CN220339185U - Water storage and heat exchange device of sponge city reservoir - Google Patents

Abstract

The utility model provides a water storage heat exchange device of a sponge city reservoir, which comprises a body, wherein the body comprises a plurality of water storage heat exchange modules and connecting pieces, the water storage heat exchange modules comprise a shell, a plurality of first partition plates and a plurality of second partition plates are arranged in the shell, the inner space of the shell is divided into a plurality of water storage units by the first partition plates and the second partition plates, a support column is arranged in each water storage unit, and the water storage units are used for storing water; a heat exchange pipeline is also arranged in the shell; the heat exchange pipelines in the water storage heat exchange modules are sequentially connected by the connecting pieces and then communicated with the water source heat pump unit to form a heat pump system for heating or refrigerating surrounding buildings. The device adopts modular structure, can change the concatenation form of retaining heat transfer module according to the in-service use needs, and production and transportation cost are low.

Description

Water storage and heat exchange device of sponge city reservoir

Technical Field

The utility model relates to the technical field of sponge cities, in particular to a water storage and heat exchange device of a sponge city reservoir.

Background

The sponge city is a new generation city rain and flood management concept, and the city can be like a sponge, has good elasticity in the aspects of adapting to environmental changes, coping with natural disasters caused by rainwater and the like, and can be also called as a 'water elasticity city'.

The city can be like a sponge, has good elasticity in the aspects of adapting to environmental changes, coping with natural disasters and the like, and the international general term is 'low-influence development rainwater system construction', absorbs water, stores water, permeates water and purifies water during raining, and releases and utilizes the stored water when needed so as to realize free migration of rainwater in the city.

From the ecological system service, the construction of the water ecological infrastructure through the trans-scale construction and the combination of various specific technologies is the core of the sponge city.

Under the new situation, the sponge city promotes the green building construction, the low-carbon city development and the innovative expression formed by the smart city, and is the organic combination of the modern green new technology under the new era characteristic background and a plurality of factors such as society, environment, humanity and the like.

The sponge urban material is applied substantially, has the characteristics of excellent water seepage, compression resistance, wear resistance, skid resistance, environmental protection, beautiful appearance, comfort, easy maintenance, sound absorption, noise reduction and the like, forms the urban landscape pavement capable of breathing, effectively relieves the urban heat island effect, and prevents the urban pavement from generating heat.

Meanwhile, the sponge body of the sponge city is a huge energy reservoir, a great amount of developable energy is reserved, and the heat pump system is combined to provide refrigerating and heating services for the city.

For the above reasons, there is a need for a water storage and heat exchange device for a sponge city reservoir to develop and utilize energy in the sponge city sponge.

Disclosure of Invention

The utility model aims to provide a water storage heat exchange device of a sponge city reservoir, which is assembled into a sponge city precipitation collection water tank with proper size through a plurality of water storage heat exchange modules, can fully utilize huge heat contained in water, and provides refrigeration and heating services for surrounding buildings by combining a water source heat pump unit.

In order to achieve the above object, the present utility model provides the following technical solutions:

the device is buried underground in the ground of a sponge city, and comprises a body, wherein the body comprises a plurality of water storage heat exchange modules and connecting pieces, each water storage heat exchange module comprises a shell, a plurality of first partition plates and a plurality of second partition plates are arranged in the shell, the inner space of the shell is divided into a plurality of water storage units by the first partition plates and the second partition plates, each water storage unit is internally provided with a support column, each support column is used for supporting the corresponding water storage unit, and each water storage unit is used for storing water; a heat exchange pipeline is also arranged in the shell; and the water storage heat exchange modules are sequentially spliced to form a matrix structure, and the heat exchange pipelines in the water storage heat exchange modules are sequentially connected by the connecting pieces and then are communicated with the water source heat pump unit.

Further, in the sponge city reservoir water storage heat exchange device, the shell comprises four side plates, the four side plates are sequentially connected and then enclose into the shell, two ends of the first partition plate are respectively connected with two opposite side plates, two ends of the second partition plate are respectively connected with two other side plates, the upper end of the first partition plate is flush with the upper end of the shell, the upper end of the second partition plate is flush with the upper end of the shell, a distance exists between the lower end of the first partition plate and the lower end of the shell, and the lower end of the second partition plate is flush with the lower end of the shell; the first partition plates are uniformly arranged along the width direction of the shell, and the second partition plates are uniformly arranged along the length direction of the shell.

