CN210399153U - Indoor machine of cabinet air conditioner - Google Patents

Abstract

The utility model provides a cabinet air conditioner indoor unit, which comprises a shell, an air supply fan arranged in the shell, a heat exchanger, an air guide component and a driving mechanism; the air guide component comprises at least three air guide rings which are provided with front and rear openings and are communicated with each other in the middle, the air guide rings are sequentially arranged in the front and rear direction to form a through air channel which penetrates through the air guide rings, a jet opening is formed between every two adjacent air guide rings, the jet opening is configured to guide heat exchange air flow to the through air channel and blow the air flow forwards so as to drive the air in the through air channel to be sent forwards to an air outlet positioned on the front side of the shell; the driving mechanism is connected with the at least two adjacent air guide rings and is configured to enable the at least two air guide rings to move so as to change the orientations of front and rear openings of the at least two air guide rings, so that the air supply direction of the through air duct is changed, the air supply range of the indoor unit is enlarged, the uniformity of the temperature in the room is improved, and better refrigerating and heating experience is provided for users.

Description

Indoor machine of cabinet air conditioner

Technical Field

The utility model relates to an air treatment technical field especially relates to a cabinet air conditioner indoor unit.

Background

The air conditioner is one of the necessary household appliances, and the cabinet air conditioner indoor unit is a common indoor unit form, and has the characteristics of high power and quick refrigeration and heating, so that the application is very wide.

The existing cabinet air conditioner indoor unit can not adjust the air outlet direction of the air outlet, so that the temperature of the area opposite to the air outlet and other areas around the air outlet has deviation, and the temperature in the room is not uniform. Further, since the wind blown out from the outlet tends to be concentrated in the central area, when the user is in the central area, the user is directly blown by the wind to feel uncomfortable, and the cooling and heating delay is felt in other areas than the central area. Therefore, the existing cabinet air conditioner indoor unit has poor use experience for users.

Disclosure of Invention

An object of the utility model is to provide a cabinet air conditioner indoor set that use experience is good.

A further object of the present invention is to provide a cabinet air conditioner with a softer and more uniform air supply temperature.

Particularly, the utility model provides a cabinet air conditioner indoor unit, it includes:

the air conditioner comprises a shell, a fan and a fan, wherein an air inlet is formed in the shell, and an air outlet is formed in the front wall of the shell;

a blower configured to draw in ambient air from an ambient environment of the air inlet and urge the ambient air to flow toward the air outlet;

the heat exchanger is arranged on an air inlet flow path between the air inlet and the air supply fan and is used for exchanging heat with ambient air entering from the air inlet so as to form heat exchange airflow;

the air guide component comprises at least three air guide rings which are provided with front and rear openings and are communicated with each other in the middle, the air guide rings are sequentially arranged in the front and rear direction to form a through air channel which penetrates through the air guide rings, a jet opening is formed between every two adjacent air guide rings, and the jet opening is configured to guide heat exchange air flow to the through air channel and blow the air flow forwards so as to drive the air in the through air channel to be sent to the air outlet forwards; and

and the driving mechanism is connected with the at least two adjacent wind guide rings and configured to enable the at least two wind guide rings to move so as to change the air supply direction.

Optionally, the number of the air guide rings is at least four, the at least two air guide rings are two air guide rings located in the middle, the two air guide rings are two middle air guide rings, and the two middle air guide rings are configured to move under the driving of the driving mechanism.

Optionally, the air guide member further comprises:

the mounting plate is positioned in front of the air guide ring at the foremost side, is arranged in the shell and is provided with an opening communicated with the through air duct;

the drive mechanism includes:

the motor is arranged below the front side of the mounting plate and is provided with an output shaft parallel to the height direction of the shell;

the driving box is positioned below the air guide ring, the front end of the driving box is arranged on the mounting plate, the rear end of the driving box is arranged on the air guide ring behind the rear middle air guide ring, and a first fixed shaft which is parallel to the output shaft and extends upwards is formed in the driving box;

the first crank is positioned in the driving box, is rotatably connected with the first fixed shaft, and is provided with a first connecting shaft which is parallel to the output shaft and extends upwards and a second connecting shaft which extends downwards, and the first connecting shaft penetrates through the driving box and is fixedly connected with the lower end of the middle air guide ring positioned in front;

one end of the second crank is fixedly connected with the output shaft, and a rotating shaft which is parallel to the output shaft and extends upwards is formed at the other end of the second crank; one end of the driving connecting rod is connected with the rotating shaft of the second crank, and the other end of the driving connecting rod penetrates through the driving box to be connected with the second connecting shaft so as to drive the middle air guide ring positioned in front to rotate leftwards or rightwards; and

the two ends of each balance connecting rod are respectively and rotatably connected with the upper ends of the two middle air guide rings, so that when the middle air guide ring positioned in front rotates, the middle air guide ring positioned in the rear is driven to synchronously rotate.

Optionally, the drive mechanism further comprises:

the supporting box is positioned above the air guide ring, the front end of the supporting box is arranged on the mounting plate, and the rear end of the supporting box is arranged on the air guide ring behind the rear middle air guide ring;

and the third crank is positioned in the support box and is provided with a third connecting shaft which is parallel to and opposite to the first connecting shaft, and the third connecting shaft penetrates through the support box and extends downwards to be fixedly connected with the upper end of the middle air guide ring positioned in front.

