JP6660799B2 - Damper plate - Google Patents

Description

  The present invention relates to a damper plate that opens and closes an air passage of a retainer forming a register.

  2. Description of the Related Art Conventionally, a register is provided on an instrument panel of a vehicle such as an automobile, and is configured to blow air conditioned from the register toward a vehicle cabin. A damper plate is rotatably disposed inside the retainer that constitutes the register, and is configured to control the blowing of the conditioned air and the stop thereof.

  As a technique relating to such a damper plate, a technique described in Patent Document 1 is known. The air damper described in Patent Literature 1 includes a plate portion pivotally supported on left and right side walls of a retainer main body, and a damper seal provided around the plate portion. In such a register, the air damper blows out and stops the conditioned air by rotating the air damper inside the retainer main body using a damper opening / closing mechanism.

  More specifically, when the blowing of the conditioned air is stopped, the damper seal is elastically brought into close contact with the upper inner wall and the lower inner wall of the retainer body by rotating the air damper. Thus, the ventilation path inside the retainer main body can be closed by the air damper, so that the air is not blown out from the air outlet of the register. On the other hand, when the air-conditioning air is allowed to be blown, a gap is provided between the damper seal and the upper inner wall and the lower inner wall of the retainer body by rotating the air damper. This allows the conditioned air to flow down the ventilation passage inside the retainer body without being obstructed by the air damper, so that the conditioned air can be blown out from the air outlet of the register.

Utility Model Registration Publication No. 2570855

  In a register using a damper plate such as an air damper described in Patent Literature 1, abnormal noise may occur in various situations, and it is desired to reduce abnormal noise generated from the register due to the damper plate. I have.

  For example, in a state in which the damper plate is rotated so that the ventilation passage inside the retainer is substantially fully opened, the damper plate assumes a posture along the flow direction of the conditioned air (the blowing direction). In such a case, out of the edges of the damper plate, the edge located on the upstream side in the downflow direction may cut off the flow of the conditioned air to be blown, thereby generating abnormal noise (wind noise). is there. The abnormal noise thus generated may increase due to resonance with the reflected sound reflected on the inner wall surface of the retainer or the like.

  Further, in such a register, abnormal noise may be generated even when the blowing of the conditioned air is restarted from the stopped state by the damper plate. When restarting the air supply of the conditioned air, it is necessary to rotate the damper plate in reverse using the damper opening / closing mechanism to release the elastic close contact of the damper seal with the upper inner wall and the lower inner wall of the retainer main body. At this time, the damper seal returns from the state in which it is elastically adhered to the upper wall and the lower wall of the retainer main body to the original state where it is not elastically deformed. There is.

  The present invention has been made in order to solve the above-described problems, and relates to a damper plate that opens and closes a ventilation path of a retainer that constitutes a register, and a damper that can reduce abnormal noise generated from the register due to the damper plate. Provide a plate.

In order to achieve the above object, the damper plate according to claim 1 constitutes a register, and in a retainer having an air passage for guiding air to an air outlet of the register inside, a pair of the air passages forming the air passage. A damper plate that is rotatably disposed between opposing side walls and opens and closes the ventilation path, wherein the damper plate has a rotation shaft portion on both sides corresponding to the pair of side walls. A plate member formed into a flat plate shape including the rotation shaft portion, and a soft seal member formed around the plate member excluding the rotation shaft portion and elastically contacting an inner peripheral wall forming an air passage of the retainer. When the formed along a soft sealing member to the outer peripheral edge of the damper plate, have a, a projection projecting in a direction perpendicular to said plate member, said flexible sealing member At the tip of the peripheral portion, an inclined portion is provided, and the inclined portion is formed by a pair of inclined portions formed from the apex, which is the tip of the soft seal member, toward each surface of the flat plate member. an inclined surface, the damper plate is one of a pair of the inclined surface, a peripheral wall in an elastically contact inner forming an air passage of said retainer, to close the air passage, characterized in that.

A damper plate according to a second aspect is the damper plate according to the first aspect, wherein the soft seal member is provided on the plate member side from the position of the inclined portion and is formed continuously with the inclined surface. Wherein the protrusion is provided on the flat portion .

  The damper plate according to claim 3 is the damper plate according to claim 1 or 2, wherein the amount of protrusion of the protrusion with respect to the plate member is such that the ventilation path is opened by the damper plate. , The protruding portion located on the upstream side in the downflow direction is larger than the protruding portion located on the downstream side in the downflow direction of the air flowing through the ventilation path.

  The damper plate according to claim 4 is the damper plate according to any one of claims 1 to 3, wherein the damper plate closes an air passage of a retainer with the damper plate. At the edge of the soft seal member elastically contacting the inner peripheral wall in the ventilation passage, at a position closer to the rotation shaft than the protrusion, in a direction perpendicular to the plate member from one surface side of the damper plate. It has a concave portion formed so as to be depressed.

The damper plate according to claim 1 is rotatably disposed between a pair of opposed side walls forming a ventilation passage inside the retainer forming the register, and sends air to an air outlet of the register. The ventilation path to be guided is opened and closed. The damper plate has a plate member, a soft seal member, and a protrusion. When the ventilation path is closed by the damper plate, the soft sealing member constituting the damper plate can be brought into elastic contact with the inner peripheral wall forming the ventilation path of the retainer. The blowing of the conditioned air through the outlet can be more reliably stopped. In the damper plate, the protruding portion is formed along the outer peripheral edge of the damper plate by the soft seal member and protrudes in a direction perpendicular to the plate member, so that the ventilation path is opened. In the rotated state, it is possible to suppress generation of an abnormal noise (wind noise) caused by the damper plate and increase of the noise level due to resonance of the abnormal noise.
Further, an inclined portion having a pair of inclined surfaces formed to be inclined from the tip (apex) of the soft seal member is provided at the tip of the outer peripheral portion of the soft seal member. The damper plate makes one of the pair of inclined surfaces elastically contact the inner peripheral wall of the retainer, and closes the ventilation path. The damper plate can make wall elastic contact with the inner peripheral wall of the retainer only by the inclined surface. Thereby, according to the damper plate, the contact area of the soft seal member with respect to the inner peripheral wall of the retainer can be reduced, so that abnormal noise when the soft seal member elastically contacts the inner peripheral wall of the retainer can be reduced.

