CN216716520U - Air conditioner - Google Patents

Abstract

The utility model provides an air conditioner. Wherein the air conditioner includes: the refrigerant pipeline is internally provided with a refrigerant flowing and provided with a one-way throttling device; the electric control board is provided with an electric control device which generates heat during working; one side of the heat dissipation plate is attached to the electric control plate so as to conduct heat generated by the electric control device to the whole heat dissipation plate; the capillary tube is at least partially attached to the other side of the heat dissipation plate and is arranged in the refrigerant pipeline in series, and the refrigerant takes away heat of the heat dissipation plate when flowing through the capillary tube. According to the air conditioner, the capillary tube is arranged, so that the electric control device of the air conditioner can be effectively radiated by a simple structure, a large space is prevented from being occupied, and the radiating effect is ensured while the cost is saved; different throttling degrees can be realized by the one-way throttling device when the flowing directions of the refrigerants are different, different throttling requirements of the air conditioner on the refrigerants when the air conditioner operates in different modes are met, the overall working reliability is improved, and the use experience of users is further improved.

Description

Air conditioner

Technical Field

The utility model relates to the technical field of household appliances, in particular to an air conditioner.

Background

With the social development and the increasing living standard of people, the air conditioner is more and more used as the household appliance essential to the life of people. With the increasing functions of air conditioners, the number of electric control components carried by the air conditioners, such as Intelligent Power modules (IPM for short) and Insulated Gate Bipolar transistors (IGBT for short), and other high-Power devices, is also increasing, and the heat generation and Power density of the electric control components are increasing.

In the prior art, aiming at the problem of large heat productivity of an electric control device of an air conditioner, a common solution is wind cooling and refrigerant cooling. The air cooling needs to additionally add a heat dissipation device in the air conditioner, occupies a larger space, and has a poor cooling effect. Refrigerant cooling is because the refrigerant state difference of cooling plate entrance is very big, if the cooling refrigerant temperature is lower, then probably condensation on some electron device, and automatically controlled board has the short circuit to burn out the risk, and the refrigerant cooling also has the problem of refrigerating output decay simultaneously.

Especially, the air conditioner frequency converter generally adopts IPM as a frequency conversion driving power switch, the area of a top heat dissipation source is small, and some heat dissipation sources are only 2cm²About 80W of heat dissipation power and 40W/cm of heat flux density². Due to the existence of high heat flow density, the existing heat dissipation mode can not effectively solve the problem of heat dissipation, the temperature of the surface of a heat source can reach 105 ℃, and when the outdoor unit of the air conditioner works in the tropical climate or summer environment, the outdoor high-temperature environment temperature can influence the surface of the heat source moreThe temperature of (2). The high temperature of the frequency converter limits the high-frequency operation of the frequency converter, so that the refrigerating capacity of the air conditioner is insufficient, and the working performance of the air conditioner is seriously influenced.

SUMMERY OF THE UTILITY MODEL

An object of the present invention is to realize effective heat dissipation of an electric control device of an air conditioner with a simple structure.

A further object of the present invention is to meet the different throttling requirements for the refrigerant when the air conditioner operates in different modes, and to improve the overall operational reliability.

In particular, the present invention provides an air conditioner comprising: the refrigerant pipeline is internally provided with a refrigerant flowing and provided with a one-way throttling device; the electric control board is provided with an electric control device which generates heat during working; one side of the heat dissipation plate is attached to the electric control plate so as to conduct heat generated by the electric control device to the whole heat dissipation plate; and the capillary tube is at least partially attached to the other side of the heat dissipation plate and is arranged in the refrigerant pipeline in series, and the refrigerant takes away the heat of the heat dissipation plate when flowing through the capillary tube.

Optionally, the refrigerant pipeline is provided with in series: the heat exchanger comprises a compressor, a four-way valve, a first heat exchanger, a one-way throttling device and a second heat exchanger, wherein a capillary tube is arranged between the one-way throttling device and the second heat exchanger.