Optionally, a second fixed shaft parallel to the first fixed shaft is formed in the driving box;

the drive mechanism further includes:

the fourth connecting shaft is positioned in the driving box, is parallel to the first connecting shaft, is connected with the second fixed shaft at the lower end, and is rotatably connected with the lower end of the middle air guide ring positioned at the rear part by penetrating through the driving box at the upper end;

and the fifth connecting shaft is positioned in the supporting box, is parallel to and opposite to the fourth connecting shaft, and penetrates through the supporting box to be rotatably connected with the upper end of the middle air guide ring positioned at the rear part.

Optionally, a first limiting part is formed in the driving box, and comprises a first slide rail consistent with the rotation path of the first crank and two first limiting columns located at two ends of the first slide rail;

a second limiting part is formed in the support box and comprises a second slide rail consistent with the rotation path of the third crank and two second limiting columns positioned at two ends of the second slide rail;

under the drive of the motor and the drive connecting rod, the first crank slides along the first slide rail and drives the front middle air guide ring to rotate, so that the third crank is driven to slide along the second slide rail and simultaneously drives the rear middle air guide ring to synchronously rotate.

Optionally, the number of the balance links is two, and the two balance links are located at both lateral sides of the support box in the lateral direction.

Optionally, the driving box comprises a first box body with an open upper end and a first cover plate covering the open upper end of the first box body; the first limiting part is formed on the inner side of the upper wall of the first cover plate;

the supporting box comprises a second box body with an open upper end and a second cover plate covering the open upper end of the second box body; the second limiting part is formed on the inner side of the bottom wall of the second box body.

Optionally, the inner side of the bottom wall of the first box body is further formed with a screw post extending upwards at the front side of the first fixed shaft, so that the first box body is connected with the first cover plate by a screw inserted into the screw post; the driving connecting rod is provided with an avoiding hole for the screw column to pass through.

Optionally, a natural air inducing port is formed in a region of the rear wall of the casing, which is opposite to the through air duct, so that when the jet port ejects the air flow in the through air duct forward, ambient air around the natural air inducing port flows forward to enter the through air duct and is mixed with the heat exchange air flow blown out by the jet port.

The utility model discloses a cabinet air conditioner indoor unit makes two adjacent at least wind-guiding circles the motion through setting up actuating mechanism, changes the open-ended orientation around these two at least wind-guiding circles to the change link up the air supply direction in wind channel, the air supply scope of increase indoor set promotes the homogeneity of room internal temperature, and experience for the user provides the refrigeration better and heats.

Further, the utility model discloses an among the cabinet air conditioner indoor unit, through position and the structure of optimizing each part among the actuating mechanism, make the horizontal hunting of wind-guiding circle more stable to make the inside part compact structure of indoor set, the space in the make full use of indoor set casing has reduced occupation space on the one hand, and on the other hand also can reduce the air supply windage.

Further, the utility model discloses an among the cabinet air conditioner indoor unit, form and link up the communicating natural wind induced air mouth in wind channel through the rear wall at the casing, when the jet orifice will link up the air current in the wind channel and spout forward, make the ambient air around the natural wind induced air mouth flow forward get into link up the wind channel in mix with the heat transfer air current that the jet orifice blew off, and blow to indoor from the air outlet that is located the front side, so increased whole air supply distance and air supply volume, and make the air current that blows soft, form the heat and not dry, cool and the comfortable wind that does not cool, user experience is more comfortable.

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

Drawings

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

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

fig. 2 is a side view of a cabinet air conditioner indoor unit according to an embodiment of the present invention;

fig. 3 is a side view of the air guide member and the driving mechanism of the indoor unit of the cabinet air conditioner according to an embodiment of the present invention;

fig. 4 is a schematic perspective view of the air guide member and the driving mechanism of the indoor unit of the cabinet air conditioner according to an embodiment of the present invention;

FIG. 5 is an exploded schematic view of FIG. 4;

fig. 6 is a schematic partial exploded view of a wind guide member of an indoor unit of a cabinet air conditioner according to an embodiment of the present invention;

fig. 7 is an exploded view of the driving box of the air guide member of the indoor unit of the cabinet air conditioner and its internal components in one direction according to an embodiment of the present invention;

fig. 8 is an exploded view of the driving box of the air guide member and its internal components of the cabinet air conditioner indoor unit according to another embodiment of the present invention; and

fig. 9 is an exploded view of the support box of the air guide member and its internal components of the indoor unit of the cabinet air conditioner according to an embodiment of the present invention.

Detailed Description

For convenience of description, the directions "up", "down", "front", "back", "top", "bottom", "transverse", etc. mentioned in the description are defined according to the spatial position relationship of the cabinet air conditioner 100 in the normal working state, for example, as shown in fig. 2, the side of the cabinet air conditioner 100 facing the user is front, and the side close to the wall is back. The lateral direction means a direction parallel to the width direction of the indoor unit 100.

Figure 1 is a schematic perspective view of a cabinet air conditioner indoor unit 100 according to one embodiment of the present invention,

fig. 2 is a side view of a cabinet air conditioner indoor unit 100 according to an embodiment of the present invention.

The cabinet air conditioner indoor unit 100 generally includes a cabinet, an air supply assembly, and a heat exchanger.

As shown in fig. 1 and 2, the casing may generally include a front panel 101, a casing 102 at the rear of the front panel 101, and a base 107 at the bottom, the front panel 101, the casing 102, and the base 107 cooperating to define a heat exchanging plenum chamber. The housing is provided with an air inlet 101c and an air outlet 101a, wherein the air outlet 101a is formed on a front wall of the housing, that is, the front panel 101. In some embodiments, the intake vent 101c is formed in a rear wall of the housing, which may also be understood as being formed in a rear wall of the enclosure 102. In an alternative embodiment, the air inlet may be formed at a side of the cabinet.

