1. STAIR STEP POWER GENERATION
Project Coordinator
Asst. Prof. Zahid Khan
Project Guide
Asst. Prof. Gunjan Yadav
Presented by
Vivek Mishra
Shivendra Pratap Singh
Ravi Pratap Singh
Vikrant Pratap Singh
Sonu Gupta
Akanksha Gupta
INSTITUTE OF TECHNOLOGY AND MANAGEMENT
2. BACKGROUND
In present days , the energy is vital issue of social
society. Energy is major input in all the sectors to
improve economy of country. There are many
issues due to which ongoing energy crisis have
engulf the country some important issues are given
below.
Rapid population growth.
Change of living standards of human beings.
Mismanagement.
Lack of awareness of emerging energy generation
techniques.
3. INTRODUCTION
For an alternative method to generate electricity,
there are number of methods by which electricity
can be produced, out of such methods , STAIR
STEP ENERGY GENERATION can be an effective
method to generate electricity.
4. PRINCIPLE
This setup works on the principle of obtaining the
sufficient pressure energy which can rotate the
dynamo, by converting the reciprocating motion into
rotary one. As this pressure energy rotates the
dynamo current is generated which is finally stored
in the provided battery.
5. PRINCIPLE
The amount of final rotation of dynamo depends upon the
weight of the man stepping onto it. Heavier will be the
weight larger will be the amount of energy obtained.
As stated above the dynamo works according to Faraday’s
Theory that whenever a conductor is placed in a varying
magnetic field electro motive force is induced which is
called ‘induced EMF’, If the conductor circuit is closed
current is also induced which is called “induced current”.
11. APPLICATION
Traffic Lights.
Railway LED signal and display boards.
Air circulation system in rooms.
Security Alarms
Door bells
Charging batteries.
12. ADVANTAGES
Easy construction and installation.
Energy can be stored and regulated.
Replacement of polluting resources.
Ideal non conventional energy resource.
No need of extra energy for functioning.
Independent of weather, day or night conditions.
Does not require extra space for installation.
A multi purpose aspect.
13. FUTURE ASPECTS
Can be used in speed breakers.
Can be adopted in railway projects.
Can be adopted in over crowded areas.
Can be adopted in LED traffic signals.
14. CONCLUSION
A very promising technology to provide efficient
solution of various problems.
A boon for techno field for saving energy.
Future creation of new urban landscape , athletic
fields and other
Harnessing human locomotion for electricity.
Ecofriendly approach.
15. ACKNOWLEDGEMENT
We owe a debt of gratitude to respected
“Asst. Prof. Gunjan Yadav Sir” for the vision and
foresight which inspired us to conceive this Project.
We are greatly indebted to respected “Asst.
Prof. Zahid Khan” for inspiring and motivating us for
this project.
It is also our duty to record our thankfulness
to honorable “Dr. P.N. Singh Sir” (H.O.D., department
of mechanical engineering) for his consistent support.
Finally we take this opportunity to
acknowledge the help of whole mechanical engineering
department.
16. REFERENCE
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H. Kulah and K. Najafi, "An electromagnetic micro power generator for
low-frequency environmental vibrations," 17th IEEE
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S. Roundy and P.K. Wright, "A piezoelectric vibration basedgenerator for
wireless electronics," Smart Materials and Structures,vol. 13, pp. 1131-
1142, 2004
H.A. Sodano, D.J. Inman, and G. Park, "A review of power harvesting
from vibration using piezoelectric materials," The Shockand Vibration
Digest, vol. 36, n. 3, pp. 197-205, 2004
D.M. Rowe, "Thermoelectrics, an environmentally-friendly source
of electrical power," Renewable Energy, vol. 16, pp. 1251-1256, 1999.
W. Sun, N.P. Kherani, K.D. Hirschman, L.L. Gadeken, and P.M.Fauchet,
"A three-dimensional porous silicon p-n diode for betavoltaics and
photovoltaics," Advanced Materials, vol. 17