CN221055141U - A compressor heat abstractor and air conditioner for air conditioner - Google Patents
A compressor heat abstractor and air conditioner for air conditioner Download PDFInfo
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- CN221055141U CN221055141U CN202322358057.6U CN202322358057U CN221055141U CN 221055141 U CN221055141 U CN 221055141U CN 202322358057 U CN202322358057 U CN 202322358057U CN 221055141 U CN221055141 U CN 221055141U
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Abstract
The utility model provides a compressor heat dissipation device for an air conditioner and the air conditioner. A compressor heat sink for an air conditioner, comprising: the heat exchange structure is used for radiating heat for the compressor; one end of the telescopic structure is connected with the heat exchange structure, and the other end of the telescopic structure is fixed on an outer machine bottom plate of the air conditioner; the telescopic structure is used for supporting the heat exchange structure and adjusting the distance between the heat exchange structure and the compressor through telescopic adjustment. Through set up extending structure in heat exchange structure's bottom, can adjust heat exchange structure and compressor's distance according to the difference of compressor size, this compressor heat abstractor's simple structure, dismantlement and simple to operate can adapt to not unidimensional compressor.
Description
Technical Field
The utility model relates to the technical field of compressor heat dissipation, in particular to a compressor heat dissipation device for an air conditioner and the air conditioner.
Background
The compressor in the air conditioner off-premises station can produce a large amount of heat when running, still can wrap up the one deck soundproof cotton for the compressor in general in order to fall the noise, and the compressor of this moment can gather a large amount of heat and can't distribute, if in summer, the compressor temperature can be higher, and this not only causes the influence to performance, the operating life of compressor, can also make the temperature rise suddenly in the outer machine cavity, causes the destruction to the electronic components on the automatically controlled box, and then influences the refrigerating system of air conditioner.
In the prior art, compressors of different sizes are also designed with different heat sinks, so that the manufacturing cost is increased. Therefore, providing a heat dissipating device that can adapt to compressors of different sizes is a technical problem that needs to be solved at present.
Disclosure of utility model
The utility model aims to provide a compressor heat radiator for an air conditioner, which has a simple structure, is convenient to detach and install, and can adapt to compressors with different sizes.
In order to solve the above problems, the present utility model provides a compressor heat sink for an air conditioner, comprising: the heat exchange structure is used for radiating heat for the compressor; one end of the telescopic structure is connected with the heat exchange structure, and the other end of the telescopic structure is fixed on an outer machine bottom plate of the air conditioner; the telescopic structure is used for supporting the heat exchange structure and adjusting the distance between the heat exchange structure and the compressor through telescopic adjustment.
The utility model can ensure the absorption of heat generated by the compressor by installing the heat exchange structure near the bottom of the compressor. Because the sizes of the compressors of different air conditioner models are different, the situation that the distance between the heat exchange structure and the bottom of the compressor is too large or too small occurs when the heat radiator is fixed in the outdoor unit, and the heat exchange structure cannot be close to the bottom of the compressor due to the too large distance, so that the heat radiation effect is greatly reduced, and the heat radiator cannot be normally installed due to the too small distance, so that a telescopic structure is required to be arranged on the heat radiator; the telescopic structure can adjust the distance between the heat exchange structure and the compressor when providing support for the heat exchange structure, and then improves the heat dissipation effect for the compressor, so that the problem that an air conditioner external unit is difficult to work normally under a high temperature condition is avoided, the temperature of the compressor is effectively reduced, the compressor and other parts are well protected, and the air conditioner performance is improved.
In any of the above technical solutions, a heat exchange cavity is provided in the heat exchange structure; the telescopic structure comprises a water inlet pipe which is communicated with the heat exchange cavity and used for supplying water to the heat exchange cavity.
The heat exchange structure is provided with a heat exchange cavity, so that condensed water can be prevented from directly contacting the bottom of the compressor while heat exchange is fully performed, and the situations of dampness, dirty blockage and corrosion of the compressor are avoided. Through the inner space communication of water inlet pipe and heat exchange cavity for the liquid is led to the heat exchange cavity from the water inlet pipe and is carried out the heat exchange, thereby reaches the purpose of cooling for heat exchange structure.
