WO2013011007A2 - Method for carrying out measurements on solar cells and corresponding device - Google Patents

Abstract

The invention relates to a method and a device (10) for carrying out measurements on solar cells, said method and device being particularly suitable for monitoring quality during solar cell production. According to said method for carrying out measurements on solar cells, in which a solar cell (22) is irradiated by a radiation source (12) and in which the solar cell (22) is partially shaded, a temperature distribution across the solar cell (22) during the partial shading process and the number of regions having a temperature value that is higher than other temperature values on the cell (22) are recorded. A measuring device (24) for recording a temperature distribution across the solar cell (22) and an evaluation unit (30) for comparing temperature values from the temperature distribution with a threshold value are provided for the device (10) that comprises a radiation source (12) and a shading device (18).

Description

 Method for measuring solar cells and corresponding device

The present invention relates to a method for measuring solar cells, in which a solar cell is irradiated with a radiation source and the solar cell is partially shaded. It also relates to a device with a radiation source and a shading device.

Such methods and devices are well known. The standard IEC 61215: 2005, Chapter 10.9, describes the measurement of short circuits in solar cells in the module to detect critical cells. For this purpose, a solar cell module is illuminated, and a current-voltage characteristic is measured. Then individual solar cells of the module are covered, e.g. by templates, and a drop in short-circuit current is evaluated, whereby a solar cell is determined, at which the largest current drop is measured. Optionally, the solar cell can also be determined from the module at which the highest temperature is measured. It can then be determined whether the current of the module remains below a certain threshold when the detected solar cell is covered. If this is the case, the covered area is reduced in each case determined solar cell, e.g. by moving templates until the current level is as close as possible to the threshold. If the module is kept at a constant short-circuit current, e.g. illuminated with a second radiation source, a temperature value of the module should be at 50 ° C ± 10 ° C. If a solar cell of the module exceeds the specified values, the entire module is sorted out.

Individual solar cells have been tested in solar cell manufacturing so far in the known methods in the dark, e.g. by energizing and measuring the temperature with a

Infrared camera. However, this does not correspond to the real conditions with respect to solar lighting and shading and there is no satisfactory measure of the quality of the solar cells. Thus, e.g. Short circuits are detected under

Circumstances are not critical to the operation of solar cells in the module. On the other hand, it can also happen that bad solar cells are not sorted out in the known methods.

It is an object of the present invention to provide a method and a device that is particularly suitable for quality monitoring in solar cell production. This object is achieved by the method according to claim 1. In a method for measuring solar cells, wherein a solar cell is irradiated with a radiation source, and wherein the solar cell is partially shaded, provided that a temperature distribution on the solar cell during the partial Abschattens is detected, and that a number of areas is detected whose respective temperature value is higher than other temperature values on the solar cell.

An advantage of the method is that each solar cell taken in isolation can be measured in detail and can be determined from its properties, whether it is suitable for operation in a solar cell module.

Preferably, local maxima or temperature values which exceed a first threshold value can be determined from the temperature distribution.

Preferably, the partial shadowing takes place in a predetermined number of steps, with a shaded area increasing with each step. From this, it is possible to check for a large number of different shades whether a threshold value is exceeded. The partial shading can also be carried out several times in succession, wherein a direction in which the shaded area increases, can be changed, that is, for example, the shaded area on the solar cell in a first Abschattungsvorgang from left to right and in a second

Shading process from top to bottom extend. In each step, the solar cell can be illuminated for a certain period of time, e.g. In the range of

Milliseconds to seconds. Likewise, the shaded area can be reduced with each step.

The solar cell may preferably be shaded in the predetermined number of steps from 0% to 100%. The steps may be the same size, i. there is a linear increase in shading, so that e.g. at five steps in a first step a shading of 20%, in a second step a shading of 40%, in a third step, a shading of 60%, in a fourth step, a shading of 80% and in a fifth step a shading of 100% is achieved. The shading may also be non-linear, e.g. can in four steps in a first step one

Shading of 10%, in a second step a shading of 30%, in one third step shading of 60% and in a fourth step shading of 100% can be achieved. By varying the number of steps can be any

Accuracy can be achieved, the accuracy increases as more steps are used. For example, the shaded area may also be in 1% increments, i. be enlarged in one hundred steps. Alternatively, the shading can also vary continuously between 0% and 100%.

