1. Field of the Invention
This invention relates to a solar cell; more particularly, a method for extracting solar cell parameters which can gain the series resistance of the solar cell through calculation without presuming current-voltage functional form.
2. Description of the Prior Art
As known, with the drying out of oil resource and the awareness of environment protection, the discovery of alternative resources is gradually more emphasized by many countries. In which, due to the inexhaustible characteristic of solar energy, the discovery of solar energy has gotten more attention; therefore, many countries have tried to discover and establish the application techniques of solar energy, in order to reduce the dependence on the petrochemical energy through the exploitation of solar energy. As a result, the trend of the development has resulted in the manufacture of solar cell.
Over the years, various methods have been proposed for extracting the series resistance and related device parameters of solar cells. These methods either involve current-voltage (I-V) measurements with different illumination levels, or employ integration procedures based on the computation of the area under the linear regression, etc. Currently, all these previously proposed methods of extracting the series resistance and related device parameters of solar cells are mostly based on the assumption of the intrinsic I-V relationship of the solar cell, that is the Shockley-type single exponential I-V characteristic with ideality factor. Although the exponential I-V assumption may produce equivalent-circuit model quickly and easily, and it can be used in conventional simulation tools; however, it can not be used in all solar cells, such as non p-n junction type devices or organic solar cell (OSC), etc. As a result, using Shockley-type single exponential I-V characteristic with ideality factor to measure the intrinsic I-V relationship and related device parameters of a solar cell is not really practical.
Therefore, how to use a single method to measure the series resistance inside of all kinds of solar cells is in fact a meaningful thinking direction.
Consequently, the purpose of this invention is to provide a method for parameters extraction of solar cells which can measure all kinds of solar cell parameters.
In order to reach the goal stated above, the implementation of the technology of the present invention is described as follows:
A method for parameters extraction of solar cells includes the following steps: (a) apply a first simulated solar luminosity having a first intensity to a solar cell; (b) measure a first current value and a first voltage value generated by the solar cell when the solar cell is illuminated by the first simulated solar luminosity; (c) apply a second simulated solar luminosity having a second intensity to the solar cell; (d) measure a second current value and a second voltage value generated by the solar cell when the solar cell is illuminated by the second simulated solar luminosity; (e) presume a series resistance, use a first calculation process to gain a total resistance, use a second calculation process, series resistance, the first current value and the first voltage value to gain a first photocurrent value, and the values of a voltage across diode and a diode current can be gained by the first current value and the first voltage value; (f) a second photocurrent value can be gained in accordance with the second calculation process, the series resistance, the second current value and the second voltage value; (g)a calculated voltage value and a calculated current value can be gained in accordance with the series resistance, the total resistance, the second photocurrent value, the value of the voltage across diode and the diode current value; (h) use the root mean square error (RMSE) between the calculated voltage value and the calculated, and the second voltage data and the second current data, respectively; (i) if the value of the RMSE is larger than a certain value, then repeat from step (e) to step (h), if it's less than a certain value, then the second series resistance is the series resistance of the solar cell.
Another embodiment of the present invention further includes isolating the solar cell from outside luminosity source before step (a), so as to avoid any possible impact factors when measuring the solar cell.
Another embodiment of the present invention further includes switching off the first simulated solar luminosity after step (b), and the step of switching off the second simulated solar luminosity after step (d), so as to avoid any possible impact factors when measuring the solar cell.
a) illustrates the I-V curve of the multi-crystal silicon diode.
b) illustrates the I-V curve of the amorphous silicon diode.
The method for extracting of solar cell parameters of the present invention gains the actual series resistance mainly through the actual equivalent circuit figure of
Because the series resistance Rs and the shunt resistance Rsh are both constant, under the condition of the simulated solar luminosity with the same intensity, the photocurrent Iph, voltage across diode VD and the current across diode f(VD) are all constant; hence, under the condition of the simulated solar luminosity with the same intensity, the measured current Im and the measured voltage Vm of the solar cell are both constant.
