of the microscope and a prepared slide of stained fibers on the mechanical stage. Starting at one end of the slide: about a quarter of the way down from the top, move 22 MICROSCOPICAL EXAMINATION the slide in a straight line throughout its entire length by means of the mechanical stage. In moving thus through the field of view each fiber or part of a fiber shall be counted which passes directly under the dot or point formed by the intersecting cross lines on the disk. Some of the fibers may be long and pass under the point twice or more but they shall be counted each time. If aggregations of fibers such as occur in groundwood are encoun- tered the number of single fibers in the aggregation shall be esti- mated and. counted as if the fibers. were completely separated. Select another path across the slide about half way down from the top. Repeat. the entire counting process adding the results to those obtained foregoing. Repeat again over a path about three- quarters of the way down from the top of the slide. Add the results to the foregoing. Select two or more up and down paths and repeat the process. The record of the count may be made conveniently in either of two ways: (1) By making separate columns for each kind of fiber observed in passing over the slide and entering a record in the proper column as soon as a fiber passes under the dot. (2) By making a complete trip across the slide counting only one kind of fiber, e.g. rag. A return trip is then made over the same path counting only another kind of fiber, e.g. chemical wood. In this way successive trips are made over the same path until every kind of fiber present has been counted and the results for a given fiber are recorded after each trip. c. ALTERNATIVE METHODS 1—Estimation Method: - The estimation method involves train- ing the eye by the comparison of unknown samples with standard mixtures of known composition. Accuracy in the estimation method requires considerable practice and continual reference to the standard mixtures. Although this method gives accurate re- sults when used by experienced analysts, the actual counting of the fibers is specified in the official method as counting is con- sidered a more practicable procedure for general use as it enables comparatively inexperienced operators. to obtain ‘satisfactory results. . . { 2—Spence and Krauss Method: A third method of fiber analy- sis is the fiber-weight-length method proposed by Spence and Krauss: The slide is placed under a microscope of 160 diameters and the length of the various fibers is measured in terms of the diameter of the field seen through the microscope. The total length of each kind of fiber present multiplied by its weight factor gives a set of results that are directly comparable and may be converted into per cent of each kind of fiber present. The weight factors as determined by the originators of the method are: Rag, 1.000; hemlock, 0.870; poplar, 0.454; birch, 0.652; beech, 0.525; maple, 0.365. It remains to be proven whether these factors or FIBER COMPOSITION a any factors are general applicable to fibrous raw materials from different sources. It presents possibilities, however, in the direction of securing increased accuracy. d. Discussion oF MANIPULATION The following suggestions are offered to those just beginning these tests: It is absolutely essential to have a satisfactory stain or else the results will be worthless. To test out a stain make up a mixture of about equal parts of bleached soda pulp, bleached sulphite pulp and rag filter paper. Prepare a microscope slide from this mixture and stain with the stain to be tested. If the stain is correct, then the soda pulp should show a dark blue color, due to the thicker and more opaque fiber walls; the sulphite pulp should show a light blue, due to the thin fiber walls; and the rag fibers will show a red or wine-red color. If the blue color is more of a violet, then too much iodine is present and more water or zinc chloride should be added. Zinc chloride produces the blue color, iodine produces the red and the yellow colors and the addition of water serves to weaken the color that predominates. In some cases where it is necessary to examine all grades of paper, it is advisable to keep several stains on hand. A stain that gives the best color on groundwood and bleached sulphite seldom gives a correct color on mixtures of rag, bleached sulphite and soda pulps. In such a case, make up one stain so that it will give a bright lemon yellow on a known sample of groundwood pulp and a slightly greenish blue on unbleached sulphite. For the mixture of rag, bleached sulphite and soda pulp, so adjust a second stain: that the rag shows as a clear wine-red, the sulphite as a blue, and the soda fibers as a dark blue. In testing out a stain always have on hand authentic samples of pulp so these mixtures may be made up. : To check estimates of fiber analysis, slides of fibers in known proportions are made. Pure stock is beaten in a small beater and made into hand sheets. Sheets of the various pure fibers are kept under the same atmospheric conditions. To make up a field of known composition take weights of the pure fiber sheets and make up a total of at least 5 grams in proportions to give the percentage desired. Disintegrate and mix thoroughly by shaking with shot in a bottle or by the action of a small disintegrator. Sample and make up the slide as for any disintegrated paper sample. The estimation of the fiber content is based on the relative pro- portion of the kind of fibers contained therein, expressed on the percentage basis, considering the total fiber content as 100 per cent. In making a fiber estimation no account is taken of the per cent of clay, alum, size, etc., that may be contained in the paper. 24 MICROSCOPICAL EXAMINATION For best results for microscopic work a clear north light is desirable and is to be preferred. However, where there is a large amount of routine testing that must be done, it is more advisable to have a more constant source of light. There are various types of lamps available but good results can be obtained with a Mazda nitrogen-filled lamp of 150 watts. It is necessary, however, to use a blue “daylight” filter in that case. It is to be noted that the color of the stained fibers on the slide will be somewhat different for the two kinds of illumination. A set of colored plates has been prepared by the Bureau of Standards of the Department of Commerce, illustrating eight paper fiber compositions as seen under the microscope. They are intended to serve as reference standards for use in the identifica- tion of paper fibers and in the estimation of the fiber composition of the paper. These plates are published in Technologic Paper No. 250 of the Bureau, entitled Pulp and Paper Fiber Composition Standards. It is frequently desirable to make photomicrographs of fibers examined as these serve as a permanent record. For information on equipment and the use of it for this purpose it is suggested that analysts consult the Bureau of Standards Techno- logic Paper No. 217, The Photonucrography of Paper Fibers. e. SPECIAL STAINS In addition to the stains used for determination of fiber compo- sition as given in the official method, the following stains are used to detect presence of groundwood fiber, being applied directly to the paper under examination. Phloroglucinol: Dissolve 5 grams of phloroglucinol in a mix- ture of 125 cc. of distilled water and 125 cc. of concentrated hydro- chloric acid. The solution should be kept in the dark as much as possible as it is prone to lose its staining property on exposure to light. This solution produces a magenta or wine-red color on mechanical pulp. The color may be easily noted by applying some of the stain to a piece of newsprint paper. There is approximately 80 per cent of mechanical pulp in newspaper so that a deep ma- genta color is developed. The depth of color is an indication of the amount of mechanical pulp present. A very light shade of color, however, does not necessarily prove the presence of me- ‘chanical pulp as partly cooked jute, partly cooked unbleached sulphite pulp, and some other fibers are also slightly colored. An additional formula is as follows: Phiotoglucine 4.4.08 2 grams Alcohol, (95. per: cent) 2. 100 ce. Concentrated HCL. ............ eet a Oe Aniline Sulphate: Dissolve 5 grams of aniline sulphate in 50 cc. of distilled water and acidulate with one drop of concentrated sulphuric acid. This stain produces a yellow color on papers CLASSIFICATION OF FIBERS 25 containing a large percentage of mechanical pulp. This stain is not quite so sensitive to mechanical pulp as phloroglucinol, but it is easier to obtain and prepare. Para-nitroantline: Saturated solution in concentrated hydro- chloric acid. This stain produces an orange yellow color in the presence of mechanical pulp and other lignified fibers. 2. Classification of Papermaking Fibers! For convenience in studying fibers it is desirable to know re- lations of the various groups and the accompanying chart (Fig. 5) indicates the arrangement of the fibers that are used for paper making. It is to be understood that this is not a botanical classifi- cation and any standard textbook on botany is to be consulted if this information is desired. : CLASSIFICATION OF PAPERMAKING FIBERS A. Seed hair fibers—fibers which grow on seeds...... Cotton Flax Hemp Jute B. Bast fibers—from the inner bark of trees, shrubs ) Ramie TICE TATE Seer heer te. oh era Se cee py Gee” a chpae Wagnds wale cgseis Kodzu ; Mitsumata Gampi New Zealand flax Abaca Sisal C. Leaf fibers—from the leaf or leaf stem............ Aloe, American (Century plant) Pineapple Wood fibers, coniferous Wood fibers, D. Stem fibers—from the main stem or trunk of the deciduous VERRAN WWE gues ee Ceca mca ae aera ar Straw Esparto Bagasse PETC DELS Metin (Hue fh, sii sic.c'sgl io. siiwiaiesiatece 8 aie Miagie ae hs Cocoanut In addition to the vegetable fibrous raw materials, wool is com- monly used for paper making. It is usually found in building felt. Following are the characteristics of wool fibers. Dimensions—Length, 25 to 200 mm.; diameter, 0.010 to 0.100 mm. Microscopic appearance—Under even moderately low power of magnification (50 diameters) the epidermal scales on the surface of the fiber can be seen. Neither silk nor any of the vegetable fibers have this appearance. The scales are more or less trans- lucent in appearance, and permit the under cortical layer to be seen through them. The medulla, commonly called the pith from its analogous structure in plant stem, can usually be seen in the coarser fibers. Micro-chemical reactions—Iodine-zinc-chloride solution, pale yellow; nitric acid, deep yellow color; concentrated hydrochloric or sulphuric acid, gradually dissolves with red coloration. 1 “Vegetable Fibers Used in Papermaking.'’"—F, C. Clark, Paper 23, folio p. 944 (Feb, 26, 1919.) *SUIEJS UOUTUIOD S1OU 9Y} JO [BIIAIS Y}IM UOTJI¥AI 10[0D ay1 SaAIs ostR pue Suryew ssded 10% pasn s1aqy. SnoLeA jo ainjonsys pue adeys 94} 01 pseZat ur UoTEUIIOJUT saad YyOIyM aIqQeu} YW ‘“s19qra ‘S$ “OLY MoOTa4 SS9[I010—) MOTTPA = ATIYSIS us2e1S YSIMOTJAX Al}JYZYS 10 paiojod ON petojoo JON a1 S59] TOTO) pat dseq pet AYSYS Apysys 10 exes TN ‘parojoo JON MO -[PA us01B 0} pot. 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Fibers (x 100). bers (Coni i Hemlock Wood F ing ak Photomicrographs of Paperm 28 IG. VOC, Spruce Groundwood Fibers (Coniferous). Fic. 6d. Pine Wood Fibers (Coniferous). Photomicrographs of Papermaking Fibers (x 100). 29 Fic 0e Cotton Rag Fibers. Fic. 6f. Hemp Fibers. Photomicrographs of Papermaking Fibers (x 100). 30 Fic. 6g. Jute Fibers. Fic. 6h. Wool Fibers. Photomicrographs of Papermaking Fibers (x 100). 31 Fic. 61. Esparto Fibers. Rice Straw Fibers. Photomicrographs of Papermaking Fibers (x 100). 32 Fic. 7b. Photomicrographs of Cotton Rag Fibers showing Progressive Change in Structure with Beating (x 100). Fig. 7a. shows the fibers at the start of the beating and Fig. 7d. shows their condition at the completion of the beating, the other two figures showing their condition at equal inter- vals between these extremes. 33 Pics 7G, Photomicrographs of Cotton Rag Fibers Showing Progressive Change in Structure on Beating (x 100). 34 | BEATING 35 3: Degree of Beating By a careful examination of the fibers under the microscope it is often possible to determine something of the amount .of beating to which the stock has been subjected. The length of the fibers, the amount that the ends have been frayed and the degree of the breaking down of the cell walls all give information in regard to the beating treatment. It is necesssary, however, to have con- siderable experience before the results are reliable. The use of photomicrographs assists in this study and the accompanying plates (Fig. 7) indicate some of the characteristic differences of fibers caused by the beating treatment. | 4. Specks or Dirt in Paper The appearance of a sheet may show imperfections caused by foreign materials or malformation on the wire. These are the most common causes of poor looking paper. Generally, specks need microscopic examination. A Bausch and Lomb binocular microscope shown in Fig. 4, and a set of dissect- ing needles are useful. For chemical tests on small particles small test tubes made by sealing one end of small glass tubing are con- venient if the reaction is to be watched under the microscope. RuBBER.—This is very objectionable. It finds its way into the stock along with rag stock, sometimes as rubber paste in tire fabrics and the like, and sometimes in paper stock as rubber bands from office waste. Under the magnifying glass rubber specks can be stretched by pinning down one end with a dissecting needle and pulling out the speck with another needle point. | Rubber specks will give a characteristic rubber odor if burned by sticking them into a flame on the end of a needle. They are soluble in carbon tetrachloride. Rostn Specks.—These are translucent, amber colored specks so resembling rosin that they are easily recognized. Proof of their identity can be had by dissolving the separated speck in ether in a small tube so that the action can be watched under the micro- scope. Qualitative rosin tests can be applied to the speck as. given under qualitative tests for rosin. Other specks resembling small bark eM age may come from size which was made from impure rosin without proper filtration. Although not as translucent as the ordinary rosin speck they usually carry enough rosin to respond to the qualitative test. Woop Specxs.—Chips or wood fibers which might result from the accidental grinding off of a beater paddle or similar cause can be quickly identified by applying phloroglucinol; they give a char-. acteristic red coloration as in the groundwood test. 7 36 MICROSCOPICAL EXAMINATION Iron Specks.—Washer or beater bars, jordans, scaly pipes, cor- roded overhead ironwork, and iron buttons from rags contribute iron in metallic or oxidized form at times. The metallic particles will be attracted by a magnet after being freed from the sheet. The scale or oxidized iron can be dissolved in hydro- chloric acid and a drop of potassium sulphocyanate added. Iron gives a characteristic wine-red color. This test can be applied to the separated particle in a small tube, or the sheet believed to con- tain iron may be placed on a glass plate, wetted with concentrated hydrochloric acid for five minutes and then with 10 per cent potassium sulphocyanate solution. Each iron speck shows red when the sheet is held up to the light. The glass plate forms a convenient holder for the sheet. The red color fades in a few minutes and count should be taken immediately. Another method is to immerse the paper in 2 per cent potassium ferrocyanide, then in 2 per cent acetic acid, then wash well in water. Hang the sheets vertically until dry. There will be a blue coloration wherever there is an iron speck in the sheet. This method makes a more permanent record than the sulphocyanate treatment. Or. Spots.—Oil spots are translucent and can be spread or thinned with ether or chloroform. Extraction with either of these solvents removes the oil, unless it is of a peculiar pasty formation caused by use of oily rags in the stock. Mineral oil in rags is prone to form a dirty, congealed mass in the washers, which specks the halfstuff with black specks in which the mineral oil is the binder. Such specks in the finished sheet are not entirely re- moved by ether or chloroform. They are slightly translucent, and unaffected by solution in concentrated sulphuric acid. Cotor Srots.—Poorly ground colors give a fine, specky appear- ance usually identified by color only. ALuM Spots.—These are usually pulverized by the pressure of the calender rolls. They are soluble in water and give a slight acid reaction with indicators. This reaction is best watched by dissolving the speck in a very small test tube and adding the indi- cator while the tube is under the microscope and against a white background. Coat ParticLEs.