RU234738U1 - Portable laboratory research stand for studying the parameters and characteristics of solar photovoltaic cells - Google Patents

Abstract

The utility model relates to research devices for studying the parameters and characteristics of solar photovoltaic elements intended for use in solar batteries of spacecraft, for express input control, and for selecting solar elements with identical characteristics for solar batteries. A portable laboratory and research stand is proposed for studying the parameters and characteristics of solar cells and their input express control, comprising an analog-to-digital converter, a microcontroller, a controlled light source for irradiating solar cells and a device for repeatable fixation of the tested solar cell, connected in an electric circuit using connecting wires, placed in a single housing, characterized in that it additionally includes a controlled current source, regulated by the microcontroller and designed with the possibility of automating the process of work on the stand, and the first and second contacts of the fixation device are secured in the housing with ensuring the same location of the tested solar cell relative to the controlled light source, wherein the first terminal of the controlled current source, the first terminal of the analog-to-digital converter and the first contact of the fixation device are connected to each other, and the second terminal of the controlled current source, the second terminal of the analog-to-digital converter and the second contact of the fixation device are connected to each other. Carrying out measurements in a batch of solar cells will allow rejecting samples unsuitable for use, selecting the most similar in characteristics for use in a single solar battery, and also having a history of their characteristics for measuring the degradation of these characteristics over time in the case of thermal vacuum and other tests.

Description

The utility model relates to research installations and devices for studying the volt-ampere and power characteristics of solar photovoltaic cells intended for use in solar batteries of spacecraft, for express input control, and for selecting solar cells with identical characteristics for solar batteries.

A laboratory stand for studying the characteristics of solar photovoltaic modules is known (Patent of the Russian Federation No. 91776 G09B 23/18, 2010). The stand contains a light source based on incandescent lamps, the light of which falls on the surface of a solar photovoltaic module optically connected to it, a load for consuming electrical energy, and a cooling unit for the solar photovoltaic module, made in the form of a fan.

The disadvantage of the known laboratory stand for studying the characteristics of solar photovoltaic modules is the limited functionality due to the impossibility of its long-term operation, which is necessary when conducting experiments that require a significant amount of time. This disadvantage is due to the fact that the spectrum of the light radiation generated by the incandescent lamp-based source has a large share of infrared (thermal) radiation, compared to natural sunlight, and when conducting long-term experiments, for example, to simulate the operating modes of an autonomous solar power plant with an electric energy storage device, excessive heating of the surface of the solar photovoltaic module occurs in a time shorter than required by the experimental conditions.

The result of this is a change in the parameters of the solar photovoltaic module during the measurement process and unreliable data obtained.

The closest in technical essence to the proposed utility model is a laboratory research stand for studying the characteristics of solar cells and a battery of solar cells (Patent of the Russian Federation No. 111314, class G02B 27/20, 2011). The stand contains a battery of solar cells, a light source fixed on a movable stand above the solar cells, a lux meter, an ammeter, a voltmeter, a demonstration load, which are connected in an electric circuit using wires, as well as a variable load, which is two resistors, and to measure the dark characteristic of one of the solar cells, other solar cells are used, connected according to the circuit. The stand is also additionally equipped with an accumulator, charged from the solar cells and used to measure the dark characteristic.

Disadvantages of the laboratory research stand for studying the characteristics of solar cells and solar cell batteries: the stand does not have the ability to automatically record the volt-ampere and power characteristics of solar cells for different time intervals, and also has additional measuring devices (ammeter, voltmeter, luxmeter) and batteries, which complicate and increase the cost of the design of this stand.

The technical task of the utility model is to create a device for studying the volt-ampere and power characteristics of solar cells and their input express control, which would allow obtaining a significant technical result, namely, to eliminate the shortcomings of known devices using incandescent lamps - measuring the volt-ampere and power parameters of solar cells in the process of removing their characteristics, to reduce the cost and simplify the design of the device due to the absence of external measuring devices, and also to optimize the process of working on the device due to the arrangement of components in the form of a single device performing the study, providing visual control of the measurement process and automatic recording of readings and plotting graphs.

The said problem is solved in that a portable laboratory research stand is proposed for studying the volt-ampere and power characteristics of solar cells and their input express control, comprising an analog-to-digital converter, a microcontroller, a controlled light source for irradiating solar cells and a device for repeatable fixation of the tested solar cell, connected in an electric circuit using connecting wires, placed in a single housing, characterized in that it additionally includes a controlled current source, regulated by a microcontroller, configured with the possibility of connecting to a control computer via a connector for a USB interface, and the fixation device contains first and second contacts fixed in the housing, for holding the solar cell relative to the light source, wherein the first terminal of the controlled current source, the first terminal of the analog-to-digital converter and the first contact of the fixation device are connected to each other, and the second terminal of the controlled current source, the second terminal of the analog-to-digital converter and the second contact of the fixation device are connected to each other.

