CN107747770B - Indoor unit of wall-mounted air conditioner - Google Patents

Abstract

The invention provides a wall-mounted air conditioner indoor unit, which comprises: the shell is provided with an air inlet and an air supply outlet; a heat exchanger; the air injection assembly is arranged in the air supply opening and comprises a first air injection part and a second air injection part which are transversely arranged, wherein the first air injection part and the second air injection part are respectively formed on the inner peripheral wall of the first air injection part and the second air injection part and are respectively used for jetting the air flow in the air injection part forwards and driving the ambient air in an air suction hole defined by the inner peripheral wall of the air injection part to be sent forwards, and the air suction hole is communicated with the surrounding environment at the upstream of the air supply direction; the first air supply assembly is used for generating a first heat exchange air flow which enters from the air inlet and is supplied to the first air injection part after exchanging heat with the heat exchanger, and the second air supply assembly is used for generating a second heat exchange air flow which enters from the air inlet and is supplied to the second air injection part after exchanging heat with the heat exchanger. The scheme increases the air supply quantity and leads the indoor temperature to be wholly and uniformly reduced.

Description

Indoor unit of wall-mounted air conditioner

Technical Field

The invention relates to an air conditioner, in particular to an indoor unit of a wall-mounted air conditioner.

Background

The air conditioner is one of the necessary household appliances, and along with the increasing requirements of users on comfort and health, the air supply mode of the traditional air conditioner is to send cold air indoors, then the cold air is slowly convected with ambient air, the heat exchange speed is slower, people cannot feel cool rapidly, the air supply port of the indoor unit directly blows the people, adverse effects can be brought to the health of the users, and air conditioning diseases are easy to occur.

To this problem, the indoor unit of the spraying air outlet of soft air supply appears in the prior art, and it utilizes less air outlet to drive the surrounding air and blows out for the air after the heat transfer is mixed with the surrounding air and is sent out, however the requirement of spraying air outlet to the structure is higher, makes the spraying air outlet be applied to in the comparatively abundant cabinet indoor unit in space mostly. The hanging type indoor unit using the jet outlet often needs to set the casing to be round or in other irregular shapes in order to meet the structural requirement of the jet outlet, so that on one hand, the hanging type indoor unit has a gap with the use habit of a user and the existing cognition of the hanging type indoor unit, and is not easy to accept by the user; on the other hand, the installation of the hanging type indoor unit is troublesome, so that the hanging type indoor unit using the jet air outlet cannot meet the use requirement of a user.

Disclosure of Invention

The invention aims to provide a wall-mounted air conditioner indoor unit with soft air supply and high heat exchange speed.

A further object of the present invention is to provide a wall-mounted air conditioner indoor unit that is compact and compatible with the use habits of users.

Another further object of the present invention is to make the air supply mode of the indoor unit of the wall-mounted air conditioner flexible, and to meet the adjustment requirements of different requirements.

In particular, the present invention provides a wall-mounted air conditioner indoor unit, comprising: the shell is provided with an air inlet and an air supply outlet, and the air supply outlet is in an oblong shape and is arranged at the lower part of the shell; the heat exchanger is arranged in the shell; the air injection assembly is arranged in the air supply opening and comprises a first air injection part and a second air injection part which are transversely arranged, a first air injection port and a second air injection port are respectively formed in the inner peripheral walls of the first air injection part, the first air injection port is used for injecting air flow in the first air injection part forwards and driving ambient air in a first air suction hole defined by the inner peripheral wall of the first air injection part to be sent forwards, the second air injection port is used for injecting air flow in the second air injection part forwards and driving ambient air in a second air suction hole defined by the inner peripheral wall of the second air injection part to be sent forwards, and the first air suction hole and the second air suction hole are respectively communicated with the surrounding environment at the upstream of the air supply direction; the first air supply assembly and the second air supply assembly are transversely arranged in the shell at intervals, the first air supply assembly is used for generating first heat exchange air flow which enters from the air inlet and is supplied to the first air injection part after exchanging heat with the heat exchanger, and the second air supply assembly is used for generating second heat exchange air flow which enters from the air inlet and is supplied to the second air injection part after exchanging heat with the heat exchanger.

Optionally, the first air injection part and the second air injection part are respectively formed by an annular inner wall and an annular outer wall, the annular outer wall and the annular inner wall of the first air injection part jointly define a first air supply cavity, the edge of the annular outer wall of the first air injection part, which is connected with the annular inner wall, forms a first air injection port, and the end part, far away from the second air injection part, of one side of the first air injection part is provided with a first air inlet communicated with the first air supply assembly, so that the first heat exchange air flow is introduced into the first air supply cavity; the annular outer wall and the annular inner wall of the second air injection part jointly define a second air supply cavity, the edge of the annular outer wall and the annular inner wall of the second air injection part are connected to form a second air injection port, and the end part of one side of the first air injection part far away from the second air injection part is provided with a second air inlet communicated with the second air supply assembly, so that second heat exchange air flow is introduced into the second air supply cavity.

Optionally, the rear side edge of the annular inner wall of the first air injection part is recessed toward the inside of the first air supply cavity, and the position of the annular outer wall of the first air injection part opposite to the rear side edge of the annular inner wall is provided with an outward flanging, so that a gap between the annular outer wall of the first air injection part and the rear side edge of the annular inner wall forms a first air injection port; the rear side edge of the annular inner wall of the second air injection part is recessed towards the inside of the second air supply cavity, and the position, opposite to the rear side edge of the annular inner wall, of the annular outer wall of the second air injection part is provided with an outward flanging, so that a gap between the annular outer wall of the second air injection part and the rear side edge of the annular inner wall forms a second air injection port.

Optionally, the annular inner wall of the first jet section extends forwardly from its rear side edge to form a continuously outwardly expanding first coanda surface; the section of the part of the annular outer wall of the first air injection part, which is positioned at the rear side of the air injection assembly, is spiral, so that the air flow of the first air supply cavity is ejected from the first air injection port along the annular outer wall of the first air injection part, is sent out forwards along the first coanda surface, and drives the ambient air in the first air pumping hole to be pumped out; and the annular inner wall of the second jet section extends forwardly from its rear edge to form a continuously outwardly expanding second coanda surface; and the section of the part of the annular outer wall of the second air injection part, which is positioned at the rear side of the air injection assembly, is spiral, so that the air flow of the second air supply cavity is ejected out of the second air injection port along the annular outer wall of the second air injection part, is sent out forwards along the second coanda surface, and drives the ambient air in the second air pumping hole to be pumped out.