—Coal dust is insoluble and gives no color re- actions with any reagent. In appearance iron scale can be mis- taken for it, and in doubtful cases an iron test should be made on the sheet and the unaffected black particles examined for coal. Under the microscope it can be seen that coal particles in a cal- endered sheet have been so pulverized by the pressure of the rolls that they shatter very easily when picked with a dissecting needle. STARCH 37 Large particles give a characteristic black smear when crushed and rubbed across the sheet. Button Specks.—Bone buttons ground by beaters or jordans into small pieces appear in the finished sheet as light colored, powdered spots because of crushing in the calenders. A hole is often made by a button speck due to the particle piercing the sheet and then partly crumbling out after calendering. Such specks can be differentiated from alum as they are insoluble in water and give no acid reaction with the indicators. PAPER SpECKS.—In stock made from old papers small, unde- fibered pieces may slide through the screens and form specks on the sheet. Such specks are fibrous and when lifted out of the sheet they can be defibered under the microscope with dissecting needles, showing their identity by this characteristic. Foam Spots.—Because of the depression left after each foam bubble there is a circular spot more translucent than the rest of the sheet formed wherever foam bursts on the partly formed sheet. The result is characteristic, the spot being circular and translucent, similar to a small, round watermark. Drac Spotrs.—Stock adhering to the slices on the wire forms small, uneven lumps when it drags off upon the sheet. These spots are not very common but can be recognized as irregular forma- tions having no foreign material present. Kwnots.—Fabrics in rag stock with knotted threads very often show the knots in the finished sheet. The knotted thread is easily recognized under the microscope. 5. Starch In addition to chemical tests for the determination of starch in paper, it is possible to determine the kind of starch used. The various untreated starches have characteristic shapes and markings which may be easily identified under the microscope. This is. also possible in some cases with treated starches used in the tub size. III. PHYSICAL TESTING 1. Influence of Hygrometric State Paper, in common with other hygroscopic materials, experiences certain changes. in its physical properties in consequence of the changing hygrometric conditions of the surrounding atmosphere. As the fibers of paper absorb increasing amounts of moisture they increase in diameter and become more pliable, but suffer a loss in felting strength or bonding ability. Such alterations in the fibers affect the strength and many other physical properties of the paper. The effects are considerable and follow very rapidly upon the at- mospheric changes so that it is necessary to carry out most physical tests on paper in an atmosphere of definite hygrometric state. a. ‘TEMPERATURE AND Humipity (ABSOLUTE AND RELATIVE) The amount of moisture in the air (the weight of moisture per unit. volume of air) is often referred to as the absolute humidity. The term relative humidity, which is more often encountered, refers to the amount of moisture in the air relative to the amount which it is capable of containing and is expressed as the per cent saturation of the air with moisture at the existing temperature. The results of numerous experiments indicate that the amount of moisture in paper and those physical properties which are affected by moisture content bear no definite relation to the amount of moisture in the air (absolute humidity), but are governed by the relative humidity of the atmosphere. With a constant relative humidity the effect of temperature is comparatively small. Ac- cording to available data a change in temperature of 10 degrees with constant relative humidity has about the same effect on paper as a change in relative humidity of 1 or 2 per cent at constant tem- perature. It is therefore desirable in the control of the hy- grometric conditions for paper testing to give more attention to maintaining a constant relative humidity than to maintaining a constant temperature. It is, however, desirable to maintain both humidity and temperature constant and TAPPI has adopted 65 per cent relative humidity and 70 degrees F., as the official standard hygrometric state for the testing of paper, this hy- grometric state having been used for many years both in this country and abroad. The relative humidity of the natural or un- conditioned atmosphere varies considerably both seasonally and diurnally. It is sometimes as low as 10 or 15 per cent in steam- ~ heated rooms during the winter and at times during the summer it is well above 90 per cent. During the day it is normally highest in the early morning hours, falling to a minimum value for the day at midafternoon. Because of this daily fluctuation in relative humidity and because considerable time is required for the 38 PYGROME TRIG = STATE 39 moisture content of paper to come to equilibrium with the prevail- ing hygrometric condition, tests requiring hygrometric control are not reliable if carried out in the natural atmosphere of the labora- tory even though the relative humidity is determined and the re- sults are referred to tables or curves for correction. b. ContRroL or RELATIVE Humuipity Maintenance: Some of the more important means of maintain- ing constant humidity are: (1) Air is saturated with moisture by blowing it through a spray of water at the dew point temperature corresponding to the desired temperature and relative humidity and is then heated to the desired temperature, which lowers the relative humidity to the desired value. (2) Moisture from a steam or water spray is mixed with the air until the desired relative humidity is obtained. The apparatus may be either automatic or hand controlled. The temperature may also be automatically controlled, the two control systems being more or less independent. In order to make a device of this nature more generally useful a dehumidifying apparatus may also be added. Moisture is removed from the air either by passing the air over brine coils which condense a part of the moisture, or by passing it over a desiccating agent, such as calcium chloride. (3) Two streams of air, one relatively moist and the other relatively dry, are mixed in the proper proportions to produce the required relative humidity. (4) Air is exposed to a suitable solution having definite relative vapor pressure corresponding to the relative humidity desired’ until the air comes to hygrometric equilibrium with the solution. Automotic control of temperature may be used in connection with any of these methods of controlling relative humidity. References: “Testing Section, Government Printing Office’—Paper Trade Journal 79, No; 18 COct. 30,1924). “The Design, Construction and Use of a Constant Humidity Room’’— ite Launderers’ Research Association, 17 Lancaster Gate, London W. 2, ngland. “A Small Constant Humidity Testing Cabinet’—F. T. Carson, Paper Mill, March 13, 1926; Technical Association Papers, Series IX, No. 1, Technical Association of the Pulp and Paper Industry, New York. ““A Constant Temperature and Humidity Room for the Testing of Paper, Textiles, Etc.”’—-F. P. Veitch and E. O. Reed, Journal of Industrial and Engineering Chemistry 10, No. 1, 38 (Jan. 1918); Paper 21, No. 23, 174 (Feb. Esso L918). “Notes on Temperature and Humidity Control Cabinets’’—Circular No. 310, May 1927, American Paint and Varnish Manufacturers’ Association, 2201 New York Avenue, Washington, D. C. “Constant Humidity Testing Room’’—H. T. Ruff, Paper Trade Journal, 85, No. 8 (Aug. 25, 1927). Measurement: No apparatus for maintaining constant relative humidity has been so perfected as to dispense with frequent mea- surement of the relative humidity. Of the many methods and de- vices which have been used for measuring humidity—the wet and 40 PHYSICAL TESTING dry bulb psychrometer, the hair hygrometer, the dew point appara- tus, gravimetric or volumetric determination of the moisture in the air, electrical resistance hygrometer, refractometric hygrometer, thermal conductivity hygrometer, spectroscopic hygrometer and rigidity measurements of vegetable fibers—the simplest and most satisfactory means of confirming the relative humidity is the use of the ventilated wet and dry bulb psychrometer for accuracy and the recording hair hygrometer for constancy of relative hu- midity. The thermometers used in the psychrometer should be graduated to tenths of a degree, the wet bulb should be com- pletely covered with a tight fitting wick of clean muslin or silk and should be ventilated at a rate of not less than 3 meters per second. A table or chart is used for finding the relative humidity from the thermometer readings. The. hygrometer should be fre- quently calibrated against the psychrometer. A discussion of this subject, together with a lengthy bibliography is contained in the following publication by Ewing and Glazebrook, “The Measurement of Humidity in Closed Spaces,” Proceedings Physical Society (London) 34, No. 192, pages I-XCV (Feb. 15, 1922). (It can be obtained in pamphlet form as Special Report No. 8, Food Investigation Board, Department of Scientific and In- dustrial Research, London). c. Errects PropucepD BY CHANGES IN HyGROMETRIC STATE A brief outline is given following of the principal effects upon the physical properties of paper which are produced by fluctuations in the hygrometric state. Moisture Content: If moisture content is plotted against relative humidity the first half of the curve resembles an absorption curve, the moisture content increasing rapidly at first with increasing relative humidity and then less and less rapidly with further in- crease of relative humidity. But in the region between 50 and 80 per cent relative humidity a reversal occurs and the moisture con- tent mounts at an ever increasing rate as the condition of saturated ~ water vapor is approached. At the standard hygrometric condition the moisture content is from 5 to 10 per cent of the weight of the dry paper, the amount depending upon the kind of paper. Between about 35 and 65 per cent relative humidity this moisture content difference for different kinds of paper is practically constant, the rate of increase of moisture content of most papers being virtually constant in this region. Weight: The change in the weight of a sheet of paper as a re- sult of fluctuations in the hygrometric state is of course the same as the change in the moisture content. However, the change in ream weight is somewhat different from the change in moisture content, owing to the concomitant change in area of the sheet. With in- crease in relative humidity the increase in ream weight is slightly less than the increase in total weight. With decreasing relative HBVGROMETRIC STATE 4] humidity the ream weight changes slightly more rapidly than total weight. Area: ‘The area of a sheet of paper normally increases some- what with increasing moisture content. The change is greater in the cross direction than in the machine direction since the fibers expand in diameter and little or none in length, and the prepon- derance of fibers have their diameters in the cross direction. Ac- cording to available data, a change of 10 per cent in relative humi- -dity from the standard results in a change in dimensions of a stan- dard area (area under standard hygrometric state of 65 per cent relative humidity and 70 degrees F.) ranging from less than 0.05 per cent to nearly 0.5 per cent, the amount depending upon the kind of paper and the direction of the measurement. Tensile Breaking Strength: The breaking strength of paper is greatest at about 35 per cent relative humidity, decreasing in a regular manner from this point with either increasing or decreasing relative humidity. Fluctuations in hygrometric conditions have a somewhat greater effect on the breaking strength in the cross di- rection than on that in the machine direction. According to avail- able data, a change of 10 per cent in relative humidity from the standard results in a departure from a standard breaking strength (that at standard hygrometric state) of some 5 to 25 per cent, the amount depending upon the kind of paper and the direction tested. Elongation at Rupture: Elongation at rupture increases with increasing relative humidity and the curves for this property are somewhat similar in form to those for moisture content. The effect is somewhat greater in the machine direction than in the cross direction. According to available data, a change of 10 per cent in relative humidity from the standard results in a departure from the standard elongation (that at standard hygrometric state) of some 10 to 125 per cent, the amount depending upon the kind of paper and the direction tested. Bursting Strength (Mullen): The bursting strength of paper is also greatest at about 35 per cent relative humidity and decreases both ways from this point in a manner similar to the behavior of the breaking strength, except that the magnitude of the change is only about half of that for breaking strength. Folding Endurance (Schopper): In general the folding endur- ance increases rapidly with increase of relative humidity, so much so that folding endurance tests have very little significance unless carried out under constant hygrometric conditions. The change is somewhat more rapid in the machine direction than in the cross direction. According to available data, a change of 10 per cent in the relative humidity from the standard results in a departure from the standard folding endurance (that at standard hygrometric state of some 5 to 70 per cent, the amount depending upon the ‘kind of paper and the direction tested. ~. é. ies ( h Ww es tron Values at S S G urves) mpos ite 0. aS on of Physical Qua Variat: er “ee? Per Cent--Re vtathe Hamden 42 rie. 8. ical Prop:rt’es of Paper with Chonges in litmid: v. Variation ‘n Phys Hy GRhOmethiG slATE 43 Tearing Resistance (Elmendorf): In general, within the hygro- metric range which has been studied, tearing resistance increases rather rapidly, with increasing relative humidity. The tearing re- sistance of some kinds of paper, however, begins to decrease at very high humidities. According to available data, a change of 10 per cent in relative humidity from the standard results in a de- parture from the standard tearing resistance (that at standard hy- grometric state) of some 5 to 20 per cent, depending upon the kind of paper. Permeability: Tests involving the penetration of water and its solutions into paper, such as tests for degree of sizing, water re- sistance, saturation, etc., are affected to some extent by the initial moisture content of the paper. An increase in the initial moisture content (with increase of relative humidity) results in an increase in the rate of penetration, and a decrease in the total absorption (saturation value). Fig. 8 shows graphically the extent of the changes in these various physical properties of paper from their values at the stan- dard hygrometric state. d. OrriciAL ConpitionNiInc METHOD Following is theofficial Association method of conditioning paper for testing: I, Relative Humidity and Temperature : Whenever required in the test method, the paper sample shall he conditioned and tested in an atmosphere maintained at 65 per cent relative humidity and 21 degrees C. (70 degrees F.) tem- perature. A tolerance of plus or minus 2 per cent in relative humidity (63 to 67 per cent) and of plus 5 degrees C. (9 degrees F.) in temperature is permissible. Il. Conditioning : Each specimen of the paper sample, after preparation for ap- plication of the test as specified in the test method, shall be so suspended that the conditioning atmosphere will have free ac- cess to all surfaces. Means shall be provided for so circulating the air of the conditioning and testing chamber that its humidity and temperature will be uniformly maintained. The conditioning time shall be sufficient for the moisture content of the specimen to attain equilibrium with the conditioning atmosphere, this to be determined by conditioning to constant weight, weighing at intervals of not less than % hour. Note:—A conditioning period of 2 hours is usually sufficient for papers of ordinary weight and composition. - Some papers, however, such as boards and certain specialties made water re- sistant, may require much longer periods. III, Determination of Humidity and Temperature : The relative humidity of the conditioning atmosphere shall be determined by means of either (1) a sling psychrometer, or 44 PHYSICAL Ro ae (2) a stationary type of psychrometer having the air circulated over the thermometer bulbs mechanically. In both cases, the cir- culation of air around the thermometer bulbs must be at the rate of not less than 3 meters (10 feet) per second. When the sling type is used, care must be taken to make the readings as quickly as possible after bringing it to rest. The thermometers used for determining humidity and tem- perature must be accurately calibrated by comparison with certi- fied standard thermometers and any corrections found neces- sary applied to the readings. Note:—It is recommended that thermometers approaching as closely as possible to the following specifications be used: Range 0 degrees C. (32 degrees F.) to 50 degrees C, (122 degrees F.) ; graduation, 0.2 degrees. 