JP2019082284A - Damper device - Google Patents

Abstract

To provide a damper device capable of preventing or suppressing an increase in vibration noise caused by vibration of a motor for linearly moving a movable cover.SOLUTION: A damper device 1 includes: a movable cover for controlling a flow rate of gas passing through an opening portion; a drive unit 3 for linearly moving the movable cover between a first position 2A at which the flow rate becomes a first flow rate and a second position that is located closer to the opening portion than the first position 2A and at which the flow rate becomes a second flow rate smaller than the first flow rate; and a support body 4 having a support portion 13 for supporting the drive unit 3. The drive unit 3 includes a motor body 67 (motor). The support body 4 includes fan support shafts 31-33 each protruded in an X1 direction at an outer peripheral side of the support portion 13 and having a tip to which a centrifugal fan is fixed. Through holes 40-42 are provided in a region at the outer peripheral side of the support portion 13 in an end plate portion 11 of the support body 4 and nearer to the support portion 13 than the fan support shafts 31-33.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a damper device that adjusts the flow rate of fluid passing through an opening.

  Patent Document 1 describes a damper device which is disposed in an opening of a fluid passage through which a fluid such as cold air flows in a refrigerator to adjust the flow rate of the fluid passing through the opening. The damper device of Patent Document 1 includes a movable cover for adjusting the flow rate of fluid, a drive unit for driving the movable cover, and a support for supporting the drive unit. The support comprises a support-side opening in communication with the opening of the fluid passage. The drive unit includes a motor as a drive source, and a rotating body that is rotated by driving the motor. The movable cover, by transmitting the rotation of the rotating body through the feed screw mechanism, linearly moves between an abutting position abutting on the support and a separated position separating from the support. When the movable cover is placed in the abutting position, the support side opening is covered by the movable cover, so that the flow of fluid through the opening is blocked. When the movable cover is disposed at the separated position, the fluid flows through the opening, the support side opening, and the support and the movable cover.

JP, 2016-161232, A

  When the vibration of the motor which is the drive source of the drive unit is transmitted to the support, the vibration may be amplified by the support, and the vibration noise may increase.

  In view of such a problem, an object of the present invention is to provide a damper device capable of preventing or suppressing an increase in vibration noise caused by vibration of a motor for moving the movable cover directly.

  In order to solve the above-mentioned subject, the damper device of the present invention has a movable cover for adjusting a flow rate of gas passing through an opening, the movable cover, and a first position where the flow rate becomes a first flow rate; A drive unit that linearly moves between a second position where the flow rate is closer to the opening than the first position and the second flow rate is smaller than the first flow rate; and a support for supporting the drive unit The drive unit includes a motor as a drive source, and the support is provided on the outer peripheral side of the support from the first position in the linear movement direction of the movable cover. A fan supporting shaft is provided which protrudes in the closing direction toward the second position and the fan is fixed to the tip end portion, and is an outer peripheral side of the supporting portion in the supporting body and closer to the supporting portion than the fan supporting shaft. The area is provided with a through hole And said that you are.

  In the present invention, the through hole is provided on the outer peripheral side of the support portion for supporting the drive unit in the support. Therefore, even when the vibration of the motor which is the drive source of the drive unit is transmitted to the support via the support, the propagation of the vibration can be blocked or suppressed by the through hole. Therefore, the vibration of the motor is amplified by the support, and the vibration noise can be prevented or suppressed from becoming large.

In the present invention, it is desirable that the through hole is provided at a position closer to the support portion than the fan support shaft. In this way, the propagation of the vibration of the motor can be shut off or suppressed at a position close to the support portion.

  In the present invention, the through hole may have an arc shape extending in the circumferential direction along the outer periphery of the support portion. In this way, even when the opening area of the through hole is small, the propagation of the vibration can be efficiently suppressed. That is, if the through hole is formed in an arc shape extending in the circumferential direction, it is easy to reduce the connecting portion connecting the support portion and the portion of the support located on the outer peripheral side of the through hole. Here, if the connection portion is small, the vibration propagating from the support portion is easily attenuated by the connection portion.

  In the present invention, it is preferable that the through hole includes a plurality of the through holes provided around the support portion. In this way, it is easy to increase the total open area of the through holes. This makes it possible to reduce the area of the portion of the support that propagates the vibration from the support portion, so it is easy to suppress the propagation of the motor's vibration.

  In the present invention, a plurality of the fan support shafts provided around the support portion may be provided as the fan support shaft. If the fans are supported by the plurality of fan support shafts, the support can reliably support the fans.

  In the present invention, the support includes an attachment portion for fixing the support to an external device, and the attachment portion is provided on the outer peripheral side of the plurality of fan supporting shafts surrounding the support portion. Can be. In this way, even when the vibration of the motor, which is the drive source of the drive unit, is transmitted to the support via the support, the vibration is up to the mounting portion located on the outer peripheral side of the plurality of fan support shafts. It is easy to suppress propagation.

  In the present invention, in order to linearly move the movable cover between the first position and the second position, the drive unit is driven by the motor and rotates about an axis extending in the linear movement direction of the movable cover. The rotating body includes a rotating body, and the rotating body includes an engaging portion having a helical convex portion or a concave portion on the outer peripheral surface, and the movable cover has a portion where the engaging portion of the rotating body is formed. A rotating body disposition hole disposed inside, and an engaged portion configured to engage with the engagement portion at an inner peripheral surface of the rotation body disposition hole to configure the engagement portion and the feed screw mechanism It can be done.

  In the present invention, the drive unit may include a gear train that transmits the rotation of the motor to the rotating body. In the case where the drive unit is provided with a gear train, vibrations may be generated and transmitted to the side of the support when the gear train is driven. However, the transmission of the vibrations is achieved by the through holes provided in the support. Can be blocked or suppressed.

  In the present invention, the movable cover protrudes in the closing direction from the facing portion facing the support in the linear movement direction and the outer peripheral edge of the facing portion, and is fixed to the fan support shaft at the second position. A side plate portion positioned on an outer peripheral side of the fan may be provided, and the fan supporting shaft may penetrate the opposing portion. With this configuration, when the movable cover is disposed at the second position, it becomes easy to cover the fan fixed to the tip portion of the fan support shaft from the outer peripheral side by the movable cover.