Optionally, the air conditioner includes an indoor unit and an outdoor unit, and the first heat exchanger is disposed in the outdoor unit and the second heat exchanger is disposed in the indoor unit.

Optionally, in a case where the air conditioner operates in the cooling mode, the one-way throttling device is in a conducting state.

Alternatively, in the case where the air conditioner is operated in the heating mode, the one-way throttle device is in the throttle state.

Optionally, when the air conditioner operates in a cooling mode, the refrigerant sequentially flows through the compressor, the four-way valve, the first heat exchanger, the one-way throttling device, the capillary tube and the second heat exchanger.

Optionally, when the air conditioner operates in the heating mode, the refrigerant sequentially flows through the compressor, the four-way valve, the second heat exchanger, the capillary tube, the one-way throttling device, and the first heat exchanger.

Optionally, the one-way throttling device is a one-way throttling valve configured to control the refrigerant flow rate by changing a throttling cross section or a throttling length.

Optionally, the electrically controlled device is a device having a power switch.

Optionally, one side of the heat dissipation plate is attached to the electronic control plate through an interface heat conducting medium, and the capillary is also attached to the other side of the heat dissipation plate through the interface heat conducting medium.

The air conditioner of the present invention includes: the refrigerant pipeline is internally provided with a refrigerant flowing and provided with a one-way throttling device; the electric control board is provided with an electric control device which generates heat during working; one side of the heat dissipation plate is attached to the electric control plate so as to conduct heat generated by the electric control device to the whole heat dissipation plate; the capillary tube is at least partially attached to the other side of the heat dissipation plate and is arranged in the refrigerant pipeline in series, when a refrigerant flows through the capillary tube, heat of the heat dissipation plate is taken away, and through the arrangement of the capillary tube, effective heat dissipation of an electric control device of the air conditioner is achieved through a simple structure, occupation of a large space is avoided, and the heat dissipation effect is guaranteed while cost is effectively saved.

Furthermore, in the air conditioner, under the condition that the air conditioner operates in a refrigeration mode, the one-way throttling device is in a conducting state, and a refrigerant sequentially flows through the compressor, the four-way valve, the first heat exchanger, the one-way throttling device, the capillary tube and the second heat exchanger; under the condition that the air conditioner operates in the mode of heating, one-way throttling arrangement is the throttle state, and the refrigerant flows through the compressor in proper order, cross valve, second heat exchanger, capillary, one-way throttling arrangement, first heat exchanger, through setting up one-way throttling arrangement, can realize different throttle degrees at the refrigerant flow direction inequality, satisfy the air conditioner and operate to the different throttle demands of refrigerant when different modes, improve whole operational reliability, and then promote user's use and experience.

The above and other objects, advantages and features of the present invention will become more apparent to those skilled in the art from the following detailed description of specific embodiments thereof, taken in conjunction with the accompanying drawings.

Drawings

Some specific embodiments of the utility model will be described in detail hereinafter, by way of illustration and not limitation, with reference to the accompanying drawings. The same reference numbers in the drawings identify the same or similar elements or components. Those skilled in the art will appreciate that the drawings are not necessarily drawn to scale. In the drawings:

fig. 1 is a schematic structural view of an indoor unit in an air conditioner according to an embodiment of the present invention;

fig. 2 is a schematic structural view of an electric control panel in an air conditioner according to an embodiment of the present invention;

fig. 3 is a schematic structural view of a heat radiating plate in an air conditioner according to an embodiment of the present invention;

fig. 4 is a schematic structural view of a refrigerant pipe in an air conditioner according to an embodiment of the present invention; and

fig. 5 is a schematic diagram showing relative positions of an electric control board, a heat radiating plate and a capillary tube in an air conditioner according to an embodiment of the present invention.

