JP2008089198A - Fan motor unit and air-conditioning indoor machine comprising the same - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a fan motor unit having superior assembling workability, and capable of correctly and easily mounting a vibration absorbing body preventing diffusion of vibration to a stator. <P>SOLUTION: This fan motor unit 72 for rotating a fan 71 disposed in the air-conditioning indoor machine 2, comprises a rotator 719, the stator 721 and a vibration-proofing member 77. The rotator 719 is fixed to a rotating shaft of the fan 71 and rotated by the action of magnetic force. The stator 721 allows magnetic force to act on the rotator 719. The vibration-proofing member 77 is mounted along an outer periphery of the stator 721 and absorbs the vibration of the stator 721. The vibration-proofing member 77 has a plurality of vibration absorbing bodies 771, 772, 773, and thin tabular connecting bodies 774 for connecting the plurality of vibration absorbing bodies in the longitudinal direction. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a fan motor unit that is mounted in an air conditioning indoor unit and rotates a fan for circulating air inside the air conditioning indoor unit, and an air conditioning indoor unit including the fan motor unit.

Conventionally, a fan motor unit mounted in an air conditioning indoor unit has a configuration in which a rotor that rotates by magnetic force and a stator that generates magnetic force are opposed to each other, and the rotor is connected to a rotating shaft of the fan. Yes. In this type of fan motor unit, if the followability of fan rotation is poor with respect to the rotation of the rotor, vibration in the rotational direction is transmitted from the rotor to the stator. Then, the vibration transmitted to the stator is transmitted to the support frame that supports the fan motor unit, and abnormal noise is generated when the support frame resonates. Therefore, in order to absorb the vibration transmitted to the stator and suppress the vibration from being transmitted to the support frame, a plurality of vibration absorbers are mounted on the stator (see, for example, Patent Document 1).
Japanese Patent Laid-Open No. 2005-30689

  The vibration absorbers disclosed in Patent Document 1 are individually attached to three locations on the outer periphery of the stator, and the vibration absorbers positioned vertically below are not subject to permanent deformation due to the gravity of the stator. It is formed in a shape different from these two. For this reason, when attaching the vibration absorber to the stator, an attachment error may occur. In addition, the assembly work is inefficient because the three vibration absorbers are attached to the stator one by one.

  An object of the present invention is to provide a fan motor unit with good assembling workability capable of accurately and easily mounting a vibration absorber that suppresses vibration diffusion to a stator.

  A fan motor unit according to a first aspect of the present invention is a fan motor unit that rotates a fan disposed in an air conditioning indoor unit, and includes a rotor, a stator, a vibration isolating member, and a housing. The rotor is fixed to the rotating shaft of the fan and rotates by the action of magnetic force. The stator applies a magnetic force to the rotor. The vibration isolating member is attached to the stator. The housing houses the stator and the vibration isolating member. The vibration isolator has a plurality of vibration absorbers that absorb the vibration of the stator and a thin plate-like connector that connects the plurality of vibration absorbers in the longitudinal direction. The vibration absorber is interposed between the housing and the stator to hold the stator and restrict its position.

  In this fan motor unit, the operation of taking out the vibration isolating member to which the plurality of vibration absorbers are connected takes less time than the operation of taking out the plurality of vibration absorbers one by one, and the assembly workability is improved.

  A fan motor unit according to a second invention is the fan motor unit according to the first invention, wherein when the vibration absorber is mounted along the outer periphery of the stator, the vibration absorbers connected by the connecting body The interval and the interval between the vibration absorbers that are not connected by the connecting body are uneven.

  In this fan motor unit, when the mounting position of the vibration isolating member is wrong, it cannot be mounted because the distance between the vibration absorbers is different. For this reason, the operator can quickly recognize an error in the mounting position of the vibration isolating member, and an assembly failure is prevented in advance.

  A fan motor unit according to a third aspect is the fan motor unit according to the first aspect, wherein the stator has a protrusion. The protruding portion protrudes outward in a region where the vibration absorber is mounted. The vibration absorber has a bag-like recess that fits into the protrusion.

  In this fan motor unit, the mounting state of the vibration absorber can be visually confirmed. For this reason, it is possible to quickly confirm whether the mounted state is good or bad and prevent assembly failure.

  A fan motor unit according to a fourth aspect of the present invention is the fan motor unit according to the first aspect of the present invention, wherein the vibration absorber and the connecting body are integrally formed.