  In the present invention, the motor can be a stepping motor. In the stepping motor, periodic vibration occurs during driving, so this vibration may be transmitted to the side of the support. However, the transmission of the vibration can be blocked or suppressed by the through holes provided in the support.

  In the damper device of the present invention, a through hole is provided on the outer peripheral side of the support portion of the drive unit in the support body. Therefore, even when the vibration of the motor which is the drive source of the drive unit is transmitted to the support via the support, the propagation of the vibration can be blocked or suppressed by the through hole. Therefore, the vibration of the motor is amplified by the support, and the vibration noise can be prevented or suppressed from becoming large.

It is a top view at the time of seeing the damper device to which the present invention is applied from the side of a support body. It is a perspective view at the time of seeing the damper device to which the present invention is applied from the side of a support body. It is a perspective view of a damper device in the state where a movable cover is in the 1st position. It is a perspective view of a damper device in the state where a movable cover is in the 2nd position. It is explanatory drawing of operation | movement of a damper apparatus. It is an exploded perspective view when a damper device is seen from the side of a support body. It is an exploded perspective view when a damper device is seen from the side of a movable cover. It is an exploded perspective view of a support body and a drive unit. It is an exploded perspective view of a drive unit. It is a top view at the time of seeing a damper device of a modification from the side of a support body.

  Hereinafter, an embodiment of a damper device to which the present invention is applied will be described with reference to the drawings.

(overall structure)
FIG. 1 is a plan view of a damper device to which the present invention is applied as viewed from the side of a support. FIG. 2 is a perspective view of a damper device to which the present invention is applied as viewed from the side of a support. FIG. 3 is a perspective view of the damper device when the movable cover is in the first position as viewed from the side of the movable cover. FIG. 4 is a perspective view of the damper device when the movable cover is in the second position as viewed from the side of the movable cover. FIG. 5 (a) is a side view of the damper device with the movable cover in the first position, and FIG. 5 (b) is a side view of the damper device with the movable cover in the second position. FIG. 6 is an exploded perspective view of the damper device as seen from the side of the support. FIG. 7 is an exploded perspective view of the damper device as viewed from the side of the movable cover. FIG. 8 is an exploded perspective view of a support and a drive unit. The damper device 1 controls the flow rate of the fluid flowing through the opening O of a fluid passage such as a duct through which the fluid flows. In this example, the damper device 1 adjusts the flow rate of the cold air flowing through the opening O provided in the cold air passage in the refrigerator. The damper device 1 is disposed at a position opposite to the opening O outside the cold air flow path.

  As shown in FIG. 3 and FIG. 4, the damper device 1 has a movable cover 2 for adjusting the flow rate of cold air flowing through the opening O, and a direction in which the movable cover 2 approaches and separates from the opening O It has a drive unit 3 that drives in linear motion, and a support 4 that supports the drive unit 3. Further, the damper device 1 has a wire 5 for supplying power to the drive unit 3. In FIG. 3 and FIG. 4, the cold air flow path is on the opposite side to the damper device 1 across the opening O.

  The support 4 is, as shown in FIGS. 1 and 2, one of four sides defining a square end plate portion 11 positioned on one side of the movable cover 2 and an outer peripheral edge of the end plate portion 11. And a side plate portion 12 extending to the movable cover 2 side. The end plate portion 11 extends perpendicularly to the linear movement direction in which the movable cover 2 linearly moves. At a central portion of the end plate portion 11, a support portion 13 for supporting the drive unit 3 is provided. As shown in FIG. 3, the drive unit 3 is attached to the support 13 and protrudes toward the movable cover 2. At an outer peripheral edge portion of the end plate portion 11, a mounting portion 14 for fixing the damper device 1 (support 4) to an external device such as a refrigerator is provided. In the present example, the mounting portions 14 are mounting holes provided at the four corners of the end plate portion 11 respectively. The support 4 is fixed to a refrigerator or the like by a screw passing through the mounting hole.

  The movable cover 2 has a first position 2A in which the flow rate of cold air flowing through the opening O is a first flow rate when the drive unit 3 is driven, and a second position 2B in which a second flow rate is a flow rate smaller than the first flow rate. To move between As shown to FIG. 3 and FIG. 5 (a), in the 1st position 2A, the movable cover 2 is spaced apart from the opening O, and is arrange | positioned in the position near the end plate part 11. As shown in FIG. As shown in FIGS. 4 and 5B, in the second position 2B, the movable cover 2 is disposed at a position spaced apart from the end plate 11 more than the first position 2A, and the opening O than the first position 2A. Is approaching.

  In the following description, the posture of the damper device 1 shown in FIGS. 1 to 4 is referred to as an installation posture 1A of the damper device 1. In the installation posture 1A, the linear movement direction of the movable cover 2 is horizontal. Further, in the installation posture 1A, three directions orthogonal to each other are taken as an X direction, a Y direction, and a Z direction. The X direction is the linear movement direction of the movable cover 2 and is the horizontal direction when the damper device 1 is in the installation posture 1A. The Y direction is the width direction of the damper device 1, and the Z direction is the vertical direction. Further, in the X direction (the linear movement direction), the side on which the end plate portion 11 is positioned is referred to as the X1 direction, and the side on which the movable cover 2 is positioned is the X2 direction. The X1 direction is an opening direction for releasing the opening O, and the X2 direction is a closing direction for narrowing the opening O. In the Y direction, the side on which the side plate portion 12 is positioned is taken as the Y1 direction, and the opposite side is taken as the Y2 direction. Further, the lower side in the Z direction is taken as the Z1 direction, and the upper side in the Z direction is taken as the Z2 direction. In the installation posture 1A, the end face 11a of the end plate portion 11 faces in the X1 direction. Further, in the installation posture 1A, the side plate portion 12 includes the side surface 12a that extends in the up-down direction facing the Y1 direction. The end surface 11 a of the end plate portion 11 and the side surface 12 a of the side plate portion 12 are orthogonal to each other. Hereinafter, the damper device 1 will be described in the installation posture 1A.