2. Machine Direction Several methods’ are available for determining the machine directions of the original paper sample sheets. The major direc- mere inspection of the sheet, as the formation noted on looking through it is often conclusive to the trained observer. The usual machine wire imparts to the sheet of paper a “wire mark” consisting of a series of diamond-shaped marks, the long diagonal of which points in the machine direction. If the wire mark is sufficiently prominent so that its direction can be de- termined this will establish the machine direction. Following is the official Association method for determining machine direction: I. Terminology and Definition: The two major directions of paper shall be termed: Machine Direction—The direction of paper parallel to its for- ward movement on the paper machine. Cross Direction—The direction of the paper at right angles to the machine direction. Il. Specimens: The test specimens shail be cut with sides parallel to the major directions of the original paper sample sheets. The major direc- tions of both the sample sheets and the test speciments shall be so marked that they can be respectively identified. For method 1, a piece approximately 50 mm. (2 inches) square or a circular piece 2 inches in diameter, and for method 2, two strips approxi- mately 12.5 mm. (0.5 inch) wide and 152 mm. (6.0 inches) long, cut at right angles to each other, shall be used. ITI. Methods: A positive result obtained by one of the following methods shall be regarded as a conclusive aetermination. 1. Float the specimen on water and note the direction of the 1 Chemistry of Pulp and Paper Making by Edwin Sutermeister. Chapter 15, pages 386-428. MACHINE DIRECTION 45 curl. The axis of the curl is parallel to the machine direction of the paper. Paper which absorbs water readily should not be exposed to the water for more than a few seconds. 2. Hold the two strips by the ends in a horizontal position, one over the other, placing first one and then the other on top. The strip cut in the cross direction will bend the more and fall away from the one cut in the machine direction. 3. Burst the specimen, using the instrument described in the official method for determination of bursting strength. The chief line of rupture will be at right angles to the machine direction of the paper. IV. Report: In reporting test results the terms “machine direction” and “cross direction” shall be used. When the strength of paper in the two major directions is reported, it shall be understood that the line of bending or rupture of the paper was at right angles to the major direction specified. V. Additional Information: By the term “grain” as applied to paper is meant the machine direction of the paper. 3. Wire or Felt Side? In many cases this may be determined very easily by a simple inspection but in some papers the wire marks do not stand out at all plainly. Sometimes they may be more prominent by plung- ing the sample for a moment into water and draining or blotting off the excess. The moisture causes the fibers. to expand, thus undoing the work of the calenders and restoring the texture of the sheet as it left the machine wire. Inspection of a sheet thus dampened will often show that the wire marks stand out plainly, where before they were indistinguishable. This method very often proves satisfactory even for coated paper. 4. Weight of Paper a. OrriciIAL METHOp. Following is the official Association method for determination of ream weight of paper: I. Apparatus : The balance used for weighing paper shall have a sensitivity of not less than 0.25 per cent of the load applied and shall be so graduated that readings of this degree of accuracy can be made. The balance shall preferably be a specially constructed sheet weighing device indicating the equivalent weight of a 500-sheet ream and a 480-sheet ream in pounds when a specimen consisting of one sheet of designated size is weighed. The balance musi be protected from air currents. 2 Chemistry of Pulp and Paper Making, by Edwin Sutermeister, Chapter 15, pages 386-428. 46 PHYSICAL-TESTING The scale used for measuring the size of the specimen shall be graduated not more than 0.05 inch (1.27 mm.). For trimming the specimens to the desired size, a special paper -cutter with an attachment for ensuring parallelism of the opposite -cut edges is recommended. IT. Calibration: The balance shall be calibrated at intervals of not more than 30 days, both with increasing and decreasing load, by applying accurate weights. Care must be taken that, before calibrating, the ‘balance be properly leveled and give zero reading with no load. Ili. Method: The specimen for test shall consist whenever possible of at Fic. 9a: Quadrant Scale. (Fred Baker, New York, N. Y.) WEIGHT OF. PAPER 47 Fic. 9b. Torsion Balance. (Torsion Balance Co., New York, N. Y.) Teast 10 sheets, 10 by 10 inches (254 mm.) in size, of book or writing papers and equivalent amounts of other kinds of paper of greater or less weight than these. The specimen shall be condi- tioned by the official method, cut accurately as to parallelism of opposite edges, its exact dimensions measured to the nearest 0.05 inch (1.27 mm.), and its weight then determined to the nearest 0.25 per cent of its total weight, the entire operatron being carried out in the official atmospheric conditions. When a balance is used which does not indicate the ream weight directly, the weight in grams of a single sheet multiplied by 1.102 gives the equivalent weight in pounds of a 500 sheet ream for sheets having the size of the sheet weighed. Duplicate determinations when calculated to ream weight shall agree within 1 per cent of the ream weight. IV. Report: The report shall give the equivalent ream weight in pounds for a ream consisting of 500 sheets, 25 inches (635 mm.) by 40 inches (1016 mm.) in size, and also the equivalent weight for the basic weight area commonly used by the paper industry for the pat- ticular kind of paper. The weight shall be reported to the nearest 1 per cent of the total ream weight. my V. Additional Information : To convert the weight of a standard ream of 500 sheets, 25 by 40 inches in size, to the weight of a ream of 500 sheets of trade custom size, multiply the former by one of the factors given below: PHYSICAL TESTING 48 Trade Custom Size & © Ome a oS ~ . N BAN Vv ‘ atom 9 MN 3 <4 sae as: eae eo te a. e if Beha Oi a ae Ones =} ER: MS y pag QQ Boards . Bristolyarid tag san ceinuel ite Card Book eee eee we ewe 25 SS - . . Cover eee News T . issue Wrapp Wr . ing 17 x 22 oe F it a nF ERE ays sony Fic. 9c Basis Weight Scale. (Thwing Instrument Co. Philadelphia, Pa.) WEIGHT OF PAPER 49 ~ ~ Fic. 9d. Pea and Beam Scale Commonly Used in Paper Machine Rooms. (Fairbanks & Co., New York, N, Y b. BALANCES AND SCALES Various types of weighing devices are illustrated in Figs. 9a to 9d, inclusive. The sheet-weighing device that indicates the equivalent weight in pounds in terms of a 5(00-sheet ream, is most suitable for labora- tory or mill use. In weighing very small samples it is not desirable to use a weigh- ing device graduated in terms of a 500-sheet ream. For such cases a chemical balance should be used and the weight in grams multi- plied by 1.102 will give the equivalent weight of 500 sheets of the size weighed, Formula for sample weight on sheet paper scales: iwte eine) 5<1_.C1,000) —_ — = weight 25 x 40—500 Area of sheet in sq. in. (wt. in lb. & (area of trade size desired) d $C 6 = wt, of trade size desired Area of sheet in sq. in. It is obvious that the samples being weighed must be accurately measured to determine their size, and this is done by means of an accurate rule, graduated in 0.05 inch. The following formula is of assistance where a is scale reading, b is one dimen- sion of the sample, c is the dimension at right angles to b, and d is the number of paper in the sample: 50 PHYSICAL ‘TES TING a xX 15060 —_—_—————— = weight in lb. per ream 25 x 40—500 Or Tex a For samples of paper weighing less than 20 pounds on the quadrant scale a chemical balance is used. For convenience the following formula is used: (Weight in grams) X (1,102) x (1,000) —- = wt. in lb. per ream (Area of samples in sq. in.) X (number of sheets) 25 x 40—500 To convert the weight of the standard ream to the weight of a ream of the desired trade size, it is only necessary to multiply the weight of the former by the area of the latter and divide by 1,000, provided, of course, that the Jatter ream contains 500 sheets. 3. CONVERSION Factors. The weight of a ream folio size, 17 x 22—500, can be stated as the substance number. A method for determining the substance number on small samples by the analytical balance is as follows: A flat piece of thin metal cut exactly 2 x 2 1/16 inches is held upon the sample and a sharp instrument run around the edge of the metal. The sample cut exactly 2 x 2 1/16 inches has a substance number equal to its weight in centigrams. Weight in centigrams & 500 sheets X 0.374 sq. in. per sheet ; = substance 45,360 centigrams per pound X 4.125 sq. in. in sample Weight in centigrams X 178,000 es substance number 187,110 TYPICAL EQUIVALENT WEIGHTS IN STANDARD AND TRADE SIZES Weight of ream Trade size ream Area of sheet Weight of ream 25 x 40—500 500 sheets trade size Ib. in. in. Ib. 52.6 Zax oe 950.0 50 64.2 ie ene 374.0 24 100.0 DO G25 500.0 50 156.0 22.5 x 28:5 641.3 100 Conversion between ream basis weight and grams per square meter: Weight in grams per sq. m. = (Weight in lb. of any ream, 500 sheets) XK 1406.13 —— Area of sheet in sq. in, Weight in lb. per ream of 500 sheets = (Weight in g. per sq. m.) X (Area of sheet in sq. in.) 1406.13 To convert to lb. Ream size To convert to grams 0.267 17 x 33—500 chaps) 07145) 25 x 40—500 1.40 0.429 20 x 30—... 2030 0.591 24 x 36—480 1.69 0.675 25 x 38—500 1.48 0.618 24 x 36—500 1.62 Fic. 10a. Mullen Bursting Strength Tester. (B. F. Perkins & Son, Holyoke, Mass.) Fic. 10b. Cady Bursting Strength Tester. (E. J. Cady & Co., Chicago, Til.) 51 4 PHY ShUAT. sis bis Length of paper in a roll: Roll weight Ream area (sq. in.) Length in ft... = ——@@@—@———$— quem x ae Ream weight X roll width 12 Ream size Factor 17 22500 Fie eb att oa ee 15,583 25" X'38—-S00Ge i a ee ie ee 38,583 25K EO —— SOO oa laceahace Chekate eae eke eee 41,667 20°. 26—=500... A Ae es ee 21,667 20 X28 SOA BO i Grek sisee Ca oe one nee eee 24,000 24-3 362-480) 4 25 pS Pee eee eee eae 34,500 5. Bursting Strength a. DESCRIPTION There are two types of testers available for determining the bursting strength of paper and board. One is of the hydraulic type in which the paper is clamped against a rubber diaphragm, through which the pressure is applied to a circular area of the paper measuring approximately 1 square inch. The pressure is indicated on a special Bourdon tube gage. The second type is of the spring operated metal plunger design in which the paper 1s clamped between annular rings, through which a spring operated plunger is forced. Although a large amount of data has been collected by indivi- dual laboratories with the instruments shown in the accompanying photographs (Figs. 10a, 10b, 10c, 10d) very little information has Fic. 10c. Ashcroft Bursting Strength Tester. (Ashcroft Mfg. Co., New York, N. Y.) BURSTING STRENGTH 33 Fic. 10d. Webb Bursting Strength Tester. been published. There appears to be very little, if any, relation between the data obtained with these three testers. With averages of equal number of tests, the variation seems to be inversely pro- portional to the diameter of contact. The hydraulic type of burst- ing strength tester is illustrated in Figs. 10a and 10b, and the plunger type in Figs. 10c and 10d. b. OrricraAL AssocriATION METHOD This method, which follows, specifies the use of the hydraulic type of tester. I. Apparatus : The testing instrument shall consist of: (1) A circular aperture 31.5 mm. (1.24 inches) in diameter in a’ plane surface, the aperture registering exactly with a similar aperture in a second plane surface. One aperture shall communicate with a hydraulic cham- ber and the other shall be movable along the axis passing through 34 MPHYSICAL TESTING the centers of the two apertures. (2) Means of firmly clamping the two plane surfaces together. The clamping pressure and the extent of the contacting plane surfaces shall be such that there shall occur no slipping or creeping during the test of a specimen clamped between the plane surfaces and no injury to the specimen so clamped. (3) A rubber diaphragm firmly se- cured to the inner side of the aperture in the hydraulic cham- ber so as to close it off and expand through it when hydraulic pressure is applied. (4) Means of applying hydraulic pressure through a noncompressible fluid to the rubber diaphragm. (5) Means of accurately and continuously registering the pressure maintained in the hydraulic chamber, the Bourdon tube pressure gage being preferred. IT. Specimen: Specimens for test shall be so selected from a sample secured by the official sampling method, as to be representative of the sample. lil. Method: The specimen shall be firmly clamped in position and pressure applied within the hydraulic chamber at a uniform rate such that the noncompressihle fluid shall be. displaced against the rubber diaphragm and through the aperture at a rate of 75 cc. per min- ute’ until the paper bursts. The gage used must be such that the bursting strength of the paper tested will not be greater than 3% of its capacity, nor less than 1% of its capacity. The gage read- ing shall be recorded to the nearest 2 per cent of the total read- ing. At least 10 bursts shall be made, each of a different speci- men of the sample and an equal number from each side of the specimen. Bursting strength tests shall be made on specimens conditioned according to the official methed for conditioning, and in the atmospheric conditions therein specified. IV. Calthration: The instrument shall be calibrated at intervals of not more than thirty days. The calibration shall be performed as fol- lows: The gage shall be removed and calibrated in a horizon- tal position with a deadweight gage tester of the piston type. A record shall be kept of any deviations from the indicated read- ings and corresponding corrections made in test results secured with the gage. The gage shall be replaced and the pressure chamber refilled with sufficient glycerine to leave the rubber dia- phragm, when placed in position, slightly depressed, taking care to eliminate all air bubbles. The rubber diaphragm shall be re- newed at least every thirty days. V. Report: The report shall include the average, the minimum and maxi- mum test results. The readings of the gages shall be reported 3 This rate is equivalent to turning the hand wheel of the ordinary type of bursting strength tester at a rate of 120 r.p.m. THICKNESS 55 to the nearest 2 per cent of the total reading and shall be ex- pressed as “points.” c. RATIO The bursting strength test to be of greatest use must be ex- pressed in terms of the weight of the sample. This ratio of strength to weight may then be directly compared with the strength ratio of any other paper. The strength ratio may be expressed as a percentage. Bursting strength x 100 Wt. in lb. (on a size 25 x 40—500) Strength ratio = 6. Thickness The following is the official Association method of determining the thickness of paper: I, Apparatus: (a) A micrometer of the spring actuated, dial type shall be used. The plunger shall be capable of being raised by the appli- cation of an upward pressure to it. The plunger surface shall be circular in shape and not less than 9.7 mm. (0.38 inch) nor more than 16 mm. (0.63 inch) in diameter. The dial shall be graduated PGe LE Cady Thickness Micrometer. (E. J. Cady & Co., Chicago, III.) 56 PHYSICAL TESTING preferably in divisions indicating a thickness of 0.0127 mm. (0.0005 inch) and in no case greater than 0.025 mm. (0.001 inch). Gradua- tions indicating a thickness of 0.0254 mm. (0.001 inch) shall be at least 3 mm. (0.12 inch) apart. Convenient means shall be pro- vided for setting the pointer to zero position. (b) The surfaces of the plunger and anvil shall be plane and parallel to within 0.005 mm. (0.0002 inch). (c) Under normal operating conditions the downward pressure of the plunger shall be not less than 709 grams (25 ounces) and not more than 1418 grams (50 ounces), at a reading of 3.81 mm. (0.15 inch). (d) Measurements made on standard steel thickness gages shall be within the following tolerances. Permissible deviation of reading from actual thickness of standard Intervals steel gage 0 to0:25. mm...(0to’ 0.01 in inch) 5 = a eee 0.0025 mm. (0.0001 in.) Over 0.25 mm. to 1.02 mm. (0.01 to 0.04 in.)..... 