In some embodiments, the front wall of the indoor unit 100 may further have another air outlet 101b, the another air outlet 101b is located below the air outlet 101a, as shown in fig. 1, the another air outlet 101b is formed at a position close to the bottom end of the lower portion of the front panel 101, and the air outlet 101a is formed at a position close to the top end of the upper portion of the front panel 101.

And the heat exchanger (not shown) is arranged on the air inlet flow path between the air supply assembly and the air inlet 101c to exchange heat with the ambient air entering from the air inlet 101c to form heat exchange airflow. The heat exchanger is used as a part of a refrigeration system, the refrigeration system can be realized by utilizing a compression refrigeration cycle, and the compression refrigeration cycle realizes heat transfer by utilizing a compression phase change cycle of a refrigerant in a compressor, a condenser, an evaporator and a throttling device. The refrigerating system can also be provided with a four-way valve to change the flow direction of the refrigerant, so that the heat exchanger can be alternately used as an evaporator or a condenser to realize the refrigerating or heating function. Since the compression refrigeration cycle in the air conditioner is well known to those skilled in the art, the operation principle and structure thereof will not be described herein.

And an air supply assembly (not shown) disposed in the heat exchange air supply chamber and including an air supply fan, wherein in the embodiment where the indoor unit 100 only has the air outlet 101a, the air supply fan is configured to draw in ambient air from the surroundings of the air inlet 101c and force the ambient air to flow toward the air outlet 101 a. In the embodiment where the indoor unit 100 has the air outlet 101a and the other air outlet 101b, the air supply assembly further includes another air supply fan configured to draw in ambient air from the surroundings of the air inlet 101c and cause it to flow toward the other air outlet 101 b. Wherein, air supply fan, another air supply fan all can be centrifugal fan, and centrifugal fan's axis of rotation can extend along the fore-and-aft direction of casing.

Fig. 3 is a side view of the air guide member 10 and the driving mechanism of the cabinet air conditioner indoor unit 100 according to an embodiment of the present invention, fig. 4 is a perspective view of the air guide member 10 and the driving mechanism of the cabinet air conditioner indoor unit 100 according to an embodiment of the present invention, and fig. 5 is an exploded view of fig. 4.

Specifically, as shown in fig. 3 to 5 in combination with fig. 1, the indoor unit 100 of the present embodiment further includes an air guiding member 10, which includes at least three air guiding rings 110 having front and rear openings and a through center, wherein the air guiding rings 110 are sequentially arranged in the front and rear direction to form a through air channel 1101 penetrating through each air guiding ring 110, a jet opening 110a is formed between two adjacent air guiding rings 110, and the jet opening 110a is configured to guide the heat exchange air flow to the through air channel 1101 and blow the air flow forward, so as to drive the air in the through air channel 1101 to be sent forward to the air outlet 101 a. That is to say, each wind-guiding ring 110 is an annular wind-guiding ring which is through from front to back, each wind-guiding ring 110 has its own air inlet and air outlet, the rear opening of each wind-guiding ring 110 is its air inlet, the front opening is its air outlet, at least three wind-guiding rings 110 are arranged in sequence along the front-back direction, a jet opening 110a is formed between two adjacent wind-guiding rings 110, and two adjacent wind-guiding rings 110 are communicated through their through front-back openings, thereby forming a through air duct 1101.

As described above, in the present embodiment, the air outlet 101a may be formed at a position close to the top end of the upper portion of the front panel 101, and accordingly, the air guiding member 10 is located in a space close to the top end in the enclosure, obviously, the air guiding member 10 is located above the air supply fan, and the heat exchange air flow flows upward through the air supply fan, enters the through air duct 1101 through the jet opening 110a between two adjacent air guiding rings 110, flows forward, and is blown to the room through the air outlet 101 a.

In some embodiments, as shown in fig. 2, in order to match the through air duct 1101, a natural air inducing port 101d is provided in a region of the rear wall of the housing opposite to the through air duct 1101, and when the jet port 110a ejects the air flow in the through air duct 1101 forward, ambient air around the natural air inducing port 101d is caused to flow forward, enter the through air duct 1101, mix with the heat exchange air flow blown out by the jet port 110a, and blow into the room from the air outlet 101a located on the front side, so that the overall air supply distance and the air supply amount are increased, and the blown air flow is soft, and forms warm, cool and non-cold comfortable air, so that the user experience is more comfortable. Wherein, the natural wind inducing opening 101d and the air outlet 101a can be both circular.

In the embodiment where the indoor unit 100 has the other air outlet 101b, the indoor unit 100 may control the start and stop of the blower and the other blower according to the operation mode, so as to blow the air flow from the air outlet 101a and/or the other air outlet 101b into the room. For example, in the cooling mode, the air supply fan may be turned on, the other air supply fan may be turned off, the heat exchange air flow may enter the through air duct 1101 through the jet port 110a under the driving of the air supply fan, and a sufficient negative pressure may be formed in the through air duct 1101, so that the ambient air around the natural air inducing port 101d may enter the through air duct 1101 under the negative pressure to mix with the heat exchange air flow, and then may be discharged through the air outlet 101a, thereby improving the air supply comfort. In the heating mode, the air supply fan can be turned off, the other air supply fan is turned on, the heat exchange air flow is sent out from the other air outlet 101b positioned below under the driving of the other air supply fan, hot air is sent out from the bottom of the indoor unit 100, foot warming type air supply is realized, and the leg and foot positions of a user can be rapidly heated.

