CN113375484A - Quick heat exchange graphite plate - Google Patents

Abstract

The invention discloses a rapid heat exchange graphite plate, which comprises a water pipe, an energy storage unit and a graphite unit; the graphite units and the energy storage units are uniformly combined in a crossed manner, and the graphite units and the energy storage units form a plate body together; the water pipe penetrates through the plate body. According to the invention, the graphite units and the energy storage units are uniformly combined in a cross manner, the heat can be rapidly transferred in the horizontal and vertical directions of the graphite plate by utilizing the good heat conduction performance of the graphite, and the heat can be uniformly distributed in the graphite plate by utilizing the good uniform heat performance of the graphite; meanwhile, the heat energy brought by the graphite is stored by utilizing the heat storage function of the energy storage unit, and the heat is slowly radiated, so that the indoor temperature is comfortable; in addition, the graphite also has good toughness, and can increase the strength of the whole plate and improve the performance of the plate.

Description

Quick heat exchange graphite plate

Technical Field

The invention relates to the technical field of heating and refrigeration, in particular to a quick heat exchange graphite plate.

Background

Along with the continuous development of social economy, people constantly improve to the requirement of indoor comfort level, and radiation air conditioning system receives people's favor more and more, and the air conditioner heat transfer is terminal as the device directly relevant with indoor comfort level, receives people's attention more and more.

The heat exchange tail end of the existing heat radiation system is also commonly compounded to be made into a graphite composite plate by utilizing the heat conductivity of the graphite plate, as described in the patent of the invention with the application publication number of CN 111502149A named as 'a graphite composite plate', but the graphite composite plate can only realize the quick uniform heat conduction on the same plane layer, the heat transfer efficiency in the direction vertical to the graphite plate is not fast enough, and the temperature regulation effect on a room is influenced.

Disclosure of Invention

In order to solve the technical problem, the invention provides a rapid heat exchange graphite plate.

The technical scheme adopted by the invention is as follows: a quick heat exchange graphite plate comprises a water pipe, an energy storage unit and a graphite unit; the graphite units and the energy storage units are uniformly combined in a crossed manner, and the graphite units and the energy storage units form a plate body together; the water pipe penetrates through the plate body.

The invention has the beneficial effects that: according to the invention, the graphite units and the energy storage units are uniformly combined in a cross manner, the heat can be rapidly transferred in the horizontal and vertical directions of the graphite plate by utilizing the good heat conduction performance of the graphite, and the heat can be uniformly distributed in the graphite plate by utilizing the good uniform heat performance of the graphite; meanwhile, the heat energy brought by the graphite is stored by utilizing the heat storage function of the energy storage unit, and the heat is slowly radiated, so that the indoor temperature is comfortable; in addition, the graphite also has good toughness, and can increase the strength of the whole plate and improve the performance of the plate.

Further, the graphite unit is a graphite film layer or a graphene layer, the energy storage unit is an adhesive layer, and the plate body is formed by spacing the graphite film layer or the graphene layer and the adhesive layer.

Further, the graphite unit is thin strip graphite membrane or graphite alkene, the energy storage unit comprises gluing material, thin strip graphite membrane or graphite alkene are mixed and disorderly and glue material homogeneous mixing.

Furthermore, the energy storage unit is formed by uniformly mixing an adhesive and water.

Further, the adhesive is gypsum, cement or resin.

The manufacturing method of the rapid heat exchange graphite plate is characterized by comprising the following steps:

1) cutting the graphite film or graphene into a proper size and shape;

2) mixing an adhesive and water according to a certain proportion to form an adhesive material;

3) compounding the graphite film or the graphene layer by using an adhesive material to form a multilayer material;

4) in the process of the step 3, embedding a water pipe in time;

5) and (5) solidifying the adhesive layer.

The manufacturing method of the rapid heat exchange graphite plate is characterized by comprising the following steps:

1) cutting the graphite film or graphene into strips;

2) uniformly mixing an adhesive and water to form an adhesive material;

3) uniformly mixing the thin strip-shaped graphite film or graphene with the adhesive material;

4) putting into a water pipe;

5) and (5) solidifying the adhesive material.

Drawings

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

FIG. 2 is a cross-sectional view A-A of FIG. 1;

FIG. 3 is a disassembled schematic view of the first embodiment of the present invention;

FIG. 4 is a schematic view of a second embodiment of the present invention;

FIG. 5 is a cross-sectional view of embodiment two B-B of the present invention.

Graphite unit 2, energy storage unit 2, water pipe 3.

Detailed Description

The invention is further described with reference to the following figures and examples.

In the embodiment, as shown in fig. 1 and 4, the rapid heat exchange graphite plate comprises a water pipe 3, an energy storage unit 2 and a graphite unit 1; the graphite unit 1 and the energy storage unit 2 are uniformly combined in a crossed manner, and form a plate body together; the water pipe 3 penetrates the plate body. In the embodiment, the heat brought by the water pipe 3 is rapidly and uniformly transferred and distributed in the plate by utilizing the good heat conduction and heat equalization performance of the graphite; meanwhile, the heat storage function of the energy storage unit 2 is utilized to store the heat brought by the graphite unit 1, and the heat is slowly radiated, so that the indoor temperature is comfortable; in addition, the graphite also has good toughness, and can increase the strength of the whole plate and improve the performance of the plate.

