Shanghai, China
Shanghai, China

Hanwha SolarOne, Ltd. is an integrated manufacturer of solar panels based in Qidong, China. Its products includes photovoltaic cells and panels, and silicon ingots and wafers.The company was established in 2004 as Solarfun Power Holdings by Linyang Electronics. In 2006, Solarfun was listed at NASDAQ. In 2008, Solarfun acquired a manufacturer of silicon ingots Jiangsu Yungguang Solar. In 2010, 49% of company shares was acquired by Hanwha Chemical, a subsidiary of Hanwha Group. Consequently the company was renamed Hanwha SolarOne.By the end of 2010, Hanwha SolarOne had annual module manufacturing capacity of 900 MW, cell manufacturing capacity of 600 MW, and ingot/wafer manufacturing capacity of 400MW. It also had a capacity of 15 MW for automated building integrated photovoltaics . According to PVinsights, in 2010 it was seventh largest photovoltaic module producer in the world. Wikipedia.

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Wan S.,Shanghai JiaoTong University | Xu L.,Shanghai JiaoTong University | Liu F.,Hanwha SolarOne | Hu J.,Shanghai Hi Show PV Science and Technology Co.
Taiyangneng Xuebao/Acta Energiae Solaris Sinica | Year: 2013

An improved "slope method of the I-V curve at open circuit point" (slope method) for determining the series resistance of solar cells was presented in this paper, and using Lambert's W function to express the current-voltage relationship of solar cells. The slope method was used to compare with three other methods for series resistances. Then, the simulated results were verified by experiment and some theoretical explanations were given. Especially, the reason why the data from current simulator test is large was explained. The analyses results showed that the slope method stands out among those four methods to extract series resistance for the solar simulator with convenient, reliable, and small non-repetitive features.


