GENERATION OF WIND POWER USING HELICAL STRUCTURED BLADES BY THE CONCEPT OF “WIND TREE


NOVATEUR PUBLICATIONS  
International Journal of Research Publications in Engineering and Technology [IJRPET]  

ISSN: 2454-7875 
VOLUME 3, ISSUE 3, March-2017 

116 | P a g e  
 

GENERATION OF WIND POWER USING HELICAL STRUCTURED BLADES 

BY THE CONCEPT OF “WIND TREE”
VIVEK R. RAUT 

Department of Electrical, DBACER, Nagpur, India, vivekrautphw@gmail.com 

 

SAYLI S. DHANDE 

Department of Electrical, DBACER,  Nagpur, India, sayli.dhande30@gmail.com 

 

ROHIT H. JAMBHULKAR 

Department of Electrical, DBACER, Nagpur, India, rohitjam76@gmail.com

 

ABSTRACT: 

  Power requirements of the world are ever 

increasing. In order to fulfill these, it is essential to 

discover new energy sources or rather improvise the 

existing techniques for extracting maximum energy. 

The Wind tree is a concept that uses a helical blade 

(VAWT) for generation of electric power. The helical 

blade is Omni-directional which means it is capable of 

rotating irrespective of the wind flow. The project aims 

at generating electricity by means of small wafts of air 

that circulate around the buildings and streets. Despite 

of the wind being fluctuating in nature; the turbine is 

capable of generating electricity, as a small waft of air 

is sufficient to rotate this turbine. 

KEYWORDS: Wind turbine, Helical Blades, Omni-

directional, VAWT, Generation. 

 

I.  INTRODUCTION: 
 Wind is considered as the fastest growing clean 

energy source which is readily available. The concept of 

wind tree is unique in itself the turbines are sculpted in the 

form of an artificial tree. It aims at utilizing the low winds 

that circulate around buildings and streets. The artificial 

Aeroleafs serving as microturbines spin on a vertical axis 

and is capable of harnessing more gentle winds. The 

turbine being small and light in weight are set in motion by 

winds as light as 4.4 miles/hr.  The Betz’s law calculates 

the maximum power that can be extracted from the wind, 

independent of the design of a wind turbine. According to 

Betz’s law, no turbine can capture more than 59.3% of the 

kinetic energy in wind. Bets law explains that power 

extracted from wind energy is directly proportional to the 

cube of wind velocity. 

 
Figure 1.   Global Wind Data 

 BETZ’S LAW: 

Before you begin to format your paper, According 

to Betz's law, no turbine can capture more than 16/27 

(59.3%) of the kinetic energy in wind. The factor 16/27 

(0.593) is known as Betz's coefficient. Practical utility-scale 

wind turbines achieve at peak 75% to 80% of the Betz 

limit. The Betz limit is based on an open disk actuator. If a 

diffuser is used to collect additional wind flow and direct it 

through the turbine, more energy can be extracted, but the 

limit still applies to the cross-section of the entire 

structure. The power of the wind is proportional to air 

density, area of the segment of wind being considered, and 

the natural wind speed. The relationships between the 

above variables are provided in equation, 

Pw = ½ρAu3. 

 

 
Figure 2.  Betz’s law 

 

II. BACKGROUND  STUDY: 
The idea of creating an electrical power generating 

system in the form of a tree, with each leaf as an actual 

mini wind turbine. Capturing low wind speeds and 

turbulence is at the crux of this novel approach which can 

deliver power and autonomy simply through a 

proliferation of leaves. It is the first human-scale 

biomimetic wind turbine capable of recreating a 

sympathetic bond between the consumer and their means 

of power generation. 

 

mailto:vivekrautphw@gmail.com
mailto:sayli.dhande30@gmail.com
mailto:rohitjam76@gmail.com


NOVATEUR PUBLICATIONS  
International Journal of Research Publications in Engineering and Technology [IJRPET]  

ISSN: 2454-7875 
VOLUME 3, ISSUE 3, March-2017 

117 | P a g e  
 

III.   SYSTEM BLOCK DIAGRAM: 

:

 
 

IV.  HELICAL BLADES: 

 
Figure 3. Helical blades views 

 

V.  DC GENERATOR: 

 

 
Figure 4.  DC Series Generator 

 

VI. CONTROL UNIT: 

Control unit helps to store electrical energy by 

charging the battery as well as supplying power to load 

using  the wind energy thus resulting in maximum wind 

power utilization during charging mode. Control unit 

checks for the main generated voltage and the battery 

voltage. If generation is ON, supply is directed to battery 

and it is charged. If  generation  is OFF, then battery is 

charged using wind tree In case of no main supply, load is 

switched ON, which uses  the voltage from battery. The 

battery voltage is checked continuously and shown in 

display. If it goes less than a 8V battery indication is shown 

and the load is turned OFF. The control circuits is a 

microcontroller kit programmed in embedded C. The 

control circuit consists of LDR, so that the lighting load will 

be switched OFF during day and the LDR is connected to 

relay to trip the load from battery. 