0.0051 mm. (0.0002 in.) Over 1.02 mm. to 3.05 mm. (0.04 to 0.12 in. incl.) 0.0102 mm. (0.0004 in.) II. Specimens: The test specimens shall consist of original sample sheets so selected as to be representative of the entire sample. III, Method: At least 10 thickness tests shall be made, each on a different specimen except in the case of paper less than 0.05 mm. (0.002 inch) in thickness when a sufficient number of specimens shall be placed together and tested so that a reading on the scale of not less than 0.13 mm. (0.005 inch) is obtained. Thickness tests shall be made on specimens conditioned by the official method and in the atmospheric conditions therein specified. IV. Calibration: (a) For testing for compliance with Section 1 (b), a hard steel ball, 4.77 mm. (0.125 inch) in diameter shall be placed at different points on the anvil and the thickness readings observed. It is recommended that the ball be fixed in a flat piece of metal, part of which acts as a handle. (b) For testing for compliance with Section 1 (c), the pres- sure must be measured by means of a suitable balance device applied to the plunger. (Details of such device may be obtained from the U. S. Bureau of Standards.) V. Report: The average, maximum and minimum thickness shall be re- ported in parts of an inch to the nearest 0.0025 mm. (0.0001 inch). VI. References: “A Study of Commercial Dial Micrometers for Measuring the Thickness of Paper.”—P. L. Houston and D, R. Miller. Technologic Paper No. 226, U. S. Bureau of Standards. The type of thickness tester mentioned is shown in Fig. 11. 7. Bulk The bulk of paper is the thickness of a certain number of pages and applies more particularly to book papers where the printer - BULK “i Hig 212: Bulk Tester. (B. F. Perkins & Son, Holyoke, Mass.) desires a book of a certain number of pages to bulk one inch. The bulk of a paper is measured by cutting out short strips of paper, piling them up to the required number and measuring the combined height of the pack. This measurement may be made by the use of a Perkins bulk tester (Fig. 12). This instrument measures the bulk in inches; also the pressure of clamping, and takes the place of the ordinary graduated sliding clamp which is in common use. In specifying the bulk of a paper, where the hand 58 PHYSICAL FESTING clamp is used, it is necessary to specify whether heavy, medium or light pressure is used. In using the Perkins bulk tester, the pres- sure is specified in pounds per square inch, as indicated on the dial. 8. Folding Endurance a. GENERAL INFORMATION The folding endurance of paper is measured by means of an instrument by which the paper is held under a fixed tension and repeatedly folded on itself until it breaks. There are two types of commercial instruments available. The type specified in the official method following is known as the Schopper (Fig. 13), which was originally designed by Louis Schopper. This was de- signated in the official method owing to its being the only commer- cial instrument in extensive use at the time and to very complete ‘data on its performance being available. The other type of folder described appears, in principle, to have several advantages. Refer- ence to the discussion of effect of hygrometric state on the folding endurance test (page 41) will make clear the necessity of accu- rately controlled humidity conditions for this test. b. OrricrAL ASSocIATION METHOD I. Apparatus: The testing instrument shall consist of: Miers. Schopper Folding Endurance Tester. (Foreign Paper Mills, New York, N. Y.) FOLDING ENDURANCE 59 (1) Two horizontally opposed jaws which are constrained to move in the same straight line without rotation. The jaws shall be suitably supported as by frictionless rollers (see note). The jaws shall be adapted to maintain the ends of the specimen in the same vertical plane. There shall be provided a means for holding the jaws in a fixed position while inserting the specimen and a means of subsequently subjecting the specimen to a maximum tension of 1 kilogram and a minimum tension of approximately 0.8 kilogram alternately as the specimen is folded and unfolded. Note—Cylindrical rollers are preferable to the knife-edge rollers some times used for the purpose as the edges of the latter fer- quently become flattened, causing increased friction and conse- quent error in the results. (2) A vertically slotted, horizontally reciprocating blade mount- ed between the jaws and moving transversely to the line of motion of the jaws in such manner that the edges of the slot shall push the specimen alternately to either side of its neutral position in_ the line of motion of the jaws by a distance of 10.16 mm. (0.400 inch). The slotted blade shall have a thickness of 0.50 mm. (0.020 inch) and the edges of the vertical slot shall be rounded to a cylindrical surface. The vertical extension of the slot shall be such as to extend beyond the upper and lower edges of the speci- men. (3) Four rollers rotating on vertical axes mounted in a quad- rangle about the central position of the vertical slot in the recip- rocating blade so as to cause the specimen to fold around the edges of the vertical slot and lie against the blade as it moves back and forth. These rollers shall be so mounted that the recip- rocating blade bisects the clearance between rollers in one direc- tion and the specimen in its neutral position bisects the clear- ance between rollers in the transverse direction. The minimum clearance between the blade and the rollers on either side shall be €.38 mm. (0.015 inch) and the minimum clearance between rollers in the space occupied by the specimen shall be approximately 0.50 mm. (9.020 inch). The design throughout shall be such as to entail a minimum of friction in the moving parts. (4) A means of imparting harmonic motion of constant period to the reciprocating blade. A power driven apparatus is prefer- able. (5) A device for registering the number of double folds re- quired to sever the specimen. IT. Specimens: Specimens to be tested shall be cut accurately in each principal direction of the paper with a width of 15 mm. (0.59 inch) and a length such as to insure a firm grip in the jaws without buckling. They shall initially be free from foldsi or wrinkles or blemishes not inherent in the paper. The edges of the specimens must be 60 PHYSICAL TESTING clean-cut and parallel to the opposite edges. The specimens shall be so selected from the sample secured by the official sampling method as to be representative of the sample. III. Method: With the vertical slot of the reciprocating blade in its central position the specimen shall be placed in the slot and the ends clamped firmly and squarely in the jaws with the surface of the specimen lying wholly within one plane. The specimen shall be handled by the ends and not touched with the hands in the region which is to be folded. The specified tension shall then be applied and the specimen folded at a uniform rate of approximately 120 double folds per minute until it is severed at the crease. The number of double folds required to sever the specimen shall be recorded. Not fewer than 10 strips cut in each principal direction of the paper shall be tested. Folding endurance tests shall be made on paper conditioned according to the official method for conditioning, and in the atmospheric conditions therein specified IV. Calibration: é Two pairs of bow dividers, a 1 kilogram weight, and preferably a suitable medium, such as a balanced frictionless pulley or bell- crank lever, for applying deadweight load to a horizontally mov- ing jaw are required for the calibration. . All working parts shall be in good condition, well oiled and in proper adjustment. Especial attention should be given to the con- dition of the supporting rollers, particularly if they are of the knife-edge type, replacement being necessary if the edges are worn flat at any point. The calibration shall be made essentially as follows: On each jaw make two very small punch-marks in a line par- allel with the direction of motion of the jaw, one punch-mark being made on the shoulder of the jaw and the other on the adjacent shoulder of the fixed jaw-stem guide. Clamp in the jaws, according to procedure under Method, a strip of cellu- loid 0.005 inches thick. Revolve the driving wheel until the slot in the folding blade is farthest from its central position and then apply the tension to the jaws by pulling out the two spring hous- ings simultaneously. Adjust one of the bow dividers to accur- ately span the interval between the punch-marks on one jaw and adjust the other pair of dividers similarly to span the interval between punch marks on the other jaw. Take care that these divider settings remain unchanged during the calibration. Release the spring tension, revolve the driving wheel a half revolution, again apply the spring tension and see if the intervals are the same as before. If not the crank pin is probably worn and must be put in repair so that each interval is the same for the two antipodal positions. Apply a deadweight load of 1 kilogram (see note) to one of the jaws, tap apparatus lightly and allow the FOLDING ENDURANCE 61 stressed jaw to come to a stable position. Adjust the tension of the spring until the interval between the two punch-marks is ex- actly the same as for the original setting of the dividers for that jaw. In a similar manner adjust the spring tension of the other jaw so that a deadweight load of 1 kilogram produces the interval between punch-marks for which the other dividers were set. This procedure insures that the maximum tension on the specimen being folded is exactly 1 kilogram. Put a specimen in place in the tester and apply the tension as for a folding test. Turn the driving wheel until the folding blade is farthest from its central position as at first and see if the two intervals are the same as for the setting of the respective dividers. If so the tester is ready for use. If one interval is greater and the other less than the setting of the respective dividers it is impossible to calibrate the instru- ment until the jaw springs have been replaced by matched springs. The folding tester shall be calibrated at intervals of not more than 30 days. Note—The deadweight load may be applied in the horizontal normal operating position by means of a balanced bell-crank lever having knife edge suspension or by means of a frictionless pulley Fic. 14. Bell-Crank Lever for Calibrating Schopper Folding Endurance Tester, Bureau of Standards, Washington, D. C.) 62 PHYSICAL TESTING over which is passed a strong thread or fine wire, one end of which is fastened in the jaw and the other attached to a kilo- gram weight. In the latter case it is necessary to take one of the jaws with its support out of the way while calibrating the other, and to take care that the wire or thread does not touch any part of the apparatus other than those specified; or if de- sired the jaw to be calibrated may be removed together with housing and support, taken apart so as to obtain the weight of the jaw, reassembled and clamped in a vertical position, and stressed by a deadweight which together with the weight of the jaw is equal to 1 kilogram. bk Report: Tht results shall be reported in double folds. The average, the maximum and the minimum folding endurance for both of the principal directions of the paper shall be reported. VI. References: “Folding Endurance of Paper.’—F. P. Veitch, C. F. Sammet and E. O. Reed. Paper 20, No. 12 (May 30, 1917). “Resistance to Folding.’—W. Herzberg. Chemical Abstracts 14, page 2262 (July 20, 1920). “Calibration and Adjustment of Schopper Folding Tester.”—F. T. Garson and L. W. Snyder (describes use of bell-crank lever for calibrating). Bureau of Standards Technologic Paper. No. 357. c. CALIBRATION Following is a description of a bell-crank lever ae at the Bureau of Standards for calibrating the Schopper folding tester (Fig. 14): This device is a convenient means of adjusting the tension on the clamp springs without disturbing the assembly of the tester. It consists of a bell-crank lever having two arms of equal length and at right angles to each other, the intersection being on the knife edge K.. The knife edge rests on the end of the bracket B which is clamped about the fixed barrel of the spring housing in a definite position. The bell-crank lever is counterbalanced so that it is in static equilibrium as it rests on the knife edge support, the weight W and the tab T being removed. In using the appara- tus the proper deflection interval is determined as outlined in the calibration method is spanned by the bow divider D. The bell-crank lever is then put in place, the tab T is clamped between the jaws (the tab T is connected to the lever arm by a short link) and a 1-kilogram weight W is suspended from the hook at the end of the other arm. The spring is now adjusted until the proper deflection interval is obtained as indicated by the setting of the dividers D. During this adjustment the spring housing is tapped lightly so as to bring the spring to equilibrium. d. M.I.T. (MassacHusetts INSTITUTE OF TECHNOLOGY) FOoLDING "TESTER In this folding tester (Fig. 15) one end of the strip of paper to be tested is held in an oscillating clamp each of whose jaws FOLDING ENDURANCE 63 Pres 15; M. I. T. Folding Endurance Tester. (Tinius Olsen Testing Machine Co., Philadelphia, Pa.) is tapered to a rounded edge. These two edges are cylindrical surfaces having a diameter of about 0.75 mm. and are very near the center of oscillation of the clamp. As the clamp oscillates the paper is bent about these rounded edges through an angle of 135 degrees each side of the vertical. The test strip is held under definite tension, the other end being fastened in a clamp which is attached to a calibrated spring. A ratchet counter registers the number of double folds required to wéaken the strip sufficiently to break under the constant spring tension (usually 1 kilogram). The relatively few working parts to be driven by the specimen, 64 PHYSICAL TESTING Pre. 16a: Schopper Tensile Breaking Strength Tester. (Foreign Paper Mills, New York, N. Y.) the absence of jar or impact upon the specimen, the constancy of the fénsion during a test, the ease with which the spring is calibrated and the readiness with which the spring tension may be varied to suit the type of paper to be tested are outstanding advantages of this type of tester. 9. Tensile Breaking Strength a. DESCRIPTION The tensile breaking strength of paper is the load required to ‘pull a strip apart. Figs. 16a, 16b, 16c and 16d illustrate the com- mercial instruments available for applying this test. The first Fic. 16b. Scott Tensile Breaking Strength Tester. (Henry L. Scott Providence, R. I.) 65 PHYSICAL TESTING Fic. 16c Perkins Tensile Breaking Strength Tester. (B. F. Perkins & Son, Holyoke, Mass.) two are the pendulum type specified in the official Association method following, T hey may be obtained both hand driven and electrically driven, the latter being preferable. b. OrricraL Meruop I. Apparatus: The instrument shall consist of, (1) two clamps whose centers shall be in the same plane parallel with the direction of motion TENSILE STRENGTH 67 Pig. Lod. Schopper Tensile Breaking Strength Tester. (Foreign Paper Mills, New York, N. Y.) of the stressing clamp and so alined that they will hold the test specimens wholly in one plane, (2) a pendulum so attached to one clamp as to accurately balance the load applied to the test specimen, (3) a device attached to the pendulum to indicate on a graduated scale the breaking load of the test specimen, (4) a scale graduated in weight units (preferably metric) which may be read to an accuracy of not less than 0.2 per cent of the total reading and (5) a means of moving the stressing clamp at a uniform rate. The machine shall preferably be power driven. Ti. Specimens: Specimens for test shall be cut accurately in each principal direction of the paper, not less than 12.7 mm. (0.5 inch) nor more than 25.4 mm. (1 inch) wide, and not less than 140 mm: (5.5 inches) in length. The edges of the specimens must be clean cut and parallel to the opposite edges. The specimens must be accurately cut to the predetermined width. They shall be so se- lected from the sample secured by the official sampling method as to be representative of the sample. III. Method: The ratio of the clearance distance between jaws to the width of the specimen shall be not less than 5:1, nor more than 12:1. The test specimen shall be firmly clamped squarely in the jaws of the clamps and the stressing jaw then operated at a speed of 30.5 cm. (12 inches) per minute until the specimen breaks. ‘The breaking load shall be recorded to the nearest 2 per cent of tne total indicated retading. The tester shall be of such capacity that the tensile strength of the paper tested will be not greater than 90 per cent, nor less than 10 per cent of the capacity of the tester. Not less than 10 strips cut in each principal direction of the pa- per shall be tested. Ail the readings obtained when the paper breaks at or in the jaws shall be rejected. Tensile strength tests shall be made on paper conditioned according to the official meth- od, and in the atmospheric conditions therein specified. 