JP2018189309A - Indoor equipment of air conditioner - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide indoor equipment of an air conditioner which can reduce abnormal noise and rattling occurring when a flap is rotated.SOLUTION: Indoor equipment of an air conditioner includes: a flap which changes a wind direction; housing side brackets which support the flap located below on a body part; and connection shafts 21 which are fixed to the flap and inserted into shaft insertion holes formed at the housing side brackets to rotate the flap in the shaft insertion holes. The connection shaft 21 has a lower claw part 29b and an upper claw part 29a which are inserted into the shaft insertion hole to contact with an inner periphery of the shaft insertion hole at outer peripheries. The lower claw part 29b has rigidity higher than that of the upper claw part 29a.SELECTED DRAWING: Figure 6

Description

  The present invention relates to an indoor unit of an air conditioner including a flap that changes a wind direction.

The indoor unit of the air conditioner is provided with a flap for changing the air direction after air conditioning in the vertical direction. In order to rotate the flap, a mechanism for supporting the flap so as to be rotatable with respect to the main body of the indoor unit is provided.
In Patent Document 1, the flap is rotatably supported by inserting a connecting member fixed to the flap into the main body attachment hole.

JP 2017-53508 A

The connecting member described in Patent Document 1 supports the flap while maintaining a contact state with respect to the inner peripheral surface of the main body attachment hole by elastically deforming the four elastic deformation pieces.
As a result of further studies by the present inventors, it has been found that the deformation state of the four elastically deformable pieces differs depending on the rotation angle when a load due to the weight of the flap is applied to the connecting member. That is, since the load of the flap is applied below the connecting member, the elastic deformation piece located below is most deformed. If the elastic deformation piece to which the flap load is applied changes according to the rotation of the flap, the deformation state of the elastic deformation piece changes, which may cause abnormal noise and rattling.

  This invention is made in view of such a situation, Comprising: It aims at providing the indoor unit of the air conditioning apparatus which can reduce the noise and rattle which arise when rotating a flap. .

In order to solve the above problems, the indoor unit of the air conditioner of the present invention employs the following means.
That is, the indoor unit of the air conditioner according to the present invention includes a flap that changes a wind direction, a support portion that supports the flap positioned below with respect to a main body portion, and is fixed to the flap, and the support portion And a connecting member that is inserted into the through hole formed in the through hole and pivots the flap within the through hole. The connecting member is inserted into the through hole and has an outer periphery that contacts the inner periphery of the through hole. It has a nail | claw part and an upper nail | claw part, The said nail | claw part has rigidity larger than the said upper nail | claw part, It is characterized by the above-mentioned.

A support part is supported so that a lower flap may rotate via a connection member. By rotating the flap, the air direction after the air conditioning blown out from the indoor unit is changed.
The connecting member is fixed to the flap, and is inserted into a through hole formed in the support portion. Thereby, a flap is attached so that rotation with respect to a support part is possible.
The connecting member has a lower claw portion and an upper claw portion, and is attached so that each claw portion contacts the inner periphery of the through hole. And while a lower nail | claw part receives the load by the dead weight of the flap located below, an upper nail | claw part does not receive the load by the dead weight of a flap. Therefore, the rigidity of the lower claw portion is made larger than that of the upper claw portion, and the deformation amount of the lower claw portion that receives the load of the flap is made as small as possible. As a result, even if the flap rotates together with the connecting member around the center of the through hole, the load of the flap is received by the lower claw portion, so that it is possible to reduce noise and rattling due to deformation of the connecting member.

  Furthermore, in the indoor unit of the air conditioning apparatus of the present invention, the distance from the rotation center of the connecting portion to the outer peripheral surface of the upper claw portion is greater than the distance from the rotation center to the outer peripheral surface of the lower claw portion. It is large.

  The distance from the rotation center of the connecting member to the outer peripheral surface of the upper claw portion was made larger than the distance from the rotation center of the connection portion to the outer peripheral surface of the lower claw portion. Thereby, the upper claw part can be deformed positively (bend) rather than the lower claw part, and can be suitably brought into contact with the inner peripheral surface of the through hole of the support part.

  Furthermore, in the indoor unit of the air conditioning apparatus of the present invention, the outer peripheral surface of the lower claw portion is a substantially cylindrical surface formed over approximately 180 °.

  If the neutral position of the rotation range of the flap is set at the center of the lower claw portion by setting the outer peripheral surface of the lower claw portion to a substantially cylindrical surface formed over about 180 °, the rotation range of about 180 ° The flap load can be received at the lower nail portion.

  Since the load of the flap is received by the lower claw part having higher rigidity than that of the upper claw part, it is possible to reduce noise and rattling due to the deformation of the connecting member.