In any of the above technical schemes, the heat exchange structure is also provided with a water outlet communicated with the heat exchange cavity, and one end of the water inlet pipe far away from the heat exchange cavity is communicated with a condensed water discharge pipeline of the air conditioner.
The condensate water is introduced into the heat exchange cavity by communicating the water inlet pipe with the condensate water discharge pipeline of the indoor unit, so that the condensate water has larger cold energy and can quickly exchange heat with the cavity wall of the heat exchange cavity, the utilization rate of the condensate water discharged by the indoor unit is effectively improved, and the energy-saving and environment-friendly effects are realized; and the communication mode of the compressor heat abstractor and the condensed water discharge pipeline is simple, the installation is convenient, and the manufacturing cost is low.
In any of the above technical schemes, the heat exchange structure is disc-shaped, the inner wall of the heat exchange cavity forms a dent, and the dent is used for accommodating the bottom of the compressor.
The compressor is generally cylindrical, and in order to reduce production cost, facilitate installation and improve heat dissipation efficiency, the heat exchange structure is designed to be disc-shaped and corresponds to the bottom of the compressor. The inner wall in heat exchange cavity forms the sunken for the compressor can imbed or install into in the sunken, under this structure, can guarantee that heat exchange structure absorbs more heat of compressor.
In any of the above technical solutions, the telescopic structure further includes a sleeve, and the sleeve is sleeved outside the water inlet pipe to perform relative movement; the sleeve is provided with a sliding groove, the pipe wall of the water inlet pipe is provided with a fixing pin, and the fixing pin stretches into and is clamped in the sliding groove.
Through locating the sleeve cover outside with the income water pipe in order to carry out relative movement, can adjust the distance of heat exchange structure and compressor bottom, and then guarantee the radiating effect. Through setting up the sliding groove on the sleeve, set up the fixed pin on the water inlet pipe, the sleeve cover is located the water inlet pipe outside in order to guarantee that the fixed pin inlays in the sliding groove for the fixed pin removes in the sliding groove, thereby makes the water inlet pipe reciprocate in the sleeve.
In any of the above technical solutions, the sliding groove is spirally arranged around the periphery of the outer wall of the sleeve from top to bottom; the fixed pin walks along the sliding groove to lift.
The sliding groove is spirally wound on the sleeve, and the fixed pin cannot move by itself under the condition of no external power due to the blocking of the sliding groove, so that the fixed pin can be moved to a certain position on the sliding groove only by rotating the water inlet pipe, and the sliding groove also plays a certain role in fixing. The heat exchange structure is horizontally rotated to drive the water inlet pipe to rotate, and the fixing pin moves up and down along the sliding groove so as to enable the heat exchange structure to be close to or far away from the bottom of the compressor. The spiral sliding groove can realize the distance required by the up-and-down movement of the heat exchange structure under the shorter sleeve, and can be randomly moved to any position within a limited range, and the optional range of the movement distance is larger.
In any of the above technical schemes, the end of the sleeve is provided with a base, the base is provided with screw holes, and the sleeve is connected with the bottom plate of the external machine through screws penetrating the screw holes.
The bottom end of the sleeve is provided with the base, the base is provided with screw holes, the base and the screws are matched and detachably arranged on the bottom plate of the external machine, and the sleeve is connected with the heat exchange structure, so that the installation stability of the heat exchange structure is ensured; the design of base makes telescopic dismantlement more convenient, and then guarantees the convenience that heat transfer structure dismantled. Therefore, the base can achieve the purposes of convenient disassembly and installation, and further the heat exchange cavity is convenient to clean regularly.
In any of the above technical solutions, the heat exchange structure is made of metal.
The metal is used as the material of the heat exchange structure, so that the heat of the compressor can be well absorbed, and the purpose of radiating the heat of the compressor is achieved. The metal material adopted by the heat exchange structure has the characteristics of low cost, easy manufacture, easy material acquisition, high strength and the like, and particularly, the metal has better heat conduction performance.