Further, in the water storage and heat exchange device of the sponge city reservoir, the support column is of a round platform structure, and the inside of the support column is hollow; the large end of the support column is flush with the upper end of the shell, and the small end of the support column is flush with the lower end of the shell; a plurality of fixing plates are arranged around the support columns, and the support columns are connected with the first partition plate, the second partition plate or the side plates through the fixing plates.

Further, in the water storage heat exchange device of the sponge city reservoir, the first partition plate is provided with two blocks, the second partition plate is provided with three blocks, and the first partition plate and the second partition plate divide the inner space of the shell into twelve water storage units.

Further, in the water storage heat exchange device of the sponge city reservoir, the length of the shell is 800mm, the width of the shell is 600mm, and the height of the shell is 300mm.

Further, in the water storage heat exchange device of the sponge city reservoir, two heat exchange pipelines are arranged in the water storage heat exchange module, the space between the lower surface of the first partition plate and two adjacent rows of support columns is used for accommodating the heat exchange pipelines, the width of the heat exchange pipelines is consistent with that of the shell, and the axis of the heat exchange pipelines is parallel to that of the first partition plate; the outer wall of the heat exchange pipeline is connected with the two rows of support columns and the lower surface of the first partition plate.

Further, in the water storage heat exchange device of the sponge city water storage tank, in the vertical direction of the device, the upper ends of the two water storage heat exchange modules are connected with each other, or the lower ends of the two water storage heat exchange modules are connected with each other; two adjacent water storage heat exchange modules are fixedly connected through a clamp.

Further, in the water storage heat exchange device of the sponge city reservoir, the connecting piece comprises an embedded joint, a first elbow and a second elbow, the embedded joint is a straight joint, the first elbow and the second elbow are both U-shaped elbows, and the length of the main body of the first elbow is smaller than that of the main body of the second elbow; in the horizontal direction of the device, the heat exchange pipelines in two adjacent water storage heat exchange modules are connected through the embedded joints; in the vertical direction of the device, the heat exchange pipelines in the two water storage heat exchange modules with the upper ends mutually connected are connected through the first elbow; the device is in the vertical direction, and the lower extreme interconnect's two in the retaining heat transfer module the heat transfer pipeline passes through the second elbow connection.

Further, in the water storage heat exchange device of the sponge city reservoir, the water storage heat exchange module is made of pp materials.

Further, in the water storage and heat exchange device of the sponge city reservoir, the device further comprises a bottom plate and a protective plate protective layer, the body is arranged on the bottom plate, the bottom plate is formed by pouring concrete, and the periphery of the body is wrapped by a geomembrane and an impermeable membrane; the protection board protective layer covers the upper portion of the body, and the protection board protective layer is made of XPS extruded sheets.

According to analysis, the utility model discloses a water storage heat exchange device of a sponge city reservoir, which has good stability by arranging a plurality of first partition plates, a plurality of second partition plates and support columns in a water storage heat exchange module, wherein the inner space of the water storage heat exchange module is used for storing water, the water storage rate is high, the device adopts a modularized structure, the splicing form of the water storage heat exchange module can be changed according to actual use requirements, and the production and transportation cost is low. The water storage heat exchange module is combined and then connected with the water source heat pump unit to form a heat pump system for heating or refrigerating the surrounding building. The water storage heat exchange module is made of pp materials, so that the device can bear larger upper pavement pressure. The body wraps up geomembrane and prevention of seepage membrane all around, and the body below sets up the bottom plate of concrete, prevents the loss of water, and the water storage rate is high.

Drawings

The accompanying drawings, which are included to provide a further understanding of the utility model and are incorporated in and constitute a part of this specification, illustrate embodiments of the utility model and together with the description serve to explain the utility model. Wherein:

fig. 1 is a schematic structural diagram of an embodiment of the present utility model.

Fig. 2 is a schematic top view of a water storage heat exchange module according to an embodiment of the utility model.

Fig. 3 is a schematic left-view structural diagram of a water storage heat exchange module according to an embodiment of the utility model.

Fig. 4 is a schematic cross-sectional structure of the N-N direction of fig. 2.

Fig. 5 is a schematic cross-sectional structure of the M-M direction of fig. 2.

Fig. 6 is a schematic structural diagram of heat exchange pipeline connection between water storage heat exchange modules according to an embodiment of the utility model.

Fig. 7 is a schematic structural view of an embedded joint according to an embodiment of the utility model.