Because the equivalent circuit of solar cell is already disclosed in
When the voltage across diode VD is zero, the current across diode f(VD) is also zero, at the same time, the power of the solar cell is provided by the photocurrent Iph;
When the voltage across diode VD is less than zero, the current across diode f(VD) is close to a negative value −f0, which is attributed to the leakage current of shunt resistance Rsh;
Photocurrent Iph will change with the differences of the intensity of the simulated solar luminosity.
From the second presumption, it can be predicted that when the voltage across diode VD is less than zero, the measured voltage VD is also less than zero. With equations (1) and (2), measured voltage VD can be removed, and the following equations can be gained:
The total resistance of solar cell is presumed to be Rt, then Rt=Rs+Rsh. Together with equations (1) and (2), the following equations can be gained:
Moreover, the following equation can be gained from presumption (a):
I
ph
=−I
m(Vm@VD=0) (7)
Presume a series resistance Rs, and use equation (3) to gain a total resistance Rt. With equation (4), series resistance Rs, the first current value Im1 and the first voltage value Vm1, a first photocurrent value Iph1 can be gained. Insert the five values into equations (3), (5) and (6), a first photocurrent value Iph1 can be gained, and insert the five values, the series resistance Rs, the total resistance Rt, the first photocurrent value Iph1, the first current value Im1, the first voltage value Vm1 into equations (3), (5) and (6), a voltage across diode VD and a current across diode f(VD) can be gained. According to equation (4), the series resistance Rs, the total resistance Rt, the second current value 1m2 and the second voltage value Vm2, a second photocurrent value Iph2 can be gained. According to the series resistance Rs, the total resistance Rt, the second photocurrent value Iph2, the voltage across diode VD and the current value of the diode f(VD), insert the five values into equations (3), (5) and (6), a calculated voltage value Vmc and a calculated current value Imc can be gained. Finally, the calculated voltage value Vmc and the calculated current value Imc form a value, and the second voltage value Vm2 and the second current value Im2 form another value. Use root mean square error between the two values gained above, if the value of the RMSE is larger than a certain value, steps (e)˜(h) are repeated; and if the value of the RMSE is less than a certain value, the second series resistance Rs2 is the series resistance of the solar cell. Moreover, the measuring of the intrinsic series resistance value and other parameters is completed. Consequently, the I-V curve of the solar cell of the present invention does not need to be presumed, all parameters of the solar cell can be gained accurately, which is really practical.
Moreover, after the completion of step S2, the step of switching off the first simulated solar luminosity is further included, to avoid any possible impact on the current value and the voltage value when the solar cell is illuminated by the second simulated solar luminosity with the second intensity. Same as above, after the completion of Step S4, the step of switching off the second simulated solar luminosity is further included, to avoid any possible impact on the current value and the voltage value when the solar cell is illuminated by the third simulated solar luminosity.
In the present invention, the first simulated solar luminosity and the second simulated solar luminosity (i.e. all the simulated luminosities with different intensity) is provided by a solar luminosity generating unit. Therefore, during measurement, the user has to control the simulated luminosity manually to change the intensity of solar luminosity. If the number of the solar cells to be measured is too large, the loading of the users will be increased. As a result, the solar luminosity generating unit used in the present invention can be switched to the second simulated solar luminosity automatically to reduce the work load of the users switching manually after a certain period of time of simulated solar luminosity is provided, such as 5 seconds or 10 seconds, until the first current value and the first voltage value are constant. Furthermore, when the second current value and the second voltage value are constant, the solar luminosity generating unit will switch off automatically until being driven again the next time so as to save unnecessary electricity consumption.
a) illustrates the I-V characteristics of a multi-crystal diode. First gain the series resistance from the equation and two luminosities, and then use the gained series resistance to further gain the I-V characteristic figure of diode of
Although this invention is disclosed above with the preferred embodiments, the embodiments above do not intend to limit the present invention. Any person who is skilled in the art can make a little modification and revision without departing from the scope and spirit of the present invention. Therefore, the scope of the present invention is defined by the appended claims.
Number | Date | Country | Kind |
---|---|---|---|
099120405 | Jun 2010 | TW | national |
This Non-provisional application claims priority under 35 U.S.C. §119(a) on Patent Application No(s). 099120405 filed in Taiwan, Republic of China, Jun. 23, 2010 the entire contents of which are hereby incorporated by reference.