CN215929783U - Shell assembly - Google Patents

Abstract

The embodiment of the application discloses a shell assembly. The shell assembly comprises a shell, a door plate and a driving assembly, wherein the shell is provided with an air inlet, the door plate is rotatably connected with the shell to open or close the air inlet, the driving assembly is connected with the shell, and the driving assembly is connected with the door plate to drive the door plate to open or close the air inlet. According to the embodiment of the application, the door plate is driven to rotate by the driving assembly to open or close the air inlet on the shell, so that when the cabinet air conditioner is in a non-working state, the door plate can close the air inlet, and dust is prevented from entering the shell to cause dust accumulation; when the cabinet air conditioner is in a working state, the door plate can open the air inlet and play a role in supporting, and curtains and the like are prevented from being adsorbed on the air inlet due to the fact that the air inlet generates pressure difference, and therefore normal operation of the cabinet air conditioner is guaranteed.

Description

Shell assembly

Technical Field

The application relates to the field of air conditioners, in particular to a shell assembly.

Background

At present, a cabinet air conditioner is usually exposed in the air, and as the air inlet is formed in the shell of the cabinet air conditioner, when the cabinet air conditioner does not work, particles such as dust and the like can enter the shell, so that dust accumulation is generated in the shell; when the cabinet air conditioner runs, the pressure difference generated by the air inlet of the cabinet air conditioner can cause curtains and the like to be adsorbed at the air inlet, and the air inlet effect of the cabinet air conditioner is influenced.

SUMMERY OF THE UTILITY MODEL

The embodiment of the application provides a shell assembly, can solve among the prior art outer shell air intake and easily produce the dust and pile up and adsorb the problem of (window) curtain.

The embodiment of the application provides a housing assembly, housing assembly is used for cabinet air conditioner, housing assembly includes:

the shell is provided with an air inlet;

the door plate is rotatably connected with the shell to open or close the air inlet;

and the driving assembly is connected with the door panel to drive the door panel to open or close the air inlet.

Optionally, in some embodiments of the present application, the door panel has a rotation axis with respect to the housing, the rotation axis extending in a height direction of the housing.

Optionally, in some embodiments of the present application, the air inlet has a first side and a second side that are opposite to each other in a height direction of the housing;

the first side edge is provided with a first mounting hole, a first mounting part is arranged at the position of the door panel corresponding to the first mounting hole, and the first mounting part is rotatably mounted in the first mounting hole so as to enable the door panel to be rotatably connected with the shell; alternatively, the first and second electrodes may be,

the first side is provided with the second installation department, the door plant corresponds the position of second installation department is provided with the second mounting hole, the second installation department rotates to be installed in the second mounting hole, so that the door plant with the shell rotates to be connected.

Optionally, in some embodiments of the present application, the air inlet has a third side and a fourth side that are opposite to each other, and the third side is connected between the first side and the second side; the fourth side is connected between the first side and the second side;

the door plate is rotatably connected with the third side edge; or the like, or, alternatively,

the door plate is rotatably connected with the fourth side edge.

Optionally, in some embodiments of the present application, the door panel includes a first sub-door panel and a second sub-door panel, the first sub-door panel is rotatably connected to the third side, and the second sub-door panel is rotatably connected to the fourth side; the driving assembly is connected with the first sub door panel and the second sub door panel to drive the first sub door panel and the second sub door panel to open or close the air inlet.

Optionally, in some embodiments of the present application, an edge of the first sub-door panel away from the third side edge is at least partially located on one side of the second sub-door panel.

Optionally, in some embodiments of the present application, a limiting portion is disposed on an edge of the first sub-door panel away from the third side edge, and the limiting portion is located on one side of the second sub-door panel; the second sub-door plate and the side face opposite to the limiting part are provided with accommodating grooves, and at least part of the limiting part is accommodated in the accommodating grooves.

Optionally, in some embodiments of the present application, the limiting portion extends along an edge of the first sub-door panel away from the third side edge; the receiving groove extends along an edge of the second sub-door panel away from the fourth side.

Optionally, in some embodiments of the application, the housing is provided with a plurality of air inlets, and the plurality of air inlets are sequentially distributed along a height direction of the housing; and each air inlet is correspondingly provided with the door plate and the driving assembly.

Optionally, in some embodiments of the present application, the driving assembly includes:

a motor coupled to the housing, the motor having a drive shaft;

the air inlet is formed in the door plate, one end of the driving piece is connected with a driving shaft of the motor, the other end of the driving piece is connected with the door plate, and the driving shaft of the motor rotates to drive the driving piece to rotate so that the door plate can be opened or closed.