Further, in the damper plate according to claim 2, the soft seal member has a flat portion provided on the plate member side from the position of the inclined portion and formed continuously with the inclined surface, and the projecting portion is , Provided on the plane portion. Therefore, according to the damper plate, the protruding portion is provided on the flat portion adjacent to the inclined surface elastically contacting the inner peripheral wall. Thereby, in the state where the damper plate is slightly opened from the closed state (the state where the inclined surface is slightly separated from the inner peripheral wall), the distance between the flat portion and the inner peripheral wall, that is, the distance between the protruding portion and the inner peripheral wall. Can be shortened. In other words, when the damper plate is slightly opened and air passes through the gap to generate abnormal noise, the projecting portion can be arranged closer to the inner peripheral wall, and the projecting portion can be protruded by the air passing through the gap. Thus, the flow of air can be disturbed by the projecting portions, and generation of abnormal noise (such as wind noise) can be effectively suppressed.

  In the damper plate according to the third aspect, the amount of protrusion of the protruding portion with respect to the plate member is located on the downstream side in the downflow direction of the air flowing through the ventilation path when the ventilation path is opened by the damper plate. The protruding portion located on the upstream side in the downflow direction is formed larger than the protruding portion. Therefore, according to the damper plate, it is possible to more efficiently suppress the generation of abnormal noise (wind noise) caused by the damper plate and reduce the noise level due to the resonance of the abnormal noise.

  According to the damper plate of the fourth aspect, when the air passage of the retainer is closed by the damper plate, a concave portion is provided at an edge of the soft seal member that elastically contacts an inner peripheral wall of the air passage. The concave portion is formed so as to be depressed in a direction perpendicular to the plate member from one surface side of the damper plate at a position closer to the rotation shaft portion than the projecting portion. Therefore, according to the damper plate, the soft seal member can be returned from the state in which it is in elastic contact with the inner peripheral surface of the retainer to the original state, with the concave portion formed in the soft seal member as the center. Thus, the elastic force acting upon the elastic return can be suppressed. Thus, according to the damper plate, the generation of the abnormal noise due to the elastic return of the soft seal member can be suppressed by the concave portion formed in the soft seal member.

It is a back perspective view (1) of the register concerning this embodiment. It is a back perspective view (2) of the register concerning this embodiment. It is a side view of the register concerning this embodiment. It is a horizontal sectional view of a register concerning this embodiment. It is a perspective view showing the 1st surface side of the damper plate concerning this embodiment. It is a perspective view showing the 2nd surface side of the damper plate concerning this embodiment. It is a perspective view showing the 1st surface side of the plate member in a damper plate. It is a perspective view which shows the 2nd surface side of the plate member in a damper plate. It is a perspective view showing the 1st surface side of the soft seal member in a damper plate. It is a perspective view which shows the 2nd surface side of the soft seal member in a damper plate. It is an enlarged view showing the composition of the 1st seal part in a damper plate. It is an enlarged view showing the composition of the 2nd seal part in a damper plate. It is sectional drawing of the register which shows the state which opened the ventilation path of the retainer. It is sectional drawing which shows the structure of the 1st seal part in a damper plate. It is sectional drawing which shows the structure of the 2nd seal part in a damper plate. It is explanatory drawing regarding generation | occurrence | production of the wind noise in the register of the state where the ventilation path was opened. It is a graph which shows the influence which the presence or absence of a protrusion in a 1st seal part has on wind noise. It is sectional drawing of the register which shows the state which closed the ventilation path of the retainer. It is an expanded sectional view showing the 1st seal part in the state where the ventilation path was closed. It is an expanded sectional view showing the 2nd seal part in the state where the ventilation path was closed. It is an expanded sectional view about operation of the 1st seal part at the time of opening a ventilation path from the closed state. It is an expanded sectional view about operation of the 2nd seal part when opening a ventilation path from the state where it closed up.

  Hereinafter, a damper plate according to the present invention will be described based on embodiments embodying the present invention with reference to the drawings.

(Schematic configuration of register)
First, a schematic configuration of a register using the damper plate according to the present embodiment will be described in detail with reference to FIGS.
In the following description, the downstream side (ie, the passenger compartment side) of the register 1 in the blowing direction will be referred to as the front side, and the upstream side (ie, the air conditioner side) in the blowing direction will be referred to as the rear side. The vertical direction and the horizontal direction are defined with reference to the register 1 (see FIG. 1 and the like).

  As shown in FIGS. 1 to 4, the register 1 includes a retainer 5 and a damper plate 20, and is configured to blow conditioned air adjusted by an air conditioner into a vehicle interior. . In the register 1, the damper plate 20 is rotatably disposed, and by rotating the damper plate 20, the flow rate of the conditioned air blown into the vehicle compartment can be adjusted. it can.