Preferably, at least one region whose respective temperature value is higher than other temperature values on the solar cell can be shaded, and the shading that covers this region can be increased or decreased in a predetermined number of steps. In this case, the shading in turn can be done gradually until the entire solar cell is shaded or illuminated. That is, when the shading is increased, an illuminated area of the solar cell is reduced, and when the shading is reduced, an illuminated area of the solar cell is increased. The shading, as well as the illumination, may e.g. by forming shaded concentric circles around the respective region whose respective temperature value is higher than other temperature values on the solar cell whose diameter increases or decreases gradually, or by forming shaded concentric squares. The shading may also have any other shapes, so that e.g. also several different, not even

contiguous areas on the solar cell can be shaded. Likewise, several, non-contiguous areas can be illuminated and the other areas are shaded. Alternatively, an area or each area whose respective temperature value is higher than other temperature values on the solar cell may be shaded in a first or last step of a predetermined number of steps, with a shaded area decreasing or increasing with each step. In this case, in a last or first step, a larger area around the area, whose respective temperature value is higher than other temperature values on the solar cell, illuminated while the

Environment, ie the remaining solar cell is shaded. The illuminated area has, for example, the shape of a circle or square, with the area whose respective temperature value is higher than other temperature values on the solar cell, as the center. As the shading increases, the circle or square that is illuminated decreases concentrically. The illuminated area or according to the shaded area can also have any other shape. In particular, the area whose respective temperature value is higher than other temperature values on the solar cell need not be in the middle of the illuminated area. During the partial shading, a second temperature distribution on the solar cell can preferably be detected, and it can be determined whether temperature values from the second temperature distribution exceed a second threshold value. If this is the case, the solar cell can be sorted out. Optionally, a constant electrical load can be applied to the solar cell. This allows the parallel measurement of a characteristic, eg the current-voltage characteristic. In this way, additional properties of the solar cell can be detected.

Preferably, the solar cell can be pulsed irradiated. It can be irradiated with frequencies between 1 Hz and 500 Hz. In this way it can be prevented that a dissipation heat arising in a region spreads too much or that an average temperature of the solar cell rises too much. Advantageously, the so-called lock-in method is used, in which the difference of the individual states is measured, integrated and averaged in order to additionally minimize measurement errors due to noise.

Optionally, the solar cell can be cooled. This also has the advantage that a spread of dissipation heat generated in a region is prevented. The object is also achieved by a device comprising a radiation source and a shading device, wherein a measuring device for detecting a

Temperature distribution on the solar cell and an evaluation unit for comparing temperature values from the temperature distribution are provided with a threshold value. The device is particularly suitable for carrying out the method described above and its preferred embodiments.

An advantage of the device is that a single solar cell can be measured in detail under simulated real conditions and its suitability for operation, for example in a solar cell module, can be determined. The shading device preferably comprises a matrix with which shaded regions on the solar cell can be shaded. This may be, for example, a mirror matrix or a liquid crystal display matrix. The measuring device preferably comprises an infrared camera for measuring the

Temperature distribution over the surface of the solar cell.

Optionally, a cooling device for cooling the solar cell may be provided during the execution of the measurement of the solar cell.

The present invention will be explained in more detail with reference to a preferred embodiment. Show this

Figure 1 is a schematic representation of a first embodiment of an apparatus for carrying out the method according to the invention;

Figure 2 is a schematic representation of an example of a

 Shade device for operation with the device in Figure 1; Figure 3 is a schematic representation of a second embodiment of an apparatus for carrying out the method according to the invention;

Figure 4 is a schematic representation of a shading course

 Solar cell according to a first embodiment of the

 inventive method;

Figure 5 is a schematic representation of a shading course of a

 Solar cell according to a second embodiment of the

 inventive method;

Figure 6 is a schematic representation of a shading course

 Solar cell according to a third embodiment of the

inventive method; Figure 7 is a schematic representation of a shading course

 Solar cell according to a fourth embodiment of the

 inventive method;

Figure 8 is a schematic representation of the method according to a first

 Embodiment of the invention; and

Figure 9 is a schematic representation of the method according to a second

 Embodiment of the invention.

