阅读说明：本技术 安装结构、滑动门组件和空调器 (Mounting structure, sliding door subassembly and air conditioner ) 是由 赵健聪 丘晓宏 罗文君 邵家成 于 2019-10-21 设计创作，主要内容包括：本申请提供一种安装结构、滑动门组件和空调器,包括第一安装架(1)、与待驱动件相连接的传动件(2),所述传动件(2)能够在所述第一安装架(1)上沿所述待驱动件的运动方向滑动,所述传动件(2)与所述第一安装架(1)之间具有朝向所述待驱动件所在侧或远离所述待驱动件所在侧的作用力,以使所述传动件(2)在滑动时抵靠在所述第一安装架(1)上。本发明的实施例中所提供的一种安装结构、滑动门组件和空调器,能够减少滑动门的抖动,提高在运转过程中的平稳性,进而提高使用体验。(The application provides a mounting structure, sliding door subassembly and air conditioner, include first mounting bracket (1), with driving medium (2) that treat that the driving piece is connected, driving medium (2) can follow on first mounting bracket (1) treat that the direction of motion of driving piece slides, driving medium (2) with have the orientation between first mounting bracket (1) treat that the driving piece place inclines or keep away from treat the effort of driving piece place side, so that driving medium (2) support when sliding and lean on first mounting bracket (1). The mounting structure, the sliding door assembly and the air conditioner provided by the embodiment of the invention can reduce the shaking of the sliding door, improve the stability in the operation process and further improve the use experience.)

1. The utility model provides a mounting structure, its characterized in that, includes first mounting bracket (1), with driving medium (2) that are connected of treating the driving piece, driving medium (2) can follow on first mounting bracket (1) the direction of motion of treating the driving piece slides, driving medium (2) with have the orientation between first mounting bracket (1) treat the driving piece place side or keep away from treat the effort of driving piece place side, so that driving medium (2) support when sliding and lean on first mounting bracket (1).

2. The mounting structure according to claim 1, wherein a first connecting unit is arranged on the first mounting frame (1), a second connecting unit is arranged on the transmission member (2), the first connecting unit is in plug-in fit with the second connecting unit, and the transmission member (2) is slidably plugged on the first mounting frame (1) through the first connecting unit and the second connecting unit.

3. The mounting structure according to claim 2, wherein the first connecting unit comprises a first guiding rib (11), the second connecting unit comprises a first slot (21), the slot wall of the first slot (21) on the side close to the member to be driven is a first slot wall, the slot wall on the side far away from the member to be driven is a second slot wall, the first guiding rib (11) is inserted into the first slot (21), and the first guiding rib (11) abuts against the first slot wall and/or the second slot wall.

4. The mounting structure according to claim 3, wherein a side of the first guide rib (11) close to the member to be driven is provided with a first protrusion, and the first guide rib (11) abuts against the first groove wall through the first protrusion;

and/or a second bulge is arranged on one side, far away from the to-be-driven piece, of the first guide rib (11), and the first guide rib (11) abuts against the second groove wall through the second bulge.

5. The mounting structure according to claim 4, wherein the first protrusions are plural, the plural first protrusions include at least two class A first protrusions (111) and at least one class B first protrusion (112), the class A first protrusions (111) have a height higher than that of the class B first protrusions (112), and at least one class B first protrusion (112) is provided between two class A first protrusions (111).

6. A mounting structure according to claim 3, characterized in that the first guide rib (11) has a space from the second groove wall when the first guide rib (11) abuts against the first groove wall; when the first guide rib (11) abuts against the second groove wall, a gap is formed between the first guide rib (11) and the first groove wall.

7. The mounting arrangement according to claim 2, wherein the first connection unit has a toothed structure, the opening of which is directed towards the transmission piece (2).

8. The mounting structure according to claim 1, characterized in that it further comprises a second mounting frame (3), on which second mounting frame (3) said transmission (2) is slidingly arranged, said transmission (2) being arranged between said second mounting frame (3) and said first mounting frame (1).