News Article | November 2, 2016
Site: www.newsmaker.com.au

This report studies Solar Grade Multi Crystal Silicon Ingot in Global market, especially in North America, Europe, China, Japan, Southeast Asia and India, focuses on top manufacturers in global market, with capacity, production, price, revenue and market share for each manufacturer, covering  WACKER SCHOTT Solar GmbH  NEXOLON  Green Energy Technology  SINO-AMERICAN SILICON PRODUCTS   Hanwha SolarOne  EVERSOL CORPORATION  PV CRYSTALOX SOLAR  TARGRAY  Rexor  Maharishi Solar  Photowatt  GCL Solar  JinkoSolar  RENESOLA  LDK Solar   Jiangxi Sornid Hi-Tech  Shandong DAHAI New Energy Development   Shaanxi Hermaion Solar  Yingli Green Energy Holding Company  HUANTAI GROUP  CNPV  Yichang CSG  CHINA GUODIAN  Jiangxi Xinshun New Energy Science and Technology  Lu’an Group  Hareon Solar   Anhui Eisen New Energy Market Segment by Regions, this report splits Global into several key Regions, with production, consumption, revenue, market share and growth rate of Solar Grade Multi Crystal Silicon Ingot in these regions, from 2011 to 2021 (forecast), like  North America  Europe  China  Japan  Southeast Asia  India Split by product type, with production, revenue, price, market share and growth rate of each type, can be divided into  Type I  Type II  Type III Split by application, this report focuses on consumption, market share and growth rate of Solar Grade Multi Crystal Silicon Ingot in each application, can be divided into  Application 1  Application 2  Application 3 Global Solar Grade Multi Crystal Silicon Ingot Market Research Report 2016  1 Solar Grade Multi Crystal Silicon Ingot Market Overview  1.1 Product Overview and Scope of Solar Grade Multi Crystal Silicon Ingot  1.2 Solar Grade Multi Crystal Silicon Ingot Segment by Type  1.2.1 Global Production Market Share of Solar Grade Multi Crystal Silicon Ingot by Type in 2015  1.2.2 Type I  1.2.3 Type II  1.2.4 Type III  1.3 Solar Grade Multi Crystal Silicon Ingot Segment by Application  1.3.1 Solar Grade Multi Crystal Silicon Ingot Consumption Market Share by Application in 2015  1.3.2 Application 1  1.3.3 Application 2  1.3.4 Application 3  1.4 Solar Grade Multi Crystal Silicon Ingot Market by Region  1.4.1 North America Status and Prospect (2011-2021)  1.4.2 Europe Status and Prospect (2011-2021)  1.4.3 China Status and Prospect (2011-2021)  1.4.4 Japan Status and Prospect (2011-2021)  1.4.5 Southeast Asia Status and Prospect (2011-2021)  1.4.6 India Status and Prospect (2011-2021)  1.5 Global Market Size (Value) of Solar Grade Multi Crystal Silicon Ingot (2011-2021) 7 Global Solar Grade Multi Crystal Silicon Ingot Manufacturers Profiles/Analysis  7.1 WACKER SCHOTT Solar GmbH  7.1.1 Company Basic Information, Manufacturing Base and Its Competitors  7.1.2 Solar Grade Multi Crystal Silicon Ingot Product Type, Application and Specification  7.1.2.1 Type I  7.1.2.2 Type II  7.1.3 WACKER SCHOTT Solar GmbH Solar Grade Multi Crystal Silicon Ingot Capacity, Production, Revenue, Price and Gross Margin (2015 and 2016)  7.1.4 Main Business/Business Overview  7.2 NEXOLON  7.2.1 Company Basic Information, Manufacturing Base and Its Competitors  7.2.2 Solar Grade Multi Crystal Silicon Ingot Product Type, Application and Specification  7.2.2.1 Type I  7.2.2.2 Type II  7.2.3 NEXOLON Solar Grade Multi Crystal Silicon Ingot Capacity, Production, Revenue, Price and Gross Margin (2015 and 2016)  7.2.4 Main Business/Business Overview  7.3 Green Energy Technology  7.3.1 Company Basic Information, Manufacturing Base and Its Competitors  7.3.2 Solar Grade Multi Crystal Silicon Ingot Product Type, Application and Specification  7.3.2.1 Type I  7.3.2.2 Type II  7.3.3 Green Energy Technology Solar Grade Multi Crystal Silicon Ingot Capacity, Production, Revenue, Price and Gross Margin (2015 and 2016)  7.3.4 Main Business/Business Overview  7.4 SINO-AMERICAN SILICON PRODUCTS   7.4.1 Company Basic Information, Manufacturing Base and Its Competitors  7.4.2 Solar Grade Multi Crystal Silicon Ingot Product Type, Application and Specification  7.4.2.1 Type I  7.4.2.2 Type II  7.4.3 SINO-AMERICAN SILICON PRODUCTS  Solar Grade Multi Crystal Silicon Ingot Capacity, Production, Revenue, Price and Gross Margin (2015 and 2016)  7.4.4 Main Business/Business Overview  7.5 Hanwha SolarOne  7.5.1 Company Basic Information, Manufacturing Base and Its Competitors  7.5.2 Solar Grade Multi Crystal Silicon Ingot Product Type, Application and Specification  7.5.2.1 Type I  7.5.2.2 Type II  7.5.3 Hanwha SolarOne Solar Grade Multi Crystal Silicon Ingot Capacity, Production, Revenue, Price and Gross Margin (2015 and 2016)  7.5.4 Main Business/Business Overview  7.6 EVERSOL CORPORATION  7.6.1 Company Basic Information, Manufacturing Base and Its Competitors  7.6.2 Solar Grade Multi Crystal Silicon Ingot Product Type, Application and Specification  7.6.2.1 Type I  7.6.2.2 Type II  7.6.3 EVERSOL CORPORATION Solar Grade Multi Crystal Silicon Ingot Capacity, Production, Revenue, Price and Gross Margin (2015 and 2016)  7.6.4 Main Business/Business Overview  7.7 PV CRYSTALOX SOLAR  7.7.1 Company Basic Information, Manufacturing Base and Its Competitors  7.7.2 Solar Grade Multi Crystal Silicon Ingot Product Type, Application and Specification  7.7.2.1 Type I  7.7.2.2 Type II  7.7.3 PV CRYSTALOX SOLAR Solar Grade Multi Crystal Silicon Ingot Capacity, Production, Revenue, Price and Gross Margin (2015 and 2016)  7.7.4 Main Business/Business Overview  7.8 TARGRAY  7.8.1 Company Basic Information, Manufacturing Base and Its Competitors  7.8.2 Solar Grade Multi Crystal Silicon Ingot Product Type, Application and Specification  7.8.2.1 Type I  7.8.2.2 Type II  7.8.3 TARGRAY Solar Grade Multi Crystal Silicon Ingot Capacity, Production, Revenue, Price and Gross Margin (2015 and 2016)  7.8.4 Main Business/Business Overview  7.9 Rexor  7.9.1 Company Basic Information, Manufacturing Base and Its Competitors  7.9.2 Solar Grade Multi Crystal Silicon Ingot Product Type, Application and Specification  7.9.2.1 Type I  7.9.2.2 Type II  7.9.3 Rexor Solar Grade Multi Crystal Silicon Ingot Capacity, Production, Revenue, Price and Gross Margin (2015 and 2016)  7.9.4 Main Business/Business Overview  7.10 Maharishi Solar  7.10.1 Company Basic Information, Manufacturing Base and Its Competitors  7.10.2 Solar Grade Multi Crystal Silicon Ingot Product Type, Application and Specification  7.10.2.1 Type I  7.10.2.2 Type II  7.10.3 Maharishi Solar Solar Grade Multi Crystal Silicon Ingot Capacity, Production, Revenue, Price and Gross Margin (2015 and 2016)  7.10.4 Main Business/Business Overview  7.11 Photowatt  7.12 GCL Solar  7.13 JinkoSolar  7.14 RENESOLA  7.15 LDK Solar   7.16 Jiangxi Sornid Hi-Tech  7.17 Shandong DAHAI New Energy Development   7.18 Shaanxi Hermaion Solar  7.19 Yingli Green Energy Holding Company  7.20 HUANTAI GROUP  7.21 CNPV  7.22 Yichang CSG  7.23 CHINA GUODIAN  7.24 Jiangxi Xinshun New Energy Science and Technology  7.25 Lu’an Group  7.26 Hareon Solar   7.27 Anhui Eisen New Energy


