Wirelesspowertransmission 100831100802-phpapp01

Wireless Power Transmission
Presented by
Rakesh K.K.
4NM07EC080
Department of Electronics and Communication
Engineering
NMAM Institute of Technology, Nitte

Overview
 What is wireless power
transmission(WPT)?
 Why is WPT?
 History of WPT
 Types of WPT
◦ Techniques to transfer energy wirelessly
 Advantages and disadvantages
 Applications
 Conclusion
 References
2/18/2015 Wireless Power Transmission 2

What is WPT?
 The transmission of energy from one
place to another without using wires
 Conventional energy transfer is using
wires
 But, the wireless transmission is made
possible by using various technologies

Why not wires?
 As per studies, most electrical energy
transfer is through wires.
 Most of the energy loss is during
transmission
• On an average, more than 30%
• In India, it exceeds 40%

Why WPT?
 Reliable
 Efficient
 Fast
 Low maintenance cost
 Can be used for short-range or
long-range.

History
 Nikola Tesla in late 1890s
 Pioneer of induction techniques
 His vision for “World Wireless System”
 The 187 feet tall tower to broadcast
energy
 All people can have access to free
energy
 Due to shortage of funds, tower did not
operate

History (contd…)
 Tesla was able to transfer energy from
one coil to another coil
 He managed to light 200 lamps from a
distance of 40km
 The idea of Tesla is taken in to
research after 100 years by a team led
by Marin Soljačić from MIT. The
project is named as ‘WiTricity’.

Energy Coupling
 The transfer of energy
◦ Magnetic coupling
◦ Inductive coupling
 Simplest Wireless Energy coupling is
a transformer

Types and Technologies of
WPT
 Near-field techniques
Inductive Coupling
Resonant Inductive Coupling
Air Ionization
 Far-field techniques
Microwave Power Transmission (MPT)
LASER power transmission

Inductive coupling
 Primary and secondary coils are not
connected with wires.
 Energy transfer is due to Mutual
Induction

Inductive coupling (contd…)
 Transformer is also an example
 Energy transfer devices are usually air-
cored
 Wireless Charging Pad(WCP),electric
brushes are some examples
 On a WCP, the devices are to be kept,
battery will be automatically charged.

Inductive coupling(contd…)
 Electric brush also charges using
inductive coupling
 The charging pad (primary coil) and
the device(secondary coil) have to be
kept very near to each other
 It is preferred because it is
comfortable.
 Less use of wires
 Shock proof

Resonance Inductive
Coupling(RIC)
 Combination of inductive coupling and
resonance
 Resonance makes two objects interact
very strongly
 Inductance induces current

How resonance in RIC?
 Coil provides the inductance
 Capacitor is connected parallel to the
coil
 Energy will be shifting back and forth
between magnetic field surrounding
the coil and electric field around the
capacitor
 Radiation loss will be negligible

Block diagram of RIC

An example

WiTricity
 Based on RIC
 Led by MIT’s Marin Soljačić
 Energy transfer wirelessly for a
distance just more than 2m.
 Coils were in helical shape
 No capacitor was used
 Efficiency achieved was around 40%

WiTricity (contd…)

WiTricity… Some statistics
 Used frequencies are
1MHz and 10MHz
 At 1Mhz, field strengths
were safe for human
 At 10MHz, Field
strengths were more than
ICNIRP standards

WiTricity now…
 No more helical coils
 Companies like Intel are also working
on devices that make use of RIC
 Researches for decreasing the field
strength
 Researches to increase the range

RIC vs. inductive coupling
 RIC is highly efficient
 RIC has much greater range than
inductive coupling
 RIC is directional when compared to
inductive coupling
 RIC can be one-to-many. But usually
inductive coupling is one-to-one
 Devices using RIC technique are
highly portable

Air Ionization
 Toughest technique
under near-field energy
transfer techniques
 Air ionizes only when
there is a high field
 Needed field is
2.11MV/m
 Natural example:
Lightening
 Not feasible for practical
implementation

Advantages of near-field
techniques
 No wires
 No e-waste
 Need for battery is
eliminated
 Efficient energy
transfer using RIC
 Harmless, if field
strengths under
safety levels
 Maintenance cost
is less

Disadvantages
 Distance constraint
 Field strengths have to be under
safety levels
 Initial cost is high
 In RIC, tuning is difficult
 High frequency signals must be the
supply
 Air ionization technique is not feasible

Far-field energy transfer
Radiative
Needs line-of-sight
LASER or microwave
Aims at high power transfer
Tesla’s tower was built for this

Microwave Power
Transfer(MPT)
 Transfers high power from one place
to another. Two places being in line of
sight usually
 Steps:
◦ Electrical energy to microwave energy
◦ Capturing microwaves using rectenna
◦ Microwave energy to electrical energy