Detailed Description

The embodiment provides an air conditioner, which can realize effective heat dissipation of an electric control device of the air conditioner by using a simple structure, avoid occupying a larger space, and ensure the heat dissipation effect while effectively saving the cost. Fig. 1 is a schematic structural diagram of an indoor unit 100 in an air conditioner according to an embodiment of the present invention, fig. 2 is a schematic structural diagram of an electric control board 300 in an air conditioner according to an embodiment of the present invention, fig. 3 is a schematic structural diagram of a heat dissipation board 400 in an air conditioner according to an embodiment of the present invention, fig. 4 is a schematic structural diagram of a refrigerant pipe 200 in an air conditioner according to an embodiment of the present invention, and fig. 5 is a schematic relative position diagram of the electric control board 300, the heat dissipation board 400 and a capillary 500 in an air conditioner according to an embodiment of the present invention. As shown in fig. 1 to 5, the air conditioner of the present embodiment may generally include: refrigerant pipeline 200, electric control board 300, heat dissipation board 400 and capillary 500.

The refrigerant pipeline 200 has a refrigerant flowing therein, and the refrigerant pipeline 200 is provided with a one-way throttle device 210. An electric control device 310 which generates heat during operation is arranged on the electric control board 300. One side of the heat dissipation plate 400 is attached to the electronic control board 300 to conduct heat generated by the electronic control device 310 to the entire heat dissipation plate 400. The capillary tube 500 is at least partially attached to the other side of the heat sink 400 and is serially disposed in the refrigerant pipeline 200, and the refrigerant takes heat of the heat sink 400 away when flowing through the capillary tube 500.

The capillary 500 is at least partially attached to the other side of the heat sink 400, that is, a part of the capillary 500 may be attached to the other side of the heat sink 400, or the whole capillary 500 may be attached to the other side of the heat sink 400. In a preferred embodiment, the capillary 500 can be completely attached to the other side of the heat dissipation plate 400, so that the heat dissipation plate 400 can be dissipated to the maximum extent, the electric control device 310 is cooled, and the heat dissipation and cooling effects are effectively improved.

As shown in fig. 4, the refrigerant pipeline 200 is provided with: compressor 220, four-way valve 230, first heat exchanger 240, one-way throttle device 210, and second heat exchanger 250, and capillary tube 500 is disposed between one-way throttle device 210 and second heat exchanger 250. Generally, an air conditioner includes an indoor unit 100 and an outdoor unit (not shown), and a first heat exchanger 240 is disposed in the outdoor unit and a second heat exchanger 250 is disposed in the indoor unit 100.

In a specific embodiment, the one-way throttling device 210 is in a conducting state when the air conditioner is operating in a cooling mode. When the air conditioner operates in a cooling mode, a refrigerant sequentially flows through the compressor 220, the four-way valve 230, the first heat exchanger 240, the one-way throttle device 210, the capillary tube 500, and the second heat exchanger 250. That is, in the case where the air conditioner operates in the cooling mode, the refrigerant passes through the one-way throttling device 210, but directly flows into the capillary tube 500 without being throttled.

When the air conditioner is operated in the heating mode, the one-way throttle device 210 is in the throttle state. When the air conditioner operates in the heating mode, the refrigerant sequentially flows through the compressor 220, the four-way valve 230, the second heat exchanger 250, the capillary tube 500, the one-way throttling device 210, and the first heat exchanger 240. That is, when the air conditioner is operated in the heating mode, the refrigerant flows out of the capillary tube 500, is throttled by the one-way throttle device 210, and then flows into the first heat exchanger 240.

In a preferred embodiment, the one-way throttling device 210 is a one-way throttle valve configured to control the refrigerant flow rate by changing the throttling section or the throttling length. As mentioned above, in the case where the air conditioner is operated in the cooling mode, the one-way throttle device 210 is in the on state. When the air conditioner is operated in the heating mode, the one-way throttle device 210 is in the throttle state. When the one-way throttle device 210 is a one-way throttle valve, the on state or the throttle state can be realized by changing the throttle cross section or the throttle length. Further, the throttle degree can also be adjusted by changing the throttle section or the throttle length.