Fig. 8 is a schematic structural view of a first elbow according to an embodiment of the present utility model.

Fig. 9 is a schematic structural view of a second elbow according to an embodiment of the present utility model.

Reference numerals illustrate: 1 a water storage heat exchange module; 2 a shell; 3 a first separator; 4 a second separator; 5 supporting columns; 6, a heat exchange pipeline; 7, embedding a joint; 8, a first elbow; 9, a second elbow; 10, fixing a plate; 11 body.

Detailed Description

The utility model will be described in detail below with reference to the drawings in connection with embodiments. The examples are provided by way of explanation of the utility model and not limitation of the utility model. Indeed, it will be apparent to those skilled in the art that modifications and variations can be made in the present utility model without departing from the scope or spirit of the utility model. For example, features illustrated or described as part of one embodiment can be used on another embodiment to yield still a further embodiment. Accordingly, it is intended that the present utility model encompass such modifications and variations as fall within the scope of the appended claims and their equivalents.

In the description of the present utility model, the terms "longitudinal", "transverse", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", etc. refer to the orientation or positional relationship based on that shown in the drawings, merely for convenience of description of the present utility model and do not require that the present utility model must be constructed and operated in a specific orientation, and thus should not be construed as limiting the present utility model. The terms "coupled," "connected," and "configured" as used herein are to be construed broadly and may be, for example, fixedly connected or detachably connected; can be directly connected or indirectly connected through an intermediate component; either a wired electrical connection, a radio connection or a wireless communication signal connection, the specific meaning of which terms will be understood by those of ordinary skill in the art as the case may be.

One or more examples of the utility model are illustrated in the accompanying drawings. The detailed description uses numerical and letter designations to refer to features in the drawings. Like or similar designations in the drawings and description have been used to refer to like or similar parts of the utility model. As used herein, the terms "first," "second," and "third," etc. are used interchangeably to distinguish one component from another and are not intended to represent the location or importance of the individual components.

As shown in fig. 1 to 9, according to an embodiment of the present utility model, there is provided a water storage and heat exchange device of a sponge city reservoir, as shown in fig. 1, which is buried under the ground of the sponge city, the device including a body 11, the body 11 including a plurality of water storage and heat exchange modules 1 and connecting members, wherein, as shown in fig. 2 to 5, the water storage and heat exchange modules 1 include a housing 2, a plurality of first partition plates 3 and a plurality of second partition plates 4 are provided in the housing 2, the inner space of the housing 2 is divided into a plurality of water storage units by the plurality of first partition plates 3 and the plurality of second partition plates 4, each water storage unit is provided therein with a support column 5, the support column 5 is used for forming a support for the water storage unit, and the water storage unit is used for water storage; as shown in fig. 3, a heat exchange pipeline 6 is also arranged in the shell 2. The water storage heat exchange modules 1 are spliced in sequence to form a matrix structure, and the heat exchange pipelines 6 in the water storage heat exchange modules 1 are connected in sequence by the connecting piece and then communicated with the water source heat pump unit. The device makes the device have fine stability through setting up polylith first baffle 3, polylith second baffle 4 and support column 5 in retaining heat transfer module 1, and the inner space of retaining heat transfer module 1 is used for retaining, and the water storage rate is high, and the device adopts modular structure, can change the concatenation form of retaining heat transfer module 1 according to the in-service use needs, and production and transportation cost are low. The water storage heat exchange module 1 is combined and then connected with a water source heat pump unit to form a heat pump system for heating or refrigerating the surrounding building.

Further, the external dimension of the water storage heat exchange module 1 is rectangular, the shell 2 of the water storage heat exchange module 1 comprises four side plates, the four side plates are sequentially connected and then form the shell 2, two ends of the first partition plate 3 are respectively connected with two opposite side plates in the length direction of the water storage heat exchange module 1, two ends of the second partition plate 4 are respectively connected with the other two side plates, the upper end of the first partition plate 3 is flush with the upper end of the shell 2, the upper end of the second partition plate 4 is flush with the upper end of the shell 2, a distance exists between the lower end of the first partition plate 3 and the lower end of the shell 2, and the lower end of the second partition plate 4 is flush with the lower end of the shell 2; the plurality of first partitions 3 are uniformly arranged in the width direction of the housing 2, and the plurality of second partitions 4 are uniformly arranged in the length direction of the housing 2. The support column 5 is of a truncated cone structure, the inside of the support column 5 is hollow, and the upper end and the lower end of the support column 5 are open; the large end of the support column 5 is flush with the upper end of the shell 2, and the small end of the support column 5 is flush with the lower end of the shell 2; a plurality of fixing plates 10 are arranged around the supporting columns 5, and the supporting columns 5 are connected with the first partition plate 3, the second partition plate 4 or the side plates through the fixing plates 10. The first partition plate 3 and the second partition plates 4 provide stable support for the water storage heat exchange module 1, so that the device has good stability.