The shell assembly comprises a shell, a door plate and a driving assembly, an air inlet is formed in the shell, the door plate is rotatably connected with the shell, the driving assembly is connected with the shell, and the driving assembly is connected with the door plate. The door plate is driven to rotate by the driving assembly to open or close the air inlet, so that when the cabinet air conditioner is in a non-working state, the door plate can close the air inlet, and dust is prevented from entering the shell to cause dust accumulation; when the cabinet air conditioner is in a working state, the door plate can open the air inlet and play a role in supporting, and curtains and the like are prevented from being adsorbed on the air inlet due to the fact that the air inlet generates pressure difference, and therefore normal operation of the cabinet air conditioner is guaranteed.

Drawings

In order to more clearly illustrate the technical solutions in the embodiments of the present application, the drawings needed to be used in the description of the embodiments are briefly introduced below, and it is obvious that the drawings in the following description are only some embodiments of the present application, and it is obvious for those skilled in the art to obtain other drawings based on these drawings without creative efforts.

Fig. 1 is a schematic structural diagram of a cabinet air conditioner provided in an embodiment of the present application when being turned on;

fig. 2 is a schematic structural diagram of a cabinet air conditioner provided by an embodiment of the present application when the cabinet air conditioner is turned off;

FIG. 3 is an enlarged schematic view of area A in FIG. 1 according to an embodiment of the present disclosure;

fig. 4 is an enlarged schematic view of a region B in fig. 1 according to an embodiment of the present disclosure.

Description of reference numerals:

Detailed Description

The technical solutions in the embodiments of the present application will be clearly and completely described below with reference to the drawings in the embodiments of the present application, and it is obvious that the described embodiments are only a part of the embodiments of the present application, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present application. Furthermore, it should be understood that the detailed description and specific examples, while indicating exemplary embodiments of the invention, are given by way of illustration and explanation only, and are not intended to limit the scope of the invention. In the present application, unless indicated to the contrary, the use of the directional terms "upper" and "lower" generally refer to the upper and lower positions of the device in actual use or operation, and more particularly to the orientation of the figures of the drawings; while "inner" and "outer" are with respect to the outline of the device.

The embodiment of the application provides a casing subassembly and cabinet air conditioner. The following are detailed below. It should be noted that the following description of the embodiments is not intended to limit the preferred order of the embodiments.

First, the embodiment of the application provides a shell assembly for cabinet air conditioner, and the shell assembly includes shell, door plant and drive assembly, wherein, has seted up the air intake on the shell, and the door plant rotates with the shell to be connected in order to open or close the air intake, and drive assembly is connected with the shell, and drive assembly and door plant are connected in order to drive the door plant and open or close the air intake.

As shown in fig. 1 and 2, in the case assembly 100 of the embodiment of the present application, which is used for the cabinet air conditioner 10, the case assembly 100 includes an outer casing 110, the outer casing 110 is an outer contour of the entire cabinet air conditioner 10, and by structurally designing the outer casing 110, an appearance of the cabinet air conditioner 10 can be optimized, and an overall aesthetic feeling of the cabinet air conditioner 10 is enhanced.

The housing 110 is provided with an air inlet 111, and when the cabinet air conditioner 10 works, indoor air enters the inside of the cabinet air conditioner 10 from the air inlet 111 and is blown out after heat exchange is performed by other components in the cabinet air conditioner 10, so that circulation and heat exchange of the indoor air are realized.

Optionally, the housing assembly 100 includes a door 120, and the door 120 is rotatably connected to the housing to open or close the air inlet 111. When the cabinet air conditioner 10 is in a non-operating state, since the housing assembly 100 is exposed in the air, particles such as dust in the air can enter the interior of the housing assembly 100 through the air inlet 111 on the outer shell 110, so that dust accumulation is caused, and the heat exchange effect of the cabinet air conditioner 10 is affected. Through setting up door plant 120 for when cabinet air conditioner 10 stopped operating, door plant 120 can close air intake 111, prevents inside particles such as dust from getting into housing assembly 100, thereby guarantees cabinet air conditioner 10's normal operating.

In addition, when the cabinet air conditioner 10 is in an operating state, the air inlet 111 generates a pressure difference due to air circulation, and when the cabinet air conditioner 10 is placed near a window, objects such as curtains and the like are adsorbed to the air inlet 111 due to the pressure difference, and even the air inlet 111 is shielded, so that the air inlet effect of the cabinet air conditioner 10 is affected.

