CN218868149U - Intelligent photovoltaic power supply system - Google Patents

Abstract

The utility model discloses an intelligence photovoltaic power supply system, include: the glass ceiling structure is provided with a photovoltaic glass assembly, and the photovoltaic glass assembly is used for photovoltaic power generation and heating air in the glass ceiling structure; the heat conduction type water heating structure is arranged in the glass ceiling structure, is connected with the small steam turbine generator set, and heats water in the heat conduction type water heating structure by utilizing the heated air so as to enable the small steam turbine generator set to generate electricity; and the waste heat generating end is arranged in the glass ceiling structure and is connected with the non-electric lithium bromide air conditioning system, and the heated air is used for heating the waste heat generating end so as to refrigerate the non-electric lithium bromide air conditioning system. This intelligence photovoltaic power supply system is except producing the electric energy through photovoltaic glass, also can utilize the inside light and heat auxiliary steam turbine electricity generation and the supplementary lithium bromide air conditioner refrigeration that produces of roof to can also give indoor auxiliary heating with the direct mode through the conduction of heat winter.

Description

Intelligent photovoltaic power supply system

Technical Field

The utility model relates to a photovoltaic light and heat technical field especially relates to a factory intelligence photovoltaic power supply system is examined to motor car.

Background

Due to the reproducibility of sunlight and the increasing shortage of global energy, photovoltaic power generation is becoming the first choice of all countries and cities, and when a plant area with a large area and a roof are paved with solar photovoltaic panels or photovoltaic glass, and sunlight shines, power can be continuously generated to provide power for power utilization ends of the plant area. Meanwhile, sunlight irradiation also generates heat, particularly, a roof provided with a large amount of photovoltaic glass can gather a large amount of heat indoors under continuous irradiation of sunlight, and in many occasions where glass photovoltaic is laid, people can adopt various heat dissipation facilities to dissipate heat of indoor high temperature, and actually if the heat is utilized, the heat can also be used reasonably as energy, but at present, the heat is matched with the heat, and few devices reasonably use the heat in the photovoltaic glass roof are provided.

SUMMERY OF THE UTILITY MODEL

The utility model is exactly to the above-mentioned problem, a intelligence photovoltaic power supply system is proposed, and it is applicable to the motor car and examines factory area, and this intelligence photovoltaic power supply system except producing the electric energy through photovoltaic glass, also can utilize the inside photo-thermal auxiliary steam turbine power generation and the refrigeration of supplementary lithium bromide air conditioner that produces in roof to can also give indoor auxiliary heating directly through the mode of conduction with the heat winter.

In order to solve the above problem, the utility model discloses a following technical scheme realizes:

an intelligent photovoltaic power supply system comprising: the glass ceiling structure is provided with a photovoltaic glass assembly, and the photovoltaic glass assembly is used for photovoltaic power generation and heating air in the glass ceiling structure;

the heat conduction type water heating structure is arranged in the glass ceiling structure, is connected with the small steam turbine generator set, and heats water in the heat conduction type water heating structure by utilizing the heated air so as to enable the small steam turbine generator set to generate electricity;

and the waste heat generation end is arranged in the glass ceiling structure and is connected with the non-electric lithium bromide air conditioning system, and the heated air is used for heating the waste heat generation end so as to refrigerate the non-electric lithium bromide air conditioning system.

Optionally, the thermally conductive water heating structure comprises: the first closed water storage tank body is arranged on the inner wall of the left side of the glass ceiling structure; the second closed water storage tank body is arranged on the inner wall of the right side of the glass ceiling structure;

the first closed type water storage tank body and the side edge of the second closed type water storage tank body all comprise: the electric water inlet mechanism and the electric water outlet mechanism are connected with the small-sized steam wheel generator set.

