Researchpaper Wireless Power Transmission via Solar Power Satellite

8/10/2019 Researchpaper Wireless Power Transmission via Solar Power Satellite

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Wireless Power Transmission ViaSolar Power Satellite

M.Muthupriya,B.E(EEE),

vivekanandha college of technology,for women, Namakkal,

Tamil nadu,India.

[email protected]

S.Vinothini, B.E(EEE),

vivekanandha college of technology,for women, Namakkal.

Tamil nadu,India.

[email protected]

ABSTRACTIn this paper, we present the concept of Solar Power Satellites -The solar cells in the satellite willconvert sunlight to electricity, which will changed to radio frequency energy, then beamed to a receiver site onearth and reconverted to electricity by using transmitting and receiving antenna with the technology of wirelesspower transmission (i.e., transmitting power as microwaves in order to reduce the transmission and distributionlosses). This concept is also known as Microwave Power Transmission. The advantages, disadvantages,biological impacts and applications of WPT are also presented.

Index TermsGrid, Microwaves, Microwave generator, Nikola Tesla, Rectenna, Solar Power Satellites (SPS),Transmitting antenna, Wireless Power transmission (WPT).

1 INTRODUCTIONThe Solar Power Satellite energy system is to

place giant satellites, covered with vast arrays of solarcells, in geosynchronous orbit 22,300 miles above theEarth's equator. Each satellite will be illuminated bysunlight 24 hours a day f or most of the year. Because ofthe 23" tilt of the axis, the satellites pass either above orbelow the Earths shadow. It is only during the equinox

period in the spring and f all that they will pass

through the shadow. They will be shadowed f or less than1% of the time during the year. The solar cells willconvert sunlight to electricity, which will then bechanged to radio-frequency energy by a transmittingantenna on the satellite and beamed to a receiver site onEarth. It will be reconverted to electricity by thereceiving antenna, and the power would then be routedinto our normal electric distribution network f or use hereon the Earth. One of the major issue in power system isthe losses occurs during the transmission andDistribution of electrical power. As the Demandincreases day by day, the power generation increases andthe power loss is also increased. The percentage of loss

of power during transmission and distribution isapproximated as 26%. The main reason f or power lossduring transmission and distribution is the resistanceof wires used f or grid. The ef f iciency of powertransmission can be improved to certain level by usinghigh strength composite over head conductors andunderground cables that use high temperature superconductor. But, the transmission is still inef f icient.

According to the World Resources Institute (WRI),Indias electricity grid has the highest transmission anddistribution losses in the world a whopping 27%.

Numbers published by various Indian governmentagencies. Put that number at 30%, 40% and greater than

40%. This is attributed to technical losses (gridsinef f iciencies) and thef t.

Any problem can be solved by state of -the-arttechnology. The above discussed problem can be solved bychoose an alternative option f or power transmissionwhich could provide much higher Eff iciency, lowtransmission cost and avoid power theft. MicrowavePower Transmission is one of the promisingTechnologiesand may be the righteous alternative f or eff icient powertransmission.

2 SEGMENTS OF SPS

The SPS is a gigantic satellite designed as an electricpower plant orbiting in the Geostationary Earth Orbit(GEO). It consists of mainly three segments; solar energycollector to convert the solar energy into DC (directcurrent) electricity, DC-to-microwave converter, andlarge antenna array to beam down the microwave powerto the ground. The f irst solar collector can be either

photovoltaic cells or solar thermal turbine. The secondDC-to-microwave converter of the SPS can be eithermicrowave tube system and/or semiconductor system. Itmay be their combination. The third segment is a

gigantic antenna array. An amplitude taper on thetransmitting antenna is adopted in order to increase thebeam collection eff iciency and to decrease sidelobe levelin almost all SPS design. A typical amplitude taper iscalled 10 dB Gaussian in which the power density in thecenter of the transmitting antenna is ten times largerthan that on the edge of the transmitting antenna.Power will be transmitted over a 1-1/4 mile rangeto a receiving antenna (rectenna) and then f ed into acommercial utility power grid. Table 1 showssome typical parameters of the transmittingantenna of the SPS The rectenna array, with a

typical radius of approximately 2 km, is an

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important element of the radio technology forwhich high efficiency is essential. The efficiencydepends on the input power, and the input-

power flux density is not constant over the entirerectenna site for the SPS system.

