CN210638173U - Heat exchanger of air conditioner indoor unit and air conditioner indoor unit - Google Patents

Abstract

The utility model belongs to the technical field of the air conditioner, concretely relates to machine in heat exchanger and air conditioning of machine in air conditioning. The utility model discloses the heat exchanger that aims at solving current air conditioner is difficult to with the even heat transfer of air current, the unsatisfactory problem of heat transfer effect. Mesh for this reason, the utility model discloses a coil pipe of heat exchanger is by dividing liquid component to refrigerant output tube outdiffusion setting to make the multistage connecting pipe of coil pipe can form a great frame construction jointly, make the heat transfer position diffusion distribution of this heat exchanger open, and then make a plurality of heat transfer positions of coil pipe can disperse in the air current, increased the heat transfer uniformity degree of heat exchanger and air current. In addition, the diffused frame structure increases the fin arrangement space, so that the whole heat exchange area of the heat exchanger is obviously increased. That is to say, the utility model discloses a heat exchanger makes the heat transfer performance of heat exchanger obtain showing and promoting from the mode that the diffusion was arranged heat transfer point and increase heat transfer area.

Description

Heat exchanger of air conditioner indoor unit and air conditioner indoor unit

Technical Field

The utility model belongs to the technical field of the air conditioner, concretely relates to machine in heat exchanger and air conditioning of machine in air conditioning.

Background

As air conditioners are widely used in thousands of households, users have higher and higher requirements on the use performance of the air conditioners. Taking a cabinet air conditioner as an example, generally, under the same condition, the performance of the cabinet air conditioner depends on the heat exchange efficiency, the heat exchange efficiency has a direct relationship with the heat exchange area, and the larger the heat exchange area is, the higher the heat exchange efficiency is generally.

Generally, the structure and the arrangement mode of the heat exchanger directly determine the size of a heat exchange area and the height of heat exchange efficiency. In the existing cabinet air conditioner, the heat exchanger is usually disposed in the air conditioner housing in an inclined manner or attached to the air inlet. Generally, in order to ensure that the heat exchanger has a large heat exchange area, the coil pipes are mostly arranged in a bent shape such as a U shape or an L shape. When the heat exchanger is installed in the inclined or wall-attached mode, the heat exchanger is difficult to uniformly contact and exchange heat with air flow, and the heat exchange effect is not ideal.

Accordingly, there is a need in the art for a new heat exchanger for an indoor unit of an air conditioner and an indoor unit of an air conditioner that solve the above problems.

SUMMERY OF THE UTILITY MODEL

In order to solve above-mentioned problem among the prior art, be difficult to for the heat exchanger of solving current air conditioner with the even heat transfer of air current, the unsatisfactory problem of heat transfer effect promptly, the utility model provides a heat exchanger of air conditioning indoor unit, the heat exchanger is including dividing liquid component, refrigerant output tube, coil pipe and fin, divide the liquid component with the refrigerant output tube is arranged from top to bottom, the coil pipe includes the multistage connecting pipe and every section the both ends of connecting pipe communicate respectively to divide the liquid component with the refrigerant output tube, the fin set up in on the multistage connecting pipe, the shape of refrigerant output tube is nonlinear line shape, the multistage connecting pipe by divide the liquid component extremely refrigerant output tube outdiffusion sets up.

In the preferable technical scheme of the heat exchanger, the shape of the refrigerant output pipe is arc or circular.

In the preferable technical scheme of the heat exchanger, the plurality of sections of connecting pipes are straight pipes, and the input ends of the plurality of sections of straight pipes are distributed on the liquid separating component in a circular distribution mode.

In the preferable technical scheme of the heat exchanger, the liquid separating component comprises a spherical liquid separating cavity, and a refrigerant input port and a plurality of refrigerant output ports which are arranged on the spherical liquid separating cavity, and the refrigerant output ports are connected with the connecting pipes in a one-to-one correspondence manner.

In the preferable technical scheme of the heat exchanger, the plurality of refrigerant output ports are uniformly distributed along the circumferential direction of the middle part of the outer side of the spherical liquid distribution cavity.

In the preferable technical scheme of the heat exchanger, the number of the fins is multiple, each fin is an annular fin, and the multiple annular fins are respectively connected with the connecting pipe and cover the connecting pipe in a manner of abutting against the connecting pipe in sequence.

Additionally, the utility model provides an indoor unit of air conditioning, the indoor unit of air conditioning include the casing and set up in heat exchanger and water collector in the casing, the water collector is located the below of heat exchanger, the heat exchanger is any kind of heat exchanger of the aforesaid.

In the preferable technical scheme of the indoor unit of the air conditioner, the water receiving tray comprises a first water receiving structure, a second water receiving structure and a drainage tube arranged between the first water receiving structure and the second water receiving structure, and the first water receiving structure and the second water receiving structure are vertically arranged up and down.

In the preferable technical scheme of the air conditioner indoor unit, the first water receiving structure is a circular disc and the circular disc is located above, the second water receiving structure is an annular disc and the annular disc is located below, the circular disc and the annular disc are coaxially arranged, and one sides of the circular disc and the annular disc, which are close to each other, are arranged in a staggered mode.

In the preferable technical scheme of the air conditioner indoor unit, the first water receiving structure is a circular disc and the circular disc is located below, the second water receiving structure is an annular disc and the annular disc is located above, the circular disc and the annular disc are coaxially arranged, and one sides of the circular disc and the annular disc, which are close to each other, are arranged in a staggered mode.

As can be understood by those skilled in the art, the heat exchanger of the present invention comprises a connection pipe for communicating the liquid separating member with the refrigerant output pipe and a fin disposed on the connection pipe, wherein the liquid separating member, the refrigerant output pipe and the plurality of sections are disposed on the connection pipe. The refrigerant output pipe is nonlinear and is vertically arranged with the liquid separating member, and the plurality of sections of connecting pipes are arranged by outward diffusion from the liquid separating member to the refrigerant output pipe. Through the arrangement, on the one hand, the heat exchanger is provided with a plurality of branches allowing the refrigerant to flow through the arrangement of the plurality of sections of connecting pipes, so that the probability of occurrence of the phenomenon of supercooling degree or superheat degree of the refrigerant is effectively reduced, and the unstable heat exchange condition of the indoor unit of the air conditioner is avoided to a certain extent. On the other hand, the non-linear arrangement of the refrigerant output pipe increases the length of the pipe body. Under the condition that above-mentioned multistage connecting pipe diffusion set up for the multistage connecting pipe can form a great frame construction jointly, make the heat transfer position diffusion of this heat exchanger open, make the coil pipe can disperse in the air current, arrange the heat transfer uniformity degree that has increased heat exchanger and air current through the dispersion of a plurality of heat transfer positions. In addition, the diffused frame structure increases the fin arrangement space, so that the whole heat exchange area of the heat exchanger is obviously increased. That is to say, the utility model discloses a heat exchanger makes the heat transfer performance of heat exchanger obtain showing and promoting from the mode that the diffusion was arranged heat transfer point and increase heat transfer area.