Optionally, the outer wall of the first closed water storage tank body is of a right convex arc-shaped wall structure, and a first high heat conduction layer is coated outside the right convex arc-shaped wall structure; the outer wall of the closed water storage tank body of the second is a left convex arc-shaped wall structure, and a second high heat-conducting layer is coated outside the left convex arc-shaped wall structure.

Optionally, the waste heat generating end includes: the solar energy heat collecting system comprises a glass ceiling structure, a plurality of heat collecting pipes and a plurality of air inlet holes, wherein the heat collecting pipes are transversely arranged in the glass ceiling structure, the left side of each heat collecting pipe is connected with the heat inlet end of the non-electric lithium bromide air conditioning system, the right side of each heat collecting pipe is connected with the inner wall of the right side of the glass ceiling structure, and each heat collecting pipe is provided with at least three air inlet holes for guiding air in the glass ceiling structure into the heat collecting pipes.

Optionally, the method further comprises: a movable heat insulation structure arranged in the glass ceiling structure and positioned below the waste heat generation end,

to prevent air within the glass roof structure from passing downwardly;

and the movable heat conduction structure is arranged in the glass ceiling structure and is positioned below the movable heat insulation structure so as to transfer the air in the glass ceiling structure downwards.

Optionally, the mobile insulation structure comprises: the first transverse guide rail is transversely arranged between the two inner walls of the glass ceiling structure, the first transverse guide rail is connected with first telescopic cloth through a first guide rail sliding group, and the right side of the first telescopic cloth is connected with a first motor capable of enabling the first telescopic cloth to slide and stretch left and right along the first transverse guide rail through a first elastic connecting sheet;

the mobile heat conductive structure includes: the second transverse guide rail is transversely arranged between the two inner walls of the glass ceiling structure, the second transverse guide rail is connected with second telescopic cloth through a second guide rail sliding group, and the right side of the second telescopic cloth is connected with a second motor capable of enabling the second telescopic cloth to slide and stretch left and right along the second guide rail through a second elastic connecting piece.

Optionally, the second transverse rail is located at the bottom of the first rail, 10-20 cm apart.

Optionally, the number of the heat collecting pipes is 3-6, and the diameter is 20-30 cm; two groups of electric air guide devices capable of accelerating the conduction of hot air in the heat collecting pipe to the left are arranged in the heat collecting pipe.

Optionally, the upper end of the glass ceiling structure is provided with a comprehensive air monitoring module integrating a wind direction monitoring module, a wind power monitoring module, a temperature monitoring module and a humidity monitoring module, and the comprehensive air monitoring module is in control connection with the input ends of the first motor and the second motor through a microprocessor.

Optionally, the first telescopic cloth comprises two oppositely arranged surfaces, and a first heat conduction layer is coated on one surface close to the waste heat generation end; one surface far away from the waste heat generating end is coated with a heat insulation layer;

the second telescopic cloth comprises two oppositely arranged surfaces, and a heat absorbing layer is coated on one surface close to the movable heat insulation structure; and one surface far away from the residual heat generating end is coated with a second heat conduction layer.

The utility model discloses one of following advantage has at least:

the utility model discloses a photovoltaic glass's structure is laid comprehensively to three-dimensional roof, can the maximize utilize the roof to carry out solar photovoltaic electricity generation, improves the generated energy.

The utility model discloses a large amount of heats that utilize the inside sunshine of roof to shine the gathering assist steam turbine power generation and supplementary lithium bromide air conditioner refrigeration, the heat that the maximize ground produced through the photovoltaic glass lower extreme reaches further electricity generation and refrigerated utilization purpose.

The utility model discloses can also give indoor auxiliary heating with the direct mode through the conduction of heat winter for the heat through the gathering of photovoltaic glass further obtains utilizing.

