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HOW TO INSTALL 
 
 qtriq Bells, 
 
 2lNNUN@m TORS, 
 
 and Alarms. 
 
 INCLUDING 
 
 tteries. Wires and Wiring, Circuits, Pushes, Bells, E 
 Alarms, High and Low Water Alarms, Fire Alarms, 
 Thermostats, Annunciators, and the Location 
 and Remedying of Troubles. 
 
 By NORMAN H. SCHNEIDER 
 
LEARN TO DO THINGS 
 
 Model Library Series 
 
 OF COPYRIGHTED BOOKS 
 
 1. The Study of Electricity for Beginners, 
 
 2. Dry Batteries, How to Make them. 
 
 3. Electrical Circuits and Diagrams, Part 1. 
 
 4. Electric Bells, Annunciators and Alarms. 
 
 5. Modern Primary Batteries. 
 
 6. Experimenting with Induction Coils. 
 
 7. Electric Gas Igniting Apparatus. 
 
 8. Small Accumulators, How to Make and Use 
 
 9. Model Steam Engine Design. 
 
 10. Practical Electrics. 
 
 1 1. Inventions, How to Protect and Sell them. 
 
 12. Woodwork Joints, How to Make and Use. 
 
 13. The Fireman’s Guide to the Care of Boilers 
 
 14. The Slide Valve Simply Explained. 
 
 15. The Magneto Telephone. 
 
 16. The Corliss Engine and Its Management. 
 
 17. Making Wireless Outfits. 
 
 18. Wireless Telephone Construction. 
 
 19. The Wimshurst Machine, How to Make It. 
 
 20. Simple Experiments in Static Electricity. 
 
 21. Small Electrical Measuring Instruments. 
 
 22. Electrical Circuits and Diagrams, Part 2. 
 
 23. Induction Coils, How to Make Them. 
 
 24. Model Vaudeville Theatres, 
 
 25. Alternating Currents, Simply Explained. 
 
 26. How to Build a 20 foot Bi-plane Glider. 
 
 27. A B C of the Steam Engine. 
 
 28. Simple Soldering, Hard and Soft. 
 
 29. Telegraphy for Beginners. 
 
 30. Low Voltage Lighting with Storage Batteri es 
 
 33. House Wiring for Electric Light. 
 
 34. Magnets and Magnetism. 
 
 36. Small Windmills and How to Make Therm 
 
 31. Lieckfield Gas and Oil Engines. 
 
 37. Collin's Wireless Plans, Part 1. 
 
 38. Collin’s Wireless Plans, Part 2. 
 
 IN PAPER COVERS 
 
 PRICE 35 CENTS EACH 
 
HOW TO INSTALL 
 
 Electric Bells, Annunciators, 
 and Alarms. 
 
 INCLUDING 
 
 Batteries , Wires and Wiring, Circuits, Pushes, Bells , 
 Burglar Alarms, High and Low Water Alarms, 
 Fire Alarms, Thermostats, Annunciators , 
 and the Locatio?i and Remedying 
 of Troubles . 
 
 B Iv 
 
 NORMAN HT SCHNEIDER, 
 
 Author of “The Study of Electricity for Beginners,” “Care and 
 Handling of Electric Plants,” etc., etc. 
 
 THIRD EDITION, ENLARGED 
 
 NEW YORK 
 
 SPON & CHAMBERLAIN, 120 LIBERTY STREET 
 LONDON 
 
 E. & F. N. SPON, Limited, 57 HAYMARKET, S.W, 
 
 1918 
 
CONTENTS 
 
 Introduction 
 
 Page 
 
 Introduction. The principle of an electric bell. ix 
 
 Chapter I 
 
 The Leclanche cell — Polarization — Setting up — The 
 dry cell — The gravity cell — Connecting up cells . 1 
 
 Chapter II 
 
 The single stroke bell — The shunt bell — The differen- 
 tial bell — The continuous ring bell — The water- 
 proof bell — Forms of gongs — The buzzer — Long 
 distance bells — The relay — The push — Three point 
 or double contact push — Floor push — Door pull 
 — Indicating push 9 
 
 Chapter III 
 
 Bell wires — Joints — Running wires — How to put up a 
 door bell — Combinations of bells, pushes and bat- 
 teries — Faults in bells, faults in wiring — How to 
 locate and remedy faults 23 
 
vi 
 
 CONTENTS 
 
 Chapter IV 
 
 Page 
 
 Fire alarms — Thermostats — Metallic thermostats — Mer- 
 cury thermostat — How to connect thermostats — 
 Water level indicators — Burglar alarms — Open and 
 closed circuit alarms — Window, door and shade 
 springs — Alarm matting — Yale lock alarm — Doo 
 trip alarm 40 
 
 Chapter V 
 
 The annunciator drop — The needle or arrow drop — 
 
 The pendulum drop — Wiring up annunciators — 
 Return or fire call systems — Double wire system — 
 Western Electric single wire system .... 55 
 
 Chapter VI 
 
 Three-.wire return call system — Installing elevator an- 
 nunciators — Burglar alarm annunciators — Clock 
 alarm circuit — Bells for high voltages — Bell-ringing 
 transformers — Combination bell, door opener and 
 telephone circuits — Fire alarm circuit — interior fire 
 alarm system — Fire alarm system for considerable 
 
 areas 
 
 64 
 
LIST OF ILLUSTRATIONS 
 
 Fig. Page 
 
 1 Electric bell, push, and battery x 
 
 2 Leclanche cell 1 
 
 3 Dry cell 4 
 
 4 Gravity cell 5 
 
 5 Vibrating bell 10 
 
 6 Single stroke bell 10 
 
 7 Shunt or short circuit bell 10 
 
 8 Continuous ring bell 13 
 
 0 Waterproof bell 14 
 
 10 Dome gong 15 
 
 11 Tea gong 15 
 
 12 Cow gong 15 
 
 13 Sleigh bell gong 15 
 
 14 Spiral gong 15 
 
 15 Relay and circuit 16 
 
 16 Door push 19 
 
 17 Pear push 19 
 
 18 Door push 19 
 
 19 Wall push 19 
 
 20 Floor push 20 
 
 21 Door pull attachment 22 
 
 22 Wire joint first operation 25 
 
 23 Wire joint second operation 25 
 
 24 Wire joint insulating 25 
 
 25 Section of house showing wiring 29 
 
 26 Bell with ground return 30 
 
 27 Pushes in multiple , 31 
 
viii LIST OF ILLUSTRATIONS 
 
 Fig. Page 
 
 28 Bells in series 31 
 
 29 Bells in multiple 31 
 
 30 Two bells and two pushes 32 
 
 31 Two bells and two pushes 32 
 
 32 Two bells, two pushes and one battery .... 33 
 
 33 Double contact push 33 
 
 34 Grounded bell 34 
 
 35 Tongue test of wiring 38 
 
 36 Knife test of wiring 38 
 
 37 Knife test of wiring 30 
 
 38 Metallic thermostat 40 
 
 39 Mercury thermostat 41 
 
 40 Mercury thermostat circuit 42 
 
 41 Water level alarm 44 
 
 42 Lever water level alarm 45 
 
 43 High or low water level alarm 45 
 
 44 Window spring for burglar alarm 47 
 
 45 Burglar alarm — closed circuit 47 
 
 46 Special bell connection for burglar alarm ... 48 
 
 47 Special bell connection for burglar alarm ... 49 
 
 48 Burglar alarm and relay 50 
 
 49 Window-shade contact spring 51 
 
 50 House wired for burglar alarm 52 
 
 51 Door trip alarm 53 
 
 52 Annunciator drop .... 55 
 
 53 Needle drop 56 
 
 54 Needle drop indicating 50 
 
 55 Pendulum drop 57 
 
 56 Annunciator drop circuit 58 
 
 57 Simple annunciator circuit 59 
 
 58 Annunciator and fire call circuit 60 
 
 59 Single- wire room and fire call 6X 
 
LIST OF ILLUSTRATIONS 
 
 Fig. -x Page 
 
 60 Three-wire return call circuit 65 
 
 61 Elevator bells and annunciator circuit 67 
 
 62 Burglar alarm annunciator circuit 69 
 
 63 Clock alarm circuit 71 
 
 64 Bell-ringing transformer 73 
 
 65 Bell-ringing transformer with three secondary 
 
 * voltages 73 
 
 66 Western Electric interphone system 75 
 
 67 Western Electric interphone system for more ex- 
 
 tensive service 77 
 
 68 Fire alarm circuit 79 
 
 69 Interior fire alarm circuit 81 
 
 70 Fire alarm circuit for considerable areas 82 
 
INTRODUCTION 
 
 An electric bell depends for its action on the 
 fact that a piece of iron wound with insulated 
 wire becomes a magnet and will attract another 
 piece of iron just so long as an electric current is 
 allowed to travel through the wire. 
 
 The instant the current ceases, the magnetism 
 also ceases, and the attracted piece of iron (termed 
 the armature) is no longer held in contact. 
 
 The general construction of an electric bell 
 is shown in Fig. 1. M M are coils of insulated 
 wire wound on soft iron cores. A is a soft iron 
 armature mounted on a flat spring so that it is 
 normally kept a slight distance away from the 
 soft iron cores. 5” is a brass screw with a plat- 
 inum tip touching a platinum disc on a spring 
 attached to the armature. 
 
 When the push button P is pressed down, its 
 two brass springs touch each other, the current 
 from the battery cell B then flows through the 
 wire W , through the push P, through the 
 coils M M, along A to the platinum disc, out 
 
INTRODUCTION 
 
 at S, which touches this disc, and back to the 
 battery. 
 
 The instant this is done the current causes the 
 iron cores to become magnets, they attract A, 
 which then breaks contact at S'. The spring 
 mounting of A causes it to jump back to its 
 first position, 5* then touches the platinum disc 
 again, the current flows as before, and the arma- 
 ture is again attracted only to break contact 
 with S' and fly back. 
 