Preferably, the shape of the refrigerant output pipe is arc or circular, and the plurality of sections of connecting pipes are all straight pipes. The input ends of the multiple straight pipes are distributed on the liquid separating member in a circular distribution mode, so that the shape of the heat exchanger is similar to a funnel shape or a curved surface shape. Through the setting, make the utility model discloses a heat exchanger when increasing heat transfer area, promoting its and the even degree of heat transfer of air current, the overall structure that can also avoid the heat exchanger sets up and causes the hindrance to the flow of air current, has guaranteed the smooth and easy nature of flow of air current. The air flow heat exchanger not only avoids the flowing noise when the air flow passes through the heat exchanger for heat exchange, but also can avoid the conditions of uneven temperature of the whole air flow, lower heat exchange efficiency of partial coil pipes of the heat exchanger and the like caused by the fact that partial air flow stays to the position of the heat exchanger for a long time.

Preferably, the liquid separation cavity of the liquid separation member is spherical. The spherical liquid separating cavity promotes the refrigerant to flow in the liquid separating cavity in a rotating mode, so that the refrigerant can flow into the connecting pipes more smoothly and uniformly under the action of centrifugal force, and the uniform distribution degree of the refrigerant quantity in the multi-section connecting pipes is guaranteed.

Further, divide a plurality of refrigerant delivery outlets of liquid component along the circumference evenly distributed in its spherical outside middle part of dividing the liquid chamber to further promote the even liquid effect of dividing of refrigerant.

Preferably, the fins are all annular fins, the number of the annular fins is multiple, and the annular fins are sequentially abutted on the connecting pipe, so that the smoothness of airflow flowing through the heat exchanger is further ensured while the heat exchange area is increased.

The utility model also provides an indoor heat exchanger, this indoor heat exchanger include above-mentioned heat exchanger, and then possess whole beneficial effect of above-mentioned heat exchanger.

Preferably, the water pan of the indoor heat exchanger comprises a first water receiving structure, a second water receiving structure and a drainage tube arranged between the first water receiving structure and the second water receiving structure, the first water receiving structure and the second water receiving structure are vertically arranged up and down, so that the mode that the water pan is arranged in a split mode can enable the water pan to receive liquid dripped by the heat exchanger and allow air flow to pass through the water pan, and the water pan can be applied to a scene that air enters the indoor unit of the air conditioner downwards (namely, the air flow passes through the water pan from the bottom of the water pan to the position of the heat exchanger).

Furthermore, one of the first water receiving structure and the second water receiving structure is a circular disc, the other one is an annular disc, and the circular disc and the annular disc are arranged up and down and are staggered on the sides close to each other. Through the arrangement, when all liquid dropping areas of the heat exchanger are located in the water receiving range of the water receiving disc, the air flow can flow to the position of the heat exchanger through the annular air passing area between the disc and the annular disc, so that the air flow can directly surround the heat exchanger after passing through the water receiving disc, and the heat exchange efficiency of the air flow and the heat exchanger is improved. When the heat exchanger is funnel-shaped or curved cambered surface, the uniform contact degree and contact speed of the air flow and the fins and the coil pipe of the heat exchanger can be further improved by combining the annular distribution mode of the air flow, so that the heat exchanger has better heat exchange performance.

Drawings

The preferred embodiments of the present invention will now be described with reference to the accompanying drawings in conjunction with a cabinet air conditioner indoor unit. The attached drawings are as follows:

fig. 1 is a schematic view of the overall structure of a cabinet air conditioner indoor unit of the present invention in accordance with embodiment 1;

fig. 2 is a top view of the heat exchanger of the present invention;

fig. 3 is a front view of the heat exchanger of the present invention;

fig. 4 is a schematic structural view of a first embodiment of a water pan of a cabinet air-conditioning indoor unit of the present invention;

fig. 5 is a schematic structural view of a second embodiment of a water pan of a cabinet air-conditioner indoor unit of the present invention;

fig. 6 is a schematic view of a first working mode of the annular air outlet structure of the indoor unit of the cabinet air conditioner of the present invention;

fig. 7 is a schematic view of a second working mode of the annular air outlet structure of the indoor unit of the cabinet air conditioner of the present invention;

fig. 8 is a schematic view of the overall structure of a cabinet air conditioner indoor unit according to the embodiment 2 of the present invention;

fig. 9 is a schematic view of the overall structure of a cabinet air conditioner indoor unit of the present invention in accordance with embodiment 3;

FIG. 10 is a schematic view of the forward structure of the sterilization and purification module of the indoor unit of the cabinet air conditioner of the present invention;

FIG. 11 is a cross sectional view of the sterilization and purification module of the indoor unit of the cabinet air conditioner of the present invention;

fig. 12 is a schematic view of the entire structure of a cabinet air conditioner indoor unit according to embodiment 4 of the present invention;

fig. 13 is a schematic view of the whole structure of the fresh air module of the indoor unit of the cabinet air conditioner;

fig. 14 is a schematic view showing the operation of the cabinet air conditioner indoor unit in the first air intake mode according to the present invention;

FIG. 15 is a schematic view showing the second air intake mode of the indoor unit of the packaged air conditioner of the present invention;

fig. 16 is a schematic diagram showing a third air intake mode of the cabinet air conditioner indoor unit according to the present invention;

fig. 17 is a schematic view of the entire structure of a cabinet air conditioner indoor unit according to embodiment 5 of the present invention;

fig. 18 is a schematic view of the entire configuration of a cabinet air-conditioning indoor unit according to embodiment 6 of the present invention.

In the drawings: 1. a housing; 11. a columnar fuselage; 111. an air inlet; 12. an annular air outlet structure; 121. an inner ring surface; 122. an outer annular surface; 123. a first air outlet; 124. a second air outlet; 125. an arc-shaped air guide structure; 126. a first wind shielding assembly; 127. a second wind blocking assembly; 2. a heat exchanger; 21. a liquid separating member; 22. a connecting pipe; 23. a refrigerant output pipe; 24. a fin; 3. a water pan; 31. an annular disc; 32. a disc; 33. a drainage tube; 4. an air supply fan; 5. a humidifying device; 51. a water storage member; 52. an atomizer; 6. a sterilization purification module; 61. a HEPA filter layer; 62. a cold catalyst filter layer; 63. a negative ion germicidal lamp; 64. an ion converter; 7. a fresh air module; 71. a cylindrical housing; 72. a fresh air fan; 73. a variable speed drive mechanism; 731. a drive motor; 732. a gear set; 733. an electric shifting fork; 8. a base; 9. an air inlet pipe.