Specifically, the one-way throttle valve may mainly include a valve body, a valve seat, and a conical cylindrical spool. The valve body is provided with a throttling port and a conducting port; the valve seat is arranged in the valve body and is provided with a valve seat cavity, the valve seat is connected with the valve body in a necking sealing mode, and the waist of the valve seat is provided with a plurality of through holes; the valve core is arranged in the valve seat cavity and used for sliding back and forth along the valve seat cavity to block or keep away from the through hole, and the valve core is provided with a valve core head and a throttling hole penetrating through the valve core. The end part of the valve seat is provided with a throttling opening, a flow channel is arranged between the valve body and the valve seat, when a refrigerant participates in refrigeration and is input from the conduction port, the valve core is pushed away from the through hole, the refrigerant flows out from the cavity of the valve seat through the through hole, and is output from the throttling port after passing through the flow channel; when the refrigerant participates in heating and is input from the throttling port, the refrigerant enters the valve seat cavity from the throttling opening, the valve core blocks the through hole, and the refrigerant is subjected to auxiliary throttling through the throttling hole and is output from the conducting port. The one-way throttle valve is mainly characterized by refrigerating one-way conduction and heating for auxiliary throttling.

Solid arrows in fig. 4 indicate the flow direction of the refrigerant when the air conditioner is operating in the cooling mode, and broken arrows indicate the flow direction of the refrigerant when the air conditioner is operating in the heating mode. The following describes specific changes of the refrigerant when the air conditioner operates in the cooling mode and the heating mode.

When the air conditioner operates in a refrigeration mode, a refrigerant is sucked by the compressor 220 in a gaseous state, the refrigerant is compressed into high-temperature high-pressure steam to enter the first heat exchanger 240, the steam is condensed into high-temperature high-pressure liquid to flow to the one-way throttling device 210, then the high-temperature high-pressure liquid flows through the capillary tube 500 to take away heat of the heat dissipation plate 400, the electric control device 310 is cooled, the refrigerant after being throttled and decompressed is changed into a low-temperature low-pressure gas-liquid mixture to enter the second heat exchanger 250, the heat in the air is absorbed to be vaporized, and the low-pressure superheated steam is sucked back by the compressor 220.

When the air conditioner operates in a heating mode, a refrigerant is sucked by the compressor 220 in a gaseous state, is compressed into high-temperature high-pressure steam, enters the second heat exchanger 250, is condensed into high-temperature high-pressure liquid, flows to the capillary tube 500, takes away heat of the heat dissipation plate 400, cools the electric control device 310, then flows through the one-way throttling device 210, is changed into a low-temperature low-pressure gas-liquid mixture, enters the first heat exchanger 240, absorbs heat in air to be vaporized, and is changed into low-pressure superheated steam, and the low-pressure superheated steam is sucked back by the compressor 220.

It should be noted that four-way valve 230 can be configured as: the flow direction of the refrigerant is switched. That is, the flow direction of the refrigerant can be changed by adjusting the four-way valve 230 under different conditions of the air conditioner in the cooling mode and the heating mode. When the air conditioner is operated in a cooling mode, the four-way valve 230 communicates a path from the outlet of the compressor 220 to the inlet of the first heat exchanger 240 and a path from the outlet of the second heat exchanger 250 to the inlet of the compressor 220. When the air conditioner is operated in a heating mode, the four-way valve 230 communicates a path from the outlet of the compressor 220 to the inlet of the second heat exchanger 250 and a path from the outlet of the first heat exchanger 240 to the inlet of the compressor 220.

However, regardless of whether the air conditioner is operated in the cooling mode or the heating mode, the refrigerant flows from the one-way throttling device 210 to the capillary tube 500 or from the second heat exchanger 250 to the capillary tube 500, and absorbs heat when flowing through the capillary tube 500, so as to take away heat of the heat dissipation plate 400 and cool the electronic control device 310. The air conditioner of this embodiment, through setting up capillary 500 to a simple structure realizes effectively dispelling the heat to the automatically controlled device 310 of air conditioner, avoids taking great space, guarantees the radiating effect when effectively practicing thrift the cost.