In the first embodiment, as shown in fig. 1 to 3, the graphite unit 1 is a graphite film layer or a graphene layer, the energy storage unit 2 is an adhesive layer, and the plate body is formed by laminating the graphite film layer or the graphene layer and the adhesive layer. In an embodiment, the water pipe 3 is integrally poured in the plate body, the graphite film layer or the graphene layer comprises multiple layers, and the multiple layers of graphite films can realize rapid uniform heat conduction in the horizontal direction and rapid heat conduction in the vertical direction, so that heat brought by the water pipe 3 can be rapidly and uniformly transferred to each corner of the plate body.

In the second embodiment, as shown in fig. 4 to 5, the graphite unit 1 is a thin strip-shaped graphite film or graphene, the energy storage unit 2 is made of an adhesive material, and the thin strip-shaped graphite film or graphene is mixed with the adhesive material uniformly in a disordered manner. In the second embodiment, water pipe 3 runs through in the board that is formed by the silent membrane of thin strip stone or graphite alkene and the even mixture of adhesive material, adhesive material solidifies the back as energy storage unit 2, the silent membrane of thin strip stone of equipartition or graphite alkene in the board are as the even heat of 1 heat conduction of graphite unit to make the heat in water pipe 3 can reach each position of board fast evenly, realize the even quick transmission of heat in each position, the rethread energy storage unit 2 slowly dispels the heat, adjust the room temperature, it is stable comfortable to make the room temperature.

In the embodiment, the energy storage unit 2 is formed by uniformly mixing an adhesive and water. The adhesive can be gypsum, cement, resin and the like, has small heat conductivity coefficient and good heat preservation effect, can be used as the energy storage unit 2, stores heat and slowly dissipates heat, and therefore can realize stability and comfort at room temperature.

In one embodiment, a method for manufacturing a rapid heat exchange graphite plate includes the following steps:

1) cutting the graphite film or graphene into a proper size and shape;

2) mixing an adhesive and water according to a certain proportion to form an adhesive material;

3) compounding the graphite film or the graphene layer by using an adhesive material to form a multilayer material;

4) in the process of the step 3, embedding a water pipe in time;

5) and (5) solidifying the adhesive layer.

In a second embodiment, a method for manufacturing a rapid heat exchange graphite plate includes the following steps:

1) cutting the graphite film or graphene into strips;

2) uniformly mixing an adhesive and water to form an adhesive material;

3) uniformly mixing the thin strip-shaped graphite film or graphene with the adhesive material;

4) a water pipe 3 is put in;

5) and (5) solidifying the adhesive material.

It should be understood that the above-described embodiments of the present invention are merely examples for illustrating the present invention, and are not intended to limit the embodiments of the present invention. Obvious variations or modifications of the present invention are possible within the spirit of the present invention.

Claims (7)

1. A quick heat exchange graphite plate is characterized in that: comprises a water pipe (3), an energy storage unit (2) and a graphite unit (1); the graphite unit (1) and the energy storage unit (2) are uniformly combined in a crossed manner to form a plate body; the water pipe (3) penetrates through the plate body.

2. The rapid heat exchange graphite sheet of claim 1, wherein: the energy storage unit is characterized in that the graphite unit (1) is a graphite film layer or a graphene layer, the energy storage unit (2) is an adhesive layer, and the plate body is formed by spacing the graphite film layer or the graphene layer and the adhesive layer.

3. The rapid heat exchange graphite sheet of claim 2, wherein: graphite unit (1) is thin strip graphite membrane or graphite alkene, energy storage unit (2) comprises the gluing material, thin strip graphite membrane or graphite alkene are mixed and disorderly and glue the material homogeneous mixing.

4. The rapid heat exchange graphite sheet of claim 1, wherein: the energy storage unit (2) is formed by uniformly mixing an adhesive and water.

5. The rapid heat exchange graphite sheet of claim 4, wherein: the adhesive is gypsum, cement or resin.

6. The manufacturing method of the rapid heat exchange graphite plate is characterized by comprising the following steps:

cutting the graphite film or graphene into a proper size and shape;

mixing an adhesive and water according to a certain proportion to form an adhesive material;

3) compounding the graphite film or the graphene layer by using an adhesive material to form a multilayer material;

4) in the process of the step 3, embedding a water pipe in time;

5) and (5) solidifying the adhesive layer.

7. The manufacturing method of the rapid heat exchange graphite plate is characterized by comprising the following steps:

cutting the graphite film or graphene into strips;

uniformly mixing an adhesive and water to form an adhesive material;

uniformly mixing the thin strip-shaped graphite film or graphene with the adhesive material;

putting into a water pipe;

and (5) solidifying the adhesive material.

Images