Detailed Description

It should be understood by those skilled in the art that these embodiments are only for explaining the technical principle of the present invention, and are not intended to limit the scope of the present invention. And can be adjusted as needed by those skilled in the art to suit particular applications. For example, although the present invention has been described in connection with a cabinet air conditioner indoor unit, in practice, the heat exchanger of the present invention can be configured for use in any air conditioner having similar heat exchange requirements. Similarly, the utility model discloses an indoor air conditioner's water collector also can be applied to in its remaining air inlet air conditioner.

It should be noted that in the description of the present invention, the terms of direction or positional relationship indicated by the terms "upper", "lower", "inner", "outer", etc. are based on the directions or positional relationships shown in the drawings, which are merely for convenience of description, and do not indicate or imply that the device or element must have a specific orientation, be constructed and operated in a specific orientation, and thus, should not be construed as limiting the present invention. Furthermore, the terms "first" and "second" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

Furthermore, it should be noted that, in the description of the present invention, unless otherwise explicitly specified or limited, the terms "connected" and "connected" should be interpreted broadly, and may be, for example, fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meaning of the above terms in the present invention can be understood by those skilled in the art according to specific situations.

Example 1: as shown in fig. 2 and fig. 3 (fig. 3 is a schematic view of a forward structure of the heat exchanger after vertical cutting), the heat exchanger 2 of the present invention includes a liquid separating member 21, a refrigerant output pipe 23, a coil pipe and fins 24. Wherein, the liquid separation member 21 and the refrigerant output pipe 23 are arranged up and down. The liquid separating component 21 is communicated with a refrigerant input pipeline of the air conditioner, and the refrigerant output pipe 23 is communicated with a refrigerant output pipe 23 of the air conditioner. The coil comprises a plurality of sections of connecting pipes 22, and two ends of each section of connecting pipe 22 are respectively communicated to the liquid separating member 21 and the refrigerant output pipe 23, so that a plurality of refrigerant flowing branches are formed between the liquid separating member 21 and the refrigerant output pipe 23, and the refrigerant flowing into the branches can realize heat exchange with the air flow in the air conditioner. The fins 24 are disposed on the plurality of sections of connecting pipes 22 so as to conduct heat or cold of the refrigerant of each section of connecting pipe 22, thereby increasing the heat exchange area of the heat exchanger 2. Further, the shape of refrigerant output tube 23 is nonlinear, and the multistage connecting tubes 22 are arranged by separating member 21 to refrigerant output tube 23 in an outward diffusion manner, so that the multistage connecting tubes 22 can be dispersedly arranged between refrigerant output tube 23 and separating member 21, the distribution space of connecting tubes 22 is increased, and the air flow and connecting tubes 22 can be contacted and exchanged heat more uniformly.

In the above embodiment, the vertical arrangement of the liquid separation member 21 and the refrigerant outlet pipe 23 is in terms of the airflow direction, and the vertical arrangement specifically refers to the upstream and downstream arrangement in the airflow direction. For example, when the air flow vertically flows through the heat exchanger 2 to the air outlet in the air conditioner, the vertical arrangement of the liquid separation member 21 and the refrigerant output pipe 23 is an upper-lower arrangement mode; when the air flow flows through the heat exchanger 2 to the air outlet position along the vertical and left-inclined upward direction in the air conditioner, the vertical arrangement of the liquid separating member 21 and the refrigerant output pipe 23 is an upper-left-right-lower arrangement mode. The plurality of connecting pipes 22 are extended outward from the liquid separating member 21 to the refrigerant outlet pipe 23, specifically, the plurality of connecting pipes 22 are extended outward away from the liquid separating member 21 and connected to the refrigerant outlet pipe 23 during the process of extending from the liquid separating member 21 to the refrigerant outlet pipe 23. In this case, the non-linear arrangement of the refrigerant output pipe 23 is combined, so that the overall frame of the heat exchanger 2 constructed by the coil pipes and the refrigerant output pipe 23 has a spatial shape, and the dispersive arrangement effect of the multiple sections of the connecting pipes 22 is further improved.

Preferably, the refrigerant outlet pipe 23 has an arc shape or a circular shape. The plurality of connecting pipes 22 are straight pipes. The input ends of the multiple straight pipes are distributed on the liquid-separating member 21 in a circular distribution (including a circumferential distribution or a partial circumferential, i.e., circular arc distribution).

When the refrigerant outlet pipe 23 is arc-shaped, the frame of the heat exchanger 2 is substantially fan-shaped with a curved surface. Is suitable for being installed in an air conditioner shell 1 with a small radial size, such as a rectangular shell 1. Compared with the common heat exchanger 2, the diffused curved fan-shaped heat exchanger 2 has a larger heat exchange area, better heat exchange positions (namely the positions of the connecting pipes 22) are dispersed, and the heat exchange uniformity and the heat exchange effect are better.

When the refrigerant outlet pipe 23 is circular, the frame of the heat exchanger 2 is substantially funnel-shaped, and is suitable for being installed in the cylindrical shell 71 of the air conditioner, such as the prismatic shell 71 and the cylindrical shell 71 1, so as to maximize the heat exchange area. The transposition positions are distributed circumferentially, the dispersion effect is better, and the overall heat exchange performance is greatly optimized.

Of course, the shape of the refrigerant outlet pipe 23 is not limited to arc or circle, and the shape of the connecting pipe 22 is not limited to visual. For example, the refrigerant outlet pipe 23 may have a spiral shape, and the connection pipe 22 may have an arc shape protruding outward. The shape of any one of the refrigerant outlet pipe 23 and the connecting pipe 22 can be improved according to the installation space of the air conditioner casing, the heat exchange requirement of the air conditioner and other factors as long as the flow of the refrigerant in the heat exchanger 2 is not influenced and the heat exchange performance of the heat exchanger 2 is ensured.

In a preferred embodiment, the liquid separating member 21 includes a spherical liquid separating chamber, and a refrigerant inlet and a plurality of refrigerant outlets provided on the spherical liquid separating chamber. The refrigerant output ports are connected with the connecting pipes 22 in a one-to-one correspondence manner, so that the refrigerant can rotationally flow in the spherical liquid separating cavity and be divided into a plurality of strands to enter each connecting pipe 22 after entering the spherical liquid separating cavity through the refrigerant input pipeline of the air conditioner.