(Support)
The support 4 is made of resin. As shown in FIGS. 1 and 2, a support portion 13 for supporting the drive unit 3 is provided at a central portion of the end plate portion 11. The contour of the support 13 as viewed in the X direction is substantially circular. As shown in FIG. 2, the support portion 13 is coaxial with the first cylindrical portion 15 from the end plate portion 11 as shown in FIG. 8 with the first cylindrical portion 15 projecting in the X1 direction from the end plate portion 11. And a second cylindrical portion 16 that protrudes in the X2 direction. The central hole 15 a of the first cylindrical portion 15 and the central hole 16 a of the second cylindrical portion 16 communicate with each other through a through hole 11 b provided in the end plate portion 11. The central hole 15 a of the first cylindrical portion 15 is smaller in diameter than the central hole 16 a of the second cylindrical portion 16. As shown in FIG. 2, in the first cylindrical portion 15, a notch 17 is provided in a part in the circumferential direction in the Y1 direction (the side on which the side plate portion 12 is positioned).

  A wiring disposition groove 18 extending from the notch 17 of the first cylindrical portion 15 to the side surface 12 a of the side plate portion 12 is provided on the end surface 11 a of the end plate portion 11 facing the X1 direction. The wiring disposition groove 18 inclines in the Z1 direction from the end on the outer circumferential side of the inner circumferential groove portion 19 extending in the horizontal direction from the notch 17 (support portion 13) and the outer circumferential side groove portion 19 toward the side plate portion 12 An inclined groove portion 20 and an outer peripheral groove portion 21 extending horizontally from an outer peripheral end of the inclined groove portion 20 and reaching the side surface 12 a of the side plate portion 12 are provided. The end on the side plate portion 12 side of the outer circumferential groove portion 21 is open to the side surface 12 a.

  An opening 22 is provided at the bottom 18 a of the inclined groove portion 20. As shown in FIGS. 7 and 8, a cylindrical portion 23 protruding in the X2 direction from a portion overlapping the opening edge of the opening 22 is provided on the opposite surface 11 c of the end plate portion 11 facing the movable cover 2. There is.

  Further, as shown in FIG. 2 and FIG. 6, the end plate portion 11 has a first claw portion 25 projecting to the inside of the inner circumferential groove portion 19, and a second claw portion 26 projecting to the inside of the outer circumferential groove portion 21. And. The first claw portion 25 protrudes in the Z2 direction, and the second claw portion 26 protrudes in the Z1 direction. The first claw portion 25 and the second claw portion 26 are respectively separated from the bottom portion 18 a of the wiring disposition groove 18 in the X1 direction.

  Furthermore, as shown in FIG. 3 and FIG. 8, the end plate portion 11 includes three fan supporting shafts 31 to 33 protruding in the X2 direction, and two guide shafts 34 and 35. The three fan support shafts 31 to 33 and the two guide shafts 34 and 35 are all located on the outer peripheral side of the support portion 13. Therefore, the three fan supporting shafts 31 to 33 and the two guide shafts 34 and 35 are all located on the outer peripheral side of the drive unit 3 attached to the supporting portion 13. Further, the three fan supporting shafts 31 to 33 and the two guide shafts 34 and 35 are provided at positions closer to the support portion 13 than the mounting portion 14.

  The three fan supporting shafts 31 to 33 are provided at positions surrounding the supporting portion 13 at equal angular intervals. As shown by a dotted line in FIG. 5A, a centrifugal fan F may be attached to the tip end portions of the fan support shafts 31 to 33. That is, when the cold air is blown into the refrigerator, the centrifugal fan F may be disposed at a position facing the opening O outside the cold air flow path. In this case, the centrifugal fan F is connected to the tip end portions of the fan support shafts 31 to 33 to blow cold air from the opening O toward the damper device 1 side. The centrifugal fan F is disposed at a position facing the opening O while being supported by the support 4. In addition, if the centrifugal fan F is supported by the plurality of fan supporting shafts 31 to 33 provided so as to surround the support portion 13, the centrifugal fan F can be reliably supported by the support 4.

  The two guide shafts 34 and 35 are provided on the outer peripheral side of the three fan supporting shafts 31 to 33. The two guide shafts 34, 35 are a part of the configuration of the guide mechanism 30 for guiding the movable cover 2 in the X direction. One of the two guide shafts 34 and 35 protrudes from the end plate portion 11 in the Z1 direction from the Y1 direction in the X1 direction. The other guide shaft 35 protrudes in the X2 direction from the portion on the Z2 direction side in the Y2 direction of the end plate portion 11.

  Moreover, the end plate part 11 equips the opposing surface 11c with three buffer members 37-39, as shown to FIG. 7, FIG. The three buffer members 37 to 39 are disposed on the inner peripheral side of the guide shafts 34 and 35. Further, the three buffer members 37 to 39 are disposed between the three fan supporting shafts 31 to 33 and the supporting portion 13. The buffer members 37 to 39 are disposed at positions at which the support portion 13 is surrounded at equal angular intervals. The buffer members 37 to 39 have a rectangular parallelepiped shape, and the longitudinal direction thereof is in the circumferential direction of the support portion 13. The buffer members 37 to 39 are elastic members and porous members. As the buffer members 37 to 39, foamed polyurethane, rubber, sponge or the like can be used. The material of the buffer members 37 to 39 is selected according to the use environment.

  Furthermore, the end plate portion 11 is an outer peripheral side of the support portion 13 and a region closer to the support portion 13 than the fan support shafts 31 to 33 (between the support portion 13 and the three fan support shafts 31 to 33 Region) is provided with three through holes 40-42. As shown in FIGS. 1 and 2, the through holes 40 to 42 are provided at positions closer to the support portion 13 than the fan support shafts 31 to 33. In the present example, the through holes 40 to 42 are provided between the buffer members 37 to 39 and the support portion 13. Each through hole 40 to 42 penetrates the end plate portion 11 in the X direction.

The three through holes 40 to 42 are provided on the outer peripheral side of the support portion 13 at positions avoiding the wiring disposition groove 18 in the circumferential direction. The three through holes 40 to 42 together with the wiring disposition groove 18 surround the support portion 13 from the outer peripheral side. As shown in FIG. 2, each of the through holes 40 to 42 has an arc shape extending in the circumferential direction along the outer peripheral edge of the support portion 13 (first cylindrical portion 15). The shapes of the through holes 40 to 42 are arcs defined at the center of the support portion 13, and the radial width dimensions of the three through holes 40 to 42 are equal to one another. In the end plate portion 11, a plate portion positioned between the first through hole 40 and the wiring disposition groove 18 in the circumferential direction of the support portion 13, and a plate portion positioned between the first through hole 40 and the second through hole 41 The plate portion positioned between the second through hole 41 and the third through hole 42, and the plate portion positioned between the third through hole 42 and the wiring disposition groove 18 respectively include the support portion 13 and each of them. Connecting ribs 11e-11 connecting the plate portion of the end plate portion 11 positioned on the outer peripheral side of the through holes 40-42
It is h.

