AU2020101308A4 - Energy storage wall and solar greenhouse - Google Patents

Abstract

Our Ref.: 6966-191503AU ABSTRACT The present disclosure relates to an energy storage wall and a solar greenhouse. The energy storage wall comprises a wall body, a heat absorption pipe layer, a heat storage pipe layer, a 5 first connecting pipe and a second connecting pipe, wherein the heat absorption pipe layer is laid on a surface of one side in a thickness direction of the wall body; the heat storage pipe layer is laid inside the wall body; an upper end of the heat absorption pipe layer is connected with an upper end of the heat storage pipe layer through the first connecting pipe, and a lower end of the heat absorption pipe layer is connected with a lower end of the heat storage pipe 10 layer through the second connecting pipe, such that the heat absorption pipe layer and the heat storage pipe layer communicate with each other to form a heat transfer pipeline in which a fluid heat transfer medium is provided, the fluid heat transfer medium being capable of circulating in the heat transfer pipeline under the action of temperature difference. The energy storage wall according to the present disclosure can effectively improve the heat storage 15 capacity of the wall body. 13 Our Ret: 6966-191503AU DRAWING OF ABSTRACT 14 43 42 41 21 31 5 51 52 53 5 FIG. 3 1

Description

Our Ret: 6966-191503AU

DRAWING OF ABSTRACT

14

43 42 41

21 31 5 51 52 53 FIG. 3

Our Ref.: 6966-191503AU

SPECIFICATION TITLE ENERGY STORAGE WALL AND SOLAR GREENHOUSE CROSS-REFERENCE TO RELATED APPLICATIONS

The present application claims the priority of the application for a patent for invention filed in

China on April 9, 2020 with the application number of 202010275472.3 and the title of

"Energy Storage Wall and Solar Greenhouse", the entire content of which being herewith

incorporated by reference as if fully disclosed herein.

TECHNICAL FIELD

The present disclosure relates to the technical field of agricultural facilities, and in particular

relates to an energy storage wall and a solar greenhouse.

BACKGROUND

Solar greenhouse is a professional equipment widely used in vegetable cultivation. In the wall

of a solar greenhouse, due to the thermal performance of wall materials and structural reasons,

there is a stable layer with a lower temperature about 200 to 300 mm away from the inner

surface of the wall. Usually, the temperature of the stable layer is not higher than 10°C, and the

existence of this low temperature zone greatly limits the heat storage capacity of the wall,

which in turn has an adverse impact on the thermal environment of the solar greenhouse.

SUMMARY

In view of the above defect in the prior art, an object of the present disclosure is to provide an

energy storage wall which can improve the heat storage capacity of the wall and a solar

greenhouse with the energy storage wall.

To this end, the present disclosure provides the following technical solution.

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The present disclosure provides an energy storage wall which comprises a wall body, a heat

absorption pipe layer, a heat storage pipe layer, a first connecting pipe and a second connecting

pipe,

wherein the heat absorption pipe layer is laid on a surface of one side in a thickness direction of

the wall body, and the heat storage pipe layer is laid inside the wall body,

wherein an upper end of the heat absorption pipe layer is connected with an upper end of the

heat storage pipe layer through the first connecting pipe, and a lower end of the heat absorption

pipe layer is connected with a lower end of the heat storage pipe layer through the second

connecting pipe, such that the heat absorption pipe layer and the heat storage pipe layer

communicate with each other to form a heat transfer pipeline, and

wherein a fluid heat transfer medium is provided in the heat transfer pipeline, and can circulate

in the heat transfer pipeline under the action of temperature difference.

In at least one embodiment, the heat absorption pipe layer and the heat storage pipe layer are

arranged facing each other in the thickness direction of the wall body.

In at least one embodiment, in a pipe section of the first connecting pipe arranged along the

thickness direction of the wall body, one end of the pipe section close to the heat absorption

pipe layer is higher than the other end of the pipe section close to the heat storage pipe layer.

In at least one embodiment, the energy storage wall further comprises an insulation layer which

is at least provided on a surface of the other side in the thickness direction of the wall body and

an upper end surface of the wall body.

In at least one embodiment, the heat absorption pipe layer comprises a plurality of heat

absorption pipes which are arranged at intervals along a length direction of the wall body.

In at least one embodiment, the heat storage pipe layer comprises a plurality of heat storage

pipes which are arranged at intervals along the length direction of the wall body.

In at least one embodiment, the number of the heat absorption pipes in the heat absorption pipe

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layer is equal to the number of the heat storage pipes in the heat storage pipe layer.

