CN220119563U - Heat abstractor of air conditioning unit - Google Patents

Abstract

The utility model discloses a heat dissipation device of an air conditioning unit, which comprises a plurality of communicated heat dissipation mechanisms; the heat dissipation mechanisms comprise a plurality of snake-shaped outer sleeves which are sequentially communicated, a snake-shaped heat dissipation inner pipe is sleeved in the snake-shaped outer sleeves, two ends of the snake-shaped heat dissipation inner pipe penetrate through the snake-shaped outer sleeves, and the snake-shaped heat dissipation inner pipes are communicated through a U-shaped connecting pipe; the serpentine heat dissipation inner tube is sealed with the serpentine outer sleeve through a sealing piece; the air conditioning unit heat dissipation device also comprises a heat dissipation blower which is communicated with the air inlet end of the snakelike outer sleeve; the air outlet end of the snakelike outer sleeve is communicated with a heat energy recovery mechanism, and the heat energy recovery mechanism is used for recovering heat energy of high-temperature gas. The device component realizes environmental protection and temperature reduction of high-temperature gas generated by working equipment in a relatively efficient and energy-saving mode. The mode realizes the separation treatment of the hazardous gas and the cooling gas, and reduces the workload of the subsequent adsorption treatment equipment.

Description

Heat abstractor of air conditioning unit

Technical Field

The utility model belongs to the technical field of air conditioning unit heat dissipation, and particularly relates to a heat dissipation device of an air conditioning unit.

Background

The air conditioning unit comprises an air conditioning host and a pipeline communicated with the air conditioning host, wherein in the working process, the air conditioning host pumps out high-temperature hot air generated by working, the high-temperature hot air is cooled and then is discharged into tail gas treatment equipment at low temperature to be subjected to tail gas treatment, and if the adsorption equipment adsorbs harmful gas in the tail gas, the tail gas is subjected to environment-friendly emission.

At present, high-temperature hot air generated by working equipment can only be pumped into the air after heat exchange with the air by utilizing a conveyed airflow pipeline in the process of conveying the pipeline. However, this mode not only results in a large amount of heat in the high temperature air unable recovery cover, and the pipeline of long-time high temperature heating transport high temperature steam very easily leads to the pipeline temperature too big, can't give off the heat fast, leads to the packing ring of interface between the pipeline ageing serious, and the leakproofness reduces seriously.

More importantly, the mode has low heat dissipation efficiency, the temperature of the tail gas directly discharged into the tail gas adsorption equipment from the pipeline is too high, the tail gas with too high temperature not only easily causes the adsorption efficiency of the tail gas adsorption equipment to be too low, but also greatly reduces the service life of the active carbon and the like of the adsorption equipment. Meanwhile, a large amount of heat energy and harmful high-temperature gas are discharged into the air due to low adsorption efficiency.

Disclosure of Invention

Based on the background, the utility model aims to provide a heat dissipating device of an air conditioning unit.

In order to achieve the above purpose, the utility model adopts the following technical scheme:

a heat dissipating double-fuselage of air conditioning unit, including several communicating heat dissipating double-fuselage;

the heat dissipation mechanisms comprise a plurality of snake-shaped outer sleeves which are sequentially communicated, a snake-shaped heat dissipation inner pipe is sleeved in the snake-shaped outer sleeves, two ends of the snake-shaped heat dissipation inner pipe penetrate through the snake-shaped outer sleeves, and the snake-shaped heat dissipation inner pipes are communicated through a U-shaped connecting pipe;

the serpentine heat dissipation inner tube is sealed with the serpentine outer sleeve through a sealing piece;

the air conditioning unit heat dissipation device further comprises a heat dissipation blower, and the heat dissipation blower is communicated with the air inlet end of the snakelike outer sleeve;

the air outlet end of the snakelike outer sleeve is communicated with a heat energy recovery mechanism, and the heat energy recovery mechanism is used for recovering heat energy of high-temperature gas.