9. The mounting structure according to claim 1, characterized in that the mounting structure further comprises a motor (5) and a gear (6), wherein the motor (5) and the gear (6) are arranged on the first mounting frame (1), a rack matched with the gear (6) is arranged on the transmission member (2), the motor (5) and the gear (6) are in transmission connection through the rack, and the motor (5) drives the transmission member (2) to slide on the first mounting frame (1) through the gear (6).

10. The mounting structure according to claim 3, wherein a roller mounting groove (12) is provided on the first mounting bracket (1), a roller (4) is provided in the first slot (21), and the first slot (21) is pressed on the roller (4).

11. The mounting arrangement, as set forth in claim 10, characterized in that the peripheral outer edge of the roller (4) projects into the first slot (21).

12. A sliding door assembly, comprising a mounting structure according to any one of claims 1-11, arranged on an inner wall of the sliding door.

13. An air conditioner characterized by comprising the mounting structure according to any one of claims 1 to 11.

Technical Field

The application belongs to the technical field of air conditioning, concretely relates to mounting structure, sliding door subassembly and air conditioner.

Background

Along with the improvement of living standard, the air conditioner has become common consumer in the life, and circular cabinet machine is as one kind of air conditioner indoor set, receives consumers 'liking deeply, and the air outlet of circular cabinet machines can realize the closure, nevertheless because of the volume of sliding door is great, shakes easily at the operation process production, seriously influences consumer's use experience.

Disclosure of Invention

Therefore, the technical problem that this application will be solved lies in providing a mounting structure, sliding door subassembly and air conditioner, can reduce the shake of sliding door, improves the stationarity at the operation in-process, and then improves and uses experience.

In order to solve the problem, the application provides a mounting structure, include first mounting bracket, with treat the driving medium that the driving piece is connected, the driving medium can follow on the first mounting bracket treat that the direction of motion of driving piece slides, the driving medium with the orientation has between the first mounting bracket treat that the driving piece place side or keep away from treat the effort of driving piece place side, so that the driving medium supports and leans on when sliding on the first mounting bracket.

Preferably, a first connecting unit is arranged on the first mounting frame, a second connecting unit is arranged on the transmission piece, the first connecting unit is in plug-in fit with the second connecting unit, and the transmission piece is in sliding plug-in fit with the first mounting frame through the first connecting unit and the second connecting unit.

Preferably, the first connecting unit includes a first guiding rib, the second connecting unit includes a first slot, a slot wall of the first slot close to one side of the to-be-driven member is a first slot wall, a slot wall of the first slot far away from one side of the to-be-driven member is a second slot wall, the first guiding rib is inserted into the first slot, and the first guiding rib abuts against the first slot wall and/or the second slot wall.

Preferably, a first protrusion is arranged on one side, close to the to-be-driven piece, of the first guide rib, and the first guide rib abuts against the first groove wall through the first protrusion; and/or one side of the first guide rib, which is far away from the to-be-driven piece, is provided with a second protrusion, and the first guide rib abuts against the second groove wall through the second protrusion.

Preferably, the first bulges are multiple, the multiple first bulges comprise at least two class-A first bulges and at least one class-B first bulge, the height of the class-A first bulge is higher than that of the class-B first bulge, and at least one class-B first bulge is arranged between the two class-A first bulges.

Preferably, when the first guide rib abuts against the first groove wall, a gap is formed between the first guide rib and the second groove wall; when the first guide rib abuts against the second groove wall, a gap is formed between the first guide rib and the first groove wall.

Preferably, the first connecting unit has a toothed structure, the opening of which faces the transmission piece.

Preferably, the mounting structure further comprises a second mounting frame, the transmission member is slidably disposed on the second mounting frame, and the transmission member is disposed between the second mounting frame and the first mounting frame.