In any of the above technical solutions, the heat exchange structure is connected with the compressor; and/or the air conditioner comprises a bracket for supporting the compressor, and the heat exchange structure is connected with the bracket.
The heat exchange structure is arranged on the bottom plate of the external machine, and is supported through the telescopic structure, but the long-term stability of the support is limited, and particularly after the heat exchange cavity is filled with condensed water, the telescopic structure is more difficult to support the weight of the heat exchange structure. Therefore, the heat exchange structure is selectively connected with the bottom of the compressor or the bracket for supporting the compressor, so that a certain supporting and stabilizing effect can be achieved on the heat exchange structure.
The utility model provides an air conditioner, which comprises: a compressor; the compressor heat sink according to any one of the above aspects, wherein the compressor heat sink is configured to dissipate heat from a compressor. The air conditioner has the beneficial effects of the compressor heat dissipation device according to any one of the above technical schemes, and therefore, the description thereof is omitted herein.
After the technical scheme of the utility model is adopted, the following technical effects can be achieved:
According to the utility model, the heat exchange structure is arranged near the bottom of the compressor, so that the heat generated by the compressor can be absorbed, and the heat dissipation device is fixed in the outdoor unit under the condition that the distance between the heat exchange structure and the bottom of the compressor is too large or too small due to the different sizes of the compressors, so that the telescopic structure is arranged on the heat dissipation device, and can adjust the distance between the heat exchange structure and the compressor while providing support for the heat exchange structure, thereby effectively reducing the temperature of the compressor and well protecting the compressor and other parts, and further improving the air conditioning performance.
Drawings
Fig. 1 is a schematic structural diagram of a heat dissipating device of a compressor according to an embodiment of the present utility model;
FIG. 2 is a top view of the heat sink of the compressor of FIG. 1;
fig. 3 is a cross-sectional view of the heat sink of the compressor of fig. 1.
Reference numerals illustrate:
100-compressor heat sink; 110-a heat exchange structure; 111-a heat exchange cavity; 112-water outlet; 113-inner wall; 120-telescoping structure; 121-a water inlet pipe; 122-sleeve; 123-a sliding groove; 124-fixing pins; 125-base.
Detailed Description
In order that the above objects, features and advantages of the utility model will be readily understood, a more particular description of the utility model will be rendered by reference to specific embodiments thereof which are illustrated in the appended drawings.
Embodiments of the present utility model will be further described with reference to fig. 1 to 3.
An embodiment of the present utility model provides a compressor heat sink 100 for an air conditioner, including: the heat exchange structure 110, the heat exchange structure 110 is used for dissipating heat for the compressor; the telescopic structure 120, one end of the telescopic structure 120 is connected with the heat exchange structure 110, and the other end is fixed on an external machine bottom plate of the air conditioner; the telescopic structure 120 is used for supporting the heat exchange structure 110, and adjusting the distance between the heat exchange structure 110 and the compressor through telescopic operation.
As shown in fig. 1, the present embodiment provides a compressor heat sink 100 for an air conditioner, which can ensure absorption of heat generated by a compressor by installing a heat exchange structure 110 near the bottom of the compressor. Because the sizes of the compressors of different air conditioner models are different, the situation that the distance between the heat exchange structure 110 and the bottom of the compressor is too large or too small occurs when the compressor heat dissipation device 100 is fixed in the outdoor unit, the heat exchange structure 110 cannot approach to the bottom of the compressor due to the too large distance, the heat dissipation effect is greatly reduced, and the compressor heat dissipation device 100 cannot be normally installed due to the too small distance, so that the telescopic structure 120 is required to be arranged on the compressor heat dissipation device 100; the telescopic structure 120 can adjust the distance between the heat exchange structure 110 and the compressor while providing support for the heat exchange structure 110, so as to improve the heat dissipation effect of the compressor, thereby avoiding the problem that the air conditioner external unit is difficult to work normally under the high temperature condition, effectively reducing the temperature of the compressor, well protecting the compressor and other parts, and improving the air conditioning performance.