More particularly, the indoor unit 100 of the present embodiment further includes a driving mechanism, which is connected to at least two adjacent wind-guiding rings 110 and configured to move the at least two wind-guiding rings 110 to change the blowing direction thereof. That is, at least two adjacent wind-guiding rings 110 can move, swing or rotate under the driving of the driving mechanism, or perform a compound motion combining at least two motions of moving, swinging and rotating. Therefore, the direction of the front opening of the corresponding air guide ring 110 can be directly changed through the rotation or swing of the at least two air guide rings 110, that is, the air supply direction of a partial section of the through air duct 1101 is changed, so that the air supply direction of the air outlet 101a is directly adjusted, the air supply coverage is enlarged, and the cooling and heating effects are uniformly and quickly achieved in the whole indoor area. Moreover, the air supply direction can be adjusted conveniently by a user according to the requirement of the user, and the use experience of the user is improved. Or the size of the jet opening 110a between the at least two wind-guiding rings 110 and the adjacent wind-guiding ring 110 can be changed by the movement of the at least two wind-guiding rings 110, so as to change the amount of air blown into the through air duct 1101 by the different jet openings 110a, thereby realizing the adjustment of the air blowing direction of the air outlet 101a by using the change of the amount of air blown by the different jet openings 110 a.

In the indoor unit 100 of this embodiment, the driving mechanism is arranged to move the at least two adjacent air guide rings 110, and the directions of the front and rear openings of the at least two air guide rings 110 are changed, so as to change the air supply direction of the through air duct 1101, increase the air supply range of the indoor unit 100, improve the uniformity of the temperature in the room, and provide better cooling and heating experience for the user.

In some embodiments, the number of the wind-guiding rings 110 is at least four, wherein the at least two wind-guiding rings 110 are two wind-guiding rings 110 located in the middle, and the two wind-guiding rings 110 are two middle wind-guiding rings configured to move under the driving of the driving mechanism. That is, if the number of the wind-guiding rings 110 is at least four and is even, the two middle wind-guiding rings are two wind-guiding rings located at the middle of the wind-guiding ring; if the number of the wind-guiding rings 110 is at least four and is odd, the wind-guiding ring 110 located in the middle is one of the middle wind-guiding rings 110, and the wind-guiding ring 110 located adjacent to the front side or the wind-guiding ring 110 located adjacent to the rear side of the wind-guiding ring 110 located in the middle can be used as the other middle wind-guiding ring 110. Therefore, by driving the two middle wind-guiding rings 110 to move, the wind-guiding rings 110 on the front side and the wind-guiding rings 110 on the rear side of the two middle wind-guiding rings 110 can be used for providing support for the installation of the driving mechanism, and the layout compactness of all parts is ensured.

As shown in fig. 3, in the present embodiment, four wind-guiding rings 110 are sequentially marked as a front wind-guiding ring, a first middle wind-guiding ring, a second middle wind-guiding ring, and a rear wind-guiding ring from front to back. The inner peripheral wall of each air guide ring 110 can be in a cylindrical shape gradually reduced from back to front, the air outlet of the back air guide ring extends into the air inlet (namely, a back opening) of the second middle air guide ring, the air outlet of the second middle air guide ring extends into the air inlet of the first middle air guide ring, the air outlet of the first middle air guide ring extends into the air inlet of the front air guide ring, and the air guide rings 110 are arranged at intervals in a non-contact manner, so that an annular jet opening 110a is defined by a gap between every two adjacent air guide rings 110. The jet port 110a forms a continuous outwardly-expanding coanda surface by means of the outwardly-expanding outer peripheral surface of the jet air ring 110 located on the front side, and the ambient air in the through air duct 1101 can be driven by the acceleration of the airflow through the jet port 110 a. The ambient air is mixed with the heat-exchange air flow ejected from the ejection port 110a, thereby increasing the air supply distance and the air supply amount and forming soft comfortable air.

Referring to fig. 3, a plurality of flow deflectors 1102 distributed at intervals along the circumferential direction of the outer wall of each air guiding ring 110 may be formed, and the flow deflectors 1102 extend toward the jet orifice 110a and are used for dividing the jet orifice 110a into a plurality of jet sub-orifices uniformly distributed along the circumferential direction, so that the heat exchange air flow uniformly enters the through air duct 1101 along the circumferential direction.

Fig. 6 is a schematic diagram of a partial explosion of the air guide member 10 of the cabinet air conditioner indoor unit 100 according to an embodiment of the present invention, fig. 7 is a schematic diagram of an explosion of the driving box 130 of the air guide member 10 of the cabinet air conditioner indoor unit 100 and its internal components in one direction according to an embodiment of the present invention, fig. 8 is a schematic diagram of an explosion of the driving box 130 of the air guide member 10 of the cabinet air conditioner indoor unit 100 and its internal components in another direction according to an embodiment of the present invention, and fig. 9 is a schematic diagram of an explosion of the supporting box 120 of the air guide member 10 of the cabinet air conditioner indoor unit 100 and its internal components according to an embodiment of the present invention.

