CN217763944U - Novel wind-heat solar heat collector - Google Patents

Abstract

The utility model discloses a solar energy technical field's a novel wind-heat solar collector, include: the wind-heat solar thermal collector assembly comprises a frame, a metal thermal collecting plate arranged on the inner side of the frame, and a fan arranged in the inner cavity of the connecting hole; toughened glass with do sealed the processing between the frame, the heat preservation backplate with do sealed the processing between the frame, toughened glass, frame with the heat preservation backplate encloses into a hollow storehouse body, the inner chamber packing of the storehouse body has the air, the utility model discloses a toughened glass, frame and heat preservation backplate enclose into a hollow storehouse body, fill the air at the inner chamber of the storehouse body, heat the air of internal chamber in storehouse through the heat absorption of metal thermal-arrest board, and the air after the heating enters into the inner chamber of heat preservation tuber pipe through the fan, does not need to have the molding medium to carry out the heat transfer, has effectively solved the drawback that traditional solar energy prevents frostbite in winter and can't use.

Description

Novel wind-heat solar heat collector

Technical Field

The utility model relates to a solar energy technical field specifically is a novel wind-heat solar collector.

Background

Solar energy is a renewable energy source. It refers to the heat radiation energy of the sun, and the main expression is the solar ray. In modern times it is commonly used to generate electricity or to power water heaters.

Traditional solar energy utilizes vacuum glass pipe to carry out energy conversion and becomes hot water with water heating, carries out the heat exchange through the circulation to hot water to reach the purpose of heating, however, under the comparatively cold condition of weather in winter, water can condense into ice in vacuum glass pipe, causes the inflation of volume to cause the damage to vacuum glass pipe, influences solar equipment's life.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a novel wind-heat solar collector to under the comparatively chilly condition of weather winter that proposes in solving above-mentioned background art, water can condense into ice in the vacuum glass pipe, causes the inflation of volume to cause the damage to the vacuum glass pipe, influences solar equipment's life's problem.

In order to achieve the above object, the utility model provides a following technical scheme: a novel wind-heat solar thermal collector, comprising:

the wind-heat solar collector assembly comprises a frame, a metal heat collecting plate arranged on the inner side of the frame, tempered glass arranged on the outer side of the frame and in contact with the metal heat collecting plate, a heat-insulating back plate arranged on one side, far away from the tempered glass, of the frame and a connecting hole formed in the long edge of the outer side wall of the frame and communicated with the inner cavity of the frame, wherein a fan is arranged in the inner cavity of the connecting hole;

the toughened glass and the frame are sealed, the heat-insulating back plate and the frame are sealed, the toughened glass, the frame and the heat-insulating back plate form a hollow bin body, and the inner cavity of the bin body is filled with air.

Preferably, the portable electronic device further comprises a connecting pipe, and the connecting pipe is installed between two adjacent frames through the connecting hole.

Preferably, the heat-insulation air pipe is further included, one end of the heat-insulation air pipe is installed on the air outlet of the frame through the connecting hole, and the other end of the heat-insulation air pipe is connected with the air inlet of the heat exchanger.

Preferably, the heat exchanger further comprises a circulating air pipe, one end of the circulating air pipe is connected with the air outlet of the heat exchanger, and the other end of the circulating air pipe is installed on the air inlet of the frame through the connecting hole.

Preferably, still include the bracket component, the bracket component is including setting up keep away from on the heat preservation backplate the first connecting block at metal heat collection plate one side top, install through the pivot the support frame subassembly on the first connecting block, set up keep away from on the heat preservation backplate metal heat collection plate one side bottom and with the corresponding second connecting block of first connecting block and through the bearing respectively with the second connecting block with the connecting rod that the support frame subassembly is connected.

Preferably, the support frame assembly comprises a support frame and sliding grooves which are arranged on the front side and the rear side of the support frame and connected with the connecting rod.

Preferably, the heat exchange water tank is further included, and comprises a water tank, a water inlet and a water outlet, wherein the water tank is connected with the exhaust port of the heat preservation air pipe and connected with the air inlet of the circulating air pipe, the water inlet is formed in the outer side wall of the water tank, and the water outlet is formed in the outer side wall of the water tank.

Compared with the prior art, the beneficial effects of the utility model are that: this kind of novel wind-heat solar collector encloses into a hollow storehouse body through toughened glass, frame and heat preservation backplate, fills the air at the inner chamber of the storehouse body, heats the air of storehouse body inner chamber through the heat absorption of metal thermal-arrest board, and the air after the heating enters into the inner chamber of heat preservation tuber pipe through the fan, need not have the type medium to carry out the heat conversion, has effectively solved the drawback that traditional solar energy prevents frostbite in winter and can't use.

Drawings

FIG. 1 is a schematic view of the present invention;

FIG. 2 is a schematic view of the wind-heat solar collector assembly of the present invention;

FIG. 3 is a schematic view of the wind-heat solar collector assembly and the bracket assembly of the present invention;

fig. 4 is the installation schematic diagram of the heat preservation air pipe, the circulating air pipe and the heat exchange water tank of the utility model.