 This continual making and breaking of the 
 circuit keeps up as long as the push is pressed, a 
 ball mounted on A by means of a rod strikes 
 against the gong G causing a continuous ringing 
 of the bell. The wires leading between the bell, 
 battery cell and push must all be insulated, that 
 is, covered with cotton, rubber, etc., which pre- 
 vents the leakage of current should two wires 
 cross each other. Copper wire is mostly used for 
 circuits indoors, the details of the kind and size 
 of wire will be given later on. 
 
 The main parts of an electric bell circuit are 
 then — the battery to supply the electric current; 
 the circuit, or wires, to carry this current ; a push, 
 or circuit breaker, to control the current flow; 
 and a bell to utilize the current. 
 
INTRODUCTION 
 
 c- 
 
 
 
 I 22 
 
 
 
 
CHAPTER I 
 The Battery 
 
 The Battery Cell. The battery cell most used 
 in electric bell work is the Leclanche, or some 
 modification of it. 
 
 The Leclanche battery cell is shown in Fig. 2, 
 
 Fig. 2 
 
 where / is a glass jar, Z a rod of zinc, and P a jar 
 of porous earthenware containing a carbon rod 
 surrounded by powdered carbon and peroxide of 
 manganese. 
 
2 
 
 ELECTRIC BELLS AND ALARMS 
 
 In setting up this cell about four ounces of 
 sal ammoniac (chloride of ammonia) are put into 
 the jar and enough water added to come about 
 half way up the jar. 
 
 The porous jar P and the zinc Z are then 
 inserted, and the cell is ready for use in a few 
 minutes after the liquid has soaked through the 
 earthenware into the carbon-manganese mixture. 
 Water is often poured into the porous jar through 
 holes in its top to hasten this wetting. 
 
 Wires are clamped by nuts or set-$crews to the 
 negative terminal on the zinc or the positive ter- 
 minal on the carbon, it generally not being of 
 consequence which terminal is attached to either 
 wire of the circuit. 
 
 A battery cell could be constructed without the 
 manganese, using simply a plate of carbon and 
 a rod of zinc, but hydrogen gas would be gen- 
 erated on the carbon plate when the cell was work- 
 ing and would stop the current flowing. 
 
 This is called polarization, and peroxide of man- 
 ganese is a de-polarizer, because it combines with 
 this hydrogen gas almost as fast as it is generated, 
 and prevents, to a great extent, the polarization. 
 
 But it does not stop it entirely, as will be seen 
 if the Leclanche cell is kept working above its 
 capacity. Then the hydrogen is generated too 
 fast for the manganese to destroy it, and the cell 
 
THE BATTERY 
 
 3 
 
 ceases to work. In this case a rest will often 
 restore the cell to its former power. 
 
 Cells which have been almost unable to make 
 a bell give even a single tap have been found 
 good again when allowed to remain at rest over 
 night. 
 
 In setting up a battery cell no liquid should be 
 splashed on the brass terminals or corrosion will 
 take place. Every metal surface where connec- 
 tion is made to allow electric current to pass must 
 be clean and bright, and all screws, or nuts, hold- 
 ing wires must be screwed up tight so that the 
 wires are firmly clamped. 
 
 Loose or dirty connections are the cause of 
 probably eight out of every ten troubles affecting 
 bells and batteries. 
 
 When the fluid in a Leclanche cell becomes 
 milky, more sal ammoniac must be added. Or, 
 better still, throw out the old solution, wash the 
 porous jar thoroughly in clean water, scrape the 
 zinc bright, and half fill the cell with fresh solu- 
 tion. 
 
 The zinc wearing away rapidly or becoming 
 covered with crystals, and a strong smell of am- 
 monia, show generally that the cell is being worked 
 too hard, or that the current is leaking where it 
 should not. 
 
 A zinc rod in a cell working the average door 
 
4 ELECTRIC BELLS AND ALARMS 
 
 bell should last for six months, the porous jar for 
 a year. 
 
 The Dry Cell. The Leclaiiche cell being a 
 cell with much free liquid is liable to dry up if 
 not watched. The dry cell (Fig. 3) is a modern 
 
 Fig. 3 
 
 form of the Leclanche where the liquid is held by 
 an absorbent material, such as blotting paper, or 
 plaster. 
 
 A typical dry cell* is shown in the figure. An 
 
 *For full description of this class pf battery see No. 3 
 Book on “Dry Batteries.” 
 
THE BATTERY 
 
 5 
 
 outside case of zinc is lined with blotting paper 
 dampened with chloride of zinc and sal ammoniac. 
 A carbon rod is then inserted in the centre and 
 packed around with carbon dust and peroxide of 
 manganese. The latter mixture is also somewhat 
 dampened. 
 
 Molten wax, or a suitable composition, is then 
 poured on top of the contents of the cell to seal it 
 up and prevent the evaporation of the fluid. A 
 
 Fig. 4 
 
 terminal on the carbon rod and another on the 
 zinc case complete the cell. 
 
 The voltage of both the Leclanche and the dry 
 cell is about 1.45, when it goes below this it in- 
 dicates that the cell is worked out. 
 
 The two cells described are known as open- 
 circuit cells and are only intended for intermittent 
 working. 
 
 When a current is needed for a long period at 
 a time a closed circuit cell should be used, such as 
 the gravity Daniell cell. 
 
6 
 
 ELECTRIC BELLS AND ALARMS 
 
 The Gravity Daniell Cell. The gravity cell, 
 Fig. 4, has a zinc block Z suspended from the 
 side of the jar and a number of copper leaves C 
 standing on edge at the bottom. A quantity of 
 bluestone (sulphate of copper) is poured over the 
 copper leaves and the jar filled with water. 
 
 During the working of this cell, copper is de- 
 posited on the copper plate, and sulphate of zinc 
 formed at the zinc. To hasten the action a small 
 quantity of zinc sulphate can be added to the 
 solution when setting up the cell. 
 
 The name of this cell comes from the fact that 
 the copper solution being heavier remains at the 
 bottom of the jar. If the cell is not worked 
 enough, all the solution will become blue and the 
 zinc will blacken. If very dirty from this cause, 
 remove the zinc, scrape and wash ‘it thoroughly. 
 Throw out all the solution, add new sulphate and 
 water and replacing the zinc, then put the cell 
 on short circuit by connecting the copper and 
 zinc together for a few hours. 
 
 E. M. F. The e. m. f. of a gravity cell is within 
 a fraction of one volt, its current nearly one-half 
 ampere. 
 
 Warmth makes it give a greater current; on 
 no account let a gravity cell freeze. 
 
THE BATTERY 
 
 7 
 
 Resistance of a Cell. The fluids in a cell do 
 
 not conduct electricity as well as copper does ; they 
 offer more resistance and thus reduce the current 
 output. 
 
 The internal resistance of a cell may be low- 
 ered by using large zinc plates curled around the 
 porous pot. 
 
 The Samson cell has a large zinc plate bent in 
 the form of a cylinder, the carbon-manganese 
 combination standing in the centre of it. 
 
 The dry cell also has a large zinc, the internal 
 resistance being thus much lowered, the current 
 output is increased. This is by reason of Ohm’s 
 law, which teaches that to increase the current 
 flow, either the voltage of the battery must be in- 
 creased, or the resistance decreased. 
 
 But increased current means lessened life; there 
 is only just so much energy in a cell mainly de- 
 pendent on the quantity of chemicals. 
 
 Grouping of Cells. Cells may be grouped in a 
 battery to get increased voltage, or increased am- 
 perage. When connected for the former, they 
 are in series, the carbon of one is connected to the 
 zinc of the next, and so on. 
 
 If all the carbons are connected together and all 
 the zincs, they are in multiple, and will give the 
 
8 
 
 ELECTRIC BELLS AND ALARMS 
 
 same voltage as -of one cell but the combined am- 
 perage of all. 
 
 In ordinary bell work the series is the general 
 connection, the higher the resistance of the cir- 
 cuit, or the longer the wires, the more voltage is 
 required. 
 
CHAPTER II 
 
 Bells and Pushes 
 
 Electric Bells. The two main types of house 
 bells are the iron box and the skeleton. 
 
 The iron box has a cast-iron frame, or base, and 
 a cast- or stamped-iron cover over the mechanism. 
 
 The skeleton bell has an iron frame but no 
 cover, and is generally better finished and more 
 expensive than the iron box bells. 
 
 For fire alarm purposes, mechanical bells or 
 gongs are made, in which a clockwork mechan- 
 ism causes the hammer to strike the gong upon 
 being released by electromagnetism. 
 
 Marine or waterproof bells have an iron cover 
 fitting tight over a rubber gasket; they are for 
 marine, or mining, work. 
 
 Polarized, or magneto, bells are used in tele- 
 phone work, and are rarely operated by a battery, 
 but have a miniature dynamo generator operated 
 by hand, or power, to supply the actuating cur- 
 rent. 
 
 Most bells are classed for size by the diameter 
 of the gong, a four-inch bell being one with a 
 gong four inches in diameter; a six-inch bell one 
 with a six-inch gong, and so on. 
 
10 
 
 ELECTRIC BELLS AND ALARMS 
 
 According to the use for which they are in- 
 tended, bells may be vibrating, as before described, 
 single-stroke, shunt or short-circuiting, differen- 
 tial, continuous-ringing, or adapted for circuits of 
 high voltage. 
 
 The Single-stroke Bell. The bell before de- 
 scribed, and again shown in Fig. 5, is a vibrating, 
 or trembling, bell. It is often desired to have the 
 hammer give only one stroke for each pressure of 
 the push, as in signaling with a code of taps; in 
 this case a single-stroke bell is used. The circuit 
 
 from the binding posts is then directly through 
 the magnet coils without any break at the contact 
 screw, as in Fig. 6. 
 