  The retainer 5 is formed in a substantially rectangular cylindrical shape, and the inside thereof constitutes the ventilation passage 10. Since the rear end of the retainer 5 is connected to an air conditioner (not shown) through the ventilation passage 10, the register 1 is provided with the ventilation passage 10 and the air blower that constitutes the front end of the ventilation passage 10. Via the outlet 12, conditioned air conditioned by the air conditioner can be blown out. The retainer 5 includes a left side wall 6 that forms the left side of the ventilation path 10, a right side wall 7 that forms the right side of the ventilation path 10, an upper side wall 8 that forms the upper surface of the ventilation path 10, and a ventilation path 10. And a lower side wall 9 which constitutes a lower surface of the lower side.

  A left shaft hole 6A is formed in the left side wall 6, and a right shaft hole 7A is formed in the right wall 7. The left shaft hole 6A and the right shaft hole 7A face each other via the ventilation passage 10, and rotatably support a damper plate 20, which will be described later.

  An opening / closing operation unit 15 is provided on the front side wall 11 that forms the left front side of the retainer 5. The opening / closing operation section 15 includes a knob member 16, a link member 17, and a shaft-side connecting member 18, and is used for rotating the damper plate 20. The knob member 16 has an arc-shaped operation knob portion and a first connecting portion 16 </ b> A, and is rotatably supported by a shaft portion 13 formed on the front side wall 11. The first connecting portion 16A is formed on the knob member 16 on the opposite side of the operation knob portion, and one end of a link member 17 is connected to the first connecting portion 16A.

  The shaft-side connecting member 18 is attached to the left rotation shaft portion 32 of the damper plate 20 via the left shaft hole 6A of the left wall 6, and is disposed rotatably around the left shaft hole 6A. I have. A second connecting portion 18A is formed integrally with the shaft-side connecting member 18, and the other end of the link member 17 is connected to the second connecting portion 18A. Therefore, according to the opening / closing operation portion 15, by rotating the knob member 16, the shaft-side connecting member 18 can be rotated around the left shaft hole 6A via the link member 17, and The ventilation passage 10 can be opened and closed by the damper plate 20.

  The damper plate 20 is basically formed in a substantially rectangular flat plate member 30 rotatably disposed in the ventilation passage 10, and formed around the plate member 30. And a soft seal member 40 elastically contacting the inner peripheral wall. The configuration of the damper plate 20 will be described later in detail with reference to the drawings.

(Schematic configuration of damper plate)
Next, a schematic configuration of the damper plate 20 according to the present embodiment will be described in detail with reference to FIGS. In the following description, the upper surface of the damper plate 20 in a state where the ventilation passage 10 is opened is referred to as a “first surface”, and the back surface thereof (that is, the lower surface of the damper plate 20 in the above case) is referred to as a “first surface”. Two sides. " FIG. 5 is a perspective view showing the first surface side of the damper plate according to the present embodiment, and FIG. 6 is a perspective view showing the second surface side of the damper plate according to the present embodiment.

  As described above, the damper plate 20 includes the plate member 30 having a substantially rectangular flat plate shape, and the soft seal member 40 elastically contacting the inner peripheral wall of the ventilation passage 10. A left rotation shaft 32 is formed on the left edge of the damper plate 20, and a right rotation shaft 33 is formed on the right edge of the damper plate 20. The damper plate 20 is rotatably supported inside the ventilation passage 10 by the cooperation of the left rotation shaft portion 32 and the right rotation shaft portion 33, the left shaft hole 6A, and the right shaft hole 7A. 10 can be opened or closed.

  The damper plate 20 is formed by two-color molding including two steps of primary molding and secondary molding. In the primary molding in the two-color molding, the plate member 30 is formed of the soft seal member 40 using a hard material (such as polypropylene). In the secondary molding after the primary molding, a soft seal member 40 is formed of a soft material (olefin-based elastomer) with respect to the plate member 30 formed by the primary molding.

  As described above, in the damper plate 20 according to the present embodiment, the soft seal member 40 is formed by two-color molding in which the plate member 30 is first molded from a hard material and then the plate member 30 is secondarily molded with a soft material. Therefore, there is no need to manually assemble the plate member 30 and the soft seal member 40, and handling becomes easy.

(Schematic configuration of plate member)
Subsequently, the plate member 30 constituting the damper plate 20 according to the present embodiment will be described in detail with reference to FIGS. FIG. 7 is a perspective view showing the first surface side of the plate member 30, and FIG. 8 is a perspective view showing the second surface side of the plate member 30.

  As shown in FIGS. 7 and 8, the plate member 30 according to the present embodiment is formed of a hard material (such as polypropylene), and includes a plate body 31, a left rotation shaft 32, and a right rotation. It has a shaft portion 33 and a seal disposing portion 34. The plate body 31 has a plate shape that forms the skeleton of the damper plate 20, and is formed in a substantially rectangular shape slightly smaller than the opening area in the ventilation passage 10.

  Further, a left-side rotating shaft portion 32 and a right-side rotating shaft portion 33 are formed at the short side edge of the plate body portion 31. The left rotation shaft portion 32 is formed so as to protrude at a central portion of the left end edge of the plate body portion 31 and is rotatably supported by a left shaft hole 6A of the left wall 6. The shaft-side connecting member 18 is attached to the left rotation shaft portion 32 via the left shaft hole 6A. Further, the right rotation shaft portion 33 is formed so as to protrude at a center portion of the right end edge of the plate body portion 31 and is rotatably supported by a right shaft hole 7A of the right wall 7.

  The seal disposing portion 34 is formed on the outer peripheral portion of the plate main body portion 31 on the second surface side except for the positions where the left rotating shaft portion 32 and the right rotating shaft portion 33 are formed. 35. The plurality of anchor holes 35 are formed at regular intervals along the outer peripheral portion of the plate main body 31 in which the seal arrangement portions 34 are formed. Each of the anchor holes 35 can fix the plate member 30 to the damper plate 20 by cooperating with each of the anchor protrusions 71 of the soft seal member 40 described later.

