CN220087259U - Photovoltaic module thermal cycle test cabin - Google Patents

Abstract

The utility model relates to the technical field of photovoltaic production, in particular to a photovoltaic module thermal cycle test cabin which comprises an experiment cabin, a top cover module, a solar panel, a heat insulation board, a hydraulic cylinder, a heating block, two sliding grooves, a detection module and a cooling unit, wherein the cooling unit comprises a connecting pipe, an air cooler, an intelligent terminal, an air outlet pipe and a temperature sensor, the top cover module is opened, the solar panel is placed in the sliding grooves to slide to the bottom and be communicated with the detection module, the top cover module is closed, the heating block is opened for heating, the temperature of the air which is transmitted by the temperature sensor is observed, the air cooler is opened to suck air into the experiment cabin from the outside, so that the effect of cooling the inside of the experiment cabin is achieved, the hot air is discharged outwards from the air outlet pipe, and is discharged into the experiment cabin after the cooling treatment in such a way, so that the solar panel is cooled, and is favorable for workers to take the test efficiency of the workers is improved.

Description

Photovoltaic module thermal cycle test cabin

Technical Field

The utility model relates to the technical field of photovoltaic production, in particular to a thermal cycle test cabin of a photovoltaic module.

Background

Solar energy is inexhaustible renewable energy for human beings, has the advantages of sufficient cleanliness, absolute safety, relative universality, long service life, maintenance-free property, sufficiency of resources, potential economy and the like, has an important role in long-term energy strategy, and a photovoltaic module is a key part in a photovoltaic power generation system and consists of high-efficiency crystalline silicon solar cells, ultra-white textured toughened glass, EVA, transparent TPT back plates and aluminum alloy frames.

After the experiment of the solar panel in the cabin is completed, the surface temperature of the solar panel is higher, and workers can be scalded easily when the workers are directly held by hands.

Disclosure of Invention

The utility model aims to provide a thermal cycle test cabin of a photovoltaic module, and aims to solve the problems that after the experiment of a solar panel in a cabin body is completed, the surface temperature of the solar panel is high, and workers are easy to scald when the solar panel is directly held by hands.

In order to achieve the above purpose, the utility model provides a photovoltaic module thermal cycle test cabin, which comprises an experiment cabin, a top cover assembly, a solar panel, a heat insulation board, a hydraulic cylinder, a heating block, two sliding grooves, a detection assembly and a cooling unit, wherein the cooling unit comprises a connecting pipe, an air cooler, an intelligent terminal, an air outlet pipe and a temperature sensor, the top cover assembly is covered on the experiment cabin, the heat insulation board is horizontally arranged in the experiment cabin, the hydraulic cylinder is fixedly connected with the experiment cabin and is positioned at the bottom of the experiment cabin, the two sliding grooves are fixedly connected with the experiment cabin and are respectively positioned on the inner wall of the experiment cabin, the two ends of the solar panel are in sliding connection with the two sliding grooves and are positioned in the two sliding grooves, the output end of the hydraulic cylinder penetrates through the heat insulation board and is connected with the detection assembly and is positioned below the detection assembly, the detection assembly is detachably connected with the solar panel and is positioned below the solar panel, the heating block is fixedly connected with the experiment cabin and is fixedly connected with the air cooler, the experiment cabin is fixedly arranged on one side of the experiment cabin and is fixedly connected with the air cooler, and is fixedly connected with the experiment cabin, and is fixedly positioned on one side of the experiment cabin.

The top cover assembly comprises a cover and a sealing ring, the cover is detachably connected with the experiment cabin and located at the top of the experiment cabin, the sealing ring is fixedly connected with the cover and located below the cover, and the sealing ring is in contact with the experiment cabin.

The detection assembly comprises a detection machine and a connection block, wherein the connection block is fixedly connected with the hydraulic cylinder and is positioned at the output end of the hydraulic cylinder, the detection machine is fixedly connected with the connection block and is positioned above the connection block, the detection machine is detachably connected with the solar panel and is positioned below the solar panel, and the detection machine is electrically connected with the intelligent terminal.