 In adjusting such a bell to give a clear sound, 
 press the armature up against the iron magnet 
 cores and then bend back the hammer until it just 
 clears the gong. The spring of the hammer wire 
 will carry the hammer sufficiently forward to hit 
 the gong. The tone will be clearer than if the 
 hammer dampered the gong by pressing against 
 it when the armature was nearest the core. 
 
BELLS AND PUSHES 
 
 11 
 
 By bringing out a third connection, a vibrating 
 bell may be made both single stroke and vibrating. 
 
 The Shunt Bell. There is a form of bell, 
 Fig. 7, known as the shunt, or short circuit bell, 
 which is often used when two or more are to be 
 connected in series, as will be seen in the descrip- 
 tion of circuits. In this bell the circuit through 
 the magnets is not broken at the contact screw, 
 but the forward movement of the armature short 
 circuits the coils. 
 
 As the short, or shunt, circuit is very much 
 lower in resistance than the wire on the magnet 
 coils, the main current flows around the latter and 
 they do not become energized. The sparking at 
 the shunting contact screw is much less than it 
 would be at the ordinary breaking contact screw, 
 and the platinum points last longer. 
 
 The Differential Bell. Sparking at the break- 
 ing contacts of an electric bell is detrimental to 
 the platinum points, and many remedies have been 
 devised to overcome it. 
 
 Sparking is due to the self-induction of one 
 turn of the wire coil acting on its neighbor, and 
 this property is utilized in the gas engine, or gas- 
 lighting spark coil, where a fat spark is needed to 
 ignite gas. 
 
12 
 
 ELECTRIC BELLS AND ALARMS 
 
 The differential bell has two windings in oppo- 
 site directions. The action of one would be to 
 produce an N-pole at one end and an S-pole at 
 the other. But the second coil produces poles just 
 the opposite, as the polarity of a magnet depends 
 on the direction in which the current flows around 
 it. 
 
 Where the current flows around the first wind- 
 ing the armature is attracted and its spring con- 
 tact meets the contact screw and allows the cur- 
 rent to divide, part flowing through the first coil, 
 the other flowing in the reverse direction in the 
 opposite way. One coil would tend to produce 
 an N-pole where the other coil produced an S-pole, 
 and these opposite poles would so neutralize each 
 other that there would be no magnetism. 
 
 The armature would therefore be pulled back 
 by its spring when both coils were thrown into 
 circuit. In so doing it would cut out one coil 
 and the same series of operations would recom- 
 mence. 
 
 As a spark is normally produced where mag- 
 netism is lost by a break of circuit,* no spark ap- 
 pears, as magnetism is produced by a break of 
 circuit in this case. 
 
 *For a full explanation of self-induction see No. I of 
 this series. 
 
BELLS AND PUSHES 
 
 13 
 
 Continuous-ring Bell. In some classes of bell 
 work, such as burglar alarms, it is desired that the 
 bell when once started shall continue to ring until 
 stopped by the person called. In this case a con- 
 tinuous-ringing bell is needed, such as in Fig. 8. 
 
 When the push P is pressed, the current flows 
 
 Fig. s 
 
 in the usual way through contact screw L, arma- 
 ture spring A, magnet coils M M, battery B, back 
 to P, and the bell rings. But on the first forward 
 movement of the armature it releases the spring 
 contact S, which flies forward and makes contact 
 at U. The circuit is now from B, through M M , 
 
14 
 
 ELECTRIC BELLS AND ALARMS 
 
 to A, thence through L and S, to U and back 
 to B. 
 
 The bell will continue to ring until the spring 
 contact .S' is moved back and caught by the pro- 
 jection on the armature A. 
 
 A continuous-ring attachment is also made and 
 sold in most electrical supply stores, which is com- 
 plete in itself and can be applied to any bell. 
 
 Fig. 9 
 
 Waterproof Bells. In Fig. 9 is an example of 
 a waterproof bell where the mechanism is almost 
 all entirely encased in a waterproof brass case. 
 
 The circuit is made and broken inside the case, 
 but the magnet cores project through it and act 
 on a second armature placed outside. This sec- 
 ond armature carries the hammer which strikes 
 the gong and is governed in speed by the contact- 
 breaking armature inside. 
 
BELLS AND PUSHES 
 
 15 
 
 Forms of Bell Gongs. In order to provide a 
 variety of sounds, bells are provided with gongs 
 of various shapes. 
 
 Fig. 10 shows the ordinary form of gong. 
 
 Fig. 10 Fig. 11 Fig. 12 Fig. 13 
 
 Fig. 11, a tea gong; Fig. 12, a cow gong; and 
 Fig. 13, a sleigh bell. 
 
 A coil of steel wire is also used, as in Fig. 14, 
 which on being struck by the hammer gives a 
 pleasant but not loud tone. 
 
 Fig. 14 
 
 The Buzzer. The buzzer is the mechanism of 
 a vibrating bell less the hammer and gong. As 
 the armature vibrates it makes a buzzing noise 
 which does not carry as far as the sound from 
 a struck gong. It is used chiefly for a desk call 
 
16 
 
 ELECTRIC BELLS AND ALARMS 
 
 and in telephone exchange work, or any place 
 where general attention is not desired to the signal. 
 
 Operating Bells at a Distance. When it is 
 desired to ring a bell situated at a considerable 
 distance from the push, the resistance of the line 
 becomes objectionable. 
 
 Fig. 15 
 
 On lines of 500 feet, No. 18 copper wire and 
 upwards, the battery necessary would be very 
 large, two small batteries and a relay would prove 
 more satisfactory. 
 
 In Fig. 15 the circuit of a simple form of relay 
 is given. An adjustable contact screw C is placed 
 where an extension S' of the armature A can strike 
 
BELLS AND PUSHES 
 
 17 
 
 it. This extension is provided with a platinum 
 contact. The connections are as in the figure. 
 
 When the push P is depressed, the current from 
 the main battery M energizes the electromagnet E , 
 and the armature A being attracted, contacts 5 
 and C meet. These contacts close the second cir- 
 cuit containing the bell 3 and the local battery L. 
 
 The relay resembles a second push near the 
 bell, but controlled by current from a distance 
 instead of being depressed by hand. Its advan- 
 tage consists in it needing but a very weak cur- 
 rent to move the armature A, which is held back 
 by a light spring, or by gravity. 
 
 The relay may then be set near the bell and 
 the wires from the push may be of a very great 
 length. Battery L, which actually rings the bell, 
 will thus only have to work through a few feet 
 of wire. 
 
 Reducing Resistance of a Bell. Sometimes 
 it is desired to reduce the resistance the bell coils 
 offer to the current, the bell then working over a 
 very short line with few cells of battery. Or 
 the bell coils may have been wound with fine 
 wire for large battery voltage and a long line. 
 
 The bell coils may be put in multiple, the cur- 
 rent then dividing and one-half going through 
 each spool. 
 
18 
 
 ELECTRIC BELLS AND ALARMS 
 
 Untwist the joint between the spools near the 
 yoke or iron bar to which the spools are attached. 
 Join one of these ends to the wire at the armature 
 end of the other spool and the second untwisted 
 end to the armature end wire of its neighboring 
 spool. Use short pieces of insulated wire for 
 these extra connections. 
 
 The current now instead of having to go 
 through one spool and then the other, can branch 
 through both at once. 
 
 The resistance to the current of one spool is 
 half the resistance of two, the current through one 
 spool will therefore be twice that through the 
 two spools as at first connected. And as there are 
 two paths for it, each one-half the first resistance, 
 the total will be only one-fourth the resistance 
 of the ordinary series arrangement. 
 
 The same size battery will therefore send four 
 times the current through the spools in multiple 
 than when they are in series. 
 
 It is to be noted that the wire on one spool is 
 wound in the reverse direction to that on the 
 other. The reason will be apparent if the two 
 spools and yoke are considered as merely one 
 spool bent in a U or horseshoe form. 
 
 If both spools were wound in the same direc- 
 tion they would be in opposite directions when the 
 U were straightened out, and would cause like 
 
BELLS AND PUSHES 
 
 19 
 
 poles at the same ends. These poles would neu- 
 tralize one another, so that there would be no 
 magnetic attraction. 
 
 This can be readily proved by joining together 
 the two yoke ends and the two armature ends of 
 the spool wires. Then pass the current through 
 these two joined connections. 
 
 Fig, 18 Fig. 19 
 
 Fig. 17 
 
 Fig. 16 
 
 The Push Button. Push buttons, or pushes, 
 are made in a variety of forms, with metal, wood, 
 hard rubber, or porcelain bases. 
 
 Fig. 16 has a metal base, and is suitable for 
 a front door. 
 
 Fig. 17 is a wooden pear push, and is attached at 
 the end of a cord which has the two conductors 
 braided in it, each, however, having its own in- 
 sulation. 
 
 Fig. 18 is a plate push for an outside door. 
 
20 
 
 ELECTRIC BELLS AND ALARMS 
 
 Fig. 19 is either of metal, wood, or porcelain, 
 and is the shape most commonly used. 
 
 A three-point push has three contact springs. 
 One is movable by means of the button, one is 
 below the movable spring, and the third is above 
 it. 
 
 When the push button is not being depressed, 
 
 the movable spring makes contact with the upper 
 spring. But when the button is depressed, these 
 two springs part, and the movable spring makes 
 contact with the lower one. 
 
 This style of push is used for special bell and 
 annunciator work, as will be described later. 
 
 The form of combination floor and table push in 
 Fig. 20 is the most solidly constructed device of 
 its kind. The lower part is set in a hole bored 
 in the flooring, the metal flange keeping it in 
 place and preventing its slipping through. 
 