Drawings

Fig. 1 is an external structural view of an intelligent photovoltaic power supply system according to an embodiment of the present invention;

fig. 2 is a schematic view of various structures inside a roof according to an embodiment of the present invention;

fig. 3 is a schematic structural diagram of a first stretchable fabric according to an embodiment of the present invention;

fig. 4 is a schematic structural diagram of a second retractable cloth according to an embodiment of the present invention;

description of reference numerals:

1. a glass ceiling structure; 2. a photovoltaic glass assembly; 3. an interface; 4. a heat inlet end; 5. a first closed water storage tank body; 6. a second closed water storage tank body; 7. an electric water inlet mechanism; 8. an electric water outlet mechanism; 9. a right convex curved wall structure; 10. a first high thermal conductivity layer; 11. a left convex arc wall structure; 12. a second high thermal conductivity layer; 13. a heat collecting pipe; 14. an air inlet hole; 15. a first transverse guide rail; 16. a first rail sliding group; 17. a thermal insulation layer; 18. a first thermally conductive layer; 19. a first telescopic cloth; 20. a first elastic connecting piece; 21. a first motor; 22. a second transverse guide rail; 23. a second rail sliding group; 24. a second heat conducting layer; 25. a heat absorbing layer; 26. a second telescopic cloth; 27. a second elastic connecting piece; 28. a second motor; 29. an electric wind guide device; 30. a wind direction monitoring module; 31. a wind power monitoring module; 32. a temperature monitoring module; 33. a humidity monitoring module; 34. a comprehensive air monitoring module; 35. a microprocessor.

Detailed Description

The following describes the intelligent photovoltaic power supply system provided by the present invention in further detail with reference to the accompanying drawings and the detailed description. The advantages and features of the present invention will become more apparent from the following description. It should be noted that the drawings are in a very simplified form and are not to precise scale, and are provided for convenience and clarity in order to assist in describing embodiments of the present invention. To make the objects, features and advantages of the present invention more comprehensible, please refer to the attached drawings. It should be understood that the structure, ratio, size and the like shown in the drawings attached to the present specification are only used for matching with the content disclosed in the specification, so as to be known and read by those skilled in the art, and are not used for limiting the limitation of the implementation of the present invention, so that the present invention does not have the essential significance in the technology, and any modification of the structure, change of the ratio relationship or adjustment of the size should still fall within the scope of the technical content disclosed in the present invention without affecting the function and the achievable purpose of the present invention.

It can be known to combine fig. 1 and fig. 2, an intelligence photovoltaic power supply system, it can be applicable to the motor car and examine the factory area (also can be the house of other house friend photovoltaic glass subassemblies, the utility model discloses not so limit), including the glass ceiling structure 1 that is located motor car and examines factory area top, photovoltaic glass subassembly 2 has all been laid on this glass ceiling structure 1's upper end and four limits, and photovoltaic power generation through photovoltaic glass subassembly 2 provides the power for the power supply facility in the motor car is examined the factory area.

The heat-conducting water heating system is characterized in that an interface 3 of a small steam wheel generator set and a heat inlet end 4 of a non-electric lithium bromide air conditioning system are further arranged in a bullet train check plant area, a heat-conducting water heating structure connected with the small steam wheel generator set is arranged in the glass ceiling structure 1, and a waste heat generating end connected with the non-electric lithium bromide air conditioning system is arranged in the glass ceiling structure, air temperature in the glass ceiling structure is heated through a heat conducting function except for power generation of the photovoltaic glass assembly 1, heated air is applied to the heat-conducting water heating structure to heat water, the waste heat generating end generates waste heat with a certain temperature through the heated air, meanwhile, a movable heat insulation structure capable of preventing heated air in the glass ceiling structure 1 from being transferred downwards is arranged at the lower part of the glass ceiling structure 1, and a movable heat conducting structure capable of transferring the heated air in the glass ceiling structure 1 downwards is arranged.

Referring next to fig. 2, in the present invention, a preferred heat conduction type water heating structure includes: the first closed type water storage tank body 5 located on the inner wall of the left side of the glass ceiling structure 1 and the second closed type water storage tank body 6 located on the inner wall of the right side of the glass ceiling structure 1 are respectively provided with an electric water inlet mechanism 7 and an electric water outlet mechanism 8 on the side edges of the first closed type water storage tank body 5 and the second closed type water storage tank body 6, and the electric water outlet mechanism 8 is connected with a small steam turbine generator unit.