Therefore, by rotatably connecting the door panel 120 with the outer shell 110, when the cabinet air conditioner 10 is in an operating state, the door panel 120 is rotated to a position for opening the air inlet 111, so that indoor air enters the interior of the housing assembly 100 through the air inlet 111; meanwhile, the door plate 120 itself can be used as a support to isolate the air inlet 111 and the curtain, so as to prevent the curtain from being adsorbed to the air inlet 111, thereby ensuring the normal air inlet effect of the cabinet air conditioner 10.

Optionally, the casing assembly 100 further includes a driving assembly 130, the driving assembly 130 is connected to the outer casing 110, and the driving assembly 130 is connected to the door panel 120 and drives the door panel 120 to open or close the air inlet 111. The driving assembly 130 is used as driving power of the housing assembly 100 to directly control the rotation mode of the door panel 120, and different rotation requirements of the door panel 120 can be met by the structural design of the driving assembly 130 and the design of the connection mode of the driving assembly 130 and the door panel 120, so that the application range of the housing assembly 100 is expanded.

In the embodiment of the present application, the casing assembly 100 includes the outer casing 110, the door panel 120 and the driving assembly 130, by rotatably connecting the door panel 120 with the outer casing 110, the driving assembly 130 is connected with the door panel 120 and drives the door panel 120 to open or close the air inlet 111, so that when the cabinet air conditioner 10 is in a stop operation state, the door panel 120 can close the air inlet 111 to prevent dust and the like from entering the inside of the casing assembly 100; meanwhile, when the cabinet air conditioner 10 is in an operating state, the door panel 120 can open the air inlet 111 and serve as a support to isolate the air inlet 111 and the curtain, so that the curtain is prevented from being adsorbed on the air inlet 111 due to pressure difference, and normal operation of the cabinet air conditioner 10 is ensured.

Alternatively, the door panel 120 has a rotational axis relative to the housing 110, i.e., the door panel 120 rotates relative to the housing 110 about the rotational axis. The extending direction of the rotation axis is directly related to the setting mode and the rotation direction of the door panel 120, and only the door panel 120 can shield dust when closing the air inlet 111 and the door panel 120 can play a role of a support when opening the air inlet 111, which is not limited herein.

Alternatively, the door panel 120 extends in the height direction of the outer shell 110 relative to the rotation axis of the outer shell 110, that is, the rotation axis is aligned with the height direction of the outer shell 110, and the door panel 120 rotates around the height direction of the outer shell 110. At this time, the door panel 120 rotates towards the left and right sides of the outer shell 110 in the rotating process, and the plane where the door panel 120 is located is always parallel to the height direction of the outer shell 110, that is, the door panel 120 does not collapse due to the self-gravity, thereby ensuring the stability of the door panel 120 relative to the outer shell 110.

It should be noted that the rotation axis of the door panel 120 relative to the outer shell 110 can be perpendicular to the height direction of the outer shell 110, that is, the door panel 120 rotates to the upper side and the lower side of the outer shell 110 when rotating, and due to the influence of the gravity of the door panel 120, a support structure needs to be disposed between the door panel 120 and the outer shell 110, so as to avoid the door panel 120 collapsing due to the influence of the gravity and affecting the normal operation of the cabinet air conditioner 10 during the operation of the cabinet air conditioner 10.

Optionally, the air inlet 111 has a first side 112 and a second side 113 opposite to each other along the height direction of the housing 110, that is, the air inlet 111 has upper and lower sides opposite to each other along the height direction of the housing 110.

As shown in fig. 3, in some embodiments, the first side 112 is provided with a first mounting hole 1121, the door panel 120 is provided with a first mounting portion 1211 at a position corresponding to the first mounting hole 1121, and the first mounting portion 1211 is rotatably mounted in the first mounting hole 1121, so that the door panel 120 is rotatably connected to the housing 110. That is, the door panel 120 and the housing 110 are engaged with each other through the first mounting hole 1121 and the first mounting portion 1211 to realize the rotation of the door panel 120 around the rotation axis so as to open or close the air inlet 111.

In order to further ensure the stability of the door panel 120 relative to the housing 110, a first sub-mounting hole is simultaneously formed in a position of the second side 113 corresponding to the first mounting hole 1121, a first sub-mounting portion is formed in a position of the door panel 120 corresponding to the first sub-mounting hole, and the first sub-mounting portion is rotatably mounted in the first sub-mounting hole, so that the door panel 120 is rotatably connected to the housing 110. That is, the door panel 120 is rotatably connected to the first side 112 and the second side 113 of the outer shell 110, so that the door panel 120 is prevented from falling off during the rotation process, and the structural stability of the housing assembly 100 is improved.

