State of Art of Solar Photovoltaic Technology
Hindawi Publishing Corporation
Conference Papers in Energy
Volume2013,Article ID764132,9pages
https://www.sodocs.net/doc/337067284.html,/10.1155/2013/764132
Conference Paper
State of Art of Solar Photovoltaic Technology
Utpal Gangopadhyay,Sukhendu Jana,and Sayan Das
Meghnad Saha Institute of Technology,Techno India Group,Kolkata700150,India
Correspondence should be addressed to Utpal Gangopadhyay;utpal ganguly@https://www.sodocs.net/doc/337067284.html,
Received2January2013;Accepted30April2013
Academic Editors:P.Agarwal,B.Bhattacharya,and U.P.Singh
This Conference Paper is based on a presentation given by Sukhendu Jana at“International Conference on Solar Energy Photovoltaics”held from19December2012to21December2012in Bhubaneswar,India.
Copyright?2013Utpal Gangopadhyay et al.This is an open access article distributed under the Creative Commons Attribution License,which permits unrestricted use,distribution,and reproduction in any medium,provided the original work is properly cited.
Solar electricity is more expensive than that produced by traditional sources.But over the past two decades,the cost gap has been closing.Solar photovoltaic(SPV)technology has emerged as a useful power source of applications such as lightning,meeting the electricity needs of villages,hospitals,telecommunications,and houses.The long and increasing dominance of crystalline silicon in photovoltaic(PV)market is perhaps surprising given the wide variety of materials capable of producing the photovoltaic effect.
PV based on silicon wafers has captured more than90%market share because it is more reliable and generally more efficient than competing technologies.The crystalline silicon PV is reliable as far as long term stability in real field but it is not economically viable due to starting material silicon itself costly.But still,research continues on developing a diverse set of alternative photovoltaic technology.Now PV technology is being increasingly recognized as a part of the solution to the growing energy challenge and an essential component of future global energy production.In this paper,we give a brief review about PV technology particularly crystalline silicon PV including the world and Indian PV scenarios.
1.Introduction
Solar energy is the most readily available and free source of energy since prehistoric times although it is used in most primitive way.Solar energy can be used directly for heating and lighting home and buildings,for generating electricity, cooking food,hot-water heating,solar cooling,drying mate-rials,and a variety of commercial and industrial uses[1–3].
Solar energy can be utilized through two different routes, solar thermal routes and solar photovoltaic routes[4,5].Solar energy can be converted into thermal energy with the help of solar collectors and receivers known as solar-thermal devices. PV-created direct current(DC)electricity that can be used as such is converted to alternating current(AC)or stored for later use.This type of solar electricity is more expensive than that produced by traditional sources.But over the past two decades,the cost gap has been closing.Solar photovoltaic (SPV)technology has emerged as a useful power source of applications such as lightning,meeting the electricity needs of villages,hospitals,telecommunications,and houses.
The long and increasing dominance of crystalline silicon in photovoltaic(PV)market is perhaps surprising given the wide variety of materials capable of producing the photovoltaic effect.PV based on silicon wafers has captured more than90%market share because it is more reliable and generally more efficient than competing technologies[6].But it is not economically viable due to starting material silicon itself costly.Therefore,research continues on developing a diverse set of alternative photovoltaic technology.
Now PV technology is being increasingly recognized as a part of the solution to the growing energy challenge and an essential component of future global energy production.In this paper,we give a brief review about particularly crystalline silicon PV technology including the world and Indian PV scenarios.
2.Photovoltaic Technologies
The early dominance of silicon in the laboratory has extended to the market for commercial modules.Crystalline silicon
100
2030405060708090100199719981999200020012002200320042005200620072008200920102011
T o t a l p r o d u c t i o n (M W p ) (%)
Y ear
Row
Japan and Taiwan Japan
US Europe
Figure 1:PV cells/modules production by region 1997–2011.
designs have never accounted for less than 80%of the market for commercial modules and nearly 15–18%of the market was not crystalline silicon.It was based on amorphous silicon-a PV technology that is almost exclusively used for consumer electronics such as watches and calculators.If we were to exclude electronics and define the market as electricity deliv-ery system of 1kW or more,current production is dominated by single-crystal and polycrystalline silicon modules,which represent 94%of the market.There are a wide range of PV cell technologies on the market today,using different types of materials,and an even larger number will be available in the future.PV cell technologies are usually classified into three generations,depending on the basic material used and the level of commercial maturity [7].