. BELLS AND PUSHES 
 
 21 
 
 The floor push attachment works as follows : 
 The central metal rod is divided into two parts 
 B D y by an insulating piece of hard rubber. When 
 depressed against the action of the spiral spring 
 by the foot, the upper part B connects together the 
 contact springs A C , closing the circuit of bell 
 and battery. These contact springs are insulated 
 from each other by a hard rubber block R. 
 
 From the table push a cord containing two in- 
 sulated wires leads to the two parts of the rod 
 at B and D. When the push centre is pressed 
 down, the push springs come together and practi- 
 cally short circuit B and D , which completes the 
 circuit of bell and battery. At any time the centre 
 rod may be removed, leaving a surface almost 
 flush with the carpet, or floor, over which furni- 
 ture may be moved without injury to the mechan- 
 ism of the push. 
 
 For a floor push alone a shorter form of the 
 centre rod is also sometimes furnished which is 
 not divided by insulation. The spiral spring 
 keeps it clear of the lower contact A but enables 
 it to always make connection with the upper con- 
 tact B. Pressing this rod down will also short 
 circuit the bell and battery so that the signal is 
 given. 
 
 A door pull attachment, like Fig. 21, is made 
 so that the ordinary form of lever pull bell may 
 
22 
 
 ELECTRIC BELLS AND ALARMS 
 
 be changed into an electric bell. Being screwed 
 up near the door pull, a wire is run front the lat- 
 ter and fastened to lever L. When the pull is 
 drawn out the lever L turns on a pivot and a 
 projection presses the insulated spring S against 
 the metal base B. The circuit of the bell and 
 battery being thus closed, the bell rings. 
 
 Indicating Push Button. A push button is 
 made which contains in the base a small electro- 
 magnet in series with the line. An armature on 
 a spring is fixed near the magnet poles. When 
 the push is depressed, the current travels through 
 this electromagnet, and as the circuit is made 
 and broken at the distant bell, it is also interrupted 
 in the electromagnet. The armature vibrates in 
 unison with the bell and thus gives an audible 
 indication that the bell is ringing. 
 
CHAPTER III 
 
 Wiring , Circuits and Troubles 
 
 The Wire. The size of the copper wire used 
 in bell work is No. 16, or No. 18, B and S gauge, 
 and sometimes smaller, such as No. 20 to 22. 
 But smaller wire than No. 18 has too much re- 
 sistance, and would necessitate a larger battery 
 power, even if its mechanical strength were not 
 too low. The insulating coverings are cotton satu- 
 rated with paraffin wax or compounds. 
 
 The covered wires are variously known as an- 
 nunciator, office, or weatherproof wire, these terms 
 being mostly for distinction of the coverings and 
 not for the use to which the wire would be put. 
 
 Annunciator wire has two layers of cotton 
 merely wrapped around the copper and then satu- 
 rated with paraffin. 
 
 Office wire has the two cotton layers braided, 
 the inside one being filled with a moisture-repel- 
 ling compound. 
 
 Both office and annunciator wires have their 
 outside coverings filled with paraffin and highly 
 polished. 
 
 From the ease with which annunciator wire is 
 
24 
 
 ELECTRIC BELLS AND ALARMS 
 
 stripped of its cotton covering, the braided office 
 wire is to be preferred. These coverings are made 
 in a variety of colors. 
 
 Weatherproof covered wire is mostly used for 
 electric light work, but the sizes given above are 
 good for bell work, although their larger outside 
 diameter makes them harder to conceal. 
 
 The approximate number of feet to the pound 
 of office and annunciator wire is given in the 
 table. 
 
 Office 
 
 Wire. 
 
 Annunciator Wire. 
 
 No. 
 
 Feet per lb. 
 
 No. 
 
 Feet per lb. 
 
 12 
 
 35 
 
 18 
 
 180 
 
 14 
 
 55 
 
 20 
 
 225 
 
 16 
 
 95 
 
 
 
 18 
 
 135 
 
 
 
 Joints. Upon the care with which a joint is 
 made much depends, a loose or poorly made joint 
 will offer much resistance to the current. 
 
 The correct way to start a joint in annunciator, 
 or office, wire is shown in Fig. 22. About three 
 inches of each wire to be joined is bared of its 
 insulation and scraped bright. The ends are then 
 
WIRING, CIRCUITS AND TROUBLES 
 
 25 
 
 bent at right angles to each other, hooked together 
 and one end firmly twisted around the other, as 
 shown in Fig. 23. Any projecting pieces are cut 
 off, and the joints should then be soldered to pre- 
 vent corrosion. 
 
 Fig. 22 
 
 (ZZZZZZZZ 
 
 zzzzzzzzza 
 
 Fig. 23 
 
 a t t / # f .i jy 
 
 Ictzxjez la 
 
 Fig. 24 
 
 Adhesive tape (“friction tape”) is wrapped 
 around the joint, Fig. 24, and pressed firmly to- 
 gether so that there is no chance of its unravelling. 
 The tape wrapping should extend across the joint 
 and on to about a half inch of the insulation 
 around each wire. 
 
26 
 
 ELECTRIC BELLS AND ALARMS 
 
 Running the Wires. To detail all the opera- 
 tions of installing a complex system of bell, alarm 
 and annunciator wires would be impossible from 
 the reasons that conditions vary and space is lim- 
 ited. General directions will then only be given 
 to enable the inexperienced to run such wires as 
 may be needed in ordinary domestic work and to 
 guard against the most common causes of failure. 
 
 Wires may be run in tin tubes to prevent the 
 depredations of rats and mice, or they may be run 
 with simply their own covering for protection ; it 
 is presumed the latter is undertaken. 
 
 In a case where the building is of frame and 
 in course of erection the task is much simplified. 
 
 Having first decided upon the plan, number of 
 bells, pushes, etc. and their location, proceed to 
 run the wires first in order that the pushes, bells, 
 etc. may not be injured. 
 
 But where the house is already occupied, as in 
 the majority of cases likely to be met with by the 
 reader, the bell and battery may be set first. 
 
 Take the case of an ordinary door bell with the 
 push at the front door, the bell in the kitchen and 
 the battery in the cellar. If possible get the wire 
 on two spools; it will simplify matters if both 
 wires are of different colors. Starting at the push, 
 have a foot of each wire for connection and slack, 
 and fasten each wire lightly to the woodwork with 
 
WIRING, CIRCUITS AND TROUBLES 27 
 
 staples, or double-pointed tacks, never putting two 
 wires under one staple nor driving in a staple so 
 it cuts the insulation. Some cases will require a 
 staple about every foot, on straight runs some- 
 times every three feet. 
 
 In many cases the wires can be partly con- 
 cealed in the angle between a moulding and the 
 wall, or even in a groove of the moulding itself. 
 When running along a skirting, the wires may 
 often be pushed out of sight between it and the 
 floor. Do not attempt to draw the wires too 
 tight or the changes of the weather may break the 
 wires when the woodwork shrinks or swells. 
 
 The wires will be, one from the push to the 
 bell, one from the push to the battery, and one 
 from the bell to the battery. So it is probable 
 that the second wire can be run right through a 
 small hole bored in the flooring under the push, 
 but inside the front door. In this case it will 
 be perhaps easier if the spool be left in the cellar 
 and the end of the wire be pushed up from below 
 and stapled to the woodwork near the push, leav- 
 ing the cellar work to the last. Only one wire 
 will be run then direct to the bell upstairs and 
 it can be better concealed than two. 
 
 If necessary it may be drawn under a carpet 
 and not stapled, or it can often be forced into the 
 crack between two boards, But if not, run it 
 
28 
 
 ELECTRIC BELLS AND ALARMS 
 
 along the skirting, following the walls until it 
 reaches below the bell. It is often better to go 
 entirely around a room than to cross below a 
 door. 
 
 If a door must be crossed the wire may either 
 run up one side of the frame and down the other 
 or laid beneath the carpet on the sill. The former 
 is preferable, but takes more wire. 
 
 In many houses the bell wire as well as the bat- 
 tery wire may be run across the cellar beams 
 (Fig. 25), in which case bore a second hole for it 
 near the push ; do not draw it through the same 
 hole as the push to battery wire. And, of course, 
 here work upwards with the spool in the cellar. 
 
 Having reached the bell location, run the third 
 wire down into the cellar to the battery. Now 
 connect up the push, baring an inch or so of each 
 wire, push them through the holes provided in 
 the push base, screw down the push base and 
 clamp the wires under the washers through which 
 the connection screws run. Do this neatly, be sure 
 the ends of the wires do not stick out, cut off 
 what is left free of the bared ends. Then con- 
 nect the battery to the wire from the push and the 
 wire from the bell. The last thing is to scrape 
 and fasten the bell wires to the bell binding posts. 
 Do this so that they cannot come loose and that 
 they make good contact. 
 
Fig. 25 
 
30 
 
 ELECTRIC BELLS AND ALARMS 
 
 The bell should now ring properly when the 
 push is pressed. 
 
 To sum up, one wire leads from one spring 
 of the push to the bell, one wire from the other 
 spring of the push to the battery, and another wire 
 from the remaining binding post on the bell to the 
 remaining binding post on the battery. It is im- 
 material whether the zinc terminal or the carbon 
 terminal go to the bell or push. 
 
 Combinations of Bells and Pushes. One of 
 
 the wires in a bell circuit may be replaced by 
 the ground (Fig. 26). Connection may be made 
 to a gas or water pipe or to a metal plate buried 
 deep in damp earth. Any wire fastened to such a 
 
 plate must be thoroughly soldered to it or a voltaic 
 action will be set up, which will eat it away at the 
 point of contact. 
 
 When one bell is to be rung from two or 
 more points the pushes are to be connected in 
 
WIRING, CIRCUITS AND TROUBLES 
 
 31 
 
 multiple (Fig. 27) as if they were in series; all 
 would have to be closed to complete the circuit. 
 
 If two bells are to be operated from one push 
 
 they may be in series (Fig. 28), but in this case 
 one of them must be arranged for single stroke. 
 