MP T (contd…)
 AC can not be directly converted to
microwave energy
 AC is converted to DC first
 DC is converted to microwaves using
magnetron
 Transmitted waves are received at
rectenna which rectifies, gives DC as
the output
 DC is converted back to AC

LASER transmission
 LASER is highly directional, coherent
 Not dispersed for very long
 But, gets attenuated when it
propagates through atmosphere
 Simple receiver
◦ Photovoltaic cell
 Cost-efficient

Solar Power Satellites (SPS)
 To provide energy to earth’s
increasing energy need
 To efficiently make use of
renewable energy i.e., solar energy
 SPS are placed in geostationary
orbits

SPS (contd…)
 Solar energy is captured using
photocells
 Each SPS may have 400 million
photocells
 Transmitted to earth in the form of
microwaves/LASER
 Using rectenna/photovoltaic cell, the
energy is converted to electrical
energy
 Efficiency exceeds 95% if microwave2/18/2015 Wireless Power Transmission 30

Rectenna
 Stands for rectifying antenna
 Consists of mesh of dipoles and
diodes
 Converts microwave to its DC
equivalent
 Usually multi-element phased array

Rectenna in US
 Rectenna in US receives 5000MW of
power from SPS
 It is about one and a half mile long

Other projects
 Alaska’21
 Grand Bassin
 Hawaii

LASER vs. MPT
 When LASER is used, the antenna
sizes can be much smaller
 Microwaves can face interference (two
frequencies can be used for WPT are
2.45GHz and 5.4GHz)
 LASER has high attenuation loss and
also it gets diffracted by atmospheric
particles easily

Advantages of far-field energy
transfer
 Efficient
 Easy
 Need for grids, substations etc are
eliminated
 Low maintenance cost
 More effective when the transmitting
and receiving points are along a line-
of-sight
 Can reach the places which are
remote 2/18/2015 Wireless Power Transmission 35

Disadvantages of far-field energy
trasnfer
 Radiative
 Needs line-of-sight
 Initial cost is high
 When LASERs are used,
◦ conversion is inefficient
◦ Absorption loss is high
 When microwaves are used,
◦ interference may arise
◦ FRIED BIRD effect

Applications
 Near-field energy transfer
◦ Electric automobile charging
 Static and moving
◦ Consumer electronics
◦ Industrial purposes
 Harsh environment
 Far-field energy transfer
◦ Solar Power Satellites
◦ Energy to remote areas
◦ Can broadcast energy globally (in future)

Conclusion
 Transmission without wires- a reality
 Efficient
 Low maintenance cost. But, high initial cost
 Better than conventional wired transfer
 Energy crisis can be decreased
 Low loss
 In near future, world will be completely
wireless

References
 S. Sheik Mohammed, K. Ramasamy, T. Shanmuganantham,”
Wireless power transmission – a next generation power
transmission system”, International Journal of Computer
Applications (0975 – 8887) (Volume 1 – No. 13)
 Peter Vaessen,” Wireless Power Transmission”, Leonardo
Energy, September 2009
 C.C. Leung, T.P. Chan, K.C. Lit, K.W. Tam and Lee Yi Chow,
“Wireless Power Transmission and Charging Pad”
 David Schneider, “Electrons unplugged”, IEEE Spectrum,
May 2010
 Shahrzad Jalali Mazlouman, Alireza Mahanfar, Bozena
Kaminska, “Mid-range Wireless Energy Transfer Using
Inductive Resonance for Wireless Sensors”
 Chunbo Zhu, Kai Liu, Chunlai Yu, Rui Ma, Hexiao Cheng,
“Simulation and Experimental Analysis on Wireless Energy
Transfer Based on Magnetic Resonances”, IEEE Vehicle
Power and Propulsion Conference (VPPC), September 3-5,
2008

References(contd…)
 André Kurs, Aristeidis Karalis, Robert Moffatt, J.
D. Joannopoulos, Peter Fisher and Marin
Soljačić, “Wireless Power Transfer via Strongly
Coupled Magnetic Resonances”, Science, June
2007
 T. R. Robinson, T. K. Yeoman and R. S. Dhillon,
“Environmental impact of high power density
microwave beams on different atmospheric
layers”,
 White Paper on Solar Power Satellite (SPS)
Systems, URSI, September 2006
 Richard M. Dickinson, and Jerry Grey, “Lasers
for Wireless Power Transmission”
 S.S. Ahmed, T.W. Yeong and H.B. Ahmad,
“Wireless power transmission and its annexure to
the grid system” 2/18/2015 Wireless Power Transmission 40

THANK YOU!

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