As shown in fig. 2, an electric control board 300 in the air conditioner is provided with an electric control device 310 that generates heat during operation. In one particular embodiment, electronically controlled device 310 is a device having a power switch. For example, the electric control component can be an IPM, an IGBT or other high-power device. The IPM not only integrates the power switching device and the driving circuit, but also integrates therein fault detection circuits such as overvoltage, overcurrent, and overheat, and can send detection signals to the CPU. The high-speed low-power-consumption transistor consists of a high-speed low-power-consumption transistor core, an optimized gate driving circuit and a quick protection circuit. IPM generally uses an IGBT as a power switching element and an integrated structure in which a current sensor and a driver circuit are integrated. The IGBT is a composite full-control voltage-driven power semiconductor device consisting of a BJT (bipolar junction transistor) and an MOS (metal oxide semiconductor), namely a bipolar transistor and an insulated gate field effect transistor, and has the advantages of high input impedance and low conduction voltage drop.

In a specific embodiment, the electronic control Board 300 may be a Printed Circuit Board (PCB), which may also be referred to as a PCB or a PCB. The PCB is a support for the electronic control device 310 and a carrier for electrical connection of the electronic control device 310 as an important electronic component. The electronic control device 310 can be distributed at different positions of the electronic control board 300, and a heat generating area is formed on the electronic control board 300 during operation.

In a specific embodiment, the IPM can be used as an inverter driving power switch of an air conditioner, which integrates a power switch device and a driving circuit, and further integrates a fault detection circuit having a plurality of protection functions (such as over-temperature, over-voltage, over-current, under-voltage protection, etc.) therein. When the air conditioner works at high frequency, the temperature of the heating area on the electric control board 300 can reach 100 ℃. The high temperature may affect the high frequency operation of the air conditioner and affect the performance of the air conditioner.

The air conditioner of the present embodiment can effectively solve the above-mentioned heat dissipation problem by providing the heat dissipation plate 400 and the capillary tube 500. As mentioned above, the heat dissipation plate 400 can conduct the heat generated by the electric control device 310 to the whole heat dissipation plate 400, and in a specific embodiment, the heat dissipation plate 400 can be a temperature equalization plate, which can effectively increase the heat dissipation speed. As shown in fig. 3, a sintering heat pipe 420 may be embedded in one side of the heat dissipation plate 400, and a region of the heat dissipation plate 400 where a partial pipe section of the sintering heat pipe 420 is located is attached to a heat generation region on the electronic control board 300, so as to conduct heat generated by the heat generation region to the entire heat dissipation plate 400. Wherein, part of the pipe sections of the sintered heat pipe 420 can be the middle pipe section thereof, and at the moment, the heat is conducted from the middle pipe section of the sintered heat pipe 420 to the pipe sections at the two ends; part of the pipe section of the sintered heat pipe 420 may also be one end of the pipe sections at both ends thereof, and at this time, heat is conducted from the end of the sintered heat pipe 420 to the other end, and both of these two ways can conduct heat generated in the heating region to the entire heat dissipation plate 400, so that the heat dissipation plate 400 can achieve rapid temperature equalization.

The heat pipe utilizes the phase change process of medium evaporation at the hot end and then condensation at the cold end (namely, utilizes the latent heat of evaporation and the latent heat of condensation of liquid) to quickly conduct heat. A typical heat pipe may consist of a pipe casing, a wick and end caps. The interior of the heat pipe is pumped into a negative pressure state and filled with liquid with a low boiling point so as to be easy to volatilize. The tube wall has a wick that is constructed of a capillary porous material. Generally, one part of the heat pipe is used as an evaporation section, the other part is used as a condensation section, when the evaporation section of the heat pipe is heated, the liquid in the capillary 500 is rapidly vaporized, the vapor flows to the condensation section under the power of heat diffusion, the heat is released at the condensation section, the liquid flows back to the evaporation end along the porous material by virtue of the capillary action, and the circulation is not stopped until the temperatures at the two ends of the heat pipe are equal (at the moment, the heat diffusion of the vapor is stopped). This cycle is rapid and heat can be conducted away from the heat source.