68 PHYSICAL TESTING IV. Calibration: The machine shall be accurately leveled in both of the princi- pal directions. The stressing clamp shall be displaced or re- moved and accurate weights corresponding to various divisions of the scale markings shall be suspended from the pendulum ac- tuating clamp. The weights shall be held at the start and re- leased slowly so that the pendulum is actuated at a rate similar to that specified above and other conditions must simulate the paper testing conditions as closely as possible. A record shall be made of deviations from the scale readings and corresponding corrections shall be made in the test results. The machine shall be calibrated at intervals of not more than 30 days. 7. Report: The result shall be reported in kilograms per 15 mm, width to the nearest 2 per cent of the total reading. The average, maxi- mum and minimum tensile strength for both of the principal di- rections of the paper shall be reported. The report shall include the width of the specimen in millimeters. c. Wet TENSILE STRENGTH It is sometimes desired to determine the tensile strength of papers when wet, this applying to papers used in that condition such as blueprint. The wet tensile strength is determined by breaking a strip of paper of a definite width, after it has been immersed in water at a constant temperature for a definite period of time. The jaws of the clamps should open in front so the ends of the wet strips may be inserted without injury, and are set at 10 cm. apart, as a short strip of wet paper can be handled more easily. The test strips are cut 15 mm. wide and sufficiently long to allow for clamping in the machine. Tests are made in both the machine and cross direction, running five to each direction. The tester is operated at a speed of 12 inches per minute. The strips are placed separately in a water bath at 70 degrees F., for 20 minutes. After the specified time they are removed one at a time and tested immediately. To obtain accurate results extreme care must be exercised in handling and clamping the wet strips to prevent injury to them. The tensile strength tester used for this purpose must have a capacity of not more than 5 kilograms. 10. Tearing Strength Following is the official Association method for determining the tearing strength of paper. Fig. 17 illustrates the type of instru- ment designated in, this method. I. Apparatus: The testing apparatus shall consist of a stationary jaw, a mov- able jaw carried on qa pendulum, a slitting device and a device for registering the tearing force. The pendulum shall perferably be in the shape of a sector and carry on it’ a scale, the graduation of which shall indicate the tearing force, preferably directly in TEARING STRENGTH Fic. 17. Elmendorf Tearing Tester. (Thwing Instrument Co., Philadelphia, Pa.) grams, from 0 to 100, laid off on the sector within approximately 50 degrees of arc. A stop shall be provided for holding the sector in its initial displaced position and for releasing it quickly. With the pendulum in its initial position ready for a test, the two jaws shall be separated by an interval of about 3 mm. (0.12 inch) and 69 70 PHYSICAL. TESTING shall be in line so that the specimen clamped in them lies in a plane perpendicular to the plane of oscillation of the pendulum, and so that the tops of the jaws are in a horizontal line. The movable jaw shall be so placed on the sector that a line in the plane of the sector from the point of suspension of the pendulum to a point where the top of the jaw is in contact with the speci- men shall be about 10 cm. (4 inches) long and shall make an angle of about 30 degrees with the plane of the specimen. The slitting device shall be so arranged as to cut an initial slit in the speci- men half-way between the two jaws and extending from the lower edge of the specimen to a distance of about 4 mm. (0.16 inch) above the top of the jaws. IT. Specimens: ; Specimens for test shall be cut accurately in each principal direc- tion of the paper not less than 6.3 cm. (2.5 inches) in length (the horizontal position when placed in the jaws) and of such width that the paper shall extend exactly 43 cm. (1.69 inches) above the apex of the initial slit. The edges of the specimens must be clean cut and the opposite edges parallel. The specimens shall be sa selected from a sample secured by the official method as to be representative of it. III, Method: Enough sheets shall be torn at one time so that the readings on the scale shall be not less than 20 grams and not more than 40 grams. The test specimen shall be so placed in the jaws that it rests evenly on their bottom plates and so that the paper extends a distance of not less than 2.5 cm. (1 inch) into the movabie jaw. Readings obtained when the tear deviates more than 6.3 mm (0.25 inch) from the line of the initial slit shall be rejected. The sector stop must be released sharply in operating the in- strument. The knife for making the initial slit shall be main+ tained sharp. Not less than 5 tearing tests shall be made in each principal direction of the paper and the results shall be computed in grams per single sheet of paper by multiplying the readings of the instrument by 16 and dividing by the number of sheets tested at one time. Tearing strength tests shall be made on paper conditioned by the official method and in the atmos- pheric conditions therein specified. IV. Calibration: ; With the sector raised to its initial position and resting against its stop the jaws shall be accurately alined, readjusting the stop if necessary. The ball bearings shall be adjusted so as not to bind and shall be well oiled. The instrument shall be levelled so that the edge of the stop against which the sector rests in its initial position lies vertically below the point of suspension of the sector. A white line is usually placed on the sector for convenience in making this adjustment. With the sector freely suspended and TEARING STRENGTH 71 at rest this mark should be in line with the edge of the stop. Verify the position of the mark with a plumb line cutting the axis of suspension of the sector. After being levelled, the instrument shall be operated several times with nothing in the jaws (movable jaw closed) to find if it registers zero with no tearing load. If necessary the pointer stop shall be adjusted until the zero read- ing is correctly registered. Place the pointer exactly on zero. Without again touching the pointer operate the instrument three times, being very careful each time not to jar the pointer in setting the sector against its stop. The pointer will be pushed beyond zero for a distance which measures the maximum pointer friction, This should be equivalent to not more than 3 grams (compare with distance from zero to 3 on scale). If necessary to reduce this friction, clean pointer sleeve and groove (washing with gasoline if necessary) and apply fresh oil. Note: The friction error allowed has been compensated for at its maximum value by the shifting of the pointer stop in adjusting the zero reading. V. Report: - The results shall be reported in grams to the nearest 1 gram. The average, maximum and minimum tearing strength for both of the principal directions of the paper shall. be reported. The report shall include the number of sheets torn at one time. Fic. 18. Bureau of Standards Modification of the Elmendorf Tearing Tester for Increasing Its Capacity. 72 PHYSICAL TESTING VI. References: “Tearing Strength Test for Paper.”—-A. Elmendorf, Paper, 26, folio page 302 (April 21, 1920). “ Tearing Strength of Paper, Supplementary Study of Commercial Instru- ments of Determining.’”—P. L. Houston, Paper Trade Journal 74, No. 10, 43 (March 9, 1922). A publication of the Bureau of Standards, Means of Increasing the Capacity of the Elmendorf Tearing Tester, describes a modifi- cation of this tester which makes possible its use for testing very strong and heavy papers. This modification is illustrated by Fig. 18. The publication also contains additional information ‘on calibration and adjustment of this instrument. It is doubtful if a shearing stress type of tester such as this actually gives a test in accordance with service conditions as in the latter case the paper tear is usually a combination of shear- ing stress and eccentrically applied tensile stress. There is need of further investigation in the direction of improving the design of tearing instruments. 11. Wet Rub Determination of the resistance of paper, when moistened, to surface abrasion is important in the case of most surface treated papers such as blueprint, map and ledger. Fig. 19 illustrates an instrument developed at the Bureau of Standards for obtaining a reproducible numerical value for this property. It consists of (1) a means of clamping the specimen over a smooth, hard sur- face; (2) a power driven rubber friction surface or mechanical finger, maintained under constant pressure; (3) a means of keep- ing the paper moistened, while it is being tested; (4) an electrical Fic. 19. Wet-Rub Tester. (Bureau of Standards, Washington, D. C.) WET RUB if: Fic. 20a. Gurley Densometer. (W. & L. E. Gurley, Troy, N. Y.) contact device which automatically stops the tester as soon as a hole is worn through the paper; (5) an automatic counter to record the number of rubs. 12. Air Resistance or Porosity There are three classes of instruments available for this pur- pose: (1) those which compress the air and force it through Fic. 20b. Schopper Densometer. (Foreign Paper Mills, New York, N. Y.)- | 74 | rae POROSITY 75 Fic. 20c. Emanueii Porosimeter. (Philip Torchio, New York, N. Y.) the paper under hydrostatic pressure; (2) those which create a partial vacuum and draw the air through the paper; and (3) those which measure the pressure drop through the instrument caused by the resistance of the paper to permeation of air. In- struments of the first class are somewhat more simple and have been used more extensively than instruments of the second class, even though they are open to the objections that (1) when water is used the air is forced through the paper at a higher humidity than normal, causing swelling of the fibers which reduces the 76 PHYSICAL -FEusTING penetrability of the paper; and (2) the pressure of the air is not uniform throughout the test. The first objection may be overcome by using a light lubricating oil instead of water. In- struments of the third class avoid the objections mentioned and appear to embody the soundest principles in general. A discussion of this subject, together with descriptions of various instruments, is given in Paper 33, No. 17, page 14 (Feb. 14, 1924). Information on the construction and use of the Eman- ueli Porosimeter was published in Paper Trade Journal 85, No. 10, page 48 (Sept. 8, 1927). The three classes are illustrated, respectively, by Figs. 20a, 20b and 20c. 13. Degree of Sizing a. DEGREE OF INTERNAL SIZING Paper is made moderately resistant to water by incorporating in it a water resistant material such as rosin. A very complete discussion of the various methods for measuring the degree of sizing of such papers is contained in the Bureau of Standards Technologic Paper No. 326, Measurement of the Degree of Sizing of Paper, by F. T. Carson. Following are descriptions of the five outstanding methods and the conclusions regarding them, ab- stracted from this publication: Ink Flotation Test: A sizing test somewhat similar to the method of Klemm (per- haps an adaptation of it) has long been used in this country and today enjoys the prestige of custom and precedent. Specimens of paper are Hoated on the surface of ink and kept continuously under observation until transudation of ink is detected on the upper side. The time interval required for the staining through of the ink is considered a measure of the degree of sizing of the paper. Method of Stockigt: A specimen of paper is floated on a 2 per cent solution of ammonium thiocyanate. The upper surface is lightly dabbed with a brush wetted with a 1 per cent solution of ferric chloride until red specks of iron thiocyanate appear all over the surface of the sheet. The experimental datum of the test is the time from the contact of the paper with the ammonium thiocyanate until the ap- pearance of the red specks on the upper surface. A useful modi- fication of this method consists in applying the ferric chloride at frequent intervals with a pen or fine-tipped brush, always in a new place, until the red coloration develops immediately. Method of Okell: An old idea was given a new application when the Kohlrausch method of conductivity measurement was cleverly adapted to the problem of measurement of the degree of sizing of paper. Ac- DEGREE OF SIZING 77 cording to the proposal of Okell, the paper to be tested is inter- posed between the electrodes of a specially constructed electrolytic cell having controlled means of bringing the electrolyte into con- tact with the paper. As the solution of electrolyte penetrates the paper partition from both sides the decreasing resistance (or increasing conductance) is measured by means of a Wheat- stone bridge. By plotting the resistance (or conductance) against time a continuous record is obtained, and, assuming the rate of increase of conductance to be proportional to the rate of increase of permeation, the data are interpreted in terms of degree of sizing. ita oe Vailey Size Tester. (Valley Iron Works, Appleton, Wis.) 78 PHYSICAL..TESTING Method of Boon and Fourness: In order to obviate the use of a sensitive galvanometer or tele- phone receiver, the method of Okell is modified so as to substitute a series circuit containing a milliammeter for the Wheatstone Bridge. A constant temperature is maintained thermostatically. An arbitrary end point is chosen ‘which is four-fifths the normal conductance of the circuit when operated with no paper in the cell. A commercial instrument of this type is illustrated by Fig. 21. Curl Methed: When a small piece of paper is floated on water, it curls up as a result of the wetting and consequent expansion of the under side. In a short time it attains a maximum degree of curling and then begins to uncurl as a result of expansion setting in on the upper side of the sheet as the water penetrates beyond the median plare. The time from the contact of the paper with the water until the instant when the specimen begins to uncurl is con- sidered a measure of the relative degree of sizing within the sheet for papers of the same thickness, tested under the same conditions of temperature and relative humidity. When it is Pigs oz, Curl Sizing Tester. (Bureau of Standards, Washington, D. C.) DEGREE OF SIZING 79 necessary to test papers of different thicknesses the quotient ob- tained by dividing the time by the square of the thickness in each case is an expression of the relative degree of sizing within the sheet. The test is made preferably with an apparatus such as that shown in Fig. 22 devised by F. T. Carson, the originator of the method. The specimen $ is held in a definite position on a float having an.aperture through which the water presents a small restricted surface convex upward. The part of the specimen lying over this aperture is wetted on the under side. The pointed part remains dry and serves as a pointer to magnify the movement due to the curling. This pointer is viewed against a background of small black dots on a white field, which facilitates determining the instant at which it begins to retreat. The whole mechanism is controlled by an operating lever, the initial depression of which brings the specimen in contact with the water and starts a stop watch. A second depression of the lever at the instant the speci- men starts to uncurl arrests the stop watch. The time is rec- orded. On raising the lever to the vertical position the stop watch is set to zero, the transparent hood is thrown back, and the speci- mynen is lifted from the water. When a new specimen is put in position on the float, all is in readiness for another test. Bureau of Standards Dry-Indicator Method: The accidental observation that grains of sugar on the surface of paper give an indication of the presence of transuded moisture by melting down into droplets long before the presence of water can be detected by other simple means has led to the development of a new method at the Bureau of Standards. Sugar, at first used alone, was supplemented to great advantage by adding small amounts of dyes. Powdered sugar and one or more water-soluble dyes are mixed in such proportion (approximately 50 parts of sugar to 1 part of dye) that the mixture shows very little color. The mixture is applied through a sieve to the paper being tested. The specimen is then floated on a vessel of water at a definite temperature and the time determined until the characteristic color of the dye begins to appear in the mixture as a result of wetting by transuded moisture. This time interval is then interpreted in the same manner as in the curl method, either as a measure of the relative degree of sizing of papers of the same thickness or by ac- counting for the effect of thickness in the manner described under the