In some embodiments of the present invention, a heat exchange cavity 111 is provided inside the heat exchange structure 110; the telescopic structure 120 includes a water inlet pipe 121, and the water inlet pipe 121 communicates with the heat exchange chamber 111 for supplying water to the heat exchange chamber 111.
As shown in fig. 3, the heat exchange structure 110 is provided with a heat exchange cavity 111, so that condensed water can be prevented from directly contacting the bottom of the compressor while heat exchange is fully performed, and further, the situations of dampness, dirt blockage and corrosion of the compressor are avoided. Under the condition that liquid is not introduced into the heat exchange cavity 111, the heat exchange structure 110 comprises two layers of materials for absorbing heat, and a certain space is formed between the two layers, so that a certain heat dissipation efficiency is ensured after the heat exchange structure 110 absorbs the heat. For example, the outdoor unit is generally provided with fins, which are mainly used for radiating heat to devices in the outdoor unit, and are generally made of aluminum materials, and the distribution area of the fins is relatively large, so that the heat radiating device 100 of the compressor is ensured to be close to the compressor, and is installed at a position close to the fins to absorb heat of the heat exchange structure 110.
In addition, the heat exchange cavity 111 is communicated with the inner space of the water inlet pipe 121, so that the liquid can be led into the heat exchange cavity 111 from the water inlet pipe 121 to exchange heat, and the purpose of cooling the heat exchange structure 110 is achieved. The liquid is generally a cooling liquid, such as pure water, mineral oil, and fluorinated liquid, and is introduced into the heat exchange cavity 111, then the opening of the water inlet pipe 121 is closed, and after the heat exchange structure 110 absorbs the heat of the compressor, the liquid in the heat exchange cavity 111 can absorb the heat contained in the heat exchange structure 110, so as to achieve the effect of dissipating the heat of the heat exchange structure 110.
In some embodiments of the present application, the heat exchange structure 110 is further provided with a water outlet 112 communicating with the heat exchange cavity 111, and an end of the water inlet pipe 121 away from the heat exchange cavity 111 is communicated with a condensate water discharge pipeline of the air conditioner.
As shown in fig. 3, by communicating the water inlet pipe 121 with the condensed water discharge pipeline of the indoor unit, so that condensed water is introduced into the heat exchange cavity 111, the condensed water has larger cold energy and can quickly exchange heat with the cavity wall of the heat exchange cavity 111, thereby effectively improving the utilization rate of condensed water discharged by the indoor unit and realizing the effects of energy conservation and environmental protection; and the communication mode between the compressor heat sink 100 and the condensed water drain line is simple, the installation is convenient, and the manufacturing cost is low. In addition, the water inlet pipe 121 is arranged at the bottom of the heat exchange structure 110, so that the condensed water exchanges heat from bottom to top, the condensed water is fully guided to all directions of the heat exchange structure 110, the contact area between the condensed water and the heat exchange structure 110 is maximized, the heat absorbed by the heat exchange structure 110 is effectively taken away, and the heat exchange efficiency is improved.
For example, the installation height of the outdoor unit is lower than the installation height of the condensate water discharge pipeline, and under the action of gravity and potential energy difference, the condensate water continuously flows from high water level to low water level until the condensate water in the heat exchange cavity 111 fills the cavity space from bottom to top, so as to achieve the purpose of cooling the heat exchange structure 110. In addition, a water collecting tank can be arranged near the outdoor unit, condensed water is firstly collected in the water collecting tank, then the condensed water is conveyed to the water inlet pipe 121 along the water pipe through the miniature water pump, the pressure of the water pump ensures that the condensed water flows from the bottom of the compressor heat radiating device 100 to the top, the condensed water fills the whole heat exchange cavity 111, finally reaches the water outlet 112 communicated with the heat exchange cavity 111, and the condensed water absorbing heat is discharged out of the heat exchange cavity 111, so that the circulation of the condensed water in the heat exchange device is realized, and the heat exchange efficiency of the compressor is ensured.