  In this fan motor unit, the vibration absorber and the connecting body are simultaneously formed of the same material, and the manufacturing cost is reduced by sharing the material.

  A fan motor unit according to a fifth aspect of the present invention is the fan motor unit according to the fourth aspect of the present invention, wherein when the vibration absorber and the coupling body are integrally molded, the coupling body is molded in a bent state.

  In this fan motor unit, the longitudinal dimension of the vibration isolating member in the molding die is shortened by bending the coupling body. For this reason, the number of vibration isolation members in the molding die is increased, and the unit price is reduced.

  A fan motor unit according to a sixth aspect is the fan motor unit according to the first aspect, wherein the vibration absorber has a protrusion that protrudes in a direction against the gravity of the stator and contacts the protrusion.

  In this fan motor unit, the protrusions are deformed by receiving the gravity of the stator to relieve the stress, so that the area other than the protrusions is prevented from being flattened by the gravity of the stator. For this reason, the position shift of the stator due to the flatness of the vibration absorber is also suppressed.

  A fan motor unit according to a seventh aspect of the present invention is the fan motor unit according to the sixth aspect of the present invention, wherein among the plurality of vibration absorbers, the vibration absorber whose position after assembly is substantially vertically downward is another vibration absorber. More protrusions than

  In this fan motor unit, even if the gravity component of the stator is vertically below the maximum, a plurality of projections are deformed by the gravity component to deform and relieve the stress, so that areas other than the projections are flattened by the gravity of the stator. Is suppressed. For this reason, the position shift of the stator due to the flatness of the vibration absorber is also suppressed.

  An air conditioning indoor unit pertaining to an eighth aspect of the invention comprises a fan, the fan motor unit according to any one of claims 1 to 7, and an indoor heat exchanger. The fan motor unit rotates the fan. The indoor heat exchanger exchanges heat with the air flow generated by the rotation of the fan.

  In this air conditioning indoor unit, fan motor unit assembly workability is good, and an increase in manufacturing cost is suppressed.

  In the fan motor unit according to the first aspect of the present invention, the operation of taking out the vibration isolating member to which the plurality of vibration absorbers are connected takes less time than the operation of taking out the plurality of vibration absorbers one by one, and the assembly workability Will improve.

  In the fan motor unit according to the second aspect of the invention, when the mounting position of the vibration isolating member is wrong, the vibration absorbers are different from each other and cannot be mounted. For this reason, the operator can quickly recognize an error in the mounting position of the vibration isolating member, and an assembly failure is prevented in advance.

  In the fan motor unit according to the third invention, the mounting state of the vibration absorber can be visually confirmed. For this reason, it is possible to quickly confirm whether the mounted state is good or bad and prevent assembly failure.

  In the fan motor unit according to the fourth aspect of the present invention, the vibration absorber and the coupling body are simultaneously formed of the same material, and the manufacturing cost is reduced by sharing the material.

  In the fan motor unit according to the fifth aspect of the invention, the longitudinal dimension of the vibration isolating member in the molding die is shortened by bending the coupling body. For this reason, the number of vibration isolation members in the molding die is increased, and the unit price is reduced.

  In the fan motor unit according to the sixth aspect of the present invention, the protrusion is deformed by receiving the gravity of the stator and relaxes the stress, so that the area other than the protrusion is prevented from being flattened by the gravity of the stator. For this reason, the position shift of the stator due to the flatness of the vibration absorber is also suppressed.

  In the fan motor unit according to the seventh aspect of the invention, even if the gravity component of the stator is below the maximum vertical direction, the plurality of protrusions are deformed by receiving the gravity component and relieve the stress, so that the region other than the protrusions is the stator. Is prevented from being flattened by gravity, and the displacement of the stator due to the flatness of the vibration absorber is also suppressed.

  In the air conditioning indoor unit pertaining to the eighth aspect of the invention, the assembly workability of the fan motor unit is good, and the manufacturing cost is reduced.

<Overall configuration of air conditioner>
FIG. 1 is an external view of an air conditioner. The air conditioner 1 is a device for supplying conditioned air to a room, and is an air conditioner indoor unit 2 (hereinafter referred to as an indoor unit 2) attached to an indoor wall surface or the like, and an air conditioner installed outdoors. An outdoor unit 3 (hereinafter referred to as an outdoor unit 3) is provided. The indoor unit 2 and the outdoor unit 3 are connected by a refrigerant pipe 4 so that refrigerant can be circulated.