The heat pipe in this embodiment may be a sintered heat pipe 420, and the capillary structure is made by sintering copper powder at high temperature. The capillary permeability of each portion of the sintered heat pipe 420 is substantially the same and the copper powder agglomerates are distributed with a substantially uniform thickness.

The heat conduction performance of the heat pipe is also influenced by the size of the heat pipe, and the heat conduction performance of the heat pipes with different diameters is greatly different. The length of the heat pipe is 150mm, and the thermal resistance value of the heat pipe with the diameter of 3mm is 0.33. And at a diameter of 5mm, the thermal resistance immediately dropped to 0.11. When the diameter of the heat pipe is enlarged to 8mm, the thermal resistance is suddenly reduced to 0.0625. Preferably, the diameter of the sintered heat pipe 420 of the present embodiment may be 6mm or 8mm to reduce thermal resistance and improve heat conduction efficiency. The above specific values are merely examples, and the length and the diameter of the heat pipe may be selected according to the amount of heat to be dissipated and the size of the heat dissipation area in the specific embodiment, which is not a limitation of the present invention.

The heat dissipating plate 400 in the air conditioner of this embodiment may utilize the sintering heat pipe 420 to conduct the heat with large heat flux density in the micro area of the heating area on the electric control board 300 to the whole heat dissipating plate 400, so as to achieve rapid temperature equalization and provide a precondition for the next effective heat dissipation. In a specific embodiment, since the heat conduction efficiency of the metal aluminum is high and the cost is low, the heat dissipation plate 400 may be made of an aluminum plate, a plurality of grooves 410 are further formed on one side of the heat dissipation plate 400, and the sintering heat pipe 420 is welded in the grooves 410. The sintered heat pipe 420 is a flat heat pipe or a semicircular heat pipe, and a part of the pipe wall of the sintered heat pipe is flush with the surface of the heat dissipation plate 400, so that the heat dissipation plate 400 is reliably attached to the electronic control board 300, and the other part of the pipe wall is matched with the groove 410 in shape. The plurality of grooves 410 may be uniformly spaced to further increase the temperature equalization rate.

As shown in fig. 5, at least a partial region of the capillary tube 500 is attached to the other side of the heat dissipation plate 400, and the refrigerant exchanges heat with the heat dissipation plate 400 when flowing through the capillary tube 500, thereby taking away heat of the heat dissipation plate 400 and cooling the electronic control device 310.

The refrigerant is a substance that easily absorbs heat to become gas and easily releases heat to become liquid. When the refrigerant is pressed, the heat is released and changed into liquid; when the high-pressure liquid is decompressed into gas, the gas absorbs heat. The air conditioner of this embodiment utilizes this characteristic of refrigerant, flows through capillary 500 through the refrigerant to make capillary 500 throttle the decompression to the refrigerant, absorb the heat of heating panel 400, realize the cooling to heating panel 400 and electrically controlled device 310. The capillary tubes 500 are serially connected in the refrigerant pipeline 200, and the refrigerant of the air conditioner is used for heat dissipation, so that an additionally arranged heat dissipation device is avoided, the occupied space is reduced, the cost is saved, the heat dissipation efficiency is improved, and the operational reliability and the working efficiency of the air conditioner are ensured.

As shown in fig. 5, one side of the heat sink 400 is attached to the electronic control board 300, and the capillary 500 is attached to the other side of the heat sink 400. In a preferred embodiment, one side of the heat dissipation plate 400 is attached to the electronic control board 300 through an interface heat-conducting medium, and the capillary 500 is also attached to the other side of the heat dissipation plate 400 through an interface heat-conducting medium. Specifically, the area of the heat dissipation plate 400 where the partial pipe sections of the sintered heat pipe 420 are located is attached to the heat generation area on the electronic control board 300 through the interface heat conducting medium. The interface heat-conducting medium is coated between the heat dissipation plate 400 and the electric control plate 300 and between the capillary 500 and the heat dissipation plate 400, so that gaps between contact surfaces are filled, heat conduction is smoother by utilizing the excellent heat-conducting effect of the interface heat-conducting medium, and the gaps are prevented from hindering the heat conduction. The interface heat-conducting medium can be heat-conducting silica gel, heat-conducting silicone grease, metal heat-conducting fins, graphite heat-conducting films and other materials. Since the heat-conducting silica gel has more insulating ability than the electrically conductive heat-conducting silicone grease, the metal heat-conducting sheet, the graphite heat-conducting film, and the like, the interface heat-conducting medium of the embodiment is preferably the heat-conducting silica gel.