Preferably, the water outlet 112 is arranged at the top end periphery of the outer wall of the heat exchange cavity 111, so that condensed water can be rapidly discharged from the water outlets 112 around, and the cooling capacity of condensed water in the heat exchange cavity 111 is guaranteed in real time. Further, a water receiving tray may be provided at a corresponding position of the device water outlet 112 to be discharged to the outside of the outdoor unit through a water course, or the collected water may be recycled to the water collecting tank to realize reuse of the condensed water. The used condensed water is discharged or collected, so that the internal corrosion of the outdoor unit is avoided, and the service life of the outdoor unit is prolonged.
Preferably, the inner wall 113 of the heat exchange chamber 111 is disposed opposite to the outer wall, i.e., the distance between each of the opposite portions of the inner wall 113 and the outer wall is similar, approximately parallel, and the condensed water heat exchange chamber 111 gradually exchanges heat from bottom to top. It should be noted that the distance between the outer wall and the inner wall 113 is not too large or too small, and if the distance is too large, the outer wall is far away from the compressor, so that heat cannot be absorbed, and the heat dissipation effect of the compressor is reduced; if the distance is too small, the volume of the heat exchange cavity 111 is small, so that the amount of water flowing into the cavity is small, and the heat exchange effect of the condensed water cannot be achieved.
In some embodiments of the present application, the heat exchange structure 110 is disc-shaped, and the inner wall 113 of the heat exchange chamber 111 forms a recess for receiving the bottom of the compressor.
As shown in fig. 2, the compressor is generally cylindrical, and the heat exchanging structure 110 is designed in a disc shape corresponding to the bottom of the compressor for the purpose of reducing production costs, facilitating installation, and improving heat dissipation efficiency. The inner wall 113 of the heat exchange cavity 111 forms a recess such that the compressor can be embedded or mounted in the recess, which may be semi-spherical, conical, cylindrical-like or other irregular structure, in which the compressor is as close as possible to the heat exchange structure 110 such that the heat exchange structure 110 absorbs more heat of the compressor. Preferably, the inner wall 113 of the heat exchange cavity 111 is provided with a recess having a certain radian, such as a semi-spherical structure, to ensure that the radian is matched with the semi-spherical structure of the bottom of the compressor, so that the recess is matched with the bottom of the compressor as much as possible.
In some embodiments of the present application, the telescopic structure 120 further includes a sleeve 122, and the sleeve 122 is sleeved outside the water inlet pipe 121 to perform relative movement; the sleeve 122 is provided with a sliding groove 123, a fixing pin 124 is provided on the pipe wall of the water inlet pipe 121, and the fixing pin 124 extends into and is engaged with the sliding groove 123.
As shown in fig. 3, the sleeve 122 is sleeved outside the water inlet pipe 121 to perform relative movement, so that the distance between the heat exchange structure 110 and the bottom of the compressor can be adjusted, and the heat dissipation effect is further ensured. By arranging the sliding groove 123 on the sleeve 122, the fixing pin 124 is arranged on the water inlet pipe 121, and the sleeve 122 is sleeved outside the water inlet pipe 121 to ensure that the fixing pin 124 is embedded in the sliding groove 123. For example, a straight sliding groove 123 along the axial direction of the sleeve 122 may be designed, and three or more clamping grooves are provided on one side or both sides of the sliding groove 123, when the heat exchange structure 110 needs to be adjusted to move up and down, the water inlet pipe 121 is moved up and down along the sleeve 122, and when the water inlet pipe moves to a desired position, the fixing pin 124 on the water inlet pipe 121 can be clamped into the clamping groove.
It should be noted that, the materials of the sleeve 122 and the water inlet pipe 121 may be rigid structures, so that sufficient supporting effect is ensured when the sliding groove 123 and the fixing pin 124 are mutually embedded, and the water inlet pipe 121 also supports the heat exchange structure 110 when moving. Preferably, the top of the heat exchange structure 110 may be provided with a horizontal annular rim to assist in holding the heat exchange structure 110 for up and down displacement.