(Schematic configuration of soft seal member)
Next, the soft seal member 40 constituting the damper plate 20 according to the present embodiment will be described in detail with reference to FIGS. FIG. 9 is a perspective view showing the first surface side of the soft seal member 40, and FIG. 10 is a perspective view showing the second surface side of the soft seal member 40.

  As shown in FIGS. 9 and 10, the soft seal member 40 is formed of a soft material (olefin-based elastomer) into a substantially rectangular frame shape corresponding to the outer peripheral shape of the plate member 30. , A right shaft recess 42, a first seal portion 50, a second seal portion 60, an anchor portion 70, and an overlap portion 75.

  The left shaft recess 41 is formed in a central portion of the left short side of the soft seal member 40 so as to be concave in an arc shape corresponding to the left rotation shaft portion 32 of the plate member 30. When the soft seal member 40 is fixed to the plate member 30, a part of the left-side rotating shaft portion 32 is disposed inside the left-side shaft concave portion 41. A part of the outer peripheral portion of the shaft portion 32 is covered.

  The concave portion 42 for the right shaft is formed in a central portion of the right short side of the soft seal member 40 so as to be concave in an arc shape corresponding to the right rotating shaft portion 33 of the plate member 30. When the soft seal member 40 is fixed to the plate member 30, a part of the right rotation shaft 33 is disposed inside the right shaft recess 42, so that the right shaft recess 42 is rotated right. Part of the outer peripheral portion of the shaft portion 33 is covered.

  A first seal portion 50 and a second seal portion 60 are formed on the long sides of the soft seal member 40 that face each other. The first seal portion 50 is a portion that elastically contacts the upper side wall 8 when the ventilation passage 10 is closed by the damper plate 20, and is located upstream in the blowing direction B when the ventilation passage 10 is opened. This is the part to do. The configuration of the first seal portion 50 will be described later in detail with reference to the drawings.

  On the other hand, the second seal portion 60 forms a long side portion facing the first seal portion 50 in the soft seal member 40, and when the ventilation passage 10 is closed by the damper plate 20, the second seal portion 60 is located on the lower side wall 9. This is the part that makes elastic contact. The second seal portion 60 is located on the upstream side in the blowing direction B when the ventilation passage 10 is opened. The configuration of the second seal portion 60 will be described later in detail with reference to the drawings.

  As shown in FIGS. 9 and 10, an anchor portion 70 and an overlap portion 75 are formed on the inner peripheral side of the soft seal member 40. A plurality of anchor projections 71 are formed on the anchor part 70. The plurality of anchor projections 71 are formed at regular intervals along the inner peripheral portion of the soft seal member 40 except for the left shaft recess 41 and the right shaft recess 42. Each of the anchor projections 71 is fitted into each of the anchor holes 35 formed in the seal arrangement portion 34. The overlap portion 75 is formed so as to overlap with the end of the plate body 31 when the soft seal member 40 is fixed to the plate member 30.

  In the damper plate 20 according to the present embodiment, after the plate member 30 is primarily formed from a hard material, the soft seal member 40 is secondarily formed with a soft material on the plate member 30 (ie, two-color molding). Formed by Here, in the present embodiment, each anchor hole 35 is formed in the seal arrangement portion 34 of the plate main body 31 during the primary molding of the plate member 30, and thereafter, in the secondary molding, a soft material such as an olefin elastomer is used. Each anchor protrusion 71 is formed by injecting a resin material into each of the anchor holes 35. As a result, the plate member 30 and the soft seal member 40 are fixed to each other by the cooperation of the anchor holes 35 and the anchor protrusions 71, so that the plate member 30 and the soft seal member 40 are fixed to each other. It is possible to reliably prevent the soft seal member 40 from coming off from 30.

(Schematic configuration of first seal portion and second seal portion)
Subsequently, the configuration of the first seal portion 50 and the second seal portion 60 that constitute the soft seal member 40 will be described in detail with reference to FIGS. As described above, when the ventilation passage 10 is closed by the damper plate 20, the first seal portion 50 is a portion that elastically contacts the upper side wall 8. B is located on the upstream side.

  As shown in FIG. 11 and FIG. 14 in an enlarged manner, the first seal portion 50 is configured to include an inclined portion 51, a flat portion 55, and a concave portion 58. The inclined portion 51 forms a distal end portion of the first seal portion 50, and is directed toward the first surface side and the second surface side with the vertex 52 being the distal end of the first seal portion 50 as a reference. And a pair of inclined surfaces 53 formed so as to be inclined (see FIG. 14).

  In the first seal portion 50, the flat portion 55 is formed adjacent to the inclined surface 53 on the first surface side and the second surface side of the inclined portion 51, respectively, and has a protruding portion 56. I have. As shown in FIGS. 9 to 12 and the like, the protruding portion 56 is formed by the soft seal member 40 along the outer peripheral edge corresponding to the first seal portion 50 among the outer peripheral edges of the damper plate 20. It protrudes in a direction perpendicular to the plate body 31 of the plate member 30.

  Specifically, the projecting portion 56 of the first seal portion 50 forms a plurality of projecting pieces 57 at predetermined intervals along the outer peripheral edge corresponding to the first seal portion 50 among the outer peripheral edges of the damper plate 20. It is constituted by setting. Each protruding piece 57 is formed so as to protrude from the flat portion 55 by the soft seal member 40 in a direction perpendicular to the plate body 31 of the plate member 30. As will be described later, each projecting portion 56 reduces the wind noise when the ventilation passage 10 is opened (see, for example, FIGS. 16 and 17), and performs the ventilation by the airflow when the ventilation passage 10 is closed. Reduce sound. The amount of protrusion of each protruding piece 57 with respect to the surface of the plate body 31 is larger than the amount of protrusion of each protruding piece 67 in the second seal portion 60 described later (see FIGS. 14 and 15).

