CN114244271B - Light-following type graphene double-glass shed body - Google Patents

Abstract

The invention belongs to the technical field of solar energy, and particularly relates to a light-following type graphene double-glass shed body, which comprises a double-glass power generation system, a circulating cooling system, an auxiliary flushing system and a main body supporting system, wherein the circulating cooling system comprises a water cooling system, an air cooling system and a first single-blade double-blade switch, and the auxiliary flushing system comprises a water flushing system, an air flushing system and a second single-blade double-blade switch; the invention adopts the single-blade double-blade switch to realize the switching of water cooling and air cooling, the switching of the water flushing system and the air flushing system, has simple structure and easy realization, and the water cooling system and the water flushing system use circulating water, thereby saving water resources; and a graphene layer is arranged between the photovoltaic module and the cooling system, and the heat generated by the photovoltaic module is taken away by utilizing the good heat conduction performance of graphene, so that the power generation efficiency is improved.

Description

Light-following type graphene double-glass shed body

Technical Field

The invention belongs to the technical field of solar energy, and particularly relates to a light-following type graphene double-glass shed body.

Background

Shed bodies with solar power generation function have attracted more and more attention in recent years due to their wide applicability, including solar vegetable greenhouses, solar car sheds and the like. The solar greenhouse body is a modern sustainable greenhouse body based on solar energy, and taking a solar vegetable greenhouse as an example, a photovoltaic assembly is arranged at the top of a common vegetable greenhouse, so that solar radiation can be decomposed into energy required by vegetable growth and light energy required by photovoltaic power generation, and the normal growth of plants can be ensured, and photovoltaic power generation can be performed.

During operation, the photovoltaic module constantly produces heat under the irradiation of sunshine, causes the temperature to rise constantly, and then leads to photoelectric conversion efficiency to reduce, and output declines, and current cooling mode generally adopts forced air cooling, water-cooling or the combination of both, thereby can lead to the photovoltaic module to obtain cooling after breaking down when both are used independently and influence output, and often divide into two sets of structures when both combine the use to the structure is complicated, and disposable water-cooling mode can cause a large amount of waste of water resource.

Because factors such as climate and environment influence, dust is easy to deposit on the surface of the photovoltaic module, and dust can influence the illumination intensity of the photovoltaic cell and further influence the output power of the photovoltaic cell, dust is another important factor influencing the efficiency of a power generation system of the photovoltaic module, and therefore the photovoltaic module is required to be cleaned irregularly, but the disposable clean water also can cause a great amount of waste of water resources.

Disclosure of Invention

The invention aims to solve the technical problems that: in order to solve the problems that in the prior art, the cooling of the photovoltaic module is air cooling, water cooling or combination of the air cooling and the water cooling, the photovoltaic module cannot be cooled after the photovoltaic module breaks down due to independent use of the air cooling and the water cooling, and the combination of the air cooling and the water cooling is complex in structure, the light-following type graphene double-glass shed body is provided.

In order to solve the technical problems, the invention adopts the following technical scheme: the light-following type graphene double-glass shed body comprises a double-glass power generation system, a circulating cooling system, an auxiliary flushing system and a main body supporting system;

the double-glass power generation system comprises a plurality of photovoltaic power generation sleeve plates, wherein each set of photovoltaic power generation sleeve plates comprises two graphene layers, two photovoltaic modules and two glass cover plates which are arranged from inside to outside, and graphene has good heat conduction performance and can rapidly take away heat generated by the photovoltaic modules;

the circulating cooling system comprises a water cooling system, an air cooling system and a first single-blade double-blade switch, wherein the water cooling system and the air cooling system are switched through the first single-blade double-blade switch; when the weather enters deep winter, natural air convection heat exchange cannot be performed in the double-glass power generation, even if the temperature rise is obvious under the working condition of winter, the outdoor liquid needs to be cooled, but the flow of outdoor liquid is seriously blocked due to low temperature, and at the moment, the first single-blade double-blade switch is turned on, and the water cooling can be switched into air cooling;

the auxiliary flushing system comprises a water flushing system, an air flushing system and a second single-blade double-blade switch, and the water flushing system and the air flushing system are switched through the second single-blade double-blade switch; when the weather enters into deep winter, the flow of outdoor liquid can be seriously blocked due to low temperature, and at the moment, the second single-blade double-blade switch is started and can be switched from water flushing to wind flushing;

the main body support system is used for supporting the double-glass power generation system.