<Schematic configuration of refrigerant circuit of air conditioner>
FIG. 2 is a configuration diagram of a refrigerant circuit of the air conditioner. The refrigerant circuit is formed by an accumulator 31, a compressor 32, a four-way switching valve 33, an outdoor heat exchanger 30, an electric expansion valve 34, and an indoor heat exchanger 50.

  The indoor heat exchanger 50 is arrange | positioned in the indoor unit 2, and heat-exchanges with indoor air. The indoor unit 2 is provided with a fan 71 and an indoor fan motor unit 72. The fan 71 sucks room air and discharges the air heat-exchanged by the indoor heat exchanger 50 into the room. The indoor fan motor unit 72 rotates the fan 71.

  The accumulator 31, the compressor 32, the four-way switching valve 33, the outdoor heat exchanger 30, and the electric expansion valve 34 are disposed in the outdoor unit 3. The accumulator 31 is connected to the suction side of the compressor 32, and the four-way switching valve 33 is connected to the discharge side of the compressor 32.

  The outdoor unit 3 is provided with a propeller fan 38 and an outdoor fan motor unit 39. The propeller fan 38 discharges the air heat-exchanged by the outdoor heat exchanger 30 to the outside. The outdoor fan motor unit 39 rotates the propeller fan 38.

<Configuration of indoor unit>
FIG. 3 is a right side sectional view of the indoor unit of the air conditioner.

(Upper casing)
The upper casing 6 covers the upper part of the indoor unit 2. The upper casing 6 is provided with suction ports 60 and 61. The indoor heat exchanger 50 is disposed so as to face the circumferential surface of the fan 71 and is attached so as to surround the front, upper, and rear of the fan 71. In the indoor heat exchanger 50, heat exchange is performed between the air sucked from the suction ports 60 and 61 and the refrigerant by rotating the fan 71.

(Lower casing)
The lower casing 70 includes an outer surface portion 79, a support frame 78, and the like. The outer surface portion 79 is a portion that appears in the field of view as the outer surface of the indoor unit 2 in front view. In addition, the outer surface 79 is provided with an air outlet 741 that is an opening along the longitudinal direction of the indoor unit 2. As shown in FIG. 3, the air outlet 741 communicates with the internal space in which the fan 71 is accommodated. From this air outlet 741, the air flow generated by the fan 71 is blown into the room. In addition, the air outlet 741 is provided with a horizontal flap 742 for guiding the air flow to be blown out. The horizontal flap 742 is provided so as to be rotatable about an axis parallel to the longitudinal direction of the indoor unit 2. The horizontal flap 742 is rotationally driven by a flap motor (not shown), and can open and close the air outlet 741.

(Blower unit)
FIG. 4 is a schematic plan view of the blower unit. The blower unit 8 includes a fan 71 and an indoor fan motor unit 72 for rotating the fan 71. The fan 71 is made of a resin material such as AS resin, is formed in a long and thin cylindrical shape, and is arranged so that the long axis is horizontal.

(fan)
FIG. 5 is a cross-sectional view of the fan and the indoor fan motor unit assembled in the support frame. The fan 71 includes end plates 710 and 711, a first shaft 712, a second shaft 713, and a wing portion 714. The end plates 710 and 711 are provided on both sides of the wing portion 714. The end plate 710 is formed integrally with the rotor 719 in order to connect the fan 71 and a rotor 719 described later. The first shaft 712 is disposed on the rotation axis of the end plate 710 and is connected to the end plate 710. The second shaft 713 is disposed on the rotation axis of the end plate 711 and is connected to the end plate 711. The first shaft 712 and the second shaft 713 serve as rotation axes when the fan 71 rotates.

(Indoor fan motor unit)
The indoor fan motor unit 72 is an outer rotor type motor, and includes a rotor 719 and a stator assembly 720.

  The rotor 719 is formed of a resin material containing minute magnet particles, and rotates by a magnetic force generated from the stator 721 of the stator assembly 720. Note that the rotor 719 is disposed on the radially outer side of the stator 721.

  FIG. 6 is an exploded perspective view of the stator assembly. As shown in FIG. 6, the stator assembly 720 includes a stator 721, a stator housing 731, a vibration isolating rubber 77, and a stator bearing 75. The stator 721 includes a cylindrical portion 722 that protrudes in the axial direction and a protruding portion 723 that protrudes radially outward of the cylindrical portion 722.