Preferably, the air conditioning unit heat dissipation device comprises two heat dissipation mechanisms which are arranged at left and right intervals;

the heat dissipation mechanism further comprises a rectangular frame seat, and the snakelike outer sleeve is fixedly assembled in the rectangular frame seat.

Preferably, a plurality of transverse frame screws which are arranged at intervals up and down are fixedly connected in the rectangular frame seat, and penetrate through the gaps of the snakelike outer sleeve;

the front end and the rear end of the transverse frame screw rod are respectively in threaded connection with positioning nuts, and annular pressing flanges which are pressed on the snakelike outer sleeve are integrally formed on the positioning nuts.

Preferably, the outer communicating pipe is communicated with the serpentine outer sleeve at an upper-lower interval, and two ends of the outer communicating pipe are respectively communicated with the air outlet end of the serpentine outer sleeve on one side and the air inlet end of the serpentine outer sleeve on the other side.

Preferably, the heat dissipation mechanisms at the left side and the right side are communicated through a horizontal through pipe;

two ends of the horizontal through pipe are respectively communicated with the air inlet end of the snakelike outer sleeve on one side and the air inlet end of the snakelike outer sleeve on the other side;

the heat dissipation air blower is communicated with the horizontal through pipe, and valves for controlling air intake to the snakelike outer sleeve are respectively assembled and connected at two ends of the horizontal through pipe.

Preferably, one end of the U-shaped connecting tube is communicated with the air outlet end of the serpentine heat dissipation inner tube at one side part, and the other end of the U-shaped connecting tube is communicated with the air inlet end of the serpentine heat dissipation inner tube at the other side part.

Preferably, the U-shaped connecting tube comprises a U-shaped bending part, two ends of the U-shaped bending part are integrally formed with horizontal penetrating parts, and the horizontal penetrating parts penetrate through and are positioned in the snake-shaped outer sleeve;

the horizontal through part is connected with a sealing piece through threads.

Preferably, the sealing element comprises an annular sealing plate, and an annular sealing plug is integrally formed on the inner side wall of the annular sealing plate;

the annular sealing plug is in threaded connection with the penetrating part of the snakelike outer sleeve and the snakelike heat dissipation inner tube.

Preferably, the heat energy recovery mechanism comprises air guide plates arranged at intervals on two sides, the inner air guide plate is communicated with the air outlet end of the snakelike outer sleeve, a plurality of arched radiating pipes are communicated between the air guide plates, and a plurality of radiating fins are fixedly connected to the arched radiating pipes;

a heat dissipation outer bobbin is fixedly connected between the air guide plates, and the heat dissipation outer bobbin is welded on the air guide plates in a sealing way;

the cooling outer bobbin is respectively communicated with a cold water inlet pipe and a hot water outlet pipe, and valves are respectively assembled and connected on the cold water inlet pipe and the hot water outlet pipe.

Preferably, annular flanges are fixedly connected to the side walls of the air guide plates, which face each other, respectively, and the heat dissipation outer bobbin is fixedly connected to the annular flanges.

The utility model has the following beneficial effects:

1. in the working process, the air inlet end of the snakelike heat dissipation inner pipe which is communicated in series is connected to the high-temperature exhaust hole of the working equipment. The high-temperature exhaust gas is discharged from the exhaust end from the three snakelike heat dissipation inner pipes sequentially along the snakelike running position.

In the process, the heat dissipation blower is turned on, the cooling air flow is pumped into the snakelike outer sleeve pipes which are sequentially connected in series by the heat dissipation blower, flowing air flow is generated in the snakelike outer sleeve pipes, at the moment, heat exchange is carried out between the snakelike heat dissipation inner pipes located in the snakelike outer sleeve pipes and the cold air flow, and due to the fact that snakelike running distribution is adopted, a path for increasing high-temperature air is achieved, and then the heat dissipation path is improved.

2. The cold air flow and the high-temperature air flow generated by the equipment are separated, the equipment air flow is subjected to subsequent environmental protection treatment, the cooling air flow is directly discharged through subsequent heat energy recovery, the hazard gas and the cooling air are separated, and the workload of subsequent adsorption treatment equipment is reduced.