  As shown in FIGS. 13 and 14, the concave portion 58 is formed on the first surface side of the first seal portion 50 such that the rotation axis of the damper plate 20 (the left rotation axis portion 32 and the right rotation axis) is larger than the protrusion 56. It is formed on the side of a virtual axis connecting the parts 33. The concave portion 58 is formed so that the surface on the first surface side of the first seal portion 50 is depressed in a direction perpendicular to the plate body portion 31 of the plate member 30. It extends along 56. By forming the concave portion 58, the thickness of the first seal portion 50 can be partially reduced. Thereby, the elastic force when the soft seal member 40 elastically returns to the original state from the elastic contact state with the inner peripheral surface of the retainer 5 is suppressed, and abnormal noise is generated when the soft seal member 40 elastically returns. Can be prevented.

  The second sealing portion 60 is a portion that makes elastic contact with the lower wall 9 when the ventilation passage 10 is closed by the damper plate 20, and when the ventilation passage 10 is open, the second sealing portion 60 is downstream in the blowing direction B. Located on the side.

  As shown in FIG. 12 and FIG. 15 in an enlarged manner, the second seal portion 60 has an inclined portion 61, a flat portion 65, and a concave portion 68, similarly to the first seal portion 50. . The inclined portion 61 constitutes a distal end portion of the second seal portion 60, and a vertex 62 which is a distal end of the second seal portion 60 and a first surface side and a second surface side with respect to the vertex 62. And a pair of inclined surfaces 63 formed so as to be inclined (see FIG. 15).

  In the second seal portion 60, the flat portion 65 is formed adjacent to the inclined surface 63 on the first surface side and the second surface side of the inclined portion 61, and has the protruding portion 66. I have. As shown in FIGS. 9 to 12 and the like, the protruding portion 66 is formed by the soft seal member 40 along the outer peripheral edge corresponding to the second seal portion 60 among the outer peripheral edges of the damper plate 20. It protrudes in a direction perpendicular to the plate body 31 of the plate member 30.

  Specifically, the projecting portions 66 of the second seal portion 60 form a plurality of projecting pieces 67 at predetermined intervals along an outer peripheral edge of the damper plate 20 corresponding to the second seal portion 60. It is constituted by setting. Each protruding piece 67 is formed so as to protrude from the flat portion 65 by the soft seal member 40 in a direction perpendicular to the plate body 31 of the plate member 30. As will be described later, each projecting portion 66 reduces wind noise when the ventilation passage 10 is opened (see, for example, FIGS. 16 and 17), and at the same time, winds due to airflow when the ventilation passage 10 is closed. Reduce sound. The amount of protrusion of each protruding piece 67 with respect to the plate body 31 is smaller than the amount of protrusion of each protruding piece 57 in the first seal portion 50 (see FIGS. 14 and 15).

  As shown in FIGS. 13 and 15, the concave portion 68 is provided on the first surface side of the second seal portion 60 with respect to the rotation axis (the left rotation axis portion 32 and the right rotation axis) of the damper plate 20 more than the protrusion 66. It is formed on the side of a virtual axis connecting the parts 33. The concave portion 68 is formed so that the surface on the first surface side of the second seal portion 60 is depressed in a direction perpendicular to the plate body portion 31 of the plate member 30. It extends along 66. By forming the concave portion 68, the thickness of the second seal portion 60 can be partially reduced. Thereby, the elastic force when the soft seal member 40 elastically returns to the original state from the elastic contact state with the inner peripheral surface of the retainer 5 is suppressed, and abnormal noise is generated when the soft seal member 40 elastically returns. Can be prevented.

(Generation of wind noise at the register with the ventilation path open)
Here, a description will be given, with reference to FIG. 16, of the generation of the wind noise generated when the ventilation path is opened by the damper plate P having the plate member and the soft seal member in the general register D.

  In the example illustrated in FIG. 16, the register D includes a retainer R formed in a substantially rectangular cylindrical shape using the upper side wall WU and the lower side wall WL, and a damper plate P having a plate member and a soft seal member. By rotating the damper plate P, the conditioned air blown in the blowing direction B can open and close the ventilation passage.

  In this case, the damper plate P includes a substantially flat plate member, and a soft seal member that elastically contacts the upper wall WU and the lower wall WL of the retainer R. The configuration is similar to the above-described damper plate 20 in that the road is configured to be able to be sealed. However, unlike the above-described damper plate 20, the damper plate P does not have the first seal portion 50 and the second seal portion 60 (specifically, a protruding portion, a concave portion, or the like), and is formed by a soft seal member. It is configured to become thinner toward the edge.

  In the register D configured as described above, when the ventilation path inside the retainer R is opened by the damper plate P (see FIG. 16), the damper plate P is in a state along the blowing direction B of the conditioned air. . In this case, the flow of the conditioned air according to the blowing direction B is such that the air-conditioning air flows toward the upper side wall WU side by contacting the edge located on the upstream side in the blowing direction B among the edges of the damper plate P. The flow is divided into flows toward the lower side wall WL.

  When the flow of the conditioned air is cut off by contact with the edge of the damper plate P, vortex V is generated on the upper wall WU side and the lower wall WL side of the damper plate P, respectively. Then, a sound wave related to the generated sound SG is generated and is detected as a wind noise (see FIG. 16). The generated sound SG generated on the upper side wall WU of the damper plate P is reflected to the damper plate P side as the reflected sound SR with the upper side wall WU of the retainer R being a fixed end. On the other hand, the sound SG generated on the lower wall WL side of the damper plate P is reflected to the damper plate P side as the reflected sound SR with the lower wall WL of the retainer R serving as a fixed end.