  The cylindrical portion 722 stores an iron core (not shown), a coil (not shown), and the like for generating a magnetic field, and is arranged with a certain clearance from the inner peripheral surface of the rotor 719 (see FIG. 5). Anti-vibration rubber 77 is attached to the protruding portion 723. The stator 721 has a bearing hole 724 penetrating in the center in the axial direction.

  As shown in FIG. 6, the stator housing 731 includes a stator case 732 and a stator cover 739. The stator case 732 has a cylindrical portion 733 and a cylindrical portion 734. Further, as shown in FIG. 5, a cylindrical portion 722 of the stator 721 is disposed in the cylindrical portion 733, and a predetermined interval is provided between the outer peripheral surface of the cylindrical portion 722 and the inner peripheral surface of the cylindrical portion 733. Space 733a is secured. A rotor 719 is inserted into the space 733a, but a certain gap is secured between the outer peripheral surface of the rotor 719 and the inner peripheral surface of the cylindrical portion 733.

  The cylindrical portion 734 houses the protruding portion 723 of the stator 721 to which the vibration isolating rubber 77 is attached. As shown in FIG. 6, the cylindrical portion 734 includes a partition 734 a that protrudes from the inner peripheral surface, and the partition 734 a causes the first vibration absorber 771, the second vibration absorber 772, and the second vibration absorber 772 of the vibration-proof rubber 77. Both ends of the three vibration absorber 773 are positioned. In addition, on the inner peripheral surface of the cylindrical portion 734, a slightly protruding convex portion 734 b is provided at a portion where the outer periphery on the bottom surface side of the second vibration absorber 772 contacts, and the outer periphery on the bottom surface side of the second vibration absorber 772 is provided. The cylindrical portion 734 is not in close contact with the inner peripheral surface.

  Since the inner diameter of the cylindrical portion 733 is smaller than the inner diameter of the cylindrical portion 734, a step 735 is formed at the boundary between the cylindrical portion 733 and the cylindrical portion 734. The first vibration absorber 771, the second vibration absorber 772, and the third vibration absorber 773 of the anti-vibration rubber 77 are held between the step 735 and the stator cover 739. In the step 735, a convex portion 735 a that slightly protrudes is provided at a portion in contact with the first vibration absorber 771, the second vibration absorber 772, and the third vibration absorber 773, so the first vibration absorber 771, The second vibration absorber 772 and the third vibration absorber 773 are not in close contact with the step 735.

  The stator cover 739 has a confirmation hole 739a in the center. The confirmation hole 739 a has a larger inner diameter than the bearing hole 724 of the stator 721. For this reason, when the stator bearing 75 is inserted into the bearing hole 724 of the stator 721, it is confirmed from the outside whether or not the stator bearing 75 is accurately fitted in the bearing hole 724.

(Anti-vibration rubber)
FIG. 7 is a cross-sectional view of the anti-vibration rubber, and FIG. 8 is a front view of the stator to which the anti-vibration rubber is attached. As shown in FIG. 7, the anti-vibration rubber 77 includes a first vibration absorber 771, a second vibration absorber 772, a third vibration absorber 773, and a thin plate-like connection that connects the vibration absorbers in the longitudinal direction. It consists of a body 774. The first vibration absorber 771 has a bag-shaped recess 771a. The recess 771a is provided to cover the protruding portion 723 of the stator 721, and is formed by an opening surface 771b, a bottom surface portion 771c, a short side surface portion 771d, and a long side surface portion 771e (see FIG. 6). Yes. The short side surface portion 771d is provided with a cavity portion 771f in order to reduce the rigidity in the circumferential direction.

  The second vibration absorber 772 also has a bag-like recess 772a. The concave portion 772a is provided to cover the protruding portion 723 of the stator 721, and is formed by an opening surface 772b, a bottom surface portion 772c, a short side surface portion 772d, and a long side surface portion 772e (see FIG. 6). Yes. The short side surface portion 772d is provided with a cavity portion 772f in order to reduce the rigidity in the circumferential direction.

  Furthermore, the third vibration absorber 773 also has a bag-shaped recess 773a. The concave portion 773a is provided to cover the protruding portion 723 of the stator 721, and is formed of an opening surface 773b, a bottom surface portion 773c, a short side surface portion 773d, and a long side surface portion 773e (see FIG. 6). Yes. The short side surface portion 773d is provided with a hollow portion 773f in order to reduce the rigidity in the circumferential direction.