The technical scheme adopts the single-blade double-blade switch to realize the switching of water cooling and air cooling, the switching of the water flushing system and the air flushing system, has simple structure and easy realization, and the water cooling system and the water flushing system use circulating water, thereby saving water resources; and a graphene layer is arranged between the photovoltaic module and the cooling system, and the heat generated by the photovoltaic module is taken away by utilizing the good heat conduction performance of graphene, so that the power generation efficiency is improved.

Further, the water cooling system comprises a water storage tank, a first water inlet pipe, a water outlet pipe, a coil pipe and a first electric water pump, wherein one ends of the first water inlet pipe and the water outlet pipe are communicated with the water storage tank, the other ends of the first water inlet pipe and the water outlet pipe are respectively communicated with two ends of the coil pipe, the coil pipe is positioned between two graphene layers, the temperature of the graphene layers rises after heat of the photovoltaic module is conducted by the graphene layers, cold water is injected into the coil pipe between the graphene layers to cool the graphene layers, and the first electric water pump is arranged between the water storage tank and the first water inlet pipe; the water in the water storage tank returns to the water storage tank after passing through the first inlet pipe, the coil pipe and the water outlet pipe, so that the circulating water is realized, and the water resource is saved;

the air cooling system comprises a fan and an air outlet pipe, and shares a first air inlet pipe and a coil pipe with the water cooling system, a single-blade double-blade switch is arranged between the air outlet pipe and the air outlet pipe for switching, two ends of the coil pipe are respectively communicated with one ends of the first air inlet pipe and one end of the air outlet pipe, the other end of the first air inlet pipe is communicated with the output end of the fan, and the air cooling system and the water cooling system can be switched through the first single-blade double-blade switch.

Further, the water flushing system comprises a second electric water pump, a second inlet pipe, a movable circular pipe, a spray head and a liquid collecting pipe, wherein one ends of the liquid collecting pipe and the second inlet pipe are communicated with the water storage tank, the other end of the second inlet pipe is communicated with the movable circular pipe through a telescopic hose, a plurality of spray heads are arranged on the movable circular pipe, the lower end of the movable circular pipe is provided with a roller wheel which can move up and down along the surface of a shed body, water discharged from the spray head cleans the surface, dust accumulation caused by insufficient flushing force at the lower end of a photovoltaic power generation sleeve plate is avoided, the other end of the liquid collecting pipe penetrates through the shed body and is level with the outgoing surface, water and natural rainwater after flushing the photovoltaic sleeve plate enter the liquid collecting pipe along an inclined glass surface and then enter the water storage tank to start circulation;

the water flushing system and the water cooling system share a water storage tank, part of water in the water storage tank returns to the water storage tank through the second inlet pipe, the movable circular pipe and the liquid collecting pipe, so that circulating water is realized, rainwater can also enter the water storage tank through the liquid collecting pipe, and the reutilization of the rainwater is realized;

the wind flushing system comprises a fan, a second inlet pipe, a movable circular pipe and a spray head are shared with the water flushing system, one end of the fan is communicated with the second inlet pipe, the other end of the fan is communicated with the movable circular pipe through a hose, and the water flushing system and the wind flushing system can be switched through a second single-blade double-blade switch.

Further, the main body supporting system comprises a bracket and a plurality of rotating shafts rotatably connected to the bracket, the bracket is used for supporting the double-glass power generation system, the rotating shafts are used for driving the photovoltaic module to track the sun at the optimal inclination angle all the time, and the most sufficient solar energy can be obtained at all times; the two ends of the rotating shaft are respectively provided with a gear which is meshed with the gears on the support, so that the rotating shaft is connected with the support in a rotating way, the rotating shaft corresponds to the photovoltaic power generation sleeve plates one by one and is fixedly connected with the photovoltaic power generation sleeve plates corresponding to the rotating shaft, and the two ends of the coil pipe penetrate through the inner holes of the rotating shaft and are respectively communicated with the inlet pipe and the outlet pipe.

Further, the upper end and the lower extreme of every photovoltaic power generation sleeve board all are equipped with insulating sleeve and detain, and two insulating sleeve detain opening opposite directions, and adjacent two photovoltaic power generation sleeve boards pass through insulating sleeve knot cover and connect, and when the canopy body was in closed state, adjacent two photovoltaic power generation sleeve boards were detained each other through insulating sleeve, and when photovoltaic power generation sleeve board began to rotate along with the axis of rotation, two insulating sleeve detained and are separated gradually.

Further, a filter is arranged in the water storage tank, a filter screen is arranged between the water storage tank and the liquid collecting pipe, the washed water and rainwater contain impurities, the water enters the water storage tank for recycling, the water can be blocked for a long time, and the filter screen can filter the water.