(i)First-generation PV systems (fully commercial)use the wafer-based crystalline silicon (c-Si)technology,either single crystalline (sc-Si)or multicrystalline (mc-Si).(ii)Second-generation PV systems (early market deploy-ment)are based on thin-film PV technologies and generally include three main families:(1)amor-phous (a-Si)and micromorph silicon (a-Si/μc-Si);(2)cadmium telluride (CdTe);and (3)copper indium selenide (CIS)and copper indium-gallium diselenide (CIGS).(iii)Third-generation PV systems include technologies,
such as concentrating PV (CPV)and organic PV cells that are still under demonstration or have not yet been widely commercialized,as well as novel concepts under https://www.sodocs.net/doc/337067284.html,mercial production of c-Si modules began in 1963when Sharp Corporation of Japan started producing com-mercial PV modules and installed a 242Watt (W)PV module on a lighthouse,the world’s largest commercial PV installa-tion at the time (M.A.Green 2001).Total PV cells/modules production by region 2007–2011(data:Navigant consult-ing graph:PSE AG 2012)is shown in Figure 1.It has been observed that Japan attributed to increase their PV cells/modules production capacity from 1997to 2004and then drastically reduced their production capacity after 2004.Same trend was observed in PV cells/module production in Europe also but up to year 2008,and then they reduced their production capacity.On the other hand in year 1997,PV cells/module production capacity of US was the highest,and after then they reduced their production capacity every year.Whereas PV cells/modules production scenarios of China were just the reverse compared to US.Given the vast potential of photovoltaic technology,worldwide production of terrestrial solar cell modules has been rapid over last several years,with China recently taking the lead in total production volume as shown in Figure 1.Another interesting picture related to the global cumulative PV installation until 2011was noticed as shown Figure 2.It was observed that still Germany including other European country contributed to major role towards the global cumulative PV installation until 2011,that is,70%of global PV installation.So PV installation market in Europe is too much promising till now compared to other countries.
Figure 3shows the PV production development by tech-nology in the year 2011.It was from this global PV production scenario in the year 2011that almost more than 85%of the solar cell production was based on crystalline silicon.Even it was observed that even PV installation scenario,crystalline silicon solar cell,dominated the world market as indicated in Figure 4.
The year wise efficiency record of solar cell fabri-cated under different technological approaches is shown in Figure 5.From this record,it is evident that laboratory monocrystalline silicon solar cell efficiency was still higher
America, 7%
Figure 2:Global cumulative PV installation until 2011(data:EPA Graph:PSE AG 2012).All percentages are related to the total global
installation.
102030405060708090100P r o d u c t i o n (M W p ) (%)
Y ear
1980
1982
1984
1986
1988
1990
1992
1994
1996
1998
2000
2002
2004
2006
2008
2010
Thin film 3,204Ribbon-Si 120
Multi-Si 10,336Mono-Si 9,114
Figure 3:PV production development by technology (data:Navi-gant Consulting Graph:PSE AG 2012).
compared to other existing solar cell technology except III-V multijunction concentrator solar cell and monocrys-talline concentrator solar cell,respectively.
Best laboratory cell versus best laboratory module fabri-cated under different PV technology is also given in Figure 6.It is observed from Figure 6that the lab.made monocrys-talline solar cell and module efficiency were 25%and 22.9%,respectively,whereas multicrystalline solar cell and module efficiency were 20.4%and 18.2%,respectively.One important point to be noted is that the efficiency of thin film CI(G)S solar cell was 19.6%(area 0.42cm 2).So there is enough scope of work related to CI(G)S solar cell technology.
After more than 20years of R&D,thin-film solar cells are beginning to be deployed in significant quantities.Thin-film solar cells could potentially provide lower cost electricity than c-Si wafer-based solar cells.However,this is not certain,as 2010
2005
2000
Thin film Mono-Si Multi-Si Ribbon-Si
22.8 GWp end of 2011
Figure 4:Global annual PV installation by technology at end of 2011(data:Navigant Consulting Graph:PSE AG 2012).
lower capital costs including lower production and materials costs are offset to some extent by lower efficiencies and very low c-Si module costs make the economics even more challenging.
Thin-film solar cells comprised successive thin layers,just 1μm to 4μm thick,of solar cells deposited onto a large,inexpensive substrate such as glass,polymer,or metal.As a consequence,they require a lot less semiconductor material to be manufactured in order to absorb the same amount of sunlight (up to 99%less material than crystalline solar cells).In addition,thin films can be packaged into flexible and lightweight structures,which can be easily integrated into building components (building-integrated PV ,BIPV).