In at least one embodiment, a surface of the heat absorption pipe layer is black.

In at least one embodiment, the heat absorption pipe layer and/or the heat storage pipe layer are

vertically arranged.

The present disclosure also provides a solar greenhouse, which comprises an energy storage

wall according to any one of the above embodiments, and the surface of one side of the energy

storage wall is located inside the solar greenhouse.

By adopting the above technical solution, the present disclosure provides an energy storage

wall.

By providing a heat absorption pipe layer on the surface of the wall body and providing a heat

storage pipe layer inside the wall body, the energy storage wall can effectively transmit the heat

generated by the sun to the inside of the wall body and store it by the wall body, thereby

effectively improving the heat storage capacity of the wall body.

It can be understood that the solar greenhouse with the energy storage wall has the same

beneficial effects.

BRIEF DESCRIPTION OF THE DRAWINGS

Fig. 1 is a schematic drawing showing the structure of a solar greenhouse according to the

present disclosure.

Fig. 2 shows a sectional view taken along a direction A in Fig. 1.

Fig. 3 shows a structural diagram of an energy storage wall according to the present disclosure.

Explanation of the reference numerals

10 energy storage wall; 20 roof; 30 greenhouse space

1 wall body; 2 heat absorption pipe layer; 21 heat absorption pipe; 3 heat storage pipe layer; 31

heat storage pipe;

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4 first connecting pipe; 41 upper heat absorption header section; 42 upper heat storage header

section; 43 upper connecting pipe section;

5 second connecting pipe; 51 lower heat absorption header section; 52 lower heat storage

header section; 53 lower connecting pipe section;

6 insulation layer

DETAILED DESCRIPTION OF THE ILLUSTRATED EMBODIMENTS

Exemplary embodiments of the present disclosure are described below with reference to the

accompanying drawings. It should be understood that these specific descriptions are only

intended for teaching those skilled in the art how to implement the present disclosure, instead

of exhausting all possible implementing modes of the present disclosure or limiting the scope

of protection of the present disclosure.

Hereinafter, a specific embodiment of the solar greenhouse according to the present disclosure

will be described in detail with reference to Figs. 1 to 3.

In the present embodiment, as shown in Fig. 1, the solar greenhouse comprises an energy

storage wall 10 and a roof 20 which are combined to form a closed greenhouse space 30 for the

growth of vegetables and other plants.

In the present embodiment, as shown in Figs. 1, 2 and 3, the energy storage wall 10 comprises

a wall body 1, a heat absorption pipe layer 2, a heat storage pipe layer 3, a first connecting pipe

4, a second connecting pipe 5 and an insulation layer 6.

The heat absorption pipe layer 2 consists of a heat absorption pipe 21 which is laid on a surface

of one side of the wall body 1 close to the greenhouse space 30 in a thickness direction of the

wall body 1. There may be a plurality of heat absorption pipes 21 which are arranged at

intervals along a length direction of the wall body 1. The heat absorption pipes 21 may be

vertically arranged or may be disposed at a certain included angle with respect to a vertical

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direction.

The heat storage pipe layer 3 comprises a heat storage pipe 31 vertically provided inside the

wall body 1. There may be a plurality of heat storage pipes 31 which are arranged at intervals

along the length direction of the wall body 1. The heat storage pipes 31 may be vertically

disposed or may be disposed at a certain included angle with respect to the vertical direction.

It should be understood that the heat storage pipe layer 3 may be arranged in one row (as

shown in Fig. 1) or in multiple rows in the thickness direction of the wall body 1.

In the present embodiment, the heat storage pipe layer 3 may be disposed 200-300 mm away

from a surface of one side of the wall body 1 where the heat absorption pipe layer 2 is disposed.

In this way, it is beneficial for the stable layer with a lower temperature to store heat.

An upper end of the heat absorption pipe layer 2 and an upper end of the heat storage pipe

layer 3 are connected by a first connecting pipe 4, and a lower end of the heat absorption pipe

layer 2 and a lower end of the heat storage pipe layer 3 are connected by a second connecting

pipe 5, such that the mutually connected heat absorption pipe layer 2 and the heat storage pipe

layer 3 form a heat transfer pipeline. A fluid heat transfer medium (for example, water or oil) is

provided in the heat transfer pipeline, and can circulate in the heat transfer pipeline.

In the present embodiment, as shown in Fig. 3, the heat absorption pipes 21 and the heat

storage pipes 31 are arranged facing each other in the thickness direction of the wall body 1.