The photovoltaic module thermal cycle test cabin further comprises a handle and a storage hook, wherein the handle is fixedly connected with the cover and is located above the cover, and the storage hook is fixedly connected with the test cabin and is located on one side of the test cabin.

The photovoltaic module thermal cycle test cabin further comprises four universal wheels, wherein the four universal wheels are rotationally connected with the test cabin and are respectively located at the bottom of the test cabin.

According to the photovoltaic module thermal cycle test cabin disclosed by the utility model, the top cover assembly is opened, the solar panel is placed in the chute to slide to the bottom and be communicated with the detection assembly, the top cover assembly is closed, the heating block is opened at the same time, the solar panel is heated, after the data on the intelligent terminal are recorded, the temperature transmitted by the temperature sensor is recorded, the air cooler is opened to suck air into the interior of the test cabin from the outside, meanwhile, the air is subjected to temperature reduction treatment, so that the effect of cooling the interior of the test cabin is achieved, hot air is discharged outwards from the air outlet pipe, the top cover assembly is opened to enable the hydraulic cylinder to move the solar panel upwards, the original model is recovered after the hydraulic cylinder is removed, the air is cooled in the test cabin in a cooling manner, and the solar panel is cooled, so that the test cabin is favorable for workers to take the air, and the test efficiency of the workers is improved.

Drawings

In order to more clearly illustrate the embodiments of the present utility model or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below.

Fig. 1 is a schematic overall structure of a first embodiment of the present utility model.

Fig. 2 is a left side view of a first embodiment of the present utility model.

Fig. 3 is a cross-sectional view taken along line A-A of fig. 2 in accordance with the present utility model.

Fig. 4 is a schematic overall structure of a second embodiment of the present utility model.

101-experiment cabin, 102-top cover assembly, 103-solar panel, 104-heat insulation board, 105-hydraulic cylinder, 106-heating block, 107-chute, 108-detection assembly, 109-cooling unit, 110-connecting pipe, 111-air cooler, 112-intelligent terminal, 113-air outlet pipe, 114-temperature sensor, 115-lid, 116-sealing ring, 117-detector, 118-connecting block, 201-handle, 202-object placing hook and 203-universal wheel.

Detailed Description

The following detailed description of embodiments of the utility model, examples of which are illustrated in the accompanying drawings and, by way of example, are intended to be illustrative, and not to be construed as limiting, of the utility model.

First embodiment:

referring to fig. 1 to 3, fig. 1 is a schematic overall structure of a first embodiment of the present utility model, fig. 2 is a left side view of the first embodiment of the present utility model, and fig. 3 is a sectional view taken along line A-A of fig. 2.

The utility model provides a photovoltaic module thermal cycle test cabin, which comprises a test cabin 101, a top cover assembly 102, a solar panel 103, a heat insulation plate 104, a hydraulic cylinder 105, a heating block 106, two sliding grooves 107, a detection assembly 108 and a cooling unit 109, wherein the cooling unit 109 comprises a connecting pipe 110, an air cooler 111, an intelligent terminal 112, an air outlet pipe 113 and a temperature sensor 114, the top cover assembly 102 comprises a cover 115 and a sealing ring 116, and the detection assembly 108 comprises a detector 117 and a connecting block 118.

For this embodiment, after cooling the air by the air cooler 111, the air is discharged into the experiment cabin 101 through the connecting pipe 110, so as to cool the parts of the experiment cabin 101, and the hot air is discharged from the air outlet pipe 113, so that a worker can test the solar panel 103 quickly, and the model of the temperature sensor 114 is PT100.