It should be noted that, the arrangement positions of the first sub-mounting hole and the first sub-mounting portion can be replaced with each other, and only the first sub-mounting hole and the first sub-mounting portion are required to be matched with each other to ensure the normal rotation of the door panel 120 relative to the housing 110.

In other embodiments, the first side 112 is provided with a second mounting portion, the door panel 120 is provided with a second mounting hole at a position corresponding to the second mounting portion, and the second mounting portion is rotatably mounted in the second mounting hole, so that the door panel 120 is rotatably connected with the outer shell 110. That is, the door panel 120 and the outer shell 110 are mutually matched with each other through the second mounting hole and the second mounting portion, so that the door panel 120 is rotated around the rotation axis to open or close the air inlet 111.

The second side 113 is provided with a second sub-mounting portion corresponding to the second mounting portion, the door panel 120 is provided with a second sub-mounting hole corresponding to the second sub-mounting portion, and the second sub-mounting portion is rotatably mounted in the second sub-mounting hole, so that the door panel 120 is rotatably connected to the housing 110. That is, the door panel 120 is rotatably connected to the first side 112 and the second side 113 of the outer shell 110, so that the door panel 120 is prevented from falling off during the rotation process, and the structural stability of the housing assembly 100 is improved.

It should be noted that the positions of the second sub-mounting portion and the second sub-mounting hole can be replaced with each other, and only the second sub-mounting portion and the second sub-mounting hole are required to be matched with each other to ensure the normal rotation of the door panel 120 relative to the housing 110.

In addition, the installation positions of the installation portion and the installation hole directly affect the overall structural design of the housing assembly 100 and the rotation mode of the door panel 120. The first side 112 is provided with a first mounting hole 1121, and the door panel 120 is provided with a first mounting portion 1211 at a position corresponding to the first mounting hole 1121.

If the first mounting holes 1121 are disposed in the two side regions of the first side 112, and the first mounting portions 1211 are also disposed in the two side regions of the door 120, when the door 120 rotates relative to the housing 110, the door 120 is opened or closed in the two side regions of the air inlet 111, that is, when the door 120 is opened, the door 120 is located outside the air inlet 111 and does not extend into the air inlet 111, which is beneficial to disposing other components of the cabinet air conditioner 10 in the air inlet 111, and improving the space utilization rate of the cabinet air conditioner 10.

If the first mounting hole 1121 is disposed in the middle area of the first side 112 and the first mounting portion 1211 is correspondingly disposed in the middle area of the door 120, when the door 120 rotates relative to the housing 110, the door 120 is opened or closed in the middle area of the air inlet 111, that is, when the door 120 is opened, the door 120 is partially located outside the air inlet 111 and partially extends into the air inlet 111, so that a part of space needs to be reserved for the door 120 to rotate to ensure that the door 120 does not collide with other components in the cabinet air conditioner 10 when rotating.

Although the overall space utilization rate of the cabinet air conditioner 10 can be reduced by the structure, the door panel 120 is located in the middle area and is more beneficial to the isolation of the door panel 120 to the curtain compared with the door panel 120 located in the two side areas, so that the curtain is prevented from being adsorbed at the air inlet 111 due to the pressure difference generated at the air inlet 111, and the air inlet effect of the cabinet air conditioner 10 is ensured.

Optionally, the air inlet 111 has a third side 114 and a fourth side 115, which are oppositely disposed, the third side 114 is connected between the first side 112 and the second side 113, and the fourth side 115 is connected between the first side 112 and the second side 113, that is, the air inlet 111 has left and right sides opposite to the upper and lower sides.

The door panel 120 is rotatably connected to the third side 114 or rotatably connected to the fourth side 115, that is, the door panel 120 is directly rotatably connected to one of the left and right sides to open or close the air inlet 111 of the door panel 120, without providing the first mounting hole 1121 on the first side 112, and the first sub-door panel 121 is provided with the first mounting portion 1211 at the corresponding position, so as to avoid the risk that the door panel 120 is jammed and cannot be used normally in the using process of the housing assembly 100 due to the difference in precision between the first mounting hole 1121 and the first mounting portion 1211.

It should be noted that the door panel 120 and the third side 114 or the fourth side 115 can be hinged, connected by hinges, connected by rotating shafts, or connected by other rotating methods, and only the door panel 120 and the third side 114 or the fourth side 115 need to be connected in a normal rotating manner, so that the door panel 120 can open or close the air inlet 111.