Furthermore, a plurality of refrigerant delivery outlets are uniformly distributed along the circumferential direction of the middle part of the outer side of the spherical liquid separating cavity, so that the refrigerant in the spherical liquid separating cavity can be divided into more uniform multi-strand refrigerant in the rotating process to flow into each branch. In actual installation, in order to make the refrigerant flow in the branch of each connection pipe 22 smoother, as an example, one end of the connection pipe 22 close to the spherical liquid-dividing chamber is provided with a radian. This setting both had been convenient for connecting pipe 22 and the middle part butt joint intercommunication of spherical minute liquid chamber, made the refrigerant input section of connecting pipe 22 become curved transition pipeline section again, had guaranteed the smoothness nature when refrigerant after dividing the liquid gets into connecting pipe 22.

In a preferred embodiment, each fin 24 is an annular fin. A plurality of ring-shaped fins are respectively connected to the connection pipes 22 and cover the connection pipes 22 in a sequentially abutting manner. That is, each ring fin has a plurality of connection positions equal to the number of the connection pipes 22, and each connection pipe 22 is connected to one ring fin through one connection position. The annular fins are connected to the connecting pipes 22 in turn in the above-described connection manner and abut against each other in turn so as to cover the diverging straight connecting pipes 22 to form a conical cylinder surrounded by a fan-shaped annular curved surface. Through the setting, the heat exchange area of the heat exchanger 2 is increased, so that the heat exchanger 2 is provided with a gentle heat exchange surface, the airflow can smoothly flow along the surface of the fin 24 of the heat exchanger 2, and the heat exchange effect of each airflow part is more uniform, and the overall heat exchange uniformity of the airflow is better. Of course, the fins 24 may also be provided in other shapes, such as regular polygonal fins, without affecting the flow of the airflow.

When the annular fins and the straight pipe with the transition pipe section are arranged simultaneously, the annular fins are not connected with the arc-shaped transition pipe section of the straight pipe exemplarily, so that air flow can penetrate through gaps between heat exchange surfaces formed by the spherical liquid distribution cavity and the fins 24, the inner side and the outer side of the fins 24 of the heat exchanger 2 can be surrounded by the air flow for heat exchange, and the heat exchange efficiency is high.

In a preferred embodiment, the heat exchanger 2 of the present invention comprises the above-mentioned liquid separating member 21 with a spherical liquid separating chamber, the circular refrigerant output pipe 23 and the coil pipe comprising multiple straight pipes, so as to form the funnel-shaped heat exchanger 2 with a conical heat exchanging curved surface.

As shown in fig. 1, 2 and 3, the present invention also provides a cabinet air conditioner indoor unit for the heat exchanger 2. The cabinet air-conditioning indoor unit comprises a casing 1. The housing 1 is provided with an air inlet 111 and a first air outlet 123. Any of the heat exchangers 2 described above is disposed within the housing 1. The cabinet air-conditioner indoor unit also comprises a water pan 3 and an air supply fan 4 which are arranged in the shell 1. Wherein, the water pan 3 is positioned below the heat exchanger 2 so as to receive liquid drops dropping from the heat exchanger 2. The air supply fan 4 is arranged between the heat exchanger 2 and the first air outlet 123, so that airflow exchanging heat with the heat exchanger 2 is promoted to flow into a room through the first air outlet 123, new airflow is promoted to enter the shell 1, and the air outlet effect of the cabinet air conditioner indoor unit is guaranteed.

Preferably, the cabinet air-conditioning indoor unit casing 1 has an overall shape similar to a cylinder, and the heat exchanger 2 is the above-mentioned funnel-shaped heat exchanger 2. Specifically, the casing 1 includes a cylindrical body 11 and an annular air outlet structure 12 disposed at the top of the cylindrical body 11. The water pan 3, the heat exchanger 2 and the air supply fan 4 are arranged in the columnar machine body 11 from bottom to top in sequence. The air inlet 111 is disposed at the bottom of the columnar body 11 and below the water pan 3, and the first air outlet 123 is formed on the annular air outlet structure 12. After entering the columnar body 11 through the air inlet 111, the airflow flows to the heat exchanger 2 through the water pan 3 and exchanges heat with the heat exchanger 2, and then flows out to the indoor through the first air outlet 123 under the guidance of the air supply fan 4.

As shown in fig. 1, 4 and 5, in order to optimize the heat exchange performance of the cabinet air conditioner indoor unit, the maximum radial dimension of the heat exchanger 2, i.e. the difference between the radial dimension of the circular refrigerant output pipe 23 above the funnel-shaped heat exchanger 2 and the inner diameter dimension of the columnar body 11, is set as small as possible, so as to make the heat exchange area of the heat exchanger 2 large enough. In this case, when the heat exchanger 2 is installed in the cylindrical body 11, the drip receiving area of the drip tray 3 covers almost the entire cross section of the cylindrical body 11. In this case, in order to allow the water pan 3 to allow airflow to pass through and achieve bottom air intake of the cabinet air conditioner indoor unit, preferably, the water pan 3 includes a first water receiving structure, a second water receiving structure, and a drainage tube 33 disposed between the first water receiving structure and the second water receiving structure. The first water receiving structure and the second water receiving structure are vertically arranged up and down so as to form air allowing air flow to pass through between the first water receiving structure and the second water receiving structure. The drainage tube 33 communicates the water receiving area between the first water receiving structure and the second water receiving structure so as to facilitate the uniform treatment of the wastewater in the water receiving tray 3. For example, the lower one of the first water receiving structure and the second water receiving structure is communicated with a drain pipe of the cabinet air conditioner indoor unit so as to discharge water in the water receiving tray 3 to the outside of the casing 1.

In a preferred embodiment, as shown in fig. 4, the first water receiving structure is a disk 32 with the disk 32 located above, and the second water receiving structure is a ring 31 with the ring 31 located below. Fig. 4 is a front view of the water pan 3 after vertical cutting, wherein the section on the upper side is the section of the disk 32, and two symmetrical sections on the lower side are the sections of the ring-shaped disk 31. The circular disc 32 and the annular disc 31 are coaxially arranged, and the circular disc 32 and the annular disc 31 are arranged in a staggered mode on the side close to each other, so that a uniform circular ring-shaped air passing structure is formed between the circular disc 32 and the annular disc 31, meanwhile, the water receiving areas of each other can be overlapped, and the water receiving effect of the water receiving disc 3 is not affected. The arrangement of the annular air passing structure enables most of air flow to pass through the water pan 3 and flow to the position of the heat exchanger 2 and surround the circumferential heat exchange surface of the heat exchanger 2, and the air passing effect is good.