Wherein the top cover assembly 102 is covered on the experiment cabin 101, the heat insulation plate 104 is horizontally arranged in the experiment cabin 101, the hydraulic cylinder 105 is fixedly connected with the experiment cabin 101, the two sliding grooves 107 are fixedly connected with the experiment cabin 101, the two ends of the solar panel 103 are slidably connected with the two sliding grooves 107, the output end of the hydraulic cylinder 105 penetrates through the heat insulation plate 104 and is connected with the detection assembly 108, the detection assembly 108 is detachably connected with the solar panel 103, the heating block 106 is fixedly connected with the experiment cabin 101, the air cooler 111 is fixedly connected with the experiment cabin 101, the two ends of the connecting pipe 110 are communicated with the experiment cabin 101 and the air cooler 111, the temperature sensor 114 is fixedly connected with the experiment cabin 101, the intelligent terminal 112 is fixedly connected with the experiment cabin 101, the temperature sensor 114 is electrically connected with the intelligent terminal 112, the air outlet pipe 113 is communicated with the experiment cabin 101, the top cover assembly 102 is opened, the solar panel 103 is placed in the chute 107 to slide to the bottom and is communicated with the detection assembly 108, the top cover assembly 102 is closed, the heating block 106 is opened at the same time, the solar panel 103 is heated, the data on the intelligent terminal 112 is observed, after the data are recorded, the temperature transmitted by the temperature sensor 114 is recorded, the air cooler 111 is opened to suck air into the experiment cabin 101 from the outside so as to achieve the effect of cooling the inside of the experiment cabin 101, the hot air is discharged from the air outlet pipe 113 outwards, the top cover assembly 102 is opened so that the solar panel 103 is moved upwards by the hydraulic cylinder 105, the original model is restored after the data are taken down, through the mode, air is discharged into the experiment cabin 101 after being cooled, so that the solar panel 103 is cooled, and the air is favorable for workers to take, thereby improving the testing efficiency of the workers.

Secondly, lid 115 with be connected is dismantled to experiment cabin 101, sealing washer 116 with lid 115 fixed connection, sealing washer 116 with experiment cabin 101 contact, will lid 115 is taken off from the top of experiment cabin 101, and sealing washer 116 can improve the holistic leakproofness of the device, the condition that air overflows can not appear when heating and cooling, has effectively improved the efficiency of test.

Meanwhile, the connecting block 118 is fixedly connected with the hydraulic cylinder 105, the detecting machine 117 is fixedly connected with the connecting block 118, the detecting machine 117 is detachably connected with the solar panel 103, the detecting machine 117 is electrically connected with the intelligent terminal 112, the solar panel 103 is communicated with the detecting machine 117, signals are transmitted to the intelligent terminal 112 when the signals are detected, and test data are collected, so that an operator can analyze after the test is finished.

When the photovoltaic module thermal cycle test cabin is used, the cover 115 is opened, the solar panel 103 is placed in the chute 107 to slide to the bottom and communicated with the detector 117, the cover 115 is closed, the heating block 106 is opened at the same time, the solar panel 103 is heated, after the data on the intelligent terminal 112 are recorded, the temperature transmitted by the temperature sensor 114 is observed, the air cooler 111 is opened to suck air into the test cabin 101 from the outside, so that the effect of cooling the inside of the test cabin 101 is achieved, the hot air is discharged outwards from the air outlet pipe 113, the cover 115 is opened to enable the hydraulic cylinder 105 to move the solar panel 103 upwards, the original pattern is recovered after the cover is removed, the air is cooled in the test cabin 101 in a cooling manner, and the solar panel 103 is cooled by discharging the cooled air into the test cabin 101, so that the test cabin is beneficial to staff to take the air.

Second embodiment:

referring to fig. 4 on the basis of the first embodiment, fig. 4 is a schematic overall structure of a second embodiment of the present utility model.

The utility model provides a thermal cycle test cabin of a photovoltaic module, which further comprises a handle 201, a storage hook 202 and four universal wheels 203.

For this embodiment, the handle 201 may be added to quickly open the cover 115, and the storage hook 202 may rest the cover 115, and then the universal wheel 203 may facilitate moving the device.

The handle 201 is fixedly connected with the cover 115, the object placing hooks 202 are fixedly connected with the experiment cabin 101, the four universal wheels 203 are rotatably connected with the experiment cabin 101, the cover 115 can be taken away from the top of the experiment cabin 101 by pulling the handle 201, the object placing hooks 202 can be matched with the handle 201, the effect of placing the cover 115 is achieved, the universal wheels 203 can move the device under the condition that large machinery is not used, unnecessary cost expenditure is reduced, the efficiency of testing the solar panel 103 is effectively improved, and the device is simple in structure and convenient to learn and operate.