  Here, the circumferential length of the first connection rib 11 e between the wiring arrangement groove 18 and the first through hole 40 located next to the wiring arrangement groove 18 in the CW direction when viewed from the side in the X1 direction The dimension is shorter than the circumferential length dimension of the first through hole 40. The circumferential length dimension of the second connection rib 11 f located between the first through hole 40 and the second through hole 41 located next to the first through hole 40 in the CW direction is the first through hole 40. And the circumferential length dimension of the second through hole 41. The circumferential length dimension of the third connection rib 11 g located between the second through hole 41 and the third through hole 42 located next to the second through hole 41 in the CW direction is the second through hole 41. And the circumferential length dimension of the third through hole 42. The circumferential length dimension of the fourth connection rib 11 h located between the third through hole 42 and the wiring disposition groove 18 is shorter than the circumferential length dimension of the third through hole 42.

  Next, as shown in FIG. 2, the side plate portion 12 includes a wire locking portion 45, a first binding portion 46, and a second binding portion 47. The wire locking portion 45 has a protruding portion 51 protruding in the Y1 direction from the side surface 12a of the side plate portion 12, a first locking portion 52 extending in the Z1 direction from the tip end portion of the protruding portion 51 along the side surface 12a, and a protruding portion And a second locking portion 53 extending in the Z2 direction along the side surface 12a from the tip end portion of 51. The protruding portion 51 of the wiring locking portion 45 is provided at a height position overlapping the end opening 18 b of the wiring disposition groove 18 exposed to the side surface 12 a of the side plate portion 12 in the Z direction. The protruding portion 51 of the wiring locking portion 45 is at the same height position as the Z-direction central portion of the outer circumferential groove portion 21 of the wiring disposition groove 18 in the Z direction.

  In addition, the wiring locking portion 45 extends from the lower end portion of the first locking portion 52 toward the side plate portion 12 (side surface 12 a), and the side of the side plate portion 12 of the first locking portion 54. And a first inclined portion 55 extending in a direction away from the side plate portion 12 in the Z1 direction from the end of the Furthermore, the wiring locking portion 45 extends from the upper end portion of the second locking portion 53 toward the side plate portion 12 (side surface 12 a), and the side of the side plate portion 12 of the second locking portion 56. And a second inclined portion 57 extending in a direction away from the side plate portion 12 in the Z2 direction from the end of the second portion.

  The first binding portion 46 is provided in the Z1 direction of the wire locking portion 45. The second binding portion 47 is provided in the Z2 direction of the wire locking portion 45. The first binding portion 46 and the second binding portion 47 are portions which can bind the binding band 59. The first binding portion 46 and the second binding portion 47 have the same shape. When viewed from the Z direction, the first bundling portion 46 and the second bundling portion 47 are provided at positions overlapping the wire locking portion 45. Each of the first binding portion 46 and the second binding portion 47 extends from the lower side of the groove 60 in the Y1 direction in the groove 60 extending linearly in the X direction on the side surface 12 a of the side plate 12 and in the side surface 12 a of the side plate 12 The lower protrusion 61 which protrudes, the upper protrusion 62 which protrudes in the Y1 direction from the upper side of the groove 60, and the end portion on the side of the side surface 12a of the lower protrusion 61 which extends in the Z direction along the side 12a And a connecting portion 63 connecting the end portion of the side surface 12 a of the projection 62.

(Drive unit)
FIG. 9 is an exploded perspective view of the drive unit 3. As shown in FIG. 8, the drive unit 3 has a geared motor 65 and a rotating body 66 that is rotated by the drive of the geared motor 65. As shown in FIG. 9, the geared motor 65 transmits the rotation of the motor body 67 (motor), the output gear 68, and the output shaft (not shown) of the motor body 67 (rotation of the motor body 67) to the output gear 68. And a gear train 69. The motor main body 67 is a stepping motor. The motor main body 67 is disposed in a posture in which the output shaft protrudes in the X2 direction. As shown in FIG. 8, the motor main body 67 includes a power feeding unit 70 to which the wiring 5 is connected at an end portion in the X1 direction (opposite output side). The gear wheel train 69 is a reduction wheel train.

  Further, as shown in FIG. 9, the geared motor 65 includes an end plate member 71 fixed to the end face 11a on the output side of the motor main body 67, and a case 72 covered on the end plate member 71 from the X2 direction. The gear train 69 is accommodated between the end plate member 71 and the case 72. The gear wheel train 69 transmits the rotation of the output shaft of the motor body 67 to the output gear 68. The output gear 68 projects in the X2 direction from an opening 72a provided on the end surface of the case 72 in the X2 direction.

  Here, the geared motor 65 is X2 in the center hole of the support portion 13 of the support 4 (the center hole 15a of the first cylindrical portion 15, the center hole 16a of the second cylindrical portion 16 and the through hole 11b of the end plate portion 11). Inset from the side of the direction. When the geared motor 65 is fitted into the support portion 13, as shown in FIGS. 1 and 2, the end portion of the motor main body 67 in the X1 direction is inserted into the center hole 15a of the first cylindrical portion 15 from the X2 direction side. . As a result, the end portion of the motor main body 67 in the X1 direction is fitted to the first cylindrical portion 15. Further, as shown in FIG. 2, the power feeding portion 70 of the motor main body 67 is disposed at an angular position corresponding to the notch 17 of the first cylindrical portion 15. Therefore, it is easy to pull out the wiring 5 connected to the feeding portion 70 into the wiring arrangement groove 18. Further, as shown in FIG. 8, the geared motor 65 is fixed to the support portion 13 by two screws 74 penetrating the case 72 from the side in the X2 direction. In a state where the geared motor 65 is fixed to the support portion 13, the rotation center axis of the output gear 68 extends in the X direction (linear movement direction).