The heat absorption pipes 21 and the heat storage pipes 31 may be arranged in one-to-one

correspondence, and the number of the heat absorption pipes 21 and the number of the heat

storage pipes 31 may be equal. Undoubtedly, the present disclosure is not limited to this, and

the number of the heat absorption pipes 21 and that of the heat storage pipes 31 may be

different.

It can be understood that each heat absorption pipe 21 and the corresponding heat storage pipe

31 may be connected by a set of connecting pipes (one upper connecting pipe and one lower

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connecting pipe), or multiple heat absorption pipes 21 and multiple heat storage pipes 31 may

be connected by a set of connecting pipes (one upper connecting pipe and one lower

connecting pipe).

In a case where one heat absorption pipe 21 and the corresponding heat storage pipe 31 are

connected by a set of connecting pipes (one upper connecting pipe and one lower connecting

pipe), the connecting pipes may be straight pipes extending substantially along the thickness

direction of the wall body 1.

In a case where a plurality of heat absorption pipes 21 and a plurality of heat storage pipes 31

are connected by a set of connecting pipes (one upper connecting pipe and one lower

connecting pipe), an upper first connecting pipe 4 may include an upper heat absorption header

section 41 and an upper heat storage header section 42 which extend substantially along the

length direction of the wall body 1, and an upper connecting pipe section 43 which extends

substantially along the thickness direction of the wall body 1. Upper ends of the plurality of

heat absorption pipes 21 are connected to the upper heat absorption header section 41, upper

ends of the plurality of heat storage pipes 31 are connected to the upper heat storage header

section 42, and the upper connecting pipe section 43 is connected to the upper heat absorption

header section 41 and the upper heat storage header section 42. A lower second connecting pipe

5 may include a lower heat absorption header section 51 and a lower heat storage header

section 52 which extend substantially along the length direction of the wall body 1, and a lower

connecting pipe section 53 which extends substantially along the thickness direction of the wall

body 1. Lower ends of the plurality of heat absorption pipes 21 are connected to the lower heat

absorption header section 51, lower ends of the plurality of heat storage pipes 31 are connected

to the lower heat storage header section 52, and the lower connecting pipe section 53 is

connected to the lower heat absorption header section 51 and the lower heat storage header

section 52.

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As shown in Fig. 3, the first connecting pipe 4 and the second connecting pipe 5 may be

straight pipes, and may also be U-shaped or H-shaped bent pipes.

In the present embodiment, when the first connecting pipe 4 is a straight pipe, one end of the

first connecting pipe 4 connected to the heat absorption pipe 21 may be higher than the other

end of the first connecting pipe 4 connected to the heat storage pipe 31. Optionally, a gradient

formed by the first connecting pipe 4 may be1%.

When the first connecting pipe 4 is U-shaped or H-shaped, one end of the upper connecting

pipe section 43 close to the heat absorption pipe 21 may be higher than the other end of the

upper connecting pipe section 43 close to the heat storage pipe 31. Optionally, a gradient

formed by the upper connecting pipe section 43 may be I%.

In the present embodiment, the surface of the heat absorption pipes 21 may be painted black. In

this way, it is beneficial to enhance the absorption of solar energy by the heat absorption pipes

21.

In the present embodiment, as shown in Figs. 1 and 2, the insulation layer 6 is provided on a

surface of one side of the wall body 1 away from the greenhouse space 30 and on the upper end

surface of the wall body 1. In this way, it is possible to reduce the loss of heat stored in the wall

body 1.

In the present embodiment, an exhaust device (e.g., an exhaust valve) may be provided at the

top of the heat absorption pipe layer 2.

The working principle of the energy storage wall according to the present disclosure will be

described below.

In daytime, after absorbing the heat radiated by the sun (as shown by the arrows in Fig. 1), the

temperature of the heat absorption pipe layer 2 rises, and the fluid heat transfer medium (e.g.,

water or oil) in the heat absorption pipe layer 2 becomes less dense after being heated. The

fluid heat transfer medium enters the heat storage pipe layer 3 by buoyancy, and releases heat

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to the wall body 1 in the heat storage pipe layer 3, then the temperature of the fluid heat

transfer medium decreases and the density increases, and then the fluid heat transfer medium

flows downward back to the heat absorption pipe layer 2. This process is repeated to store the

heat within the wall body 1.