Further, the first partition plate 3 is provided with two, the second partition plate 4 is provided with three, the first partition plate 3 and the second partition plate 4 divide the inner space of the shell 2 into twelve water storage units, and the stability of the device can be improved while the device has a high water storage rate through the arrangement.

Further, the housing 2 has a length of 800mm, a width of 600mm, and a height of 300mm. The sponge city precipitation collection water tank with proper size can be assembled by utilizing the water storage heat exchange module 1, and the production and transportation cost is low.

Further, two heat exchange pipelines 6 are arranged in the water storage heat exchange module 1, the space between the lower surface of the first partition plate 3 and the adjacent two rows of support columns 5 is used for accommodating the heat exchange pipelines 6, the width of each heat exchange pipeline 6 is consistent with that of the shell 2, the axis of each heat exchange pipeline 6 is parallel to that of the first partition plate 3, and each heat exchange pipeline 6 sequentially penetrates one side plate, a plurality of second partition plates 4 and the other side plate; the outer wall of the heat exchange pipeline 6 is connected with the lower surfaces of the two rows of support columns 5 and the first partition plate 3. The two heat exchange pipelines 6 are arranged in the water storage heat exchange module 1, so that the heat exchange efficiency can be improved.

Further, in the vertical direction of the device, the upper ends of the two water storage heat exchange modules 1 are connected with each other, or the lower ends of the two water storage heat exchange modules 1 are connected with each other, so that the structural stability of the device can be improved. Two adjacent water storage heat exchange modules 1 are fixedly connected through a clamp.

Further, as shown in fig. 7 to 9, the connecting piece includes an embedded joint 7, a first elbow 8 and a second elbow 9, the embedded joint 7 is a straight joint, the first elbow 8 and the second elbow 9 are both U-shaped elbows, and the length of the main body of the first elbow 8 is smaller than that of the main body of the second elbow 9; in the horizontal direction of the device, heat exchange pipelines 6 in two adjacent water storage heat exchange modules 1 are connected through embedded joints 7; in the vertical direction of the device, heat exchange pipelines 6 in two water storage heat exchange modules 1 with the upper ends connected with each other are connected through a first elbow 8; in the vertical direction, the heat exchange pipelines 6 in the two water storage heat exchange modules 1 with the lower ends mutually connected are connected through a second elbow 9.

Further, the water storage heat exchange module 1 is made of pp materials, so that the device can bear larger upper pavement pressure.

Further, the device still includes bottom plate and protection shield inoxidizing coating, and the bottom plate is placed in to body 11 on the bottom plate, and the bottom plate is formed by concrete placement, and body 11 wraps up through geomembrane and prevention of seepage membrane all around, so the setting can prevent the loss of water, makes the device have higher water storage rate. The protection shield protection layer covers the top at body 11, and the material of protection shield protection layer is XPS extruded sheet, and the protection shield protection layer can prevent earth debris to drop in the retaining heat transfer module 1.

From the above description, it can be seen that the above embodiments of the present utility model achieve the following technical effects:

the utility model provides a sponge city cistern retaining heat transfer device, the device makes the device have fine stability through setting up polylith first baffle 3, polylith second baffle 4 and support column 5 in retaining heat transfer module 1, retaining heat transfer module 1 inner space is used for retaining, and the device adopts modular structure, can change retaining heat transfer module 1's concatenation form according to the in-service use needs, and production and cost of transportation are low. The water storage heat exchange module 1 is combined and then connected with a water source heat pump unit to form a heat pump system for heating or refrigerating the surrounding building. The water storage heat exchange module 1 is made of pp materials, so that the device can bear larger upper pavement pressure. The body 11 wraps up geomembrane and prevention of seepage membrane all around, and the bottom plate of body 11 below setting up concrete prevents the loss of water, and the water storage rate is high.

The above description is only of the preferred embodiments of the present utility model and is not intended to limit the present utility model, but various modifications and variations can be made to the present utility model by those skilled in the art. Any modification, equivalent replacement, improvement, etc. made within the spirit and principle of the present utility model should be included in the protection scope of the present utility model.