In the utility model, the outer wall of the first closed water storage tank body 5 is a right convex arc-shaped wall structure 9, and the outside of the right convex arc-shaped wall structure 9 is coated with a first high heat-conducting layer 10; the outer wall of the second closed water storage tank body 6 is a left convex arc-shaped wall structure 11, and the outside of the left convex arc-shaped wall structure 11 is coated with a second high heat conduction layer 12.

The utility model discloses in, preferred waste heat generation end includes: transversely set up many thermal-collecting tubes 13 in glass ceiling structure 1 the utility model discloses in, the left side of each thermal-collecting tube 13 all is connected with non-electric lithium bromide air conditioning system's heat input end 4, the right side of each thermal-collecting tube 13 and the wall connection in the glass ceiling structure 1 right side, and each thermal-collecting tube 13 all is equipped with at least three air inlet hole 14 in leading-in thermal-collecting tube 13 with the air in the glass ceiling structure.

In the utility model, the number of the heat collecting pipes 13 is 3-6, and the diameter is 20-30 cm; and two groups of electric air guiding devices 29 capable of accelerating the conduction of the hot air in the heat collecting tube 13 to the left are arranged in the heat collecting tube 13.

In the present invention, a preferable mobile heat insulation structure includes: the first transverse guide rail 15 is transversely arranged between two inner walls of the glass ceiling structure 1, a first telescopic cloth 19 (see fig. 3) with a heat insulation layer 17 at the bottom and a first heat conduction layer 18 at the upper end is connected to the first transverse guide rail 15 through a first guide rail sliding group 16, and a first motor 21 capable of sliding and stretching the first telescopic cloth 19 left and right along the first transverse guide rail 15 is connected to the right side of the first telescopic cloth 19 through a first elastic connecting piece 20.

The utility model discloses in, preferred portable heat conduction structure includes: the second transverse guide rail 22 is transversely arranged between two inner walls of the glass ceiling structure 1, the second transverse guide rail 22 is connected with a second telescopic cloth 26 (see fig. 4) with a second heat conduction layer 24 at the bottom and a heat absorption layer 25 at the upper end through a second guide rail sliding group 23, and the right side of the second telescopic cloth 26 is connected with a second motor 28 capable of sliding and stretching the second telescopic cloth 26 left and right along the second transverse guide rail 22 through a second elastic connecting sheet 27.

In the present invention, the second cross rail 22 is located at the bottom of the first cross rail 15, which is 10-20 cm apart.

The upper end of the glass ceiling structure 1 is provided with a comprehensive air monitoring module 34 which integrates a wind direction monitoring module 30, a wind power monitoring module 31, a temperature monitoring module 32 and a humidity monitoring module 33, and the comprehensive air monitoring module 34 is in control connection with the input ends of the first motor 21 and the second motor 28 through a microprocessor 35.

The above structure is particularly applied as follows: when the sunshine is abundant, the photovoltaic glass components 2 laid at the upper end and four sides of the glass ceiling structure 1 generate power to provide power for power supply facilities in a motor car inspection area; through the monitoring feedback of comprehensive air monitoring module 34, if when summer, the temperature in glass ceiling structure 1 is higher, can utilize this part light and heat resource, specifically be: the first motor 21 drives the first telescopic cloth 19 to cover the whole first transverse guide rail 15 through the first guide rail sliding group 16, that is, all the spaces above the first transverse guide rail 15 in the glass ceiling structure 1 are isolated independently, because the bottom of the first telescopic cloth 19 is provided with the heat insulation layer 17 and the upper end is provided with the first heat conduction layer 18, all hot air can be left in the space and cannot be conducted downwards to the ground, along with the continuous irradiation of sunlight, the temperature of the space in the area is higher and higher, the heat passes through the right convex arc-shaped wall structure 9 provided with the first high heat conduction layer 10 and the left convex arc-shaped wall structure 11 provided with the second high heat conduction layer 12 to continuously heat the water in the first closed water storage tank body 5 and the second closed water storage tank body 6 to boiling, and the boiling water is connected with the small steam turbine generator set through the electric water outlet mechanism 8, so as to achieve the purpose of generating electricity by the small steam turbine generator set.