  As shown in FIGS. 8 and 9, the rotating body 66 has a circular bottom plate portion 75 and a cylindrical portion 76 extending from the outer peripheral edge of the bottom plate portion 75 in the X1 direction. At the center of the bottom plate portion 75, a meshing portion 77 with which the output gear 68 of the geared motor 65 meshes is provided. The meshing portion 77 includes a through hole 77a penetrating the bottom plate portion 75 in the X direction, and a spline 77b formed on the inner peripheral surface of the through hole 77a. The rotating body 66 is placed on the geared motor 65 in the X2 direction. As a result, the output gear 68 of the geared motor 65 is engaged with the meshing portion 77. Therefore, when power is supplied to the motor main body 67 to drive the geared motor 65, the rotating body 66 rotates around the axis L when the output gear 68 rotates.

  Here, the axis L of the rotating body 66 coincides with the central axis of rotation of the output gear 68. The axis L of the rotating body 66 coincides with the center of the support 13 of the support 4. Therefore, the fan supporting shafts 31 to 33 provided on the support 4 and the buffer members 37 to 39 fixed to the end plate portion 11 of the support 4 are located at equal angular intervals around the axis L.

  An annular flange portion 78 projecting outward in the radial direction from the end in the X2 direction of the cylindrical portion 76 is provided at the end in the X2 direction of the rotating body 66. As shown in FIG. 4, when the movable cover 2 is disposed at the second position 2B, the flange portion 78 abuts on the movable cover 2 and cold air leaks from between the drive unit 3 and the movable cover 2. Suppress. As shown in FIG. 9, holes for draining water 78 a are formed at two positions in the circumferential direction on the inner peripheral edge of the flange portion 78. The holes 78 a discharge water adhering to the cylindrical portion 76 due to condensation or the like and ice pieces scraped off from the cylindrical portion 76 and prevent the ice pieces from being caught between the flange portion 78 and the movable cover 2.

  On the outer peripheral surface of the cylindrical portion 76 of the rotating body 66, an engaging portion 80 formed of a helical convex portion or concave portion is formed. In the present example, the engaging portion 80 is composed of two convex portions that extend in a spiral shape. The engaging portion 80 extends from the end of the cylindrical portion 76 in the X1 direction to the flange portion 78. The end 80 a on the side of the flange portion 78 of each engaging portion 80 is adjacent to the hole 78 a of the flange portion 78 in the X1 direction. The end 80a is a contact portion at which the movable cover 2 abuts when the rotary body 66 rotates in the counterclockwise direction CCW and the movable cover 2 is disposed at the second position 2B.

(Movable cover)
The movable cover 2 is made of resin. As shown in FIG. 6, the movable cover 2 includes a cover end plate portion 83 (opposite portion) extending in parallel with the end plate portion 11 of the support 4. The cover end plate portion 83 has a generally circular end plate portion 84 and a protruding end plate portion 85 projecting in the Z1 direction from a part of the outer peripheral edge of the circular end plate portion 84 in the circumferential direction when viewed in the X direction. And. The projecting end plate portion 85 protrudes from the center of the circular end plate portion 84 in the Z1 direction from a position deviated in the Y2 direction.

  The movable cover 2 further includes a cover side plate portion 86 (side plate portion) extending in the X2 direction from the outer peripheral edge portion except the lower end edge 85a of the protruding end plate portion 85 at the outer peripheral edge of the cover end plate portion 83. In the movable cover 2, a portion where the cover side plate portion 86 is not provided is a rectangular cutout opening 87 opened in the Z1 direction. That is, the movable cover 2 is provided with a rectangular notch opening 87 opening in the Z1 direction.

  When the centrifugal fan F is disposed at a position facing the opening O outside the cold air flow path, the movable cover 2 is located at the tip of the three fan supporting shafts 31 to 33 of the support 4. When connected to the centrifugal fan F, the cover side plate portion 86 is located on the outer peripheral side of the centrifugal fan F at the second position 2B. As a result, as shown in FIG. 5 (b), the centrifugal fan F can be accommodated in the space defined by the cover end plate 83 and the cover side plate 86.

  The cover side plate portion 86 is provided with a first projecting portion 88 and a second projecting portion 89 which project outward. The first projecting portion 88 is provided on the Z1 direction side of the Y1 direction of the circular end plate portion 84. The second projecting portion 89 is provided on a portion of the circular end plate portion 84 on the Z2 direction side in the Y2 direction. The first projecting portion 88 and the second projecting portion 89 have a cylindrical shape extending in the X direction along the cover side plate portion 86. Through holes 88 a and 89 a penetrating in the X direction are formed in the first projecting portion 88 and the second projecting portion 89, respectively.

  At the center of the circular end plate portion 84, there is provided a rotating body arranging portion 91 for arranging a portion (cylindrical portion 76) in which the engaging portion 80 of the rotating body 66 of the drive unit 3 is formed. As shown in FIG. 6, the rotating body placement portion 91 has a disk portion 92 protruding toward the support 4 from the facing surface 83 a facing the support 4 at the cover end plate portion 83, a disk portion 92 and a circular end plate And a rotary body arrangement hole 93 penetrating the portion 84. An engaged portion 95 which engages with the engaging portion 80 to configure the engaging portion 80 and the feed screw mechanism 94 is formed on the inner peripheral surface of the rotary body disposition hole 93. The engaged portion 95 is a spirally extending groove. The engaging portion 80 is fitted inside the engaged portion 95. In this embodiment, when forming the groove (engaged portion 95), a portion in the circumferential direction of the inner peripheral surface of the rotary body disposition hole 93 is a protruding portion 96 protruding inward in the radial direction. The groove (engaged portion 95) is provided in the Here, the engaged portions 95 are formed at two places in the circumferential direction. Further, the cover end plate portion 83 is provided with an opening 97 on the Y1 direction side of the rotating body disposition portion 91. The cylindrical portion 23 of the support 4 is inserted into the opening 97.

  Furthermore, the cover end plate portion 83 includes three through holes 101 to 103 penetrating in the X direction, and two guide holes 104 and 105. The three through holes 101 to 103 are formed inside the cover side plate portion 86. The through holes 101 to 103 are provided at positions that surround the rotating body disposition holes 93 at equal angular intervals. In other words, the through holes 101 to 103 are provided at equal angular intervals around the axis L. In the three through holes 101 to 103, three fan supporting shafts 31 to 33 provided at positions at which the support 13 is surrounded at equal angular intervals in the support 4 are inserted from the side in the X1 direction.