It is the perspective view which showed the indoor unit of the air conditioning apparatus which concerns on one Embodiment of this invention. It is sectional drawing in II-II of FIG. It is a front view which shows the state which removed the suction panel of the front surface of the indoor unit of FIG. It is the perspective view which showed the attaching part. It is the disassembled perspective view which showed the attaching part. It is the side view which showed the connection shaft. It is the front view which showed the connection shaft. It is the longitudinal cross-sectional view which showed the connection shaft inserted in the shaft connection hole. It is the elements on larger scale which showed the connection shaft inserted in the shaft connection hole.

Hereinafter, an indoor unit 1 of an air conditioner according to an embodiment of the present invention will be described in detail with reference to the drawings.
As shown in FIGS. 1, 2, and 3, an indoor unit 1 of an air conditioner is housed in a housing 2 that has a horizontally long rectangular parallelepiped shape in a horizontal direction during installation, and inside the housing 2. An air conditioner (main body part) 3 is provided. The indoor unit 1 is an apparatus that performs air conditioning in the room by sucking air A and adjusting the temperature and humidity and then discharging the air A from the outlet 4. The indoor unit 1 of this embodiment is provided with a flap 8 that changes the blowing direction of the air A up and down.

  In the present embodiment, the horizontal direction during installation is defined as the left-right direction, the vertical direction during installation is simply defined as the vertical direction, and the directions perpendicular to the horizontal direction and the vertical direction are defined as the front-rear direction. Note that the front side in the front-rear direction is the front side during installation.

  As shown in FIG. 2, the air conditioner 3 includes a heat exchanger 5, a blower fan 6 provided so as to be covered by the heat exchanger 5, a filter 7 provided at an air A suction port, and an air A A flap 8 provided at the outlet 4 and a control box 9 (see FIG. 3) provided on one end side in the left-right direction for controlling air conditioning.

The housing 2 includes a front panel 10 disposed on the front side that is the front side during installation, a top panel 11 that is integrally connected to the front panel 10 and disposed upward during installation, and the front panel 10 and the top panel 11. And a housing body 12 that forms a space S in which the air conditioner 3 is accommodated.
The housing 2 has a suction panel 13 that covers the front panel 10 from the front.

  The housing body 12 includes a pair of side panels 14 arranged in the left-right direction, a back panel 15 integrally connected to the pair of side panels 14 and facing the installation surface, and the pair of side panels 14 and the back panel 15. And a bottom panel 16 disposed below.

The housing body 12 forms a space S that houses the air conditioner 3 surrounded by the pair of side panels 14, the back panel 15, and the bottom panel 16. In the case main body 12, the space S is opened forward and upward. That is, the housing body 12 is formed with a front opening OP1 penetrating the housing 2 in the front-rear direction and an upper surface opening OP2 penetrating in the vertical direction.
The air A is taken into the space S of the housing 2 from the upper surface opening OP2.

  The front panel 10 has a lattice shape and is provided integrally with the housing body 12 on the front side of the front opening OP1. The upper surface panel 11 has a lattice shape and is provided integrally with the housing body 12 on the upper surface side of the upper surface opening OP2.

  The suction panel 13 is arranged further forward of the front panel 10 so as to cover the front opening OP1 and the front panel 10. The suction panel 13 can be attached to and detached from the housing body 12 to open and close the front opening OP1.

  A flap 8 provided at the outlet 4 is a wind direction adjusting plate that changes the vertical direction of the air A from the outlet 4. The indoor unit 1 includes two flaps 8. The two flaps 8 can be arranged so as to block the outlet 4. The two flaps 8 can be rotated around the axis O so as to follow the flow of the air A discharged by the blower fan 6.

  Next, the attachment structure of the flap 8 will be described. Here, the attachment structure of the flap 8 arrange | positioned back among the two flaps 8 is demonstrated. Of the two flaps 8, the attachment structure of the flap 8 disposed in the front is substantially the same as the attachment structure of the flap 8 disposed in the rear, and the description thereof is omitted.

  As shown in FIG. 3, the flaps 8 are connected to the housing 2 through a mounting portion 17 so as to be rotatable around an axis O extending in the left-right direction at a plurality of positions spaced in the left-right direction. . The flap 8 is rotationally driven around the axis O by a drive motor (not shown) provided on one end side in the axis O direction (left-right direction). For this reason, a pin 35 extending in the direction of the axis O is provided at one end of the flap 8, and this pin 35 is connected to a drive motor (not shown).

  As shown in FIGS. 4 and 5, the attachment portion 17 includes a flap side bracket 19 provided integrally with the flap body 18 of the flap 8, and a case side bracket (support portion) 20 provided on the case 2. And a connecting shaft (connecting member) 21 that connects the flap-side bracket 19 and the housing-side bracket 20. In addition, the code | symbol 22 shows the housing | casing side bracket used for the flap arrange | positioned ahead.