Optionally, the first air supply assembly includes: the first centrifugal fan is used as a power source of first heat exchange airflow, and the first air guide component is connected between an exhaust port and a first air inlet of the first centrifugal fan so as to guide the airflow exhausted by the first centrifugal fan into the first air supply cavity; the second air supply assembly includes: the second centrifugal fan is used as a power source of second heat exchange airflow, and the second air guide component is connected between an exhaust port and a second air inlet of the second centrifugal fan so as to guide the airflow exhausted by the second centrifugal fan into the second air supply cavity.

Optionally, the housing comprises: the housing and the front panel are arranged in front of the housing; the wall-mounted air conditioner indoor unit further comprises a partition board, the partition board is longitudinally arranged above the air injection assembly in the shell, a heat exchanger accommodating cavity is defined between the partition board and the front panel, and the heat exchanger is arranged in the heat exchanger accommodating cavity; and the impellers and the spiral case of the first centrifugal fan and the second centrifugal fan are arranged in the space defined by the partition plate and the housing.

Optionally, a first through hole and a second through hole which are transversely arranged at intervals are arranged in the middle of the partition plate; the air collecting port of the first centrifugal fan penetrates out of the first through hole to suck air from the heat exchanger accommodating cavity, the air outlet of the volute of the first centrifugal fan faces the side wall of the shell on one side of the first air inlet, and the air inlet of the first air guide component is connected with the air outlet of the volute of the first centrifugal fan; the air collecting port of the second centrifugal fan penetrates out of the second through hole to suck air from the heat exchanger accommodating cavity, the air outlet of the volute of the second centrifugal fan faces the side wall of the shell on one side of the second air inlet, and the air inlet of the second air guide component is connected with the air outlet of the volute of the second centrifugal fan.

Optionally, the first wind guiding component includes: the first diversion section is provided with an air inlet of the first air guide component, at least part of the first diversion section is in a spiral shape, and the air flow direction discharged by the first centrifugal fan is guided downwards; the first air supply section is connected with the first drainage section, a first air collection cavity is defined in the first air supply section and used for receiving air flow discharged by the first centrifugal fan, and a first air outlet connected with the first air inlet is formed in the first air supply section so that the air flow of the first air collection cavity is supplied to the first air supply cavity; and the second air guiding member includes: the second diversion section is provided with an air inlet of the second air guide component, at least part of the second diversion section is in a spiral shape, and the air flow direction discharged by the second centrifugal fan is guided downwards; the second air supply section is connected with the second drainage section, and a second air collection cavity is defined in the second air supply section and used for receiving air flow discharged by the second centrifugal fan, and a second air outlet connected with the second air inlet is formed in the second air supply section so that the air flow of the second air collection cavity is supplied to the second air supply cavity.

Optionally, the first drainage section is gradually reduced from the air inlet of the first air guide component along the air flow direction, the first air supply section forms a volute shape along the air outlet direction of the first drainage section, and the wind resistance of the first heat exchange air flow in the first air collection cavity is reduced; the second drainage section gradually tapers from the air inlet of the second air guide component along the air flow direction, the second air supply section forms a volute shape along the air outlet direction of the second drainage section, and the wind resistance of the second heat exchange air flow in the second air collection cavity is reduced.

Alternatively, the casing and the lower portion of the front panel form a front-rear penetrating air supply port, and the rear side of the casing forms the position of the air supply port is recessed forward so that there is an air circulation area behind the air supply port.

The invention relates to a wall-mounted air conditioner indoor unit, which is characterized in that an oblong air supply opening is arranged below a shell and is used for arranging an annular air injection assembly, the air injection assembly comprises a first air injection part and a second air injection part which are independently arranged, and the first air injection assembly and the second air injection assembly are used for supplying air flows which pass through heat exchange of a heat exchanger, so that the air flows after heat exchange are sprayed out from the air injection openings of the first air injection part and the second air injection part, ambient air around the air supply opening is sucked and mixed with heat exchange air with severe ambient temperature difference, the sent air flows are soft, the feeling of blowing to a human body is more comfortable, on one hand, the air supply amount is increased, the flow of indoor air is accelerated, the indoor temperature can be uniformly reduced as a whole, and the air outlet of the wall-mounted air conditioner indoor unit is in an oblong runway shape and is arranged below the shell, has an integral structure which is relatively similar to that of the prior traditional wall-mounted indoor unit, is easy to accept by users, and can easily replace the prior traditional wall-mounted indoor unit, and the installation position is flexible.

Further, the wall-mounted indoor unit provided by the invention has the advantages that the two air supply assemblies respectively provide the air flow after heat exchange to the two air injection parts of the air injection assembly and are finally sprayed out from the air injection port, the two air supply assemblies are mutually matched to supply air together, and the two air supply assemblies can be respectively and independently controlled according to working conditions, for example, the two air supply assemblies can supply air according to the same air quantity at the same time; respectively supplying air according to different air volumes; the air supply is started alternatively, so that the air outlet of the indoor unit meets the requirements of different working conditions, the control is more flexible, and the different requirements of users are met.

Furthermore, the wall-mounted air conditioner indoor unit has compact internal component structure, fully utilizes the space in the shell and can make the wall-mounted air conditioner indoor unit thinner.

Furthermore, the indoor unit of the wall-mounted air conditioner improves the positions and the structures of the heat exchanger, the centrifugal fan, the air guide component and the like, so that the occupied space is reduced, and the air supply wind resistance is reduced.

The above, as well as additional objectives, advantages, and features of the present invention will become apparent to those skilled in the art from the following detailed description of a specific embodiment of the present invention when read in conjunction with the accompanying drawings.