  The generated sound SG and the reflected sound SR generated on the upper wall WU side of the damper plate P may resonate with the generated sound SG and the reflected sound SR generated on the lower wall WL side of the damper plate P, respectively. In some cases, the noise level of the wind noise in the frequency band (for example, 2000 Hz to 2500 Hz) is amplified (see the second noise level GB in FIG. 17).

(Effects of the presence or absence of the protrusions on the first seal portion and the second seal portion on wind noise)
Next, the measurement result of the noise level of the wind noise generated by the damper plate when the ventilation path is opened will be described with reference to FIG.
The first noise level GA in FIG. 17 indicates the relationship between the noise level of the wind noise generated when the ventilation path 10 is opened by the damper plate 20 according to the present embodiment and the frequency band. The second noise level GB in FIG. 17 is a noise level of wind noise generated when the ventilation path is opened by the damper plate P shown in FIG.

  As shown in FIG. 17, in a predetermined frequency band (for example, 2000 Hz to 2500 Hz), the first noise level GA related to the damper plate 20 shows a significantly smaller value than the second noise level GB related to the damper plate P. ing. As shown in FIGS. 13 and 16, the damper plate 20 differs from the damper plate P in that the first seal portion 50 and the second seal portion 60 have a protrusion 56 and a protrusion 66, respectively. Therefore, according to the register 1 using the damper plate 20, the presence of the projections 56 and 66 suppresses the generation of the wind noise generated when the ventilation path 10 is opened, and reduces the noise of the wind noise. The noise level can be reduced.

  This is because the flow of the conditioned air on the first surface side of the damper plate 20 is different from the flow of the conditioned air on the second surface side, thereby affecting the generation of the vortex V and the resonance of the generated sound SG and the reflected sound SR. It can be considered that the noise level of the wind noise in this case is reduced.

  Further, as described above, the protruding portion 56 of the first seal portion 50 is configured by arranging a plurality of protruding pieces 57 at predetermined intervals (see FIG. 11), and the protruding portion 66 of the second seal portion 60. Is constituted by arranging a plurality of projecting pieces 67 at predetermined intervals (see FIG. 12). Therefore, the vortex generated in the vicinity of the first seal part 50 and the second seal part 60 in the damper plate 20 can be divided into fine vortices in the left-right direction by the plurality of protruding pieces 57 and the protruding pieces 67. By dividing the vortex finely, generation of abnormal noise (wind noise) generated in the vicinity of the first seal portion 50 and the second seal portion 60 in the damper plate 20 can be suppressed, and the abnormal noise can be suppressed. Noise level can be reduced.

  Further, as shown in FIGS. 11 to 15, in a state where the ventilation passage 10 is opened by the damper plate 20, the protrusion of the protrusion 56 related to the first seal portion 50 located on the upstream side in the blowing direction B of the conditioned air. The amount is formed larger than the amount of protrusion of the protrusion 66 of the second seal portion 60 located on the downstream side in the blowing direction B. That is, the damper plate 20 can efficiently separate the flow of the conditioned air, the vortex, and the like on the upstream side in the air-flow direction B of the conditioned air. Generation of sound (wind noise) can be suppressed, and the noise level related to the abnormal noise can be reduced.

(Operation of the damper plate when closing the ventilation passage of the retainer)
Subsequently, in the register 1 according to the present embodiment, the closing operation of the ventilation path 10 performed via the damper plate 20 will be described in detail with reference to FIGS.
First, in a state where the ventilation passage 10 of the retainer 5 in the register 1 is opened, the damper plate 20 is held in a horizontal state in the ventilation passage 10 as shown in FIG.

  When closing the ventilation passage 10 of the retainer 5, the link member 17 and the shaft-side connecting member 18 are rotated by rotating the knob member 16 of the opening / closing operation unit 15 around the shaft 13 in a predetermined direction. Then, the damper plate 20 is rotated. In this case, the damper plate 20 moves in a predetermined direction (in the counterclockwise direction in FIG. 13) around the left rotation shaft portion 32 and the right rotation shaft portion 33 inside the ventilation passage 10 in conjunction with the rotation operation of the knob member 16. (Clockwise).

  At this time, the first seal portion 50 approaches the upper wall 8 of the retainer 5 with the rotation of the damper plate 20 and makes elastic contact with the upper wall 8 forming the ventilation path 10. . On the other hand, with the rotation of the damper plate 20, the second seal portion 60 approaches the lower wall 9 of the retainer 5 and elastically contacts the lower wall 9 of the ventilation path 10.

  In this case, the first seal portion 50 elastically contacts the upper side wall 8 with the inclined surface 53 of the two inclined surfaces 53 located on the first surface side of the damper plate 20. At this time, as shown in FIG. 19, the concave portion 58 of the first seal portion 50 is elastically deformed so that its opening edge is widened. On the other hand, the second seal portion 60 elastically contacts the lower wall 9 with the inclined surface 53 of the two inclined surfaces 63 located on the second surface side of the damper plate 20. At this time, the concave portion 68 of the second seal portion 60 is elastically deformed so that its opening edge approaches (see FIG. 20). In this manner, the ventilation is performed by rotating the damper plate 20 so that the first seal portion 50 of the damper plate 20 elastically contacts the upper wall 8 and the second seal portion 60 elastically contacts the lower wall 9. The passage 10 can be closed by a damper plate 20.