  The first vibration absorber 771, the second vibration absorber 772, the third vibration absorber 773, and the connecting body 774 are integrally formed by a molding die. When the molding die is manufactured, if the connecting body 774 is kept straight, the length of the part becomes long, so that the number of vibration isolating rubber 77 on one side of the die is reduced, which is uneconomical. Therefore, in the present embodiment, the connection body 774 in the molding die is bent as shown in FIG.

  The connection body after being taken out from the molding die is made of rubber, so that it can be freely deformed and the bending is naturally eliminated. As already described, the first vibration absorber 771, the second vibration absorber 772, and the third vibration absorber 773 are attached to the three protrusions 723 of the stator 721, respectively. After assembly, the second vibration absorber 772 at the center is substantially vertically downward after assembly and receives the gravity of the stator 721, so that the bottom surface portion 772c is easily flattened. Therefore, a plurality of protrusions 772h are provided on the bottom surface portion 772c of the concave portion 772a of the second vibration absorber 772 in a direction against the gravity of the stator 721, and the flatness of the bottom surface portion 772c is suppressed. For this reason, the position shift of the stator 721 is suppressed.

  The gravity of the stator 721 also acts on the short side surface 771d of the recess 771a and the short side surface 773d of the recess 773a. The short side surfaces 771d and 773d are provided with projections 771h and 773h in a direction against the gravity of the stator 721. For this reason, the flatness of the short side surfaces 771d and 773d is suppressed, and the displacement of the stator 721 is suppressed.

  A convex portion 771k is provided on the inner surface of the long side surface 771e of the first vibration absorber 771. The convex portion 771k is fitted with a concave portion 723k (see FIG. 6) provided on the side surface of the protruding portion 723 of the stator 721, and is prevented from dropping due to its own weight during assembly.

  Similarly, a convex portion 773k is provided on the inner surface of the long side surface 773e of the third vibration absorber 773. The convex portion 773k is fitted into a concave portion 723k provided on the side surface of the protruding portion 723 of the stator 721, and is prevented from dropping due to its own weight during assembly.

  Further, as shown in FIG. 8, the assembled first vibration absorber 771 and third vibration absorber 773 are at a position away from the second vibration absorber 772 by 110 ° as the central angle. In other words, with respect to one protrusion 723 positioned vertically below the stator 721, the other two protrusions 723 are positioned 110 ° above the central angle, and the three vibrations correspond to them. The intervals between the absorbers 771, 772, and 773 are set.

  For this reason, if the operator makes a mistake in the mounting position of each vibration absorber, one of the three vibration absorbers 771, 772, and 773 cannot be mounted. To be prevented.

(bearing)
As shown in FIG. 5, the stator bearing 75 is a member that supports the first shaft 712 of the fan 71, and includes a bearing portion 751 and a bearing holding portion 752.

  The bearing portion 751 is made of a synthetic resin, and is disposed at a substantially central portion of the stator 721. The bearing holding portion 752 is formed of a rubber material in a cylindrical shape, and supports the bearing portion 751 so as to wrap the bearing portion 751 in order to suppress minute vibrations of the bearing portion 751 due to the rotation of the fan 71.

  The fan bearing 76 is a bearing that supports the second shaft 713 of the fan 71, and includes a bearing portion 761 and a bearing holding portion 762.

  The bearing portion 761 is made of synthetic resin and is provided on a part of the support frame 78 that faces the end plate 711 of the fan 71. The bearing holding portion 762 is formed of a rubber material in a cylindrical shape, and supports the bearing portion 761 so as to wrap the bearing portion 761 in order to suppress minute vibrations of the bearing portion 761 due to the rotation of the fan 71.

<Effects of rotor and fan rotation on each part>
Below, the influence which the rotor 719 and the fan 71 exert on each part when the rotor 719 and the fan 71 rotate is demonstrated.

  When the rotor 719 and the fan 71 rotate about the first shaft 712 and the second shaft 713, a minute vibration accompanying the rotation of the rotor 719 and the fan 71 is caused from the first shaft 712 and the second shaft 713 to the stator bearing 75. And transmitted to the fan bearing 76.