 If both were vibrating bells the armature of one 
 would not vibrate in unison with the other arma- 
 
 ture and the result would be irregular contact 
 breaking and intermittent ringing. 
 
 A preferable connection for two or more bells 
 
32 
 
 ELECTRIC BELLS AND ALARMS 
 
 and one push is Fig. 29, where the bells are in 
 multiple. This requires more current than the 
 series method. 
 
 To ring two bells from either one of two points, 
 the arrangement in Fig 30 will answer. It re- 
 quires only two wires or one wire and ground 
 return, but two batteries. As both bells are in 
 
 Fig. 31 
 
 multiple both will ring, the one nearest the push 
 being depressed ringing the loudest. This is a dis- 
 advantage. If the series arrangement in Fig. 31 
 
WIRING, CIRCUITS AND TROUBLES 33 
 
 be selected, one bell must be arranged for single 
 stroke. Both bells will ring with equal power. 
 
 In Fig. 32 only the distant bell rings, the cir- 
 
 cuit having only one battery but three wires, or 
 two wires and ground return. 
 
 A plan where two batteries are needed but only 
 two wires, or one wire and ground is in Fig. 33. 
 
 Fig. 33 
 
 here, making one contact when depressed and a 
 second one when not being touched. 
 
 In this figure only the distant bell rings. 
 
34 
 
 ELECTRIC BELLS AND ALARMS 
 
 Faults in Bells. On examining many electric 
 bells it will be noted that only one binding post 
 is insulated from the frame when the latter is 
 
 Fig. 34 
 
 of iron (Fig. 34). As the armature spring S' is in 
 electrical connection with the frame F by reason 
 of its metal screws and support, the circuit may 
 run from the insulated post U to the magnet eoils, 
 thence through the insulated contact screw C 
 through the armature spring (when it is making 
 contact) and through the frame to the uninsulated 
 post /. 
 
 This saves labor, wire and complication, but if 
 the insulation of the post U, the wires W V , or the 
 contact screw C be injured, the current may take 
 a short path back to the frame. 
 
 If C were thus grounded, the bell would act as 
 a single-stroke bell. 
 
 If C/ were grounded, the bell would not ring 
 
WIRING, CIRCUITS AND TROUBLES 
 
 35 
 
 at all, as that would be a short circuit on the bat- 
 tery between / and U and the latter would also 
 result if the bare wire were touching the frame 
 at V. 
 
 If the bare wire touched the frame bevond M M, 
 that is, along W, it would be a single-stroke bell, 
 as if C were grounded. 
 
 As any one of these faults is likely to occur, 
 they should be looked for when the bell acts im- 
 perfectly, or not at all. 
 
 A very common fault in a bell is when its arma- 
 ture sticks to the cores and thus does not make 
 contact with the contact screw. This may be from 
 a weak spring or because of the loss of the pieces 
 of brass inserted in the ends of the cores to keep 
 the armature away from actual contact. A piece 
 of a postage stamp stuck over the core end will 
 often help out in the latter case. 
 
 A high screeching noise from the armature vi- 
 brating too rapidly but with too little play, may 
 be from excessive battery power or the contact 
 screw being too far forward. The former will 
 generally be detected by the violent sparking as 
 well as the rapid vibration. 
 
 In very cheap bells the platinum contacts may 
 be replaced by German silver or some other metal. 
 
 Platinum is necessary because the sparking 
 would soon corrode other metals, but it is very 
 
36 
 
 ELECTRIC BELLS AND ALARMS 
 
 expensive. To test for platinum put a tiny drop 
 of nitric acid on the suspected metal. If bubbles 
 or smoke appear it is not platinum. After apply- 
 ing this test in any case however, carefully wash 
 off and remove all traces of the acid, as it will cor- 
 rode the metal into which the platinum is riveted. 
 
 Dirty contacts will decrease the current in the 
 bell coils and it will not work well, if at all. 
 
 Loose contact screws and wires also give 
 trouble. The adjusting of the contact screw is of 
 the utmost importance, and should never be at- 
 tempted 'unless it is clearly necessary. 
 
 Faults in Line. In looking for a fault in a 
 bell circuit make sure the battery is working; if 
 only one or two cells, put the ends of two wires 
 attached to the terminals on the tongue : a metallic 
 taste will indicate current. 
 
 Then see that the circuit wires are firmly 
 clamped in the terminals and no dirt or corrosion 
 on the connections. 
 
 Next examine the push button and see that the 
 wire connections at the springs are perfect. 
 
 If there is no movement of the bell at all when 
 the push is pressed in, take a pocket knife or 
 screw driver, and touch the blade across the push 
 springs. If there is current flowing sparks will 
 be seen when the blade breaks contact between 
 
WIRING, CIRCUITS AND TROUBLES 37 
 
 the springs. If there are no sparks, detach the 
 wires from the bell and twist the bare ends to- 
 gether. Then try again for sparks — they may 
 now be very minute. The tongue test is good here. 
 
 If current is detected, examine the bell for the 
 defects first mentioned. 
 
 But if no current is found at the push now the 
 wires are broken somewhere. 
 
 First short circuit the push springs by insert- 
 ing a knife blade or piece of wire so as to touch 
 both of them. Then touch the two wires at the 
 bell, one to each side wire coming from the mag- 
 net coils. If current is up to the bell and the coils 
 are all right, a single stroke should result. 
 
 Replace the wires in the binding posts, clean 
 the platinum on both contact screw and armature 
 spring and try the adjustment. Troubles in the 
 bell will be mostly similar to those before men- 
 tioned. 
 
 If no current has been obtained at either bell 
 or push, and the battery is in good working order, 
 the line must be tested for a cross or break. 
 
 If the wires are touching each other (Fig. 35) 
 at some bare spot S' between the bell and the bat- 
 tery, it will be shown by the metallic taste upon 
 detaching one wire from the battery and laying 
 it on the tongue T, together with another wire W 
 from the disconnected terminal of the battery. The 
 
38 
 
 ELECTRIC BELLS AND ALARMS 
 
 current will travel from the battery to the cross 
 at S, then back along the second circuit wire to 
 the tongue and through the short wire to the 
 battery. 
 
 able that the wire is broken. 
 
 The easiest way to find this is to take a bell 
 to the battery and connect it between the circuit 
 wires and the battery (Fig. 36). 
 
 Then with a sharp knife carefully cut away a 
 
WIRING, CIRCUITS AND TROUBLES 
 
 89 
 
 little piece of the insulation from each wire beyond 
 the bell and battery and short circuit the bared 
 spots with the knife blade K. Keep working 
 towards the push. The bell will ring each time 
 
 at K K until the break D is passed, at C it will 
 not. It becomes an easy matter then to locate 
 it 
 
 If the bell and push are far apart, as in Fig. 37, 
 a break between the push and the bell may be 
 found as shown. With the knife blade K at differ- 
 ent points the bell will ring, but after passing the 
 break D it will not ring. 
 
 Such simple tests as are here given can be car- 
 ried out by any one, but far better results will be 
 obtained if the reason for each is first learned. 
 
 This can be readily done by a careful study of 
 the diagrams and text. 
 
CHAPTER IV 
 Alarms 
 
 Fire Alarms. Thermostats, heat alarms and 
 fire alarms are all practically the same, the term 
 thermostat being applied principally to the appa- 
 ratus which closes the electrical circuit. 
 
 i 
 
 i 
 
 i 
 
 I 
 
 i 
 
 i 
 
 Fig. 38 
 
 Thermostats act on the principle that heat causes 
 expansion whether of substances, liquids, or gases. 
 
 The degree in which different substances ex- 
 pand varies for the same increase in temperature. 
 This fact is used in a common form of thermo- 
 stat shown in Fig. 38. A strip of wood or hard 
 rubber R has a strip of thin sheet metal S riveted 
 to it. This compound strip is held at one end by 
 
ALARMS 
 
 41 
 
 a lug L screwed fast to a baseboard. Upon an 
 increase of temperature the hard rubber expands 
 more than the metal strip and the compound strip 
 bends towards the adjustable contact screw A. 
 Upon touching the latter, the circuit through the 
 bell B, battery C and the metal strip 5" is com- 
 pleted, and the bell rings. A contact screw can 
 be arranged at the other side of S R, which will 
 
 give warning of a decrease in temperature, as the 
 rubber contracts more than the metal strip. 
 
 In some thermostats of this character two metals 
 having different coefficients of expansion, such as 
 steel and brass, are used instead of metal and hard 
 rubber. 
 
 Thermostats of this nature are much used in 
 incubators, and they can readily be combined with 
 electric apparatus to open or close hot-air valves, 
 
42 
 
 ELECTRIC BELLS AND ALARMS 
 
 dampers, etc., and thus regulate the supply of 
 hot air, hot water, or gas. 
 
 A thermostat much used in fire alarm work has 
 a thin metal chamber which is air tight. An in- 
 crease of temperature causes' the air to expand, 
 which swells out the walls of the chamber and 
 closes an electric circuit. 
 
 A 
 
 
 0 ^ 
 
 B 
 
 <0 
 
 
 Q- 
 
 
 J0 
 
 
 cp 
 
 i 
 
 i 
 
 <Q 
 
 
 Fig. 40 
 
 The mercurial thermostat shown in Fig. 39 has 
 a glass tube T and bulb containing mercury. Into 
 each end is sealed a platinum wire P P. Upon 
 the temperature rising to a predetermined degree, 
 the expanded mercury completes the circuit be- 
 tween P P and the battery C and bell B are put 
 in operation. 
 
 Fig. 40 is the open circuit system most used by 
 
ALARMS 
 
 43 
 
 the fire alarm companies, only one circuit of six 
 thermostats being illustrated. 
 