FIG. 1 shows a schematic representation of a device 10 according to a first exemplary embodiment of the invention. The device 10 comprises a

Radiation source 12, with the radiation 14, which in particular has a spectral range similar to that of solar radiation, via an optic, e.g. a first lens 16 is irradiated onto a matrix 18. The matrix 18 reflects the radiation from the radiation source 12 via a second lens 20 onto a solar cell 22, which serves as a projection surface of the radiation 14. A measuring device 24, e.g. an infrared camera, measures the temperature distribution over the surface of the solar cell 22. As the matrix 18 is particularly suitable

Mirror matrix 26 with a plurality of switchable or tiltable mirror 27, as shown in Figure 2. For this purpose, e.g. Each micromirror of such a mirror matrix 26 can be individually adjusted in its angle and usually has two stable end states, between which it can change up to 5000 times within one second The number of mirrors is the resolution of the projected image, where a mirror can represent one or more pixels

Digital Light Processing Projector (DLP projector). An LCD matrix (Liquid Crystal Display Matrix), as explained in more detail with respect to FIG. 3, can also be used as a matrix in the exemplary embodiment shown here. With such a known mirror matrix 26, the amount of radiation which reaches the solar cell 22 can be determined precisely. The mirror matrix 26 thus allows targeted shading of clearly defined regions on the solar cell 22. The matrix 18, 26 therefore serves not only for illuminating the solar cell 22 but also as a shading device. For driving the matrix 18, 26, a drive device 28 is provided. For the testing of solar cells, a radiation source 12 whose spectral range is as similar as possible to the sun is preferably suitable. The spectrum should be the

Standard spectrum AM1, 5 adapted and have a radiation power of 1000 W / m ² . A coupling of the radiation source 12 can be carried out, for example, by a light guide or mixing rod, for example made of glass fiber, and projected onto matrix 18 by means of this.

The measuring device 24 is coupled to an evaluation unit 30, with which the measured temperature distribution is evaluated. A number of temperature values exceeding a threshold are determined. The threshold defines one

Limit value for a temperature development on the solar cell. The area in which a high temperature occurs, is generally referred to as a hot spot (hot spot).

Solar cell modules are tested according to the IEC 61215 standard, chapter 10.9, by covering individual cells of the solar cell modules so that they can not generate any voltage. As the surrounding solar cells continue to generate voltage, the covered solar cell acts as an electrical resistance. If a blocking voltage of the covered solar cell is exceeded by the voltage of the solar cells connected in series with the covered solar cell, there current flows, which is converted into thermal power, whereby the solar cell can be destroyed and it can lead to insulation damage during operation of the solar cell in a module ,

The measuring device 24 is coupled to the drive device 28 via the evaluation unit 30, so that the adjustment of the matrix 18, e.g. the shading of a specific area on the solar cell 22 or the adjustment of the radiation intensity in a specific area, depending on the values measured by the measuring device 24, can be carried out.

FIG. 3 shows a further embodiment 32 of the device according to the invention. Here, in contrast to the embodiment shown in FIG. 1, a matrix is designed for measurements in reflection for measurements in transmission. For this purpose, e.g. a liquid crystal display matrix, also called LCD matrix 34. The LCD matrix 34 is made up of segments that can independently change their brightness. For this purpose, the segments are irradiated with unpolarized light and hit a polarizing filter, which polarizes the radiation. With electrical voltage in each segment, an alignment of the liquid crystals is controlled to hit the polarized light. This can be the

Change permeability to the polarized light. This can also be a Any desired shading of the solar cell can be achieved. The matrix 34 in FIG. 3 therefore serves not only for illuminating the solar cell 22 but also as

Abschattvorrichtung. The measuring device 24 is connected to an evaluation unit 36, which together with a drive device 38 for the matrix 34 in one

Computer 40 is arranged.

Optionally, the devices 10, 32 of FIGS. 1 and 3 may include a device (not shown) for applying electrical power to the solar cell 22. For this purpose, a further measuring device (not shown) may be provided with which a current-voltage characteristic can be measured. This can be additional

 Characteristics of the solar cell 22 are detected. Additionally or alternatively, a cooling device (not shown) may optionally be provided for cooling the solar cell 22.

FIG. 4 shows, by way of example, a schematic representation of a shading profile 42 of a solar cell 22 according to an exemplary embodiment of the method according to the invention. The solar cell 22 is first completely illuminated (state 44), wherein a

Temperature distribution on the solar cell 22 is detected. The solar cell 22 is then increasingly shaded, e.g. State 46 shows the solar cell 22 with 30 percent shading, state 48 shows the solar cell 22 with 70 percent shading. A shaded area 50 increases from top to bottom. Between

States 44, 46, 48 can be carried out as required intermediate states with other shading values as required, in which the solar cell 22 preferably has a shadowing, which lies between the respective shadowing of the states 44, 46, 48. In a last state 51, the solar cell 22 is 100% shaded.

FIG. 5 shows by way of example a schematic representation of a second one

Shading curve 52 of a solar cell 22 according to an embodiment of the method according to the invention. This shading process may be performed instead of or following the shading process 42 shown in FIG.