Third-generation PV technologies are at the pre-comme-rcial stage and vary from technologies under demonstration (e.g.,multijunction concentrating PV to novel concepts
10
20304050
60
III-V multijunction concentrator solar cell Slicon concentrator cell Monocrystalline silicon Multi crystalline silicon Thin-film CIGS Thin-film CdTe
Dye-sensitized solar cell Organic solar cell
S o l a r c e l l e ffi c i e n c y (%)
Y ear
Figure 5:Development of laboratory solar cell efficiency (Data:Solar Cell Efficiency tables (version 1-40),Progress in PV:Research and Applications,1992–2012,Graph:Simon Philipps,Fraunhofer ISE).
still in need of basic R&D (e.g.,quantum-structured PV cells).Some third-generation PV technologies are beginning to be commercialized,but how successful they will be in taking market share from existing technologies remains to be seen.
Novel and emerging solar cell concepts in addition to the previously mentioned third-generation technologies;there are a number of novel solar cell technologies under development that rely on using quantum dots/wires,quan-tum wells,or super
lattice technologies (Nozik,2011and Raffaelle,2011).These technologies are likely to be used in concentrating PV technologies where they could achieve very high efficiencies by overcoming the thermodynamic limitations of conventional (crystalline)cells.However,these high-efficiency approaches are in the fundamental materials research phase.Furthermore from the market are the novel concepts,often incorporating enabling technologies such as nanotechnology,which aim to modify the active layer to better match the solar spectrum (Leung,2011).
A newer technology,thin-film PV ,accounts for 10%–15%of global installed PV capacity [8].Rather than using polysilicon,these cells use thin layers of semiconductor mate-rials like amorphous silicon (a-Si),copper indium diselenide (CIS),copper indium gallium diselenide (CIGS),or cadmium telluride (CdTe).The manufacturing methods are similar to those used in producing flat panel displays for computer monitors,mobile phones,and televisions;a thin photoactive film is deposited on a substrate,which can be either glass
Efficiency η(%)
CI(G)S 0.4cm 2cell CI(G)S 0.97m 2module CdTe/CdS 1cm 2cell CdTe 0.67m 2module
a-Si tandem (0.27cm 2cell)a-Si tandem (905cm 2module)Multi-Si block (1cm 2cell)
Multi-Si block (1.4709m 2module)Mono-Si FZ n-type (4cm 2cell)
Mono-Si FZ n-type (778cm 2module)
Figure 6:Efficiency comparison of technology:best laboratory cells versus best laboratory module (Data:Green et al.;Solar Cell Efficiency tables (version 1-40),Progress in PV:Research and Applications,2012,Graph:PSE AG 2012).
or a transparent film.Afterwards,the film is structured into cells.Unlike crystalline modules,thin-film modules are manufactured in a single step.Thin-film systems usually cost less to be produced than crystalline silicon systems but have substantially lower efficiency rates [9].On average,thin-film cells convert 5%–13%of incoming sunlight into electricity,compared to 11%–20%for crystalline silicon cells.However,as thin film is relatively new,it may offer greater opportunities for technological improvement.
3.Monocrystalline Silicon Solar Cell Technology
Traditional c-Si cell design and its development up to year 2000have been focused on in the Figure 7.Different types of c-Si cell structure have been used for improving the efficiency of crystalline silicon solar cell.Metal-insulator NP solar cell (MINP),passivated emitter solar cell (PESC),passivated emitter and rear cell (PERC),passivated emitter,rear locally diffused cell (PERL),and interdigitized back contact cell (IBC)are useful solar cell structures used by the different well-recognized universities or laboratories.
1214
16
18202224
26Crystalline silicon
Single crystal
E ffi c i e n c y (%)
Y ear
(a)
Antireflection
Top metal
Traditional cell design
?No passivation metallic front contacts
?Full metallic contact covering entire rear area ?May or may not be BSF
(b)
Figure 7:Traditional c-Si cell design and its development up to year 2000.
Finger
Microgroove
Thin oxide
p
n +
p +
Figure 8:Passivated emitter solar cell.
In MINP structure,there was SiO 2passivation surface underneath contact and current conduction by tunneling through the thin oxide [10].
But in PESC structure [11,12],there was no oxide underneath contact as shown in Figure 8.Contact width is reduced by laser microgrooving as shown in Figure 9.