In a preferred embodiment, as shown in fig. 5, the first water receiving structure is a disk 32 with the disk 32 located below, and the second water receiving structure is a ring 31 with the ring 31 located above. Fig. 5 is a front view of the water pan 3 after vertical cutting, wherein two sections shown at the upper side are sections of the annular plate 31, and a section shown at the lower side is a section of the disk 32. The circular disks 32 and the annular disks 31 are coaxially arranged and the sides of the circular disks 32 and the annular disks 31 adjacent to each other are staggered.

In the above embodiment, when the first water receiving structure and the second water receiving structure are the disk 32 and the annular disk 31, respectively, the coaxiality of the two structures can be changed, so long as the disk 32 and the annular disk 31 form a complete water receiving area and do not leak the drip of the heat exchanger 2 when the two structures are not coaxially arranged. In addition, when the annular air passing structure does not need to be arranged, the first water receiving structure and the second water receiving structure can also be water receiving structures with other shapes, for example, two semicircular structures which are arranged up and down and are arranged oppositely, and straight side sides of the two semicircular water receiving structures which are close to each other are arranged in a staggered mode.

Fig. 6 and 7 are plan views of the annular air outlet structure 12 in fig. 1, which are cut along the transverse direction, and as shown in fig. 1, 6 and 7, the arrangement scheme of the annular air outlet structure 12 is as follows: the annular outlet structure 12 includes an inner annular surface 121 and an outer annular surface 122. The outer ring surface 122 is sleeved outside the inner ring surface 121 and surrounds the inner ring surface 121 to form an air outlet cavity, a ventilation structure is arranged at the bottom of the outer ring surface 122, and the columnar body 11 is communicated to the air outlet cavity through the ventilation structure. The outer annular surface 122 and the inner annular surface 121 each include a first end and a second end, and one of the first end and the second end is a front end of the outer annular surface 122 and the inner annular surface 121, and the other end is a rear end, according to the orientation of fig. 1. Taking the first end as the front end and the second end as the rear end as an example, the first air outlet 123 is formed by the front ends of the outer annular surface 122 and the inner annular surface 121, and the outer annular surface 122 is connected to the rear end of the inner annular surface 121 to be closed. In this case, the airflow exchanges heat with the heat exchanger 2 and then flows through the ventilation structure, the air outlet chamber, and the first air outlet 123 to reach the indoor.

Furthermore, the outer annular surface 122 is further provided with a second air outlet 124, and the cabinet air conditioner indoor unit further includes a first wind shielding assembly 126 capable of closing or opening the first air outlet 123 and a second wind shielding assembly 127 capable of closing or opening the second air outlet 124. Through the arrangement, air can be ejected out from the first air outlet 123 at the front side of the annular air outlet structure 12 or the second air outlet 124 at the side part (left side and/or right side and/or upper side and/or lower side) under the control of the first wind shielding assembly 126 and the second wind shielding assembly 127, so that the cabinet air conditioner indoor unit can realize front direct air blowing and side diffusion type air outlet, and a user can have various air outlet experiences. Fig. 6 shows a situation of air outlet from the first air outlet 123 of the annular air outlet structure 12, fig. 7 shows a situation of air outlet from the second air outlet 124 of the annular air outlet structure 12, and schematic structures of the first wind shielding assembly 126 and the second wind shielding assembly 127 in fig. 6 and fig. 7 indicate open and closed states of the first air outlet 123 and the second air outlet 124 except for different air outlet situations.

As an example, the second outlet 124 includes a plurality of strip-shaped outlet holes uniformly distributed along the front edge of the outer annular surface 122, and the plurality of strip-shaped outlet holes integrally form a strip-shaped outlet extending almost on the whole side of the annular outlet structure 12, so that the airflow blown out by the second outlet 124 can be diffused and ejected from the upper, lower, left and right sides of the annular outlet structure 12.

Further, the annular air outlet structure 12 further includes two arc-shaped air guiding structures 125 respectively disposed at the first air outlet 123 and the second air outlet 124. As shown in fig. 6 or 7, the arc-shaped air guiding structures 125 are protruded toward a side away from the outer annular surface 122, one of the arc-shaped air guiding structures 125 and the inner wall of the first inner annular surface 121 jointly form a diffusion-shaped air duct communicated with the first air outlet 123, the other one of the arc-shaped air guiding structures 125 and the arc-shaped surface of the arc-shaped air guiding structure 125 jointly form a diffusion-shaped air duct communicated with the first air outlet 123, and the two diffusion-shaped air ducts gradually converge the air flow space communicated with the first air outlet 123 and the second air outlet 124, so that the air flow can increase the flow rate through the converging type reducing arrangement of the two diffusion-shaped air ducts when flowing through the first air outlet 123 and the second air outlet 124, and the air outlet effect of the annular air outlet structure 12 is.

In the above embodiment, the arrangement of the first wind shielding member 126 and the second wind shielding member 127 is not limited as long as the first wind shielding member 126 and the wind shielding member are implemented in a manner that can effectively implement the opening and closing control of the first outlet 123 and the second outlet 124. For example, the first wind shielding assembly 126 and/or the second wind shielding assembly 127 may be implemented in a form of controlling an annular retaining ring by a linear motor, and the linear motor drives the annular retaining ring to move back and forth in the wind outlet cavity, so as to control the opening and closing of the first wind outlet 123 and/or the second wind outlet 124; or the linear motor can be replaced by a combination of a rotary motor, a gear rack, a chain and the like. For another example, the first wind shielding assembly 126 and/or the second wind shielding assembly 127 may be configured to control the opening and closing of the second wind outlet 124 through an electromagnetic absorption manner, that is, the retainer ring is made of a metal material, an electromagnetic coil is disposed in the wind outlet cavity, an elastic member is disposed between the retainer ring and the inner annular surface 121 or the outer annular surface 122, when the electromagnetic coil is powered on, the magnetic force generated by the electromagnetic coil attracts the retainer ring, and the elastic member stores elastic potential energy, so as to open the first wind outlet 123 or the second wind outlet 124; when the electromagnetic coil is powered off, the retainer ring returns to the initial position under the action of the elastic piece to close the first air outlet 123 or the second air outlet 124. For another example, one of the first wind shielding assembly 126 and the second wind shielding assembly 127 may be omitted, and selective opening of any one of the first wind outlet 123 and the second wind outlet 124 may be achieved only by controlling the movement of the one wind shielding assembly.