The beneficial effects of the invention are as follows: the invention adopts the single-blade double-blade switch to realize the switching of water cooling and air cooling, the switching of the water flushing system and the air flushing system, has simple structure and easy realization, and the water cooling system and the water flushing system use circulating water, thereby saving water resources; and a graphene layer is arranged between the photovoltaic module and the cooling system, and the heat generated by the photovoltaic module is taken away by utilizing the good heat conduction performance of graphene, so that the power generation efficiency is improved.

Drawings

FIG. 1 is a schematic diagram of the structure of the present invention;

FIG. 2 is a schematic structural view of a photovoltaic power generation panel;

FIG. 3 is a schematic diagram of the assembly of a coil and a photovoltaic power generation panel;

FIG. 4 is a schematic diagram of a left-hand structure of a photovoltaic power generation panel;

in the figure:

1. a dual-glass power generation system; 101. photovoltaic power generation sleeve plate; 1011. a graphene layer; 1012. a photovoltaic module; 1013. a glass cover plate; 1014. an insulating sleeve buckle;

2. a circulation cooling system; 201. a water storage tank; 202. a first inlet pipe; 203. a water outlet pipe; 204. a coiled pipe; 205. a first electric water pump; 206. an air outlet pipe; 207. a first single-blade double-blade switch;

3. an auxiliary flushing system; 301. a second electric water pump; 302. a second inlet pipe; 303. moving the round tube; 304. a spray head; 305. a liquid collection tube; 306. a second single-blade double-blade switch; 307. a filter screen; 308. a filter;

4. a main body support system; 401. and (3) a bracket.

Detailed Description

The invention will now be described in further detail with reference to the accompanying drawings. The drawings are simplified schematic representations which merely illustrate the basic structure of the invention and therefore show only those features which are relevant to the invention, and orientation and reference (e.g., up, down, left, right, etc.) may be used solely to aid in the description of the features in the drawings. The following detailed description is, therefore, not to be taken in a limiting sense, and the scope of the claimed subject matter is defined only by the appended claims and equivalents thereof.

Example 1

As shown in fig. 1-4, the invention discloses a light-following type graphene double-glass shed body, which comprises a double-glass power generation system 1, a circulating cooling system 2, an auxiliary flushing system 3 and a main body supporting system 4;

the double-glass power generation system 1 comprises a plurality of photovoltaic power generation sleeve plates 101, each set of photovoltaic power generation sleeve plates 101 comprises two graphene layers 1011, two photovoltaic modules 1012 and two glass cover plates 1013 which are arranged from inside to outside, and graphene has good heat conduction performance and can rapidly take away heat generated by the photovoltaic modules 1012;

the circulating cooling system 2 comprises a water cooling system, an air cooling system and a first single-blade double-edge switch 207, wherein the water cooling system comprises a water storage tank 201, a first inlet pipe 202, an outlet pipe 203, a coil 204 and a first electric water pump 205, one ends of the first inlet pipe 202 and the outlet pipe 203 are communicated with the water storage tank 201, the other ends of the first inlet pipe and the outlet pipe 203 are respectively communicated with two ends of the coil 204, the coil 204 is positioned between two graphene layers 1011, the graphene layers 1011 conduct heat of a photovoltaic module 1012 and then the temperature rises, cold water is injected into the coil 204 between the graphene layers 1011 to cool the graphene layers, and the first electric water pump 205 is arranged between the water storage tank 201 and the first inlet pipe 202; the water in the water storage tank 201 returns to the water storage tank 201 again after passing through the first inlet pipe 202, the coil 204 and the outlet pipe 203, thereby realizing circulating water and saving water resources;

the air cooling system comprises a fan and an air outlet pipe 206, and shares a first air inlet pipe 202 and a coil 204 with the water cooling system, a single-blade double-edge switch is arranged between the water outlet pipe 203 and the air outlet pipe 206 for switching, two ends of the coil 204 are respectively communicated with one ends of the first air inlet pipe 202 and one end of the air outlet pipe 206, and the other end of the first air inlet pipe 202 is communicated with the output end of the fan;

the cooling can be carried out at ordinary times, when the weather gets into the deep winter, because the natural air convection heat transfer can't be carried out in the dual glass electricity generation inside, even under winter operating mode, the intensification is also comparatively obvious, need cool off, but outdoor liquid's flow can receive serious repression because of the low temperature, and first single sword double-edged switch 207 opens this moment, can switch to the forced air cooling by the water-cooling.

