JP2018194041A - Fluid damper device and apparatus with damper - Google Patents

Abstract

To properly fix a cover to an opening portion of a case in a fluid damper device.SOLUTION: A fluid damper device 10 includes a rotor 30 inserted to a bottomed cylindrical case 20, and a cover 60 fixed to an opening portion 29 of the case 20. A thin portion 28 is formed on an end portion at one side L1 in an axial direction L, of the case 20, and four stopper portions 70 kept into contact with a small-diameter portion 63 of the cover 60 in the axial direction L, are formed on an inner peripheral face of the thin portion 28 at equal intervals. The inner peripheral face of the case 20 is provided with partitioning projecting portions 26 for partitioning a damper chamber 11 in a circumferential direction, and the stopper portions 70 are formed on circumferential positions corresponding to the partitioning projecting portions 26. Recessed portions 73 recessed to a radial outer side, are formed on circumferential positions different from the stopper portions 70, and projecting portions 80 for welding are formed on the recessed portions 73. The small-diameter portion 63 is welded to the projecting portions 80 for welding by ultrasonic welding.SELECTED DRAWING: Figure 7

Description

  The present invention relates to a fluid damper device and a device with a damper in which a fluid is filled between a case and a rotor.

  Patent Document 1 discloses a fluid damper device in which a fluid such as oil is filled between a bottomed cylindrical case and a rotor. In the fluid damper device of Patent Document 1, one end of the rotor (rotating shaft) in the axial direction is disposed inside the case, a damper chamber is formed between the rotating shaft and the inner peripheral surface of the case, and is provided on the side surface of the rotating shaft. The valve body is placed in the damper chamber. When the rotor rotates in the first direction, the radial tip of the valve body is in contact with the inner peripheral surface of the case. Therefore, the rotational load of the rotor is large. On the other hand, when the rotor rotates in the direction opposite to the first direction, there is a gap between the valve body and the case inner peripheral surface due to the resistance of the fluid, so that the fluid passes through this gap, so the rotational load on the rotor is small. .

JP 2006-223538 A

  In the fluid damper device of Patent Document 1, the rotor is prevented from coming off from the case by a cover fixed to the opening of the case. As a method for fixing the cover, a screw-type fixing method in which a female screw formed on the inner peripheral surface of the case and a male screw formed on the outer peripheral surface of the cover are screwed together is used. However, the screw type has a large dimension in the axial direction, and the mold cost for forming the screw portion is expensive. Therefore, in order to reduce the thickness in the axial direction and reduce the cost, fixing by welding is performed. When fixing the cover to the case by welding, the inner peripheral surface of the case and the end of the cover inserted inside the case are melted and the cover is pushed into the case.

  When fixing by welding, in order to make the pushing amount of the cover into the case appropriate, a step portion is formed on the inner peripheral surface of the case and the cover is brought into contact with the step portion. However, even when the step portion is formed in the case, the portion where the step portion and the cover come into contact with each other may be deformed by the influence of welding, and the amount of the cover pushed into the case may vary. For example, when ultrasonic welding is performed, a horn that generates ultrasonic waves is applied to melt the welding location, but if there is a variation in the welding height due to the horn, the stepped portion may be deformed and the amount of pushing of the cover may vary. There is. If the amount of pressing of the cover into the case varies, the dimensional accuracy in the axial direction of the damper chamber filled with fluid decreases. As a result, the volume of the damper chamber changes and the damper performance may vary.

  In view of the above problems, an object of the present invention is to appropriately fix a cover in a fluid damper device.

In order to solve the above problems, a fluid damper device according to the present invention includes a bottomed cylindrical case that opens to one side in the axial direction, a rotating shaft and a valve body that are inserted into a damper chamber formed in the case. A rotor provided with the fluid filled in the damper chamber, a cover provided with a through-hole through which the rotor passes, fixed to the opening of the case, an outer peripheral surface of the rotor, and an inner peripheral surface of the case A sealing member that seals the gap, and a contact portion that is in contact with the cover in the axial direction is formed in a part of the circumferential direction on the inner peripheral surface of the case. To do.

  In the present invention, a contact portion that contacts the cover fixed to the opening of the case in the axial direction is formed in a part of the circumferential direction on the inner peripheral surface of the case of the fluid damper device. Therefore, when the cover is fixed by welding, the welded portion and the contact portion can be provided at different positions in the circumferential direction, so that the contact portion is less likely to be deformed due to the influence of welding. Therefore, the cover can be accurately positioned in the axial direction, and the cover can be properly fixed. Thereby, the dimensional accuracy of the damper chamber in the axial direction can be improved, and variations in damper performance can be suppressed.

  In the present invention, a partition convex portion for partitioning the damper chamber in the circumferential direction is formed on an inner peripheral surface of the case, and the contact portion is formed at a circumferential position corresponding to the partition convex portion. Yes. If it does in this way, positioning of the direction of an axis of a cover can be performed with sufficient accuracy in the position of the convex part for partition. Therefore, the dimensional accuracy in the axial direction of the damper chamber can be improved, and the variation in the damper performance can be suppressed.

  In the present invention, a rib extending in a radial direction is formed on one end face in the axial direction of the partitioning convex portion, and the contact portion is formed in a range including an angular position of the rib. Yes. If it does in this way, positioning of the direction of an axis of a cover can be performed with sufficient accuracy in the position of a rib for raising the sealing accuracy of a damper room. Therefore, the sealing accuracy of the damper chamber can be increased.