In addition, a heat insulating layer may cover a side of the capillary 500 not attached to the heat sink 400 to insulate external heat and prevent the capillary 500 from heat exchange with an external environment. Wherein the heat preservation layer can be formed by heat preservation cotton. The area of the heat sink 400 may be smaller than or equal to the area of the capillary 500 so that the heat sink 400 is completely covered by the capillary 500. Therefore, the other side of the whole heat dissipation plate 400 can be attached to at least partial area of the capillary 500, heat exchange between the whole heat dissipation plate 400 and the capillary 500 is realized, and the problem that the heat dissipation plate 400 cannot realize effective heat dissipation in partial area is avoided. In addition, the area of the heat dissipation plate 400 may be at least larger than the area of the heat generation area on the electronic control board 300, so that the heat dissipation area is increased, and the heat dissipation speed is increased.

In a preferred embodiment, the electronic control board 300 may be horizontally disposed, and a portion of the sintered heat pipe 420 attached to the heat generating region is used as an evaporation end, and a portion of the sintered heat pipe away from the evaporation end is used as a condensation end. That is, the sintered heat pipe 420 can quickly transfer high heat of the heat generating region on the electronic control board 300 from one section of the pipe to another section of the pipe, so that the heat dissipation board 400 can achieve quick temperature equalization.

In some alternative embodiments, the area of the heat dissipation plate 400 where the middle segment of the sintered heat pipe 420 is located may be attached to the heat generating area on the electronic control board 300, so that heat is conducted from the middle segment of the sintered heat pipe 420 to the two end segments. In addition, the area of the heat dissipation plate 400 where the pipe segment at one end of the heat pipe 420 is located may be attached to the heat generating area on the electronic control board 300, and at this time, heat is conducted from the end of the heat pipe 420 to the other end.

The air conditioner of this embodiment, at first utilize heating panel 400 to conduct the heat that the automatically controlled device 310 on with automatically controlled board 300 produced to whole heating panel 400, recycle the refrigerant and flow through capillary 500 and carry out the heat exchange with heating panel 400, take away the heat of heating panel 400, realize the quick samming and the effective heat dissipation of automatically controlled board 300, make air conditioner 100 can work in the high frequency mode under the very high condition of ambient temperature, promote the quick refrigeration ability under the high temperature weather.

As shown in fig. 1, the indoor unit 100 may generally include: the housing 110, and a lower portion of a front side of the housing 110 may be provided with an air outlet 111. The interior of the housing 110 defines a cavity in which the second heat exchanger 250 may be disposed. The air conditioner may further include: a first fan disposed opposite to the first heat exchanger 240; and a second fan disposed opposite to the second heat exchanger 250. Neither the first fan nor the second fan is shown in the drawings, and it should be noted that the first fan may be disposed in the outdoor unit to correspond to the first heat exchanger 240, and the second fan may be disposed in the cavity to correspond to the first heat exchanger 240. Taking the second fan as an example, when the air conditioner operates in the cooling mode, the refrigerant flows through the second heat exchanger 250 to absorb heat, so that the second fan can send out cold air through the air outlet 111, reduce the ambient temperature, and realize cooling. When the air conditioner operates in the cooling mode, the refrigerant flows through the second heat exchanger 250 to release heat, so that the second fan can send hot air out through the air outlet 111 to raise the ambient temperature, thereby realizing heating.