Table 1 Typical parameters of the transmitting antenna of the SPS

Model Old JAXAModel

JAXA1 model JAXA2 model NASA/DOEMODEL

Frequency 5.8 GHz 5.8 GHz 5.8 GHz 2.45 GHz

Diameter ofTransmitting antenna

2.6 km 1 km 1.93 km 1 km

Amplitude taper 10 dB Gaussian 10 dB Gaussian 10 dB Gaussian 10 Db Gaussian

Output power(beamed to earth)

1.3 GW 1.3 GW 1.3 GW 6.72 GW

Maximum powerDensity at center 63 mW/ cm^2 420 mW/cm^2 114 mW/cm^2 2.2 W/ cm^2Minimum powerDensity at center

6.3 mW/ cm^2 42 mW/ cm^2 11.4 mW/cm^2 0.22 W/ cm^2

Antenna spacing 0.75 0.75 0.75 0.75

Power per oneantenna(Number of elements)

Max. 0.95 W(3.54 billion)

Max. 6.1W(540 million)

Max. 1.7 W(1,950 million)

Max. 185 W(97 million)

Rectenna diameter 2.0 km 3.4 km 2.45 km 1 kmMaximum powerDensity

180 mW/cm^2 26 Mw/cm^2 100 mW/cm^2 23 mW/cm^2

Efficiency 96.5 % 86 % 87 % 89 %JAXA : Japan Aerospace Exploration Agency, NASA : National Aeronautics and SpaceAdministration, DOE : U.S. Department Of Energy.

3WIRELESS POWER TRANSMISSION

Fig .1 Block Diagram of WPT via SPS


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Nicola Tesla he is who invented radio and shown ushe is indeed the Father of Wireless. Nicola Tesla isthe one who f irst conceived the idea Wireless PowerTransmission and demonstrated the transmission ofelectrical energy without wires" that depends uponElectrical conductivity as early as 1891.COMPONENTS OF WPT SYSTEM

The Primary components of Wireless PowerTransmission are Microwave Generator, Transmittingantenna and Receiving antenna (Rectenna). Thecomponents are described in this chapter.

Microwave GeneratorThe microwave transmitting devices are

classif ied as Microwave Vacuum Tubes (magnetron,klystron, Travelling Wave Tube (WT), and MicrowavePower Module (MPM)) and Semiconductor Microwavetransmitters (GaAs MESFET, GaN pHEMT, SiC

MESFET, AlGaN/GaN HFET, and InGaAS). Magnetronis widely used f or experimentation of WPT. Themicrowave transmission of ten uses 2.45GHz or 5.8GHzof ISM band. The other choicesof frequencies are 8.5GHz 10 GHz and 35 GHz . The highest ef f iciency

over 90% is achieved at 2.45 GHz among all thef requencies .

Transmitting AntennaThe slotted wave guide antenna, microstrip patchantenna, and parabolic dish antenna are the most

popular type of transmitting antenna. The slottedwaveguide antenna is ideal f or powertransmission

because of its high aperture ef ficiency (> 95%) and highpower handling capability.Rectenna

The rectenna is a passive element consists of antenna,rectif ying circuit with a low pass f ilter between theantenna and rectif ying diode. The antenna used inrectenna may be dipole, Yagi Uda, microstrip or

parabolic dish antenna. The patch dipole antenna achievedthe highest eff iciency among the all. Schottky barrierdiodes (GaAs-W, Si, and GaAs) are usually used in therectif ying circuit due to the f aster reverse recovery timeand much lower f orward voltage drop and good RFcharacteristics.