In some embodiments, under the condition that the sufficient matching precision of the mounting hole and the mounting portion is ensured, the door panel 120 can be rotatably connected to the first side 112 through the mutual matching between the first mounting hole 1121 and the first mounting portion 1211, and at the same time, rotatably connected to the third side 114 or the fourth side 115 through a hinge connection, a rotating shaft connection, or the like, so as to perform double protection on the rotational connection between the door panel 120 and the housing 110, thereby further improving the structural stability of the door panel 120 and the housing 110, and ensuring the stable use of the housing assembly 100.

Optionally, the door panel 120 includes a first sub-door panel 121 and a second sub-door panel 122, the first sub-door panel 121 is rotatably connected to the third side 114, the second sub-door panel 122 is rotatably connected to the fourth side 115, and the driving assembly 130 is connected to the first sub-door panel 121 and the second sub-door panel 122 to drive the first sub-door panel 121 and the second sub-door panel 122 to open or close the air inlet.

Wherein, first sub-door plant 121 and second sub-door plant 122 open to both sides from the middle zone of air intake 111, and first sub-door plant 121 and second sub-door plant 122 form bearing structure respectively in the left and right sides of air intake 111 simultaneously, compare in door plant 120 and support at the unilateral of air intake 111, this kind of structural design more is favorable to preventing at cabinet air conditioner 10 operation in-process, and air intake 111 leads to the (window) curtain to adsorb at air intake 111 owing to there is pressure differential to influence cabinet air conditioner 10's air inlet effect.

In some embodiments, the first sub-door panel 121 and the second sub-door panel 122 open from both sides of the air intake 111 to a middle area of the air intake 111. That is, the first sub-door panel 121 and the second sub-door panel 122 are respectively matched with the first installation portion 1211 through the first installation hole 1121, so as to realize the rotational connection between the first sub-door panel 121 and the second sub-door panel 122 and the shell 110.

It should be noted that, when the surface of the outer shell 110 is of an arc-shaped structure, in order to ensure that the first sub-door panel 121 and the second sub-door panel 122 can open the air inlet 111 in a sufficient area, the curvature of the surface of the first sub-door panel 121 and the surface of the second sub-door panel 122 departing from the air inlet 111 should be reduced, and the opening area of the air inlet 111 is prevented from being affected by mutual collision when the first sub-door panel 121 and the second sub-door panel 122 are opened, so as to ensure the air inlet effect of the cabinet air conditioner 10.

In other embodiments, the first sub-door panel 121 opens from the middle area of the air inlet 111 to the left side of the air inlet 111, and the second sub-door panel 122 opens from the right side of the air inlet 111 to the middle area of the air inlet 111, that is, the first sub-door panel 121 is rotatably connected to the housing 110 through the cooperation of the first mounting hole 1121 and the first mounting portion 1211, or the first sub-door panel 121 is rotatably connected to the housing 110 through the rotation of the third side 114, and the second sub-door panel 122 is rotatably connected to the housing 110 through the cooperation of the first mounting hole 1121 and the first mounting portion 1211 in the middle area of the air inlet 111.

Due to the structural design, when the first sub-door panel 121 and the second sub-door panel 122 are used as a support to isolate the curtain, the distance between the first sub-door panel 121 and the second sub-door panel 122 is reduced, so that the risk that the curtain is adsorbed to the air inlet 111 between the first sub-door panel 121 and the second sub-door panel 122 is reduced.

It should be noted that the rotation connection manners of the first sub-door panel 121 and the second sub-door panel 122 and the outer shell 110 can be interchanged, that is, the first sub-door panel 121 is connected to the outer shell 110 in a rotation manner through the first mounting hole 1121 and the first mounting portion 1211 which are engaged with each other in the middle area of the air inlet 111, and the second sub-door panel 122 is connected to the outer shell 110 in a rotation manner through the fourth side 115. That is, the first sub-door panel 121 is opened from the left side of the air inlet 111 to the middle area of the air inlet 111, and the second sub-door panel 122 is opened from the middle area of the air inlet 111 to the right side of the air inlet 111.

Optionally, the edge of the first sub-door panel 121 away from the third side edge 114 is at least partially located on one side of the second sub-door panel 122. That is, when the first sub-door panel 121 and the second sub-door panel 122 close the air inlet 111, the edge portions of the first sub-door panel 121 and the second sub-door panel 122 are overlapped, so as to ensure that the air inlet 111 is completely shielded when the first sub-door panel 121 and the second sub-door panel 122 are closed, and prevent dust from entering the interior of the housing assembly 100 due to a gap between the first sub-door panel 121 and the second sub-door panel 122.

In the actual use process, the driving assembly 130 controls the rotation angle and the rotation speed of the first sub door panel 121 and the second sub door panel 122 to adjust the positions of the first sub door panel 121 and the second sub door panel 122, so that the first sub door panel 121 and the second sub door panel 122 are ensured not to collide or interfere with each other in the rotation process, and the air inlet 111 is not closed due to insufficient rotation angle.