3. During the working process, cold water is pumped from the cold water inlet pipe, then the cold water is pumped into the heat dissipation outer bobbin, the cold water is soaked in the arched heat dissipation pipe-heat dissipation fin structure, and then the heated cold water is discharged from the hot water outlet pipe. The heated hot water can be used for production and living, and further the recovery of heat energy is realized.

Drawings

In order to more clearly illustrate the embodiments of the utility model or the technical solutions in the prior art, the drawings that are required in the embodiments or the description of the prior art will be briefly described, it being obvious that the drawings in the following description are only some embodiments of the utility model, and that other drawings may be obtained from the structures shown in these drawings without inventive effort for a person skilled in the art.

FIG. 1 is a schematic diagram of the overall structure of an embodiment of the present utility model;

FIG. 2 is a schematic view of a seal in accordance with an embodiment of the present utility model;

FIG. 3 is a schematic view of a heat recovery mechanism according to an embodiment of the present utility model;

FIG. 4 is a schematic view of a structure of an arcuate radiating pipe and radiating fins according to an embodiment of the present utility model;

FIG. 5 is a schematic view of an arcuate radiating pipe according to an embodiment of the present utility model;

fig. 6 is a schematic structural diagram of the embodiment of the present utility model in another view of fig. 1.

The achievement of the objects, functional features and advantages of the present utility model will be further described with reference to the accompanying drawings, in conjunction with the embodiments.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and fully with reference to the accompanying drawings, in which it is evident that the embodiments described are only some, but not all embodiments of the utility model. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

It should be noted that all directional indicators (such as up, down, left, right, front, and rear … …) in the embodiments of the present utility model are merely used to explain the relative positional relationship, movement, etc. between the components in a particular posture (as shown in the drawings), and if the particular posture is changed, the directional indicator is changed accordingly.

Furthermore, descriptions such as those referred to as "first," "second," and the like, are provided for descriptive purposes only and are not to be construed as indicating or implying a relative importance or implying an order of magnitude of the indicated technical features in the present disclosure. Thus, a feature defining "a first" or "a second" may explicitly or implicitly include at least one such feature. In addition, the technical solutions of the embodiments may be combined with each other, but it is necessary to base that the technical solutions can be realized by those skilled in the art, and when the technical solutions are contradictory or cannot be realized, the combination of the technical solutions should be considered to be absent and not within the scope of protection claimed in the present utility model.

Example 1

As shown in fig. 1-6, a heat dissipating device of an air conditioning unit includes two heat dissipating mechanisms that are disposed at a left-right interval and are communicated.

The specific structure of the heat dissipation mechanism is as follows: the heat dissipation mechanism comprises a plurality of snakelike outer sleeves 2 which are sequentially communicated, and the snakelike outer sleeves 2 are in the shape of a straight pipe portion 21 and a bent pipe portion 22 which is communicated with the straight pipe portion 21. Each heat dissipation mechanism has three serpentine outer sleeves 2 back and forth. Which are communicated in turn, the communication mode is as follows: the outer communicating pipe 3 (the outer communicating pipe 3 is in a U shape) which is arranged at an upper-lower interval is communicated with the serpentine outer sleeve 2 (the straight pipe part 21), and two ends of the outer communicating pipe 3 are respectively communicated with the air outlet end of the serpentine outer sleeve 2 on one side and the air inlet end of the serpentine outer sleeve 2 on the other side. I.e. all the serpentine outer sleeves 2 are connected in series by the outer connecting tube 3.

Each of the above-mentioned serpentine outer sleeves 2 is internally sleeved with a serpentine heat dissipation inner tube 4 (the serpentine heat dissipation inner tube 4 is made of red copper, the shape of the serpentine heat dissipation inner tube is adapted to the serpentine outer sleeve 2, and the serpentine heat dissipation inner tube 4 sleeved in each of the serpentine outer sleeves 2 penetrates through the serpentine outer sleeve 2). The snake-shaped heat dissipation inner pipes 4 penetrating through the snake-shaped outer sleeve 2 are communicated through U-shaped connecting pipes. I.e. all the serpentine heat-dissipating inner tubes 4 are connected by means of the U-shaped connecting tube 41. Specifically, one end of the U-shaped connecting tube 41 is connected to the air outlet end of the serpentine heat dissipation inner tube 4 at one side, and the other end of the U-shaped connecting tube 41 is connected to the air inlet end of the serpentine heat dissipation inner tube 4 at the other side.