The auxiliary flushing system 3 comprises a water flushing system, an air flushing system and a second single-blade double-blade switch 306; the water flushing system comprises a second electric water pump 301, a second inlet pipe 302, a movable circular pipe 303, a spray head 304 and a liquid collecting pipe 305, wherein one ends of the liquid collecting pipe 305 and the second inlet pipe 302 are communicated with the water storage tank 201, the other end of the second inlet pipe 302 is communicated with the movable circular pipe 303 through a telescopic hose, a plurality of spray heads 304 are arranged on the movable circular pipe 303, rollers are arranged at the lower end of the movable circular pipe 303 and can move up and down along the surface of a shed body, water discharged from the spray heads 304 cleans the surface, dust accumulation on the lower end of the photovoltaic power generation sleeve plate 101 due to insufficient flushing force is avoided, the other end of the liquid collecting pipe 305 penetrates through the shed body and is flush with the outgoing surface, water and natural rainwater after flushing the photovoltaic power generation sleeve plate 101 enter the liquid collecting pipe 305 along an inclined glass surface and then enter the water storage tank 201 to start circulation;

the water flushing system and the water cooling system share the water storage tank 201, water in the water storage tank 201 returns to the water storage tank 201 after passing through the second inlet pipe 302, the movable circular pipe 303 and the liquid collecting pipe 305, so that circulating water is realized, rainwater can also enter the water storage tank 201 through the liquid collecting pipe 305, and the reutilization of the rainwater is realized; a filter 308 is arranged in the water storage tank 201, a filter screen 307 is arranged between the water storage tank 201 and the liquid collecting pipe 305, the washed water and rainwater contain impurities, the water enters the water storage tank 201 for recycling, the water pipe can be blocked for a long time, and the filter 308 and the filter screen 307 can filter the water;

the wind flushing system comprises a fan and shares a second inlet pipe 302, a movable circular pipe 303 and a spray head 304 with the water flushing system, wherein one end of the second inlet pipe 302 is communicated with the output end of the fan, and the other end of the second inlet pipe is communicated with the movable circular pipe 303 through a hose;

when the weather enters into deep winter, the flow of outdoor liquid is seriously blocked due to low temperature, and the second single-blade double-blade switch 306 is opened at the moment, so that the water flushing can be switched into the wind flushing.

The main body support system 4 is used for supporting the double-glass power generation system 1, the main body support system 4 comprises a bracket 401 and a plurality of rotating shafts rotatably connected to the bracket 401, and the rotating shafts are used for driving the photovoltaic module 1012 to track the sun at an optimal inclination angle all the time so as to ensure that the most sufficient solar energy can be obtained at all times; the two ends of the rotating shaft are respectively provided with a gear which is meshed with the gears on the support 401, so that the rotating shaft is rotationally connected with the support 401, the rotating shaft corresponds to the photovoltaic power generation sleeve plates 101 one by one and is fixedly connected with the corresponding photovoltaic power generation sleeve plates 101, and the two ends of the coil 204 penetrate through the inner holes of the rotating shaft and are respectively communicated with the inlet pipe and the outlet pipe.

The upper end and the lower end of each photovoltaic power generation sleeve plate 101 are respectively provided with an insulating sleeve buckle 1014, the opening directions of the two insulating sleeve buckles 1014 are opposite, two adjacent photovoltaic power generation sleeve plates 101 are sleeved through the insulating sleeve buckles 1014, when the shed body is in a closed state, the two adjacent photovoltaic power generation sleeve plates 101 are mutually locked through the insulating sleeve buckles 1014, and when the photovoltaic power generation sleeve plates 101 start to rotate along with the rotating shaft, the two insulating sleeve buckles 1014 are gradually separated.

The working principle and the using flow of the invention are as follows:

and (3) water cooling: the water in the water storage tank 201 enters the coil 204 through the first inlet pipe 202, cold water in the coil 204 and the graphene layer 1011 exchange heat to take away heat, and then returns to the water storage tank 201 again after passing through the water outlet pipe 203, so that circulating water is realized;

air cooling: the first single-blade double-blade switch 207 is switched to air cooling by water cooling, a fan is started, cold air generated by the fan enters the coil 204 through the first inlet pipe 202, heat is taken away by heat exchange between the cold air in the coil 204 and the graphene layer 1011, and then the cold air is discharged through the air outlet pipe 206;

water flushing: the water in the water storage tank 201 enters the movable circular tube 303 through the second inlet tube 302 and the hose, the movable circular tube 303 can move up and down along the surface of the shed body, the surface of the shed body is cleaned by the water discharged by the spray head 304, and then part of the water returns to the water storage tank 201 through the liquid collecting tube 305 to realize circulating water;

wind flushing: the second single-blade double-blade switch 306 is turned on, water flushing is switched to wind flushing, the fan is started, cold wind generated by the fan enters the movable circular tube 303 through the second inlet tube 302 and the hose, the movable circular tube 303 can move up and down along the surface of the shed body, and the spray head 304 blows out wind to flush the surface of the shed body.