  In the stator bearing 75, minute vibrations are suppressed by the bearing portion 751 that supports the first shaft 712. In the fan bearing 76, minute vibrations are suppressed by the bearing portion 761 that supports the second shaft 713.

  The vibration that cannot be suppressed by the bearing portion 751 and the bearing portion 761 is transmitted from the stator bearing 75 to the stator 721 and from the fan bearing 76 to the support frame 78. The vibration transmitted from the stator bearing 75 to the stator 721 is absorbed and suppressed by the vibration isolating rubber 77 attached to the protruding portion 723 of the stator 721.

<Assembling the stator assembly>
Here, a method of assembling the stator assembly 720 will be described with reference to FIG. First, the operator attaches the first vibration absorber 771, the second vibration absorber 772, and the third vibration absorber 773 of the vibration-proof rubber 77 to the three protrusions 723 of the stator 721.

  Next, the operator inserts the stator 721 from the cylindrical part 734 side in the stator case 732 toward the cylindrical part 733 side. At this time, the first vibration absorber 771, the second vibration absorber 772, and the third vibration absorber 773 are positioned along the partition 734a of the cylindrical portion 734, and the first vibration absorber 771 and the second vibration absorber. 772 and the third vibration absorber 773 are inserted until they hit the step 735 of the stator case 732.

  Next, the operator inserts the stator cover 739 from the cylindrical portion 734 side of the stator case 732 toward the inside of the stator case 732. At this time, the claws 739d and 739e of the stator cover 739 are inserted until they fit into the claw holes 732d and 732e of the stator case 732.

  Next, the operator inserts the stator bearing 75 from the cylindrical portion 722 side of the stator 721 toward the inside of the bearing hole 724.

  In order to confirm whether or not the stator bearing 75 has been securely inserted into the bearing hole 724, the operator fits the stator bearing 75 into the bearing hole 724 from the confirmation hole 739 a of the stator cover 739. Visually check that

<Positioning of stator assembly to support frame>
FIG. 9 is a perspective view showing a state in which the blower unit is assembled to the support frame. The support frame 78 is a structure in which a back plate 786 that covers the back side of the wing 714 of the fan 71 and a lower plate 787 that covers the bottom of the wing 714 of the fan 71 are connected in a substantially L shape. At the corner of the support frame 78, a holding portion 788 that holds approximately half of the outer periphery of the stator case 732 is formed. After the stator case 732 is positioned on the holding portion 788, the outer peripheral holding plate 81 is attached to the support frame 78 so as to cover the exposed outer periphery of the stator case 732.

<Removing the indoor fan motor unit>
When an operator must replace the indoor fan motor unit 72 due to a failure or the like, first, the stator cover 739 is removed from the stator case 732, and then the stator 721 is pulled out in the axial direction. Thus, since the stator 721 can be removed with the outer peripheral holding plate 81 attached, workability is good.

<Features>
(1)
In the fan motor unit 72, the vibration isolation member 77 is mounted along the outer periphery of the stator 721 and absorbs the vibration of the stator 721. The vibration isolator 77 has a plurality of bag-like vibration absorbers 771, 772, 773 and a thin plate-like connector 774 that connects the plurality of vibration absorbers 771, 772, 773 in the longitudinal direction. .
In the fan motor unit 72, the operation of taking out the vibration isolating member 77 takes less time than the operation of taking out the plurality of vibration absorbers one by one, and the assembling workability is improved.
Further, when the vibration absorbers 771, 771, 773 are mounted along the outer periphery of the stator 721, the distance between the vibration absorbers connected by the connecting body 774 and the vibration absorption not connected by the connecting body 774 are obtained. The intervals between the bodies are uneven, and the operator cannot correctly mount the vehicle if the mounting position is incorrect. For this reason, the operator can quickly recognize an error in the mounting position of the vibration isolating member, and assembly failure is prevented in advance.
Further, the vibration absorbers 771, 772, and 773 have bag-like recesses 771a, 772a, and 773a that fit into the protrusions 723, so that whether the fitting state is good or not can be confirmed quickly, and assembly failure can be prevented in advance. Is done.
(2)
In this fan motor unit 72, since the vibration absorbers 771, 772, 773 and the connecting body 774 are integrally formed, the vibration absorbers 771, 772, 773 and the connecting body 774 are simultaneously formed of the same material, and the material As a result, the manufacturing cost is reduced.
Further, when the vibration absorbers 771, 772, 773 and the connecting body 774 are integrally formed, the connecting body 774 is formed in a bent state. By bending the connecting body 774, the longitudinal dimension of the vibration isolating member 77 in the molding die is shortened. For this reason, the number of vibration isolation members in the molding die is increased, and the unit price is reduced.
(3)
In the fan motor unit 72, the vibration absorbers 771, 772, and 773 have protrusions 771h, 772h, and 773h that protrude in a direction against the gravity of the stator 721 and come into contact with the protruding portion 723. In particular, the second vibration absorber 772 whose position after assembly is substantially vertically downward has a larger number of protrusions than the first vibration absorber 771 and the third vibration absorber 773. Since the protrusions 771h, 772h, and 773h are deformed by the gravity of the stator 721 and relieve the stress, the areas other than the protrusions 771h, 772h, and 773h are suppressed from being flattened by the gravity of the stator, and the position of the stator Deviation is also suppressed.

