CN217764607U - Columnar energy storage cavity device with low-thermal-resistance heat conduction supporting structure - Google Patents

Abstract

The utility model discloses a column energy storage cavity device with low thermal resistance heat conduction bearing structure, belong to the energy storage cavity field, it is whole including the energy storage, the set casing is including the surface body that generates heat and seting up at the inside energy storage chamber of the surface body that generates heat, the inside welding in energy storage chamber has column heat conduction muscle, connect column heat conduction muscle through the welded mode and realize supporting the additional strengthening in two faces in energy storage chamber, the holistic intensity of energy storage has been improved, utilize the column heat conduction muscle to absorb the heat of the surface body that generates heat, thereby dispel the heat through the louvre, the dust screen of setting inside at the louvre will avoid the dust to get into the inside in energy storage chamber, the inside of the little one side of louvre opening towards the energy storage chamber, the big one side of louvre opening is towards the outside of device, wind gets into from the big one end of louvre opening, arrange the inside in energy storage chamber by less mouth, the flow of wind accelerates, the inside to the energy storage chamber is dispelled the heat to the convenience.

Description

Columnar energy storage cavity device with low-thermal-resistance heat conduction supporting structure

Technical Field

The utility model relates to an energy storage cavity, more specifically the utility model relates to a column energy storage cavity device with low thermal resistance heat conduction bearing structure that says so.

Background

Heat exchangers (also known as heat exchangers or heat exchange devices) are devices used to transfer heat from a hot fluid to a cold fluid to meet specified process requirements, and are an industrial application of convective and conductive heat transfer. Heat exchangers can be classified in different ways. The operation process can be divided into three categories of dividing wall type, mixed type and heat accumulating type (or called regenerative type); the compact type heat exchanger can be divided into a compact type and a non-compact type according to the compact degree of the surface, and a copper pipe and an aluminum fin are arranged in an energy storage cavity in the heat exchanger.

The inside heat conduction rib strip or the embedded heat conduction fin sheet structure that sets up of current energy storage chamber, the heat diffuses to the energy storage intracavity through the heat conduction rib, and intracavity energy storage material is cut apart into a plurality of units, is unfavorable for the inflation and the shrink of material, and traditional heat conduction structure is great at the thermal-conductive thermal resistance of Z axle direction, is unfavorable for the heat to the thermal diffusion of energy storage structure.

SUMMERY OF THE UTILITY MODEL

The utility model aims to overcome among the prior art energy storage intracavity portion set up heat conduction rib strip or embedded heat conduction fin sheet structure, and the heat diffuses to the energy storage intracavity through the heat conduction rib, and intracavity energy storage material is cut apart into a plurality of units, is unfavorable for the inflation and the shrink of material, provides a column energy storage cavity device with low thermal resistance heat conduction bearing structure to not enough more than solving, facilitate the use.

In order to achieve the above purpose, the utility model provides a technical scheme does:

the utility model discloses a columnar energy storage cavity device with a low-thermal resistance heat conduction supporting structure, which comprises an energy storage whole body, wherein the energy storage whole body comprises a fixed shell and a shell cover arranged on the outer surface of the fixed shell, both sides of the shell cover are provided with alignment holes, and the outer surface of the shell cover is provided with a handle bar;

the fixed shell comprises a heating surface body and an energy storage cavity arranged inside the heating surface body, and the inside of the energy storage cavity is welded with columnar heat conducting ribs.

Preferably, both ends of the columnar heat conduction rib are welded with the inner wall of the energy storage cavity, and heat dissipation holes are formed in the side ends of the columnar heat conduction rib.

Preferably, the louvre is funnel-shaped, and the inside in energy storage chamber is faced to the one side that the louvre opening is little, and the outside of device is faced to the one side that the louvre opening is big, and the internally mounted of louvre has the dust screen.

Preferably, the outer surface of the heating surface body is provided with a mounting opening, the size of the mounting opening is matched with the shell cover, the lower end inside the mounting opening is provided with a connecting bent bar, and the middle end of the connecting bent bar is provided with a threaded hole.

Preferably, a side groove is formed in the body of the shell cover, and a bent heat insulation plate is movably arranged in the side groove.