Meanwhile, hot air enters the heat collecting tube 13 through the air inlet hole 14, and is guided to the left through the electric air guide device 29 in the heat collecting tube 13, so that the hot air is continuously transmitted to the non-electric lithium bromide air conditioning system through the hot end 4, and the purpose of refrigeration is achieved.

Through the monitoring feedback of the comprehensive air monitoring module 34, if the temperature in the glass ceiling structure 1 is higher by the sun in winter, the second motor 28 drives the second telescopic cloth 26 to cover the whole second transverse guide rail 22 through the second guide rail sliding group 23, and because the second telescopic cloth 26 has the second heat conduction layer 24 at the bottom and the heat absorption layer 25 at the upper end, the hot air in the glass ceiling structure 1 can be conducted to the lower side, so as to achieve the purpose of auxiliary heating in the room.

It is noted that, herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus. Without further limitation, an element defined by the phrases "comprising a," "8230," "8230," or "comprising" does not exclude the presence of additional like elements in a process, method, article, or apparatus that comprises the element.

In the description of the present invention, it is to be understood that the terms "center", "height", "thickness", "upper", "lower", "vertical", "horizontal", "top", "bottom", "inner", "outer", "axial", "radial", "circumferential", and the like, indicate orientations or positional relationships based on those shown in the drawings, and are used merely for convenience of description and for simplicity of description, and do not indicate or imply that the device or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and therefore, should not be construed as limiting the present invention. In the description of the present invention, "a plurality" means two or more unless otherwise specified.

In the description of the present invention, unless expressly stated or limited otherwise, the terms "mounted," "connected," and "fixed" are to be construed broadly, e.g., as meaning either a fixed connection, a removable connection, or an integral part; can be mechanically or electrically connected; either directly or indirectly through intervening media, either internally or in any other relationship. The specific meaning of the above terms in the present invention can be understood as a specific case by those skilled in the art.

In the present disclosure, unless expressly stated or limited otherwise, the first feature "on" or "under" the second feature may comprise direct contact between the first and second features, or may comprise contact between the first and second features not directly. Also, the first feature "on," "above" and "over" the second feature may include the first feature being directly above and obliquely above the second feature, or simply indicating that the first feature is at a higher level than the second feature. A first feature being "under," "below," and "beneath" a second feature includes the first feature being directly under and obliquely below the second feature, or simply meaning that the first feature is at a lesser elevation than the second feature.

While the present invention has been described in detail with reference to the preferred embodiments thereof, it should be understood that the above description should not be taken as limiting the present invention. Numerous modifications and alterations to the present invention will become apparent to those skilled in the art upon reading the foregoing description. Accordingly, the scope of the invention should be limited only by the attached claims.

Claims (10)

1. An intelligent photovoltaic power supply system, comprising: the glass ceiling structure is provided with a photovoltaic glass assembly, and the photovoltaic glass assembly is used for photovoltaic power generation and heating air in the glass ceiling structure;

the heat conduction type water heating structure is arranged in the glass ceiling structure and is connected with the small steam turbine generator set, and the heated air is used for heating water in the heat conduction type water heating structure so as to enable the small steam turbine generator set to generate electricity;

and the waste heat generating end is arranged in the glass ceiling structure and is connected with the non-electric lithium bromide air conditioning system, and the heated air is used for heating the waste heat generating end so as to refrigerate the non-electric lithium bromide air conditioning system.