Claims (10)

1. A water storage and heat exchange device of a sponge city reservoir is characterized in that the device is buried under the ground of the sponge city and comprises a body, the body comprises a plurality of water storage and heat exchange modules and connecting pieces, wherein,

the water storage heat exchange module comprises a shell, wherein a plurality of first partition plates and a plurality of second partition plates are arranged in the shell, the inner space of the shell is divided into a plurality of water storage units by the first partition plates and the second partition plates, each water storage unit is internally provided with a support column, the support columns are used for supporting the water storage units, and the water storage units are used for storing water;

a heat exchange pipeline is also arranged in the shell;

and the water storage heat exchange modules are sequentially spliced to form a matrix structure, and the heat exchange pipelines in the water storage heat exchange modules are sequentially connected by the connecting pieces and then are communicated with the water source heat pump unit.

2. The sponge city reservoir water storage heat exchange device of claim 1, wherein,

the shell comprises four side plates, the four side plates are sequentially connected and then enclose into the shell, two ends of a first partition plate are respectively connected with two opposite side plates, two ends of a second partition plate are respectively connected with the other two side plates, the upper end of the first partition plate is flush with the upper end of the shell, the upper end of the second partition plate is flush with the upper end of the shell, a distance exists between the lower end of the first partition plate and the lower end of the shell, and the lower end of the second partition plate is flush with the lower end of the shell;

the first partition plates are uniformly arranged along the width direction of the shell, and the second partition plates are uniformly arranged along the length direction of the shell.

3. The sponge city reservoir water storage heat exchange device of claim 2, wherein,

the support column is of a round platform structure, and the inside of the support column is hollow;

the large end of the support column is flush with the upper end of the shell, and the small end of the support column is flush with the lower end of the shell;

a plurality of fixing plates are arranged around the support columns, and the support columns are connected with the first partition plate, the second partition plate or the side plates through the fixing plates.

4. The sponge city reservoir water storage heat exchange device of claim 1, wherein,

the first partition plate is provided with two, the second partition plate is provided with three, and the first partition plate and the second partition plate divide the inner space of the shell into twelve water storage units.

5. The sponge city reservoir water storage heat exchange device of claim 1, wherein,

the length of the shell is 800mm, the width of the shell is 600mm, and the height of the shell is 300mm.

6. The sponge city reservoir water storage heat exchange device of claim 1, wherein,

two heat exchange pipelines are arranged in the water storage heat exchange module, the space between the lower surface of the first partition plate and two adjacent rows of support columns is used for accommodating the heat exchange pipelines, the width of each heat exchange pipeline is consistent with that of the shell, and the axis of each heat exchange pipeline is parallel to that of the first partition plate;

the outer wall of the heat exchange pipeline is connected with the two rows of support columns and the lower surface of the first partition plate.

7. The sponge city reservoir water storage heat exchange device of claim 1, wherein,

in the vertical direction of the device, the upper ends of the two water storage heat exchange modules are connected with each other, or the lower ends of the two water storage heat exchange modules are connected with each other;

two adjacent water storage heat exchange modules are fixedly connected through a clamp.

8. The sponge city reservoir water storage heat exchange device of claim 1, wherein,

the connecting piece comprises an embedded joint, a first elbow and a second elbow, wherein the embedded joint is a straight joint, the first elbow and the second elbow are both U-shaped elbows, and the length of the main body of the first elbow is smaller than that of the main body of the second elbow;

in the horizontal direction of the device, the heat exchange pipelines in two adjacent water storage heat exchange modules are connected through the embedded joints;

in the vertical direction of the device, the heat exchange pipelines in the two water storage heat exchange modules with the upper ends mutually connected are connected through the first elbow;

the device is in the vertical direction, and the lower extreme interconnect's two in the retaining heat transfer module the heat transfer pipeline passes through the second elbow connection.

9. The sponge city reservoir water storage heat exchange device of claim 1, wherein,

the water storage heat exchange module is made of pp materials.

10. The sponge city reservoir water storage heat exchange device of claim 1, wherein,

the device also comprises a bottom plate and a protective plate protective layer, wherein the body is arranged on the bottom plate, the bottom plate is formed by pouring concrete, and the periphery of the body is wrapped by a geomembrane and an impermeable membrane;

the protection board protective layer covers the upper portion of the body, and the protection board protective layer is made of XPS extruded sheets.