Preferably, the side end of the bending and moving heat-insulating plate is connected with the inner wall of the side groove through a connecting spring, and one side of the bending and moving heat-insulating plate is in direct contact with the mounting opening of the heat-generating surface body.

Preferably, the bottom end of the shell cover is provided with an adhesion layer, and the bottom end of the adhesion layer is provided with a heat insulation layer.

Preferably, the positions of the alignment holes formed in the two ends of the shell cover are consistent with the positions of the threaded holes, and the lower end of the fixing bolt is connected to the inner portion of the threaded hole in a threaded mode.

Adopt the technical scheme provided by the utility model, compare with prior art, have following beneficial effect:

compared with the prior art, the beneficial effects of the utility model are as follows:

(1) The utility model discloses a column energy storage cavity device with low thermal resistance heat conduction bearing structure, connect column heat conduction muscle on two faces in energy storage chamber through the mode of welding and realize supporting the additional action, the holistic intensity of energy storage has been improved, utilize column heat conduction muscle to absorb the heat of the body of generating heat, thereby dispel the heat through the louvre, the dust screen that sets up inside the louvre will avoid the dust to get into the inside in energy storage chamber, the one side that the louvre opening is little is towards the inside in energy storage chamber, the one side that the louvre opening is big is towards the outside of device, wind gets into from the one end that the louvre opening is big, arrange into the inside in energy storage chamber by less mouth, accelerate the flow of wind, conveniently dispel the heat to the inside in energy storage chamber;

(2) The utility model discloses a column energy storage cavity device with low thermal resistance heat conduction bearing structure, rotate fixing bolt, make fixing bolt's lower extreme rotate from the inside of screw hole, the handle strip, can dismantle the cap from the installing port department of set casing, the convenience is maintained column heat conduction muscle, the extrusion is bent and is moved the inside removal of heat insulating board to the kerve, coupling spring contracts, the cap is laid in installing port department this moment, the linking curved bar supports the shell lid, coupling spring utilizes the restoring force of self to move the inside that the heat insulating board extruded the kerve with the bending, the bending moves the inner wall of heat insulating board and installing port and contacts, reverse rotation fixing bolt, make fixing bolt's lower extreme threaded connection in the inside of screw hole, the completion is to the installation of shell lid, the insulating layer that sets up and the bending heat insulating board will be isolated to the heat that column heat conduction muscle gived off, when avoiding dismantling the cap, the handle strip is scalded.

Drawings

FIG. 1 is an overall structure diagram of the present invention;

fig. 2 is an internal structure diagram of the energy storage cavity of the present invention;

fig. 3 is an enlarged view of a point a in fig. 2 according to the present invention;

fig. 4 is a structure view of the housing cover of the present invention.

In the figure: 1. energy storage is integral; 2. a stationary housing; 21. a heat-generating surface body; 22. an energy storage cavity; 23. columnar heat conducting ribs; 24. connecting the bent strips; 25. a threaded hole; 26. heat dissipation holes; 27. a dust screen; 3. a shell cover; 31. a side groove; 32. bending and moving the heat insulation plate; 33. a connecting spring; 34. an adhesion layer; 35. a thermal insulation layer; 4. aligning the holes; 5. fixing the bolt; 6. a handle bar.

Detailed Description

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

For a further understanding of the present invention, reference is made to the following detailed description taken in conjunction with the accompanying drawings.

With reference to fig. 1 and 3, a columnar energy storage cavity device with a low thermal resistance heat conduction supporting structure comprises an energy storage body 1, wherein the energy storage body 1 comprises a fixed shell 2 and a shell cover 3 arranged on the outer surface of the fixed shell 2, alignment holes 4 are formed in two sides of the shell cover 3, and a handle bar 6 is mounted on the outer surface of the shell cover 3.

The present invention will be further described with reference to the following examples.

The first embodiment is as follows:

with reference to fig. 2 and 3, the fixing case 2 includes a heat-generating surface body 21 and an energy storage cavity 22 formed inside the heat-generating surface body 21, and a columnar heat-conducting rib 23 is welded inside the energy storage cavity 22.