The driving assembly 130 includes a sensing device, and in the rotation process of the first sub-door panel 121 and the second sub-door panel 122, the sensing device can determine whether to effectively close the air inlet 111 according to whether the first sub-door panel 121 and the second sub-door panel 122 are in contact with each other; if the first sub-door panel 121 and the second sub-door panel 122 collide or squeeze, the sensing device controls the driving assembly 130 to adjust the rotation angle of the first sub-door panel 121 or the second sub-door panel 122, so as to ensure the normal operation of the first sub-door panel 121 and the second sub-door panel 122.

Optionally, a limit part is arranged at an edge of the first sub-door panel 121 away from the third side 114, and the limit part is located at one side of the second sub-door panel 122; the second sub-door plate 122 has an accommodating groove formed in a side surface opposite to the limiting portion, and at least part of the limiting portion is accommodated in the accommodating groove, so that the first sub-door plate 121 and the second sub-door plate 122 are matched with each other to close the air inlet 111.

Due to the influence of the processing precision in the actual manufacturing process, the first sub-door panel 121 and the second sub-door panel 122 may not be perfectly matched, so that when the first sub-door panel 121 and the second sub-door panel 122 close the air inlet 111, the first sub-door panel 121 and the second sub-door panel 122 cannot be located on the same plane or the same curved surface, which affects the aesthetic property of the cabinet air conditioner 10, and also easily causes the dust accumulation due to the existence of gaps on the upper and lower sides of the air inlet 111.

The edge of keeping away from third side 114 through at first sub-door plant 121 sets up spacing portion, the holding tank has been seted up to the side that second sub-door plant 122 is relative with spacing portion, make holding tank on the second sub-door plant 122 have certain fault-tolerant rate to the spacing portion of first sub-door plant 121, spacing portion only needs the part to be located the holding tank promptly, can guarantee that first sub-door plant 121 can not take place the extrusion with second sub-door plant 122, also enable the clearance between first sub-door plant 121 and the second sub-door plant 122 and effectively sheltered from, it is inside to avoid entering casing assembly 100 such as dust.

It should be noted that the limiting portion on the first sub-door panel 121 and the accommodating groove on the second sub-door panel 122 can be replaced with each other, that is, the limiting portion is arranged on the second sub-door panel 122, the accommodating groove is arranged at the corresponding position of the first sub-door panel 121, the positions of the limiting portion and the accommodating groove can be adjusted according to design requirements, specific limitation is not required here, and only the first sub-door panel 121 and the second sub-door panel 122 need to be matched with each other to enable the air inlet 111 to be effectively closed by ensuring the limiting portion and the accommodating groove.

Optionally, the limiting portion of the first sub-door panel 121 extends along an edge of the first sub-door panel 121 away from the third side 114, and the receiving groove of the second sub-door panel 122 extends along an edge of the second sub-door panel 122 away from the fourth side 115. The limiting portion is disposed on the whole edge of the first sub-door panel 121 far away from the third side 114, and correspondingly, the accommodating groove is disposed on the whole edge of the second sub-door panel 122 far away from the fourth side 115, so that when the first sub-door panel 121 and the second sub-door panel 122 close the air inlet 111, all gaps between the first sub-door panel 121 and the second sub-door panel 122 can be effectively shielded, and the dust is further prevented from entering the inside of the housing assembly 100.

Optionally, because the cabinet air conditioner 10 is higher, in order to reduce the manufacturing difficulty of the shell assembly 100 and improve the stability of the door panel 120, the outer shell 110 is provided with a plurality of air inlets 111, and the plurality of air inlets 111 are sequentially distributed along the height direction of the outer shell 110; each air inlet 111 is correspondingly provided with a door panel 120 and a driving assembly 130 to open or close each air inlet 111, so as to shield or support each air inlet 111.

When the door panel 120 corresponding to each air inlet 111 includes the first sub-door panel 121 and the second sub-door panel 122, the rotation manner thereof may refer to the description of the related embodiments, and details are not repeated herein.

If two air inlets 111 are formed in the outer shell 110, and each air inlet 111 is correspondingly formed in a single door panel 120, when the rotation directions of the upper and lower door panels 120 are the same, the door panel 120 only supports one area of the curtain, and the curtain cannot be effectively prevented from being adsorbed to the air inlets 111.