In summary, the air conditioner of the present embodiment includes: a refrigerant pipeline 200, in which a refrigerant flows, and the refrigerant pipeline 200 is provided with a one-way throttling device 210; the electronic control board 300 is provided with an electronic control device 310 which generates heat during working; a heat dissipation plate 400 having one side attached to the electric control board 300 to transfer heat generated from the electric control device 310 to the entire heat dissipation plate 400; and the capillary tube 500, at least partially laminate with another side of the cooling plate 400, and set up in the coolant pipeline 200 in series, the coolant takes away the heat of the cooling plate 400 when flowing through the capillary tube 500, through setting up the capillary tube 500, realize the effective heat dissipation to the electric control device 310 of the air conditioner with a simple structure, avoid occupying great space, guarantee the radiating effect while effectively saving the cost.

Further, in the air conditioner of the present embodiment, when the air conditioner operates in the cooling mode, the one-way throttling device 210 is in a conducting state, and the refrigerant sequentially flows through the compressor 220, the four-way valve 230, the first heat exchanger 240, the one-way throttling device 210, the capillary tube 500, and the second heat exchanger 250; under the condition that the air conditioner operates in the mode of heating, one-way throttling arrangement 210 is the throttle state, the refrigerant flows through compressor 220 in proper order, cross valve 230, second heat exchanger 250, capillary 500, one-way throttling arrangement 210, first heat exchanger 240, through setting up one-way throttling arrangement 210, can realize different throttle degrees at the refrigerant flow direction is different, satisfy the air conditioner and operate the different throttle demands to the refrigerant when different modes, improve whole operational reliability, and then promote user's use and experience.

Thus, it should be appreciated by those skilled in the art that while a number of exemplary embodiments of the utility model have been illustrated and described in detail herein, many other variations or modifications consistent with the principles of the utility model may be directly determined or derived from the disclosure of the present invention without departing from the spirit and scope of the utility model. Accordingly, the scope of the utility model should be understood and interpreted to cover all such other variations or modifications.

Claims (10)

1. An air conditioner, comprising:

the refrigerant pipeline is internally provided with a refrigerant flowing and is provided with a one-way throttling device;

the electric control board is provided with an electric control device which generates heat during working;

one side of the heat dissipation plate is attached to the electric control plate so as to conduct heat generated by the electric control device to the whole heat dissipation plate; and

the capillary tube is at least partially attached to the other side of the heat dissipation plate and is arranged in the refrigerant pipeline in series, and the refrigerant takes away heat of the heat dissipation plate when flowing through the capillary tube.

2. The air conditioner according to claim 1,

the refrigerant pipeline is provided with in series: a compressor, a four-way valve, a first heat exchanger, the one-way throttling device, a second heat exchanger, and

the capillary tube is arranged between the one-way throttling device and the second heat exchanger.

3. The air conditioner according to claim 2,

the air conditioner comprises an indoor unit and an outdoor unit, and

the first heat exchanger is disposed in the outdoor unit,

the second heat exchanger is arranged in the indoor unit.

4. The air conditioner according to claim 3,

and under the condition that the air conditioner operates in a refrigeration mode, the one-way throttling device is in a conducting state.

5. The air conditioner according to claim 3,

and under the condition that the air conditioner runs in a heating mode, the one-way throttling device is in a throttling state.

6. The air conditioner according to claim 4,

under the condition that the air conditioner operates in a refrigeration mode, the refrigerant sequentially flows through the compressor, the four-way valve, the first heat exchanger, the one-way throttling device, the capillary tube and the second heat exchanger.

7. The air conditioner according to claim 5,

under the condition that the air conditioner operates in a heating mode, the refrigerant sequentially flows through the compressor, the four-way valve, the second heat exchanger, the capillary tube, the one-way throttling device and the first heat exchanger.

8. The air conditioner according to claim 1,

the one-way throttling device is a one-way throttling valve and is configured to control the refrigerant flow by changing the throttling section or the throttling length.

9. The air conditioner according to claim 1,

the electric control device is a device with a power switch.

10. The air conditioner according to claim 1,

one side of the heat dissipation plate is attached to the electric control plate through an interface heat-conducting medium,

the capillary tube is also attached to the other side of the heat dissipation plate through the interface heat conducting medium.

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