  The flap 8 includes a plate-shaped flap body 18 that is long in the left-right direction, and a flap-side bracket 19 provided on the flap body 18 at a position corresponding to the mounting portion 17.

  The flap side bracket 19 is integrally formed on one surface 18f of the flap body 18 so as to extend in a direction orthogonal to the surface 18f of the flap body 18. The flap side bracket 19 has a plate shape, and a main surface orthogonal to the axis O is formed.

  The flap side bracket 19 has a triangular shape when viewed from the direction of the axis O. The flap-side bracket 19 is formed with a rectangular shaft engagement hole 23 (see FIG. 5) penetrating in the direction of the axis O.

  The housing side bracket 20 has a plate shape, and a main surface orthogonal to the direction of the axis O is formed so as not to hinder the flow of the air A blown from the blowout port 4. The housing side bracket 20 is formed with a shaft insertion hole (through hole) 24 penetrating in the direction of the axis O. The shaft insertion hole 24 has a circular shape, for example.

  In the connection shaft 21, the engagement claw portion 26 engages with the shaft engagement hole 23 of the flap side bracket 19 in a state where the one end 25 a side of the shaft body 25 is inserted into the shaft insertion hole 24 formed in the housing side bracket 20. Has been.

  The shaft body 25 has a cylindrical shape centered on the central axis, that is, the axis O. As shown in FIG. 6, the shaft main body 25 includes an insertion main body portion 27 having an outer diameter smaller than the inner diameter of the shaft insertion hole 24 and an enlarged diameter portion 30 having an outer diameter larger than the inner diameter of the shaft insertion hole 24. And have.

  The insertion main body 27 has a disc shape in which a main surface orthogonal to the central axis (axis O) of the shaft main body 25 is formed on the one end 25a side of the shaft main body 25. That is, the insertion main body 27 closes the one end 25 a of the enlarged diameter portion 30.

  The enlarged diameter portion 30 has a cylindrical shape whose diameter is increased from the one end 25a side toward the other end 25b side with the insertion main body portion 27 as a base portion. A flange portion 44 that protrudes radially outward at the other end 25 b of the shaft body 25 is formed in the enlarged diameter portion 30. The flange portion 44 has the largest outer diameter in the shaft body 25. The outer diameter of the flange portion 44 is larger than that of the shaft insertion hole 24, and prevents the connection shaft 21 from coming off.

  The enlarged diameter portion 30 has slits 28 formed at two locations in the circumferential direction. The slit 28 extends from the other end 25b of the shaft body 25 toward the one end 25a side in the direction of the central axis (axis O) of the shaft body 25 to the insertion body 27. The slit 28 forms an upper upper claw portion 29a and a lower lower claw portion 29b in the enlarged diameter portion 30.

  The upper claw portion 29a and the lower claw portion 29b extend from the insertion main body portion 27 toward the other end 25b side. That is, the upper claw portion 29a and the lower claw portion 29b have a cantilever shape in which the insertion main body portion 27 is a fixed end and the distal end portion on the other end 25b side is a free end.

  As shown in FIG. 7, the lower claw portion 29b has a semicircular arc outline formed over approximately 180 ° when viewed from the front. The outer peripheral surface of the lower claw portion 29b (excluding the flange portion 44) is tapered so as to increase in diameter, and the radius of curvature at any position in the axial direction is substantially equal to the radius of curvature of the shaft insertion hole 24. I'm doing it. Therefore, when the connecting shaft 21 is inserted into the shaft insertion hole 24 as shown in FIG. 8, the entire outer peripheral surface of the lower claw portion 29 b comes into contact with and matches the inner peripheral surface of the shaft insertion hole 24.

  When the lower claw portion 29b is fixed to the flap side bracket 19 as shown in FIG. 9 and the flap 8 is positioned at the neutral position in the rotation direction, the central position in the circumferential direction of the lower claw portion 29b is the axis O. It is set so that it may be located on the vertical line VL (refer FIG. 7) which passes through. Accordingly, the lower claw portion 29b comes into contact with the inner periphery of the shaft insertion hole 24 over an angle range of ± 90 ° from the center position of the lower claw portion 29b.