In the figure: 100 wind-heat solar thermal collector assemblies, 110 side frames, 120 metal thermal collecting plates, 130 toughened glass, 140 heat-insulating back plates, 150 connecting holes, 200 connecting pipes, 300 heat-insulating air pipes, 400 circulating air pipes, 500 bracket assemblies, 510 first connecting blocks, 520 bracket assemblies, 521 supporting frames, 522 sliding grooves, 530 second connecting blocks, 540 connecting rods, 600 heat exchange water tanks, 610 water tanks, 620 water inlets and 630 water outlets.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative efforts all belong to the protection scope of the present invention.

The utility model provides a novel wind-heat solar collector encloses into a hollow storehouse body through toughened glass, frame and heat preservation backplate, fills the air at the inner chamber of the storehouse body, heats the air of storehouse body inner chamber through the heat absorption of metal heat collection plate, and the air after the heating enters into the inner chamber of heat preservation tuber pipe through the fan, does not need to have the type medium to carry out the heat transfer, has effectively solved the drawback that traditional solar energy prevents frostbite in winter and can't use, please refer to and draw together figure 1 and figure 4, include: the heat-exchange solar heat collector comprises a wind-heat solar heat collector assembly 100, a connecting pipe 200, a heat-insulation air pipe 300, a circulating air pipe 400, a bracket assembly 500 and a heat-exchange water tank 600;

referring to fig. 1-2, the wind-heat solar collector assembly 100 includes a frame 110, a metal heat collecting plate 120 installed inside the frame 110, a tempered glass 130 installed outside the frame 110 and contacting the metal heat collecting plate 120, a heat insulating back plate 140 installed on the frame 110 and far away from one side of the tempered glass 130, and a connection hole 150 opened on a long edge of an outer side wall of the frame 110 and communicated with an inner cavity of the frame 110, wherein a fan is installed in the inner cavity of the connection hole 150, the tempered glass 130 and the frame 110 are sealed, the heat insulating back plate 140 and the frame 110 are sealed, the tempered glass 130, the frame 110 and the heat insulating back plate 140 enclose a hollow cabin body, the inner cavity of the cabin body is filled with air, the sun irradiates the tempered glass 130, the sunlight irradiates the metal heat collecting plate 120 through the tempered glass 130, the air filled in the inner cavity is heated through heat collecting plate 120, and the heated air is exhausted through the fan;

referring to fig. 1-2 again, the connecting pipe 200 is installed between two adjacent frames 110 through the connecting hole 150, and the two adjacent frames 110 are connected through the connecting pipe 200, so that the inner cavities of the two adjacent frames 110 are communicated, and the frames 110 can be amplified through the connecting pipe 200;

referring to fig. 1-2 again, one end of the thermal insulation air pipe 300 is installed on the exhaust port of the frame 110 through the connection hole 150, the other end of the thermal insulation air pipe 300 is connected to the air inlet of the heat exchanger, the air heated by the metal heat collection plate 120 is pumped into the inner cavity of the thermal insulation air pipe 300 through the fan, the heated air enters the heat exchanger through the thermal insulation air pipe 300, and exchanges heat with the indoor air through the heat exchanger, so as to increase the indoor temperature, thereby achieving the purpose of heating, the thermal insulation air pipe replaces the original water supply pipeline on the solar energy, and the air is heated without heat conversion of an existing medium, thereby avoiding the phenomenon of frost cracking of the pipeline caused by freezing of water in the pipeline in winter, and effectively solving the defect that the traditional solar energy can not be used in winter;

referring to fig. 1-2 again, one end of a circulating air pipe 400 is connected to the outlet of the heat exchanger, the other end of the circulating air pipe 400 is installed on the inlet of the frame 110 through a connecting hole 150, the gas after heat exchange enters the inner cavity of the connecting hole 150 through the circulating air pipe 400, the air after heat exchange is pumped into the inner cavity of the bin body through a fan, the air is heated by solar energy, and the heated gas enters the heat exchanger through the fan again, so that the indoor heat is heated in a circulating manner, and the indoor temperature is guaranteed;

referring to fig. 1 to 3, the bracket assembly 500 includes a first connecting block 510 disposed on the heat-insulating backboard 140 away from the top of the metal heat collecting plate 120, a supporting frame assembly 520 mounted on the first connecting block 510 through a shaft pin, a second connecting block 530 disposed on the heat-insulating backboard 140 away from the bottom of the metal heat collecting plate 120 and corresponding to the first connecting block 510, and a connecting rod 540 connected to the second connecting block 530 and the supporting frame assembly 520 through a bearing, respectively, the supporting frame assembly 520 includes a supporting frame 521 and sliding slots 522 disposed on the front and rear sides of the supporting frame 521 and connected to the connecting rod 540, the supporting frame assembly 520 is turned over on the first connecting block 510 through the shaft pin, the connecting rod 540 can be turned over on the second connecting block 530 through the shaft pin, in particular, the wind-heat solar collector assembly 100 is placed on the ground or the roof, the supporting frame 521 is turned over at a certain rear included angle, one end of the supporting frame 521 away from the wind-heat solar collector assembly 100 is in contact with the ground or the roof, the wind-heat solar collector assembly 100 is supported, the connecting rod 540 slides through a slider in an inner cavity 522 of the sliding slot, so that the wind-heat collector assembly 100, the wind-heat collector 521, the wind-heat collector assembly is placed on the roof, and the roof is convenient for placing of the wind-heat collector assembly 100;