Furthermore, the cabinet air-conditioner indoor unit of the present invention further comprises a base 8 connected to the casing 1, and the casing 1 and its internal components are supported to the ground through the base 8.

Illustratively, the air supply fan 4 is driven by a digital turbine motor (or called digital motor or digital motor), which is a motor with high rotation speed and strong suction force, and the maximum rotation speed of the motor is close to 11 ten thousand revolutions per minute, which is 4-5 times of the rotation speed of the motor of a common fan.

Example 2: as shown in fig. 8, the cabinet type air conditioning indoor unit of the present invention is any one of the air conditioning indoor units described in embodiment 1, and the heat exchanger 2 of the air conditioning indoor unit is any one of the heat exchangers 2 described in embodiment 1. On this basis, this cabinet air-conditioning indoor unit still includes humidification device 5, so that make the utility model discloses a cabinet air-conditioning indoor unit possesses the humidification function, can also increase the humidity of room air when adjusting indoor temperature.

Preferably, the heat exchanger 2 of the cabinet air-conditioning indoor unit is a funnel-shaped heat exchanger 2 in embodiment 1. According to the flow path of the air flow, the water receiving tray 3, the funnel-shaped heat exchanger 2, the air supply fan 4 and the humidifying device 5 are sequentially arranged. The structures of the water pan 3, the heat exchanger 2 and the like are not repeated in the embodiment.

Further, the humidifying device 5 includes a water storage member 51 disposed on the indoor unit of the packaged air conditioner and an atomizer 52 disposed in the water storage member 51, wherein the water storage member 51 is disposed on the top of the columnar body 11, so that the atomized water vapor can rapidly flow into the indoor air through the airflow blown out by the first air outlet 123 or the second air outlet 124. The atomizer 52 may be any device having an atomizing function, such as an ultrasonic atomizer 52, an air compression atomizer 52, or the like.

Further, the water storage member 51 is disposed at the top outer side of the cylindrical body 11 to prevent the water mist from liquefying in the cylindrical body 11 of the housing 1 to form liquid droplets or liquid flow inside the cylindrical body 11. As an example, the water storage member 51 is disposed at the bottom of the inner annular surface 121 of the annular outlet structure 12, so that the water mist can be closer to the first air outlet 123, and the diffusion efficiency of the water mist is improved by the first air outlet 123.

As an example, the water storage member 51 is disposed on a side of the inner annular surface 121 away from the outer annular surface 122. The water storage member 51 may be detachably connected to the inner annular surface 121 by means of clamping, inserting, screwing, or the like, or may be integrally disposed with the inner annular surface 121 by means of integral molding, welding, bonding, or the like.

In the above embodiment, it can be understood by those skilled in the art that the installation position of the humidifying device 5 on the housing 1 is not limited, the above preferred examples do not limit the present invention, and those skilled in the art can modify the installation position and installation manner of the humidifying device 5 according to the actual water mist spraying requirement, and accordingly, the structure and shape of the water storage member 51 of the humidifying device 5 can be adapted according to the change of the installation position. The above-mentioned structural forms and the variations of the arrangement positions do not go beyond the principle and the scope of protection of the present invention.

Example 3: as shown in fig. 9, the cabinet type air conditioning indoor unit of the present invention is any one of the air conditioning indoor units described in embodiment 1, and the heat exchanger 2 of the air conditioning indoor unit is any one of the heat exchangers 2 described in embodiment 1. On the basis, the cabinet air-conditioning indoor unit further comprises a sterilization and purification module 6 arranged in the shell 1. Particularly, the above-mentioned disinfection purification specifically means that exterminates the processing and filters purification to impurity such as bacterium in the air current and dust to reduce the utility model discloses a cabinet air conditioner indoor set spun air current air contaminant's such as bacterium, dust carrying capacity for cabinet air conditioner indoor set can improve indoor air quality when adjusting indoor temperature.

In a preferred embodiment, the heat exchanger 2 of the cabinet air-conditioning indoor unit is the funnel-shaped heat exchanger 2 of example 1. According to the flow path of the air flow, a sterilization and purification module 6, the water receiving tray 3, the funnel-shaped heat exchanger 2 and the air supply fan 4 are sequentially arranged. The structures of the water pan 3, the heat exchanger 2 and the like are not repeated in the embodiment. That is, in the present embodiment, the sterilization/purification module 6 is provided at the bottom of the housing 1, and the sterilization/purification module 6 is specifically located upstream of the air inlet 111 and downstream of the drain pan 3 with respect to the flow path of the air flow. The arrangement of the positions enables air flow to be sterilized and purified by the sterilization and purification module 6 after entering the shell 1 through the air inlet 111, and enables the air flow flowing through the water pan 3, the heat exchanger 2 and the air supply fan 4 to be purified air flow, so that the dust falling condition on the water pan 3, the heat exchanger 2 and the air supply fan 4 is improved to a certain extent, the cleaning period of the indoor unit of the cabinet air conditioner is prolonged, and secondary pollution caused when the purified air flow flows through the water pan 3 with larger dust, the heat exchanger 2 and other positions can be avoided.

As shown in fig. 10 and 11, the sterilizing and purifying module 6 is shaped like a pie and includes a HEPA filter layer 61, a cold catalyst filter layer 62, an anion sterilizing lamp 63 and an ion converter 64, wherein the cold catalyst filter layer 62 is located at the top of the pie, the HEPA filter layer 61 is located at the bottom of the pie, the ion converter 64 is located at the center of the pie, and the anion sterilizing lamp 63 is provided with a plurality of rings and surrounds the side of the ion converter 64. Among them, the HEPA filter 61 is a sheet-like filter made of a laminated borosilicate microfiber. The filter layer comprises three layers (a primary filter layer, a charge layer and an electrostatic dust collection layer), and the removal efficiency of particles with the diameter of less than 0.3 micron can reach more than 99.97 percent. The cold catalyst filter layer 62 can perform catalytic reaction at normal temperature, decompose various harmful and odorous gases into harmless and odorless substances at normal temperature and normal pressure, convert simple physical adsorption into chemical adsorption, decompose while adsorbing, remove harmful gases such as formaldehyde, benzene, xylene, toluene, TVOC and the like, and generate water and carbon dioxide. In the catalytic reaction process, the cold catalyst does not directly participate in the reaction, and the cold catalyst is not changed and lost after the reaction and plays a role for a long time. The cold catalyst is non-toxic, non-corrosive and non-combustible, the reaction product is water and carbon dioxide, no secondary pollution is generated, and the service life of the adsorption material is greatly prolonged. The ion converter 64 can generate a large amount of negative ions in a power-on state, and researches show that the air contains a proper amount of negative ions, so that the air can efficiently remove dust, sterilize and purify air, and simultaneously can activate oxygen molecules in the air to form oxygen-carrying negative ions, activate air molecules, improve the lung function of a human body, promote metabolism, enhance disease resistance, regulate a central nervous system, enable the human body to be refreshed and full of vitality and the like. The negative ion sterilization reflector lamp annularly surrounds the side surface of the ion converter 64, can irradiate and sterilize the air passing through the sterilization and purification module 6, and can achieve the effects of wide irradiation range and no sterilization dead angle due to the arrangement mode of surrounding the ion converter 64.