 It will be seen that if any thermostat closes the 
 circuit between the outer and inner wires of the 
 ring A B, current will flow through the corre- 
 sponding drop of the annunciator and will attract 
 the armature A of the relay. This will cause the 
 bell to ring. As the relay is connected to the an- 
 nunciator as before shown for the annunciator bell, 
 it offers a common path for any drop to the bat- 
 tery. Thus the bell will ring for any circuit, but 
 the individual drop only will fall. In a simpler 
 circuit the relay may be dispensed with and a 
 vibrating bell only used. 
 
 Thermostats may be operated on open or closed 
 circuits, that is, they may give the alarm by clos- 
 ing a circuit and ringing a bell, or by opening one 
 and releasing a contact spring as in the burglar 
 alarm system to be described later. 
 
 Water Level Alarms. Where it is desired to 
 signal the rising or falling of water in a tank 
 above or below a given point, a water level in- 
 dicator as in Fig. 41 may be used. 
 
 A hollow ball H is mounted on the end of a 
 rod which slides vertically in guides, not shown. 
 Adjustable stops ^ 5 press against a spring 
 arm R , pressing it up or down, according as the 
 
44 
 
 ELECTRIC BELLS AND ALARMS 
 
 water level is rising or falling. If rising, R makes 
 contact with the adjustable screw A, if falling, 
 with D, in both cases completing the electrical cir- 
 cuit of the battery C and bell B. 
 
 Fig. 41 
 
 Another and simpler form is shown in Fig. 42, 
 where the ball H is mounted on the end of a 
 lever L pivoted at P, its rise or fall completing 
 the circuit of B and C as before. 
 
ALARMS 
 
 45 
 
 Where it is desired to give a different signal for 
 the rise and the fall of level, two bells B and E 
 
 (Fig. 43) may be used connected as shown. The 
 rising of the ball will ring bell B, and its fall, 
 bell E. 
 
46 
 
 ELECTRIC BELLS AND ALARMS 
 
 In both forms of indicator, a means must be 
 provided that an undue rise may not bend the 
 lever. This may be accomplished by using contact 
 springs instead of contact screws; it is, however, 
 then harder to adjust the indicator to fine differ- 
 ences of level. 
 
 In all cases the contacts must be faced with 
 platinum to prevent corrosion. 
 
 Burglar Alarms. A burglar alarm is a device 
 for indicating the opening of a door or window, 
 by the ringing of a bell or operation of an annunci- 
 ator. The contact apparatus at the points to be 
 protected may either open an electrical circuit or 
 close one, in the latter case being mere modifica- 
 tions of push buttons. The simplest form is the 
 latter or open-circuit method. 
 
 The spring contact to be inserted in the door 
 jamb or window frame is so constructed that 
 while under pressure the contacts are kept apart 
 and the circuit is open. But when the door or 
 window is opened, the pressure is released and 
 a spring forces the contacts together. 
 
 Fig. 44 is an open-circuit window spring fitted 
 in the window frame so that when the window 
 is closed the spring lug .S' is pressed inwards, 
 breaking contact with the base B. 
 
 If the window is raised, the lug flies to the 
 
ALARMS 
 
 47 
 
 position shown by the dotted lines, and making 
 contact with B, completes the circuit through bell 
 and battery. These springs are fitted in the side 
 
 ih_0 
 
 Fig. 44 
 
 of the window frame in a vertical position and 
 are entirely concealed when the window is shut. 
 
 In the closed-circuit system the reverse hap- 
 pens. The pressure of the closed door or win- 
 
 s 
 
 dow keeps the contacts together and its opening 
 enables them to spring apart. 
 
 In Fig. 45 is a diagram of a closed-circuit 
 burglar alarm, C a cell of gravity battery, R a 
 
48 
 
 ELECTRIC BELLS AND ALARMS 
 
 relay, F the fixed contact and M the movable con- 
 tact of the spring, S’ a stud projecting through 
 the base of the spring and pushed in by the closed 
 door. 
 
 When the door is closed, 6" being pushed in, 
 
 Fig. 46 
 
 the circuit of C, R, F and M is closed. The 
 magnets of the relay hold the armature arm A 
 forward against a hard rubber contact. But when 
 S' is released, the relay circuit is opened, R loses 
 its power and A flies back, making contact, and 
 throwing in circuit bell B and battery L. 
 
ALARMS 
 
 49 
 
 A form of bell and relay combined is shown in 
 Fig. 46. Here the armature A is held against the 
 magnets while the circuit through the spring F 
 and battery G is closed. But on opening this cir- 
 cuit the armature flies back and makes contact 
 with an adjustable contact screw S' putting in 
 circuit a local battery C. The bell is now practi- 
 
 cally a vibrating bell; on a closed circuit it rings 
 until the circuit is again closed or the battery runs 
 down. 
 
 A different connection of the same scheme is 
 Fig. 47, where only one battery is used. This 
 must be a gravity battery or some other closed- 
 circuit battery. The circuit can be easily traced 
 in the figure and needs no special description. 
 
50 
 
 ELECTRIC BELLS AND ALARMS 
 
 Both of the latter schemes are inferior to one 
 using a separate relay. If the circuit at the spring 
 were quickly closed again the bell would either 
 stop ringing, or be so hampered as to ring very 
 weakly. 
 
 Fig. 48 
 
 A relay made as in Fig. 48 has no spring sup- 
 port to the armature A , which falls down by grav- 
 ity. The adjustable contact C is screwed far back, 
 so that the armature must fall a considerable dis- 
 tance away from the electromagnets before it 
 makes contact. This ensures that the armature 
 will not be attracted and the bell stopped from 
 ringing by a re-closing of the circuit at the door 
 or window spring. 
 
 A shade spring (Fig. 49), is made for either 
 
ALARMS 
 
 51 
 
 open or closed circuits. In operation, the shade is 
 pulled down and its string or ring hooked on 
 to H. This draws H up a trifle against a spiral 
 spring and’ its lower end makes contact with an 
 insulated spring 5 closing the circuit. If the 
 shade is disturbed, the spiral spring on the lower 
 part of H is released and it causes a break of 
 contact with in the direction of the arrow. 
 
 When made for open circuit, ^ is bent so that 
 
 while under tension no contact is made, but re- 
 lease of tension causes the contact. 
 
 Fig. 50 gives the wiring of two windows and 
 a door on the closed-circuit system. It will be 
 seen that the contact springs are all in series, 
 opening a window or the door will thus break 
 the circuit. 
 
 When setting the alarm at night by connecting 
 up the batteries, relay and bell, should any one 
 of these springs be open the relay armature will 
 not hold, and the bell rings. 
 
Fig. 50 
 
ALARMS 
 
 53 
 
 Jn this figure the relay is replaced by an electro- 
 magnet holding up a drop shutter by magnetic 
 attraction. Upon the circuit opening, this shutter 
 falls, exposing a number painted on it. At the 
 same time it hits a spring contact placed below 
 it and closes the bell and local battery circuit. 
 
 Door Trip Alarm. A swinging contact door 
 trip can be attached over a door to ring a bell 
 when the door is opened. 
 
 Fig. 51 
 
 In Fig. 51 the door trip is screwed over the 
 door so that the lowest arm A is struck by the 
 door. When the door is opened, in the direction 
 of the arrow, the arm A is thrust forwards, and in 
 its turn moves the contact arm C, completing the 
 bell and battery circuit. But when the door is 
 being closed, A swinging in the reverse direction 
 does not move C and no alarm is given. 
 
54 
 
 ELECTRIC BELLS AND ALARMS 
 
 Miscellaneous Alarms. The Applegate elec- 
 trical matting is composed of wooden slats with 
 springs so arranged that the weight of any person 
 stepping on it will close a circuit and ring a bell. 
 
 It is intended to be put under the ordinary door 
 mat or under stair and room carpeting. 
 
 The Yale lock switch is a Yale lock and switch 
 combined. Upon any key but the right one being 
 inserted, a circuit is closed and an alarm bell is 
 rung. 
 
CHAPTER V 
 
 Annunciators 
 
 The Annunciator. The mechanism of an an- 
 nunciator consists of electromagnets which allow 
 shutters to drop or needles to move on the cir- 
 cuits being closed. A bell is also rung in most 
 cases to call attention to the annunciator. The 
 number of the circuit is marked on the shutter. 
 
 or near the needle, either shutter or needle being 
 replaced by a reset device, which may be mechan- 
 ical or electrical. 
 
 Annunciator drops are made in a variety of 
 forms. Fig. 52 illustrates the principle under- 
 lying nearly all of them. 
 
 When current flows through the magnet coils 
 M, the armature A is attracted, and being pivoted 
 at P y the lever hook H rises and allows the 
 
56 
 
 ELECTRIC BELLS AND ALARMS 
 
 weighted shutter S to fall and display a number 
 painted on its inside surface. 
 
 The needle drop in Fig. 53 is one that has met 
 with great favor and works as follows : the soft 
 iron core of the magnet C has a hole drilled 
 through it, in which turns the shaft S. An arrow 
 or needle is attached at the front end over the 
 
 face of the annunciator. A notched arm B is 
 fixed on the rear end of the shaft and is held in 
 a horizontal position by the end of armature A. 
 
 When the current flows around C, armature A 
 turns on its pivot towards the core of C, as in 
 Fig. 54, unlocking B, which falls and thereby 
 partly rotates shaft S and the arrow'. 
 
 When it is desired to reset the arrow' and arm, 
 
ANNUNCIATORS 
 
 57 
 
 a button is pressed upwards, which raises a rod 
 carrying an arm R. This latter arm in turn 
 raises B to its former position, the heavy end 
 of A falls, and its pointed end locks B . 
 
 Pendulum, or swinging, signals are used in an- 
 nunciator work, where there is a liability that the 
 
 Fig.. 55 
 
 ordinary drop shutter would not be reset. They, 
 however, only give a visible signal for a few sec- 
 onds, and are therefore liable to be overlooked. 
 