As shown in FIG. 3, the two guide holes 104 and 105 together with the two guide shafts 34 and 35 provided in the support 4 constitute a guide mechanism 30 for guiding the movable cover 2 in the X direction. The two guide holes 104 and 105 are through holes 89 a and 89 a of a first protrusion 88 and a second protrusion 89 formed on the outer peripheral side of the cover side plate 86. The guide shaft 34 provided in the Z1 direction of the end plate 11 of the support 4 in the Z1 direction is inserted into the through hole 88a of the first protrusion 88 from the X1 direction. . The guide shaft 35 provided in the Z2 direction side of the end plate 11 opposite to the cover side plate 86 is inserted into the through hole 89a of the second protrusion 89 from the X1 direction.

  Furthermore, as shown in FIG. 7, the cover end plate portion 83 is formed with a cylindrical rib 24 which protrudes in the X2 direction from around the rotating body disposition hole 93. The cylindrical rib 24 is formed so as to surround the rotating body disposition hole 93. The tip (end in the X1 direction) of the cylindrical rib 24 abuts on the flange portion 78 of the drive unit 3 when the movable cover 2 is disposed at the second position 2B, and between the drive unit 3 and the movable cover 2 Control cold air leakage from

  Further, as shown in FIG. 6, on the opposing surface 83a of the cover end plate 83, three circular recesses 107 to 109 respectively surrounding the three through holes 101 to 103 located inside the cover side plate 86 are provided. ing. Each of the three through holes 101 to 103 opens at the center of the circular bottom of each of the circular recesses 107 to 109. Further, on the facing surface 83 a of the cover end plate portion 83, convex portions 111 to 113 are respectively provided between the three through holes 101 to 103 and the rotary body disposition hole 93.

  Each of the three convex portions 111 to 113 is provided at a position overlapping with both the outer peripheral edge of each of the circular recesses 107 to 109 and the opening edge of each of the circular recesses 107 to 109 in the facing surface 83 a. Moreover, each of the three convex parts 111-113 is provided on the straight line which connected the axis line L and the center of three through-holes 101-103. Each of the convex portions 111 to 113 has a rectangular planar shape when viewed from the X direction, and is provided at a position surrounding the rotating body disposition holes 93 at equal angular intervals. Each of the convex portions 111 to 113 has its longitudinal direction directed in the circumferential direction of the rotary body disposition hole 93. The tip end surfaces of the convex portions 111 to 113 project in the X1 direction more than the disk portion 92, and are located on the side of the movable cover 2 most in the X1 direction.

  Each of the convex portions 111 to 113 is opposed to the buffer members 37 to 39 provided on the opposing surface 11 c of the support 4. That is, the three buffer members 37 to 39 provided on the facing surface 11c of the support 4 overlap the respective three convex portions 111 to 113 when viewed from the X direction. Here, the rotating body disposition hole 93 is disposed coaxially with the support portion 13 of the support 4. The axis L of the rotating body 66 passes the center of the rotating body disposition hole 93 in the X direction. Furthermore, each of the three convex portions 111 to 113 is provided on a straight line connecting the axis L and the centers of the three through holes 101 to 103 formed at equal angular intervals around the axis L. Therefore, when viewed from the X direction (linear movement direction), each of the convex portions 111 to 113 is located on the outer peripheral side of the support 13 of the support 4 and surrounds the support 13 of the support 4 at equal angular intervals. It is provided in the position.

(wiring)
As shown in FIGS. 1 and 2, the wiring 5 is drawn out from the feeding portion 70 of the motor main body 67 of the drive unit 3 fixed to the support portion 13 into the wiring disposition groove 18 via the notch 17. At this time, in the wiring disposition groove 18, the wiring 5 is disposed between the first claw portion 25 and the bottom portion 18 a of the wiring disposition groove 18 and between the second claw portion 26 and the bottom portion 18 a of the wiring disposition groove 18. Leading to the end opening 18b. Thereafter, the wiring 5 is bent along the side surface 12 a of the side plate portion 12 from the end on the side plate portion 12 side of the wiring disposition groove 18, and is locked to the wiring locking portion 45.

  In the wire locking portion 45, the wire 5 is drawn between the first locking portion 52 and the side plate portion 12 (side surface 12a) from the end plate portion 11 (end surface 11a) side, Between the 2nd latching | locking part 53 and the side plate part 12 (side surface 12a) is drawn around via the opposite side (side of X2 direction) with the end plate part 11. As shown in FIG. Thereafter, the wire 5 is pulled out from the wire locking portion 45 in the Z2 direction.

The wiring 5 drawn from the wiring locking portion 45 in the Z2 direction is further drawn in the Z2 direction along the side surface 12a after passing through the end plate side (X1 direction) of the second retaining portion 56. Then, it extends on the end plate side (the X1 direction) side of the second binding portion 47 and is bound to the second binding portion 47 by the binding band 59. That is, the wire 5 is fixed to the second binding portion 47 by the binding band 59 which is inserted into the groove 60 and wound around the connecting portion 63 between the lower protrusion 61 and the upper protrusion 62.

(Channel adjustment operation)
When electric power is supplied to the motor main body 67 via the wiring 5 to drive the drive unit 3, the rotation of the rotating body 66 is transmitted to the movable cover 2 via the feed screw mechanism 94. Here, the guide mechanism 30 for guiding the movable cover 2 in the X direction (linear movement direction) prevents the movable cover 2 from rotating together with the rotating body 66. Therefore, when the rotating body 66 rotates, the movable cover 2 moves in the X1 direction and the X2 direction along the axis L.

  As shown in FIG. 3, when the rotating body 66 rotates in the clockwise direction CW around the axis L, the movable cover 2 moves in the X1 direction of the axis L direction. Thereby, as shown to Fig.5 (a), the movable cover 2 is arrange | positioned in the 1st position 2A spaced apart from the opening part O. As shown in FIG. In the state where the movable cover 2 is disposed at the first position 2A, the opening O is released. Therefore, cold air is supplied from the space between the cold air flow path and the damper device 1 to the inside of the refrigerator as indicated by an arrow C in FIG. 3 and FIG. 5 (a). Here, when the movable cover 2 is disposed at the first position 2A, the convex portions 111 to 113 provided on the movable cover 2 abut the buffer members 37 to 39 provided on the support 4. In addition, when the movable cover 2 is disposed at the first position 2A, the buffer members 37 to 39 are in a state in which the convex portions 111 to 113 are in contact and elastically deformed. Therefore, when the movable cover 2 is disposed at the first position 2A, no collision noise is generated.