It should be noted that although the above embodiment is described in conjunction with the sterilization and purification module 6 including the HEPA filter layer 61, the cold catalyst filter layer 62, the negative ion sterilization lamp 63 and the ion converter 64, one or more of them may be selected by those skilled in the art for a specific application scenario as the sterilization and purification module 6 after being recombined to be installed in the indoor unit of the cabinet air conditioner, and the combination does not depart from the principle of the present application, and therefore, the present application shall fall within the protection scope.

Example 4: as shown in fig. 12, the cabinet type air conditioning indoor unit of the present invention is any one of the air conditioning indoor units described in embodiment 1, and the heat exchanger 2 of the air conditioning indoor unit is any one of the heat exchangers 2 described in embodiment 1. On the basis, the cabinet air conditioner indoor unit further comprises a fresh air module 7. Specifically, the fresh air module 7 is disposed below the housing 1 and connected to the housing 1. The fresh air module 7 is provided with an air suction opening and an air outlet, the air suction opening is communicated with the outside through a pipeline, and the air outlet is communicated with the air inlet 111.

Through the setting, make the utility model discloses an indoor machine of cabinet air conditioner can introduce the indoor air inlet that realizes the indoor machine of cabinet air conditioner with outdoor air to realized indoor and outdoor air exchange, improved the poor, the big condition of air turbidity of indoor circulation condition, promoted indoor air quality.

As shown in fig. 13, in a preferred embodiment, the fresh air module 7 includes a cylindrical housing 71, and a fresh air fan 72 and a variable speed driving mechanism 73 disposed in the cylindrical housing 71, wherein the variable speed driving mechanism 73 is connected to the fresh air fan 72 so as to drive the fresh air fan 72 to rotate. Through the arrangement, the fresh air fan 72 can realize the adjustment of different rotating speeds under the driving of the variable speed driving mechanism 73 so as to adjust the air inlet wind power of the cabinet type air conditioner indoor unit and change the air inlet gear of the cabinet type air conditioner indoor unit.

Further, the shift drive mechanism 73 includes a drive motor 731 and a plurality of gear sets 732 having different gear ratios. The driving wheels of the plurality of gear sets 732 are fixedly connected to the output shaft of the driving motor 731, and the driven wheels of the plurality of gear sets 732 are fixedly connected to the rotation shaft of the fresh air fan 72. By changing the meshing condition of the different gear sets 732, the gear ratio of the gear transmission of the variable speed driving mechanism 73 is changed, and the final driving rotation of the fresh air fan 72 which is in power connection with the driving motor 731 through the gear sets 732 is changed. As an example, the meshing of the different gear sets 732 is changed by an electric fork 733. In the structure diagram of the fresh air module 7 shown in fig. 13, an electric fork 733 is mounted on one of the driving wheels, so that the engagement of the different gear sets 732 is realized by adjusting the extension length of the fork. Of course, in addition to the electric fork 733, the switching manner between the different gear sets 732 may be replaced by any other manner by those skilled in the art as long as the gear sets 732 can be switched smoothly. For example, the meshing of the different gear sets 732 can be realized by using two electric push rods to respectively push the driving gears to move from two directions. Further, the rotation speed of the fresh air fan 72 can be adjusted in other manners, such as by using a servo motor with adjustable rotation speed to drive the fresh air fan 72 to rotate through the gear set 732.

Referring to fig. 14-16, the indoor unit of the cabinet air conditioner of the present invention has three different air intake modes. As shown in fig. 14, in the first air intake mode, the air supply fan 4 operates normally, the fresh air fan 72 operates at a lower speed than the air supply fan 4, and at this time, the air entering the casing 1 is divided into two parts, one part is from the fresh air module 7, and the other part is from the indoor air.

As shown in fig. 15, in the second air intake mode, the air supply fan 4 operates normally, the fresh air fan 72 operates at a rotation speed substantially equal to that of the air supply fan 4, the air flow entering the casing 1 at this time is all outdoor fresh air, and the air supply mode can introduce the fresh air and perform heat exchange treatment on the fresh air to reduce fluctuation of indoor temperature.

As shown in fig. 16, in the third air intake mode, the air supply fan 4 operates normally, the fresh air fan 72 operates at a higher speed than the air supply fan 4, and at this time, a part of the outdoor fresh air enters the casing 1 to participate in heat exchange, and the other part of the outdoor fresh air is sent into the room from the gap between the casing 1 and the fresh air module 7.

Since the fresh air module 7 is communicated with the outside of the cabinet air-conditioning indoor unit through the air inlet pipe 9 of the cabinet air-conditioning indoor unit, in order to improve the placing convenience of the cabinet air-conditioning indoor unit and avoid the improvement of the requirement of the cabinet air-conditioning indoor unit on the placing environment caused by the connection of the fresh air module 7 and the air inlet pipe 9, preferably, the fresh air module 7 is arranged between the shell 1 and the base 8 and is respectively and rotatably connected with the shell 1 and the base 8, so that when a user places the cabinet air-conditioning indoor unit, the orientation of the air inlet pipe 9 can be changed in a manner of only rotating the fresh air module 7, the extending direction of the air inlet pipe 9, the orientation of the annular air outlet structure 12 and the placing position of the base 8 are prevented from being difficult. By way of example, the fresh air module 7 is rotatably connected to the housing 1 and the base 8 respectively through bearings (not shown in the figure). For example, the outer ring of the bearing is fixedly connected with the fresh air module 7, and the top of the base 8 is provided with a cylindrical insertion column matched with the shape of the inner ring of the bearing, so that the base 8 can rotate relative to the fresh air module 7 after being inserted into the inner ring of the bearing through the insertion column.

More preferably, form the clearance between casing 1 and the new trend module 7, the air exit sets up in the top of new trend module 7, and air intake 111 sets up in the bottom of casing 1 to increase air intake area of air intake 111, make air exit and air intake 111 butt joint, and then prevent that the outdoor air current of the heat transfer of not introducing of new trend module 7 from a large amount of effluviums to indoor, change indoor temperature environment.