OPERATION

Fig.2 Functional Block Diagram of Wireless Power Transmission System

In the transmission side , the microwave power sourcegenerates microwave power and the output power is

controlled by electronic control circuits.The waveguide

circulator which protects the microwave source f romref lected power is connected with the microwave power

source through the coax- waveguide adaptor.The tuner


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matches the impedence between the transmitting antennaand the microwave source .The transmitting antennaradiates the power unif ormly through f ree space to therectenna impedance matching is the practice ofdesigning the input impedance electrical load outputimpedance to maximize the power transf eror minimizeref lections f rom the load. In the case of a complex source

impedance ZS and load impedance ZL, maximum powertransfer is obtained when

(1)

Source and load circuit impedance

where * indicates the complex conjugate. Filters aref requently used to achieve impedance matching intelecommunications and radio engineering.The powerreceived at the coax wave guide adaptor is transmittedto the load.

4CASE STUDIES

The SPS space segment consists of solar cells,RF circuits and antennas, a sensor f or the pilot signal,and a control unit f or beamf orming and retrodirectivity,and circuit power supply. A 1 GW SPS power plant hasthe f ollowing typical dimensions. The area of a solar cell

panel is approximately 10 km2 (2km x 5km) f orproduction of 2GW DC power with the solar cellconversion eff iciency of 15%. The transmitting antennaarray will typically be 1km in diameter. The aperturedistribution of the transmitting antenna is determinedsuch as unif orm prof ile or Gaussian prof ile based on therequired beam collecting eff iciency. Assuming an antennaelement spacing o 0.75 =3.8cm at 5.8GHz, a radiator

weight density of 2.69g/cc, and 160 antenna elements,one could get 9.6 kg/ m2 with this design approach.

Ground SegmentA typical rectenna site is 4 km in diameter f or a

transmitting antenna diameter of 1km operating at 5.8GHz. Under these conditions, 93% of the transmitted

power is collected. The peak microwave power density atthe rectenna site is 27 mW/cm2 if a Gaussian power

prof ile is assumed f or the transmitter. The beamintensity pattern has a non-unif orm distribution with ahigher intensity in the center of the rectenna and alower intensity at its periphery as shown in Fig. 2. The

saf ety requirement f or the microwave power density f or

humans is set to 1mW/cm2 in most countries, which issatisfied at theperiphery.

Fig. 3 Typical power density at a rectenna site

(1km TX antenna with 10dB Gaussian powerdistribution)

5ADVANTAGES

Wireless Power Transmission system wouldcompletely eliminates the existing high-tension powertransmission line cables, towers and sub stations betweenthe generating station and consumers and f acilitates theinterconnection of electrical generation plants on a

global scale. It has more f reedom of choice of bothreceiver and transmitters. Even mobile transmitters andreceivers can be chosen f or the WPT system. The cost oftransmission and distribution become less and the cost of

electrical energy f or the consumer also would be reduced.The power could be transmitted to the places where thewired transmission is not possible. Loss of transmissionis negligible level in the Wireless Power Transmission;therefore, the ef f iciency of this method is very muchhigher than the wired transmission. Power is available atthe rectenna as long as the WPT is operating. The power

f ailure due to short circuit and f ault on cables wouldnever exist in the transmission and power theft would benot possible at all. The development of Solar PowerSatellites gain the benef its of abundant, low-cost,nonpolluting energy. The great advantage of placingthe solar cells in space instead of on the ground is that

the energy is available 24 hours a day, and the totalsolar energy available to the satellite is between f ourand f ive times more than is available anywhere on Earthand 15 times more than the average location.

6 DISADVANTAGES

The Capital Cost f or practical implementation ofWPT seems to be very high and the other disadvantageof the concept is interf erence of microwave with presentcommunication systems. Heat reduction is mostimportant problem in space. All lost power converts toheat. We need special heat reduction system in space. Ifwe use high eff icient microwave transmitters, we can

reduce weight of heat reduction system. We should aim


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f or over 80 % ef f iciency f or the microwave transmitter,which must include all loss in phase shif ters, isolators,antennas, power circuits.