  Next, when the rotating body 66 rotates in the counterclockwise direction CCW around the axis L, the movable cover 2 moves in the X2 direction of the axis L as shown in FIG. 4. Thus, as shown in FIG. 5B, the movable cover 2 is disposed at the second position 2B close to the opening O. In a state where the movable cover 2 is disposed at the second position 2B, the cover end plate 83 of the movable cover 2 is in the X1 direction on the flange 78 formed on the rotary body 66 of the drive unit 3 via the cylindrical rib 24. Approach from the side of As a result, leakage of cold air from between the drive unit 3 and the movable cover 2 is suppressed. Further, in a state where the movable cover 2 is disposed at the second position 2B, the movable cover 2 partially covers the opening edge of the opening O of the cold air flow path. Furthermore, in a state where the movable cover 2 is disposed at the second position 2B, when the centrifugal fan F is fixed to the tip end portion of the fan supporting shafts 31 to 33, the cover side plate portion 86 of the movable cover 2 The centrifugal fan F is covered from the outer peripheral side. Therefore, the cold air supplied from the opening O of the cold air flow path is supplied to the inside of the refrigerator via the cutout opening 87 of the movable cover 2 as shown by the arrow D in FIG. 4 and FIG. 5 (b). Be done. Therefore, in the state where the movable cover 2 is disposed at the second position 2B, cold air having a smaller flow rate is supplied into the refrigerator as compared to the case where the movable cover 2 is at the first position 2A. Damper device 1 may arrange movable cover 2 in the middle position between the 1st position 2A and the 2nd position 2B, and may adjust the flow of cold air which goes through opening O.

Here, in this example, as shown in FIG. 1 and FIG. 2, through holes 40 to 42 are provided on the outer peripheral side of the support portion 13 that supports the drive unit 3 in the support 4. Therefore, even when the vibration of the motor main body 67 which is the drive source of the drive unit 3 is transmitted to the support 4 through the support portion 13 when operating the damper device 1, the propagation of the vibration can be 42 can block or suppress. That is, even when the vibration of the motor main body 67 which is the drive source of the drive unit 3 is transmitted to the support 4 via the support portion 13, the vibration is generated between the through holes 40 to 42 and the wiring disposition groove 18. As it propagates through the thin first connection rib 11e, the second connection rib 11f, the third connection rib 11g, and the fourth connection rib 11h, it attenuates. In particular, in the present embodiment, the motor main body 67 is a stepping motor, and periodic vibration occurs at the time of driving.
This vibration is easily transmitted to the side of the support 4. However, the propagation of the vibration can be blocked or suppressed by the through holes 40 to 42 provided in the support 4. Therefore, the vibration of the motor main body 67 is amplified by the support 4, and the vibration noise can be prevented or suppressed from becoming large.

  Further, since the three through holes 40 to 42 are provided in the region between the support portion 13 of the drive unit 3 and the three fan supporting shafts 31 to 33, the tips of the fan supporting shafts 31 to 33 are When the centrifugal fan F is fixed to a part, the vibration of the motor main body 67 and the vibration transmitted from the centrifugal fan F to the support 4 through the fan support shafts 31 to 33 overlap with each other, and the vibration is generated. It can be prevented or suppressed that the sound is loud.

  Furthermore, in the present embodiment, the mounting portion 14 for fixing the damper device 1 (support 4) to an external device is located on the outer peripheral side of the three through holes 40 to 42 and the three fan supporting shafts 31 to 33. Being located, even when the vibration of the motor main body 67 which is a drive source of the drive unit 3 is transmitted to the support 4 via the support portion 13, the vibration is on the outer peripheral side than the fan support shafts 31 to 33. It is possible to suppress propagation to the mounting portion 14 located at

  Further, since the three through holes 40 to 42 are provided at positions closer to the support portion 13 than the three fan support shafts 31 to 33, propagation of vibration of the motor main body 67 at a position near the support portion 13 Can be blocked or suppressed. Furthermore, since each of the through holes 40 to 42 has an arc shape extending in the circumferential direction along the outer periphery of the support portion 13, the propagation of vibration can be efficiently suppressed even with a small opening area. That is, if each through hole 40 to 42 has a circular arc shape extending in the circumferential direction, even with a small opening area, the support portion 13 and the plate portion of the end plate portion 11 positioned on the outer peripheral side than each through hole 40 to 42 Can be made thin (small). Here, if the connection ribs 11e to 11h are thin, it is easy to damp the vibration propagating from the support portion 13 by the connection ribs 11e to 11h. Therefore, propagation of the vibration of the motor main body 67 can be easily suppressed by the through holes 40 to 42.

  Further, in the present example, since the three through holes 40 to 42 are provided, it is possible to increase the total opening area of the through holes 40 to 42 as compared with the case where one through hole 40 to 42 is provided. it can. Thereby, the area of the part (connection rib 11e-11h) which propagates the vibration from the support part 13 to the outer peripheral side in the end plate part 11 can be made small. Therefore, it is easy to suppress the propagation of the vibration of the motor main body 67.

  Furthermore, in the present embodiment, since the drive unit 3 includes the gear train 69 that transmits the rotation of the motor main body 67 to the rotating body 66, vibration occurs when the gear train 69 is driven, and the side of the support 4 is generated. However, the transmission of the vibration can be blocked or suppressed by the through holes 40 to 42 provided in the support 4.

(Modification)
Here, the opening shape of the through holes 40 to 42 is not limited to the arc shape. FIG. 10 is a plan view of a damper device of a modification in which the shapes of the through holes 40 to 42 are changed, as viewed from the X1 direction side. As shown in FIG. 10, in the damper device 150 of this example, a plurality of circular holes 151 are formed as through holes in a region adjacent to the support 13 on the outer peripheral side of the support 13 in the end plate 11 of the support 4. Is provided. Also in this case, it is possible to reduce the area of a portion of the end plate portion 11 which propagates the vibration from the support portion 13 to the outer peripheral side. Therefore, the same function and effect as the above example can be obtained.