Li X.,Nanchang University | Deng H.,Nanchang University | Zhang X.,Jiangxi Youth Vocational College | Chen D.,Nanchang University | Wei G.,Hanwha SolarOne
Shiyou Huagong/Petrochemical Technology | Year: 2014

A catalyst, WO3/SBA-15, was prepared through immersion and characterized by means of XRD and BET. The results showed that WO3 was highly dispersed on the surface of SBA-15 and the catalyst still had regular molecular sieve structure with mesopores. The desulfurization of FCC gasoline by adsorption and oxidation-extraction was investigated with active carbon as the adsorbent, H2O2 as the oxidant, WO3/SBA-15 as the catalyst and 1-methyl-2-pyrrolidone (NMP) as the extractant. The effects of oxidative temperature and time, H2O2 volume, WO3/SBA-15 mass, volume ratio of extractant to FCC gasoline, and extraction time on the desulfurization rate were studied. The results showed that under the optimal conditions of oxidative temperature 60°C and time 75 min, 30% (w) H2O2 volume 0.5 mL, WO3/SBA-15 catalyst mass 0.16 g, FCC gasoline 10 mL, volume ratio of extractant to FCC gasoline 1.0 and extraction time 30 min, the desulfurization rate reached 81.71%. The oxidation activity of the WO3/SBA-15 catalyst decreased after regeneration four times.


Wang H.,Nanjing University of Science and Technology | Zhu J.,Nanjing University of Science and Technology | Ma Y.,Hanwha SolarOne
Taiyangneng Xuebao/Acta Energiae Solaris Sinica | Year: 2013

On the basis of constructing the optical model of encapsulated PV module with selective emitter solar cell, the concept of decibel was introduced and then the definitions of external quantum efficiency and internal quantum efficiency of module were proposed so as to make it more convenient to study the effects of each encapsulation material on conversion efficiency of solar PV module. According to the measured optical transmission of EVA and Silicone encapsulations in the range of 280nm to 1200nm, the absorption losses of the two encapsulation materials were calculated. The spectral response before and after encapsulation of single cells using EVA or Silicone were tested, and then the short circuit current density attenuation for module with selective emitter solar cell using different encapsulation was calculated respectively in short wavelength 300nm to 500nm. The comparison results show that using Silicone encapsulation can improve blue response of PV module with selective emitter solar cell. In another word, using Silicone encapsulation can improve the quantum efficiency of module.


Trademark
Hanwha SolarOne and Solarfun | Date: 2011-01-05

Photovoltaic cells and modules; photovoltaic solar modules; solar cells; solar cell modules; photovoltaic inverters and electrical controllers.