The above-described preferred embodiments according to the present invention are intended to suggest that, from the above description, various changes and modifications can be made by the worker in question without departing from the technical spirit of the present invention. The technical scope of the present invention is not limited to the description, but must be determined according to the scope of claims.

Claims (4)

1. A follow spot type graphene double-glass shed body is characterized in that: comprises a double-glass power generation system (1), a circulating cooling system (2), an auxiliary flushing system (3) and a main body supporting system (4);

the double-glass power generation system (1) comprises a plurality of photovoltaic power generation sleeve plates (101), wherein each photovoltaic power generation sleeve plate (101) comprises two graphene layers (1011), two photovoltaic modules (1012) and two glass cover plates (1013) which are arranged from inside to outside;

the circulating cooling system (2) comprises a water cooling system, an air cooling system and a first single-blade double-blade switch (207), wherein the water cooling system and the air cooling system are switched through the first single-blade double-blade switch (207);

the auxiliary flushing system (3) comprises a water flushing system, a wind flushing system and a second single-blade double-blade switch (306), and the water flushing system and the wind flushing system are switched through the second single-blade double-blade switch (306);

the main body supporting system (4) is used for supporting the double-glass power generation system (1);

the water cooling system comprises a water storage tank (201), a first inlet pipe (202), a water outlet pipe (203), a coil pipe (204) and a first electric water pump (205), wherein one ends of the first inlet pipe (202) and the water outlet pipe (203) are communicated with the water storage tank (201), the other ends of the first inlet pipe and the water outlet pipe are respectively communicated with two ends of the coil pipe (204), the coil pipe (204) is positioned between two graphene layers (1011), and the first electric water pump (205) is arranged between the water storage tank (201) and the first inlet pipe (202);

the air cooling system comprises a fan and an air outlet pipe (206), two ends of the coil pipe (204) are respectively communicated with one ends of a first air inlet pipe (202) and the air outlet pipe (206), the other end of the first air inlet pipe (202) is communicated with the output end of the fan, a single-blade double-blade switch is arranged between the water outlet pipe (203) and the air outlet pipe (206), and the first single-blade double-blade switch (207) is positioned on the first air inlet pipe (202);

the water flushing system comprises a second electric water pump (301), a second inlet pipe (302), a movable circular pipe (303), spray heads (304) and a liquid collecting pipe (305), wherein one ends of the liquid collecting pipe (305) and the second inlet pipe (302) are communicated with the water storage tank (201), the other end of the second inlet pipe (302) is communicated with the movable circular pipe (303) through a hose, a plurality of spray heads (304) are arranged on the movable circular pipe (303), and the other end of the liquid collecting pipe (305) penetrates through a greenhouse body and is flush with an outgoing surface;

the wind flushing system comprises a fan, one end of a second inlet pipe (302) is communicated with the output end of the fan, one end of the second inlet pipe is communicated with the movable circular pipe (303) through a hose, and a second single-blade double-blade switch (306) is positioned on the second inlet pipe (302).

2. The light-following type graphene double-glass shed body according to claim 1, wherein: the main body supporting system (4) comprises a bracket (401) and a plurality of rotating shafts which are rotatably connected to the bracket (401), wherein the rotating shafts are in one-to-one correspondence with the photovoltaic power generation sleeve plates (101) and are fixedly connected with the photovoltaic power generation sleeve plates (101) corresponding to the rotating shafts.

3. The light-following type graphene double-glass shed body according to claim 1, wherein: the upper end and the lower end of each photovoltaic power generation sleeve plate (101) are respectively provided with an insulating sleeve buckle (1014), the opening directions of the two insulating sleeve buckles (1014) are opposite, and the two adjacent photovoltaic power generation sleeve plates (101) are sleeved through the insulating sleeve buckles (1014).

4. The light-following type graphene double-glass shed body according to claim 1, wherein: a filter (308) is arranged in the water storage tank (201), and a filter screen (307) is arranged between the water storage tank (201) and the liquid collecting pipe (305).