description of the curl method. This method is susceptible of a number of modifications. At first methyl blue was employed as the dye constituent. Later fuchsine, methyl green, and a soluble yellow were used in three separate mixtures for the sake of the color contrast which helps in determining the end point. A procedure which gives excellent results is the following: . SO PHYSICAL TESS iis Three mixtures are prepared of powdered sugar and small amounts of finely divided dyes in the approximate ratio 50:1. The first contains methyl green, the second pontacyl scarlet, and the third national wool yellow. Three other mixtures are made, using pigments insoluble in water instead of the dyes, each of the latter three mixtures being made up to match in color one of the first three. A fluted sieve (Fig. 23a) is.made of wire screen (about 80 mesh) such as that used on a fourdrinier paper machine. The manner of construction is illustrated by b of Fig. 23. Into every other trough one of the sugar-dye mixtures is placed. Each sugar-pigment mixture is thea placed in one of the three remain- ing troughs, so that it is adjacent to the sugar-dye mixture of the same color. A test specimen is cut about 3 inches square and the edges folded over to prevent curling. The sieve is dropped on this specimen from a height of about a quarter of an inch, as a result of which the indicator mixtures are laid down close to one another in parallel lines. On floating the specimen, water penetrates through and is taken up by the sugar and transferred to the par- ticles of dye scattered through it. The colors deepen markedly and rapidly and, in contrast with the reference mixtures, stand out prominently. The end point is when one is certain that the colors have begun to develop. The end point is influenced somewhat by the solubility of the dyes. When not in use, the indicator mix- tures should be kept in a desiccator. It is well to prepare fresh mixtures frequently. In order to get comparative results over a period of time, all tests should be made under the same conditions of temperature and relative humidity. The procedure which, perhaps, best combines simplicity with a sharp end point employs one of the sugar-dye mixtures flanked on either side by its reference mixtures of sugar and an insoluble pigment. In this case only one trough in the sieve is- required. This procedure is illustrated by c of Fig. 23. The factors necessary for securing accurate results with this method are (1) uniform temperature of water and (2) a definitely standardized indicator mixture. Extreme atmospheric conditions Fic. 23. Dry-Indicator Sizing Test Method. (Bureau of Standards.) WATER RESISTANCE 8] should be avoided. It is desirable to make the tests under ac- curately controlled humidity conditions. From results of experimental comparison of these methods it was concluded that: (a) The most probable relative degrees of internal sizing of the various samples are best represented by the data of the Bureau of Standards dry-indicator method. (b) The agreement of the curl method with the dry-ind‘cator method is, with a few exceptions, very good. (c) The Stockigt method gives fairly consistent results but is characterized by an error which increases with iticrease of degree of sizing, the error being due presumably to the influence of selec- tive adsorption. . (d) The data obtained with the electrolytic method are, in general, too erratic and inconsistent to be of much value in ap- praising paper for degree of sizing. In some cases this method agrees satisfactorily with the methods which measure the rate of penetration of water, but the degrce of concordance does not follow any clearly defined principle, and hence the method can not be depended upon for consistent results. (e) The ink flotation test is too erratic and fruitless of useful information to be considered seriously as a test of the degree of internal sizing of well sized papers. b. DEGREE oF SURFACE SIZING The chief significance of degree of surface sizing is in relation to writing inks. ‘The suitability of paper for writing must be determined by observation of ink lines and characters on the sur- face. No method has come into use for expressing this property numerically. Methods which measure the rate of penetration of aqueous solutions into and through paper are not valid for this pur- pose despite the fact that most of them were proposed with the idea of expressing writing quality numerically. An adequate method giving a numerical expression for degree of surface sizing and ap- plicable to various inks is needed in the interest of research in siz- ing and in the preparation of specifications of writing papers if not for practical tests. The literature affords no better treatment of testing paper with ink than Herzberg’s papier-prufung. 14. Water Resistance - a. DEFINITION Water resistance may be considered to be a special case of de- gree of sizing in which the liquid involved in the test is definitely specified and the time of transudation is a sufficient test. However, the terms water resistance and waterproof usually imply a much longer time of transudation than is involved in testing degree of sizing. &2 PHYSICAL TESTING b. BurREAU OF STANDARDS GROUND GLAss MeETHop The application of this method is illustrated in Fig, 24. The chief source of error in testing paper for water resistance has seen the untrustworthiness of the means of detecting transuded moisture. This source of error has been removed by the use ot a ground glass surface in contact with the paper, the ground surface absorbing the transuded moisture and revealing it as a fugitive dark patch when the specimen is lifted. A shallow flat- bottomed vessel, such as the inverted cover of a can, containing sufficient paraffin to be about an eighth of an inch deep when melted is heated until the paraffin begins to “smoke.” The heating is discontinued and the end of a glass cylinder is placed in the paraffin. It is allowed to remain for a few seconds until the melted paraffin is seen to be mounting up the sides of the cylinder. it is then removed, allowed to drain for an instant, and applied to the test specimen which has been laid on a smooth surface, such as a pane of glass. A weight is then placed on the cylinder and allowed to remain until the paraffin has hardened. Such a seal will hold more than a foot of water if necessary. A piece of ground glass, G, (Fig. 24) is laid on a piece of black paper B, or other dark surface, the ground surface of the glass being upper- miost. The specimen, P, sealed to the cylinder, C, is placed on the ground surface. An inch or two of water is poured into the Fic. 24. Ground Glass Water Resistance Test Method. WATER RESISTANCE 83 Pic. 252: External View of Apparatus, Harvey Water Resistance Test Method. (A. R. Harvey, Middletown, Ohio.) cylinder. The capillary pressure in pores as small as those in pa- per is so great as compared with the hydrostatic pressure that the head is immaterial so long as it is small. At intervals the cylinder is lifted and any transuded moisture will show as a dark fugitive patch on the ground surface. While all the tests of this nature are rather sensitive to differences in temperature, the ground glass method is particularly so, not only because of the change in viscos- ity of the liquid, but also because of the effect of temperature on the sensitivity of the ground glass surface. The moisture is re- tained by adsorption and adsorption is increased as the temperature falls. For this reason it seems desirable to keep the ground glass al as low a temperature as is convenient. c. MetuHop or A. R. HARvey This test is applied where it is desired to find the degree to which a board will resist the penetration of moisture. The test was developed primarily to be used in connection with an asphalt filled board and its relation to sizing or waterproof tests has not yet been determined. The method consists in interposing the sample under test between a moist and a dry atmosphere, the amount of moisture passing through the sample being found by weight. The test is influenced by a number of factors, some of which are: Temperature and humidity of moist atmosphere. Temperature and humidity of dry atmosphere. Air circulation in moist atmosphere. Air circulation in dry atmosphere. The apparatus (Figs. 25a and 25b) used consists of a circular revolving tray which carries the samples under test and also a 84 PHYSICAL TIESTING Fig. 25i: Apparatus With Cover Raised. Harvey Water Resistance Test Method. (A: R. Harvey, Middletown, Ohio.) drying agent. The whole is encased in an air-tight chamber sur- rounded by a thermostatically controlled water bath. The tray has a diameter of 21 inches and revolves at a speed of 17.5 r.p.m. Small metallic vanes (see Fig. 25c) are fastened to the top of the chamber to aid in uniform air circulation. Fight samples are evenly spaced around the outer edge of the tray and are prepared as described helow. The sample of board to be tested, having an area of 33 square inches, is sealed around a triangular frame of light tin (see Fig. 25d). The box thus formed contains on its bottom a piece of felt saturated with water. The water is intro- duced through a hole in the tcp after the box has been completely made up in order to avoid wetting the board at any point while BicyZ se; Internal View Showing Test Samples and Vanes for Air Circulation. Harvey Water Resistance Test Method. (A. R. Harvey, Middletown, Ohio.) GREASE RESISTANCE 85 Fics 25d, Construction of Test Samples, Harvey Water Resistance Test Method. (A. R. Harvey, Middletown, Ohio.) sealing. The temperature in the desiccator is brought to 77 degrees F., and the samples are placed on the tray and allowed to season for l¢hour before making the first weighing. After running for a period of 2% to 5 hours the samples are again weighed and the loss of water determined by difference. 15. Grease Resistance The principal difficulty in the technique of testing greaseproofed paper has been the lack of a satisfactory means of applying the oil or other organic liquids to the paper. Such liquids, owing to their low surface tension, quickly spread out into a thin film, often running over the edges of the specimen and leaving insufficient liquid in place to give an adequate test. Similarly, if the speci- men is floated the liquid runs over the edges and covers the upper surface in a short time. Even when the specimen is formed into a receptacle having high walls the organic liquid rapidly creeps up the sides, over the top and down inside. Altogether such a test is vexatious and unsatisfactory. The difficulties have been overcome and the test greatly facili- tated in a method developed by Carson at the Bureau of Stand- ards. The technique is similar to that of testing water resistance by the ground glass method. ‘The test specimen is sealed to the end of a glass cylinder with a substance which is not readily wetted by organic liquids. A very thick, viscous sirup is most satisfactory for the purpose. Glue will serve as well when the sirup is not at hand. The specimen is sealed to the cylinder in much the same manner as that described above in connection with the test for water resistance. The end of the cylinder is touched to the surface of the sirup and then applied to the test specimen. A seal made in this manner will withstand organic liquids in- definitely. The actual test may be carried out in several ways. An oil- soluble dye may be dissolved in turpentine or oil which is then poured into the cylinder, the specimen being placed on a piece of white paper and lifted periodically to observe any spots, in the 86 PHYSIGALZTESTING manner recommended by Smith.’ In this case it is an advantage to cut a strip a few inches long from the sample to be tested. The cylinder is sealed to one end of the strip. with sirup (or glue) and a weight is placed on the other end. By this means the specimen is always replaced in exactly the same position after being lifted to observe the white paper underneath. In testing with turpentine or other volatile organic liquids it is preferable instead of using white paper underneath the specimen to use a ground glass surface as in the test for water resistance. A better method is to reverse the process and set the specimen which has been sealed to the cylinder, in a shallow glass vessel containing the organic liquid, in order that the specimen may be viewed from above. This method is illustrated in Fig. 26. A piece of heavy cardboard, B, having a hole, H, in the middle is supported on a ring-stand. ‘The crystallizing dish, D, containing the organic liquid is placed over the hole. The test specimen, P, sealed to the cylinder, C, is placed in the organic liquid in the crystallizing dish. A rotating mirror, M, pivoted at O, is mounted directly underneath the hole, H. The test is carried out near a window or a good artificial light giving satisfactory illumination of both the mirror and the upper surface of the specimen. The or- ganic liquid penetrating through the sheet becomes visible alter- nately as light and dark spots as the mirror is oscillated. The ex- perimental datum is the time interval until transudation is noted. 4“The Turpentine Penetration Test for Greaseproof Papers.’’—Technical Association Papers, Series VII, No. 1 (June, 1924). J eee VILL nc ae My enn LLL IL IL LLL EL DED LED IEE OF A Fic. 26. Apparatus for Grease Resistance Test. (Bureau of Standards.) Fic. 27. The Penescope. An Apparatus for Testing Resistance to Liquids. (Thwing Instrument Co., Philadelphia, Pa.) 87 ; ByG; 26a, Absorption Test, Klemm Method. An Apparatus Devised by the Bureau of Standards for Simultaneous Tests of Several Specimens. THE PENESCOPE 89 16. The Penescope An instrument, devised by Allen Abrams for applying penetration tests, such as those described above for degree of sizing, water resistance and grease resistance, is shown in Fig, 27. It has the advantage of permitting continuous observation of the effect of the test liquid on the paper specimen. The apparatus consists of a cast brass chamber. which is to be filled with the testing liquid and the outer rim of which has a plane, machined surface; the hollow screw cap in which the test specimen is inserted, with a plane, machined surface inside; and the open- ings above and below, threaded for % inch pipe connections by means of which the testing liquid is introduced, removed, and maintained at a desired level, 17. Absorption a. STRIP° | The absorption of a blotting paper is indicated by the height in millimeters to which, in a given time, a liquid will rise by capillary action, when one end of a strip of paper held vertically is immersed in water. The height in millimeters to which the liquid (preferably water) will rise in 10 minutes is taken as a measure of the relative absorption of the paper. In making this test, using the “strip” method (Fig. 28a), a strip of blotting paper 15 mm. (about 3/5 inch) wide and 150 mm. (about 6 inches) long is suspended so that the lower end dips 3 mm. (about % inch) into a pan of distilled water. Beside the strip is a scale reading in millimeters (fractions of an inch), and at the end of each minute, for 10 minutes, readings are taken of the height to which the liquid rises in the strip. Five tests are made in both the “machine” and “cross” direction and an average ob- tained. The result is reported as the height to which the liquid will rise in 10 minutes. When necessary or advisable the same strips may be subjected repeatedly to the test, which will indicate the decreasing ability to absorb water or ink. A standard ink of the ~ tollowing formula may be used: FORMULA FOR UNITED STATES GOVERNMENT STANDARD WRITING INK Grams Thana gyes cayeyel Se Mey Tt ec ra A rn SO Al Mere eee A aera ee Uae 23.4 (CSE, Grecia? a, Se es sae i ea a = a ee om ere ies MED aoe nee ee Iara eed caeae © TF HEGEGaTS AS DAC CCT YStAlS "le wee scapes o-sick meet Meche Scie ve Welles lajle ech apens aie cot 30.0 Dilaiestyarochloric. acid (10 per cent solution) 25.2. see i.e ne 25.0 Fiano) ME RPM AD NAG orb aaa One Gh Te ee om da ine aa ERICA Tal Rs ecempnicr aC cores 1 Blue dye (Soluble Blue ‘‘A’”’) color index No. 707 or Schultz No. 539 3.5 Water to make a volume of 1,000 cc. at 20 degrees C. All chemicals used should be of C. P. or U. S. P. quality. Particular attention should be given to the blue dye as many of these dyes react with phenol and cause a metallic-appearing film 5 Handbuch der Papierkunde Trea of Paper Technology), by Paul Klemm, pages 248-327. 