Both ends of the columnar heat conduction rib 23 are welded with the inner wall of the energy storage cavity 22, a heat dissipation hole 26 is formed in the side end of the columnar heat conduction rib 23, and the welding of the columnar heat conduction rib 23 supports the fixing shell 2.

The heat dissipation hole 26 is funnel-shaped, the small side of the opening of the heat dissipation hole 26 faces the inside of the energy storage cavity 22, the large side of the opening of the heat dissipation hole 26 faces the outside of the device, and a dust screen 27 is mounted inside the heat dissipation hole 26.

The outer surface of the heating surface body 21 is provided with a mounting opening, the size of the mounting opening is matched with the shell cover 3, the lower end inside the mounting opening is provided with a connecting bent strip 24, and the middle end of the connecting bent strip 24 is provided with a threaded hole 25.

In this embodiment: connect columnar heat conduction muscle 23 in two faces of energy storage chamber 22 through the welded mode and realize supporting the additional strengthening, the whole 1 intensity of energy storage has been improved, utilize columnar heat conduction muscle 23 to absorb the heat of the face body 21 that generates heat, thereby dispel the heat through louvre 26, the dust screen 27 that sets up at louvre 26 inside will avoid the dust to get into the inside of energy storage chamber 22, one side that louvre 26 opening is little is towards the inside of energy storage chamber 22, one side that louvre 26 opening is big is towards the outside of device, wind gets into from the big one end of louvre 26 opening, arrange the inside of energy storage chamber 22 into by less mouthful, the flow of wind with higher speed, conveniently dispel the heat to the inside of energy storage chamber 22.

Example two:

referring to fig. 4, a side groove 31 is formed in the body of the housing cover 3, and a bending heat insulation plate 32 is movably disposed in the side groove 31.

The side end of the bent and moved heat insulation plate 32 is connected with the inner wall of the side groove 31 by a connection spring 33, and one side of the bent and moved heat insulation plate 32 is in direct contact with the mounting opening of the heat generating body 21.

The bottom end of the shell cover 3 is provided with an adhesion layer 34, and the bottom end of the adhesion layer 34 is provided with a heat insulation layer 35.

The positions of the two ends of the shell cover 3, which are provided with the aligning holes 4, are consistent with the positions of the threaded holes 25, and the lower ends of the fixing bolts 5 are in threaded connection with the inner parts of the threaded holes 25.

In this embodiment: rotate fixing bolt 5, make fixing bolt 5's lower extreme rotate from the inside of screw hole 25, handle strip 6, can dismantle cap 3 from the installing port department of set casing 2, it is convenient to maintain column heat conduction muscle 23, the inside removal of heat insulating board 32 to side channel 31 is moved in the extrusion bending, coupling spring 33 contracts, cap 3 lays in installing port department this moment, link up bending 24 and support cap 3, coupling spring 33 utilizes the restoring force of self to move the inside that heat insulating board 32 extrudes side channel 31 in the bending, the inner wall of bending heat insulating board 32 and installing port contacts, reverse rotation fixing bolt 5, make fixing bolt 5's lower extreme threaded connection in the inside of screw hole 25, the completion is to the installation of cap 3, the heat that the heat insulating layer 35 and the bending heat insulating board 32 that set up will distribute to column heat conduction muscle is isolated, when avoiding dismantling cap 3, handle strip 6 is scalded.

