ES2899408T3 - Air conditioner - Google Patents

Abstract

An air conditioner, comprising a lower casing (310), a motor (141), and an impeller (320) rotatably mounted to the lower casing (310), the air conditioner further comprising a tilting blade (341), an impeller shaft of the impeller (320) being connected to a motor shaft of the motor (141), the tilting blade (341) being adapted to cause the impeller to move a distance along an axial direction of the impeller, with In order to perform a complete decoupling between the impeller shaft and the motor shaft during a disassembly process, when it is necessary to separate the impeller (320) from the motor (141), only the tilting plate (341) needs to be tilted, and the tilting blade (341) causes the impeller (320) to move away from the motor (141), thereby completing the impeller (320) disassembly process; wherein the tilting blade (341) comprises a driving part (3413) and a pushing part (3412), the driving part (3413) is movably mounted on a component adjacent to the impeller (320), and the driving part ( 3413) of the tilting blade (341) causes the thrust part (3412) to perform the axial movement of the impeller (320); the impeller (320) is a cross-flow impeller; the component adjacent to the impeller (320) is the lower casing (310); wherein, the tilting sheet (341) further comprises a limiting part (3414) fixedly connected to the pushing part (3412), and the tilting sheet (341) and the component on which the tilting sheet is mounted ( 341) are blocked by the limiting part 3414 when the impeller 320 separates from the motor.

Description

DESCRIPTION

Air conditioner

technical field

The present disclosure relates to an air conditioner, and falls within the technical field of an air conditioner.

Background

The air conditioner is a commonly used household appliance, and a conventional air conditioner, in which an air duct, a water duct system, and a bottom case are taken as a whole, and the air conditioner is assembled and it is fixed as a base part firstly, and if washing is required for the air conditioner, a professional is required to disassemble and clean each part of the air conditioner, which is quite inappropriate.

However, during prolonged use of the air conditioner, impurities such as dust entering the air duct and water duct system from the air inlet cause the entire air duct and water duct system to The water will be seriously polluted, and if the cleaning is not done in time, the environment will be dangerous during the operation of the air conditioner from a pollution source, which is important for the user's health.

For the convenience of washing, Patent No. CN205037533U discloses a casing of an indoor unit of an air conditioner and an indoor unit of the air conditioner with the casing, including an upper chassis, a lower chassis and an assembly. guide rail, in which a grille is detachably mounted on the upper frame and a heat exchanger is mounted on the upper frame. The blower is detachably mounted on the undercarriage. In the related art, the heat exchanger is a water pipe, an impeller below the heat exchanger forms an air passage, the blower is fixedly connected with the impeller, and the rotation of the blower causes the impeller to rotate and Therefore, when the blower is separated in the related art, the blower and the impeller need to be disassembled together, and then the contaminants on the impeller are cleaned, and this disassembly mode needs to disassemble and clean the motor assembly together. with the air duct component, which has the following problems: During cleaning, residual water can easily enter the motor part connected with the impeller to damage the motor due to residual water in the motor. Alternatively, when the user cleans, if the user forgets to turn off the power supply of the blower, a situation where the user touches the electricity may occur.

In order to solve the above technical problem, Chinese patent document CN202792451 U discloses a wall-mounted air conditioner indoor casing that facilitates disassembly, including a reciprocally fastened casing and frame, in which the frame is split type, and when it is cleaned, first of all, the casing is removed, and a fixing screw between an upper frame and a lower frame is disassembled. Next, the lower frame is disassembled, a fixing bolt between the impeller and a motor shaft is disassembled, and the upper and lower stiffening rings of a side support frame are continuously disassembled, so that the impeller can be easily disassembled. . However, in the related art, a disassembly process of the impeller and the motor is troublesome, firstly, a screw needs to be disassembled, then the shroud needs to be disassembled, the impeller can be disassembled from the motor, that is, , the impeller and motor disassembly process is complicated. On the other hand, when cleaning, it is necessary for the user to disconnect the connecting power cable between the blower motor and the power supply, and reconnecting the power supply cable may cause a bad connection. This slightly influences the use and may cause serious damage to the electric motor, and even a situation where the user stores electricity.