Example 5: as shown in fig. 17, the cabinet type air conditioning indoor unit of the present invention is any one of the air conditioning indoor units described in embodiment 1, and the heat exchanger 2 of the air conditioning indoor unit is any one of the heat exchangers 2 described in embodiment 1. On this basis, this cabinet air conditioning indoor set still includes the purification module 6 and the new trend module 7 of disinfecting that set up in casing 1, and wherein, the purification module 6 and the new trend module 7 of disinfecting are any kind of implementation structure of above-mentioned respectively, no longer give unnecessary details to the specific implementation of heat exchanger 2, the purification module 6 and the new trend module 7 of disinfecting here.

Through the arrangement, outdoor airflow sequentially flows through the air inlet pipe 9, the fresh air module 7, the air inlet 111, the sterilization and purification module 6, the heat exchanger 2 and the first air outlet 123/the second air outlet 124 and then enters the room. That is to say, the cabinet air conditioner indoor unit can introduce outdoor fresh air and can sterilize and purify at least one part of the introduced outdoor fresh air. Even make new trend module 7 introduce outdoor air current when outdoor air circumstance is relatively poor, the user also can make outdoor air current all disinfect under the mode correspondingly and purify after the heat transfer again and flow into indoor to avoid air contaminant such as dust, haze in the outdoor air to get into indoor, pollute indoor air circumstance, prevent to introduce new pollutant to indoor when realizing indoor, outer air current exchange.

Example 6: as shown in fig. 18, the cabinet type air conditioning indoor unit of the present invention is any of the air conditioning indoor units described in embodiment 1, and the heat exchanger 2 of the air conditioning indoor unit is any of the heat exchangers 2 described in embodiment 1. On this basis, this cabinet air conditioning indoor unit still includes the purification module 6 that disinfects, humidification device 5 and the new trend module 7 that set up in casing 1, and wherein, the purification module 6 that disinfects, humidification device 5 and new trend module 7 are any kind of above-mentioned implementation structure respectively, no longer gives details to the specific implementation mode of heat exchanger 2, the purification module 6 that disinfects, humidification device 5 and new trend module 7 here. Through the arrangement, the cabinet air conditioner indoor unit has the functions of improving the indoor air humidity, realizing the exchange of indoor and outdoor air, reducing the content of indoor air bacteria and pollutants and the like, greatly improves the indoor air environment, and improves the user experience.

It should be noted that, although the cabinet air conditioner indoor units in embodiments 1 to 6 are described by combining the casing 1 with different structural combinations of the humidifying device 5, the sterilization and purification module 6, the fresh air module 7, the water receiving tray 3, the heat exchanger 2, the air supply fan 4 and the base 8, the structural combinations described above should not limit the scope of the present invention. As will be understood by those skilled in the art, the structures in any of the above-mentioned combinations can be properly deleted or added to combine a new embodiment, while ensuring the normal operation of the cabinet air conditioner indoor unit. For example, the cabinet air-conditioning indoor unit can include a humidifying device 5 and a sterilization and purification module 6 in addition to the basic structures of the heat exchanger 2, the water pan 3, the air supply fan 4 and the like, so that a new structural combination of the cabinet air-conditioning indoor unit is combined.

It will be appreciated by those of skill in the art that although some embodiments described herein include some but not other features included in other embodiments, combinations of features of different embodiments are meant to be within the scope of the invention and form different embodiments. For example, in the claims of the present invention, any of the claimed embodiments may be used in any combination.

So far, the technical solution of the present invention has been described with reference to the preferred embodiments shown in the drawings, but it is easily understood by those skilled in the art that the scope of the present invention is obviously not limited to these specific embodiments. Without departing from the principle of the present invention, a person skilled in the art can make equivalent changes or substitutions to the related technical features, and the technical solutions after these changes or substitutions will fall within the protection scope of the present invention.

Claims (10)

1. A heat exchanger of an indoor unit of an air conditioner is characterized by comprising a liquid separating component, a refrigerant output pipe, a coil pipe and fins, wherein the liquid separating component and the refrigerant output pipe are arranged up and down, the coil pipe comprises a plurality of sections of connecting pipes, two ends of each section of connecting pipe are respectively communicated with the liquid separating component and the refrigerant output pipe, the fins are arranged on the plurality of sections of connecting pipes,

the refrigerant output pipe is nonlinear in shape, and the plurality of sections of connecting pipes are arranged from the liquid separating component to the refrigerant output pipe in an outward diffusion mode.

2. The heat exchanger of claim 1, wherein the refrigerant outlet tube is arcuate or circular in shape.

3. The heat exchanger of claim 2, wherein the plurality of segments of connecting tubes are straight tubes, and the input ends of the plurality of segments of straight tubes are distributed on the liquid separating member in a circular distribution manner.

4. The heat exchanger according to claim 1, wherein the liquid dividing member comprises a spherical liquid dividing cavity, and a refrigerant input port and a plurality of refrigerant output ports which are arranged on the spherical liquid dividing cavity, and the refrigerant output ports are connected with the connecting pipes in a one-to-one correspondence manner.

5. The heat exchanger as claimed in claim 4, wherein the plurality of refrigerant outlet ports are uniformly distributed along a circumferential direction of an outer middle portion of the spherical liquid-dividing chamber.

6. The heat exchanger according to claim 1, wherein the number of the fins is plural, each of the fins is an annular fin, and the plural annular fins are respectively connected to the connecting pipe and cover the connecting pipe in a manner of abutting against one another in sequence.

7. An indoor unit of an air conditioner is characterized by comprising a shell, and a heat exchanger and a water pan which are arranged in the shell, wherein the water pan is positioned below the heat exchanger, and the heat exchanger is the heat exchanger in any one of claims 1 to 6.

8. The indoor unit of claim 7, wherein the water pan comprises a first water receiving structure, a second water receiving structure and a drainage tube arranged between the first water receiving structure and the second water receiving structure, and the first water receiving structure and the second water receiving structure are vertically arranged up and down.

9. An indoor unit of an air conditioner according to claim 8, wherein the first water receiving structure is a circular plate and the circular plate is located above, the second water receiving structure is an annular plate and the annular plate is located below, the circular plate and the annular plate are coaxially arranged, and sides of the circular plate and the annular plate which are close to each other are alternately arranged.

10. An indoor unit of an air conditioner according to claim 8, wherein the first water receiving structure is a circular plate and the circular plate is located below, the second water receiving structure is an annular plate and the annular plate is located above, the circular plate and the annular plate are coaxially arranged, and sides of the circular plate and the annular plate which are close to each other are alternately arranged.

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