Drawings

Some specific embodiments of the invention will be described in detail hereinafter by way of example and not by way of limitation with reference to the accompanying drawings. The same reference numbers will be used throughout the drawings to refer to the same or like parts or portions. It will be appreciated by those skilled in the art that the drawings are not necessarily drawn to scale. In the accompanying drawings:

fig. 1 is a schematic exterior view of an indoor unit of a wall-mounted air conditioner according to an embodiment of the present invention;

fig. 2 is a schematic exploded view of an indoor unit of a wall-mounted air conditioner according to an embodiment of the present invention;

fig. 3 is a schematic view of an air injection assembly in an indoor unit of a wall-mounted air conditioner according to an embodiment of the present invention;

FIG. 4 is a front view of a first jet section of the jet assembly shown in FIG. 3;

FIG. 5 is a schematic cross-sectional airflow diagram taken along section line A-A in FIG. 4;

fig. 6 is a schematic view of internal components of an indoor unit of a wall-mounted air conditioner according to an embodiment of the present invention; and

fig. 7 is a schematic view illustrating a structure in which a first air supply unit and a second air supply unit supply air to an air injection unit in an indoor unit of a wall-mounted air conditioner according to an embodiment of the present invention.

Detailed Description

In order to facilitate description, the directions of "up", "down", "front", "back", "top", "bottom", etc. mentioned in the description are defined according to the spatial positional relationship of the wall-mounted air conditioner indoor unit 100 in the normal working state, for example, the side of the wall-mounted air conditioner indoor unit 100 facing the user is the front, and the side that is attached to the mounting position is the rear.

Fig. 1 is a schematic exterior view of a wall-mounted air conditioner indoor unit 100 according to one embodiment of the present invention, and fig. 2 is a schematic exploded view of the wall-mounted air conditioner indoor unit 100 according to one embodiment of the present invention. The wall-mounted air conditioner indoor unit 100 may generally include: the air-jet device comprises a shell 110, an air-jet assembly 120, a heat exchanger 140, a first air supply assembly and a second air supply assembly. Wherein the housing 110 may include: a housing 112, and a front panel 114 disposed in front of the housing 112. The housing 112 is formed of a top wall, side walls, and a back, which together define a space for accommodating the internal components, and a front panel 114 is disposed in front of the housing 112, thereby closing the internal space of the housing 112. The housing 110 is provided with an air inlet 116 and an air outlet 117. The air outlet 117 is formed in an oblong shape and is disposed at a lower portion of the housing 110 and communicates with the surrounding environment upstream in the air-supplying direction. The air inlet 116 may be selectively formed at any one or more of the following positions: the front panel 114, the top wall of the housing 112, the side walls of the housing 112. Since the position of the air inlet 116 may affect the direction of the air inlet flow, the air inlet 116 may be configured according to the position and shape of the heat exchanger 140 and the positions of the first air supply assembly and the second air supply assembly, and the air inlet 116 may be formed by providing holes, gratings, etc. on the housing 110.

In some preferred embodiments, the air supply opening 117 may be formed in a lower portion of the housing 110 (the housing 112 and the front panel 114 are respectively formed with an oblong through hole at corresponding positions thereof so as to form the air supply opening 117 extending therethrough, and the rear side of the housing 112 is formed with the air supply opening 117 being recessed forward so as to have an air circulation area 118 behind the air supply opening 117, thereby allowing the interior of the air supply opening 117 to communicate with the air circulation area 118, and the heat exchange gas sprayed from the air spraying assembly 120 can suck ambient air from the air circulation area 118 for mixing, the mixed air flow has a small temperature difference with the surrounding environment, is softer, and has a larger air supply volume, thereby accelerating the flow of indoor air.

In addition, the air injection assembly 120 may be disposed at a position of the lower portion of the housing 110, and the housing 110 has a hollow area at the rear portion of the air injection assembly 120, i.e. at the upstream of the air supply direction, for the heat exchange gas sprayed by the air injection assembly 120 to suck and mix the ambient air through the hollow area.

The heat exchanger 140 is disposed inside the housing 110. The heat exchanger 140 exchanges heat with air flowing therethrough to change the temperature of the air flowing therethrough. The heat exchanger 140 is part of a refrigeration system that may be implemented using a compression refrigeration cycle that uses a refrigerant to transfer heat through a compression phase change cycle of a compressor, condenser, evaporator, and throttling device. The refrigeration system may also be provided with a four-way valve to change the flow direction of the refrigerant, so that the indoor heat exchanger 140 alternately serves as an evaporator or a condenser to realize a refrigeration or heating function. Since the compression refrigeration cycle in an air conditioner is well known to those skilled in the art, the operation principle and construction thereof will not be described herein. The heat exchanger 140 is disposed against the front panel 114 of the housing 110.

The air injection assembly 120 is disposed in the air supply opening 117, the air injection assembly 120 has two first air injection portions 128 and second air injection portions 129 which are transversely arranged, the first air injection portions 128 and the second air injection portions 129 are integrally in a long circular ring shape (or racetrack shape), and can be symmetrically disposed relative to the center of the air injection assembly 120, a first air suction hole 1282 is formed in the center of the first air injection portion 128, and a second air suction hole 1292 is formed in the center of the second air injection portion 129. The first air suction hole 1282 and the second air suction hole 1292 communicate with the surrounding environment upstream in the air blowing direction, respectively.

The inner peripheral walls of the first air injection part 128 and the second air injection part 129 are respectively formed with a first air injection port 124 and a second air injection port (not labeled in the figure), the first air injection port 124 is used for injecting the air flow in the first air injection part 128 forward and driving the ambient air in a first air suction hole 1282 defined by the inner peripheral wall of the first air injection part 128 to be sent forward, and the second air injection port is used for injecting the air flow in the second air injection part 129 forward and driving the ambient air in a second air suction hole 1292 defined by the inner peripheral wall of the second air injection part 129 to be sent forward.

The first air injection part 128 and the second air injection part 129 may be respectively formed by respective annular inner walls and annular outer walls, and the annular outer walls of the first air injection part 128 and the annular inner walls together define a first air supply cavity 125, edges of the annular outer walls of the first air injection part 128 connected with the annular inner walls form a first air injection port 124, and a first air inlet 1281 communicated with the first air supply assembly is opened at the end of the first air injection part 128 on one side of the second air injection part 129, so that the first heat exchange air flow is introduced into the first air supply cavity 125.

The second air injection part 129 is identical to the first air injection part 128 in structure and symmetrically arranged, so that the annular outer wall and the annular inner wall of the second air injection part 129 jointly define a second air supply cavity (not marked in the figure), the edge of the annular outer wall and the annular inner wall of the second air injection part 129, which is connected, forms a second air injection port (not marked in the figure), and a second air inlet 1291 communicated with the second air supply assembly is formed at the end part of the second air injection part 129, which is far away from the first air injection part 128, so that the second heat exchange air flow is introduced into the second air supply cavity.

Since the second air injecting section 129 is identical to the first air injecting section 128 in structure, the structure of the first air injecting section 128 will be described with reference to the drawings. The size and specification of the first air injection part 128 and its internal components may be set according to the air supply capability of the first air supply assembly. Fig. 3 is a schematic view of a jet module 120 in the wall-mounted air conditioner indoor unit 100 according to an embodiment of the present invention, fig. 4 is a front view of a first jet part 128 in the jet module 120 shown in fig. 3, and fig. 5 is a schematic cross-sectional airflow direction view taken along a section line A-A in fig. 4. The first air injection part 128 includes an annular inner wall 121 and an annular outer wall 122, the annular inner wall 121 and the annular outer wall 122 together form the above-mentioned oblong shape, and the inner side of the annular inner wall 121 is a first air suction hole 1282. The edge of the annular outer wall 122 that meets the annular inner wall 121 forms a first air jet 124, and the first air jet 124 is configured to jet the air flow of the first air supply chamber 125 forward, and to suck the air in the rear portion of the air supply opening 117 through the air supply opening 117.

The rear side edge 126 of the annular inner wall 121 is recessed inwardly of the first air supply chamber 125, and the annular outer wall 122 has an outwardly turned edge 127 at a position opposite to the rear side edge 126 of the annular inner wall 121, so that a gap between the annular outer wall 122 and the rear side edge 126 of the annular inner wall 121 forms the first air jet 124. The rear edge 126 of the annular inner wall 121 recessed toward the inside of the first air supply chamber 125 may also have an air flow direction guiding effect, so that the air flow in the first air supply chamber 125 is smoothly sent out from the first air jet 124.

The annular inner wall 121 extends forwardly from its rear side edge 126 to form a continuous outwardly expanding coanda surface; and the section of the part of the annular outer wall 122 located at the rear side of the air injection assembly 120 is spiral, so that after the air flow of the first air supply cavity 125 is ejected from the first air injection port 124 along the annular outer wall 122, the air flow is sent forward along the first coanda surface formed by the annular inner wall 121, and the air flow drives the ambient air behind the air supply port 117 to be pumped out. The expansion inclination angle of the annular inner wall 121 extending forward and continuously expanding outwards may be 5 to 15 degrees, and the larger the inclination angle is, the faster the expansion speed of the air flow ejected from the first air jet 124 is, through a great number of tests, the expansion inclination angle of the annular inner wall 121 may be set between 6 and 10 degrees, so that the mixing with the ambient air in the first air suction hole 1282 is more facilitated.

The annular inner wall 121 and the annular outer wall 122 together define an annular first air supply chamber 125 inside the first air injection portion 128, and a lateral end (an end far away from the second air injection portion 129) of the annular outer wall 122 is provided with a first air inlet 1281 for providing air flow to the first air supply chamber 125 after heat exchange by the heat exchanger 140.

In some alternative embodiments, the first air injection portion 128 may be integrally formed into an oblong shape, and the annular inner wall 121 and the annular outer wall 122 respectively have two spaced horizontal sections and two arc sections connected to the two horizontal sections, wherein the annular outer wall 122 of one of the two arc sections, which is far from the second air injection portion 129, is provided with a first air inlet 1281 of the first air injection portion 128 for receiving the air flow provided by the first air supply assembly after heat exchange.

The above-described sections of the annular inner wall 121 and the annular outer wall 122 may be formed by a splice of a plurality of connected components, and in some preferred embodiments, the annular inner wall 121 and the annular outer wall 122 may also be formed by a unitary molding.

The first gas jets 124 may be a continuous annular groove, and in some alternative embodiments, the first gas jets 124 may be formed on a portion of the sections of the annular inner wall 121 and the annular outer wall 122, or in spaced apart segments. For example, the first air jets 124 may be provided only on the horizontal section so that the air jets are more uniform and may effectively entrain ambient air within the first air extraction holes 1282. In order to increase the jet velocity of the first air jet 124, the width of the first air jet 124 may be set to 1 to 3mm, and through a great number of tests, the width of the first air jet 124 may be preferably set to about 2mm, and the first air jet 124 with the size width not only ensures the jet velocity of the heat exchange air flow, but also can reduce the windage loss of the heat exchange air flow as much as possible and reduce noise. In fig. 5, the solid arrows indicate the air flow direction of the ambient air, and the broken arrows indicate the air flow direction of the heat exchange air flow ejected from the air ejection ports 124.

The second air injecting part 129 has the same structure as the first air injecting part 128, a rear side edge of an annular inner wall of the second air injecting part 129 is recessed toward the inside of the second air supply chamber, and a position of an annular outer wall of the second air injecting part 129 opposite to the rear side edge of the annular inner wall has an outward burring so that a gap between the annular outer wall of the second air injecting part 129 and the rear side edge of the annular inner wall forms a second air injecting port. The annular inner wall of the second jet portion 129 extends forwardly from its rear side edge to form a continuous outwardly expanding second coanda surface; and the section of the part of the annular outer wall of the second air injection part 129 located at the rear side of the air injection assembly 120 is spiral, so that the air flow of the second air supply cavity is sent out forward along the second coanda surface after being ejected from the second air injection port along the annular outer wall of the second air injection part 129, and drives the ambient air in the second air suction hole 1292 to be drawn out. A lateral end of the annular outer wall of the second air injection portion 129 (the end remote from the first air injection portion 128) is provided with a second air inlet 1291 for providing air flow to the second air supply chamber after heat exchange by the heat exchanger 140.

Additional structural details of the second air jet portion 129 may be derived from the description of the first air jet portion 128, and are not repeated herein.

In some preferred embodiments, the air jet assembly 120 may also be driven by a motor and a transmission mechanism to achieve overall up-and-down swing, adjust the air supply angle, and achieve swing air supply, thereby making the air outlet range wider.

The first air supply assembly and the second air supply assembly are transversely arranged in the shell 110 at intervals, wherein the first air supply assembly is used for generating a first heat exchange air flow which enters from the air inlet 116 and is supplied into the first air supply cavity 125 through the first air inlet 1281 after exchanging heat with the heat exchanger 140; the second air supply assembly is configured to generate a second heat exchange air flow entering from the air inlet 116, exchanging heat with the heat exchanger 140, and then being supplied to the second air supply chamber through the second air inlet 1291.

The first air supply assembly and the second air supply assembly are symmetrically arranged with the center of the heat exchanger 140, and the first air supply assembly and the second air supply assembly supply air to the first air inlet 1281 and the second air inlet 1291 at two sides of the air injection assembly 120 respectively.

The first air supply assembly includes: the first centrifugal fan 131 and the first air guide 136. The first centrifugal fan 131 is used as a power source for the flow of the first heat exchange airflow, and may be configured such that ambient air enters from the air inlet 116 and exchanges heat with the heat exchanger 140, passes through the first centrifugal fan 131, is discharged downstream, and finally is sent out of the indoor unit 100 through the air injection assembly 120. The first air guiding component 136 is connected between the air outlet of the first centrifugal fan 131 and the first air inlet 1281, and is used for guiding the air flow discharged by the first centrifugal fan 131 into the first air supply cavity 125.

The second air supply assembly includes: the second centrifugal fan 151 and the second air guide 156. The second centrifugal fan 151, which is a power source for the second heat exchange airflow, may be configured such that ambient air enters from the air inlet 116 and exchanges heat with the heat exchanger 140, passes through the second centrifugal fan 151, is discharged downstream, and finally is sent out of the indoor unit 100 through the second air injection unit 129. The second air guiding member 156 is connected between the air outlet of the second centrifugal fan 151 and the second air inlet 1291, and is used for guiding the air flow discharged from the second centrifugal fan 151 into the second air supply cavity.

Fig. 6 is a schematic diagram of internal components of a wall-mounted air conditioner indoor unit 100 according to one embodiment of the present invention. The wall-mounted air conditioner indoor unit 100 further includes a partition 143, the partition 143 being disposed longitudinally above the air injection assembly 120 inside the housing 110, and a heat exchanger accommodating chamber 144 being defined between the partition 143 and the front panel 114. The partition 143 may have a recess adapted to the outer shape of the heat exchanger 140 so that the heat exchanger 140 may be fixed in the heat exchanger receiving chamber 144. The heat exchanger 140 is disposed within the heat exchanger receiving chamber 144 and may be configured in a plate-like, multi-stage, U-shaped configuration, etc., and in some alternative embodiments, the heat exchanger 140 may be configured in a multi-stage plate-like configuration, with one portion disposed against the front panel 114 and another portion disposed against the top wall of the housing 112. The location of the heat exchanger 140 may be set according to the location of the air inlet 116.

The center of the partition plate 143 is provided with a first through hole 145 through which the first air collecting port 132 of the first centrifugal fan 131 passes, and a second through hole 146 through which the second air collecting port 152 of the second centrifugal fan 151 passes. The first and second centrifugal fans 131 and 151 suck air in the heat exchanger accommodating chamber 144, which exchanges heat with the heat exchanger 140, thereby forming first and second heat exchange airflows, respectively. The first impeller 133 and the first volute 134 of the first centrifugal fan 131 are disposed in a space defined by the partition 143 and the casing 112, and an exhaust port of the first volute 134 faces a side wall of the housing 110; the inlet of the first air guide 136 is connected to the outlet of the first volute 134.

Similarly, the second impeller 153 and the second scroll 154 of the second centrifugal fan 151 are disposed in the space defined by the partition 143 and the casing 112, and the exhaust port of the second scroll 154 is directed toward the other side wall of the housing 110; the inlet of the second air directing member 156 is connected to the outlet of the second volute 154.

Fig. 7 is a schematic diagram illustrating a structure in which a first air supply unit and a second air supply unit supply air to an air injection unit 120 in a wall-mounted air conditioner indoor unit 100 according to an embodiment of the present invention. The first air supply assembly includes: first centrifugal fan 131 and first wind-guiding part 136, the second air supply subassembly includes: the second centrifugal fan 151 and the second air guide 156. In order to ensure the air jet speed, the first air supply assembly and the second air supply assembly of the embodiment both adopt a centrifugal fan as a power source of heat exchange airflow.

The first centrifugal fan 131 accelerates the gas according to the principle that kinetic energy is converted into potential energy by using the first impeller 133 rotating at a high speed, and then decelerates and changes the flow direction, so that the kinetic energy is converted into potential energy. The first centrifugal fan 131 generally includes a first air collection port 132, a first impeller 133, and a first volute 134. The first air collecting port 132 of the first centrifugal fan 131 is used to ensure that the air flow can uniformly fill the inlet interface of the first impeller 133, so as to reduce the flow loss, in this embodiment, the first air collecting port 132 of the first centrifugal fan 131 tapers towards the first impeller 133, forming a flare, and the air exchanging heat with the heat exchanger 140 in the heat exchanger accommodating cavity 144 can be sucked into the first impeller 133 as much as possible. When the first impellers 133 of the first centrifugal fan 131 are driven by the first high-speed motor 135 to rotate along with the shaft, gas between the first impellers 133 rotates along with the first impellers 133 to obtain centrifugal force, the gas is thrown out of the first impellers 133 and enters the first volute 134, and the gas pressure increase in the first volute 134 is guided to be discharged. After the air between the blades is exhausted, negative pressure is formed; the air of the heat exchanger 140 in the heat exchanger accommodating chamber 144 outside the first air collecting port 132 is continuously sucked, thereby forming a continuous air flow.

The first impeller 133 and the first volute 134 of the first centrifugal fan 131 are disposed in a space defined by the partition 143 and the casing 112, and an exhaust port of the first volute 134 faces a side wall of the housing 110; the inlet of the first air guide 136 is connected to the outlet of the first volute 134. The first scroll 134 is spirally shaped, and sucks up air thrown out from the first impeller 133, and converts the dynamic pressure of the air flow into static pressure by the gradually widening sectional area.

The first air guiding component 136 is connected between the air outlet of the first centrifugal fan 131 and the first air inlet 1281, and is used for guiding the air flow discharged by the first centrifugal fan 131 into the first air supply cavity 125. The first wind guide component 136 may include a first drainage section 137 and a first wind supply section 138.

The first drainage segment 137 has an air inlet of the first air guiding component 136, and at least part of the segment body of the first drainage segment 137 is spiral to guide the air flow direction discharged by the first centrifugal fan 131 downward, and the first drainage segment 137 tapers from the air inlet of the first air guiding component 136 along the air flow direction, so that the air speed of the air flow entering the first air collecting cavity 139 of the first air supplying segment 138 is increased.

The first air supply section 138 is connected to the first drainage section 137, and defines a first air collecting cavity 139 therein to receive the air flow discharged from the first centrifugal fan 131, and the first air supply section 138 is provided with a first air inlet 1281 facing the first air supply cavity 125 so that the air flow in the first air collecting cavity 139 is supplied to the first air supply cavity 125. The first air supply section 138 forms a volute shape along the air outlet direction of the first drainage section 137, reduces the wind resistance of the air flow in the first air collection cavity 139, enables the air flow to form vortex in the first air collection cavity 139, and can smoothly lead to the first air supply cavity 125 from the first air collection cavity 139.

The first drainage section 137 may be disposed on one side of the first centrifugal fan 131, and because of the space limitation of the partition 143, the front-rear distance of the first drainage section 137 is smaller, and the first air supply section 138 is located below the heat exchanger accommodating chamber 144 (i.e. below the partition 143 and the heat exchanger 140), so that the distance in the front-rear direction is greater than that of the first drainage section 137, and the air outlet of the first air supply section 138 is disposed in the front portion (corresponding to the position of the first air inlet 1281) of the first air collecting chamber 139 on the side of the first air injecting section 128.

The structure of the second air supply assembly is identical to that of the first air supply assembly. Specifically, the second centrifugal fan 151 generally includes a second gas collection port 152, a second impeller 153, and a second volute 154. The second air collecting port 152 of the second centrifugal fan 151 serves to ensure that the air flow uniformly fills the inlet interface of the second impeller 153, reducing flow losses. The second air collecting port 152 of the second centrifugal fan 151 tapers towards the second impeller 153 to form a bell mouth, so that air exchanging heat with the heat exchanger 140 in the heat exchanger accommodating cavity 144 can be sucked into the second impeller 153 as much as possible. When the second impeller 153 of the second centrifugal fan 151 is driven by the second high-speed motor 155 to rotate along with the shaft, gas between the second impellers 153 rotates along with the second impeller 153 to obtain centrifugal force, the gas is thrown out of the second impeller 153 and enters the second volute 154, and the gas pressure increase in the second volute 154 is guided and discharged. After the air between the blades is exhausted, negative pressure is formed; the air of the heat exchanger 140 in the heat exchanger accommodating chamber 144 outside the second air collecting port 152 is continuously sucked, thereby forming a continuous air flow.

The second impeller 153 and the second scroll 154 of the second centrifugal fan 151 are disposed in a space defined by the partition 143 and the casing 112, and an exhaust port of the second scroll 154 faces a side wall of the housing 110; the inlet of the second air directing member 156 is connected to the outlet of the second volute 154. The second scroll 154 is formed in a spiral shape, and sucks up air thrown from the second impeller 153 and converts a dynamic pressure of the air flow into a static pressure by a widened sectional area.

The second air guiding member 156 is connected between the air outlet of the second centrifugal fan 151 and the second air inlet 1291, and is used for guiding the air flow discharged from the second centrifugal fan 151 into the second air supply cavity. The second air guide member 156 may include a second drainage section 157 and a second air supply section 158.

The second drainage section 157 has an air inlet of the second air guiding member 156, and at least a part of the second drainage section 157 is spirally formed to guide the air flow direction discharged from the second centrifugal fan 151 downward, and the second drainage section 157 is tapered from the air inlet of the second air guiding member 156 in the air flow direction, thereby accelerating the air speed of the air flow entering the second air collecting chamber 159 of the second air supplying section 158.

The second air supply section 158 is connected with the second drainage section 157, and defines a second air collection cavity 159 therein to receive the air flow discharged from the second centrifugal fan 151, and the second air supply section 158 is provided with a second air inlet 1291 for supplying the air flow of the second air collection cavity 159 to the second air supply cavity. The second air supply section 158 forms a volute shape along the air outlet direction of the second drainage section 157, reduces the wind resistance of the air flow in the second air collection cavity 159, enables the air flow to form vortex in the second air collection cavity 159, and can smoothly lead from the second air collection cavity 159 to the second air supply cavity.

The second flow guiding section 157 may be disposed at one side of the second centrifugal fan 151, and the front-rear distance of the second flow guiding section 157 is smaller due to the space limitation of the partition 143, and the second air supplying section 158 is located below the heat exchanger accommodating chamber 144 (i.e., below the partition 143 and the heat exchanger 140), so that the front-rear distance thereof is greater than the second flow guiding section 157, and the air outlet of the second air supplying section 158 is disposed at the front portion (corresponding to the position of the second air inlet 1291) of the second air collecting chamber 159 adjacent to the side of the second air injecting section 129.

The first air supply subassembly and second air supply subassembly can cooperate each other to realize the air supply, and both can start simultaneously, can start alone, and the mode of operation of first air supply subassembly and second air supply subassembly can include: the two air supply assemblies operate at the same air speed, the two air supply assemblies operate at different air speeds, the first air supply assembly operates independently, the second air supply assembly operates independently, and the first air supply assembly and the second air supply assembly operate alternately.

The above operation modes can be used in combination with various sensors of the indoor unit 100, and by detecting the operation environment of the indoor unit 100, the operation states of the first air supply assembly, the second air supply assembly and the heat exchanger 140 are adjusted according to the preset control mode, for example, when the temperature of the whole indoor unit 100 needs to be adjusted, the first air supply assembly and the second air supply assembly can be started at the same time and continuously operate at the same wind speed (which can be determined according to the difference between the set temperature and the actual temperature); in addition, the wind speeds of the first air supply assembly and the second air supply assembly are set to be different, so that the direction of the air supply flow is correspondingly adjusted to adapt to the indoor space; under some special working conditions (for example, when a certain side needs to be blown independently), the first air supply assembly and the second air supply assembly can be started alternatively, and in addition, the first air supply assembly and the second air supply assembly can be started alternately, so that an effect similar to left and right air swinging is achieved, and balanced operation of internal components of the indoor unit 100 is ensured.

Because the first air supply assembly and the second air supply assembly supply air to different air injection parts respectively and independently, the control mode is more flexible and convenient, the air supply requirements of different working conditions can be met, and the use experience of users is greatly improved.

The air supply opening 117 below the casing 110 of the wall-mounted air conditioner indoor unit 100 of this embodiment is used for arranging the annular air injection assembly 120, so that the air flow passing through the heat exchanger 140 exchanges heat is ejected from the air injection assembly 120, the ambient air around the air supply opening 117 is sucked and mixed with the heat exchange air flow with severe ambient temperature difference, thus ensuring that the sent air flow is soft, the feeling of blowing to a human body is more comfortable, on one hand, the air supply amount of the indoor unit 100 is increased, the flow of indoor air is accelerated, the indoor temperature can be uniformly reduced as a whole, and the air outlet of the wall-mounted air conditioner indoor unit 100 of this invention is oblong (also referred to as a runway shape), is arranged below the casing 110, the overall structure is relatively similar to that of the conventional wall-mounted air conditioner indoor unit, the conventional wall-mounted air conditioner indoor unit is easy to accept by a user, the conventional wall-mounted air conditioner indoor unit is easy to replace, the installation position is flexible, the internal component structure is compact, the space in the casing 110 is fully utilized, and the wall-mounted air conditioner indoor unit 100 can be thinner.

The heat exchange airflow of the wall-mounted air conditioner indoor unit 100 of the present embodiment has the following flow directions: after the first centrifugal fan 131 and the second centrifugal fan 151 are started, air around the indoor unit 100 is sucked into the heat exchanger accommodating chamber 144 from the air inlet 116, and exchanges heat with the heat exchanger 140. A part of the air flow after heat exchange enters the first centrifugal fan 131, is accelerated by the first impeller 133, enters the first air guide component 136 through the first volute 134, is guided by the first drainage segment 137 of the first air guide component 136, and enters the first air collection cavity 139 of the first air supply segment 138. The air flow enters the annular first air supply cavity 125 from the first air inlet 1281 through the air outlet of the first air supply section 138 at the first air collection cavity 139 in a vortex-type manner, thereby forming a first heat exchange air flow.

The other part of the air flow after heat exchange enters the second centrifugal fan 151, is accelerated by the second impeller 153, enters the second air guide component 156 through the second volute 154, is guided by the second drainage section 157 of the second air guide component 156, and enters the second air collection cavity 159 of the second air supply section 158. The air flow enters the annular second air supply chamber from the second air inlet 1291 at the second air collection chamber 159 in a swirling flow pattern eventually passing through the air outlet of the second air supply section 158, thereby forming a second heat exchange air flow.

After the first heat exchange air flow enters the first air supply cavity 125, the first air jet 124 is ejected forward at a high speed under the guidance of the rear side edge 126 of the annular inner wall 121, so that the air in the air circulation area 118 behind the air supply opening 117 is driven to be sucked and pass through the first air suction hole 1282, the air is mixed in front of the indoor unit 100 and then is sent into a room, the air outlet volume is greatly increased, and meanwhile, the air flow after heat exchange is mixed with ambient air and becomes cool and not cool soft air flow, so that the flow of indoor air is accelerated. After entering the second air supply cavity, the second heat exchange air flow is guided by the rear side edge of the annular inner wall of the second air injection part 129, and is ejected forward from the second air injection port at a high speed, so that the air in the air circulation area 118 at the rear part of the air supply port 117 is driven to be sucked through the second air suction hole 1292.

By now it should be appreciated by those skilled in the art that while a number of exemplary embodiments of the invention have been shown and described herein in detail, many other variations or modifications of the invention consistent with the principles of the invention may be directly ascertained or inferred from the present disclosure without departing from the spirit and scope of the invention. Accordingly, the scope of the present invention should be understood and deemed to cover all such other variations or modifications.

Claims (9)

1. An indoor unit of a wall-mounted air conditioner, comprising:

the casing, it has offered air intake and supply-air outlet, the supply-air outlet is for being oblong, set up in the lower part of casing, the casing includes: the air supply device comprises a housing and a front panel arranged in front of the housing, wherein the housing and the lower part of the front panel form the air supply opening penetrating front and back; the position of the rear side of the housing forming the air supply port is recessed forwards, so that an air circulation area is arranged behind the air supply port; the air inlet is arranged at any one or more of the following positions: the front panel, the top wall of the housing, the side walls of the housing;

the heat exchanger is arranged inside the shell;

the air injection assembly is arranged in the air supply opening and comprises a first air injection part and a second air injection part which are transversely arranged, a first air injection port and a second air injection port are respectively formed in the inner peripheral walls of the first air injection part, the first air injection port is used for injecting air flow in the first air injection part forwards and driving ambient air in a first air suction hole defined by the inner peripheral wall of the first air injection part to be sent forwards, the second air injection port is used for injecting air flow in the second air injection part forwards and driving ambient air in a second air suction hole defined by the inner peripheral wall of the second air injection part to be sent forwards, and the first air suction hole and the second air suction hole are respectively communicated with the surrounding environment at the upstream of the air supply direction;

The first air supply assembly and the second air supply assembly are transversely arranged at intervals in the shell, the first air supply assembly is used for generating first heat exchange air flow entering from the air inlet and supplying to the first air injection part after heat exchange with the heat exchanger, and the second air supply assembly is used for generating second heat exchange air flow entering from the air inlet and supplying to the second air injection part after heat exchange with the heat exchanger.