2. The intelligent photovoltaic power system of claim 1, wherein the thermally conductive water heating structure comprises: the first closed water storage tank body is arranged on the inner wall of the left side of the glass ceiling structure; the second closed water storage tank body is arranged on the inner wall of the right side of the glass ceiling structure;

the first closed type water storage tank body and the side edge of the second closed type water storage tank body all comprise: the electric water inlet mechanism and the electric water outlet mechanism are connected with the small-sized steam wheel generator set.

3. The intelligent photovoltaic power supply system of claim 2,

the outer wall of the first closed water storage tank body is of a right convex arc-shaped wall structure, and a first high heat conduction layer is coated outside the right convex arc-shaped wall structure; the outer wall of the closed water storage tank body of the second is a left convex arc-shaped wall structure, and a second high heat-conducting layer is coated outside the left convex arc-shaped wall structure.

4. The intelligent photovoltaic power supply system of claim 3,

the waste heat generating end comprises: the solar energy heat collecting system comprises a glass ceiling structure, a plurality of heat collecting pipes and a plurality of air inlet holes, wherein the heat collecting pipes are transversely arranged in the glass ceiling structure, the left side of each heat collecting pipe is connected with the heat inlet end of the non-electric lithium bromide air conditioning system, the right side of each heat collecting pipe is connected with the inner wall of the right side of the glass ceiling structure, and each heat collecting pipe is provided with at least three air inlet holes for guiding air in the glass ceiling structure into the heat collecting pipes.

5. The intelligent photovoltaic power supply system of claim 4, further comprising: a movable heat insulation structure arranged in the glass ceiling structure and positioned below the waste heat generation end,

to prevent air within the glass roof structure from passing downwardly;

and the movable heat conduction structure is arranged in the glass ceiling structure and is positioned below the movable heat insulation structure so as to transfer the air in the glass ceiling structure downwards.

6. The intelligent photovoltaic power supply system of claim 5,

the mobile thermal insulation structure includes: the first transverse guide rail is transversely arranged between the two inner walls of the glass ceiling structure, the first transverse guide rail is connected with first telescopic cloth through a first guide rail sliding group, and the right side of the first telescopic cloth is connected with a first motor capable of enabling the first telescopic cloth to slide and stretch left and right along the first transverse guide rail through a first elastic connecting piece;

the mobile heat-conducting structure includes: the second transverse guide rail is transversely arranged between the two inner walls of the glass ceiling structure and is connected with second telescopic cloth through a second guide rail sliding group, and the right side of the second telescopic cloth is connected with a second motor capable of enabling the second telescopic cloth to slide and stretch left and right along the second guide rail through a second elastic connecting piece.

7. The intelligent photovoltaic power supply system of claim 6, wherein the second cross rail is located at the bottom of the first rail, 10-20 cm apart.

8. The intelligent photovoltaic power supply system of claim 7, wherein the number of the heat collecting tubes is 3-6, and the diameter is 20-30 cm; two groups of electric air guide devices capable of accelerating the conduction of hot air in the heat collecting pipe to the left are arranged in the heat collecting pipe.

9. The intelligent photovoltaic power supply system according to claim 8, wherein a comprehensive air monitoring module integrating a wind direction monitoring module, a wind power monitoring module, a temperature monitoring module and a humidity monitoring module is arranged at the upper end of the glass ceiling structure, and the comprehensive air monitoring module is in control connection with the input ends of the first motor and the second motor through a microprocessor.

10. The intelligent photovoltaic power supply system of claim 9, wherein the first retractable cloth comprises two oppositely arranged surfaces, and one surface close to the waste heat generating end is coated with a first heat conducting layer; one surface far away from the waste heat generating end is coated with a heat insulation layer;

the second telescopic cloth comprises two oppositely arranged surfaces, and a heat absorbing layer is coated on one surface close to the movable heat insulation structure; and one surface far away from the residual heat generating end is coated with a second heat conduction layer.

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