Patent
Hanwha SolarOne | Date: 2014-10-22

The invention discloses a method for insulating an aluminum backboard of a photovoltaic module, comprising the following steps: shearing the aluminum backboard such that the dimensions of the aluminum backboard are 4-5mm smaller those of the glass; forming a square aperture at the position of the electrode lead of the aluminum backboard; insulating the square aperture by cushioning a small insulating material or wrapping the edges with an insulation film when arraying and laying the modules; laminating and trimming the superimposed module components; wrapping the trimmed laminated piece around the edge with the 0.5-1mm insulation tape; finally, framing up the laminated piece by using a frame filled with silica gel, and installing the terminal box. The invention is convenient to operate and low in investment and has a wide application prospect.


Patent
Hanwha SolarOne | Date: 2013-07-25

A method for insulating an aluminum backboard of a photovoltaic module comprises the following steps: shearing the aluminum backboard such that the dimensions of the aluminum backboard are 4-5 mm smaller those of the glass; forming a square aperture at the position of the electrode lead of the aluminum backboard; insulating the square aperture by cushioning a small insulating material or wrapping the edges with an insulation film when arraying and laying the modules; laminating and trimming the superimposed module components; wrapping the trimmed laminated piece around the edge with the 0.5-1 mm insulation tape; finally, framing up the laminated piece by using a frame filled with silica gel, and installing the terminal box. The invention is convenient to operate and low in investment and has a wide application prospect.


News Article | December 15, 2014
Site: www.bloomberg.com

A unit of Hanwha SolarOne Co., the photovoltaic manufacturing division of South Korea’s Hanwha Group, secured a three-year $23 million loan from Export-Import Bank of Korea for working capital purposes. The loan will mature on Dec. 11, 2017. The annual interest rate is 1.83 percent over the floating three-month London interbank offered rate, the company said today in a statement. Hanwha SolarOne (Qidong) Co. obtained a three-year, $100 million loan from the bank in June 2013. Hanwha SolarOne said last week it will acquire Thalheim, Germany-based Hanwha Q Cells for $1.2 billion in stock.


Hanwha SolarOne Co., Ltd. (the “Company”, or “Hanwha SolarOne”), a top-10 global photovoltaic manufacturer of high-quality, cost-competitive solar modules, today announced it has signed a memorandum of understanding (“MOU”) with Yantai Municipal Bureau of Commerce (“YMBC”) to establish a long-term strategic partnership with the aim to develop distributed generation (DG) PV projects. Yantai is a major port city located in Shandong Province, China. YMBC will help secure rooftop space, facilitate project approval and grid connection, as well as aid with obtaining tax preferences and project financing. As part of the strategic partnership Hanwha SolarOne intends to develop, own and operate 100 MW of distributed generation projects in Yantai. The agreement is in place for five years with either party able to cancel with 90 day’s notification. Mr. Jay Seo, Chief Financial Officer of Hanwha SolarOne and head of Hanwha SolarOne's China business commented, “Hanwha SolarOne continues to make progress in establishing a downstream business in China. Through this partnership we have already identified rooftops that will accommodate approximately 8 MW of DG projects and are now in the process of securing permits. We intend to use our own modules and perform the necessary EPC work for all projects under this MOU.” Mr. Seo concluded, “The latest government initiatives are already having a meaningful impact on the acceleration of distributed generation projects in China and we feel we are ideally positioned to gain further traction in the market going forward.” Hanwha SolarOne Co., Ltd. (NASDAQ: HSOL) is one of the top 10 photovoltaic module manufacturers in the world, providing cost-competitive, high quality PV modules. It is a flagship company of Hanwha Group, one of the largest business enterprises in South Korea. Hanwha SolarOne serves the utility, commercial, government and residential markets through a growing network of third-party distributors, OEM manufacturers and system integrators. The company maintains a strong presence worldwide, with a global business network spanning Europe, North America, Asia, South America, Africa and the Middle East. As a responsible company committed to sustainability, Hanwha SolarOne is an active member of the PV Cycle take-back and recycling program. For more information, please visit: www.hanwha-solarone.com. This press release contains forward-looking statements. These statements constitute "forward-looking" statements within the meaning of Section 27A of the Securities Act of 1933, as amended, and Section 21E of the Securities Exchange Act of 1934, as amended, and as defined in the U.S. Private Securities Litigation Reform Act of 1995. Forward-looking statements involve inherent risks and uncertainties and actual results may differ materially from such estimates depending on future events and other changes in business climate and market conditions. Hanwha SolarOne disclaims any obligation to update or correct any forward-looking statements.

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