Referring to fig. 3 to 5, the air guide member 10 further includes a mounting plate 140 located in front of the foremost air guide ring 110, and provided in the casing and having an opening 140a penetrating the through air duct 1101. That is, the mounting plate 140 may be mounted on the inner side of the front panel 101 of the cabinet, with the rear side of the opening 140a thereof facing and communicating with the through-air duct 1101 and the front side facing and communicating with the air outlet 101 a. As shown in fig. 5, an opening 140a is formed on the front wall of the mounting plate 140, the opening 140a may be circular, and another wind-guiding ring 141 extending from the rear to the front of the opening 140a is formed on the mounting plate 140. The front end of the other wind-guiding ring 141 is butted with the upper wind outlet 101a, the rear end of the other wind-guiding ring 141 is inserted into the front end of the wind-guiding ring 110 at the frontmost side, and the inner peripheral wall of the other wind-guiding ring 141 can be extended gradually from the rear to the front, so that the wind-outlet area of the upper wind-guiding member 10 can be enlarged, and the wind-supplying range can be increased.

Referring to fig. 5 and 7, the driving mechanism may include a motor 150, a driving cartridge 130, a first crank 133, a second crank 151, a driving link 160, and at least one horizontally extending balancing link 105.

The motor 150 may be a stepping motor, and is disposed under the front side of the mounting plate 140, and specifically, the motor 150 is fixed under the front side of the mounting plate 140 by a fixing member 152. The motor 150 has an output shaft parallel to the height direction of the housing, and the output shaft may extend upward.

The driving case 130 may be located below the wind-guiding ring 110, and the front end thereof is disposed on the mounting plate 140, and the rear end thereof is disposed on one wind-guiding ring 110 behind the middle wind-guiding ring 110 located behind. Referring to fig. 4 and 5, the number of the wind-guiding rings 110 is four, the front end of the driving box 130 is disposed on the mounting plate 140, and the rear end is disposed on the wind-guiding ring 110 at the rearmost side.

A first fixing shaft 1311 is formed in the drive case 130 to extend upward in parallel with the output shaft, the first crank 133 is disposed in the drive case 130, is rotatably coupled to the first fixing shaft 1311, and has a first coupling shaft 1333 extending upward in parallel with the output shaft and a second coupling shaft 1332 extending downward, and the first coupling shaft 1333 penetrates through the drive case 130 and is fixedly coupled to a lower end of the front middle air guide ring 110. One end of the second crank 151 is fixedly connected to the output shaft, and the other end thereof is formed with a rotating shaft extending upward in parallel to the output shaft, and one end of the driving link 160 is connected to the rotating shaft of the second crank 151, and the other end thereof passes through the driving case 130 to be connected to the second connecting shaft 1332. Thus, the driving link 160 and the first crank 133 drive the middle wind-guiding ring 110 located at the front to rotate left or right.

The balance connecting rods 105 are located above the two middle wind-guiding rings 110, and two ends of each balance connecting rod 105 are respectively connected with the upper ends of the two middle wind-guiding rings 110 in a rotating manner, so that when the middle wind-guiding ring 110 located in front rotates under the driving of the motor 150 and the driving connecting rod 160, the middle wind-guiding ring 110 located in rear is driven to rotate synchronously. Thereby realizing synchronous leftward or rightward rotation of the two middle wind-guiding rings 110.

In some embodiments, as shown in fig. 7, a second fixing shaft 1312 parallel to the first fixing shaft 1311 may be further formed in the drive case 130, and a fourth connecting shaft 134 parallel to the first connecting shaft 1333 is further disposed in the drive case 130, and has a lower end connected to the second fixing shaft 1312 and an upper end passing through the drive case 130 to be rotatably connected to the rear middle wind-guiding ring 110, thereby providing a supporting point for the lower end of the rear middle wind-guiding ring 110 and ensuring stable rotation of the rear middle wind-guiding ring 110.

In some embodiments, referring to fig. 9 in combination with fig. 3 to 5, the driving mechanism may further include a support box 120 and a third crank 123 located in the support box 120, the support box 120 is located above the wind-guiding ring 110, a front end of the support box is disposed on the mounting plate 140, and a rear end of the support box is disposed on one wind-guiding ring located behind the rear middle wind-guiding ring 110. The third crank 123 is located in the support box 120, and has a third connecting shaft 1232 parallel to and opposite to the first connecting shaft 1333, the third connecting shaft 1232 passes through the support box 120 and extends downward to be fixedly connected with the upper end of the middle wind-guiding ring 110 located in front, and rotates along with the rotation of the middle wind-guiding ring 110 located in front, so that the upper and lower ends of the middle wind-guiding ring 110 located in front are both supported, and the rotation stability of the middle wind-guiding ring 110 located in front is ensured.

Referring to fig. 9 again, as shown in fig. 7, a fifth connecting shaft 124 may be further disposed in the supporting box 120, and is parallel to and opposite to the fourth connecting shaft 134, and the fifth connecting shaft 124 passes through the supporting box 120 and is rotatably connected to the upper end of the rear middle wind-guiding ring 110, so as to provide a supporting point for the upper end of the rear middle wind-guiding ring 110, and further increase the stability of the rotation of the rear middle wind-guiding ring 110.

In the indoor unit 100 of the present embodiment, the positions and the structures of the components in the driving mechanism are optimized, so that the internal components of the indoor unit 100 are compact, the space in the casing of the indoor unit 100 is fully utilized, and on one hand, the occupied space is reduced, and on the other hand, the air supply wind resistance can also be reduced.

In the indoor unit 100 of this embodiment, the two intermediate air guiding rings 110 can synchronously rotate leftwards or rightwards, or periodically swing left and right, so as to provide various air supply modes for users and meet the diversity requirements of users.