In PERC structure as shown in Figure 10(a),rear surface of the solar cell was passivated and contact was made by point rear contact,whereas in PERL structure [13],rear contact is made by local BSF (back surface field)at rear point contact by diffusion as shown in Figure 10(b).
Interdigitized back contact solar cell [14]is now well-known promising solar cell structure used by SUNPOWER in their solar cell production line.R.M.Swanson is a key person for the development of IBC solar cell structure [15].In this structure,all solar cell contacts were made from rear surface.Both front and back surface fields have been implemented in this structure as shown in Figure 11.
18μm
Figure 9:Laser microgrooving.
Researchers in the area of crystalline silicon continuously tried to find out a new simple route by which large area high efficiency can be achieved.In 2011,Lai [16]already achieved 19.4%efficient planar cells on CZ silicon using simple cell technologies.Figure 12is the structure used during fabrication by Lai.
One key to the development of any photovoltaic technol-ogy is the cost reduction associated with achieving economies of scale.This has been evident with the development of crystalline silicon PVs and will presumably be true for other technologies as their production volumes increase.Price trend of crystalline installed PV in the world market is shown in Figure 13.
4.Indian PV Scenarios
Developing countries,in particular,face situations of limited energy resources,especially the provision of electricity in rural areas,and there is an urgent need to address this constraint to social and economic development.India faces
Rear contact
Finger
“Inverted” pyramids
Oxide
Oxide
p-silicon
n
n +
(a)
Oxide n
p-silicon
n ++
p +
+
p +
(b)
(c)
Figure 10:(a)PERC and (b)PERL solar cell structure.(c)PERL design cell marketed by SunTech as PLUTO technology cell.
Passivation layer AR layer
Emitter (B
Metal finger (p)
Metal finger (n)
n -t y p e
S i
FSF ()
BSF ()
doped) ()n +n +p +Figure 11:Interdigitized back contact solar cell.
a significant gap between electricity demand and supply.Demand is increasing at a very rapid rate compared to the supply.According to the World Bank,roughly 40percent of residences in India are without electricity.In addition,blackouts are a common occurrence throughout the country’s main cities.The World Bank also reports that one-third of Indian businesses believes that unreliable electricity is one of their primary impediments to do business.In addi-tion,coal shortages are further straining power generation capabilities.
India is endowed with rich solar energy resource.The average intensity of solar radiation received on India is 200MW/km square (megawatt per kilometer square).With a geographical area of 3.287million km square,this amounts to 657.4million MW .However,87.5%of the land is used for agriculture,forests,fallow lands,and so forth,6.7%for
housing,industry,and so forth,and 5.8%is either barren,snow bound,or generally inhabitable.Thus,only 12.5%of the land area amounting to 0.413million km square can,in theory,be used for solar energy installations.Even if 10%of this area can be used,the available solar energy would be 8million MW ,which is equivalent to 5909mtoe (million tons of oil equivalent)per year.
In order to meet the situation,a number of options are considered.Power generation using freely available solar energy is one such option.Fortunately,India is both densely populated and has high solar insolation,providing an ideal combination for solar power in India.Jawaharlal Nehru National Solar Mission is one of the major global initiatives in promotion of solar energy technologies,announced by the Government of India under National Action Plan on Climate Change.Mission aims to achieve grid tariff parity by 2022through the large-scale utilization and rapid diffusion and deployment of solar technologies across the country at a scale which leads to cost reduction and promotes the research and development activity to local manufacturing and infrastructural support.Table 1shows the road map of Jawaharlal Nehru National Solar Mission.
Under the plan,solar-powered equipment and appli-cations would be mandatory in all government buildings including hospitals and hotels.The scope for solar PV growth in India is massive,especially growth in distributed solar as over 600million people—mostly in rural areas—currently do not have access to electricity.It is useful for providing grid quality,reliable power in rural areas where the line voltage is low and insufficient to be catered to connected load.
alloying)
x (PECVD)
x (PECVD)
2(thin, thermally grown)2(thin, thermally grown)+(P)-Si (ion implantation)
(Al)-Si (LPE during +Figure 12:19.4%efficient planar cells on CZ silicon using simple cell technologies.