  The number of through holes provided in the end plate portion 11 of the support 4 may be one, and if the through holes are provided, propagation of vibration transmitted from the drive unit 3 to the end plate portion 11 through the support portion 13 is It can be suppressed.

  Here, as the guide mechanism 30, the guide shafts 34 and 35 can be provided on the movable cover 2 side, and the guide holes 104 and 105 can be formed on the support 4 side.

  Further, on the outer peripheral surface of the cylindrical portion 76 of the rotary body 66 of the drive unit 3, a spiral recess is provided as the engaging portion 80, and on the inner peripheral surface of the rotary body arrangement hole 93 of the movable cover 2, It is also possible to provide a convex portion which engages with the engaging portion 80 and the feed screw mechanism 94.

  Furthermore, in the above-mentioned example, although the notch opening 87 is provided in the cover side plate portion 86 of the movable cover 2, the cover side plate portion 86 is the cover end plate portion 83 without providing such a notch opening 87. It may extend in the X2 direction from the entire circumference of the outer peripheral edge. In this case, when the movable cover 2 is disposed at the second position 2B, the opening O can be covered by the movable cover 2. Therefore, when the movable cover 2 is disposed at the second position 2B, the flow rate (first flow rate) of the cold air passing through the opening O can be made zero.

  In the above example, although the present example is applied to the damper device 1 attached to the fluid passage through which the cold air (fluid) flows, the damper device 1 provided to the fluid passage through which various fluids (liquid or gas) other than the cold air flow This example may be applied.

1 · 150 · · · Damper device, 1 A · · · · installation attitude of the damper device, 2 ... movable cover, 2 A ... first position of the movable cover, 2 B ... second position of the movable cover, 3 ... drive unit, 4 ... support, 5 ... Wiring 11 end plate portion 11a end face of end plate portion 11b through hole of end plate portion 11c opposite surface of end plate portion 11e first connection rib 11f second connection rib 11g Third connection rib, 11h: fourth connection rib, 12: side plate portion, 12a: side surface, 13: support portion, 14: attachment portion, 15: first cylindrical portion, 15a: central hole, 16: second cylindrical portion, 16a: central hole, 18: wiring arrangement groove, 18a: bottom portion, 18b: end opening, 19: inner peripheral groove portion, 20: inclined groove portion, 21: outer peripheral groove portion, 22: opening portion, 23: cylindrical portion, 24: cylindrical rib 25: first claw portion 26: second claw portion 30: guide mechanism 31 to 33 Fan support shaft 34 · 35 · · · Guide guide shaft, 37 ~ 39 · · · Buffering member, 40 · · · first through hole, 41 · · · second through hole, 42 · · · third through hole 1 banding part 47: second banding part 51: projecting part 52: first locking part 53: second locking part 54: first retaining part 55: first inclined part 56: fifth 2 Retaining portion 57 57 second inclined portion 59 banding band 60 groove 61 lower projection 62 upper projection 63 connecting portion 65 geared motor 66 rotating body 67 ... Motor body (motor), 68 ... Output gear, 69 ... Gear train, 70 ... Power feeding section, 71 ... End plate member, 72 ... Case, 72 a ... Opening, 74 ... Screw, 75 ... Bottom plate, 76 ... Cylindrical Parts, 77b: Spline, 77: Meshing part, 78: Flange part, 78a: Water drainage hole, 80: Engagement 80a: end portion 83: cover end plate portion (facing portion) 83a: facing surface 84: circular end plate portion 85: projecting end plate portion 85a: lower end edge 86: cover side plate portion (side plate portion) 87: Notched opening 88: First projecting portion 89: Second projecting portion 91: Rotating body disposition portion 92: Disk portion 93: Rotating body disposition hole 94: Screw mechanism 95: Engaged Parts, 96: overhang parts, 97: openings, 101 to 103: through holes in the movable cover, 104, 105: guide holes, 107: circular recesses, 111 to 113: protrusions, 151: circular holes, F: centrifugal Fan, L: Axis, O: Opening

Claims (10)

A movable cover for adjusting the flow rate of gas passing through the opening;
The movable cover, a first position where the flow rate is the first flow rate, and a second position where the flow rate is closer to the opening than the first position and the flow rate is the second flow rate smaller than the first flow rate; , And a drive unit that linearly moves between
A support comprising a support for supporting the drive unit;
The drive unit comprises a motor as a drive source,
The support body projects a linear movement direction of the movable cover in a closing direction from the first position toward the second position on an outer peripheral side of the support portion, and a fan supporting shaft on which a fan is fixed at a tip portion Equipped
A damper device characterized in that a through hole is provided in an area on the outer periphery side of the support portion in the support body and closer to the support portion than the fan supporting shaft.   The damper device according to claim 1, wherein the through hole is provided at a position closer to the support portion than the fan support shaft.   The damper device according to claim 1, wherein the through hole has an arc shape extending in a circumferential direction along an outer periphery of the support portion.   The damper device according to any one of claims 1 to 3, further comprising a plurality of the through holes provided around the support portion as the through holes.   The damper device according to any one of claims 1 to 4, further comprising a plurality of fan supporting shafts provided around the supporting portion as the fan supporting shaft. The support comprises an attachment for securing the support to an external device,
The damper device according to claim 5, wherein the attachment portion is provided on an outer peripheral side of the plurality of fan supporting shafts surrounding the support portion. The drive unit includes a rotating body driven by the motor and rotated about an axis extending in the linear movement direction.
The rotating body is provided with an engaging portion having a helical convex portion or a concave portion on an outer peripheral surface,
The movable cover is engaged with the engaging portion at an inner peripheral surface of the rotating body arranging hole and a rotating body arranging hole in which a portion where the engaging portion of the rotating body is formed is disposed inside The damper device according to any one of claims 1 to 6, further comprising: an engaged portion that constitutes the engaging portion and the feed screw mechanism.   The damper device according to claim 7, wherein the drive unit includes a gear train that transmits the rotation of the motor to the rotating body. The movable cover protrudes from the outer peripheral edge of the opposing portion facing the support in the linear movement direction from the outer peripheral edge of the opposing portion in the closing direction, and the outer peripheral side of the fan fixed to the fan support shaft at the second position. A side plate portion located on the
The damper device according to any one of claims 1 to 8, wherein the fan support shaft penetrates the facing portion.   The damper device according to any one of claims 1 to 9, wherein the motor is a stepping motor.

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