 In Fig. 55 a pivoted arm carrying a soft iron 
 armature A and a thin plate B having a number 
 on it is free to swing in front of an electromag- 
 net M . 
 
58 
 
 ELECTRIC BELLS AND ALARMS 
 
 When the current flows in the electromagnet 
 the armature is attracted, and upon the circuit 
 being broken at the push, the armature is released 
 and the arm swings to and fro. 
 
 The drops of an annunciator are wired up as 
 in Fig. 56. 
 
 One end of each coil is attached to a common 
 
 return wire C, the other end going to the push P. 
 When P is depressed, the circuit of any drop is 
 through M along C through bell, battery and up 
 common battery wire W back to other contact 
 of push P. Depressing any push does not there- 
 fore affect any other drop but- the one controlled 
 by it. 
 
ANNUNCIATORS 
 
 59 
 
 Wiring up an Annunciator. A diagram of 
 the connections for an annunciator with a separate 
 bell is given in Fig. 57. Where the bell is con- 
 tained in the case a terminal will be generally 
 found for connection. 
 
 The figure shows a wire running from the bat- 
 tery to one side of each push button. This is the 
 common return, or battery wire, and saves instal- 
 
 Fig. 57 
 
 ling two wires from each push. It should be 
 larger, however, than the rest of the wires, gener- 
 ally about No. 16 B. & S. 
 
 All the wires for an annunciator should be run 
 before connecting up. There are different methods 
 of sorting out the wires at the annunciator. One 
 way is to connect the wires (except of course 
 common or battery return wires) to the drops in 
 any order. Then an assistant travels from push 
 to push and presses each button, noting the 
 
GO 
 
 ELECTRIC BELLS AND ALARMS 
 
 room numbers and the order in which they were 
 visited. 
 
 As each drop falls, its number and order is 
 noted. 
 
 Comparing this with the list made by the assis- 
 tant will show the correct changes to make. 
 
 Fig. 58 
 
 For instance, suppose pushes 1, 2, 3, 4, 5 and 6 
 were pressed in that order, and drops 3, 4, 5, 1, 
 2 and 6 fell in that order. Then the wires at 
 the annunciator would be changed as follows: 
 From 3 to 1, 4 to 2, 5 to 3, 1 to 4, and 2 to 5; 
 6 would already be in its right place. 
 
 Another way is to commence by twisting to- 
 
ANNUNCIATORS 
 
 61 
 
 gether say the wires at No. 1 push. Then go to 
 the annunciator and touch each of the push wires 
 to No. 1 drop until it falls. Then connect it, 
 untwist the wires at No. 1, push and connect it 
 up. Proceed to No. 2 and so on until all the 
 pushes have been connected in turn. 
 
 In some cases it is desired to answer back to 
 the person- calling, or to be able to call any person 
 from the annunciator. 
 
 A circuit like Fig. 58 answers the purpose of 
 both annunciator call and return, or fire, call. 
 This requires two wires from each room to the 
 annunciator and a common return wire. By trac- 
 ing out the circuit it will be seen that when a 
 room push is pressed, the annunciator needle and 
 bell indicate. And when one of the pushes near 
 the annunciator is pressed, the corresponding 
 room bell rings. The former circuit is from the 
 push, along the common return wire, through 
 bell and annunciator back to the push. 
 
 The fire call is from push up line to bell through 
 bell along common return and through battery to 
 the push. 
 
 The Western Electric single-wire system 
 (Fig. 59) uses three-point pushes, two batteries 
 and two return wires. Battery A is for the annun- 
 ciator circuit and battery F for the fire, or return, 
 call. 
 
62 
 
 ELECTRIC BELLS AND ALARMS 
 
 Fift 59 
 
ANNUNCIATORS 
 
 63 
 
 In each room the top contact and push spring 
 contact are normally together. 
 
 If one of the pushes below the annunciator is 
 pressed, battery F is thrown in series with the 
 bell in the room. 
 
 But when the room push is pressed its bell is 
 cut out and the circuit becomes like an ordinary 
 annunciator circuit. 
 
CHAPTER VI 
 Annunciators and Alarms 
 
 Three Wire Return Call System. A three 
 wire return call annunciator system is shown in 
 Fig. 60. 
 
 There are two battery wires installed, from 
 which taps are taken off and led to each room 
 or push button. 
 
 Three way or return call push buttons are 
 used as shown at points marked B. 
 
 In the diagram, the bells are marked A, the 
 drops in the annunciator D, the annunciator bell 
 C and the return call buttons in the annunciator 
 E. The batteries are as shown at F. The heavy 
 black outline encloses the annunciator mechanism 
 and connections which are drawn diagrammatically 
 for the sake of clearness. 
 
 Three stations only are shown on the sketch, 
 but the annunciators which are manufactured by 
 Edwards and Co., Inc., of New York, are made 
 in all standard sizes. 
 
 Installing Elevator Annunciators. The install- 
 ing of electric bells and annunciators in elevators 
 does not present any special problems, although 
 the apparatus used must be selected with a view to 
 
 64 
 
FIG. 60 
 
66 ANNUNCIATORS AND ALARMS 
 
 its being suitable to withstand the shocks incident 
 to elevator service. 
 
 In general the wires leading from the push but- 
 tons on the different floors to the bell or an- 
 nunciator in the elevator, are flexible and made up 
 into a cable. One end of this cable is attached to 
 the underside of the elevator car, the other end 
 being fixed usually to the elevator wall, at a point 
 midway between the top and bottom of the shaft. 
 
 In Fig. 61 is shown a diagram of the general 
 circuit used, details of course differing in each 
 installation. 
 
 One point to be taken care of in elevator work 
 is the attachment of the cables. The continual 
 movement tends to break the wires at the two ends 
 if good flexible cable is not used and the installa- 
 tion done in a workmanlike manner. 
 
 Elevator cable is a standard article and may be 
 procured through any electrical ; supply store. 
 That most commonly used consists of the requisite 
 number of copper conductors each composed of 
 16 strands No. 30 B. and S. gauge soft and un- 
 tinned copper wire. These flexible conductors are 
 insulated with two reverse wrappings of cotton and 
 one braid of cotton. The insulated conductors 
 are cabled together with a steel supporting strand 
 where extra tensile strength is required, as in the 
 case of extra long cables. The number of con- 
 ductors generally ranges from 3 to 20 inclusive. 
 
 The wires leading from the push buttons to the 
 cable should be preferably rubber covered and 
 
CABLE 
 
68 
 
 ANNUNCIATORS AND ALARMS 
 
 braided. Only where economy at the outset is de- 
 sired may ordinary annunciator or office wires be 
 employed. 
 
 A connection block carrying binding posts is 
 used at each point where the cable connects to the 
 push button wires or to the annunciator. This may 
 be home-made or purchased ready made, as desired. 
 
 Burglar Alarm Annunciators. Although almost 
 any annunciator may be used for open circuit 
 burglar alarm work, they usually do not contain 
 certain devices which are desirable in burglar alarm 
 work. 
 
 In Fig. 62 is shown a diagram of a burglar alarm 
 annunciator, the view being schematic of the back 
 board. 
 
 The references are as follows: A is the main 
 alarm bell situated wherever desired and connected 
 to the binding posts BB. The battery connection 
 leading directly to the battery K is marked C 
 and that leading to the contact spring is marked 
 D. The cut-off switch E cuts off the battery while 
 F is the constant ring switch. G is the upper bar 
 and H the lower bar, while the letters JJ denote 
 the indicating drops. The door and window springs 
 are lettered 5'. At L is a switch which may be 
 used to disconnect the entire burglar alarm sys- 
 tem. Where it is desired to disconnect only a sec- 
 tion at a time, the switch corresponding to the 
 section is turned off the upper bar G and cn to the 
 lower bar H . 
 
FIG. 62 
 
70 
 
 ANNUNCIATORS AND ALARMS 
 
 Clock Alarm Circuit. A diagram of the wiring 
 and connections on the back board of all clock 
 alarms is illustrated in Fig. 63. This diagram 
 embodies the principles of the last described circuit, 
 but includes the circuit of a clock-operated alarm. 
 
 Bells for High Voltages. The use of electric 
 bells on lighting circuits is becoming quite general, 
 as it obviates the necessity of using batteries, and 
 thereby simplifies both installation and maintenance. 
 
 There is no fundamental objection to operating 
 make and break bells on electric light circuits. Pro- 
 viding the voltage and amperage are the same, 
 there is little difference between the current from 
 a direct-current dynamo and that from a battery. 
 But owing to the higher voltages of the lighting cir- 
 cuit over that generally employed from batteries, 
 the bell coils must be wound to high resistance^ to 
 keep down the current strength. There are also 
 other slight changes to assist in suppressing spark- 
 ing, as have been already treated on. 
 
 Where the circuit is not over 220 volts, the bells 
 are wound with fine wire and have also self-con- 
 tained resistance coils. For 500 volts and over, a 
 resistance lamp is connected in with the bell which 
 in this case is wound for a 150-volt circuit. 
 
 These bells up to 6-inch and inclusive will operate 
 on circuits of either direct or alternating current. 
 
 Above this size it is necessary to use specially 
 constructed bells on alternating current circuits. 
 
 Most large hotels and office buildings having 
 
FIG. 63 
 
72 
 
 ANNUNCIATORS AND ALARMS 
 
 direct current lighting service are using it for ring- 
 ing bells and similar work to the total exclusion 
 of batteries. 
 
 Where the number of units to be operated justi- 
 fies it, motor generators are operated in connection 
 with the lighting mains to produce a low voltage 
 most suitable for the bells. The connections in 
 this case are no different to those when batteries 
 are employed. 
 