Preferably, the mounting structure still includes motor and gear, the motor with the gear setting is in on the first mounting bracket, be provided with on the driving medium with gear matched with rack, the motor with the gear passes through rack drive is connected, the motor passes through gear drive the driving medium is in slide on the first mounting bracket.

Preferably, a roller mounting groove is formed in the first mounting frame, a roller is arranged in the first slot, and the first slot is pressed on the roller.

Preferably, a circumferential outer edge of the roller extends into the first slot.

In another aspect of the present invention, there is provided a sliding door assembly including the above-described mounting structure provided on an inner wall of a sliding door.

In another aspect of the present invention, an air conditioner is provided, which includes the above-mentioned mounting structure.

Advantageous effects

The mounting structure provided by the embodiment of the invention can reduce the shaking of the sliding door, improve the stability in the operation process and further improve the use experience.

Drawings

FIG. 1 is a schematic structural diagram of an embodiment of the present application;

FIG. 2 is an exploded view of an embodiment of the present application;

FIG. 3 is a first cross-sectional view of an embodiment of the present application;

FIG. 4 is a second cross-sectional view of an embodiment of the present application;

fig. 5 is an enlarged view of a portion a in fig. 4.

The reference numerals are represented as:

1. a first mounting bracket; 11. a first guide rib; 111. a class A first lobe; 112. a class B first bump; 12. mounting grooves for rollers; 2. a transmission member; 21. a first slot; 22. a second slot; 3. a second mounting bracket; 31. a second guide rib; 311. a class A third lobe; 312. a class B third lobe; 4. a roller; 5. a motor; 6. a gear.

Detailed Description

Referring to fig. 1 to 5 in combination, according to an embodiment of the present application, an installation structure includes a first installation frame 1 and a transmission member 2 connected to a to-be-driven member, where the transmission member 2 can slide on the first installation frame 1 along a movement direction of the to-be-driven member, and an acting force toward a side of the to-be-driven member or away from the side of the to-be-driven member is provided between the transmission member 2 and the first installation frame 1, so that the transmission member 2 abuts against the first installation frame 1 when sliding. Through treating to set up driving medium 2 on the driving piece to make driving medium 2 and 1 sliding connection of first mounting bracket, and have the effort between driving medium 2 and the first mounting bracket 1, the shake of reducible sliding door improves the stationarity at the operation in-process, and then improves and uses experience.

Further, the transmission member 2 is fixedly connected with the to-be-driven member, and the to-be-driven member is driven to move by driving the transmission member 2.

Specifically, in this embodiment, the member to be driven is a sliding door of the air conditioner casing.

Further, the sliding door sets up on the casing of air conditioner, the casing of air conditioner for driving medium 2 provide with driving medium 2 with the relative reaction force of effort between the first mounting bracket 1, so that driving medium 2 supports when sliding and leans on the first mounting bracket 1.

Further, the transmission member 2 has an arc structure, and the transmission member 2 is in a strip shape, and the transmission member 2 is disposed on the inner wall of the sliding door.

Further, the driving medium 2 extrudes with the first mounting bracket 1 in a propping manner, and the driving medium 2 or the first mounting bracket 1 generates elastic deformation, so that the contact is more tight.

The mounting structure still includes motor 5 and gear 6, motor 5 with gear 6 sets up on the first mounting bracket 1, be provided with on the driving medium 2 with 6 matched with racks of gear, motor 5 with gear 6 passes through rack drive connects, motor 5 passes through the drive of gear 6 the driving medium 2 is in slide on the first mounting bracket 1.

Specifically, in this embodiment, the rack is arranged on the side wall of the transmission part 2 far away from one side of the movable door, the gear 6 is matched with the rack, and the motor 5 drives the gear 6 and the transmission part 2, so that the movable door is opened and closed.

Further, the motor 5 drives the transmission piece 2 to move along the circumferential direction of the air conditioner shell in the horizontal direction, so that the movable door is circumferentially opened or closed on the air conditioner shell.

Be provided with first linkage unit on the first mounting bracket 1, be provided with the second linkage unit on the driving medium 2, first linkage unit and the cooperation of pegging graft of second linkage unit, driving medium 2 is pegged graft on first mounting bracket 1 through first linkage unit and the slip of second linkage unit. Through setting up first linkage unit and second linkage unit into the cooperation of pegging graft of sliding, when having guaranteed driving medium 2 and 1 sliding connection of first mounting bracket, also for driving medium 2 provides the guide effect, stability when having guaranteed the sliding door switch.

The first connecting unit comprises a first guide rib 11, the second connecting unit comprises a first slot 21, the slot wall of the first slot 21 close to one side of the to-be-driven part is a first slot wall, the slot wall far away from one side of the to-be-driven part is a second slot wall, the first guide rib 11 is inserted into the first slot 21, and the first guide rib 11 abuts against the first slot wall and/or the second slot wall. Through leaning on first direction muscle 11 and first cell wall and/or second cell wall, the shake when can reduce the sliding door motion improves the stationarity in the operation process.

Further, the first slot 21 has a U-shaped structure, an opening of the first slot 21 is upward, and the first slot 21 extends along a circumferential direction of the sliding door.

Further, in this embodiment, the first guiding rib 11 abuts against the first groove wall, that is, an acting force and a reaction force in a direction toward and away from the sliding door are provided between the first guiding rib 11 and the first groove wall. Of course, as another embodiment, the first guide rib 11 may abut against the second groove wall, that is, the first guide rib 11 and the second groove wall may have an urging force and a reaction force in the direction toward and away from the sliding door. The first guide rib 11 may also abut against the first groove wall and the second groove wall at the same time.

The first mounting frame 1 is provided with a roller mounting groove 12, a roller 4 is arranged in the first slot 21, and the first slot 21 is pressed on the roller 4.

Further, gyro wheel mounting groove 12 sets up under first slot 21, gyro wheel 4 can set up in gyro wheel mounting groove 12 with rotating, the upper portion of gyro wheel 4 contacts with the notch department of first slot 21, when driving medium 2 slides on first direction muscle 11, gyro wheel 4 rotates and supports the motion of driving medium 2, through setting up gyro wheel 4, become rolling friction with the sliding friction of first slot 21 with first direction muscle 11, when having reduced frictional force, excessive wearing and tearing have been avoided, the noise has also been reduced simultaneously.

Further, gyro wheel mounting groove 12 and gyro wheel 4 one-to-one set up, and be a plurality of, and a plurality of gyro wheel mounting grooves 12 and gyro wheel 4 set up under driving medium 2 along the extending direction of driving medium 2.

A first protrusion is arranged on one side, close to the to-be-driven piece, of the first guide rib 11, and the first guide rib 11 abuts against the first groove wall through the first protrusion; and/or a second protrusion is arranged on one side, far away from the to-be-driven piece, of the first guide rib 11, and the first guide rib 11 abuts against the second groove wall through the second protrusion. Because the first guide rib 11 contacts with the first groove wall and/or the second groove wall and slides relatively, the friction force of the first guide rib 11 and the first groove wall and/or the second groove wall during sliding can be reduced by arranging the first protrusion and the second protrusion.

Further, the outer walls of the first protrusion and the second protrusion are provided with cambered surface structures.

Further, in this embodiment, the first protrusion abuts against the first groove wall, and the second protrusion is located between the first guiding rib 11 and the second groove wall and spaced from the second groove wall.

Further, first arch and second arch are a plurality of, and a plurality of first archs and the vertical setting of second arch have the interval between the adjacent first arch, have the interval between the adjacent second arch.

Further, a plurality of first archs evenly set up along the lateral wall circumference of first direction muscle 11, and a plurality of second archs evenly set up along the lateral wall circumference of first direction muscle 11.

As an embodiment, the first protrusions are multiple, the multiple first protrusions include at least two class a first protrusions 111 and at least one class B first protrusion 112, the height of the class a first protrusion 111 is greater than the height of the class B first protrusion 112, and at least one class B first protrusion 112 is disposed between the two class a first protrusions 111. Through setting up the first arch 111 of A type and the first arch 112 of B type that the height is different, can guarantee that first direction muscle 11 laminates with first cell wall mutually when passing through anomalous route, guarantee operating stability, can reduce the shake of sliding door.

Further, for example, when the first groove wall passes through a path having an S-shape, the two class a first protrusions 111 and the class B first protrusion 112 cooperate to ensure that the first guide rib 11 is attached to the first groove wall, thereby ensuring the operation stability and reducing the shaking of the sliding door.

When the first guide rib 11 abuts against the first groove wall, a gap is formed between the first guide rib 11 and the second groove wall; when first direction muscle 11 and second cell wall were leaned on mutually, have the interval between first direction muscle 11 and the first cell wall, first direction muscle 11 and first slot 21 clearance fit can reduce the shake of sliding door, when improving the stationarity of operation in-process, reduce the frictional force between first direction muscle 11 and first slot 21.

Further, in this embodiment, the first guide rib 11 abuts against the first groove wall, a gap is formed between the first guide rib 11 and the second groove wall, the first guide rib 11 applies a pressure to the first groove wall in a direction toward the sliding door, and the first groove wall applies a reaction force to the first guide rib 11 in a direction away from the sliding door.

The mounting structure further comprises a second mounting frame 3, the transmission piece 2 is arranged on the second mounting frame 3 in a sliding mode, and the transmission piece 2 is arranged between the second mounting frame 3 and the first mounting frame 1. Through setting up second mounting bracket 3, can stably set up driving medium 2 between second mounting bracket 3 and first mounting bracket 1, when having guaranteed that driving medium 2 is stable gliding, restricted driving medium 2, motor 5 and gear 6's vertical displacement, guaranteed stability.

Further, the first mounting bracket 1 is disposed on top of the second mounting bracket 3, which are detachably coupled.

Further, the motor 5 and the gear 6 are disposed between the first mounting frame 1 and the second mounting frame 3, and the gear 6 can rotate between the first mounting frame 1 and the second mounting frame 3.

Be provided with the third coupling unit on the second mounting bracket 3, be provided with the fourth coupling unit on the driving medium 2, the cooperation of pegging graft of third coupling unit and fourth coupling unit, driving medium 2 is pegged graft on second mounting bracket 3 through third coupling unit and fourth coupling unit slip. Through setting up third coupling unit and fourth coupling unit into the cooperation of pegging graft of sliding, when having guaranteed driving medium 2 and 3 sliding connection of second mounting bracket, also for driving medium 2 provides the guide effect, stability when having guaranteed the sliding door switch.

The third connecting unit comprises a second guiding rib 31, the fourth connecting unit comprises a second slot 22, the slot wall of the second slot 22 close to one side of the to-be-driven piece is a third slot wall, the slot wall far away from one side of the to-be-driven piece is a fourth slot wall, the second guiding rib 31 is inserted into the second slot 22, and the second guiding rib 31 abuts against the third slot wall and/or the fourth slot wall. By abutting the second guide rib 31 against the third groove wall and/or the fourth groove wall, the shaking of the sliding door during movement can be reduced, and the stability in the operation process is improved.

Further, the second guide rib 31 is vertically aligned with the first guide rib 11.

Further, the second slot 22 has a U-shaped structure identical to that of the first slot 21, an opening of the second slot 22 faces downward, the second slot 22 extends along a circumferential direction of the sliding door, and the transmission member 2 is slidably disposed between the second slot 22 and the first slot 21.

Further, in the present embodiment, the second guiding rib 31 abuts against the third slot wall, that is, the acting force and the reaction force in the direction toward and away from the sliding door are provided between the second guiding rib 31 and the third slot wall. As another embodiment, the second guide rib 31 may abut against the fourth groove wall, that is, the second guide rib 31 and the fourth groove wall may have an urging force and a reaction force in the direction toward and away from the sliding door. The second guiding rib 31 may also abut against the third groove wall and the fourth groove wall at the same time.

A third protrusion is arranged on one side of the second guide rib 31 close to the to-be-driven piece, and the second guide rib 31 abuts against the third groove wall through the third protrusion; and/or one side of the second guide rib 31, which is far away from the to-be-driven piece, is provided with a fourth protrusion, and the second guide rib 31 abuts against the fourth groove wall through the fourth protrusion. Because the second guide rib 11 contacts with the third groove wall and/or the fourth groove wall and slides relatively, the friction force of the second guide rib 11 when sliding with the third groove wall and/or the fourth groove wall can be reduced by arranging the third protrusion and/or the fourth protrusion.

Further, in this embodiment, the third protrusion is attached to the third groove wall, and the fourth protrusion is located between the second guiding rib 31 and the fourth groove wall and has a gap with the fourth groove wall.

Furthermore, the third protrusion and the fourth protrusion are multiple, the third protrusions and the fourth protrusions are vertically arranged, a gap is formed between every two adjacent third protrusions, and a gap is formed between every two adjacent fourth protrusions.

Further, a plurality of third protrusions are uniformly arranged in the circumferential direction of the second guide rib 31.

In this embodiment, the third protrusions are multiple, the multiple third protrusions include at least two a-type third protrusions 311 and at least one B-type third protrusion 312, the height of the a-type third protrusion 311 is greater than the height of the B-type third protrusion 312, and at least one B-type third protrusion 312 is disposed between the two a-type third protrusions 311. Through setting up the A type third arch 311 and the B type third arch 312 that highly differs, can guarantee that second direction muscle 31 and third cell are laminated mutually when passing through anomalous route, guarantee operating stability, can reduce the shake of sliding door.

Further, for example, when the third slot wall passes through a path having an S-shape, the two class a third protrusions 311 are matched with the class B third protrusion 312, so that the second guide rib 31 is ensured to be attached to the third slot wall, the operation stability is ensured, and the shaking of the sliding door can be reduced.

When the second guide rib 31 abuts against the third groove wall, a gap is formed between the second guide rib 31 and the fourth groove wall; when the second guiding rib 31 abuts against the fourth groove wall, a space is formed between the second guiding rib 31 and the third groove wall. The second guide rib 31 is in clearance fit with the second slot 22, so that the shaking of the sliding door can be reduced, the stability in the operation process is improved, and meanwhile, the friction force between the second guide rib 31 and the second slot 22 is reduced.

Further, in this embodiment, the second guide rib 31 abuts against the third groove wall, a gap is provided between the second guide rib 31 and the fourth groove wall, the second guide rib 31 applies a pressure to the third groove wall in the direction toward the sliding door, and the third groove wall applies a reaction force to the second guide rib 31 in the direction away from the sliding door.

Further, in this embodiment, the third connecting unit has a tooth-shaped structure, and the opening of the tooth-shaped structure faces the transmission member 2, so that prestress can be provided in multiple directions towards or away from the sliding door.

Further, in the present embodiment, the tooth structure provides prestress in a direction toward the sliding door in a plurality of directions.

In another aspect of the present embodiment, there is provided a sliding door assembly including the above-described mounting structure.

In another aspect of the present embodiment, an air conditioner is provided, which includes the above-mentioned mounting structure.

The mounting structure provided by the embodiment of the invention can reduce the shaking of the sliding door, improve the stability in the operation process and further improve the use experience.

It is readily understood by a person skilled in the art that the advantageous ways described above can be freely combined, superimposed without conflict.

The present invention is not intended to be limited to the particular embodiments shown and described, but is to be accorded the widest scope consistent with the principles and novel features herein disclosed. The foregoing is only a preferred embodiment of the present application, and it should be noted that, for those skilled in the art, several modifications and variations can be made without departing from the technical principle of the present application, and these modifications and variations should also be considered as the protection scope of the present application.