Photovoltaic background, technology: Difference between revisions

From Electrical Installation Guide
(Created page with '==== The photovoltaic effect ==== This is the ability to transform solar energy into electricity and is achieved by using photovoltaic (PV) cells.<br>A PV cell (see '''Fig. P1 '…')
 
No edit summary
Line 40: Line 40:




==== Photovoltaic modules ====
==== Photovoltaic modules ====


These combinations of cells (see '''Fig. P4''') enable the voltage and current to be increased. To optimise the characteristics of the modules, these are made up of cells with similar electrical characteristics.
These combinations of cells (see '''Fig. P4''') enable the voltage and current to be increased. To optimise the characteristics of the modules, these are made up of cells with similar electrical characteristics.  


----
----


'''''Fig. P4:''' PW1400 photovoltaic module dimensions:1237 x 1082 x 45 mm (source: Photowatt)''
'''''Fig. P4:''' PW1400 photovoltaic module dimensions:1237 x 1082 x 45 mm (source: Photowatt)''  


----
----


Each module providing a voltage of several tens of volts is classified by its power level measured in Watt peak (Wp).This relates to the power produced by a surface area of one m<sup>2</sup> exposed to irradiation of 1000 W/m<sup>2</sup> at 25°C. However, identical modules may produce different levels of power so the common standard variation for power is ±3% (see table in '''Figure P5'''). Modules with typical power of 160 Wp include all modules with power of between 155 Wp (160 -3%) and 165 Wp (160 +3%).<br>It is therefore necessary to compare their efficiency which is calculated by dividing their power (W/m<sup>2</sup>) by 1000 W/m<sup>2</sup>.
Each module providing a voltage of several tens of volts is classified by its power level measured in Watt peak (Wp).This relates to the power produced by a surface area of one m<sup>2</sup> exposed to irradiation of 1000 W/m<sup>2</sup> at 25°C. However, identical modules may produce different levels of power so the common standard variation for power is ±3% (see table in '''Figure P5'''). Modules with typical power of 160 Wp include all modules with power of between 155 Wp (160 -3%) and 165 Wp (160 +3%).<br>It is therefore necessary to compare their efficiency which is calculated by dividing their power (W/m<sup>2</sup>) by 1000 W/m<sup>2</sup>.  


For example, for a module of 160 Wp with a surface area of 1.338m<sup>2</sup> (*), the peak power is 160/1.338 which gives 120 Wp/m<sup>2</sup>.<br>Therefore the efficiency of this module is: 120/1000 = 12%.
For example, for a module of 160 Wp with a surface area of 1.338m<sup>2</sup> (*), the peak power is 160/1.338 which gives 120 Wp/m<sup>2</sup>.<br>Therefore the efficiency of this module is: 120/1000 = 12%.  
 
----
 
{| style="width: 553px; height: 332px" cellspacing="1" cellpadding="1" width="553" border="1"
|-
| '''Encapsulation'''
| colspan="3" | Glass/Tedlar
|-
| '''Cell size'''
| colspan="3" | 125.50 x 125.5 mm
|-
| '''Number of cells'''
| colspan="3" | 72
|-
| '''Voltage'''
| colspan="3" | 24 V
|-
| '''Number of bypass diodes'''
| colspan="3" | 4 bypass diodes
|-
| '''Typical power'''
| 150 Wp
| 160 Wp
| 170 Wp
|-
| '''Minimum power'''
| 145 Wp
| 155 Wp
| 165 Wp
|-
| '''Voltage at typical power'''
| 33.8 V
| 34.1 V
| 34.7 V
|-
| '''Current at typical power'''
| 4.45 A
| 4.7 A
| 4.9 A
|-
| '''Short circuit current'''
| 4.65 A
| 4.8 A
| 5.0 A
|-
| '''Open wire voltage'''
| 43 V
| 43.2 V
| 43.4 V
|-
| '''Maximum circuit voltage'''
| colspan="3" | 1 000 V CC
|-
| valign="top" | '''Temperature coefficient'''
| colspan="3" | α = (dl/l)/dt # + 0.032 %/°C<br>β = dV/dt # - 158 mV/°C<br>ς P/P = - 0.43 %/°C
|-
| '''Power specifications at'''
| colspan="3" | 1000 W/m²: 25°C: AM 1.5
|}
 
'''&nbsp;'''''<b>Fig. P5:</b> Electrical characteristics of a PW1400 module (source: Photowatt)''


----
----

Revision as of 12:00, 16 February 2010

The photovoltaic effect

This is the ability to transform solar energy into electricity and is achieved by using photovoltaic (PV) cells.
A PV cell (see Fig. P1 ) is capable of generating voltage of between 0.5 V and 2 V depending on the materials used and a current directly dependent on the surface area (5 or 6 inch cells).


Fig. P1: Photovoltaic cell manufactured in a silicon plate (source: Photowatt)


Its characteristics are shown in a current/voltage graph as shown inFigure 2.


Fig. P2: Typical characteristic of a photovoltaic cell


The photovoltaic effect is dependent on two physical values (see Fig. P3)
– irradiance and temperature:

  • As irradiance E (Wm²) increases, so does the current produced by the cell
  • Conversely, as the temperature (T°) increases, the output voltage decreases.

In order to compare the performance of different cells, the standard has set out Standard Test Conditions (STC) for irradiance of 1000 W/m2 at 25°C.


increases the power generated by the cell                                               decreases the power generated by the cell


        MPP : Maximum Power Point

Fig. P3: Irradiance and temperature influence the photovoltaic effect


To make it easier to use energy generated by photovoltaic cells, manufacturers offer serial and/or parallel combinations grouped into panels or modules.


Photovoltaic modules

These combinations of cells (see Fig. P4) enable the voltage and current to be increased. To optimise the characteristics of the modules, these are made up of cells with similar electrical characteristics.


Fig. P4: PW1400 photovoltaic module dimensions:1237 x 1082 x 45 mm (source: Photowatt)


Each module providing a voltage of several tens of volts is classified by its power level measured in Watt peak (Wp).This relates to the power produced by a surface area of one m2 exposed to irradiation of 1000 W/m2 at 25°C. However, identical modules may produce different levels of power so the common standard variation for power is ±3% (see table in Figure P5). Modules with typical power of 160 Wp include all modules with power of between 155 Wp (160 -3%) and 165 Wp (160 +3%).
It is therefore necessary to compare their efficiency which is calculated by dividing their power (W/m2) by 1000 W/m2.

For example, for a module of 160 Wp with a surface area of 1.338m2 (*), the peak power is 160/1.338 which gives 120 Wp/m2.
Therefore the efficiency of this module is: 120/1000 = 12%.


Encapsulation Glass/Tedlar
Cell size 125.50 x 125.5 mm
Number of cells 72
Voltage 24 V
Number of bypass diodes 4 bypass diodes
Typical power 150 Wp 160 Wp 170 Wp
Minimum power 145 Wp 155 Wp 165 Wp
Voltage at typical power 33.8 V 34.1 V 34.7 V
Current at typical power 4.45 A 4.7 A 4.9 A
Short circuit current 4.65 A 4.8 A 5.0 A
Open wire voltage 43 V 43.2 V 43.4 V
Maximum circuit voltage 1 000 V CC
Temperature coefficient α = (dl/l)/dt # + 0.032 %/°C
β = dV/dt # - 158 mV/°C
ς P/P = - 0.43 %/°C
Power specifications at 1000 W/m²: 25°C: AM 1.5

 Fig. P5: Electrical characteristics of a PW1400 module (source: Photowatt)


Share