When viewed from the front, the upper claw portion 29a has an outer line that is an arc formed over an angle range smaller than approximately 180 °. The outer peripheral surface (except for the flange portion 44) of the upper claw portion 29a is tapered to increase the diameter. When the upper claw portion 29a and the lower claw portion 29b are viewed from the front as shown in FIG. 7, the radius R1 of the upper claw portion 29a is larger than the radius R2 of the lower claw portion 29b (R1> R2). Moreover, the lower nail | claw part 29b has larger rigidity than the upper nail | claw part 29a. Specifically, since the arc length of the outer shape of the lower claw portion 29b is longer than the arc length of the outer shape of the upper claw portion 29a, the rigidity of the lower claw portion 29b is increased. Further, the thickness of the lower claw portion 29b (the thickness in the radial direction) may be larger than the thickness of the upper claw portion 29a.
Therefore, when the connecting shaft 21 is inserted into the shaft insertion hole 24, the upper claw portion 29a is deformed (bends) toward the axis O, and the lower claw portion 29b is hardly bent. Thus, since the lower claw portion 29 b hardly deforms, the entire outer peripheral surface of the lower claw portion 29 b comes into contact with the inner peripheral surface of the shaft insertion hole 24. And even if the flap 8 rotates around the shaft insertion hole 24 and the load position due to the weight of the flap 8 changes, the lower claw portion 29b hardly deforms due to rigidity, so that the entire outer peripheral surface of the lower claw portion 29b is The state of matching with the inner peripheral surface of the shaft insertion hole 24 is maintained.

According to the indoor unit 1 described above, the following operational effects can be obtained.
The lower claw portion 29 b and the upper claw portion 29 a of the connecting shaft 21 are inserted into the shaft insertion hole 24 and attached so as to contact the inner periphery of the shaft insertion hole 24. The lower claw portion 29 b receives a load due to the weight of the flap 8 positioned below, while the upper claw portion 29 a does not receive a load due to the weight of the flap 8. Therefore, the rigidity of the lower claw portion 29b is made larger than that of the upper claw portion 29a, and the deformation amount of the lower claw portion 29b that receives the load of the flap 8 is made as small as possible. Thereby, even if the flap 8 rotates together with the connecting shaft 21 around the axis O of the shaft insertion hole 24, the load of the flap 8 is received by the lower claw portion 29b, so that the claw portions 29a and 29b of the connecting shaft 21 are deformed. Abnormal noise and rattling can be reduced.

  The radius R1 from the axis O which is the rotation center of the connecting shaft 21 to the outer peripheral surface of the upper claw portion 29a is larger than the radius R2 from the axis O which is the rotation center of the connecting shaft 21 to the outer peripheral surface of the lower claw portion 29b. Increased. Thereby, the upper claw part 29a can be suitably brought into contact with the inner peripheral surface of the shaft insertion hole 24 of the housing side bracket 20 so as to positively deform (bend) the upper claw part 29a rather than the lower claw part 29b.

  By setting the outer peripheral surface of the lower claw portion 29b to a substantially cylindrical surface formed over approximately 180 °, the neutral position of the rotation range of the flap 8 is set at the center of the lower claw portion 29b. Thereby, it is possible to receive the load of the flap 8 while reducing abnormal noise and rattling at the lower claw portion 29b over a rotation range of about 180 °.

1 Indoor unit 2 Housing 3 Air conditioning equipment (main unit)
4 Outlet 5 Heat Exchanger 6 Blower Fan 7 Filter 8 Flap 9 Control Box 10 Front Panel 11 Top Panel 12 Housing Body 13 Suction Panel 14 Side Panel 15 Back Panel 16 Bottom Panel 17 Mounting Portion 18 Flap Body 18f Surface 19 Flap Side Bracket 20 Case side bracket (support)
21 Connection shaft (connection member)
23 Shaft engagement hole 24 Shaft insertion hole (through hole)
25 Shaft body 25a One end 25b The other end 26 Engaging claw part 27 Inserting main body part 28 Slit 29a Upper claw part 29b Lower claw part 30 Wide diameter part 35 Pin 44 Flange part A Air O Axis line OP1 Front opening part OP2 Upper surface opening part R1, R2 radius S space VL vertical line

Claims (3)

A flap that changes the wind direction,
A support part for supporting the flap located below with respect to the main body part;
A coupling member fixed to the flap and inserted into a through hole formed in the support portion to rotate the flap within the through hole;
With
The connecting member has a lower claw portion and an upper claw portion that are inserted into the through hole and whose outer periphery contacts the inner periphery of the through hole,
The indoor unit of an air conditioner, wherein the lower claw portion has higher rigidity than the upper claw portion.   2. The air according to claim 1, wherein a distance from a rotation center of the connecting member to an outer peripheral surface of the upper claw portion is larger than a distance from the rotation center to an outer peripheral surface of the lower claw portion. The indoor unit of the harmony device.   The indoor unit of the air conditioner according to claim 1 or 2, wherein an outer peripheral surface of the lower claw portion is a substantially cylindrical surface formed over approximately 180 °.

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