When the photovoltaic module thermal cycle test cabin is used, the handle 201 is pulled to enable the cover 115 to be taken away from the top of the test cabin 101, the object placing hook 202 can be matched with the handle 201 to achieve the effect of placing the cover 115, the universal wheel 203 can move the device under the condition that a large machine is not used, unnecessary cost expenditure is reduced, the testing efficiency of the solar panel 103 is effectively improved, and the device is simple in structure and convenient to learn and operate.

The foregoing disclosure is only illustrative of one or more preferred embodiments of the present utility model, and it is not intended to limit the scope of the claims hereof, as persons of ordinary skill in the art will understand that all or part of the processes for practicing the embodiments described herein may be practiced with equivalent variations in the claims, which are within the scope of the utility model.

Claims (5)

1. The utility model provides a photovoltaic module thermal cycle test chamber, includes experimental chamber, top cap subassembly, solar panel, heat insulating board, pneumatic cylinder, heating block, two spouts and detection component, the top cap subassembly lid closes in experimental chamber, the heat insulating board level set up in experimental chamber is interior, pneumatic cylinder with experimental chamber fixed connection, and be located the bottom of experimental chamber, two the spout all with experimental chamber fixed connection, and be located respectively experimental chamber inner wall, solar panel's both ends all with two spout sliding connection, and be located two the spout, the output of pneumatic cylinder runs through the heat insulating board and with detection component connects, and be located detection component's below, detection component with solar panel dismantles to be connected, and be located solar panel's below, heating block with experimental chamber fixed connection, and be located experimental chamber's inner wall, its characterized in that,

the cooling unit is also included;

the cooling unit comprises a connecting pipe, an air cooler, an intelligent terminal, an air outlet pipe and a temperature sensor, wherein the air cooler is fixedly connected with the experiment cabin and is positioned on one side of the experiment cabin, two ends of the connecting pipe are communicated with the air cooler and are positioned between the experiment cabin and the air cooler, the temperature sensor is fixedly connected with the experiment cabin and is positioned on the inner wall of the experiment cabin, the intelligent terminal is fixedly connected with the experiment cabin and is positioned on the outer wall of the experiment cabin, the temperature sensor is electrically connected with the intelligent terminal, and the air outlet pipe is communicated with the experiment cabin and is positioned on one side of the experiment cabin.

2. The thermal cycling test chamber of claim 1, wherein the thermal cycling test chamber comprises a plurality of thermal cycling components,

the top cap subassembly includes lid and sealing washer, the lid with the connection is dismantled to the experiment cabin, and is located the top of experiment cabin, the sealing washer with lid fixed connection, and be located the below of lid, the sealing washer with the experiment cabin contact.

3. The thermal cycling test chamber of claim 2, wherein the thermal cycling test chamber comprises a plurality of thermal cycling components,

the detection assembly comprises a detection machine and a connection block, wherein the connection block is fixedly connected with the hydraulic cylinder and is positioned at the output end of the hydraulic cylinder, the detection machine is fixedly connected with the connection block and is positioned above the connection block, the detection machine is detachably connected with the solar panel and is positioned below the solar panel, and the detection machine is electrically connected with the intelligent terminal.

4. The thermal cycling test chamber of claim 3, wherein the thermal cycling test chamber comprises a plurality of thermal cycling components,

the photovoltaic module thermal cycle test cabin further comprises a handle and a storage hook, wherein the handle is fixedly connected with the cover and is located above the cover, and the storage hook is fixedly connected with the test cabin and is located on one side of the test cabin.

5. The thermal cycling test chamber of claim 4, wherein the thermal cycling test chamber comprises a plurality of thermal cycling components,

the photovoltaic module thermal cycle test cabin further comprises four universal wheels, wherein the four universal wheels are rotationally connected with the test cabin and are respectively located at the bottom of the test cabin.