The shape of the U-shaped connecting tube 41 is: the U-shaped connecting tube 41 comprises a U-shaped bending part, wherein two ends of the U-shaped bending part are integrally formed with horizontal penetrating parts, and the horizontal penetrating parts penetrate through and are positioned in the snakelike outer sleeve 2.

Meanwhile, in order to maintain the seal between the serpentine heat dissipation inner tube 4 and the serpentine outer tube 2 at the penetration position, the serpentine heat dissipation inner tube 4 and the serpentine outer tube 2 are sealed by a sealing member.

Specifically, the sealing member includes annular sealing plate 8 (set up the screw thread through-hole on the annular sealing plate 8), integrated into one piece has annular sealing plug 81 on the inside wall of annular sealing plate 8 (set up the screw thread through-hole on the annular sealing plug 81). An annular seal plug 81 that rotates the seal to the seal plugs into the lumen void between the serpentine heat sink inner tube 4 and the serpentine outer tube 2. Correspondingly, a threaded through hole structure is formed in the horizontal penetrating part of the U-shaped connecting tube 41, and an internal thread structure is formed at the pipe orifice position of the snakelike outer sleeve 2.

The annular sealing plug 81 is rotated to be in threaded connection with the pipe orifice parts of the snakelike outer sleeve 2 and the snakelike heat dissipation inner pipe 4.

The air outlet end of the serially connected snake-shaped heat dissipation inner tube 4 penetrates through the lower end pipe orifice of the snake-shaped outer sleeve 2 from the front side part, and the penetrating position is also sealed by the sealing piece with the structure.

Similarly, the air inlet end of the serially connected snake-shaped heat dissipation inner tube 4 penetrates through the upper end pipe orifice of the snake-shaped outer sleeve 2 at the rear side part, and the penetrating position is also sealed by the sealing piece with the structure.

The left and right heat dissipation mechanisms are communicated through a horizontal through pipe 5; the communication position is between the two snakelike outer sleeves 2 at the rear side, and the concrete mode is as follows: two ends of the horizontal through pipe 5 are respectively communicated with the air inlet end of the snakelike outer sleeve 2 on one side and the air inlet end of the snakelike outer sleeve 2 on the other side.

The heat dissipation blower 6 is communicated with the horizontal through pipe 5 (the horizontal through pipe 5 is communicated with a heat dissipation blower 6), and valves for controlling air intake to the snakelike outer sleeve 2 are respectively assembled and connected at two ends of the horizontal through pipe 5.

In the working process, the air inlet end of the snakelike heat dissipation inner pipe 4 which is communicated in series is connected to the high-temperature exhaust hole of the working equipment. The high-temperature exhaust gas is discharged from the exhaust end from the three serpentine heat dissipation inner pipes 4 sequentially along the serpentine position.

In the process, the heat dissipation blower 6 is turned on, the heat dissipation blower 6 pumps cooling air flow into the serpentine outer sleeve 2 which is sequentially connected in series, and flowing air flow is generated in the serpentine outer sleeve 2, at the moment, the serpentine heat dissipation inner tube 4 positioned in the serpentine outer sleeve 2 exchanges heat with the cooling air flow, and due to the adoption of serpentine running distribution, a path for increasing high-temperature air is realized, and then a heat dissipation path is improved.

Meanwhile, the separation of the cold air flow and the high-temperature air flow generated by the equipment is realized, the subsequent environmental protection treatment of the equipment air flow is realized, the cooling air flow is directly discharged through the subsequent heat recovery, the separation treatment of the harmful gas and the cooling air is realized, and the workload of the subsequent adsorption treatment equipment is reduced (the air outlet end of the serpentine heat dissipation inner pipe 4 is communicated with the subsequent tail gas adsorption equipment).