In order to be able to disassemble the impeller conveniently and independently, Chinese patent CN2823621Y discloses a blower device for a household appliance, wherein the blower device includes a connecting device, the connecting device includes an impeller socket fitted in the center of the other end surface of a fan and a motor shaft sleeve fixedly mounted on the main shaft of a drive motor. One or more installation grooves are provided on the impeller socket, and one or more installation brackets are provided on the motor shaft sleeve, and when the fan needs to be removed for cleaning, the fan can be removed conveniently just by moving the fan. in the direction of the fan end shaft. However, in the related art, the blower is actually supported on the lower case and located in a cavity with a downward opening surrounded by the heat exchanger, and only a gap left between the blower and the heat exchanger is not , generally opposite the impeller, so it is difficult to access the impeller from the outside through the gap. A suitable tool must be found to contact and tilt the impeller through the hole. On the one hand, the operation process of using the tool is troublesome. On the other hand, it is difficult to control the type of collision or tilt that occurs during the extraction process, so that when the motor shaft sleeve is operated to sleeve together with the motor shaft, the sleeve of motor shaft is easily damaged. Therefore, there is only one such connection device, and it is still difficult for general users to disassemble and remove the impeller for cleaning.

JP H04126926 discloses a cross flow fan mounting configuration for the functional capability of a cross flow fan and a fan motor. The air conditioner according to the present invention is provided with a hook of a fan motor lead wire facing upward within the main body of a space portion for accommodating a main body of an electrical component box. Furthermore, on the side surface of the main body facing the axial direction of the cross-flow fan, there is provided an opening that can penetrate in the axial direction of the cross-flow fan, and a cover that releasably closes the opening. opening and cross flow on the inner surface of the cap. A bearing is formed to support an end shaft of the fan.

WO 2016074607 discloses an easily detachable wall mount air conditioner indoor unit including an installation plate fixed on a wall surface, a frame, a heat exchanger, a control drive module and a motor. drive, wherein an installation cavity is provided in the frame and a cross-flow fan is provided in the installation cavity. The frame and the cross-flow fan are detachably connected and constitute a first module, and the first module is detachably connected to the installation plate; and the heat exchanger and the control drive module are connected and constitute a second module, and the second module is fixedly connected to the installation plate.

JP H05322200 discloses an indoor unit of the air conditioner with reduced noise in a wall mounting unit and which can be mounted on the indoor unit. It is related to the cross flow fan of the indoor unit of the air conditioner with improvements. When the cross flow fan 1 is rotated, the indoor air sucked into the indoor unit through the suction grill 6 passes through the heat exchanger 5, passes through the cross flow fan 1 and is blown into the room from exit 7.

JP 2015206482 discloses an indoor unit of an air conditioner and, in particular, a separable structure of a cross-flow fan. The indoor unit of the air conditioner according to the present invention has a joint/parting hole and a mounting hole in a side wall, the joint/parting hole is formed in a direction perpendicular to the side wall, and the mounting hole is formed in the side wall. Inside the main body, a main body formed in parallel directions, a cross-flow fan attached to and separated from inside the main body through the joining/separation hole in the side wall, a rotation shaft provided in the cross-flow fan and the interior of the main body.

DE 102015218612 discloses an air intake device for a cooker hood and a cooker hood with an air intake device, the air intake device for a cooker hood has a fan housing with an air intake opening and an air outlet opening. A fan wheel is latchingly connected to the motor shaft of a motor. During the rotation of the motor shaft, the fan wheel is also rotated with the help of a rotary drive mechanism. A latching connection mechanism for latching connection of the fan wheel and the motor shaft is provided with at least one spring-loaded latching projection on the outer circumferential surface of the motor shaft or on the inner circumferential surface of the seat fan wheel receiving port.

Summary

The present invention provides an air conditioner with a cross-flow impeller according to attached claim 1, for which it is easier to disassemble the impeller and the motor, solving the technical problem that it is difficult to disassemble an impeller during a process of disassembly of a fan into a blower device in the related art. Preferred embodiments are defined in the attached dependent claims.

An air conditioner provided by the present invention includes a lower casing and an impeller rotatably mounted to the lower casing, wherein the air conditioner further includes a tilting blade, the tilting blade includes a driving part and a pushing part, the drive portion is movably mounted on a component adjacent to the impeller, and the drive portion of the tilting blade drives the thrust portion to effect axial movement of the impeller.

According to the invention, the tilting sheet further includes a limiting part fixedly connected with the pushing part, and the tilting sheet and the component on which the tilting sheet is mounted are locked by the limiting part, when the impeller separates from a motor.

According to the invention, the tilting sheet is movably mounted to the lower case of the air conditioner.

In an exemplary embodiment, the limiting part cooperates with a lower casing limiting groove with an inclined surface, the lower casing limiting groove 342 is formed in the lower casing, when the impeller moves in a direction away from the motor to separate from the motor, the limiting part is locked with the lower casing by the Inclined surface of the lower casing limiting groove; and when the impeller moves in a direction towards the motor, a lock between the limiting part and the lower casing is released.