  As described above, the present invention has good assembling workability of the vibration isolating member that absorbs the vibration of the stator, and is useful for the fan motor unit having a structure in which the rotor and the stator are separated.

The external view of an air conditioning apparatus. The block diagram of the refrigerant circuit of an air conditioning apparatus. The right side sectional view of the indoor unit of the air conditioner. The schematic plan view of a ventilation unit. Sectional drawing of the fan assembled to the support frame and the indoor fan motor unit. The disassembled perspective view of a stator assembly. Sectional drawing of vibration-proof rubber. The front view of the stator with which the anti-vibration rubber was mounted | worn. The perspective view which shows the state by which a ventilation unit is assembled to a support frame.

Explanation of symbols

2 Air conditioning indoor unit 50 Indoor heat exchanger 71 Fan 72 Indoor fan motor unit 77 Vibration isolator 712 First shaft (rotating shaft)
719 Rotor 721 Stator 723 Projection 771 First vibration absorber 772 Second vibration absorber 773 Third vibration absorbers 771a, 772a, 773a Recesses 771h, 772h, 773h Protrusion 774 Connecting body

Claims (8)

A fan motor unit that rotates a fan (71) disposed in an air conditioning indoor unit (2),
A rotor (719) fixed to the rotating shaft (712) of the fan (71) and rotated by the action of magnetic force;
A stator (721) for applying a magnetic force to the rotor (719);
A vibration isolating member (77) attached to the stator (721);
A housing (731) for housing the stator (721) and the vibration isolation member (77);
With
The vibration isolator (77) includes a plurality of vibration absorbers (771, 772, 773) that absorb vibration of the stator (721) and a plurality of vibration absorbers (771, 772, 773) in the longitudinal direction. A thin plate-like connecting body (774) connected to
The vibration absorber (771, 772, 773) is interposed between the housing (731) and the stator (721) to hold the stator (721) and regulate the position thereof.
A fan motor unit (72). When the vibration absorber (771, 772, 773) is mounted along the outer periphery of the stator (721), the interval between the vibration absorbers connected by the connector (774), and the connector (774) and the spacing between the vibration absorbers that are not connected to each other is uneven.
The fan motor unit (72) according to claim 1. The stator (721) has a protruding portion (723) protruding outward in a region where the vibration absorber (771, 772, 773) is mounted,
The vibration absorber (771, 772, 773) has a bag-shaped recess (771a, 772a, 773a) that fits into the protrusion (723).
The fan motor unit (72) according to claim 1. The vibration absorber (771, 772, 773) and the coupling body (774) are integrally formed.
The fan motor unit (72) according to claim 1. When the vibration absorber (771, 772, 773) and the coupling body (774) are integrally molded, the coupling body (774) is molded in a bent state.
The fan motor unit (72) according to claim 4. The vibration absorber (771, 772, 773) has protrusions (771h, 772h, 773h) that protrude in a direction against the gravity of the stator (721) and come into contact with the protrusion (723). ,
The fan motor unit (72) according to claim 1. Of the plurality of vibration absorbers (771, 772, 773), the vibration absorber (772) whose position after assembly is substantially vertically downward is the protrusion more than the other vibration absorbers (771, 773). There are many (771h),
The fan motor unit (72) according to claim 6. The fan (71);
The fan motor unit (72) according to any one of claims 1 to 7, wherein the fan (71) is rotated.
An indoor heat exchanger (50) for exchanging heat with an air flow generated by rotation of the fan (71);
Air-conditioning indoor unit (2) provided with.

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