Example 2

As shown in fig. 1 to 6, in this embodiment, based on the structure of embodiment 1, in order to realize heat energy recovery for cooling the cooling air flow, the air outlet end of the serpentine outer sleeve 2 is connected with a heat energy recovery mechanism, and the heat energy recovery mechanism is used for recovering heat energy of the high-temperature gas.

Specifically, the heat recovery mechanism includes air guide plates 71 (the air guide plates 71 are made of metal and have a plate cavity gap inside) provided at intervals on both sides.

The air guide plate 71 is connected to the air outlet end of the serpentine outer sleeve 2 (i.e. the outer communicating pipe 3 at the position), a plurality of arcuate radiating pipes 73 are connected between the air guide plates 71 (the arcuate radiating pipes 73 are made of red copper, each arcuate part 732 is formed by integrally forming two arcuate parts 732, each arcuate part 732 is integrally formed with a horizontal pipe 731 connected to the air guide plate 71), and a plurality of radiating fins 74 are fixedly connected to the arcuate radiating pipes 73.

The heat dissipation fin 74 is a rectangular fin sheet, and has a through hole in its middle, and is sealed and welded to the arcuate heat dissipation tube 73 after passing through.

In order to realize heat energy recovery, a heat dissipation outer tube is fixedly connected between the air guide plates 71, and the heat dissipation outer tube is welded on the air guide plates 71 in a sealing manner. Specifically, annular flanges 711 are fixedly connected to the side walls of the air guide plate 71 facing each other, respectively, and the heat radiation outer tube is fixedly connected to the annular flanges 711. Meanwhile, the cooling outer bobbin is respectively communicated with a cold water inlet pipe and a hot water outlet pipe, and valves are respectively assembled and connected on the cold water inlet pipe and the hot water outlet pipe.

During operation, cold water is pumped from the cold water inlet pipe, then the cold water is pumped into the heat dissipation outer bobbin, the cold water is soaked in the structure of the arched heat dissipation pipes 73 and the heat dissipation fins 74, and then the heated cold water is discharged from the hot water outlet pipe. The heated hot water can be used for life.

In the above-described structure, since the plurality of arcuate radiating pipes 73 are used, the path of the high-temperature air flow is long, and the heat is dissipated by immersing the cold water in a split-flow manner, so that the heat recovery efficiency is higher.

Example 3

As shown in fig. 1-6, in order to fix the serpentine outer sleeve 2 on the basis of the structure of embodiment 1, each heat dissipation mechanism further includes a rectangular frame 1, and the serpentine outer sleeve 2 is fixedly assembled in the rectangular frame 1. In the conventional manner, T-shaped fitting plates are welded to the front and rear side walls of the rectangular frame base 1, and fastening fitting is performed by fastening screws on the T-shaped fitting plates 11.

The specific method is as follows: a plurality of transverse frame screws which are arranged at intervals up and down are fixedly connected in the rectangular frame seat 1, and penetrate through the gaps of the snakelike outer sleeve 2; the front end and the rear end of the transverse frame screw rod are respectively in threaded connection with a positioning nut, and an annular pressing flange which is pressed on the snakelike outer sleeve 2 is integrally formed on the positioning nut.

In this way, the positioning of all the serpentine outer sleeves 2 between the positioning nuts is achieved.

It should be understood that the above description is not intended to limit the utility model to the particular embodiments disclosed, but to limit the utility model to the particular embodiments disclosed, and that the utility model is not limited to the particular embodiments disclosed, but is intended to cover modifications, adaptations, additions and alternatives falling within the spirit and scope of the utility model.