In an exemplary embodiment, two tilting blades are provided, the two tilting blades are respectively arranged at two ends only in one axial direction of the impeller, and respectively tilt the impeller in opposite directions; wherein a tilting blade that tilts the impeller, in a direction away from the motor, of the two tilting blades, has the limiting part.

In an exemplary embodiment, a protrusion is formed on a contact surface, in contact with the impeller, of the thrust portion.

In an exemplary embodiment, the projection is provided on one side, near a shaft of rotation of the impeller, of the thrust part.

In an exemplary embodiment, the tilt sheet is formed by a guide flange slidably connected with a lower casing guide member formed on the lower casing.

In an exemplary embodiment, a hook hooked to the lower casing limiting groove of the lower casing is formed on the tilt sheet.

In an exemplary embodiment, the tilting sheet is composed of four folded surfaces, wherein two adjacent folded surfaces of the four folded surfaces are connected perpendicular to each other, two folded surfaces provided at intervals are not opposite each other, and the part thrust is a folded surface provided at the uppermost end of the four folded surfaces; the driving part is provided on an upper surface of the lowermost folded surface of the four folded surfaces.

According to the invention, a distance that the tilting sheet moves along an axial direction of the impeller is greater than an amount of engagement between an impeller impeller shaft and a motor shaft, in order to realize a complete decoupling between the drive shaft and the motor shaft during a disassembly process.

In accordance with the invention, the component adjacent to the impeller is the lower casing.

In an exemplary embodiment, the number of the rocker blade is one, the rocker blade is disposed at one end portion of the impeller, and a return spring is disposed at the other end portion of the impeller, and the return spring return applies a pressure force to the impeller towards the motor.

In an exemplary embodiment, one end of the return spring bears against an impeller mount in the lower casing, and the other end of the return spring bears against the impeller shaft of the impeller.

The present invention has the following advantages over the related art:

1. The tilting sheet includes a thrust part and a driving part, the driving part is movably mounted on a component adjacent to the impeller, the thrust part is used to contact the impeller, and the thrust part is used to drive the impeller to move axially; there is a problem that it is difficult to access the impeller from outside through the gap in the related art. The driving part of the tilting blade of the present disclosure can be contacted from the gap, that is, the operator actuates the pushing part to drive the impeller to move along the axial direction of the impeller through the motor part in the hole, thus facilitating the disassembly work between the impeller and the motor.

2. The tilting sheet further includes a limiting part which is fixedly connected to the pushing part. When the impeller is separated from the motor, the tilting plate and the tilting plate mounting component are locked, that is, when the impeller is separated from the motor, the position of the tilting plate is locked, so that the impeller is limited in a position where the motor is separated from the impeller, so that the impeller cannot re-engage with the motor shaft.

3. The tilting blade is movably mounted on the lower casing of the air conditioner, and the tilting blade moves relative to the lower casing of the air conditioner to push the impeller. 4. The limiting part cooperates with a lower casing limiting groove formed in the lower casing, the lower casing limiting groove is provided with an inclined surface. The limiting part cooperates with the inclined surface, and when the impeller moves in a direction away from the motor to separate from the motor, the limiting part locks with the lower casing, so that when the impeller moves to separate of the motor, the impeller is limited to a position where the motor is separated from the impeller, so that the impeller cannot engage with the motor shaft again. The lock between the limiting part and the lower casing is released when the impeller moves in the direction close to the motor, that is, when the impeller and motor are being reinstalled and connected, the tilting sheet can move freely, and the movement of the impeller towards the motor is not left. limited.

5. The number of tilting blades is two, which are respectively arranged at two ends in the axial direction of the impeller, and respectively tilt the impeller in opposite directions. That is, each of the two end surfaces of the impeller is provided with a tilting blade, and the tilting blade on the left end surface of the impeller can tilt the impeller to the right to make the impeller move to the right. , and the tilting plate on the right end surface of the impeller can tilt the impeller to the left and then make the impeller move to the left. The tilting sheet that tilts the impeller in a direction away from the motor is provided with the limiting part, for example, the right end surface of the impeller is provided with a motor, that is, the tilting sheet on the surface of right end of the impeller can make the impeller stay away from the motor, so as to make the impeller separate from the motor, and the tilting sheet on the right end surface of the impeller is provided with the limiting part, so that after the impeller moves to a position separated from the motor, the impeller is limited in the position where the impeller is separated from the motor.