90 PHY¥SICAL ‘TESTING on the surface of the ink. Samples of dyes submitted should be tested, and only those dyes which do not react with phenol should be used for making this ink. Only distilled water should be used This ink should be made in the following manner: Dissolve the ferrous sulphate in cold water and add the hydrochloric acid. To this add the tannic and gallic acids, previously dissolved in warm water. Then add the dye dissolved in warm water and also the phenol. Dilute the mixture with water to make a volume of 1,000 cc. at 20 degrees C. b. Pipette ° In this test a 1 cc. pipette is used and is suspended in such a way that the end of the pipette is % inch from the surface of the test sample of blotter. The test sample cui’ 4 inches square is laid felt side up upon a coarse wire screen which is supported by a large beaker. This is done to prevent as far as possible the blotting paper from caving in at the center where the liquid fell upon it. (The felt side of paper is the top side of the paper as it leaves the paper machine wire.) Both distilled water and the afore- mentioned government standard ink are used at the three tempera- tures of 60, 70 and 80 degrees F. A stop watch is used to measure the time it took the 1 cc. of liquid to leave the pipette until it is totally absorbed by the paper. Also the diameter of the circular spot on the paper is measured immediately at the completion of the time reading. c. ToTaL AxpsorPTIon | By means of this test, test samples cut 2 inches square are first weighed on a chemical balance and then dropped with the felt side down on a trough of- distilled water and also on trough of gov- ernment standard ink. The same temperatures are used for the ink and water as in previous absorbency tests. After a 10 minute period of absorption the samples are taken out, drained % minute and again weighed to determine the amount of liquid absorbed. d. Brotrinc Test’ In this test small strips of blotting paper cut % inch wide by 4 inches long are used to blot signatures that are written with a stub pen on ordinary bond paper. The same signature is used throughout the test and only one signature is blotted at a time. The small size of the test sample causes each blot to be made on almost the identical spot in the blotting paper. Government stand- ard ink is used as in previous tests and a record is kept of the number of times each test sample will blot the signature before the ink shows signs of spreading on the paper. The felt side of both blotting and bond paper is used throughout the tests, and an 6 “Absorbency of Paper.’”—E. QO. Reed. Paper) 2a. 19, page 14 (Jan. 16, 1918); Journal of Indus. & Eng. Chem., Vol. 10, 44 (Jan., 1918). 7“Testing of Blotting Paper.’-—P. L. Houston and R. H. Ledig. Paper Trade Journal 73, No. 19, page 88 (Nov. 10, 1921). ABSORPTION 91 average of three tests is taken as a final result for each blotting paper. Another method for testing the quality of blotting papers has been devised by Dalen. An instrument made by Schopper to apply this method is illustrated in Fig. 28b. A definite quantity of ink, generally one drop, is allowed to fall from a burette on to a strip of well sized writing paper. A strip of blotting paper of the same width is brought into contact with the strip of writing paper under strictly regulated conditions and the two strips are passed together through small rollers driven by a motor. The result is the formation of a long or short smudge forming a tail to the drop of ink. The length of the smudge depends entirely upon the quality of the blotting paper. With papers of poor quality the smudge is naturally a long one while with papers of good quality Fic. 28b. Dalen Blotting Paper Tester. (Foreign Paper Mills, New York, N. Y.) 92 PHYSICAL TESTING Fic. 29. Opacity Tester. (Bureau of Standards.) the absorption is so rapid that there is not sufficient ink left to form an appreciable smudge. 18. Opacity Following is the tentative official Association method for de- termining the opacity of paper. The Bureau of Standards opacity apparatus designed to apply this method is illustrated by Fig. 29. I. Apparatus: The essential principle of the contrast method of determining the opacity of the paper, herein specified, is as follows. When trans- lucent paper is placed over a white surface, the luminosity ob- served is composed of the light reflected from the surface of the paper plus that which is reflected from the white surface under- neath. When paper is placed on a perfectly black surface the luminosity is that of the light reflected from the surface of the paper only, as the transmitted light has been absorbed. The ratio between these two luminosities, termed contrast ratio, represents therefore the opacity of the paper, this being unity for perfectly opaque paper and zero for perfectly transparent paper. The ap- paratus shall consist of a light chamber, a photometer, a standard white surface, a standard black surface, and a test specimen holder. A particular design of light chamber or box is not es- sential. It is essential that the light box be so designed that the OPACITY 93 surface of the sample to be tested shall be illuminated by diffused light from all directions above, and that the illumination over the black hole and white standard surface be equal. The apparatus must be so designed that only the light reflected from the surfaces of the paper covering the black and white standards can enter the photometer. The white standard surface must not touch the surface of the test specimen but must be so near it that a further decrease in distance will not affect the test results. (In the instrument mentioned below less than 2 mm. was found suitable). The white standard shall consist of a block of chemically pure magnesium carbonate of high reflecting power. The surface used shall be smooth and plane, and shall be covered with a thin (1 mm. or less thick), clear (free from color) glass disk. The black standard shall consist of a box or cavity of such depth and lined with such material that all light entering the cavity will be ab- sorbed. The box may be lined with black plush, or smoked with acetylene or other soot. A specified make or design of photo- meter is not essential. Both halves of the photometric field shall be perfectly uniform in brightness over their entire surfaces, and, when matched, the dividing line shall disappear along its entire length simultaneously. The specimen holder shall be so con- structed that the sample is held perfectly flat; otherwise the photo- metric field will not be uniform and the precision of setting will be poor. A suitable type of apparatus is described in the Bureau of Standards publication mentioned. (See VJ.) IT, Calibration: The requirement that the black and white areas must receive equal illumination is tested as follows: Both areas are covered with a uniform opaque, mat, white pa- per. The photometer is turned so that one half of the field is illuminated by light from the part of the paper over the black standard, while the other half is illuminated by the light from the part over the white standard. The two halves of the photometric field are then matched. The whole photometer is then rotated about its optic axis through 180 degrees. If the two halves of the field are still matched, the condition of equal illumination is satisfied. Specimens for test shall consist of not. less than three pieces of paper so selected as to be representative of a test sample secured by the official sampling method, and shall be of sufficient size to fit the sample holder and completely cover the standard test surfaces. They shall be kept perfectly clean and free from folds and wrinkles; and the areas to be tested should not Se touched with the fingers. IV. Method: Not less than three representative test specimens shall be tested in the following manner; one of the test specimens shall be placed 94 PHYSICAL TESTING in the specimen holder which shall then be placed in posi- tion in the apparatus so that the test specimen covers the black and the white standard test areas. The observer shall then match for brightness the two halves of the photometric field, using the scale interval between 0 and 45 degrees. A second or check observation shall then be made, and the two observations recorded. The whole photometer shall now be rotated through 180 degrees, and two more observations shall be made as before, using the scale interval between 45 and 90 degrees. After these four ob- servations have been made and recorded, the test specimen shall be removed and a second specimen shall be placed in position, and four more observations made and recorded as before. The second specimen shall then be removed and a third substituted and tested as before. The twelve readings shall be recorded and computed as in the following example. The readings for the three speci- mens are in consecutive numerical order, Nos. 1 to 4, inclusive, be- ing for one specimen, Nos. 5 to 8 for another, and 9 to 12 for the third, Ai Aa 1 34.6° 3 554°. 2 34.8 4 oe, 5 34.5 7 55.4 6 34.6 8 55.0 9 34.4 11 55.6 10 34.5 2 55.4 Means 34°—34’ 55°—25’ tan Ai = .6890, cot Ae = .6894 Contrast ratio = tan Ai & cot As = 475 V. Report: The results shall be reported in terms of “contrast ratio” to the third decimal place. VI. Additional Information: A Measurement of the Translucency of Paper, U. S. Dept. of Agricul- ture, Bureau of Chemistry Circular No. 96; Paper 7, No. 7, 22 (May 1, 1912). Specification of the Transparency of Paper and Tracing Cloth, Bureau of Standards Circular No. 63. [Copies of these publications may be obtained from the Superintendent of Documents, Government Printing Office, Wash- ington, D. C., at 5 cents (cash) per copy.] 19. Gloss Determination of the gloss of paper is one means of measuring its degree of finish. The Ingersoll Glarimeter (Fig. 30), which ap- pears to be the most suitable instrument available at present for measuring gloss, does not take into account the surface texture of paper which is a factor as regards printing. A means of meas- uring the surface texture is given in the following section. For complete measurement of finish of paper it is recommended that both gloss and surface texture measurement be made. The ten- tative official Association method for measuring gloss follows: GEOSS 95 Fic. 30. Ingersoll Glarimeter. (Central Scientific Co., Chicago, IIl.) I. Apparatus: The testing instrument shall consist of (1) a photometer so fixed in relation to the test specimen that the amount of polarized light reflected from the test specimen relative to the total amount re- flected from the test specimen at an angle of 5714 degrees may be measured; (2) a source of diffused illumination consisting of a frosted B lamp, G 18% bulb, 110 volts, 25 watts, so fixed in rela- tion to the test specimen that the light subtends an angle of 114% degrees and falls on the test specimen at an angle of 57% degrees; (3) an opal glass diffusing screen between the source of light and the specimen aperture; (4) a metal box having the photometer housed in one end, the source of illumination housed in the other end, and an aperture in one side over which the specimen 1s clamped in a fixed position, so made as to exclude all outside light and having its interior blackened. IT. Specimens: The specimens for test shall consist of not less than five pieces of paper cut from different portions of the test sample, secured by the official sampling method so as to be representative of it. These shall be of sufficient size to extend beyond all sides of the aperture of the metal box. The test specimens shall be clean, free from wrinkles and folds, shall not be exposed for any con- siderable length of time to extreme atmospheric conditions, and the parts of them actually tested shall not have been touched with the fingers. 96 PHYSICAL PEs Lips III. Method: The test specimen shall be firmly clamped in position so that-its sides extend beyond all sides of the aperture of the metal box. If the paper is translucent, a sufficient number of test specimens shall be stacked one upon another so that no incident light can penetrate entirely through them. Two tests shall be made on each side of not less than five specimens, one test in the machine direc- tion of the paper and one in the cross direction. The test results shall be recorded in degrees to the nearest 1/5 degree. The aver- age degrees of gloss shall be computed and converted to per cent gloss by formula: Per cent gloss = cos 2 (60 degrees — degrees gloss) x 100 Duplicate determinations shall agree within 0.5 per cent gloss. IV. Report: The results shall be reported in per cent gloss to the nearest one- tenth per cent. The average, maximum and minimum gloss shall be reported. Where required in order to show the difference in finish between the two sides of the paper the gloss of each side shall be reported separately. V. References: “The Glarimeter—An Instrument for Measuring the Gloss of Paper,’ by R. L. Ingersoll. Journal Optical Society of America, May, 1921. ‘“‘An Improved Form of Glarimeter,” by R. L. Ingersoll. Paper 27, No. 23, 18 (Feb. 9, 1921). ““A Means to Measure the Glaze of Paper,’’ by R. L. Ingersoll. Electrical World 63, 645 (Mar. 21, 1914); Pulp and Paper Magazine of Canada 12, 233 (Apr. 15, 1924). “Determination of Glare,’ by R. L. Ingersoll. Electrical World 64, 35. ““An Improved Form of Pickering Polarimeter for Gloss Measurements (by the Polarization Method).’”? A paper presented before the Fifth Meeting (Dec. 27-29, 1920) of the Optical Society of America (at the University of Chicago), by R. L. Ingersoll. “The Ingersoll Glarimeter.’’ Bulletin No. 100, Central Scientific Company, Chicago, Il. For a description of the Pickering Polarimeter, see Proceedings American Academy Arts and Sciences, 9, 1 (1873); also 21, 294 (1885). “The. Glarimeter and the Measurement of the Finish of Paper,’ by R. E. Lofton. Paper Trade Journal 80, No. 7, 47-49 (Feb. 12, 1925). 20. Surface Texture A. G. Rendall has described a way of measuring the surface texture of paper by means of the “slip” method. One piece of the paper under test is fastened on the face of a block of wood and another piece on the surface of an inclinable plane. The latter is raised until the block starts to slip when the angle of inclination is measured. Care must be taken not to touch the test surfaces with the fingers. 21. Volumetric Composition’ The determination of the volume composition of a paper is at best only an approximation but it is at times desirable to carry it out. The weight of a cubic centimeter of the paper is first ascer- tained by calculation from the thickness of the sample and the 8 Chemistry of Pulp and Paper Making, by Edwin Sutermeister, Chapter 15, pages 386-428, CONDUCTING PARTICLES 97 weight of a measured area. The percentage by weight of the vari- ous materials present, fibers, clay, size, etc., is then determined in the usual way and from this the weight of each cubic centimeter of the paper is calculated. The weight of each substance in grams divided by its specific gravity gives the volume occupied by it, and the sum of all of these volumes subtracted from 1.0 gives the volume of air per cubic centimeter of paper. This method is fairly accurate when only fibers, clay and rosin are present but when other substances are added as in coated papers, the problem becomes more complex and the results less reliable. If the volume of air per cubic centimeter of paper is the only information needed it may be obtained by determining the actual specific gravity by weighing in air and then 1n oil of known density exactly as in making specific gravity determinations in water. It will be found hecessary to expose the paper, submerged in oil, to reduced pressure for some time in order to be sure that all air is removed and replaced by oil. 22. Conducting Particles To show the presence of conducting particles in paper 0.5 or 0.75 mils thick, the sample is placed upon a metal plate which has been polished to a smooth plane surface. This plate is connected in series with three dry cells, a model 280 Weston voltmeter of 3-volt range or a similar instrument, and a metal piece which has a perfectly flat undersurface and will be in contact with all parts of the plate upon which it rests. This metal piece is about 1 inch long and ¥% inch wide and is attached to a handle for convenience in using. It is called the detector. To test paper, place a measured area upon the plate, make contact with the metal detector and the plate and if there is deflection of the voltmeter the instrument is ready to use. Pass the detector slowly over the paper on the plate using light pressure. When a deflection of the voltmeter in- dicates that there is a conducting particle in the sheet between the detector and the plate, the position of the detector is marked on the paper and it is then moved over the spot at right angles to its former position and the paper marked when deflection again oc- curs. This locates the particles within a half-inch square and makes them available for microscopic study. Results are ex- pressed in terms of number of conducting particles present per square foot of paper. With the thicker papers the particles cannot be registered with dependable accuracy because they seldom extend through the full thickness of the sheet. Comparison of iron par- ticles present as shown by chemical tests gives numbers far in ex- cess of the number of iron particles that are actual conductors in the sense of spoiling the paper for electrical purposes. This instru- ment is intended for use in testing papers specified for use in electrical equipment. 