Here, the shaded area 50 increases from left to right, where state 54 shows the unshaded solar cell 22, state 56 a shaded area of about 40%, state 58 a shaded area of about 93%, and state 59 a shaded area of 100 %. As already described above, any number of intermediate steps in shading can also be carried out here as required. Preferably, several shading courses are performed to areas in which a Temperature value is measured, which exceeds a first threshold, or in which a local maximum is to determine particularly accurate.

FIG. 6 shows, by way of example, a schematic representation of a third shading profile 60 of a solar cell 22 according to a third exemplary embodiment of the method according to the invention. Starting point, i. State 62 is an unshaded solar cell 22 in which one or more temperature distributions have already been measured and evaluated in one or more previous method steps, so that regions were determined in which the temperature value has exceeded a first threshold value. According to an exemplary embodiment of the method, these areas can now be deliberately shaded, the shaded area 50 increasing step by step. FIG. 6 shows in state 64 that a region 66 in which a temperature value which exceeds a first threshold value or which is maximum is measured is shaded. The temperature value can form the center of the shadowed area 50. The shaded area 50 is gradually increased as shown in states 68, 70 and 71 so that in state 71, the entire solar cell 22 is shadowed. In this case, the shaded area 50 may form concentric circles around the area in which a

Temperature value is measured, which exceeds the first threshold, the diameter of each increased. For example, instead of concentric circles, the shadowed area 50 may also be formed by concentric squares. For each state 64, 68, 70, 71 an associated temperature distribution is measured. From this, it is evaluated whether one or more temperature values exceed a second threshold value. If this is the case, the solar cell 22 is sorted out. Alternatively, it is also possible to start with a solar cell 22 which is completely or at least partially shaded, the illuminated area then being stepped around the region in which a

 Temperature value is measured, which exceeds a first threshold, or the maximum is increased. There may also be several areas where one

Temperature value is measured, which exceeds a first threshold, or is the maximum, gradually more shaded or illuminated. Because the

different areas on the solar cell 22 may occur at any distance from each other, the shaded or illuminated area may have corresponding, not contiguous, forms.

FIG. 7 shows by way of example a schematic illustration of a fourth shading curve 72 of a solar cell 22 according to a fourth exemplary embodiment of the invention Process. Again, the initial state 74 is an unshielded solar cell 22 for which one or more temperature values exceeding a first threshold or maximum are measured during previous process steps. For the or one of these temperature values, a shaded area 76 is now incremented by the area 78 in which this temperature value was measured, but from outside to inside, so that the area 78 in which the temperature value was measured remains illuminated the longest , that is shaded only in a last Abschattungsschritt. The states 80, 82, 84 show different sized shaded areas 76, 86, 88 and different sized illuminated areas 90, 92, 94. In state 95 is the entire

Solar cell 22 shaded. The illuminated areas 90, 92, 94 form in the example shown here concentric squares around the temperature value. Alternatively, the

Illuminated areas 90, 92, 94 also form concentric circles, or any other geometric shapes. Again, between the individual states 74, 80, 82, 84 may be any intermediate steps in which the shadowed area 76 makes up a different percentage of the solar cell 22. As already described in connection with FIG. 6, to each state 80, 82, 84 (and optionally to

Intermediate states), a temperature distribution on the solar cell 22 is measured and the temperature values of the temperature distribution are evaluated with respect to a second threshold value. So can solar cells 22, in which one or a number of

Temperature values exceed the second threshold, be sorted out.

The shading profiles 42, 52, 60, 72 shown in FIGS. 4 to 7 can also run in opposite directions in the direction of the arrow, so that the respective shaded area is successively reduced in size, ie. the solar cell 22 is illuminated in an increasingly large area. Also, multiple areas may be illuminated when e.g. several high temperature values were detected on the solar cell 22. Depending on the distribution of the high temperature values, the regions may also be discontinuous, at least in some shading or lighting process steps. In several illuminated or shaded areas, these can also be

have different, arbitrary shapes.

8 shows a schematic representation of the method 96 according to a first

Embodiment of the invention shown. In a first step 98, a solar cell is irradiated with a radiation source. In a second step 100, a first temperature distribution on the solar cell is measured. The solar cell is in a third Step 102 partially shaded and measured another first temperature distribution, eg with an infrared camera. In a fourth step 104, the shaded area on the solar cell is enlarged and a further first temperature distribution is measured.