6. The number of tilting blades is one, the tilting blade is provided at one end of the impeller, and a return spring is provided at the other end of the impeller, and a pressing force towards the motor is applied to the impeller. The return spring may be disposed at the same end of the impeller as the tilting blade, or the return spring and the tilting blade may be disposed at two different ends of the impeller as the tilting blade, respectively. The return spring can avoid the problem that the impeller and motor shaft do not cooperate effectively due to human reasons during a whole machine handling and installation process, thus preventing the motor from unloading after being turned on. and not work normally.

7. Return spring and toggle blade are respectively provided at two ends of the impeller, one end of the return spring bears against an impeller support in the lower casing, and the other end of the return spring bears against the impeller shaft. The force resting against the impeller shaft, at the end surface of the impeller, caused by the return spring, is concentrated on the axis of the impeller shaft, thereby reducing the amount of axial displacement of the impeller relative to the motor.

8. A protrusion is formed on a contact surface of the thrust portion to contact the impeller. Since the impeller and motor are connected by a threaded shaft sleeve, during the impeller and motor disassembly process, the impeller and motor are separated from each other by rotational movement around the motor shaft, so that sliding wear occurs between the tilting plate and the impeller. Therefore, the thrust part is provided with a protrusion to contact the impeller end surface, and the contact area between the impeller end surface and the tilting sheet is reduced, that is, the resistance to friction is reduced, and impeller damage and abnormal sound are reduced as much as possible.

9. The protrusion is provided on one side, close to a rotating shaft of the impeller, of the thrust part, so that the stressed point on the end surface of the impeller is as close as possible to the position of a rotating shaft. rotation of the impeller, thereby reducing the amount of impeller displacement during the process of separating the impeller from the motor.

10. The tilting sheet is formed by a guide flange slidingly connected with a lower casing guide member formed on the lower casing, so that the limiting part slides in a direction parallel to an axis of the impeller, preventing so that the tilting plate jumps during the sliding process of the tilting plate.

11. The tilting sheet is formed by a hook hooked to the lower casing limiting groove of the lower casing, and the limiting part slides into the lower casing limiting groove, so that the limiting part slides into a direction parallel to the impeller axis, thereby preventing the tilting blade from jumping in the process of sliding the tilting blade.

12. The tilting sheet is composed of four fold surfaces, where two fold surfaces of the four fold surfaces are connected perpendicular to each other, where two adjacent fold surfaces of the four fold surfaces are connected perpendicular to each other, and two fold surfaces proportioned to intervals do not oppose each other, and the thrust part is a folded surface provided at the uppermost end of the four folded surfaces; the driving part is provided on an upper surface of the lowermost folded surface, whereby it is convenient to operate the tilting sheet to move.

Brief description of the drawings

In order to illustrate the technical solutions of the present invention or the related art more clearly, the attached drawings required to describe the specific embodiments or the prior art are briefly presented below, and obviously the drawings attached in the following description are some embodiments of the present disclosure, ie, the present invention. The present invention is defined solely by the appended claims.

Fig. 1 illustrates an exploded diagram of an air conditioner according to an embodiment of the this disclosure;

Figure 2 illustrates an exploded diagram of an air duct assembly in accordance with one embodiment of the present disclosure;

Fig. 3 illustrates a structural schematic diagram of a lower casing limiting groove in accordance with an embodiment of the present disclosure;

Figure 4 illustrates a schematic structural diagram of a tilt sheet according to one embodiment of the present disclosure;

Figure 5 illustrates a schematic diagram of another tilt sheet in accordance with one embodiment of the present disclosure;

Figure 6 illustrates a schematic diagram of another tilt sheet in accordance with one embodiment of the present disclosure;

Figure 7 illustrates a structural schematic diagram of a lower shell cooperating with the tilting sheet of Figure 6;

Figure 8 illustrates a partial diagram of the tilting sheet assembly of Figure 6;

Figure 9 illustrates a partial diagram of the tilting sheet assembly of Figure 6;

Figure 10 illustrates a structural schematic diagram of another lower shell cooperating with the tilting sheet of Figure 6;

Figure 11 illustrates a structural installation diagram of a return spring and driver according to an embodiment of the present disclosure.

In this document, the drawings include the following drawing markers:

100, base module; 101, base element; 141, engine; 142, output shaft; 200, heat exchange module; 220: heat exchanger; 300, air duct module; 301, air duct assembly; 310, lower casing; 3108, lower closure; 3109, highlight; 310a, spring post; 310b: coil spring; 320, impeller; 321, impeller shaft; 322, lower casing guide member; 341, tilting blade; 3411, boss; 3412, thrust part; 3413, motor part; 3414, limitation part; 3415, tilt position; 3416, guide tab; 3417, hook; 3418, warp groove; 342, lower casing limiting groove; 400, decorative module; 722, return spring.

Detailed description of the embodiments

Hereinafter, the technical solutions of the present invention will be clearly and fully described with reference to the accompanying drawings, and of course the described embodiments are part of the disclosure embodiments rather than all embodiments. All other embodiments falling within the scope of the appended claims fall within the scope of protection of the present invention.

Fig. 1 illustrates a modular indoor unit of an air conditioner according to an embodiment of the present invention, including a base module 100, a heat exchange module 200, an air duct module 300, and a module. decorative 400.

The air duct module 300 includes an air duct assembly, and the air duct module 300 is connected with the base member module 101. As shown in Fig. 1, an impeller assembly in a air duct 301 includes an impeller 320 with an impeller shaft 321, one end, near the motor 141, of the impeller shaft 321 is in transmission connection with the motor 141, and the other end of the impeller shaft 321 is disposed so rotary manner in the lower casing 310.

A clutch drive mechanism is used to drive the drive shaft 321 to move along an axial direction of the output shaft 142 of the motor 141, a return spring 722 is provided at one end away from a set engine, impeller shaft. And the return spring 722 can apply a continuous pressure force to the driver 320, so that the driver 320 bears against the motor 141 located on one side of the driver 320, thus avoiding a gap produced between the driver 320 and the driver 320. engine 141 during the disassembly process. The clutch driving mechanism includes two tilting blades 341 mounted on two sides of the impeller 320, and the two tilting blades 341 are movably mounted on the lower case 310 respectively to apply a force to the impeller 320. As shown in figures 4 to 10, each of the two tilting blades 341 is composed of four folded surfaces, wherein two adjacent folded surfaces of the four folded surfaces are connected perpendicular to each other, and two folded surfaces of the four folded surfaces provided at intervals are not connected. oppose each other. As shown in Fig. 4, the tilting sheet 341 is provided with a pushing part 3412 provided at the uppermost end with a protrusion 3411, a driving part 3413, for manual transfer, provided on an upper surface of the folded surface. lowermost, and a limiting portion 3414 provided on a lower surface of the lowermost folded surface. The driving part 3413 is fixedly connected to the pushing part 3412. The protrusion 3411 is arranged on one side, near the rotating shaft of the pusher 320, of the pushing part 3412. The limiting part 3414 cooperates with the groove lower casing limiting groove 342 with an inclined surface, the lower casing limiting groove 342 is formed in the lower casing 310, and when the impeller 320 moves in a direction away from the motor 141 to separate from the motor 141, the limitation part 3414 hangs with the lower casing 310 by the inclined surface of the lower casing limiting groove 342. When the impeller 320 moves in a direction towards the motor 141, a lock between the limiting part 3414 and the lower casing 310 is released. A distance a which the tilting blade moves along an axial direction of the impeller 320 is greater than an amount of engagement between an impeller shaft of the impeller and a motor shaft, in order to realize complete decoupling between the impeller shaft and the motor shaft during a disassembly process. The tilting blade 341 and the impeller 320 come into contact through a function of the projection 3411; the driving part 3413 can facilitate the manual operation of the tilting sheet 341. By the function of the limiting bracket of the limiting part 3414, the tilting sheet 341 is slidably connected to the lower casing limiting groove 342 formed in the lower case 310. A stroke of the tilting sheet 341 is limited by limiting a stroke length of the lower case limiting groove 342. The tilting sheet 341 is formed by a guide flange 3416 slidably connected to the guide member of the lower case. lower casing 322 formed on the lower casing 310, so that the limiting part 3414 slides in a direction parallel to an impeller shaft, so as to prevent the tilting blade from jumping during a sliding process, as shown in figure 4.

The base module 100 is assembled with a motor 141 for rotating the impeller, that is, an impeller shaft is connected to a motor shaft, and on one side, near the motor 141, of the impeller shaft is provided with a tilting plate 341 for mounting and dismounting the impeller 320 and the motor.

As shown in Fig. 2, the tilting blade 341 is movably mounted on a component adjacent to the impeller 320, the tilting blade 341 includes a pushing part 3412 and a driving part 3413, the pushing part 3412 is adapted to enter in contact with impeller 320 and is used to cause impeller 320 to move axially. The driving part 3413 is fixedly connected to the pushing part 3412 and is located in a position that can be accessed from the outside through the gap. The driving part 3413 of the tilting sheet 341 of the present embodiment can be accessed from the gap, that is, the operator operates the pushing part 3412 to push the pusher 320 to move in the axial direction by the driving part 3413 in the gap, thus facilitating the disassembly work between the impeller 320 and the motor. The tilting sheet 341 of the present embodiment further includes a limiting part 3414 formed on the driving part 3413, which is fixedly connected to the pushing part 3412. When the impeller 320 is separated from the motor, the tilting sheet and the component to mount the tilting slat are locked together. That is, when the impeller 320 is separated from the motor, the position of the tilting plate is locked, so that the impeller 320 is limited to a position where the motor is separated from the impeller 320, so that the impeller 320 cannot engage. again with the motor shaft.

The tilting blade is movably mounted on the lower casing 310 of the air conditioner, and the tilting blade moves relative to the lower casing 310 of the air conditioner to push the impeller 320. In Figs. lower case flip sheet mounting position 310. The limiting portion 3414 cooperates with a lower case limiting groove 342 formed in the lower case 310, the lower case limiting groove 342 is provided with an inclined surface. The limiting part 3414 cooperates with the inclined surface, and when the impeller moves in the direction away from the motor to separate from the motor, the limiting part 3414 locks with the lower casing 310, so that when the impeller 320 moves away from the motor, the impeller 320 is constrained to a motor disengagement position, and the impeller 320 cannot re-engage with the motor shaft. A lock between the limiting part 3414 and the lower casing 310 is released when the tilting plate moves in a direction close to the motor, that is, when the driver 320 and the motor are reinstalled and connected, the tilting plate can move freely without restrict the movement of the impeller 320 near the direction of the motor.

As shown in Fig. 2, the number of the tilting blade used to disassemble and assemble the impeller 320 and the motor is two, the two tilting blades are arranged at two axial ends of the impeller 320 respectively, and the two tilting blades tilt the impeller 320 in opposite directions. That is, each of the two end surfaces of the impeller 320 is provided with a tilting blade, and the tilting blade on the left end surface can tilt the impeller 320 to the right and then make the impeller 320 moves to the right, and the tilt plate on the right end surface can tilt the impeller 320 to the left and then cause the impeller 320 to move to the left. The tilting sheet that tilts the impeller 320 in a direction away from the motor is provided with the limiting part 3414, for example, a motor is provided on the right end surface of the impeller 320, that is, the tilting sheet in the right end surfaces of the impeller can make the impeller 320 stay away from the motor, so as to make the impeller 320 separate from the motor, and the tilting sheet on the right end surfaces is provided with the limiting part 3414. Therefore, after the driver 320 moves to a position separated from the motor, the driver 320 is limited to the position where the driver 320 is separated from the motor.

Alternatively, the number of the swivel blade used for disassembling and assembling the driver 320 and motor is one, the swivel blade 341 is provided at one end part of the driver 320, the return spring is provided at another end part of the driver 320. impeller 320, and the return spring applies a biasing force toward the motor to the impeller 320. The return spring may be disposed in the same end portion of the impeller 320 as the tilting blade, or the return spring and the tilting blade may be provided at two different end portions of the driver 320 respectively. The return spring can prevent the problem that the driver 320 and the motor shaft do not cooperate effectively for human reasons during a whole machine handling and installation process, thus preventing the motor from being unloaded after being turned on and not working normally. The return spring and the tilting leaf are respectively arranged in two end portions of the impeller 320, one end of the return spring abuts against an impeller support in the lower casing 310, and the other end of the return spring abuts against the impeller shaft 320. The force applied to the end surface of the impeller shaft, caused by the return spring, is concentrated on the axis of the impeller shaft, thereby reducing the amount of axial displacement of the impeller 320 with respect to to the engine. As shown in Fig. 4, a projection 3411 is formed on a contact surface of the thrust portion 3412 to contact the impeller 320. Since the impeller 320 and the motor are connected by a threaded shaft sleeve, during the disassembly process of the impeller 320 and the motor, the impeller 320 and the motor are separated from each other by a rotational movement around the motor shaft, so that sliding wear occurs between the tilting plate and the impeller 320. Therefore, a protrusion 3411 is provided to contact the impeller end surface 320 at the thrust portion 3412, and the contact area between the impeller end surface 320 and the tilting sheet is reduced, that is, the frictional resistance is reduced and the damage to the impeller 320 and the abnormal sound are reduced as much as possible. The projection 3411 is provided on one side, near the impeller rotation shaft 320, of the thrust part, so that the stress point on the end surface of the impeller 320 is near the position of an impeller rotation shaft. 320 as much as possible, thereby reducing the amount of axial displacement of the impeller 320 during the process of separating the impeller 320 from the motor. The limiting part 3414 includes a guide flange 3416 slidably connected to the lower casing guide member 322 formed on the lower casing 310, the limiting part 3414 slides in a direction parallel to the axis of the impeller 320, in order to prevent the tilting plate from jumping during the sliding process of the tilting plate. The limiting part 3414 further includes a hook 3417 hooked to the lower casing limiting groove 342 of the lower casing 310, and the limiting part 3414 slides in the lower casing limiting groove 342, so that the lower casing limiting part 342 limiter 3414 slides in a direction parallel to the axis of the impeller 320, thereby preventing the tilting blade from jumping in the process of sliding the tilting blade. The tilt sheet 341 of the present embodiment further includes a tilt position 3415 configured to be subjected to an external force to easily tilt the tilt sheet. The tilting sheet is composed of four folded surfaces, where two adjacent folded surfaces of the four folded surfaces are connected perpendicular to each other, and two folded surfaces provided at intervals do not oppose each other, and the thrust part 3412 is a folded surface arranged at the uppermost end of the four folded surfaces; the driving part 3413 is conveniently provided on an upper surface of the lowermost folded surface of the four folded surfaces, whereby it is convenient to operate the tilting sheet to move.

As a changeable embodiment, the tilt sheet of the present embodiment is used to disassemble and assemble the impeller 320 and the motor, a tilt sheet mounting position of the lower casing 310 is sunk, a return spring is provided on one surface, away from the tilting sheet, from the lower case 310, and a guide control function for the tilting sheet is performed by co-operation of a coil spring 310b and a spring post 310a. A deformation groove 3418 is formed in the tilting sheet, and when the tilting sheet is pressed down at the tilting sheet mounting position on the lower case 310, the deformation groove 3418 enables the guide flange 3416 to be pressed and deformed downward. a center of the tilting sheet, and the guide flange 3416 is pressed into the lower casing guide member 322 of the lower casing 310. At one edge of the casing guide member 322, a deformation groove is formed in the casing bottom, and when the flipper sheet is pressed down into the lower case flipper mounting position 310, the deformation groove 3418 in the lower case can allow the lower case guide member 322 to expand outward, so that the guide flange 3416 is pressed into the lower casing guide member 322, then the deformation groove 3418 is restored, and the e lower casing guide element 322 and guide flange 3416. In other words, guide flange 3416 and lower casing guide element 322 cooperate to guide and constrain the drive portion 3413 of the tilting blade in the off position. lower casing flip sheet assembly 310. The flip sheet is formed with a limiting portion 3414 for engaging the bottom lock 3108 of the lower casing 310. The lower casing 310 may further be provided with a shoulder 3109 to limit the stroke of the lower casing. tilting blade movement. The lower case guide member 322 of the tilt sheet mounting position in the lower case 310 may be in the form of a strip, as shown in Fig. 8. Alternatively, as shown in Fig. 10, the guide member The lower case 322 in the lower case 310 may be composed of three holders, which are, respectively, a first holder, a second holder and a third holder from left to right. When the guide flange 3416 is locked with the first clamp, the driver 320 is pushed to a position where the driver 320 separates from the motor; when the guide flange 3416 is pushed from a locked position where the guide flange 3416 is locked with the first fastener to a locked position where the guide flange 3416 is locked with the second fastener, the push portion 3412 of the tilting sheet it is located between the impeller 320 and the motor without interfering with the mounting of the impeller 320 and the motor. When the tilt sheet is pressed and fitted on the lower case 310, the tilt sheet connects with the third fastener on the lower case 310, and then locks. Through the arrangement of the first holder, the second holder and the third holder, the position of the thrust part 3412 can be clearly determined, that is, whether interfere with the coupling of the fan blade and the motor.

As a changeable embodiment, the number of the swivel blade is one, and the swivel blade is provided at one end portion of the impeller 320. A return spring is provided at the other end portion of the impeller 320. As shown in FIG. 11, the return spring applies a biasing force toward the motor to the driver 320. When the return spring and the swivel blade are disposed, respectively, at two ends of the driver 320, one end of the return spring abuts against a impeller support 320 of the lower casing 310, and the other end of the return spring bears against the impeller shaft 320. When the impeller 320 is mounted to cooperate with the motor, the return spring acts directly to push the impeller 320 towards the engine.

As shown in Fig. 4, the air conditioner is provided with a tilting blade 341 for the impeller 320, the tilting blade 341 is adapted to cause the impeller 320 to move along an axial direction of the impeller. When it is necessary to separate the impeller 320 from the motor, only the tilting blade 341 needs to be tilted, and the tilting blade causes the impeller 320 to move away from the motor 141, thus completing the disassembly process of the impeller 320.

Obviously, the embodiments described above are merely examples made for clarity and do not limit the invention. Other variations or variations in different ways can also be made by those skilled in the art based on the above description. It is not necessary that all embodiments be exhaustive in this case. Apparently obvious variations or variations presented in this way are still within the scope of protection of the present invention, which is defined only in the appended claims.

Claims (10)

1. An air conditioner, comprising a lower casing (310), a motor (141), and an impeller (320) rotatably mounted to the lower casing (310), the air conditioner further comprising a tilting blade (341 ), an impeller shaft of the impeller (320) being connected to a motor shaft of the motor (141), the tilting blade (341) being adapted to cause the impeller to move a distance along an axial direction of the impeller , in order to perform a complete decoupling between the impeller shaft and the motor shaft during a disassembly process, when it is necessary to separate the impeller (320) from the motor (141), only the tilting plate (341) needs to be tilted, and the tilting plate (341) causes the impeller (320) to move away from the motor (141), completing thereby disassembling the impeller (320); wherein the tilting blade (341) comprises a driving part (3413) and a pushing part (3412), the driving part (3413) is movably mounted on a component adjacent to the impeller (320), and the driving part ( 3413) of the tilting blade (341) causes the thrust part (3412) to perform the axial movement of the impeller (320); the impeller (320) is a cross-flow impeller; the component adjacent to the impeller (320) is the lower casing (310); wherein, the tilting sheet (341) further comprises a limiting part (3414) fixedly connected to the pushing part (3412), and the tilting sheet (341) and the component on which the tilting sheet is mounted ( 341) are blocked by the limiting part 3414 when the impeller 320 separates from the motor. 2. The air conditioner according to claim 1, wherein the limiting part (3414) cooperates with a lower casing limiting groove (342) with an inclined surface, the lower casing limiting groove (342) being formed in the lower casing (310), and when the impeller (320) moves in a direction away from the motor to separate from the motor, the limiting part (3414) is locked with the lower casing (310) by the inclined surface of the lower casing limiting groove (342); and when the driver (320) moves in a direction toward the motor, a lock between the limiting portion (3414) and the lower casing (310) is released. The air conditioner according to claim 1, wherein two tilting blades (341) are provided, the two tilting blades (341) being respectively arranged at two ends along the axial direction of the impeller (320). ) and adapted, respectively, to tilt the impeller (320) in opposite directions; wherein a tilting blade (341) that tilts the impeller (320), in a direction away from the motor (141), of the two tilting blades (341), has the limiting portion (3414). The air conditioner according to claim 1, wherein a protrusion (3411) is formed on a contact surface, in contact with the impeller (320), of the thrust portion (3412). The air conditioner according to claim 4, wherein the projection (3411) is provided on one side, near the impeller shaft, of the thrust portion (3412). The air conditioner according to claim 1, wherein the tilt sheet (341) is formed by a guide flange (3416) slidably connected to a lower casing guide member (322) formed on the casing. lower (310). The air conditioner according to claim 2, wherein a hook (3417) hooked to the lower casing limiting groove (342) of the lower casing (310) is formed on the tilting sheet (341). 8. The air conditioner according to claim 2, wherein the tilting sheet (341) is composed of four folded surfaces, wherein two adjacent folded surfaces of the four folded surfaces are connected perpendicular to each other, two folded surfaces of the four folded surfaces provided at intervals do not oppose each other, and the thrust portion (3412) is a folded surface provided at the uppermost end of the four folded surfaces; the driving part (3413) is provided on an upper surface of the lowermost folded surface of the four folded surfaces. The air conditioner according to claim 1, wherein the number of the swing blades (341) is one, the swing blade (341) is provided at an end portion of the impeller (320), a return spring ( 722) is disposed on the other end portion of the driver (320), and the return spring (722) applies a pressing force to the driver (320) toward the motor (141). 10. The air conditioner according to claim 9, wherein one end of the return spring (722) bears against an impeller support in the lower casing (310), and the other end of the return spring (722) bears against the impeller drive shaft (320).