 
Figure 5. Control Circuit Pin Diagram 

 

VII. SYSTEM WORKING: 

The design of wind tree is capable of extracting 

maximum kinetic energy from the wind owing to the 

structured blade design.  The helical structured blades are 

used for this purpose wherein the blades are positioned 

vertically or transverse to the axis of rotation. These 

turbines are independent of the direction of fluid flow, thus 

making it possible for them to rotate even at low velocity 

of air. The helical structured blade is considered the most 

efficient owing to its unique design and a lighter weight 

enabling a smooth flow of air throughout. The unique 

blade design rotates the turbine even by small wafts of air. 

 
A gearbox is attached between the blade and 

generator in order to increase the number of rotations and 

enables the system to work smoothly. A coreless DC 

generator having rated output of 3-48V and maximum 

speed of 5000 rpm is used that has good efficiency even at 

low rotations. A buck boost converter is connected to the 

DC generator which helps in providing a regulated DC 

output voltage from either and AC or a DC output voltage.  

A battery is used to store the generated power. A charge 

controller is connected to the battery in order to protect it 

from over charging and to stop the reverse flow of current.  

A suitable load is attached to the battery in case of 

overcharging.  

 
Specifications: 
Type: Coreless 

Rated Output Voltage: 3V-
48V DC. 

Maximum Speed: 5000 rpm. 
Rated Torque: 2.1 N-m. 

Noiseless. 
 



NOVATEUR PUBLICATIONS  
International Journal of Research Publications in Engineering and Technology [IJRPET]  

ISSN: 2454-7875 
VOLUME 3, ISSUE 3, March-2017 

118 | P a g e  
 

VIII. PROPOSED DESIGN OF SYSTEM: 

 

 

 

 

 

 

 

 

 

 

 
 

 
 

IX. SYSTEM PROTOTYPE: 

 
 

 
 

ACKNOWLEDGMENT: 

We would like to take this opportunity to 

acknowledge the invaluable guidance, enormous 

assistance and excellent co-operation extended to us from 

each and every corner for proceeding smoothly in this 

project. We express our most sincere gratitude to our 

guide and Project Coordinator Prof. S. A. Kale and co-

guide Mr. A. V. Kakde for being our constant source of 

help and inspiration throughout the work.. We are grateful 

to Dr. B. S. Umre for his suggestions. And all faculties who 

have helped us throughout. 

 

CONCLUSIONS: 

Hence we have come to the conclusion that there 

is still a lot of scope of energy production with the help of 

wind turbines. With better design and increasing the 

number of turbines along with some advanced technology 

it is possible to implement this project on a large scale. It 

would not only solve the problem of energy crisis to a great 

extent but would also give a landscape view to the city. We 

highly recommend these wind trees alongside the streets 

in order to save electricity required for the street load. By 

further increasing the height and the number of turbines, it 

is possible to light up an entire building with the help of 

these wind trees. Even though the wind being fluctuating 

in nature, it is constantly available 24*7 which makes it a 

more reliable option than the solar panels. The test result 

obtained ranged between 12-23V, and can be improved by 

précised design of areoleafs. 

 

REFERENCES: 

1) A Simulation Study OnAirfoilsUsing VAWT Design for 
Low Wind Speed Application. 

2) Peter L Franenkel: “APPLICATIONS FOR WINDS 
SYSTEMS IN DEVELOPING COUNTRIES. 1996” 

 



NOVATEUR PUBLICATIONS  
International Journal of Research Publications in Engineering and Technology [IJRPET]  

ISSN: 2454-7875 
VOLUME 3, ISSUE 3, March-2017 

119 | P a g e  
 

3) Sathyanarayana, R;Muthamizh, S ; Giriramprasath, C,; 
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Generation. Y.C. Fong* J. Hu K.W.E. Cheng  Power 

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Engineering , The Hong Kong Polytechnic University/ 

Hung Hom, Kowloon, Hong Kong. 

 

 

 

 

 

 

 

 

 

 

 

  

 

 

     

http://www.eece/

	I.  INTRODUCTION:
	II. BACKGROUND  STUDY:
	ACKNOWLEDGMENT:
	REFERENCES: