CN113803784A - Air conditioner - Google Patents

Abstract

The invention provides an air conditioner, and relates to the technical field of air conditioners. The air conditioner includes an air duct housing and an ion generator. The inner side of the air duct shell forms an air guide channel for air flow to flow, a through hole communicated with the air guide channel is formed in the air duct shell, a limiting buckle is arranged on the air duct shell, and a limiting space is formed between the limiting buckle and the air duct shell. The ionizer comprises a shell, a mesh enclosure, a limiting block and an installation lug, wherein the mesh enclosure, the limiting block and the installation lug are all installed on the outer side of the shell. The shell can move along the preset direction to drive the mesh enclosure to penetrate through the through hole to extend into the air guide channel, and can drive the limiting block to be clamped into the limiting space. The mounting ears are removably attached to the air duct housing. The air conditioner provided by the invention can solve the technical problem of low assembly efficiency of an ion generator on the air conditioner in the prior art.

Description

Air conditioner

Technical Field

The invention relates to the technical field of air conditioners, in particular to an air conditioner.

Background

With the development of society, consumers are pursuing high-quality life, and among them, air conditioners have become the primary choice of most consumers. The air conditioner can carry out air conditioning to the installation region, and then makes the environment in installation region improve, promotes consumer's travelling comfort. However, consumers now have been limited to satisfying existing air conditioning, and it is desirable to achieve higher quality conditioning effects to further improve consumer quality of life.

Among them, the ion generator has a low cost, is convenient to use, has a high sterilization efficiency, and is increasingly used in air conditioners. However, the installation of the ionizer in the air conditioner assembly takes a long time, so that the air conditioner assembly efficiency is lowered.

Disclosure of Invention

The invention solves the technical problem of low assembly efficiency of an ion generator on an air conditioner in the prior art.

In order to solve the above problems, the present invention provides an air conditioner including an air duct housing and an ion generator.

The air duct shell is characterized in that an air guide channel for air flow to flow is formed on the inner side of the air duct shell, a through hole communicated with the air guide channel is formed in the air duct shell, a limiting buckle is arranged on the air duct shell, and a limiting space is formed between the limiting buckle and the air duct shell.

The ionizer comprises a shell, a mesh enclosure, a limiting block and mounting lugs, wherein the mesh enclosure, the limiting block and the mounting lugs are mounted on the outer side of the shell.

The shell can move along a preset direction to drive at least part of the mesh enclosure to penetrate through the through hole to extend into the air guide channel, and can drive the limiting block to be clamped into the limiting space.

The mounting ears are removably connected to the air duct housing.

When the air conditioner provided by the invention is assembled with the ion generator, the movable shell can drive the mesh enclosure, the mounting lugs and the limiting blocks to move along the preset direction, so that the shell drives the mesh enclosure to penetrate through the through hole and extend into the air guide channel, and the needle electrode extending into the mesh enclosure can release ions into the air guide channel conveniently; meanwhile, when the mesh enclosure extends into the through hole, the purpose that the limiting block is clamped into the limiting space is achieved, and then the pre-installation of the ion generator is completed. When the limiting block moves to a proper position and the ion generator is located at the proper position, the ion generator can be installed through the detachable connection of the installation lug and the air duct shell. When the ion generator is assembled, the ion generator and the air duct shell can be assembled only by completing detachable connection between one installation lug and the air duct shell, the purpose of rapidly assembling the ion generator can be realized, the assembly efficiency of the ion generator is improved, the assembly efficiency of an air conditioner is improved, and the technical problem that the assembly efficiency of the ion generator on the air conditioner is low in the prior art is solved.

In order to facilitate the mesh enclosure to stretch into the through hole and simultaneously realize the mutual matching between the limiting block and the limiting buckle, optionally, the shell is provided with a first side surface and a second side surface which are adjacently arranged, the mesh enclosure is arranged on the first side surface, the limiting block is convexly arranged on the second side surface, and the limiting block extends towards one side of the first side surface. The shell can be moved along the preset direction, and meanwhile, the limiting blocks can be moved along the preset direction to enter the limiting space, and the limiting blocks and the limiting buckles are matched with each other.

Optionally, one end of the stopper close to the first side surface forms a guiding inclined surface, and the height of the stopper relative to the second side surface is gradually reduced in a direction toward the first side surface. Through the one end that is close to first side at the stopper forms the direction inclined plane, can make things convenient for the stopper card to go into to spacing space in, improve spacing knot and stopper efficiency of mutually supporting.

Optionally, the stopper extends along a straight line.

Optionally, the shell is further provided with a strengthening portion, and the strengthening portion is connected to one side of the limiting block and arranged at an included angle with the limiting block.

Through set up the intensive portion that is the contained angle setting with the stopper in one side of stopper, can improve the intensity of stopper through intensive portion, in other words, intensive portion provides the effect of strengthening rib to the stopper.

Optionally, the reinforcing part is convexly arranged on one side of the limiting block, and the shell moves in the preset direction and drives the limiting block to be clamped into the limiting space, so that the reinforcing part can be driven to abut against the limiting block.

And then drive the screen panel at the casing and stretch into the suitable position in the through-hole, and when driving the stopper and stretch into the suitable position in spacing space, can support the purpose of holding in spacing knot through the intensive portion and provide limiting displacement to the casing, and then can ensure that the screen panel can stretch into the assigned position to the ventilation passageway, and can guarantee that stopper and spacing are detained and accurately mutually support, ensure spacing stability.

Optionally, for the installation of convenience ion generator, and ensure that the screen panel can stretch into to the through-hole in, the wind channel casing includes bounding wall and mounting panel, the bounding wall with the mounting panel is the contained angle setting, just the inboard of bounding wall is used for enclosing into the wind-guiding passageway, the mounting panel sets up the outside of bounding wall.

The through-hole runs through to be seted up on the bounding wall, spacing knot is protruding to be established the mounting panel and with the mounting panel forms jointly spacing space.

Optionally, the mounting plate is provided with a mounting area, the through hole corresponds to the middle of the mounting area, and the limit buckle is arranged on one side of the mounting area.

Optionally, the limit buckle comprises a connecting portion and a buckling portion, the connecting portion is convexly arranged on the mounting plate and located on one side of the mounting area, the buckling portion is arranged at one end, away from the mounting plate, of the connecting portion and extends towards the mounting area, and the limiting space is formed between the buckling portion and the mounting plate.

Optionally, the mounting panel or still be equipped with on the bounding wall with the installation department of installation ear looks adaptation, the installation ear with the connection can be dismantled to the installation department.

Through the installation part matched with the installation lug, the installation lug and the air duct shell can be connected with each other conveniently.

Optionally, in order to improve the efficiency of mutually supporting between installation ear and the installation department, improve the installation effectiveness between installation ear and the installation department, the installation department is protruding to be located the installation department perhaps the bounding wall, the installation ear has the installation face, the mounting surface laminating in the installation department, just the installation face epirelief is equipped with the setting element, the setting element support hold in the installation department is adjacent in the side of wind channel casing. Can realize the cooperation each other of installation department and installation ear through the setting element laminating in the outside of installation department, can improve the installation effectiveness of installation ear and installation department, can also improve the cooperation installation accuracy between installation ear and the installation department simultaneously to improve the installation stability between installation ear and then the installation department.

Optionally, the installation department is the cylindricality, and forms curved outer peripheral face, the setting element bending be the arc and with the outer peripheral face looks adaptation of installation department.

In order to reinforce the strength of the mounting ear, optionally, the mounting ear further has a reinforcing surface disposed opposite to the mounting surface, and a reinforcing member is protruded from the reinforcing surface and connected to the outer side surface of the housing. The stability of the ion generator installed in the air duct housing can be ensured by enhancing the strength of the installation ear.

Drawings

Fig. 1 is a schematic structural diagram of a part of an air conditioner provided in an embodiment of the present application;

fig. 2 is an exploded view of a part of an air conditioner provided in an embodiment of the present application;

FIG. 3 is an enlarged schematic view of the structure at A in FIG. 2;

FIG. 4 is a schematic view of a first view of an ionizer provided in an embodiment of the present application;

FIG. 5 is an enlarged view of the structure at B in FIG. 4;

FIG. 6 is a schematic diagram of a second view of an ionizer provided in an embodiment of the present application;

FIG. 7 is a schematic diagram of a third view angle of an ionizer provided in the present embodiment;

fig. 8 is a partial structural view of an air conditioner provided in another embodiment of the present application;

fig. 9 is an exploded view of the structure of fig. 8.

Description of reference numerals:

10-an air conditioner; 100-an air duct housing; 110-a coaming; 111-a via; 112-air guide channels; 120-a mounting plate; 121-a mounting area; 122-a limit buckle; 1221-a connecting portion; 1222-a latch; 1223-a spacing space; 123-a mounting portion; 200-an ionizer; 210-a housing; 211-a first side; 212-a second side; 213-third side; 214-fourth side; 220-mesh enclosure; 230-a limiting block; 2311-a guiding inclined plane; 232-a strengthening part; 2321-holding surface; 240-mounting ears; 241-a mounting surface; 2411-a positioning piece; 242-a reinforcing surface; 2421-reinforcement.

Detailed Description

In order to make the aforementioned objects, features and advantages of the present invention comprehensible, embodiments accompanied with figures are described in detail below.

The air conditioner can be applied to air conditioning of a designated area, so that the air quality in the designated area meets the requirements of users, and the life quality of the users is improved. In order to further improve the quality of life, equipment for improving the quality of the air flow led out by the air conditioner can be added on the air conditioner, and the aim is achieved by improving the comfort degree of the air flow led out by the air conditioner to a user. In the prior art, in order to achieve the above purpose, an ion generator is disposed on the air conditioner, and ions released by the ion generator are introduced into an air flow led out by the air conditioner, so that the quality of the air flow led out by the air conditioner can be improved with high efficiency, and the life quality of a user is further improved.

However, in the prior art, when assembling the air conditioner, especially when installing the ionizer, it is necessary to consider that the ionizer can effectively release ions into the air flow discharged from the air conditioner, and it is also necessary to have as little influence on other parts of the air conditioner as possible. Therefore, in the prior art, the mounting and assembly of the ionizer are difficult, and the assembly efficiency of the air conditioner is affected.

In order to solve the technical problem of low assembling efficiency of an ionizer on an air conditioner in the prior art, please refer to fig. 1, the present application provides an air conditioner 10, and the air conditioner 10 can improve the installation efficiency of an ionizer 200, thereby improving the overall installation and assembling efficiency of the air conditioner 10.

Referring to fig. 2 and fig. 3, wherein an arrow at the lower left corner of fig. 2 indicates a preset direction, the air conditioner 10 at least includes an air duct housing 100 and an ion generator 200, the air duct housing 100 is used to enclose an air guiding channel 112 for airflow to flow, that is, the air guiding channel 112 can guide the airflow guided out by the air conditioner 10, so as to guide the airflow guided out by the air conditioner 10 to a specified area, thereby implementing air conditioning of the specified area. The duct casing 100 is further provided with a through hole 111, the through hole 111 is communicated with the air guide passage 112, and the through hole 111 is also used for communicating the air guide passage 112 with the external space of the duct casing 100. The outer side of the air duct casing 100 is provided with a limit buckle 122, and a limit space 1223 is formed between the limit buckle 122 and the air duct casing 100. In addition, the ionizer 200 includes a housing 210, a mesh cap 220, a stopper 230, and a mounting lug 240. The housing 210 is provided therein with a needle electrode and a circuit module connected to the needle electrode, and the circuit module can supply electric energy to the needle electrode and can release ions through the needle electrode. Meanwhile, the needle electrode protrudes to the outside of the housing 210 to discharge ions to the outside of the housing 210. In addition, the mesh enclosure 220, the stopper 230 and the mounting ears 240 are all mounted on the outside of the housing 210. The mesh cap 220 covers the needle electrode protruding from the housing 210 to provide protection for the needle electrode.

When the ion generator 200 is installed in the air duct housing 100, the housing 210 moves along a preset direction and simultaneously drives the mesh enclosure 220, the limiting block 230 and the installation ear 240 to move along the preset direction, and the housing 210 can drive at least part of the mesh enclosure 220 to penetrate through the through hole 111 and extend into the air guide channel 112, so that ions released by the needle electrode inside the mesh enclosure 220 can be released into the air guide channel 112, and further, the sterilization of air flow inside the air guide channel 112 is realized, and the purpose of improving the quality of air flow led out by the air conditioner 10 is realized. While the shell 210 moves along the preset direction and drives the mesh enclosure 220 to extend into the through hole 111, the shell 210 can also drive the limiting block 230 and the mounting lug 240 to move and enable the limiting block 230 to move along the preset direction and enter the limiting space 1223, so that the limiting block 230 and the limiting buckle 122 are matched with each other; while bringing the mounting ears 240 to a predetermined position and enabling the mounting of the ionizer 200 and the duct housing 100 by the detachable connection of the mounting ears 240 and the duct housing 100. Wherein, when stretching into screen panel 220 and needle electrode to wind-guiding passageway 112, just can realize stopper 230 and spacing knot 122 mutually support and remove installation ear 240 to suitable position, and through the mutual demountable connection realization ion generator 200 of installation ear 240 and wind channel casing 100 and the mutual assembly of wind channel casing 100, greatly improved the installation effectiveness of ion generator 200 to provide the installation effectiveness of air conditioner 10, solve the technical problem that ion generator 200 assembly efficiency is low on the air conditioner 10 among the prior art. In addition, the ion generator 200 is mounted outside the air duct housing 100, so that the influence of the ion generator 200 on other parts of the air conditioner 10 can be reduced.

Further, please refer to fig. 2, fig. 3 and fig. 4 in combination, in order to facilitate the purpose of clamping the limiting block 230 into the limiting space 1223, in some implementations of the present application, the limiting block 230 is convexly disposed at the outer side of the housing 210, and the limiting block 230 extends along a straight line, so that when the housing 210 moves along the preset direction, the limiting block 230 can be driven to move along the preset direction into the limiting space 1223, thereby achieving the mutual matching between the limiting block 230 and the limiting buckle 122. It should be noted that, the preset direction is a straight line, so that when the housing 210 moves along the straight line, the limiting block 230 can be driven to move along the straight line, and when the straight line of the preset direction coincides with or is parallel to the straight line formed by the limiting block 230, the housing 210 can drive the limiting block 230 to move into the limiting space 1223.

It should be noted that, in the embodiment of the present application, the housing 210 may have a first side 211 and a second side 212 which are adjacently disposed, and the mesh enclosure 220 is disposed on the first side 211, that is, the needle electrode protrudes from the first side 211 of the mesh enclosure 220, and the mesh enclosure 220 is disposed on the first side 211 to provide a protection effect for the needle electrode. The limiting block 230 is disposed on the second side surface 212 in a protruding manner, and the limiting block 230 extends along a straight line toward the first side surface 211, it should be noted that the direction toward the first side surface 211 refers to a direction toward a side edge of the second side surface 212 close to the first side surface 211 on the second side surface 212. As described above, when the housing 210 is moved in the predetermined direction, that is, when the housing 210 is moved such that the mesh cover 220 moves toward the through hole 111, the stopper 230 simultaneously moves toward the stopper space 1223, and when the mesh cover 220 extends inside the through hole 111, the stopper 230 extends into the stopper space 1223. When the mesh enclosure 220 extends into the air guiding passage 112, the limiting block 230 and the limiting buckle 122 are matched with each other, so as to pre-install the ion generator 200.

In some embodiments of the present application, please refer to fig. 3, fig. 4 and fig. 5 in combination, in order to facilitate the stopper 230 to extend into the stopper space 1223, optionally, a guide inclined surface 2311 is formed on a side of the stopper 230 close to the first side surface 211, and a height of the stopper 230 relative to the second side surface 212 is gradually reduced in a direction toward the first side surface 211. By the arrangement method, when the end of the limiting block 230 close to the first side surface 211 is formed with a smaller width, and the limiting block 230 moves towards the limiting space 1223, the end with the smaller width of the limiting block 230 can preferentially enter the limiting space 1223, so that the limiting block 230 can be ensured to stably move into the limiting space 1223, and the efficiency and stability of the limiting block 230 moving into the limiting space 1223 can be improved. It should be noted that the guide slope 2311 may extend along a straight line or an arc line. Of course, in some embodiments of the present application, the provision of the guide slope 2311 may be eliminated.

In addition, in order to ensure the aesthetic property of the stopper 230, an inclined surface corresponding to the guide inclined surface 2311 may be disposed at an end of the stopper 230 away from the first side surface 211, so that the stopper 230 has a symmetrical pattern. The beauty of the limiting block 230 can be improved through the arrangement mode, and the beauty of the ion generator 200 is further improved. Of course, in other embodiments, the provision of the ramp may be eliminated.

Further, in order to improve the strength of the limiting block 230, in the embodiment of the present application, a reinforcing portion 232 connected to the limiting block 230 is further disposed on the casing 210, and the reinforcing portion 232 is connected to one side of the limiting block 230 and forms an included angle with the limiting block 230. And then can provide the stiffening effect to the stopper 230 from the direction perpendicular to the extending direction of the stopper 230 through the strengthening portion 232, and then can ensure the strength of the stopper 230, so as to ensure that the stopper 230 can be stably matched with the stopper 122.

Certainly, in order to improve the matching accuracy between the limiting block 230 and the limiting buckle 122, the strengthening portion 232 is convexly disposed at one side of the limiting block 230, and when the casing 210 drives the limiting block 230 to move along the predetermined direction, the casing 210 also drives the strengthening portion 232 to abut against the limiting buckle 122 to limit the casing 210 to continue to move along the predetermined direction, which means that the limiting block 230 and the limiting buckle 122 are matched with each other, and the mesh enclosure 220 extends into the predetermined position in the air guiding channel 112. After the limiting block 230 moves into the limiting space 1223 along the predetermined direction and moves to a proper position, the mutual abutting between the reinforcing part 232 and the limiting buckle 122 can limit the first limiting block 230 to continue moving along the predetermined direction, so as to ensure that the limiting block 230 can move to a specific position, thereby ensuring that the limiting buckle 122 provides a stable limiting effect for the limiting block 230.

Optionally, in some embodiments of the present application, the strengthening portion 232 is disposed at one side of the limiting block 230 in a protruding manner, and an extending direction of the strengthening portion 232 is perpendicular to an extending direction of the limiting block 230, so that when the limiting block 230 moves in the predetermined direction and enters the limiting space 1223, the strengthening portion 232 can abut against the limiting buckle 122. In addition, a contact surface 2321 is formed on one side of the strengthening portion 232 close to the mesh enclosure 220, and the contact surface 2321 can contact the position-limiting buckle 122. That is, when the strengthening portion 232 and the position-limiting buckle 122 abut against each other, the position-limiting buckle 122 abuts against the abutting surface 2321 on the strengthening portion 232 on the side close to the mesh enclosure 220, and correspondingly, the strengthening portion 232 abuts against the side of the position-limiting buckle 122 away from the through hole 111 mutually matched with the mesh enclosure 220, so as to achieve the purpose of limiting the casing 210 to continue to move along the predetermined direction. It should be understood that in other embodiments, a reinforced portion 232 may be disposed on a side of the stopper 230 away from the housing 210, and the reinforced portion 232 and the stopper 122 can also abut against each other to limit the housing 210 to move continuously along the predetermined direction, so as to provide a positioning function to the matching position of the stopper 230 and the stopper 122 through the reinforced portion 232.

In an embodiment of the present application, with continued reference to fig. 2, the duct housing 100 includes an enclosure 110 and a mounting plate 120, and the mounting plate 120 and the enclosure 110 are connected to each other and disposed at an angle. The inner side of the surrounding plate 110 is used for surrounding the air guiding channel 112, and the mounting plate 120 is arranged corresponding to the outer side of the surrounding plate 110. The through hole 111 is opened in the shroud 110, and the through hole 111 is provided through the shroud 110 so that the through hole 111 can communicate the air guide passage 112 with the space outside the shroud 110. The position-limiting buckle 122 is convexly arranged on the mounting plate 120, and a position-limiting space 1223 is formed between the position-limiting buckle 122 and the mounting plate 120. The mounting ears 240 are detachably connected to the mounting plate 120 or the enclosing plate 110, so that the ion generator 200 is detachably mounted on the mounting plate 120, and the mesh enclosure 220 passes through the through hole 111 and extends into the air guiding passage 112, and the limiting block 230 extends into the limiting space 1223.

Further, the mounting plate 120 has a mounting area 121 thereon, and the mounting area 121 is used for mounting the ionizer 200. The through hole 111 corresponds to the middle of the mounting area 121, and further corresponds to the mesh enclosure 220 on the first side surface 211; the stopper 122 is disposed on one side of the mounting region 121 to correspond to the stopper 230 on the second side 212. When the ionizer 200 is mounted on the mounting area 121, the housing 210 moves in a preset direction toward above the mounting area 121, and at the same time, the mesh enclosure 220 moves toward the through hole 111, so that the stopper 230 moves toward the stopper space 1223; when the mesh enclosure 220 penetrates into the through hole 111, the limiting block 230 extends into the limiting space 1223. When the limiting block 230 moves to a proper position in the limiting space 1223, the reinforcing portion 232 abuts against a side of the limiting buckle 122 away from the through hole 111, meanwhile, the mesh enclosure 220 extends into the air guiding passage 112, and the housing 210 corresponds to the mounting area 121.

Optionally, referring to fig. 3, the position-limiting buckle 122 includes a connecting portion 1221 and a buckling portion 1222, and the connecting portion 1221 is protruded on the mounting plate 120 and located at one side of the mounting area 121. The latch 1222 is disposed at an end of the connecting portion 1221 away from the mounting plate 120 and extends toward the mounting region 121, so that a limiting space 1223 is formed between the latch 1222 and the mounting plate 120. When the stopper 230 is caught in the stopper space 1223, the catching portion 1222 can provide a stopper function to the stopper 230 in a direction perpendicular to the predetermined direction. When the stopper 230 is snapped into the stopper space 1223, the reinforced portion 232 abuts against a side of the fastening portion 1222 away from the through hole 111.

Further, referring to fig. 2, fig. 6 and fig. 7 in combination, in an embodiment of the present application, the housing 210 further has a third side 213 disposed opposite to the second side 212, and the mounting ear 240 is disposed on the third side 213 of the housing 210, in which the mounting ear 240 corresponds to the mounting plate 120 and is detachably connected to the mounting plate 120. When the mounting ears 240 are mounted on the mounting plate 120, the stability of the mounting of the housing 210 on the mounting plate 120 can be ensured by providing the mounting ears 240 and the stoppers 230 to the housing 210 from both sides of the housing 210, respectively. The position of the mounting plate 120 corresponding to the mounting ear 240 is located on the opposite side of the mounting region 121 from the position of the position-limiting buckle 122.

Based on this, referring to fig. 2, in order to facilitate the installation of the installation lug 240, an installation portion 123 corresponding to the installation lug 240 is protruded on the installation plate 120, and the installation portion 123 is detachably connected with the installation lug 240 to realize the detachable connection between the installation lug 240 and the installation plate 120. When the housing 210 moves along the predetermined direction, the housing 210 drives the stopper 230, the mesh enclosure 220 and the mounting ear 240 to move. When the mesh enclosure 220 passes through the through hole 111 and extends into the air guiding passage 112, the limiting block 230 extends into the limiting space 1223 at a proper position, and the reinforcing portion 232 abuts against the limiting buckle 122, the mounting lug 240 corresponds to the mounting portion 123. The ion generator 200 can then be mounted and assembled by the releasable connection of the mounting ears 240 to the mounting portion 123.

Of course, as shown in fig. 8 and 9, in another embodiment of the present application, the housing further has a fourth side 214 adjacent to the first side 211 and adjacent to the second side 212, and the mounting ears 240 may be disposed on the fourth side 214. At this time, it is also possible to provide a stabilizing effect to the housing 210 from both side surfaces of the housing 210 through the stoppers 230 and the mounting ears 240, respectively, to ensure that the housing 210 is stably mounted on the outer side of the air duct housing 100. In addition, when the mounting ears 240 are mounted on the fourth side 214, the mounting ears 240 are now removably connected to the shroud 110 to enable the housing 210 to be mounted outside of the air chute housing 100. Accordingly, the mounting portion 123 may be protruded from the enclosure 110 to detachably connect with the mounting ear 240, so as to detachably connect the mounting ear 240 with the enclosure 110.

Hereinafter, the mounting portion 123 is described as being projected on the mounting plate 120.

It should be noted that, in some embodiments of the present application, the mounting lug 240 and the mounting portion 123 may be connected by a screw, that is, a screw passes through the mounting lug 240 to be detachably connected with the mounting portion 123, so as to detachably connect the mounting lug 240 to the mounting portion 123. That is, in the embodiment of the present application, when the ion generator 200 is installed, the housing 210 drives the mesh enclosure 220 and the limiting block 230 to move to a specific position, that is, the mesh enclosure 220 passes through the through hole 111 and extends into the air guiding channel 112, and when the limiting block 230 and the limiting buckle 122 are matched with each other, the installation lug 240 and the installation portion 123 are corresponding to each other. After the mounting ears 240 and the mounting portions 123 correspond to each other, the ion generator 200 is mounted by the detachable connection between the mounting ears 240 and the mounting portions 123. Wherein, only need accomplish the dismantlement between one installation ear 240 and the wind channel casing 100 and be connected and can accomplish the installation between ion generator 200 and the wind channel casing 100, can realize the purpose of rapid Assembly ion generator 200, and then improve ion generator 200's assembly efficiency and improve air conditioner 10's assembly efficiency, solve the technical problem that ion generator 200 assembly efficiency is low on the air conditioner 10 among the prior art.

Alternatively, the mounting lug 240 has a mounting surface 241, and the mounting surface 241 is attached to the mounting portion 123 when the mounting lug 240 and the mounting portion 123 are mounted to each other. In order to improve the efficiency of the mutual fit between the mounting lug 240 and the mounting portion 123 and improve the mounting efficiency between the mounting lug 240 and the mounting portion 123, a positioning member 2411 is convexly arranged on the mounting surface 241, and the positioning member 2411 abuts against the side surface of the mounting portion 123 adjacent to the air duct housing 100. That is, when the housing 210 moves along the predetermined direction and the strengthening portion 232 abuts against the position-limiting buckle 122, the positioning member 2411 abuts against the mounting portion 123 to achieve the mutual correspondence between the mounting lug 240 and the mounting portion 123. The positioning element 2411 can improve the accuracy of the mutual correspondence between the mounting lug 240 and the mounting portion 123, and ensure that the mounting lug 240 and the mounting portion 123 are accurately and correspondingly formed into a preset state. Note that, since the mounting portion 123 is provided to protrude from the mounting plate 120, the side surface of the mounting portion 123 adjacent to the duct housing 100 means that the side surface of the mounting plate 120, that is, the peripheral surface of the mounting portion 123 is adjacent to the mounting plate 123.

Further, the mounting portion 123 has a cylindrical shape, and the mounting portion 123 forms an arc-shaped outer circumferential surface, which is a side surface of the mounting portion 123 adjacent to the mounting plate 120. The positioning piece 2411 is bent to form an arc shape matched with the outer peripheral surface of the installation part 123, so that when the casing 210 moves along the preset direction, the concave side surface of the arc positioning piece 2411 can be attached to the outer peripheral surface of the installation part 123, and the positioning accuracy of the positioning piece 2411 is improved, so that the installation ear 240 and the installation part 123 can be accurately positioned. It should be understood that in other embodiments, the positioning member 2411 may be formed in other shapes, such as a V-shape, a U-shape, etc.; alternatively, when the outer peripheral surface of the mounting portion 123 is formed in another shape, the positioning member 2411 may be provided in another shape adapted to the mounting portion 123, for example, when the mounting portion 123 is formed in a prism shape, the positioning member 2411 may be configured to extend along a straight line.

Additionally, in some embodiments of the present application, the side of the mounting ear 240 opposite the mounting surface 241 is a reinforcing surface 242. In order to enhance the strength of the mounting ears 240, the reinforcing members 2421 are protruded from the reinforcing surfaces 242, and the reinforcing members 2421 are further connected to the outer side surface of the housing 210. By providing reinforcement to the mounting ears 240 through the reinforcement members 2421, the bending resistance of the mounting ears 240 can be improved, the strength of the mounting ears 240 can be improved, and the mounting stability of the ionizer 200 can be improved. Optionally, in some embodiments of the present application, the reinforcement 2421 is a plate-shaped structure extending perpendicular to the mounting ear 240, and the reinforcement 2421 may be disposed in a plurality, and the plurality of reinforcement 2421 is disposed on the mounting ear 240 at intervals and connected to the outer side of the housing 210, so as to further improve the strength of the mounting ear 240.

To sum up, when the air conditioner 10 provided in the embodiment of the present application is assembled with the ion generator 200, the shell 210 can be moved to drive the mesh enclosure 220, the mounting lug 240 and the limiting block 230 to move along the preset direction, so that the shell 210 drives the mesh enclosure 220 to penetrate through the through hole 111 and extend into the air guiding channel 112, so that the pin electrode extending into the mesh enclosure 220 releases ions into the air guiding channel 112; meanwhile, when the mesh enclosure 220 extends into the through hole 111, the limiting block 230 is clamped into the limiting space 1223, and the pre-installation of the ion generator 200 is completed. When stopper 230 is moved into position and ionizer 200 is in position, the mounting of ionizer 200 can be accomplished by the detachable connection of mounting ears 240 to duct housing 100. Wherein, when carrying out the assembly of ion generator 200, only need accomplish the dismantlement between one installation ear 240 and the wind channel casing 100 and be connected and can accomplish the installation between ion generator 200 and the wind channel casing 100, can realize the purpose of rapid Assembly ion generator 200, and then improve the assembly efficiency of ion generator 200 and improve the assembly efficiency of air conditioner 10, solve the technical problem that ion generator 200 assembly efficiency is low on the air conditioner 10 among the prior art.

Although the present invention is disclosed above, the present invention is not limited thereto. Various changes and modifications may be effected therein by one skilled in the art without departing from the spirit and scope of the invention as defined in the appended claims.

Claims (13)

1. An air conditioner is characterized by comprising an air duct shell (100) and an ion generator (200);

an air guide channel (112) for airflow to flow is formed on the inner side of the air duct shell (100), a through hole (111) communicated with the air guide channel (112) is formed in the air duct shell (100), a limit buckle (122) is arranged on the air duct shell (100), and a limit space (1223) is formed between the limit buckle (122) and the air duct shell (100);

the ionizer (200) comprises a shell (210), a mesh cover (220), a limiting block (230) and a mounting ear (240), wherein the mesh cover (220), the limiting block (230) and the mounting ear (240) are all mounted on the outer side of the shell (210);

the shell (210) can move along a preset direction to drive at least part of the mesh enclosure (220) to penetrate through the through hole (111) to extend into the air guide channel (112), and can drive the limiting block (230) to be clamped into the limiting space (1223);

the mounting ears (240) are removably attached to the air duct housing (100).

2. The air conditioner according to claim 1, wherein the housing (210) has a first side surface (211) and a second side surface (212) which are adjacently disposed, the mesh cover (220) is disposed on the first side surface (211), the stopper (230) is protrudingly disposed on the second side surface (212), and the stopper (230) extends toward the first side surface (211).

3. The air conditioner according to claim 2, wherein an end of the stopper (230) near the first side surface (211) forms a guide slope (2311) such that a height of the stopper (230) with respect to the second side surface (212) is gradually reduced in a direction toward the first side surface (211).

4. The air conditioner according to claim 2, wherein the stopper (230) extends in a straight line.

5. The air conditioner according to claim 2, wherein the housing (210) is further provided with a reinforcing portion (232), and the reinforcing portion (232) is connected to one side of the limiting block (230) and forms an included angle with the limiting block (230).

6. The air conditioner according to claim 5, wherein the reinforcing portion (232) is disposed at one side of the limiting block (230) in a protruding manner, and when the housing (210) moves along the predetermined direction and drives the limiting block (230) to be clamped into the limiting space (1223), the reinforcing portion (232) can be driven to abut against the limiting buckle (122).

7. The air conditioner according to any one of claims 1 to 6, wherein the duct casing (100) comprises a shroud (110) and a mounting plate (120), the shroud (110) and the mounting plate (120) are arranged at an included angle, the inner side of the shroud (110) is used for enclosing the air guide channel (112), and the mounting plate (120) is arranged at the outer side of the shroud (110);

through-hole (111) run through and establish on bounding wall (110), spacing knot (122) are protruding to be established mounting panel (120) and with mounting panel (120) form jointly spacing space (1223).

8. The air conditioner as claimed in claim 7, wherein the mounting plate (120) has a mounting area (121) thereon, the through hole (111) corresponds to a middle portion of the mounting area (121), and the stopper (122) is disposed at one side of the mounting area (121).

9. The air conditioner as claimed in claim 8, wherein the position-limiting buckle (122) comprises a connecting portion (1221) and a buckling portion (1222), the connecting portion (1221) is protruded on the mounting plate (120) and located at one side of the mounting area (121), the buckling portion (1222) is arranged at one end of the connecting portion (1221) far away from the mounting plate (120) and extends towards the mounting area (121), and the position-limiting space (1223) is formed between the buckling portion (1222) and the mounting plate (120).

10. The air conditioner according to claim 7, characterized in that the mounting plate (120) or the coaming (110) is further provided with a mounting part (123) matched with the mounting ear (240), and the mounting ear (240) is detachably connected with the mounting part (123).

11. The air conditioner according to claim 10, wherein the mounting portion (123) is protruded from the mounting plate (120) or the surrounding plate (110), the mounting lug (240) has a mounting surface (241), the mounting surface (241) is attached to the mounting portion (123), a positioning element (2411) is protruded from the mounting surface (241), and the positioning element (2411) abuts against the side surface of the mounting portion (123) adjacent to the air duct housing (100).

12. The air conditioner according to claim 11, wherein the mounting portion (123) is cylindrical and forms an arc-shaped outer circumferential surface, and the positioning member (2411) is curved in an arc shape and is fitted to the outer circumferential surface of the mounting portion (123).

13. The air conditioner according to claim 11, wherein the mounting ear (240) further has a reinforcing surface (242) disposed opposite to the mounting surface (241), a reinforcing member (2421) is convexly disposed on the reinforcing surface (242), and the reinforcing member (2421) is connected to an outer side surface of the housing (210).

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