referring to fig. 1-2 and 4, the heat exchange water tank 600 includes a water tank 610 connected to an exhaust port of the heat preservation air duct 300 and an air inlet of the circulation air duct 400, a water inlet 620 formed on an outer sidewall of the water tank 610 and a water outlet 630 formed on an outer sidewall of the water tank 610, clear water is injected into an inner cavity of the water tank 610 through the water inlet 620, a heating duct is wound in the inner cavity of the water tank 610, an air inlet end of the heating duct is connected to an exhaust end of the heat preservation air duct 300, an exhaust end of the heating duct is connected to an air inlet end of the circulation air duct 400, air heated by solar energy enters the inner cavity of the heating duct through the heat preservation air duct 300 to exchange heat with the clear water, the clear water is heated, the air heated by heat exchange returns to the inner cavity of the bin body through the circulation air duct 400 to be heated by solar energy, a water outlet on the water outlet 630 on the water tank 610 is connected to a household water duct, and hot water enters the household water duct through the water outlet 630 to supply the household water supply pipe.

While the invention has been described above with reference to an embodiment, various modifications may be made and equivalents may be substituted for elements thereof without departing from the scope of the invention. In particular, as long as there is no structural conflict, the various features of the disclosed embodiments of the present invention can be used in any combination with each other, and the description of such combinations is not exhaustive in the present specification only for the sake of brevity and resource conservation. Therefore, it is intended that the invention not be limited to the particular embodiments disclosed, but that the invention will include all embodiments falling within the scope of the appended claims.

Claims (7)

1. A novel wind-heat solar heat collector is characterized in that: the method comprises the following steps:

the wind-heat solar heat collector assembly (100) comprises a frame (110), a metal heat collecting plate (120) arranged on the inner side of the frame (110), tempered glass (130) arranged on the outer side of the frame (110) and contacted with the metal heat collecting plate (120), a heat-insulating back plate (140) arranged on one side, far away from the tempered glass (130), of the frame (110) and a connecting hole (150) formed in the long edge of the outer side wall of the frame (110) and communicated with the inner cavity of the frame (110), wherein a fan is arranged in the inner cavity of the connecting hole (150);

the toughened glass (130) and the frame (110) are sealed, the heat-insulating back plate (140) and the frame (110) are sealed, the toughened glass (130), the frame (110) and the heat-insulating back plate (140) enclose a hollow bin body, and the inner cavity of the bin body is filled with air.

2. A novel wind-heat solar collector according to claim 1, characterized in that: the connecting pipe (200) is arranged between two adjacent frames (110) through the connecting hole (150).

3. A novel wind-heat solar collector according to claim 2, characterized in that: the heat-preservation air pipe is characterized by further comprising a heat-preservation air pipe (300), one end of the heat-preservation air pipe (300) is installed on the air exhaust port of the frame (110) through the connecting hole (150), and the other end of the heat-preservation air pipe (300) enters the house and is connected with the air inlet of the heat exchanger.

4. A novel wind-heat solar collector according to claim 3, characterized in that: the heat exchanger is characterized by further comprising a circulating air pipe (400), wherein one end of the circulating air pipe (400) is connected with an exhaust port of the heat exchanger, and the other end of the circulating air pipe (400) is installed on an air inlet of the frame (110) through the connecting hole (150).

5. A novel wind-heat solar collector according to claim 4, characterized in that: still include bracket component (500), bracket component (500) is including setting up keep away from on heat preservation backplate (140) first connecting block (510) at metal heat collection plate (120) one side top, install through the pivot support frame subassembly (520) on first connecting block (510), set up keep away from on heat preservation backplate (140) metal heat collection plate (120) one side bottom and with first connecting block (510) corresponding second connecting block (530) and through the bearing respectively with second connecting block (530) with connecting rod (540) that support frame subassembly (520) is connected.

6. A novel wind-heat solar collector according to claim 5, characterized in that: the support frame component (520) comprises a support frame (521) and sliding chutes (522) which are arranged on the front side and the rear side of the support frame (521) and connected with the connecting rods (540).

7. A novel wind-heat solar collector according to claim 6, characterized in that: still include heat transfer water tank (600), heat transfer water tank (600) include with heat preservation tuber pipe (300) gas vent be connected and with water tank (610) that circulation tuber pipe (400) air inlet is connected, set up water inlet (620) on water tank (610) lateral wall and set up outlet (630) on water tank (610) lateral wall.

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