In each case, the solar cell is preferably increasingly shaded in several steps, with a temperature distribution being measured for each step. In a fifth step 106, the temperature distributions are evaluated, whereby areas are determined in which temperature values from the or each temperature distribution exceed a first threshold value. In a sixth step 108, the area or one of the areas where a temperature value exceeding the first threshold value is shaded is shaded, and the shading is optionally increased with this area as the center point in a predetermined number of steps, with each step a second temperature distribution is measured. The sixth step 108 may be repeated with another region in which a temperature value exceeding the first threshold is repeated as a midpoint. In a seventh step 110, it is determined whether temperature values from the second temperature distribution exceed a second threshold value. If this is the case, the measured solar cell is sorted out. Instead of temperature values which exceed a first threshold value, local temperature maxima can alternatively be determined from the first temperature distribution in the fifth step 106. Then, the positions of the temperature maxima on the solar cell form the respective center of the shaded area during the sixth step 108.

FIG. 9 schematically shows a further embodiment 1 12 of the method according to the invention. The first four steps 98, 100, 102, 104 correspond to the method shown in FIG. In a fifth step 14, regions are determined from the temperature distribution in which the temperature is maximum. In a sixth step 16, the solar cell 22 is again shaded, wherein a region in which a temperature value is maximum is shaded in a last step of a predetermined number of steps, wherein a shaded area increases with each step. For each step, a second temperature distribution is measured. Shading may, according to the sixth step 16, be for one or more further areas in which a maximum

Temperature value measured will be repeated. In a seventh step 1 18 it is determined whether temperature values from the second temperature distribution have a second

Exceed threshold. In this case, the measured solar cell is sorted out. During each or selected steps 98-1 18 of the method 1 12, an electrical load can be applied to the solar cell, so that parallel to the measurement and Evaluation of the first and second temperature distribution (steps 100, 102, 104, 1 14) and a characteristic, such as the current-voltage characteristic, can be measured and evaluated. In one or more optional additional steps, an evaluation of the respective temperature distribution and the characteristic curve can be compared with each other and used for evaluation or to decide on a sorting.

In the embodiments of the method according to the present invention, the solar cell can be illuminated in each case with pulsed radiation. The lock-in method can also be used to reduce the noise of the measured values. For this purpose, the temperature can be measured several times, for example in the illuminated and non-illuminated state, and the mean value of the respectively measured temperatures can be formed.

Claims

1 claims

1. A method for measuring solar cells, wherein a solar cell with a

Radiation source is irradiated, and wherein the solar cell is partially shaded, characterized in that

a temperature distribution is detected on the solar cell during the partial Abschattens, and that

a number of areas is detected whose respective temperature value is higher than other temperature values on the solar cell.

2. The method according to claim 1,

characterized in that

from the temperature distribution local maxima or temperature values exceeding a first threshold can be determined.

3. The method according to claim 1 or 2,

characterized in that

the partial shading takes place in a predetermined number of steps, wherein a shaded area is increased or decreased with each step.

4. The method according to claim 3,

characterized in that

the solar cell in the specified number of steps from 0% to 100%

is shadowed.

5. The method according to any one of claims 1 to 4,

characterized in that

at least one area whose respective temperature value is higher than other temperature values on the solar cell is shaded and the shading which detects this area is increased or decreased in a predetermined number of steps.

6. The method according to any one of claims 1 to 4,

characterized in that 2

at least one area whose respective temperature value is higher than other temperature values on the solar cell is shaded in a first or last step of a predetermined number of steps, wherein a shaded area decreases or increases with each step.

7. The method according to claim 5 or 6,

characterized in that

during the partial shading, a second temperature distribution on the solar cell is detected and it is determined whether temperature values from the second temperature distribution exceed a second threshold.

8. The method according to any one of claims 1 to 7,

characterized in that

a constant electrical load is applied to the solar cell.

9. The method according to any one of claims 1 to 8,

characterized in that

the solar cell is pulsed irradiated.

10. The method according to any one of claims 1 to 9,

characterized in that

the solar cell is cooled.

1 1. Device for measuring solar cells, comprising a radiation source and a shading device,

marked by

a measuring device (24) for detecting a temperature distribution on the solar cell (22) and an evaluation unit (30) for comparing temperature values from the temperature distribution with a threshold value.

12. Device according to claim 1 1,

characterized in that

the shading device (18, 26, 34) comprises a matrix (18, 26, 34) with which predetermined areas (50, 76, 86, 88) on the solar cell (22) can be shaded.

13. Device according to claim 1 1 or 12, characterized in that

the measuring device (30) comprises an infrared camera.

14. Device according to one of claims 1 1 to 13, characterized by

a cooling device for cooling the solar cell (22).