I n s t a l l e d c o s t ($/W p )
System GP Boss Inverter
Labor
Connection Mod ASP
200820092010
2011
0E+00
1E+00
2E+003E+004E+005E+006E+007E+00
1 Q
2 Q
3 Q
4 Q 1 Q 2 Q 3 Q 4 Q 1 Q 2 Q 3 Q 4 Q P 1 Q P 2 Q P 3 Q P 4 Q P
(a)
Permits
Wafering GP $, 0.17/WP
Module assy
Cell processing GP , $0.12/Wp
Cell
Module assy GP $0.25/Wp
System expenses $1.03/Wp
System GP , $0.45/Wp
p-Si + wafer processing
(b)
Figure 13:Price trend of crystalline installed PV in the world market.
Table 1:Road map of Jawaharlal Nehru National Solar Mission.
Application segment Target for phase I (2010–13)
Cumulative target for phase 2(2013–17)Cumulative target for phase 3(2017–22)Grid solar power including roof top and distribution grid connected plants 1,000MW
4,000MW
20,000MW
Off-grid solar applications 200MW 1,000MW 2,000MW Solar collector
7million sq.meters
15million sq.meters
20million sq.meters
The Government of India is planning to electrify 18,000villages by year 2012through renewable energy systems especially by solar PV systems.This offers tremendous growth potential for Indian solar PV industry.
The growth of Indian PV is shown in the Figure 14indicating that the increase of module production up to year 2011was significant compared to solar cell production by the Indian manufacturer.This may be due to availability to solar cell with much lower prices from Chinese solar cell manufacturer and initial investment of the module plant with lower CAPEX compared to setting up new solar cell plant in India.But the status of Indian PV is related to the application in different areas by installing 53,00,000systems (~2600MW)up to 2012as shown in Figure 15.
20222532
3745
110
175240
3202023364565
80135240300600
100200300400500600700P r o d u c t i o n (M W )
Y
ear
Solar cell PV module
2001-02
2002-03
2003-04
2004-05
2005-06
2006-07
2007-08
2008-09
2009-10
2010-11
Figure 14:Growth in Indian PV production.
Grid plants 1044
Railways 55
Telecom 65
Others 270
Int projects 1000
Lights 90
Pumps 14
Off-grid plants
62
Figure 15:Status of PV in India.
Another important achievement in the Indian PV area is 1044MW capacity new Grid Solar Power projects commis-sioned by September,2012in 16States as indicate state wise in Figure 16.From this pictorial presentation,it is clear that Gujarat state much ahead compared to the rest of other state as far as installation of Grid Solar PV Power Plant in India.
5.Conclusion
One key to the development of any photovoltaic technology is the cost reduction associated with achieving economies of scale.This has been evident with the development of crystalline silicon PVs and will presumably be true for other technologies as their production volumes increase.
Given
Gujarat 680
Rajasthan 199
A.P 22
Maharashtra 20Jharkhand 16T.N 15
Karnataka 14Others 80
Figure 16:Grid solar PV power plants in India.
the vast potential of photovoltaic technology,worldwide production of terrestrial solar cell modules has been rapid over the last several years,with China recently taking the lead in total production volume.
Fortunately India is both densely populated and has high solar insolation,providing an ideal combination for solar power in India.The Government of India is planning to elec-trify 18,000villages by year 2012through renewable energy systems especially solar PV systems.This offers tremendous growth potential for Indian solar PV industry.
Acknowledgments
Authors would like to thank Meghnad Saha Institute of Technology,TIG,for providing the infrastructural support to carry out research activity in this area.The authors also gratefully acknowledge the DST,Government of India for financial support for carrying out solar-cell-related research activity.
References
[1]S.M.Xu,X.D.Huang,and R.Du,“An investigation of the solar powered absorption refrigeration system with advanced energy storage technology,”Solar Energy ,vol.85,no.9,pp.1794–1804,2011.[2]D.G.Karalis,D.I.Pantelis,and V .J.Papazoglou,“On the inves-tigation of 7075aluminum alloy welding using concentrated solar energy,”Solar Energy Materials and Solar Cells ,vol.86,no.2,pp.145–163,2005.[3]M.Neises,S.Tescari,L.de Oliveira,M.Roeb,C.Sattler,and
B.Wong,“Solar-heated rotary kiln for thermochemical energy storage,”Solar Energy ,vol.86,no.10,pp.3040–3048,2012.[4]V .R.Sardeshpande,A.G.Chandak,and I.R.Pillai,“Procedure
for thermal performance evaluation of steam generating point-focus solar concentrators,”Solar Energy ,vol.85,no.7,pp.1390–1398,2011.[5]L.L.Kazmerski,“Solar photovoltaics R&D at the tipping point:
a 2005technology overview,”Journal of Electron Spectroscopy and Related Phenomena ,vol.150,no.2-3,pp.105–135,2006.