Referring to fig. 5 and 6, each of the two middle wind-guiding rings 110 and the wind-guiding ring 110 behind the middle wind-guiding ring 110 includes a wind-guiding ring body 111 and extension plates 112 formed at the upper end and the lower end of the wind-guiding ring body 111, the extension plate 112 at the upper end of the wind-guiding ring body 111 extends upward, and the extension plate 112 at the lower end of the wind-guiding ring body 111 extends downward.

Referring to fig. 4 and 5, the number of the wind-guiding rings 110 is four, and the rear end of the driving box 130 is disposed on the lower extension plate 112 of the wind-guiding ring 110 at the rearmost side. Accordingly, the rear end of the support box 120 is disposed on the upper extension plate 112 of the rearmost deflector 110.

Referring to fig. 6, and referring to fig. 4 and 5, two ends of the balance link 105 are respectively rotatably connected to the upper ends of the two intermediate wind-guiding rings 110 through two rotating shafts 1051. In some embodiments, there are two balancing links 105, and the two balancing links 105 are located at both lateral sides of the support box 120 in the lateral direction. As shown in fig. 6, the two middle air guiding rings 110 have two upper extending plates 112 respectively having two lateral ends formed with shaft holes 112a engaged with the corresponding rotating shafts 1051, the two middle air guiding rings 110 have two other shaft holes 112b formed at substantially middle positions in the lateral direction of the two middle air guiding rings 112, the other shaft hole 112b at the upper position of the middle air guiding ring 110 at the front side is engaged with the third connecting shaft 1232, and the other shaft hole 112b at the upper position of the middle air guiding ring 110 at the rear side is engaged with the fifth connecting shaft 124. Accordingly, the other lower shaft hole 112b of the front middle air-guiding ring 110 is fitted with the first connecting shaft 1333, and the other lower shaft hole 112b of the rear middle air-guiding ring 110 is fitted with the fourth connecting shaft 134.

In the indoor unit 100 of the present embodiment, the two balance connecting rods 105, the driving box 130, the supporting box 120, the connecting shafts, and other components are designed to be at the above special positions, so that the middle positions and the two end positions of the two middle air guiding rings 110 in the transverse direction have supporting points, and the stability of the left and right rotation of the two middle air guiding rings 110 is greatly improved.

As shown in fig. 8 and 9 in combination with fig. 7, a first limiting portion 1322 is further formed in the driving box 130, and includes a first slide rail 13222 corresponding to the rotation path of the first crank 133 and two first limiting columns 13221 located at two ends of the first slide rail 13222. As shown in fig. 7 and 8, the first crank 133 may include a handle portion 1331, the first connecting shaft 1333 is formed at one end of the handle portion 1331 and extends upward, the second connecting shaft 1332 is formed at the other end of the handle portion 1331 and extends downward, and the first crank 133 is driven by the driving link 160 to rotate, so that the handle portion 1331 slides along the first slide rail 13222.

The support case 120 has a second stopper 1211 formed therein, which includes a second slide rail 12112 corresponding to the rotation path of the third crank 123 and two second stopper posts 12111 provided at both ends of the second slide rail 12112. Referring to fig. 9, the third crank 123 may include another handle 1231, the aforementioned third connecting shaft 1232 is formed at one end of the another handle 1231 and extends downward, and the third crank 123 rotates with the intermediate wind-guiding ring 110, so that the another handle 1231 slides along the second sliding rail 12112. In this way, the two first limiting columns 13221 and the two second limiting columns 12111 are used to adjust the left and right rotation amplitudes of the two intermediate air guiding rings 110 by controlling the motor 150. The left rotation amplitude and the right rotation amplitude of the two middle wind-guiding rings 110 may be the same or different, and the left rotation or the right rotation angle of the two middle wind-guiding rings 110 may be 10 ° to 15 °.

The driving cartridge 130 includes a first cartridge body 131 having an open upper end and a first cover 132 covering the open upper end of the first cartridge body 131. The first fixing shaft 1311 and the second fixing shaft 1312 are formed at the inner side of the bottom wall of the first case 131, extend upward from the bottom wall of the first case 131, and the first limiting portion 1322 is formed at the inner side of the upper wall of the first cover 132. Therefore, the components in the drive box 130 are arranged more compactly and do not interfere with each other, so that the first position-limiting portion 1322 can be better matched with the first crank 133 for position limitation.

Referring to fig. 5, 7 and 8, the bottom wall of the first case 131 is formed with two screw columns, a screw column 1313 and a screw column 1314, respectively, the screw column 1313 may be positioned at the front side of the first fixing shaft 1311, and extends upward, the screw column 1313 may have two screw holes (see fig. 7), and accordingly, the upper wall of the first cover plate 132 is formed with another three screw columns, respectively, a screw column 1321, a screw column 1323, and a screw column 1324, one screw hole of the screw column 1321 and one screw hole of the screw column 1323 are respectively in one-to-one correspondence with and opposed to the two screw holes of the screw column 1313, the front region of the first case 131 is fixed to the front region of the first cover 132 by means of the screws 135 sequentially passing through the screw posts 1313 and the screw posts 1323, the rear sub-region of the first case 131 and the rear region of the first cover 132 are fixed by screws sequentially passing through the screw posts 1314 and 1324.

The screw column 1321 may penetrate through the upper wall of the first cover plate 132, another screw column 113 (see fig. 5) extending downward is formed at the lower end of the foremost air guide ring 110, and the drive case 130 is fixed to the lower end of the foremost air guide ring 110 by a screw 135 penetrating through the screw column 1313, the screw column 1321 and the screw column 113 in sequence. And the wind-guiding ring 110 at the rearmost side can be fixed to the inner side of the rear wall of the cover 102 of the cabinet by the screw column 106.