2. The wall-mounted air conditioner indoor unit of claim 1, wherein

The first air injection part and the second air injection part are respectively formed by an annular inner wall and an annular outer wall, and

the annular outer wall and the annular inner wall of the first air injection part jointly define a first air supply cavity, the edge of the annular outer wall and the annular inner wall of the first air injection part connected with each other forms the first air injection port, and a first air inlet communicated with the first air supply assembly is formed at the end part of one side of the first air injection part far away from the second air injection part, so that the first heat exchange air flow is introduced into the first air supply cavity;

the annular outer wall and the annular inner wall of the second air injection part jointly define a second air supply cavity, the edge, which is connected with the annular outer wall and the annular inner wall, of the second air injection part forms the second air injection port, and a second air inlet communicated with the second air supply assembly is formed in the end part, which is far away from one side of the first air injection part, of the second air injection part, so that the second heat exchange air flow is introduced into the second air supply cavity.

3. The wall-mounted air conditioner indoor unit of claim 2, wherein

The rear side edge of the annular inner wall of the first air injection part is recessed towards the interior of the first air supply cavity, and the position, opposite to the rear side edge of the annular inner wall, of the annular outer wall of the first air injection part is provided with an outward flanging, so that a gap between the annular outer wall of the first air injection part and the rear side edge of the annular inner wall forms the first air injection port;

the rear side edge of the annular inner wall of the second air injection part is recessed towards the interior of the second air supply cavity, and the position, opposite to the rear side edge of the annular inner wall, of the annular outer wall of the second air injection part is provided with an outward flanging, so that a gap between the annular outer wall of the second air injection part and the rear side edge of the annular inner wall forms the second air injection port.

4. A wall-mounted air conditioner indoor unit as recited in claim 3, wherein

The annular inner wall of the first jet section extending forwardly from its rear edge to form a continuously outwardly expanding first coanda surface; the section of the part of the annular outer wall of the first air injection part, which is positioned at the rear side of the air injection assembly, is spiral, so that the air flow of the first air supply cavity is sent out forwards along the first coanda surface after being sprayed out from the first air injection port along the annular outer wall of the first air injection part, and the air flow drives the ambient air in the first air exhaust hole to be exhausted; and is also provided with

The annular inner wall of the second jet section extending forwardly from its rear edge to form a continuously outwardly expanding second coanda surface; and the section of the part of the annular outer wall of the second air injection part, which is positioned at the rear side of the air injection assembly, is spiral, so that the air flow of the second air supply cavity is sent out forwards along the second coanda surface after being sprayed out from the second air injection port along the annular outer wall of the second air injection part, and the air flow drives the ambient air in the second air exhaust hole to be exhausted.

5. The wall-mounted air conditioner indoor unit of claim 2, wherein

The first air supply assembly includes: the first centrifugal fan is used as a power source of the first heat exchange airflow, and the first air guide component is connected between an exhaust port of the first centrifugal fan and the first air inlet so as to guide the airflow exhausted by the first centrifugal fan into the first air supply cavity;

the second air supply assembly includes: the second centrifugal fan is used as a power source of the second heat exchange airflow, and the second air guide component is connected between an exhaust port of the second centrifugal fan and the second air inlet so as to guide the airflow exhausted by the second centrifugal fan into the second air supply cavity.

6. The indoor unit of wall-mounted air conditioner as recited in claim 5, wherein

The wall-mounted air conditioner indoor unit further comprises a partition board, the partition board is longitudinally arranged above the air injection assembly in the shell, a heat exchanger accommodating cavity is defined between the partition board and the front panel, and the heat exchanger is arranged in the heat exchanger accommodating cavity; and is also provided with

The impellers and the spiral case of the first centrifugal fan and the second centrifugal fan are arranged in the space defined by the partition plate and the housing.

7. The wall-mounted air conditioner indoor unit of claim 6, wherein

The middle part of the partition plate is provided with a first through hole and a second through hole which are transversely arranged at intervals;

the air collecting port of the first centrifugal fan penetrates out of the first through hole so as to suck air from the heat exchanger accommodating cavity, the air outlet of the volute of the first centrifugal fan faces the side wall of the shell at one side of the first air inlet, and the air inlet of the first air guide component is connected with the air outlet of the volute of the first centrifugal fan;

the gas collection port of the second centrifugal fan penetrates out of the second through hole so as to suck air from the heat exchanger accommodating cavity, the gas outlet of the volute of the second centrifugal fan faces the side wall of the shell on one side of the second gas inlet, and the gas inlet of the second air guide component is connected with the gas outlet of the volute of the second centrifugal fan.

8. The wall-mounted air conditioner indoor unit of claim 7, wherein

The first wind-guiding part includes: a first flow guiding section having an air inlet of the first air guiding member, and at least a part of the first flow guiding section being spirally formed so as to guide an air flow direction discharged from the first centrifugal fan downward; the first air supply section is connected with the first drainage section, a first air collection cavity is defined in the first air supply section and used for receiving air flow discharged by the first centrifugal fan, and a first air outlet connected with the first air inlet is formed in the first air supply section so that the air flow of the first air collection cavity is supplied to the first air supply cavity; and is also provided with

The second air guiding member includes: a second flow guiding section having an air inlet of the second air guiding member, and at least a part of the second flow guiding section being spirally formed so as to guide an air flow direction discharged from the second centrifugal fan downward; the second air supply section is connected with the second drainage section, a second air collection cavity is defined in the second air supply section and used for receiving air flow exhausted by the second centrifugal fan, and a second air outlet connected with the second air inlet is formed in the second air supply section so that the air flow of the second air collection cavity is supplied to the second air supply cavity.

9. The wall-mounted air conditioner indoor unit of claim 8, wherein

The first drainage section gradually tapers from the air inlet of the first air guide component along the air flow direction, the first air supply section forms a volute shape along the air outlet direction of the first drainage section, and the wind resistance of the first heat exchange air flow in the first air collection cavity is reduced;

the second drainage section gradually tapers from the air inlet of the second air guide component along the air flow direction, the second air supply section forms a volute shape along the air outlet direction of the second drainage section, and the wind resistance of the second heat exchange air flow in the second air collection cavity is reduced.