Loading Port:China main port
Payment Terms:TT or LC
Min Order Qty:10000 watt
Supply Capability:10000000000000 watt/month
Place of Origin: | Guangdong China (Mainland) | Brand Name: | CAP | Model Number: | 50w100w150w200w250w300w |
Material: | Monocrystalline Silicon | Size: | 1385*1035*75mm | Number of Cells: | 72pcs |
Max. Power: | 300w | type: | solar panel | color: | blue&black |
warranty: | 5 years |
Packaging Detail: | standard export package for solar panel |
Delivery Detail: | 7-15 days for solar panel |
solar panel
High Efficiency
25 years Warranty
High-transmissivity low-iron tempered glass
Solar Panel
50w100w150w200w250w300w
Characteristics
1,High and stable conversion efficienly based on over 4 years professional experience
2 ,High reliability with guaranteed +/-10% output power tolerance
3,Proven materials,tempered front glass,and a sturdy anodized aluminum frame allow modules to operate reliably in multiple mountily configurations
4,Combination of high efficicncy and attractive appearance
Quality and Safety
1,25 year 80%,10 year 90% power warranty 3 year power warranty
2,ISO9001:2000 (Quality Management system) certified factory
3,Product Quality warranty & products Liability Insurance to guarantee and user' benefits
4,Certifications TUV Intercert, CE Temperature Coefficients
Module Type | 100w | 150w | 200w | 250w | 300w |
Maximum Power at ST(Pmax)W | 100wp | 150wp | 200wp | 250wp | 300wp |
Maximum Power Voltage(Vmp)V | 36/18 | 36/18 | 36/18 | 30.8v | 36/18 |
Maximum Power Current(Imp)A | 2.77/5.55 | 4.16/8.33 | 5.55/11.1 | 8.11A | 8.33/16.66 |
Open Circuit Voltage(Voc)V | 39.5/19.05 | 39.3/19.4 | 39.6/19.5 | 36.2V | 39.6/19.8 |
Short Circuit Current(Isc)A | 3.04/6.09 | 4.58/9.16 | 6.1/12.2 | 8.7A | 9.16/18.33 |
Cell Efficiency(%) | 18.60% | 18.10% | 18.60% | 17.80% | 18.10% |
Module Efficiency(%) | 17.70% | 17.20% | 17.70% | 17.10% | 17.20% |
Operating Temperature°C | -40°C to +85°C | -40°C to +85°C | -40°C to +85°C | -40°C to +85°C | -40°C to +85°C |
Maximum system voltage | 1000V(IEC)DC | 1000V(IEC)DC | 1000V(IEC)DC | 1000V(IEC)DC | 1000V(IEC)DC |
Power tolerance | -0.03 | -0.03 | -0.03 | -0.03 | -0.03 |
Temperature coefficients of Pmax | -0.45%/°C | -0.45%/°C | -0.45%/°C | -0.45%/°C | -0.45%/°C |
Temperature coefficients of Voc | -0.27%/°C | -0.27%/°C | -0.27%/°C | -0.27%/°C | -0.27%/°C |
Temperature coefficients of Isc | 0.05%/°C | 0.05%/°C | 0.05%/°C | 0.05%/°C | 0.05%/°C |
Weight(kg) | 8 | 11 | 14 | 20 | 25.5 |
Number of cell(pcs) | 4*9 | 4*9 | 6*10 | 6*12 | 6*12 |
Dimensions(mm) | 1194*534*35/30 | 1580*808*50/35 | 1471*670*40/35 | 1640*992*50 | 2000*1050*50 |
Making More Solar Cells from Silicon
Silicon wafers are the conventional solar cells–they’re what absorbs sunlight and generates electrons. Yet the way wafers are currently manufactured wastes half of the expensive, ultra-pure crystalline silicon they’re made from. When large ingots of silicon are cut into hair-thin wafers, waste silicon is lost as sawdust. The new process–details of which remain secret–produces wafers directly from molten silicon without any sawing. This saves material and reduces the number of steps needed to make solar cells, both of which bring down costs.
How to Grow "Silicon" Crystals to Make Solar Cells
In industry, silicon crystals are grown to form a uniform cylinder of silicon which is used as the base material for crystalline solar cells. There is plenty of silicon about on the earth, in fact, as mentioned previously, after oxygen it is the second most abundant element. When you think that sand and quartz all contain silicon and then imagine the amount of sand in the world, you begin to realize that we are not going to run out of silicon in a hurry!
The problem with sand is that it also contains oxygen in the form of silicon dioxide, which must be removed.
The industrial process used to produce silicon requires temperatures of around 3270oF (which is about 1800oC). Obviously we can't experiment with these3 sorts of temperatures at home - but we can recreate the process!
You are going to need a saturated sugar solution; this will sit in the lid of your coffee jar. Now, take a large crystal of sugar, often sold as "rock sugar" and "glue" it to the end of the skewer. Next, drill a hole the same diameter as the skewer, and poke the skewer through the bottom of the coffee jar. Stand it on a windowsill and lower the crystal into the saturated sugar solution. Over some time, crystals should start to grow - pull the skewer up slowly, bit by bit, so that the growing crystal is still in contact with the sugar solution. This is just like the way that silicon is grown. The silicon is drawn up slowly from a bath of molten hot silicon (which is analogous to our saturated sugar solution).
Once this large crystal of silicon has been manufactured, it must be cut into slices to manufacture the solar cells.