 Bell-ringing Transformers. The best system 
 for operating bells and annunciators from alternat- 
 ing current circuits is undoubtedly that employing 
 small specially constructed transformers to reduce 
 the voltage. These transformers are being used 
 universally for hotel and office work where alternat- 
 ing current is available. They are simple, being 
 merely one or more coils of well insulated wire 
 wound on soft iron cores and having connections 
 for both the lighting circuit and the bell circuit. 
 
 As a general rule the coils are divided as to their 
 number of turns or according to the ratio of trans- 
 formation desired. For example, if the circuit 
 were 110 volts and 10 volts was required for the 
 bell circuit, the total number of turns in the trans- 
 former would be connected, 1 % 1 to the lighting cir- 
 cuit and Yu to the bell circuit. 
 
 The bell-ringing transformers on the market are 
 made in several styles. One small style, Fig. 64, 
 for single residences, is for use on 110 volts and 
 produces a bell voltage or secondary voltage as it 
 
ANNUNCIATORS AND ALARMS 
 
 FIG. 64 
 
 FIG. 65 
 
 BELL-RINGING TRANSFORMERS. 
 
74 
 
 ANNUNCIATORS AND ALARMS 
 
 is termed, of 6 volts. Another size, Fig. 65, of this 
 transformer has three secondary voltages 6, 12 and 
 18, each of which can be used by connecting to the 
 right binding posts. 
 
 It is to be noted that where the lighting service 
 voltage or primary voltage varies from the above, 
 the secondary voltage delivered to the bell circuit 
 will vary in like proportion. It should also be noted 
 that a careless reversing of the connections, that 
 is connecting the secondary leads to the light- 
 ing circuits, instead of the primary leads would 
 cause a like high voltage at the other terminals of 
 the transformer, raising it in due proportion in- 
 stead of lowering it. Thus such carelessness would 
 produce a voltage of 2,400 volts instead of 6 if a 
 transformer intended to deliver 6 volts from a 120- 
 volt circuit was wrongly connected. 
 
 The results might very well then be dangerous. 
 All transformers are properly marked, however, 
 and such an error only occurs through ignorance or 
 carelessness. 
 
 The installation of these bell-ringing transformers 
 is simplicity itself ; they require no care after in- 
 stallation and have met with the approval of the 
 National Board of Fire Underwriters. 
 
 Combination Circuits. Circuits intended pri- 
 marily for electric bells or annunciators in houses 
 and apartments may often be also made to serve 
 for other electrical devices such as door openers, 
 house telephones, etc. This subsidiary apparatus 
 
76 
 
 ANNUNCIATORS AND ALARMS 
 
 may be installed with a little additional wiring or 
 perhaps will not need any other wires, as when 
 both the devices are not used at once. 
 
 Electrical door openers are great conveniences 
 and are practically indispensable where the outside 
 door is on another level to the location of the 
 dweller or where two or more families occupy the 
 same house. The device is simple, consisting of an 
 electrically released spring-plate against which the 
 lock bolt is normally held and a door opening spring. 
 
 When the door opener button is pressed, the 
 spring plate is released, releasing the lock bolt by 
 the same action. The door spring then forces the 
 door open enough to clear the opener plate, which 
 flies back into position when the button is released. 
 
 These door openers are made in several forms 
 for door frames, such as those on thin doors, iron 
 gates, for surface or rim locks, for thick doors, 
 sliding doors and any other regular type of door. 
 
 ‘The push button is the same as used for electric 
 bells and may be located wherever desired. The 
 pushes are wired in multiple as shown in Figs. 66 
 and 67, which are two circuits of a type of the 
 Western Electric interphone, a system of house 
 telephones supplied for houses and buildings- of 
 every size. Fig. 66 shows a circuit which provides 
 telephone service between the vestibule and the 
 apartments, the door opener wiring being clearly 
 indicated. In Fig. 67 the circuit provides a more 
 extensive service, enabling the janitor, the apart- 
 ments and the tradesmen to intercommunicate in 
 
FIG. 67 
 
78 
 
 ANNUNCIATORS AND ALARMS 
 
 the most desirable system. The door opener wiring 
 is also deafly shown. 
 
 The convenience of having telephone connection 
 in the house or hotel and its advantages over speak- 
 ing tubes are ’too well known to need extended 
 comment. Where electric bells have already been 
 installed it is quite feasible now to use the same 
 wires for telephones also. 
 
 Telephone sets especially designed for this serv- 
 ice are manufactured by the Western Electric Com- 
 pany in their interphone series. They are simple 
 and compact, and may be installed by anyone who 
 can put up an electric bell. 
 
 Fire Alarm Circuits. A fire alarm circuit suit- 
 able for factories, private plants or groups of 
 buildings is shown in Fig. 68. It is a series system, 
 with closed circuit, the gongs sounding whenever 
 the circuit is opened whether by the contact breaker 
 in the boxes or by the accidental breaking of a wire. 
 This insures that it remains in good working order, 
 as when any part of the circuit is opened, a warn- 
 ing tap is sounded on every bell or gong. 
 
 The boxes have contact breakers which send a 
 separate number of impulses for each box, thus an- 
 nouncing the box number on each gong. The boxes 
 and gongs may be located anywhere, as the system 
 is perfectly flexible. 
 
 The reference letters in the diagram are as fol- 
 lows: C indicates the gongs which are preferably 
 of the electro-mechanical type, a coiled spring pro- 
 
80 
 
 ANNUNCIATORS AND ALARMS 
 
 viding force for the blow, electricity being merely 
 used to release and retain the hammer or striker. 
 The alarm boxes are marked BB and the battery 
 which, is of the closed circuit type is marked D. 
 
 Interior Fire Alarm System. Another system 
 suitable more particularly for indoor operation is 
 illustrated m Fi'g. 69. Here the alarm is given by 
 breaking the glass front of an alarm box and re- 
 leasing or pressing an electrical contact. 
 
 The box sounded indicates by causing a drop to 
 fall on an annunciator and at the same time rings 
 an alarm bell. The latter are generally provided 
 with constant ring attachments, which keep the 
 bell sounding until shut off. 
 
 The annunciator shown in the diagram has 
 switches for controlling each individual bell circuit, 
 and also for control of the entire system. 
 
 There is no practical limit to the number of sta- 
 tions in this system, it being determined by the size 
 of the annunciator used or by other obvious factors. 
 
 The reference letters on the diagram are as fol- 
 lows : A, alarm bells which may be located where- 
 ever desired. B, break-glass alarm boxes also lo- 
 cated at convenient points. C, annunciator drops, 
 D, switches on annunciator which control each in- 
 dividual bell circuit, enabling any circuit to be cut 
 out, cut in or tested without disturbing any other 
 circuit. £ is a general alarm switch, causing all 
 bells to ring at once when it is operated. 
 
 The battery F varies with the number of bells and 
 
FIRE ALARM SYSTEMS 
 
 81 
 
 boxes and the length of line, from three cells up- 
 wards. A cut-out switch H is added to cut out 
 the entire system by opening the battery wire. 
 
 y ( 
 
 ri 
 
 D ( 
 
 i - f 
 
 J o 
 
 i 
 
 4>(k 
 
 c 
 
 ■<fc 
 
 >(S) 
 
 •fl 1, 1 
 
 L_ 
 
 f L 
 
 ~'0 — o 
 
 c 
 
 FIG. 69 
 
 The annunciator bell is at /, an auxiliary bell being 
 added in multiple with it when necessary. 
 
’ 3 f 
 
 9 
 
 9 
 
 
 0 ( 
 
 3 .( 
 
 3 < 
 
 
 FIG. 70 
 
 fiHMW 
 
FIRE ALARM SYSTEMS 
 
 83 
 
 Fire Alarm System for Considerable Areas. 
 
 Where the area is more extensive and the number 
 of stations considerable, the system illustrated in 
 Fig. 70 is very suitable. It consists of the requisite 
 number of break-glass boxes, bells and a more 
 elaborate annunciator system. In general details it 
 resembles the last system, but uses a relay to send 
 out the current for ringing the alarm bells. 
 
 When a box operates, the current impulses sent 
 on the line act on the relay instead of directly on 
 the bells. Each stroke of the relay closes a local 
 circuit which includes the bells and the battery. 
 
 This system does away .with large batteries and 
 is very enconomical of wire. The current needed 
 for the relay is very small, whereas in a direct sys- 
 tem of any size, the current and voltage to ring a 
 number of bells located at wide intervals would be 
 prohibitive. 
 
 The reference letters are as follows: AA are 
 the alarm bells, BB the break-glass alarm boxes, 
 C is the annunciator bell, D is the relay which re- 
 mains closed when an alarm comes in keeping the 
 bells constantly ringing until shut off. £ is a re- 
 sistance coil and F is the battery. 
 
 A system cut-out switch G and JJ switches on 
 the annunciator for controlling individual circuits 
 are also provided. HH are the annunciator drops 
 and K is a constant-ring switch which can also be 
 used for a general alarm to ring all the bells at 
 once. 
 

 
SELENIUM CELLS 
 
 THE 
 
 Construction, Care and Use of Selenium 
 Cells with Special Reference 
 to the Fritts Cell 
 
 By ' 
 
 Thomas W. Benson 
 
 The lack of definite information relative to the 
 construction of Selenium Cells has led the writer to 
 record the results of some of his experiments and 
 to fully describe the apparatus as developed by him. 
 
 Contents of Chapters 
 
 1. Selenium The Element 
 
 2. Consideration of Cell types and their 
 Characteristics; The Bildwell Cell; 
 The Ruhmer Cell; The Mercadier 
 Cell; The Bell and Taintor Cell; 
 The Gripenberg Cell 
 
 3. Construction of Fritts Selenium Cells 
 
 4. Testing and Maturing Selenium Cells 
 
 5. Applications of Selenium Cells 
 
 6. The Care of Selenium Cells 
 
 73 pages, 15 diagrams and 3 halftone page plates, 
 734 x 534 inches. Cloth, $1.50 
 
Everybody Wants This Book. 
 
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