Therefore, when the rotation directions of the door panels 120 corresponding to the upper and lower air inlets 111 are set, the door panels 120 of the upper and lower air inlets 111 are opened in different directions, so as to ensure that the curtain is not adsorbed to the air inlet 111 due to the pressure difference generated by the air inlet 111 when the door panel 120 opens the air inlet 111, thereby ensuring the air inlet effect of the cabinet air conditioner 10.

It should be noted that the plurality of air inlets 111 can also be distributed left and right to realize air circulation in different directions and enhance the air inlet effect of the cabinet air conditioner 10, and the specific setting mode thereof can be adjusted accordingly according to actual design requirements, and is not limited herein.

Optionally, in the embodiment of the present application, the driving assembly 130 includes a motor 131 and a driving member 132, wherein the motor 131 is connected to the housing 110, and the motor 131 has a driving shaft; one end of the driving member 132 is connected to the driving shaft of the motor 131, the other end of the driving member 132 is connected to the door panel 120, the driving shaft of the motor 131 rotates to drive the driving member 132 to rotate, and the driving member 132 drives the door panel 120 to rotate to open or close the air inlet 111.

The motor 131 can be installed inside or outside the housing 110, and is fixedly connected to the housing 110 through a screw, and the specific setting mode can be adjusted according to the rotation requirement of the door panel 120. Through the design of the control mode of the motor 131 and the connection mode of the driving member 132, the rotation mode of the door panel 120 can be controlled to meet the application requirements of different door panel 120 structures.

It should be noted that, when the driving element 132 is connected to the door panel 120, the connection position of the driving element 132 and the door panel 120 is parallel to the connection line of the first installation portion 1211 and the rotation axis of the door panel 120, so that the driving element 132 can support the door panel 120 to a certain extent, and at the same time, can ensure that the door panel 120 rotates normally around the rotation axis, thereby opening or closing the air inlet 111.

Optionally, the door panel 120 includes a first sub-door panel 121 and a second sub-door panel 122, and the driving assembly 130 includes only one motor 131, that is, the motor 131 drives the first sub-door panel 121 and the second sub-door panel 122 simultaneously to open or close the air inlet 111. When the connection mode between the motor 131 and the first and second sub-door panels 121 and 122 is designed, the driving shaft of the motor 131 can be connected to the crank, the crank is connected to the driving members 132, and the rotation direction of the driving members 132 is set according to the requirement, so as to drive the first and second sub-door panels 121 and 122 to open or close the air inlet 111, thereby reducing the production cost of the housing assembly 100.

Optionally, the door panel 120 includes a first sub-door panel 121 and a second sub-door panel 122, the driving assembly 130 includes two motors 131, and the motors 131 correspond to the first sub-door panel 121 and the second sub-door panel 122, respectively, so as to drive the first sub-door panel 121 and the second sub-door panel 122 to open or close the corresponding air inlet 111, and a connection manner between the motor 131 and the first sub-door panel 121 and the second sub-door panel 122 is designed and adjusted according to rotation conditions of the first sub-door panel 121 and the second sub-door panel 122.

Through the corresponding setting of motor 131 with first sub-door plant 121 and second sub-door plant 122, can realize motor 131 to the accurate control of first sub-door plant 121 and the sub-door plant 122 rotation mode of second to can adjust the rotation mode of first sub-door plant 121 or the sub-door plant 122 of second alone according to actual design demand, be favorable to satisfying different casing assembly 100 structural design demands, enlarge casing assembly 100's range of application.

It should be noted that the door panel 120 can include a plurality of sub-door panels, and correspondingly, the motor 131 drives the plurality of sub-door panels simultaneously to open or close the air inlet 111, that is, the number of the sub-door panels and the driving manner between the motor 131 and the sub-door panels can be adjusted accordingly according to design requirements, and it is only necessary to ensure that the plurality of sub-door panels normally open or close the air inlet 111.

Secondly, this application embodiment also provides a cabinet air conditioner, this cabinet air conditioner includes the casing subassembly, and the concrete structure of this casing subassembly refers to above-mentioned embodiment, because this cabinet air conditioner has adopted the whole technical scheme of above-mentioned all embodiments, consequently has at least all beneficial effects that the technical scheme of above-mentioned embodiment brought. And will not be described in detail herein.

As shown in fig. 1 and 4, the cabinet air conditioner 10 in the embodiment of the present application includes a housing assembly 100, and a grill 200 and a filter screen disposed in the housing assembly 100, wherein the grill 200 and the filter screen are disposed at a position corresponding to the air inlet 111 of the housing assembly 100, and are used for filtering air entering the air inlet 111.