7 APPLICATIONS

The SPS is expected to realize around 2030.

Before the realization of the SPS, we can consider theother application of the WPT. In resent years, mobiledevices advance quickly and require decreasing powerconsumption. It means that we can use the diff usedweak microwave power as a power source of the mobiledevices with low power consumption such as RF-ID. TheRF-ID is a radio IC-tug with wireless powertransmission and wireless information. This is a newWPT application like broadcasting.

8 BIOLOGICAL IMPACTS

Common belief s f ear the ef f ect of microwaveradiation. But the studies in this domain repeatedly

proves that the microwave radiation level would be neverhigher than the dose received while opening themicrowave oven door, meaning it is slightly higher thanthe emissions created by cellular telephones Cellulartelephones operate with power densities at or below the

ANSI/IEEE exposure standards . Thus public exposure toWPT f ields would also be below existing saf ety

guidelines. However Tests have also shown that theenergy density in the radio-f requency beam can belimited to saf e levels f or all life f orms.

9 CONCLUSION

The concept of Microwave Power transmission(MPT) andWireless Power Transmission system is

presented. The technological developments in WirelessPower Transmission (WPT), the advantages,disadvantages, biological impacts and applications ofWPT are also discussed. This concept of f ers greater

possibilities f or transmitting power with negligiblelosses and ease of transmission. Furthermore, it appearsalmost certain that there will be a shif t towardsrenewable sources and that solar will be a majorcontributor.It is asserted that if the energy system ofthe world is to work f or all its people and be adequatelyrobust, there should be several options to develop in the

pursuit of and expanded supply. While the option ofSpace Solar Power may seem futuristic at present, it istechnologically feasible and, given appropriateconditions, can become economically v i a b l e .

REFERENCE

[1] Nikola Tesla, The Transmission of ElectricalEnergy Without Wires as a Means f or FurtheringPeace,Electrical World and Engineer. Jan. 7, p. 21, 1905.[2] Point-To-Point Wireless Power Transportation inReunion Island 48th International AstronauticalCongress, Turin, Italy, 6-10 October 1997 - IAF-97-

R.4.08 J. D. Lan Sun Luk, A. Celeste, P. Romanacce, L.

Chane Kuang Sang, J. C. Gatina - University of LaRunion - Faculty of Science and Technology.[3] Brown, W. C., Beamed microwave power transmissionand its application to space, IEEETrans. Microwave Theory Tech., vol. 40, no. 6, 1992,

pp.1239-1250.[4] Supporting Document f or the URSI White Paper on

Solar Power Satellite Systems ,2006.[5] McSpadden, J. O. and J. C. Mankins, Space SolarPower Programs and Microwave Wireless.[6] Glaser, P. E., Power f rom the Sun, Science, No.162,1968, pp.857-886.Power Transmission Technology, IEEE

Microwave Magazine, December 2002, pp.46-57.[7] Matsumoto, H., Research on Solar Power Stationand Microwave Power Transmission in Japan : Reviewand Perspectives, IEEE Microwave Magazine, December2002, pp.36-45.[8] Sivan, L., Microwave Tube Transmitters MicrowaveTechnology Series 9-, Chapman &Hall, 1994.[9] Hatsuda, T., K. Ueno, M. Inoue, Solar powersatellite interf erence assessment, IEEE Microwave

Magazine, Vol. 3, No. 4, Dec. 2002, pp.65-70.[10] Little, F. E., S. J. Kokel, C. T. Rodenbeck, K. Chang,G. D., Arndt, and P. H. Ngo,Development ofRetrodirective Control Transmitter f or Wireless PowerTransmission, The Radio Science Bulletin, No.311, 2004,

pp. 38-46.[11] Gutmann, R. J. and R. B. Gworek, Yagi-Uda

Receiving Elements in Microwave PoweTransmissionSystem Rectennas, Journal of Microwave Power, Vol.14,

No.4, 1979, pp.313-320.


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Researchpaper Wireless Power Transmission via Solar Power Satellite

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