At night, the heat in the wall body 1 is dissipated into the heat storage pipe layer 3, and the

density of the fluid heat transfer medium in the heat storage pipe layer 3 decreases after being

heated, such that the fluid heat transfer medium flows upward into the heat absorption pipe

layer 2 and releases the heat into the greenhouse space 30. After the fluid heat transfer medium

releases heat, its temperature decreases and its density increases, and then flows downward

back into the heat storage pipe layer 3. By repeating this process, the heat accumulated in the

wall body 1 can be released into the greenhouse space 30, meeting the growth demand of

plants such as vegetables in the greenhouse space 30.

It can be understood that with the energy storage wall according to the present disclosure, the

fluid heat transfer medium can naturally convect under the action force formed by the

temperature difference, such that solar energy can be stored in the wall body, and the heat in

the wall body can also be released into the greenhouse space.

By adopting the above-described technical solution, the energy storage wall according to the

present disclosure has at least the following advantages:

(1) in the energy storage wall of the present disclosure, by providing a heat absorption pipe

layer on the surface of the wall body and providing a heat storage pipe layer inside the wall

body, the heat emitted by the sun can be effectively transmitted to the inside of the wall body

and stored by the wall body, thereby effectively improving the heat storage capacity of the wall

body;and

(2) in the energy storage wall of the present disclosure, the surface of the heat absorption pipes

is painted black, which is beneficial to enhancing the absorption of solar energy by the heat

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absorption pipes.

Claims (10)

Our Ref.: 6966-191503AU THE CLAIMS DEFINING THE INVENTION ARE AS FOLLOWS:

1. An energy storage wall (10), characterized in that the energy storage wall (10) comprises a

wall body (1), a heat absorption pipe layer (2), a heat storage pipe layer (3), a first connecting

pipe (4) and a second connecting pipe (5),

wherein the heat absorption pipe layer (2) is laid on a surface of one side in a thickness

direction of the wall body (1), and the heat storage pipe layer (3) is laid inside the wall body

(1),

wherein an upper end of the heat absorption pipe layer (2) is connected with an upper end of

the heat storage pipe layer (3) through the first connecting pipe (4), and a lower end of the heat

absorption pipe layer (2) is connected with a lower end of the heat storage pipe layer (3)

through the second connecting pipe (5), such that the heat absorption pipe layer (2) and the

heat storage pipe layer (3) communicate with each other to form a heat transfer pipeline, and

wherein a fluid heat transfer medium is provided in the heat transfer pipeline, the fluid heat

transfer medium being capable of circulating in the heat transfer pipeline under an action of

temperature difference.

2. The energy storage wall (10) according to claim 1, characterized in that the heat absorption

pipe layer (2) and the heat storage pipe layer (3) are arranged facing each other in the thickness

direction of the wall body (1).

3. The energy storage wall (10) according to claim 1, characterized in that in a pipe section of

the first connecting pipe (4) arranged along the thickness direction of the wall body (1), one

end of the pipe section close to the heat absorption pipe layer (2) is higher than the other end of

the pipe section close to the heat storage pipe layer (3).

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4. The energy storage wall (10) according to claim 1, characterized in that the energy storage

wall (10) further comprises an insulation layer (6), which is at least provided on a surface of

the other side in the thickness direction of the wall body (1) and an upper end surface of the

wall body (1).

5. The energy storage wall (10) according to claim 1, characterized in that the heat absorption

pipe layer (2) comprises a plurality of heat absorption pipes (21) which are arranged at

intervals along a length direction of the wall body (1).

6. The energy storage wall (10) according to claim 1, characterized in that the heat storage pipe

layer (3) comprises a plurality of heat storage pipes (31) which are arranged at intervals along a

length direction of the wall body (1).

7. The energy storage wall (10) according to claim 1, characterized in that the heat absorption

pipe layer (2) comprises a plurality of heat absorption pipes (21) and the heat storage pipe layer

(3) comprises a plurality of heat storage pipes (31), wherein the number of the heat absorption

pipes (21) in the heat absorption pipe layer (2) is equal to that of the heat storage pipes (31) in

the heat storage pipe layer (3).

8. The energy storage wall (10) according to claim 1, characterized in that a surface of the heat

absorption pipe layer (2) is black.

9. The energy storage wall (10) according to claim 1, characterized in that the heat absorption

pipe layer (2) and/or the heat storage pipe layer (3) are vertically arranged.

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10. A solar greenhouse, characterized in that the solar greenhouse comprises the energy storage

wall (10) according to any one of claims 1 to 9, and the surface of the one side is located inside

the solar greenhouse.

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DRAWING OF ABSTRACT 2020101308

5 FIG. 3

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DRAWINGS 2020101308

FIG. 1 5

FIG. 2

2020101308 Our Ref.: 6966-191503AU

FIG. 3