In some embodiments of the present application, the sliding groove 123 is spirally formed around the outer wall periphery of the sleeve 122 from top to bottom; the fixing pin 124 moves up and down along the sliding groove 123.
As shown in fig. 1, the sliding groove 123 is spirally wound around the sleeve 122, and the fixing pin 124 cannot move by itself due to the blocking of the sliding groove without external power, so that the fixing pin 124 can be moved to a certain position on the sliding groove 123 only by rotating the water inlet pipe 121, and the sliding groove 123 also plays a certain fixing role. The spiral sliding groove 123 can realize the distance required by the up-down movement of the heat exchange structure 110 under the shorter sleeve 122 compared with the straight sliding groove 123, and the spiral sliding groove 123 can be randomly moved to any position within a limited range, and the optional range of the moving distance is larger; the straight sliding groove 123 has a limited number of grooves, and is not guaranteed to move to a proper distance, and is limited.
The heat exchanging structure 110 is horizontally rotated to drive the water inlet pipe 121 to rotate, and the fixing pin 124 moves up and down along the sliding groove 123, so that the heat exchanging structure 110 is close to or far from the bottom of the compressor. Specifically, when the heat exchange structure 110 needs to be close to the bottom of the compressor, the heat exchange structure 110 is rotated to drive the water inlet pipe 121 to rotate, so that the fixing pin 124 moves upwards along the sliding groove 123, and the heat exchange structure 110 moves upwards. When the heat exchange structure 110 needs to be far away from the bottom of the compressor, the heat exchange structure 110 is rotated to drive the water inlet pipe 121 to rotate, so that the fixing pin 124 is displaced downwards along the sliding groove 123, and the heat exchange structure 110 is further moved downwards.
In some embodiments of the present application, the end of the sleeve 122 is provided with a pedestal 125, the pedestal 125 is provided with a screw hole, and the sleeve 122 is connected with the bottom plate of the external machine through a screw penetrating the screw hole.
As shown in fig. 1, by arranging the base 125 at the bottom end of the sleeve 122, the base 125 is provided with screw holes, and the base 125 and the screw are matched and detachably arranged on the bottom plate of the external machine, and the sleeve 122 is connected with the heat exchange structure 110, so that the installation stability of the heat exchange structure 110 is ensured; the design of the base 125 makes the disassembly of the sleeve 122 more convenient, and further ensures the convenience of the disassembly of the heat exchange structure 110. Therefore, the pedestal 125 can achieve the purpose of convenient disassembly and installation, and further, the heat exchange cavity 111 is convenient to be cleaned periodically. For example, the base 125 may be designed into a ring shape or a structure with two ears, and two or three screw holes may be provided, so as to ensure the stability of installation and convenience of disassembly.
In some embodiments of the present application, the heat exchange structure 110 is made of metal.
Preferably, the material used may be carbon steel, low alloy steel, stainless steel, copper-nickel alloy, aluminum alloy, titanium, etc., and further preferably, the material used is copper. In the related life test, for the medium temperature heat exchange process, under the condition that condensed water is led into the heat exchange cavity 111, copper is the best heat exchange material, and has the characteristics of low cost, easy manufacture, easy material acquisition, high strength and the like, and particularly, the heat conduction performance of copper is better.
In some embodiments of the present application, the heat exchange structure 110 is coupled to a compressor; and/or the air conditioner includes a bracket for supporting the compressor, and the heat exchanging structure 110 is connected to the bracket.
The heat exchange structure 110 is installed on the bottom plate of the external machine, and the heat exchange structure 110 is supported by the telescopic structure 120, but the long-term stability of the support is limited, and particularly after the heat exchange cavity 111 is filled with condensed water, the telescopic structure 120 is more difficult to support the weight of the heat exchange structure 110. Therefore, the heat exchange structure 110 is selectively connected with the bottom of the compressor in a welding and bonding mode; in addition, the compressor is arranged on the upper part of the heat exchange structure 110, and a mounting bracket is needed to support the compressor, so that the heat exchange structure 110 can be selectively fastened with the bracket for supporting the compressor through a buckle and a plastic buckle, and the heat exchange structure 110 can be supported and stabilized to a certain extent.