  In the damper plate according to the present embodiment, only the inclined surface 53 of the first seal portion 50 and the inclined surface 63 of the second seal portion 60 can be brought into elastic contact with the inner peripheral surface of the ventilation passage 10 of the retainer 5. Thus, according to the damper plate 20, the contact area of the soft seal member 40 with the inner peripheral surface of the retainer 5 can be reduced, so that when the soft seal member 40 elastically contacts the inner peripheral surface of the retainer 5. Abnormal noise can be reduced.

  Further, as shown in FIGS. 19 and 20, a projecting portion 66 formed by arranging a plurality of projecting pieces 57 is formed on the flat portion 55 adjacent to the inclined surface 53 of the first seal portion 50. In addition, a protruding portion 66 configured by arranging a plurality of protruding pieces 67 is formed on a flat portion 65 adjacent to the inclined surface 63 of the second seal portion 60. Thereby, the damper plate 20 can reduce the wind noise generated by the flow of the conditioned air when the ventilation path 10 is closed via the protrusions 56 and the protrusions 66.

(Operation of the damper plate when opening the ventilation passage from the closed state)
Subsequently, in the register 1 according to the present embodiment, the opening operation of the ventilation passage 10 performed through the damper plate 20 will be described in detail with reference to FIGS.

  When the ventilation path 10 is opened from a state in which the ventilation path 10 is closed by the damper plate 20 (see FIG. 18), the knob member 16 of the opening / closing operation unit 15 is turned around the shaft 13 in a direction opposite to the closing direction. By rotating the damper plate 20, the damper plate 20 is rotated via the link member 17 and the shaft-side connecting member 18. In this case, the damper plate 20 moves in a predetermined direction (clockwise in FIG. 18) around the left rotation shaft 32 and the right rotation shaft 33 inside the ventilation passage 10 in conjunction with the rotation operation of the knob member 16. Around). At this time, as the damper plate 20 rotates, the first seal portion 50 separates from the upper wall 8 of the retainer 5, and the second seal portion 60 separates from the lower wall 9 of the retainer 5. Go.

  As shown in FIG. 21, when the first seal portion 50 moves away from the upper wall 8 of the retainer 5, the concave portion 58 of the first seal portion 50 changes from a state where the opening edge is widened to a normal state. It elastically deforms to return. At the same time, when the second seal portion 60 moves away from the lower wall 9 of the retainer 5, the concave portion 68 of the second seal portion 60 is elastically deformed so that the opening edge of the second seal portion 60 returns from the approaching state to the normal state. (See FIG. 22).

  Here, the concave portion 58 in the first seal portion 50 is formed so that the thickness of the soft seal member 40 is smaller on the rotation axis side than the projecting portion 56, and the concave portion 68 in the second seal portion 60 is The soft seal member 40 is formed so as to have a smaller thickness on the rotation shaft side than the protrusion 66. Therefore, according to the damper plate 20, the elastic force when the soft seal member 40 elastically returns to the original state from the state of being in elastic contact with the inner peripheral surface of the retainer 5 can be suppressed, and the soft seal member can be softly sealed. Abnormal noise generated when the member 40 returns elastically can be reduced.

  As described above, the damper plate 20 according to the present embodiment is rotatably disposed between the left side wall 6 and the right side wall 7 forming the ventilation path 10 inside the retainer 5 forming the register 1. The air passage 10 for guiding air to the air outlet 12 of the register 1 is opened and closed (see FIGS. 13 and 18).

  The damper plate 20 has a plate member 30, a soft seal member 40, and a protrusion 56 and a protrusion 66. When the ventilation path 10 is closed by the damper plate 20, the soft seal member 40 constituting the damper plate 20 may be brought into elastic contact with the upper side wall 8 and the lower side wall 9 forming the ventilation path 10 of the retainer 5. Therefore, the damper plate 20 can more reliably stop blowing the conditioned air through the air outlet 12 of the register 1.

  As shown in FIG. 17, in the damper plate 20, the protrusion 56 and the protrusion 66 are formed along the outer peripheral edge of the damper plate 20 by the soft seal member 40. Since it protrudes in a direction perpendicular to the main body 31, in a state where the ventilation passage 10 is opened, an unusual noise (wind noise) caused by the damper plate 20 and a noise due to resonance of the unusual noise are generated. An increase in level can be suppressed.

As shown in FIG. 11, in the damper plate 20, the protruding portion 56 of the first seal portion 50 is formed by arranging a plurality of protruding pieces 57 at predetermined intervals along the outer peripheral edge of the damper plate 20. Each protruding piece 57 is formed by the soft seal member 40 and protrudes in a direction perpendicular to the plate body 31 of the plate member 30. or,
The protruding portion 66 of the second seal portion 60 is configured by arranging a plurality of protruding pieces 67 at predetermined intervals along the outer peripheral edge of the damper plate 20, and each protruding piece 67 is formed of a soft seal. It is formed by a member 40 and protrudes in a direction perpendicular to the plate body 31 of the plate member 30 (see FIG. 12).

  According to the damper plate 20, the vortex generated near the outer peripheral edge of the damper plate 20 that divides the flow of the conditioned air is finely vortexed by the plurality of protruding pieces 57 and the protruding pieces 67 arranged at predetermined intervals. Therefore, generation of abnormal noise (wind noise) caused by the damper plate 20 can be suppressed, and the noise level of the abnormal noise can be reduced.