In summary, the following steps: the utility model relates to a columnar energy storage cavity device with low thermal resistance heat conduction supporting structure, which connects a columnar heat conduction rib 23 on two surfaces of an energy storage cavity 22 by welding to realize the supporting and reinforcing effect, thereby improving the strength of the energy storage whole body 1, absorbing the heat of a heating surface body 21 by utilizing the columnar heat conduction rib 23, thereby dissipating the heat through a heat dissipation hole 26, preventing dust from entering the interior of the energy storage cavity 22 by a dust screen 27 arranged in the interior of the heat dissipation hole 26, leading one side with small opening of the heat dissipation hole 26 to face the interior of the energy storage cavity 22 and leading one side with large opening of the heat dissipation hole 26 to face the exterior of the device, leading the wind to enter from one end with large opening of the heat dissipation hole 26, discharging the wind into the interior of the energy storage cavity 22 from a smaller port, accelerating the wind flow, facilitating the heat dissipation on the interior of the energy storage cavity 22, rotating a fixing bolt 5, make fixing bolt 5's lower extreme rotate away from the inside of screw hole 25, handle strip 6, can dismantle cap 3 from the installing port department of set casing 2, the convenience is maintained column heat conduction muscle 23, squeeze the inside removal of curved heat insulating board 32 to side channel 31, coupling spring 33 contracts, cap 3 lays in installing port department this moment, it supports cap 3 to link up the strip 24, coupling spring 33 utilizes the restoring force of self to push away the inside of heat insulating board 32 extrusion side channel 31, curved heat insulating board 32 contacts with the inner wall of installing port, reverse rotation fixing bolt 5, make fixing bolt 5's lower extreme threaded connection in the inside of screw hole 25, accomplish the installation to cap 3, the insulating layer 35 and the curved heat insulating board 32 that move that set up will isolate the heat that column heat conduction muscle 23 gived off, when avoiding dismantling cap 3, handle strip 6 is scalded.

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.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that various changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (8)

1. The utility model provides a column energy storage cavity device with low thermal resistance heat conduction bearing structure, includes that the energy storage is whole (1), its characterized in that: the energy storage whole body (1) comprises a fixed shell (2) and a shell cover (3) arranged on the outer surface of the fixed shell (2), wherein alignment holes (4) are formed in two sides of the shell cover (3), and a handle bar (6) is arranged on the outer surface of the shell cover (3);

the fixed shell (2) comprises a heating surface body (21) and an energy storage cavity (22) arranged inside the heating surface body (21), and the inside of the energy storage cavity (22) is welded with columnar heat conducting ribs (23).

2. The cylindrical energy storage cavity device with the low-thermal-resistance heat-conducting support structure according to claim 1, wherein: two ends of the columnar heat conducting rib (23) are welded with the inner wall of the energy storage cavity (22), and heat dissipation holes (26) are formed in the side end of the columnar heat conducting rib (23).

3. The cylindrical energy storage cavity device with the low-thermal-resistance heat-conducting support structure as claimed in claim 2, wherein: louvre (26) are the funnel shape, and louvre (26) opening one side that is little is towards the inside in energy storage chamber (22), and louvre (26) opening one side that is big is towards the outside of device, and the internally mounted of louvre (26) has dust screen (27).

4. The cylindrical energy storage cavity device with the low-thermal-resistance heat-conducting support structure according to claim 1, wherein: the outer surface of the heating surface body (21) is provided with a mounting opening, the size of the mounting opening is matched with the shell cover (3), the lower end of the interior of the mounting opening is provided with a connecting bent strip (24), and the middle end of the connecting bent strip (24) is provided with a threaded hole (25).

5. The cylindrical energy storage cavity device with the low-thermal-resistance heat-conducting support structure as claimed in claim 4, wherein: a side groove (31) is formed in the body of the shell cover (3), and a bending heat insulation plate (32) is movably arranged in the side groove (31).

6. The cylindrical energy storage cavity device with the low-thermal-resistance heat-conducting support structure as claimed in claim 5, wherein: the side end of the bending heat insulation plate (32) is connected with the inner wall of the side groove (31) through a connecting spring (33), and one side of the bending heat insulation plate (32) is in direct contact with the mounting opening of the heating surface body (21).

7. The cylindrical energy storage cavity device with the low-thermal-resistance heat-conducting support structure as claimed in claim 5, wherein: an adhesion layer (34) is installed at the bottom end of the shell cover (3), and a heat insulation layer (35) is installed at the bottom end of the adhesion layer (34).

8. The cylindrical energy storage cavity device with the low-thermal-resistance heat-conducting support structure as claimed in claim 7, wherein: the positions of the two ends of the shell cover (3) provided with the aligning holes (4) are consistent with the positions of the threaded holes (25), and the lower end of the fixing bolt (5) is connected with the inner part of the threaded hole (25) in a threaded manner.

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