Although the present utility model is disclosed above, the present utility model is not limited thereto. Various changes and modifications may be made by one skilled in the art without departing from the spirit and scope of the utility model, and the scope of the utility model should be assessed accordingly to that of the appended claims.
Claims (10)
1. A compressor heat sink (100) for an air conditioner, comprising:
A heat exchange structure (110), the heat exchange structure (110) being for dissipating heat from the compressor;
One end of the telescopic structure (120) is connected with the heat exchange structure (110), and the other end of the telescopic structure (120) is fixed on an outer machine bottom plate of the air conditioner;
The telescopic structure (120) is used for supporting the heat exchange structure (110) and adjusting the distance between the heat exchange structure (110) and the bottom plate of the external machine through telescopic adjustment.
2. The compressor heat sink (100) of claim 1, wherein a heat exchange cavity (111) is provided inside the heat exchange structure (110); the telescopic structure (120) comprises a water inlet pipe (121), and the water inlet pipe (121) is communicated with the heat exchange cavity (111) and is used for supplying water to the heat exchange cavity (111).
3. The compressor heat sink (100) of claim 2, wherein the heat exchanging structure (110) is further provided with a water outlet (112) communicating with the heat exchanging cavity (111), and an end of the water inlet pipe (121) away from the heat exchanging cavity (111) communicates with a condensed water discharge pipe of the air conditioner.
4. The compressor heat sink (100) of claim 2, wherein the heat exchange structure (110) is disc-shaped, and an inner wall (113) of the heat exchange cavity (111) forms a recess for receiving a bottom of the compressor.
5. The compressor heat sink (100) of claim 2, wherein the telescoping structure (120) further comprises a sleeve (122), the sleeve (122) being sleeved outside the water inlet pipe (121) for relative movement;
The sleeve (122) is provided with a sliding groove (123), a fixing pin (124) is arranged on the pipe wall of the water inlet pipe (121), and the fixing pin (124) stretches into and is clamped with the sliding groove (123).
6. The compressor heat sink (100) of claim 5, wherein the sliding groove (123) is spirally formed around the outer wall periphery of the sleeve (122) from top to bottom; the fixing pin (124) moves up and down along the sliding groove (123).
7. The compressor heat sink (100) of claim 5, wherein a base (125) is provided at an end of the sleeve (122), a screw hole is provided in the base (125), and the sleeve (122) is connected to the outer chassis plate by a screw penetrating the screw hole.
8. The compressor heat sink (100) of any one of claims 1 to 7, wherein the heat exchanging structure (110) is of metal.
9. The compressor heat sink (100) of any one of claims 1 to 7, wherein,
The heat exchange structure (110) is connected with the compressor; and/or
The air conditioner comprises a bracket for supporting the compressor, and the heat exchange structure (110) is connected with the bracket.
10. An air conditioner, characterized in that the air conditioner comprises:
A compressor;
The compressor heat sink (100) according to any one of claims 1 to 9, the compressor heat sink (100) being adapted to dissipate heat for the compressor.
Priority Applications (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN202322358057.6U CN221055141U (en) | 2023-08-31 | 2023-08-31 | A compressor heat abstractor and air conditioner for air conditioner |
Applications Claiming Priority (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN202322358057.6U CN221055141U (en) | 2023-08-31 | 2023-08-31 | A compressor heat abstractor and air conditioner for air conditioner |
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| CN221055141U true CN221055141U (en) | 2024-05-31 |
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| CN202322358057.6U Active CN221055141U (en) | 2023-08-31 | 2023-08-31 | A compressor heat abstractor and air conditioner for air conditioner |
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| CN (1) | CN221055141U (en) |
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