  As shown in FIGS. 13 to 15, in a state where the ventilation passage 10 is opened by the damper plate 20, the amount of protrusion of the protrusion 56 of the first seal portion 50 located on the upstream side in the blowing direction B of the conditioned air is: The projecting portion 66 of the second seal portion 60 located on the downstream side in the blowing direction B is formed to be larger than the projecting amount. That is, the damper plate 20 can efficiently separate the flow of the conditioned air, the vortex, and the like on the upstream side in the air-flow direction B of the conditioned air. Generation of sound (wind noise) can be suppressed, and the noise level related to the abnormal noise can be reduced.

  Further, according to the damper plate 20, when the air passage 10 of the retainer 5 is closed by the damper plate 20, the first seal portion 50 of the soft seal member 40 that elastically contacts the inner peripheral wall of the air passage 10 and The second seal portion 60 has a concave portion 58 and a concave portion 68, respectively, and the concave portion 58 and the concave portion 68 are more rotatable than the protruding portions 56 and 66 by the rotation shaft portion (the left rotation shaft portion 32). The damper plate 20 is formed so as to be depressed in a direction perpendicular to the plate main body 31 from one surface side of the damper plate 20 at a position on the right rotation shaft portion 33) side.

  Therefore, according to the damper plate 20, the soft seal is changed from the state in which the inner peripheral surface of the retainer 5 is in elastic contact with the inner peripheral surface of the retainer 5 around the recess 58 and the recess 68 formed in the soft seal member 40. The member 40 can be returned, so that the elastic force acting upon the elastic return can be suppressed. Thereby, according to the damper plate 20, it is possible to suppress the generation of abnormal noise due to the elastic return of the soft seal member 40 by the concave portions 58 and the concave portions 68 formed in the soft seal member 40.

  The embodiment does not limit the scope of the present invention, and it goes without saying that various improvements and modifications can be made without departing from the spirit of the present invention. For example, in the above-described embodiment, the protruding portions 56 and the protruding portions 66 are configured by arranging the plurality of protruding pieces 57 and the plurality of protruding pieces 67 at predetermined intervals, but are not limited to this mode. is not. For example, if each of the protrusions protrudes in the direction perpendicular to the flat plate portion of the damper plate, each protrusion is formed as a ridge extending along the outer peripheral edge of the damper plate (that is, a rib that does not have a predetermined interval). It is also possible.

In the above-described embodiment, the concave portion 58 of the first seal portion 50 and the concave portion 68 of the second seal portion 60 are both formed on the first surface side of the damper plate 20. It is not limited. For example, both the concave portion 58 of the first seal portion 50 and the concave portion 68 of the second seal portion 60 may be formed on the second surface side of the damper plate 20. Further, the concave portion 58 of the first seal portion 50 is formed on one of the first surface side and the second surface side of the damper plate 20, and the concave portion 68 of the second seal portion 60 is formed on the first surface side of the damper plate 20. Alternatively, it can be formed on the other side of the second surface side.
Next, a technical idea derived from the contents of the above embodiment will be described.
In the damper plate of the present application, the protruding portion is formed by the soft seal member, and a plurality of protruding pieces protruding in a direction perpendicular to the plate member are formed at predetermined intervals along an outer peripheral edge of the damper plate. It may be configured by arranging.
According to the damper plate, the vortex generated near the outer periphery of the damper plate that divides the flow of the conditioned air can be divided into fine vortices by a plurality of protruding pieces arranged at predetermined intervals. Thus, generation of abnormal noise (wind noise) caused by the damper plate can be suppressed, and the noise level of the abnormal noise can be reduced.

DESCRIPTION OF SYMBOLS 1 Register 5 Retainer 6 Left side wall 7 Right side wall 8 Upper side wall 9 Lower side wall 10 Ventilation path 20 Damper plate 30 Plate member 32 Left side rotation shaft part 33 Right side rotation shaft part 40 Soft seal member 50 First seal part 56 Projection 57 Projection piece 58 Recess 60 Second seal part 66 Projection 67 Projection piece 68 Recess

Claims (4)

Constructing a register, in a retainer having an air passage therein for guiding air to an air outlet of the register, rotatably disposed between a pair of opposed side walls constituting the air passage, A damper plate for opening and closing the ventilation path,
The damper plate includes:
A plate member having a rotating shaft portion on both sides corresponding to the pair of side walls, and having a plate shape including the rotating shaft portion,
A soft seal member formed around the plate member excluding the rotation shaft portion and elastically contacting an inner peripheral wall forming an air passage of the retainer;
Wherein the soft sealing member is formed along the outer periphery of the damper plate, have a, a projection projecting in a direction perpendicular to said plate member,
At the tip of the outer peripheral portion of the soft seal member,
A slope is provided,
The inclined portion,
From the apex which is the tip of the soft seal member, a pair of inclined surfaces formed to be inclined toward each surface of the flat plate member, respectively.
The damper plate includes:
One of the pair of the inclined surface, a peripheral wall in an elastically contact inner forming an air passage of said retainer, to close the air passage, the damper plate, characterized in that. The soft seal member,
A flat portion provided on the plate member side from the position of the inclined portion and formed continuously with the inclined surface,
The protrusion is
The damper plate according to claim 1, wherein the damper plate is provided on the plane portion . The amount of protrusion of the protrusion with respect to the plate member is:
In a state where the ventilation path is opened by the damper plate, the projection located on the downstream side in the downstream direction is larger than the projection located on the downstream side in the downstream direction of the air flowing through the ventilation path. The damper plate according to claim 1 or claim 2, wherein The damper plate includes:
When closing the ventilation path of the retainer with the damper plate, at the edge of the soft seal member elastically contacting the inner peripheral wall of the ventilation path,
2. A concave portion formed so as to be depressed in a direction perpendicular to the plate member from one surface side of the damper plate at a position closer to the rotation shaft portion than the projecting portion. Item 4. The damper plate according to any one of items 3.

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