Referring to fig. 7 again, the driving link 160 is formed with an avoiding hole 160a for the screw column 1313 to pass through, so that the space occupied by the driving link 160 and the screw column 1313 in the driving box 130 can be reduced, the area of the driving box 130 is reduced, the influence of the driving box 130 on the air volume is further reduced, the wind resistance is reduced, the air volume is increased (referring to fig. 3, the straight arrow in fig. 3 indicates the flowing direction of the heat exchange airflow to the wind guide member 10), and meanwhile, the problem of condensation caused by the fact that a local area of each wind guide ring 110 is shielded by the driving box 130 in the refrigeration mode can also be avoided. And the screw column 1313 can limit the movement of the driving link 160, so as to ensure the movement stability of the driving link 160, thereby increasing the movement stability of the two intermediate wind-guiding rings 110.

In order to further reduce the wind resistance caused by the driving box 130, as shown in fig. 7 and 8, the lateral side edges 131a of the first box body 131 are designed to be streamline structures with the middle concaved inwards, so that the area of the first box body 131 is reduced, the influence of the driving box 130 on the wind volume is reduced, the condensation problem at the bottom end of the wind guide ring 110 in the cooling mode is further reduced, and the airflow flows more smoothly. Here, it can be understood that a direction close to a center line extending forward and backward of the first case 131 is an inner side. The lateral side edges 131a of the first case 131 may be symmetrically arranged with respect to the center line.

The bottom wall of the first box 131 includes a first section 131b located at the middle of the transverse direction and two second sections 131c smoothly transitioning from the first section 131b to the two lateral edges 131a, wherein the first section 131b is located at a position lower than the second section 131 c. This increases the volume of the space between the first section 131b and the first cover 132, provides a space for accommodating the position of the driving link 160, and allows the airflow to flow upward more smoothly through the smooth upward extending second section 131 c.

Accordingly, the first cover 132 has a shape matching the shape of the first case 131, and specifically, the lateral edges of the first cover 132 have a streamline structure with a concave middle toward the inner side, so as to reduce the overall area of the driving case 130 and increase the smoothness of the airflow.

Referring to fig. 9, the supporting box 120 includes a second box 121 with an open upper end and a second cover 122 covering the open upper end of the second box 121, the second limiting portion 1211 is formed on the inner side of the bottom wall of the second box 121, and the second box 121 located below is used to support the third crank 123 and the fifth connecting shaft 124. The bottom wall of the second container 121 may further be formed with three screw posts extending upward, two screw posts 1214 located at the front and rear sides of the second limiting portion 1211, and two screw posts 1213 located at the rear of the screw post 1214 located at the frontmost side, respectively, and correspondingly, the second cover 122 is formed with two screw posts (not shown) corresponding to and opposite to the two screw posts 1214, respectively, and the second container 121 and the second cover 122 are fixed by two screws passing through the two screw posts 1314 and the two screw posts on the second cover 122, respectively.

And the screw column 1213 may penetrate the bottom wall of the second casing 121, and another screw column 113 (see fig. 5) extending upward is formed at the upper end of the foremost air-guiding ring 110, and the support case 120 and the upper end of the foremost air-guiding ring 110 are fixed by screws sequentially penetrating the screw column 1213 and the screw column 113.

As shown in fig. 9, the lateral edges of the second box 121 of the supporting box 120 and the lateral edges of the second cover plate 122 are both streamline structures with the middle recessed inwards, so as to reduce the area of the supporting box 120, thereby reducing the influence of the supporting box 120 on the air volume, further reducing the problem of condensation on the top end of the air guide ring 110 in the cooling mode, and making the airflow flow more smooth. It is understood that the direction close to the center line of the support box 120 extending forward and backward is the inner side, and both lateral side edges of the support box 120 may be symmetrically distributed with respect to the center line.

In the indoor unit 100 of the embodiment, by specially designing the arrangement positions and structures of the driving box 130 and the supporting box 120, the influence of the driving box 130 and the supporting box 120 on the air volume is reduced, the wind resistance is reduced, the condensation problem at the upper end and the lower end of the air guide ring 110 is reduced to a certain extent, and the material consumption is reduced.

Thus, 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 in detail herein, many other variations and modifications can be made, consistent with the principles of the invention, which are directly determined or derived from the disclosure herein, without departing from the spirit and scope of the invention. Accordingly, the scope of the present invention should be understood and interpreted to cover all such other variations or modifications.

Claims (10)

1. A cabinet air conditioner indoor unit, comprising:

the air conditioner comprises a shell, a fan and a controller, wherein an air inlet is formed in the shell, and an air outlet is formed in the front wall of the shell;

a blower configured to draw in ambient air from an environment surrounding the air inlet and cause the ambient air to flow toward the air outlet;

the heat exchanger is arranged on an air inlet flow path between the air inlet and the air supply fan and exchanges heat with ambient air entering from the air inlet so as to form heat exchange airflow;

the air guide component comprises at least three air guide rings which are provided with front and rear openings and are communicated with each other in the middle, the air guide rings are sequentially arranged in the front and rear direction to form a through air channel which penetrates through the air guide rings, a jet opening is formed between every two adjacent air guide rings, and the jet opening is configured to guide the heat exchange air flow to the through air channel and blow the air flow forwards so as to drive the air in the through air channel to be sent forwards to the air outlet; and

and the driving mechanism is connected with at least two adjacent air guide rings and configured to enable the at least two air guide rings to move so as to change the air supply direction.

2. The indoor unit of a cabinet air conditioner according to claim 1, wherein the indoor unit of the cabinet air conditioner is characterized in that

The number of the air guide rings is at least four, the at least two air guide rings are two air guide rings positioned in the middle, the two air guide rings are marked as two middle air guide rings, and the two middle air guide rings are configured to move under the driving of the driving mechanism.

3. The indoor unit of a cabinet air conditioner according to claim 2, wherein the air guide member further comprises:

the mounting plate is positioned in front of the air guide ring at the foremost side, is arranged in the shell and is provided with an opening communicated with the through air duct;

the drive mechanism includes:

a motor disposed below the front side of the mounting plate and having an output shaft parallel to the height direction of the housing;

the driving box is positioned below the air guide ring, the front end of the driving box is arranged on the mounting plate, the rear end of the driving box is arranged on the air guide ring behind the rear middle air guide ring, and a first fixing shaft which is parallel to the output shaft and extends upwards is formed in the driving box;

the first crank is positioned in the driving box, is rotatably connected with the first fixed shaft, and is provided with a first connecting shaft which is parallel to the output shaft and extends upwards and a second connecting shaft which extends downwards, and the first connecting shaft penetrates through the driving box and is fixedly connected with the lower end of the middle air guide ring positioned in front;

one end of the second crank is fixedly connected with the output shaft, and a rotating shaft which is parallel to the output shaft and extends upwards is formed at the other end of the second crank; one end of the driving connecting rod is connected with the rotating shaft of the second crank, and the other end of the driving connecting rod penetrates through the driving box to be connected with the second connecting shaft so as to drive the middle air guide ring positioned in front to rotate leftwards or rightwards; and

the balance connecting rods extend horizontally and are positioned above the two middle air guide rings, and two ends of each balance connecting rod are respectively and rotatably connected with the upper ends of the two middle air guide rings so as to drive the middle air guide ring positioned at the rear to rotate synchronously when the middle air guide ring positioned at the front rotates.

4. The indoor unit of a cabinet air conditioner according to claim 3, wherein the indoor unit of the cabinet air conditioner is characterized in that

The drive mechanism further includes:

the supporting box is positioned above the air guide ring, the front end of the supporting box is arranged on the mounting plate, and the rear end of the supporting box is arranged on the air guide ring behind the rear middle air guide ring;

and the third crank is positioned in the supporting box and is provided with a third connecting shaft which is parallel to and opposite to the first connecting shaft, and the third connecting shaft penetrates through the supporting box and extends downwards to be fixedly connected with the upper end of the middle air guide ring positioned in front.

5. The indoor unit of a cabinet air conditioner according to claim 4, wherein the indoor unit of the cabinet air conditioner is characterized in that

A second fixed shaft parallel to the first fixed shaft is formed in the driving box;

the drive mechanism further includes:

the fourth connecting shaft is positioned in the driving box, is parallel to the first connecting shaft, is connected with the second fixed shaft at the lower end, and is rotatably connected with the lower end of the middle air guide ring positioned at the rear part by penetrating through the driving box at the upper end;

and the fifth connecting shaft is positioned in the supporting box, is parallel to and opposite to the fourth connecting shaft, penetrates through the supporting box and is rotatably connected with the upper end of the middle air guide ring positioned at the rear part.

6. The indoor unit of a cabinet air conditioner according to claim 4, wherein the indoor unit of the cabinet air conditioner is characterized in that

A first limiting part is formed in the driving box and comprises a first slide rail consistent with the rotation path of the first crank and two first limiting columns positioned at two ends of the first slide rail;

a second limiting part is formed in the support box and comprises a second slide rail consistent with the rotation path of the third crank and two second limiting columns positioned at two ends of the second slide rail;

under the drive of the motor and the drive connecting rod, the first crank slides along the first slide rail and drives the middle air guide ring in front to rotate, so that the third crank is driven to slide along the second slide rail and simultaneously drives the middle air guide ring in rear to synchronously rotate.

7. The indoor unit of a cabinet air conditioner according to claim 6, wherein the indoor unit of the cabinet air conditioner is characterized in that

The number of the balance connecting rods is two, and the two balance connecting rods are located on the two transverse sides of the support box in the transverse direction.

8. The indoor unit of a cabinet air conditioner according to claim 6, wherein the indoor unit of the cabinet air conditioner is characterized in that

The driving box comprises a first box body with an open upper end and a first cover plate covering the open upper end of the first box body;

the first limiting part is formed on the inner side of the upper wall of the first cover plate;

the supporting box comprises a second box body with an open upper end and a second cover plate covering the open upper end of the second box body; the second limiting part is formed on the inner side of the bottom wall of the second box body.

9. The indoor unit of a cabinet air conditioner according to claim 8, wherein the indoor unit of the cabinet air conditioner is characterized in that

The inner side of the bottom wall of the first box body is positioned at the front side of the first fixed shaft, and a screw column extending upwards is further formed so that the first box body is connected with the first cover plate through screws inserted into the screw column;

the driving connecting rod is provided with an avoiding hole for the screw column to pass through.

10. The indoor unit of a cabinet air conditioner according to claim 1, wherein the indoor unit of the cabinet air conditioner is characterized in that

And a natural air draught opening is formed in the area, opposite to the through air channel, of the rear wall of the shell, so that when the jet opening sprays the air flow in the through air channel forwards, the ambient air around the natural air draught opening is promoted to flow forwards to enter the through air channel and be mixed with the heat exchange air flow blown out from the jet opening.

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