When the cabinet air conditioner 10 is in a non-operating state, because the cabinet air conditioner 10 is exposed in the air, particles such as dust in the air can enter the inside of the housing assembly 100 through the air inlet 111, and the grille 200 and the filter screen can play a certain role in blocking the dust, thereby preventing the dust from affecting the normal operation of other components inside the housing 110. However, the dust is directly accumulated on the grille 200 and the filter screen, and the accumulated dust is difficult to clean due to the small distance between the grille 200, and finally the air intake effect of the cabinet air conditioner 10 is directly affected.

This application embodiment is through setting up door plant 120 at air intake 111, and when cabinet air conditioner 10 was in non-operation state, air intake 111 can be closed to door plant 120 to it gets into inside shell 110 to block the dust from air intake 111, avoids the dust to produce on grid 200 and filter screen and piles up, can guarantee cabinet air conditioner 10's air inlet effect, also can reduce the washing frequency of grid 200 and filter screen, reduces cabinet air conditioner 10's use cost.

In addition, when the cabinet air conditioner 10 is in a non-operating state, since the door panel 120 closes the air inlet 111, the grille 200 is closed inside the air inlet 111 and is not exposed outside, so that the overall beauty of the cabinet air conditioner 10 can be improved.

In the foregoing embodiments, the descriptions of the respective embodiments have respective emphasis, and for parts that are not described in detail in a certain embodiment, reference may be made to related descriptions of other embodiments.

The above detailed description is made on a housing assembly and a cabinet air conditioner provided in the embodiments of the present application, and specific examples are applied herein to explain the principle and the embodiments of the present application, and the description of the above embodiments is only used to help understand the method and the core idea of the present application; meanwhile, for those skilled in the art, according to the idea of the present application, there may be variations in the specific embodiments and the application scope, and in summary, the content of the present specification should not be construed as a limitation to the present application.

Claims (10)

1. A housing assembly for a cabinet air conditioner, the housing assembly comprising:

the shell is provided with an air inlet;

the door plate is rotatably connected with the shell to open or close the air inlet;

and the driving assembly is connected with the door panel to drive the door panel to open or close the air inlet.

2. The housing assembly of claim 1, wherein the door panel has an axis of rotation relative to the outer shell, the axis of rotation extending in a height direction of the outer shell.

3. The housing assembly of claim 1, wherein the intake vent has a first side and a second side disposed opposite each other along a height of the housing;

the first side edge is provided with a first mounting hole, a first mounting part is arranged at the position of the door panel corresponding to the first mounting hole, and the first mounting part is rotatably mounted in the first mounting hole so as to enable the door panel to be rotatably connected with the shell; alternatively, the first and second electrodes may be,

the first side is provided with the second installation department, the door plant corresponds the position of second installation department is provided with the second mounting hole, the second installation department rotates to be installed in the second mounting hole, so that the door plant with the shell rotates to be connected.

4. The housing assembly of claim 3, wherein the intake vent has third and fourth oppositely disposed sides, the third side being connected between the first and second sides; the fourth side is connected between the first side and the second side;

the door plate is rotatably connected with the third side edge; or the like, or, alternatively,

the door plate is rotatably connected with the fourth side edge.

5. The housing assembly of claim 4, wherein the door panel comprises a first sub-door panel pivotally connected to the third side and a second sub-door panel pivotally connected to the fourth side; the driving assembly is connected with the first sub door panel and the second sub door panel to drive the first sub door panel and the second sub door panel to open or close the air inlet.

6. The housing assembly of claim 5, wherein an edge of the first sub-door panel distal from the third side edge is at least partially on a side of the second sub-door panel.

7. The shell assembly of claim 6, wherein an edge of the first sub-door panel away from the third side edge is provided with a limiting portion, and the limiting portion is located on one side of the second sub-door panel; the second sub-door plate and the side face opposite to the limiting part are provided with accommodating grooves, and at least part of the limiting part is accommodated in the accommodating grooves.

8. The housing assembly of claim 7, wherein the stop extends along an edge of the first subgate away from the third side; the receiving groove extends along an edge of the second sub-door panel away from the fourth side.

9. The housing assembly of claim 1, wherein the housing defines a plurality of air inlets, and the plurality of air inlets are sequentially distributed along a height direction of the housing; and each air inlet is correspondingly provided with the door plate and the driving assembly.

10. The housing assembly of claim 1, wherein the drive assembly comprises:

a motor coupled to the housing, the motor having a drive shaft;

the air inlet is formed in the door plate, one end of the driving piece is connected with a driving shaft of the motor, the other end of the driving piece is connected with the door plate, and the driving shaft of the motor rotates to drive the driving piece to rotate so that the door plate can be opened or closed.

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