The technical essence of the presented invention is explained by the drawings:

Fig. 1 shows a possible design of a stand for studying the characteristics of solar cells,

in this case, the following designations are adopted in Fig. 1:

1 - printed circuit board control;

2 - microcontroller;

3 - controlled current source;

4 - analog-to-digital converter;

5 - controlled light source;

6 - the tested solar cell placed in the fixation device;

7 - stand body;

9 - the first contact of the solar cell fixing device 6 (located underneath it, shown with a dashed line);

10 - the second contact of the solar cell fixing device 6;

11 - stand housing cover 7;

12 - connector of the standard communication interface, for which USB is selected, for communication with the control computer 8 (not shown in Fig. 4).

Fig. 2 shows the structural diagram of the proposed stand.

In Fig. 2 the following notations are used:

1 - printed circuit board control, on which the microcontroller 2, controlled current source 3 and analog-to-digital converter 4 are located;

2 - microcontroller;

3 - controlled current source;

4 - analog-to-digital converter;

5 - controlled light source;

6 - solar cell under test;

7 - stand body;

8 - control computer.

Fig. 3 shows the current taken from the voltage with constant illumination of the solar cell.

Fig. 4 shows the maximum possible power extracted from a solar cell.

A portable laboratory and research stand for studying the characteristics of solar cells (Fig. 1) consists of a printed circuit board 1 of the control, on which a microcontroller 2, a controlled current source 3, an analog-to-digital converter 4 are placed and connected into an electric circuit using connecting wires, the microcontroller 2 is connected to the control computer 8 via a standard interface, which is selected as USB, brought out to the connector 12, a light source 5 controlled by the microcontroller 2 for irradiating the tested solar cells 6 and located in the housing of the stand 7, wherein the first terminals (I) of the controlled current source 3, the analog-to-digital converter 4 and the device for fixing the tested solar cell 6 are connected to each other and the second terminals (II) of the controlled current source 3, the analog-to-digital converter 4 and the device for fixing the tested solar cell 6 are also connected to each other. The solar cell fixing device includes two contacts for holding the solar cell and a positioning device, wherein the design of the repeatable solar cell fixing device 6 ensures an invariable and repeatable positioning of the solar cell 6 relative to the controlled light source 5.

Method of application of the utility model:

Before the measurement cycle, the solar cell 6 is installed with the photoreceiver side down in the direction of the controlled light source 5 in the fixing device of the stand housing 7 (Fig. 1) between the first contact 9 and the second contact 10 of the fixing device, with the positioning device providing an unchanged and repeatable location of the solar cell 6 relative to the controlled light source 5. When the cover 11 of the stand housing 7 is closed, the measurement process is initiated. In this case, the required luminous flux from the controlled light source 5, regulated by the microcontroller 1, made of light-emitting diodes with the required spectral radiation curve, is set and fixed constant. Then, the voltage generated by the solar cell 6 is measured by the analog-to-digital converter 4, with the controlled current source 3 connected in parallel to it as a load. By controlling the current source 3, for example, according to a linear law with time in the direction of its increase, we measure the volt-ampere characteristic of the solar cell 6 at a constant illumination. If necessary, the measurement process is carried out at other values of the luminous flux. In case of significant luminous fluxes, additional cooling of the controlled current source 5 is possible, for example, using fans.

A typical view of the obtained measurement results is presented in the form of graphs in Fig. 3 and 4. The maximum of the graph in Fig. 4 corresponds to the maximum possible power removed from the solar cell at a given illumination and is used in the design of power supply systems for small spacecraft.

The tested solar cell 6 for this example was a polysilicon cell measuring 78 x 26 mm and having an effective area of about 20 cm ² . The data were obtained at a total illumination intensity of about 1300 W/m ² , of which about 350 W/m ² was in the carrier generation zone of the solar cell. The output power of such a solar cell is about 0.12 W.

The solar cell is marked with an individual code, for example using a marking printer. The measurement results are entered into a common database.

Carrying out measurements in a batch of solar cells will allow rejecting samples unsuitable for use, selecting the most similar in characteristics for use in a single solar battery, and also having a history of their characteristics for measuring the degradation of these characteristics over time in the case of thermal vacuum and other tests.

Sources of information

1. Patent of the Russian Federation No. 91776 G09B 23/18, 2010.

2. Patent of the Russian Federation No. 111314, class G02B 27/20, 2011.

Claims (1)

A portable laboratory and research stand for studying the volt-ampere and power characteristics of solar cells, comprising an analog-to-digital converter, a microcontroller, a controlled light source for irradiating solar cells and a device for repeatable fixation of a tested solar cell, connected in an electric circuit using connecting wires, placed in a single housing, characterized in that it additionally includes a controlled current source, regulated by a microcontroller, configured with the possibility of connecting to a control computer via a connector for a USB interface, and the fixation device contains first and second contacts secured in the housing for holding the solar cell relative to the light source, wherein the first terminal of the controlled current source, the first terminal of the analog-to-digital converter and the first contact of the fixation device are connected to each other, and the second terminal of the controlled current source, the second terminal of the analog-to-digital converter and the second contact of the fixation device are connected to each other.