[6]Y.S.Tsuo,T.H.Wang,and T.F.Ciszek,“Crystalline-silicon solar
cells for the21st century,”in Proceedings of the Electrochemical Society Annual Meeting,Seattle,Wash,USA,May1999.
[7]M.A.Green,“Third generation photovoltaics:ultra-high con-
version efficiency at low cost,”Progress in Photovoltaics,vol.9, no.2,pp.123–135,2001.
[8]Solar Cell Production Global Market Outlook,Business Insights,
2011,Thin-film cells trace their roots to RCA Laboratories in New Jersey.
[9]Efficiency,Which Measures the Percentage of the Sun’s Energy
Striking the Cell or Module,is One important Characteristic of a Solar Cell or Module.Over Time,Average Cell Efficiencies have Increased,European Photovoltaic Industry Association,Solar Generation6,Solar Photovoltaic Electricity Empowering the World,2011.
[10]A.Mrwa,G.Ebest,M.Rennau,and A.Beyer,“Comparison
of different emitter diffusion methods for MINP solar cells: thermal diffusion and RTP,”Solar Energy Materials and Solar Cells,vol.61,no.2,pp.127–134,2000.
[11]K.R.Catchpole and A.W.Blakers,“Modelling the PERC struc-
ture for industrial quality silicon,”Solar Energy Materials and Solar Cells,vol.73,no.2,pp.189–202,2002.
[12]K.van Wichelen,L.Tousa,A.Tiefenauera et al.,“Towards20.5%
efficiency PERC Cells by improved understanding through simulation,”Energy Procedia,vol.8,pp.78–81,2011.
[13]M.Moors,K.Baert,T.Caremans,F.Duerinckx,A.Cacciato,
and J.Szlufcik,“Industrial PERL-type solar cells exceeding19% with screen-printed contacts and homogeneous emitter,”Solar Energy Materials and Solar Cells,vol.106,pp.84–88,2012. [14]G.Galbiati,V.D.Mihailetchi,A.Halm,R.Roescu,and R.
Kopecek,“Results on n-type IBC solar cells using industrial optimized techniques in the fabrication processing,”Energy Procedia,vol.8,pp.421–426,2011.
[15]R.M.Swanson,“Point-contact solar cells:modeling and exper-
iment,”Solar Cells,vol.17,no.1,pp.85–118,1986.
[16]https://www.sodocs.net/doc/337067284.html,i,“Large area19.4%efficient rear passivated silicon
solar cells with local Al BSF and screen-printed contacts,”in Proceedings of the37th IEEE Photovoltaic Specialists Conference (PVSC’11),2011.
Journal of Engineering Energy Renewable Energy Hindawi Publishing Corporation Solar Energy Power Electronics Hindawi Publishing Corporation https://www.sodocs.net/doc/337067284.html,
Volume 2013
Advances in
Hindawi Publishing Corporation International Journal of
Photoenergy Nuclear Energy International Journal of
Wind Energy Hindawi Publishing Corporation https://www.sodocs.net/doc/337067284.html, Volume 2013Fuels
Journal of
High Energy Physics Advances in
Hindawi Publishing Corporation https://www.sodocs.net/doc/337067284.html, Volume 2013
Mechanical Engineering
Advances in Hindawi Publishing Corporation https://www.sodocs.net/doc/337067284.html, Volume 2013Number 1 S cience and Technology of
Nuclear Installations
Hindawi Publishing Corporation The Scientific World Journal Combustion Journal of https://www.sodocs.net/doc/337067284.html, Volume 2013
Structures Journal of International Journal of
R otating Machinery
Hindawi Publishing Corporation https://www.sodocs.net/doc/337067284.html,
Volume 2014Industrial Engineering Journal of
Tribology Advances in Volume 2014Energy Hindawi Publishing Corporation Journal of
Engineering Volume 2014
https://www.sodocs.net/doc/337067284.html, International Journal of Photoenergy Nuclear Installations Science and Technology of Solar Energy Wind Energy Power Electronics Fuels
Journal of Hindawi Publishing Corporation Nuclear Energy International Journal of High Energy Physics Advances in Volume 2014Mechanical
Engineering Advances in Petroleum Engineering The Scientific World Journal
Hindawi Publishing Corporation Volume 2014Volume 2014Renewable Energy Combustion https://www.sodocs.net/doc/337067284.html, Volume 2014