98 PHYSICAL SPiN A modification of the apparatus described 1s shown in Fig 3]. Here the metal base and the detector are connected in series with two dry cells and a radio head set. The presence of a conducting particle is indicated by a click in the telephone receivers. 23. Extractor and Friction Cleanser An apparatus has been developed by F. T. Carson for removing the film of carbon and binding materials from carbon paper in or- der that the tissue base may be tested. It is so constructed that vapors from a boiling solvent are condensed and fall on the paper on a rotating drum against which a felt friction pad bears. The combination of solution by the hot solvent and friction of the felt pad removes the carbon film rapidly and completely. The appara- tus may be used for various other processed papers such as paraf- fined and asphalted papers. It is illustrated by Fig. 32. 24. Retention of Filler By retention of filler is meant the proportion of the total amount of filler added to the beater that is retained in the paper. Where it is desired to make a mill test of retention the following formula suggested by E, Sutermeister is recommended: 0.94B (100 —C—A) Per cént retention = —— eee A(100—C=B3 PyG. 31. Apparatus for Detecting Conducting Particles. (Bureau of Standards.) RETENTION.OF FILLER __ 99 Bre 32. Extractor and Friction Cleanser. (Bureau of Standards.) in which A = Per cent of ash in bone dry stock going to the paper machine from the beaters. B = Per cent of ash in bone dry paper at machine reel. C = Per cent of bone dry filler lost on ignition. The figure 0.94 is the average amount of material other than filler retained on the paper machine. In twenty paper machine runs made at the Bureau of Standards, using 20 per cent of filler, the average loss agreed exactly with this figure. This figure may vary in different mills and it is advisable in each mill to find if it 1s applicable to the particular conditions obtaining in that mill. Where it is desired to estimate the amount of filler to be used from an analysis of paper, the calculation is more involved. The following formulas were devised for this purpose. The percent- ages are used in the formulas as whole numbers to the first deci- Mia piace, te, 11 the per cent of ash in the paper is 10.2,: this figure is substituted for A in the formula. Secure about a 5 pound sample of the filler to be used, being Careiul to select a representative sample.. Break up all lumps, spread on a flat surface, divide into four parts, by dividing the pile by two lines at right angles to each other crossing at the center of the pile. Select two opposite quarters, mix and proceed as before. This is known as the “quartering method of sampling.” This quartering method is continued until about 25 grams of load- ing material are obtained, which are then placed in a bottle for further use. From this bottle remove a 1 gram sample, dry at 105 degrees C. to constant weight and calculate per cent of moisture in the loading material. Place the dried residue in a crucible and heat at the full heat: of meker burner until a constant weight is 100 PHYSIGAL “FESTING secured, then calculate the per cent of water of composition in the dry clay. (Have clay in a finely divided state and stir frequently during burning). Secure sample of pulps to be used and determine per cent of moisture and per cent of ash. Weigh the pulp added to the beater. -Weigh the clay added to the beater. After running the paper over the paper machine, secure several pieces as a representative sample; dry and make the ash determination on the paper. The aforemen- tioned data used in the following formula will give the per cent of clay used and the per cent retention. Let P = Weight of pulp added (in pounds). C = Weight of clay added (in pounds). A = Per cent ash in the finished paper. Ap = Per cent ash in the pulp. Wc = Per cent water of composition in the ciay. Mp = Per cent moisture in the pulp. Mc = Per cent moisture in the clay. 100° X= (1) Per cent of clay used = -————— P 106: AS > ase (2) Per cent retention = ———__—_ C (100—A) 100 C (1—Mc) (3) Per cent of clay used = ———————— P (1—Mp) 100 PX (A—K) C (100—A—K) (4) Per cent retention = The value of K is the per cent of filler not derived from the loading added. An average value of K is 0:50 so that the formula (4) may be used as foregoing or as follows: (5) Per cent retention So, ee ee C (100—A—0.5) Formulas (3) and (5) are recommended for use by the Tech- nical Association of the Pulp and Paper Industry, although (1) and (2) may be used when accuracy is not essential or when the values for moisture content are unknown. Formula (4) does not take into consideration the per cent water of composition in the loading. Where this is known suitable correction may be made. No account is taken of the ash from alum or rosin size as the maximum amount from these factors is probably under 0.05 per cent and therefore negligible. An ash determination need not be calculated beyond the first decimal place. (See ash determination under chemical testing.) The following formula has been suggested by José de la Ma- corra, Jr., for use where “broke” paper is a part of the beater furnish: 10,000: XO" & (100—p) [P(100—Hc) + me Mc + 0.5A] Percentage retention = Hige 30: (Foreign Paper Schopper Expansion Tester. Mills, New Vork pio. Jat Gea 922, Moisture on Paper, Effect of, Paper Maker’s Monthly Journal, Vol. 57. Deol AGS, Lo, 219108 Moisture on Paper Tests, Iufluence of. Paper, Vol. 29, No. 4, p. 16. Dees, 1921. Moisture Regain of Papers at Different Humidities, by Otto Kress and G. C. McNaughton. Paper, Vol. 22, folio p. 665, Aug. 21, 1918. Opacity, Factors in Obtaining. Paper TraprE JouRNAL, Vol. 50, No. 6, Paper Microscopy, by J. H. Graff. Paper, Vol. 23, folio p. 642, Feb. 12, 1919, Paper Sizing, by Fritz Stockigt. Wochenblatt fur Papier-fabrikation, Vol, 1, p. 39: (1920); Paper, Vol: 26; folio p. i) Mare 10) 1920; Paper Testers, by D. C. Douty. Paper TrapE Journat, Vol. 50, No. 6, p. 259, Feb. 10, 1910. Paper Testing. World’s Paper Trade Review, Vol. 74, p. 26, Dec. 24, 1920 Paper Testing, by F. A. Curtis, Circular No. 107, Bureau of Standards. Paper Testing, Report of Committee of TAPPI, by F. C. Clark. Paper, Vol; 21, No. 6, p., 11, Oct..17,. 1917; Paper, Volo 21, Noss. ap eae Oct;- 24;-1917- Paper Testing, TAPPI Report on, by F. C. Clark. Paper, Vol. 25, folio p. 693, Dec. 10, 1919; Dec. 17, 1919; Dec: 24, 1919; Deco 3121919; Jansen, L920: Paper Testing, The Technique of, by H. A. Bromley. Pulp & Paper Mag. of Can., Vol. 13, No. 16, p. 439, Aug. 15, 1915. Phloroglucinol, Notes on the Chemistry of. Paper, Vol. 22, folio p. 641. Aug. 14, 1918. Photomicrographic Study of Paper, by E. A. Hunger. Paper, Vol. 20, Nov: 19) pals July 1818175 Porosity of papers, Determining the. Paper, Vol. 22, folio p. 91, Apr. 10, 1918. Porosity of Paper, Method of Testing Relative, by F. J. Seiter. Paper, Viol. 21, No. 2; p. 17,. Sept... 19, 1917. Pulps in Paper, Method for Differentiating and Estimating Unbleached Sulphite and Sulphate, by R. E. Lofton and M. F. Merritt. Tech, Papers, 189, Bureau of Standards. Qualities and Tests of Paper. La Papeterie, Aug. 10, 1919; Paper, Vol. 25, folio p. 1112 Feb. 11, 1920. Qualities and Tests of Paper. La Papeterie, Vol. 41, p. 98, June 25, ee ee 41, p. 226, Aug. 10, 1919: Paper, Volesza.peie 4 (1920). Quality of Paper, Methods of Estimating the, by F. C. Clark. Paper, Vol.c10,GNG27, palloe vane 9G. Lolo. Rosin in Paper, Quantitative Determination of, by C. F. Sammet. Jour. Ind. & Engr. Chem., Vol. 5, p. 732, Sept., 1913; Paper, Vol. 13, No. Lp SAs Septeehier wise Rosin Sizing, An Investigation of, by F. C. Clark and A. G. Durgin. Paper. Vol. 21, No: (235 p. 136,. Pebo 136, iss Size-Fastness, A New Test for, by Stanley A Okell. Paper, Vol. 20, No. 53 pe 20: April 31917. Size-Fastness, Okell’s Method for, by S. A. Okell. Paper, Vol. 22, folio p. 469, July 3, 1918. 107. 108. 109. Se 138. 140. BIBLIOGRAPHY 123 Size-Fastness of Paper, New Method for Determining the, by Fritz Stockigt. Wochenblatt fur Papier-fobrikation (1920); Paper, Vol. 26, p. 1 (1920). Sizing, A New Test for, by C. J. West. Paper TrapE JourNnaL, June 24, 1920. Sizing with Iodine, Testing for.. Jour. of Ind. & Engr. Chem. Vol. 11. PeeoeZ (1919). Sizing in High Grade Papers, Detection of Faulty, by C. F. Sammet. Circular No. 107, Bur. of Chemistry, Dept. of Agr.; Paper, Val LO SENG. O pred: Feb. 125 OTS. Sizing ‘of Paper, Research Work on the aby. beiGs-Clarksand Aq G- Durein; “Paper, Vol. 22, folio p. 223, May 15, 1918. Sizing Quality, The Determination of, by F. T. Carson. Paper TRADE JourRNAL, Vol. 74, No. 14, Apr. 6, 1922. Soda and Sulphite, Pulps, Differentiation of, by P. Klemm. Wochschr., Papier-fabrikant, Vol. 48, p. 2159. Soda and Sulphite Wood Pulps in Paper, Detection of, by R. Wasicky. AE alle Vol. 16, p. 212 (1918); Jour. Soc. Chem. Ind., Olaaoo Spots in Paper, Soot or Carbon. Paper, Vol. 17, No. 15, p. 15, Dec. 22, 1915. Staining of Wood Fibers for Permanent Microscopic Mounts, by H. N. Lee. Pulp & Paper Mag. of Can., Feb. 1, 1917. Starches—Properties Useful to Mills, by G. M. MacNider. Paper, Vol. SO mNOG ep el Om late 4-6 L917. Starch in Presence of Cellulose, Determination of, by F. Kaulfersch. Chimie et Industrie, May, 1921. Starch in Paper, Estimation of, by O. Kamm and F. H. Tendick. Paper, Vol. 25, folio p. 460, Nov. 5, 1919. Starch in Paper, Quantitative Estimation of, by V. Voorhees and O. Kamm. Paper, Vol. 24, folio p. 1091, Aug. 27, 1919. Staining of Wood Fibers for Permanent Microscopic Mounts, by H. N. Lee. Batanical Gazette, Vol. 62, No. 4, p. 318, Oct., 1916. Strength of Paper When Wet, Determining the, by E. O. Reed. Journal Ind. & Engr. Chem., Vol. 8, p. 1003, Nov., 1916; Paper, Vol. 19, No. 11, p. 15, Nov. 22, 1916. Strength Tests for Paper, Description of a Paper Tearing Resistance Tester, by H. N. Case. Jour. of Ind. & Engr. Chem., Vol. 11, No. 1, p. 49, Jan., 1919; Paper, Vol. 23, folio p. 509, Jan. 15, 1919. Sulphite and Soda Pulp in Paper, Test for. Paper, Vol. 24, folio p. Clyeewiay 7.1919. Sulphite and Sulphate Cellulose in Paper, Testing Methods for, by G. Schwalbe. Pulp & Paper Mag. of Can., Vol. 12, No. 1, pp. Ee 21, tan. 1, 1944: Sulphite Pulps. The Differentiation of, by T. B. Seibert-and J. E. Minor. Paper, Vol. 25, folio p. 1005, Jan. 28, 1920. Sulphur in Paper, Determination of, by E. Sutermeister. Pulp & Paper Mag of=Can.- Vol. 15,-No. 44, p, 1021, Noy. 1, 1917. = Tearing Resistance of Paper, Testing, by C. F. Sammet. Paper, Vol. 20,2 holies p. 1053, Keb. 4, 1920. Tearing Resistance of Paper, by S. D. Wells. Paper, Vol. 23, folio pas v0, eb. 12,-.1919. Tearing Resistance Tester, A Paper, by H. N. Case. Jour. of Ind. & Engr. Chem., Vol. 11, p. 49 (1919). Tearing Strength of Paper, Supplementary Study of Commercial In- struments for Determining, by P. L. Houston. Paper Trape JournaL, Vol. 74, No. 10, p. 43, Mar. 9, 1922. Tearing Strength of Paper. World’s Paper trade Review, Vol. 75, p. 6 Tearing Strength of Paper, Device for Testing the (U. S. Pat. No. 1,273,972), by R. O. Wood, to A. D. Little, Inc. Jour. Soc. Chem. ind., Vol. 37, No. 21 (1918). Tearing Strength Test for Paper, by A. Elmendorf. Paper, Vol. 26, folio: p. 002, Apr. 21. 1920. Tensile Strength Tester (T. ah ie & Co.). World’s Paber Trade Review, Vol. 75, No. 5, p. 468. Tearing Test, Preliminary Study of Tearing and Tearing Test Methods for Paper Testing, by P. L. Houston. Tech. Papers, No. 194. Bureau of Standards. Testing of Paper and Paper Products for Specific Use, by J. D. Mal- colmson, The Paper Industry, Vol. 1, No. 2, p. 104, May, 1919. Testing Physical Properties, by S. W. Widney. The Paper Industry, Voli1,2 Now 75. pe .514,5 Octar 1919: Translucent Effect on Paper. Photometric Experiments of the. Jour. Ind. & Engr. Chem., Vol. 9, p. 184, Aug., 1917. Translucency and Opacity of Paper, Measuring the, by R. Fournier. Papier, Vol. 23, p. 259, Nov., 1920. BIBLIOGRAPHY Translucency of Papers, A Measurement of the, by C. F. Sammet, Circ. No. 96, Bur. Chem., Dept. of Agri.; Paper, Vol. 7, No. 7, p.. 22, May 1, 1912. Transparency of Paper and Tracing Cloth, Specifications of the. Circu- lar No. 63, Bureau of Standards. Vegetable Fibers Used in Paper Making, by F. C. Clark. Paper, Vol. 23, folio p. 944, Feb. 26, 1919. Volumetric Estimation of Paper, by E. H. Hiarne, Papier-fabrikant, Vol. 13, No. 45, p. 709, Nov. 5, 1915; Paper, Vol. 17, No. 20, p. 14, Jan. 26;).1916. Water Resistance of Fabrics, by F. P. Veitch and T. D. Jarrell. Jour. Ind. & Engr. Cnem., Vol. 12, p. 26 (1920). Webb Paper Tester, by J. D. Malcolmson. Paper, Vol. 23, folio p. 976, Mar. 5, 1919; Jour. Ind. & Engr. Chem., Vol. 11, p. 133 (1919). Weight of Paper, Determination of the Apparent and Actual Unit. Papier-fabrikant, Vol. 17, p. 472 (1919). Witham Paper Tester. Paper, Vol. 24, folio p. 156, Apr. 9, 1919. Wool, Test for, by H. LeB. Gray, Jour. Ind. & Engr. Chem., Vol. 10; -p. 633" C1918): Yellowing of Paper. Paper, Vol. 22, folio p. 1, Mar. 13, 1918. Yellowing of Paper, by A. B. Hitchens. Paper, Vol. 22, folio p. 553, July 24, 1918. Zinc-Chloride-Iodine Reagent and Its Uses, by F. C. Clark. Paper, Vol. 7, No. 5, p. 23, Apr. 17, 1912. A Page PUSOTIION woo eo ee is ats 89- 90 Wir Tesistanice: oceans ss rps PREIS OSDOES fain css oS 36 Ammonium molybdate POPC CE adn RS 5 112 Aniline sulphate ....... 24 CW ale SP 2 Aga ge 41 COS (POSS a 106 Ashcroft tester ....:... by B OE FE SI a 44 Basis weight scale ..... 48 AN DAG a 25- 26 Beating, degree of .. Abs PeOntine -testo.o, cies. . 90 On ee 78 ite te Stain (cae... 20 MON Ei 56 PUtOtr SPCCKS uuu s 36 c aay tester <0. e050 6: 51 Cady micrometer ..... 55 er POMG ACI ok eee 117 We ee a eke ca 110 Chrome yellow ........ 117 Classification of fibers 25 Pra particles: ....is... 36 LO ee a 108-109 Mle ee a ae 104 ale ISPOtS en oes re 36 Coloring matter ....... 116 SOeTIOTIOE pe 43 Conducting particles . 97 WE COCO as ck oh. 42 (res Cirection....->.... 44 Gererpetnod 4... a... 78 D Dalen blotting paper OS ee ae 91 Pyensomicter 2.23... .. 73 Prt paper ......... 35 Pot retOl va a 21 PIPAVGBDOLS docs so 5 oc a's ae Dry indicator method .. 79- 80 E Elmendorf tester ...... 72 POP AUOH: Goa cia eres 41- 42 ‘Equivalent weights .... 50 Estimation method .... Ze TOeMAUSION he. s cass ee 42-102 Extensometer ......;.. 103 PREP BCUOl oo. . viers hss os ns 98 F Page Factors, conversion .... 50 ATS Sastre Pee fy ss 1 Fehling’s solution ..... 114 Melrisid@a eta ec cree ec 45 PEE heeds wreck on be, bk: 98-107 Eiotation test)... 2... 76 Ream Spots'e-, ob es 7 Folding endurance ....41-42-58 Formaldehyde .....<.: 118 OUT CSGHee ap e0 ve oF « 78 CCC oh Sie Fs 118 G Glarimeter, Ingersoll .. 94 RaLOSG tat cee rath Oalcaes tele te 94 Grease resistance ...... 85 Ground glass method .. 82 Gunning method ...... 112 H PEAIVEV INS) Eh ce wn 83 Herzberg stain, ....."s%. 18 FUME Ves eee ba 39-43-83 Hygrometric state ..... 38- 40 I Ink flotation test ...... 76 Tron specks te Ors s65 35 K Reese oe as Se a 37 ON CAUSE ava wars cate 76 bea Petiperes neue ayy Qoetel Lieberman-Storch ..... 110 Loften-Merritt stain .. 20 M Machine direction ..... 44 Microscopical examina- EPG Tart ae rote ale sek - 16 , Millon method>...2.0. ss 110 M. I. T. folding tester . 62 Wi Gisthive a Awsme:s -42-106 Mullen test yeas. eee. 41 N Nitrogen, proteinaceous 112 O OHS ER ie Mae ain Masons 117 OL SHolears eres eects 36 Okell ein, ey ak pak 76-77-78 Pact y ante aan eee 125 126 INDEX P Spence and Krauss ... 22 Page Stains, special “2 aanaeem 24 | Paper v Specks onc eus ns 37 Starch 24 dso 37-113-14 Paratin ies 4 cee 116-117-118 Stem fibers ..)..00eee 25- 27 Para-mitroamiine +2; .. 25 Stiffness. . 5. (75. eee 105 Pea and beam scale ... 49 Stockigt =. /2 ae 76- 81 Penescope 26 ies 89 Sulphur: ¢ 3... pee 115 Perkins tensile tester .. 46 Sutermeister stain .... 18 Permeability 4 kk 43 Phidroglucinol 27.426. 24 A Physical testing ....... 38 Tearing resistance ...42-43-68 Prussian Diues ook eee 117 Temperature 27) seo 38-43-83 Tensile breaking Q strength sae 41-42-64-67-68 Muadrant- scale. 45%, 5 46 Texture, surface ...e8 96 Thickness 930.0) eee 55 R Torsion: balance. een 47 Raspail methodan< 723. 110 Trade custom sizes .... 48 Rag Ac Fi can Poe 52 Resin specks 2-5 ses an 110 U Retention of filler .... 98 Ultrantarines. Gone 117 Rosinespecks¢< yong 2 35-110 Rubber specks (...<..4 3o V S Volumetric composition 96 Salievite acids S225 a 117 W Samplitip see ss, o 12 Water resistance tou se 81 DICALES orcs ute eee 49 Webb | tester, “i.e ame a3 Schopper cj ne 58-65-74-102 Weight 47440 (Geer 40- 45 Seed: hair fibers ....... 25- 26 Wet “rub. ae ya Sizing, degree of ...... 76- 81 Wire sides en eee 45 Sizing. suriace 73,5 ae 82 Wheatstone bridge .... 77- 78 Sriatts ie Ges ven aes nee 116 Wood. specks" i ue 35 126 ue Dat | L. FP F " F e D tw Eds yee ie 3. JOC #FES 7 Japer Jésti7g AMOS DORMS Vi ta gr as OORT Stes ae Z7b PEELS & GETTY CENT! TAT VAT ATU ANN HHH URE Hi] aa it Hi} ER LIBRARY Wail ] Hy 3125 00051 3586 | FT” Hl ee veer ayre ’ ‘* sere , Vv wy FS . veer ee ey FAITE LS TN Ne + v ¥, SOP THIEN ELS OID we , e, PAAPTI LEE ETE, CVA STENT LILI S. 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