Claims (10)

1. The heat dissipating device of the air conditioning unit is characterized by comprising a plurality of communicated heat dissipating mechanisms;

the heat dissipation mechanisms comprise a plurality of snake-shaped outer sleeves which are sequentially communicated, a snake-shaped heat dissipation inner pipe is sleeved in the snake-shaped outer sleeves, two ends of the snake-shaped heat dissipation inner pipe penetrate through the snake-shaped outer sleeves, and the snake-shaped heat dissipation inner pipes are communicated through a U-shaped connecting pipe;

the serpentine heat dissipation inner tube is sealed with the serpentine outer sleeve through a sealing piece;

the air conditioning unit heat dissipation device further comprises a heat dissipation blower, and the heat dissipation blower is communicated with the air inlet end of the snakelike outer sleeve;

the air outlet end of the snakelike outer sleeve is communicated with a heat energy recovery mechanism, and the heat energy recovery mechanism is used for recovering heat energy of high-temperature gas.

2. The air conditioning unit heat dissipating device according to claim 1, wherein the air conditioning unit heat dissipating device comprises two heat dissipating mechanisms arranged at a left-right interval;

the heat dissipation mechanism further comprises a rectangular frame seat, and the snakelike outer sleeve is fixedly assembled in the rectangular frame seat.

3. The heat dissipating device of an air conditioning unit according to claim 2, wherein a plurality of transverse frame screws are fixedly connected in the rectangular frame seat and are arranged at intervals up and down, and the transverse frame screws penetrate through the gaps of the snakelike outer sleeve;

the front end and the rear end of the transverse frame screw rod are respectively in threaded connection with positioning nuts, and annular pressing flanges which are pressed on the snakelike outer sleeve are integrally formed on the positioning nuts.

4. The heat dissipating device of air conditioning unit according to claim 1, wherein the outer communicating pipe is arranged on the serpentine outer sleeve at intervals from top to bottom, and two ends of the outer communicating pipe are respectively connected to an air outlet end of the serpentine outer sleeve on one side and an air inlet end of the serpentine outer sleeve on the other side.

5. The heat dissipating device of air conditioning unit according to claim 4, wherein the heat dissipating mechanisms on the left and right sides are communicated through a horizontal pipe;

two ends of the horizontal through pipe are respectively communicated with the air inlet end of the snakelike outer sleeve on one side and the air inlet end of the snakelike outer sleeve on the other side;

the heat dissipation air blower is communicated with the horizontal through pipe, and valves for controlling air intake to the snakelike outer sleeve are respectively assembled and connected at two ends of the horizontal through pipe.

6. The heat dissipating device of claim 1, wherein one end of the U-shaped connecting tube is connected to the air outlet end of the serpentine heat dissipating inner tube at one side, and the other end of the U-shaped connecting tube is connected to the air inlet end of the serpentine heat dissipating inner tube at the other side.

7. The heat dissipating device of an air conditioning unit according to claim 6, wherein the U-shaped connecting tube comprises a U-shaped bending part, two ends of the U-shaped bending part are integrally formed with a horizontal penetrating part, and the horizontal penetrating part penetrates and is positioned in the serpentine outer sleeve;

the horizontal through part is connected with a sealing piece through threads.

8. The heat dissipating device of an air conditioning unit according to claim 7, wherein the sealing member comprises an annular sealing plate, and an annular sealing plug is integrally formed on an inner side wall of the annular sealing plate;

the annular sealing plug is in threaded connection with the penetrating part of the snakelike outer sleeve and the snakelike heat dissipation inner tube.

9. The heat dissipating device of the air conditioning unit according to claim 1, wherein the heat energy recovery mechanism comprises air guide plates arranged at intervals on two sides, the inner air guide plates are communicated with the air outlet end of the snakelike outer sleeve, a plurality of arched heat dissipating pipes are communicated between the air guide plates, and a plurality of heat dissipating fins are fixedly connected to the arched heat dissipating pipes;

a heat dissipation outer bobbin is fixedly connected between the air guide plates, and the heat dissipation outer bobbin is welded on the air guide plates in a sealing way;

the cooling outer bobbin is respectively communicated with a cold water inlet pipe and a hot water outlet pipe, and valves are respectively assembled and connected on the cold water inlet pipe and the hot water outlet pipe.

10. The heat dissipating device of claim 9, wherein the side walls of the air guide plate facing each other are respectively and fixedly connected with annular flanges, and the heat dissipating outer tube is fixedly connected to the annular flanges.