  In the present invention, the contact portion is formed at two locations on the opposite side with respect to the radial center of the inner peripheral surface of the case. For example, it is formed on two straight lines extending in the diameter direction of the case and on the opposite side with respect to the radial center of the case. Thus, by forming the two contact portions on the opposite side with respect to the center in the radial direction, the cover can be accurately positioned in the axial direction. In addition, when the two contact portions are formed on a straight line extending in the diameter direction, the inclination of the cover can be suppressed.

  In the present invention, the contact portion is formed at three locations separated in the circumferential direction, and two of the three locations are the remaining of the three locations on the basis of the radial center of the case. It is arrange | positioned on the opposite side to one place. For example, the contact portions are formed at three equiangular intervals with reference to the radial center of the inner peripheral surface of the case. In this way, by forming two of the three locations separated in the circumferential direction on the side opposite to the remaining one, the cover can be accurately positioned in the axial direction. In particular, by forming the contact portion evenly in the circumferential direction, the cover can be accurately positioned in the axial direction, and the inclination of the cover can be suppressed.

  In the present invention, the contact portion is formed at four locations separated in the circumferential direction, and two of the four locations are on the first straight line extending in the diametrical direction of the case in the radial direction of the case. Two locations on the opposite side with respect to the center, and a position overlapping the rib and the axial direction, the remaining two of the four locations extending in the diameter direction of the case, and On the second straight line intersecting the first straight line, there are two places on the opposite side with respect to the radial center of the case. For example, the contact portions are formed at four equiangular intervals with reference to the radial center of the case. In this way, the cover can be accurately positioned in the axial direction. Moreover, the sealing accuracy of the damper chamber can be improved by positioning the cover in the axial direction at the position of the rib for increasing the sealing accuracy of the damper chamber. Further, by forming the contact portion evenly in the circumferential direction, the cover can be accurately positioned in the axial direction, and the inclination of the cover can be suppressed.

  In this invention, the welding convex part welded with the said cover is formed in the circumferential direction position different from the said contact part in the internal peripheral surface of the said case, and the said welding convex part is extended in the said axial direction. And the one end of the said axial direction of the said welding convex part, the said contact part, and the other end of the said axial direction of the said welding convex part are located in a line with the said axial direction in this order. As described above, if the welding convex portion and the contact portion are formed at different circumferential positions, the welding height is within a range including the position of the contact portion in the axial direction (height in the axial direction). There is little risk of deformation of the contact portion. Accordingly, the cover can be accurately positioned in the axial direction.

  In the present invention, the cover includes a small-diameter portion that is inserted into the case, and the case has an arcuate inner peripheral surface centered on the rotation center of the rotor at a circumferential position different from the welding convex portion. The small diameter portion is provided and positioned in a direction orthogonal to the axial direction by the arcuate inner peripheral surface. If it does in this way, a cover and a case can be coaxially positioned in the circumferential direction position different from a welding location.

  In the present invention, it is desirable that the inner peripheral surface of the welding convex portion has an arc shape centered on the rotation center of the rotor. If it does in this way, a welding convex part and a cover can be welded equally in the peripheral direction.

  In the present invention, it is desirable that an outflow prevention portion is provided on the radially inner side from the inner peripheral surface of the case in at least a part of the position adjacent to the welding convex portion. For example, a gap (that is, a welding burr pool) capable of holding a molten material such as a resin protruding from the welding portion can be provided as the outflow prevention portion. In this way, since the molten material that protrudes from the welded portion can be held in the outflow prevention portion, there is little risk of the molten material protruding from the outside of the case and the cover to form weld burrs, and there is a risk that the number of steps for removing the weld burrs will increase. Less is. In addition, there is little possibility that the molten material protrudes to the damper chamber side and the sealing performance of the damper chamber is lowered.

  In this case, it is desirable that the outflow prevention portion is provided at a position adjacent to at least the welding convex portion in the circumferential direction. Thereby, the molten material that protrudes in the circumferential direction can be held in the outflow prevention portion.

  In the present invention, the case and the cover are welded in a predetermined range in the axial direction, and the outflow located on the other side in the axial direction of the outflow preventing portion on the other side in the axial direction from the predetermined range. It is desirable that a regulation part is provided. If it does in this way, it can control that a fusion material flows out from the outflow prevention part to the damper room side.

  In this case, the outflow prevention portion is provided continuously from the end on one side in the axial direction of the case to the outflow restriction portion at a position adjacent to the welding convex portion in the circumferential direction. Is desirable. If it does in this way, since the outflow prevention part continuous in the direction of an axis can be provided, it can control that a fusion material flows out to the outside of a case and a cover, and the damper chamber side.

  In addition, it is desirable that the outflow prevention portion is provided on the other side in the axial direction within the predetermined range on the radially inner side from the inner peripheral surface of the welding convex portion. If it does in this way, the molten material which protrudes to the other side (damper chamber side) of an axial direction can be stored in the outflow prevention part of the diameter direction inside.

  Alternatively, it is desirable that the outflow restricting portion is provided on one side in the axial direction from the sealing member. In this way, it is possible to prevent the sealing member from being deformed by the molten material that protrudes to the other side (damper chamber side) in the axial direction. Therefore, there is little possibility that the sealing performance of the damper chamber will deteriorate.

  In this invention, the said outflow prevention part is provided in the one side of the said axial direction of the said predetermined range. If it does in this way, there is little possibility that the fusion material which protrudes from the welding range (predetermined range) to one side (opening side of a case) of the direction of an axis will flow out of the case.

  Next, the present invention is a damper-equipped device including the fluid damper device described above, and an opening / closing member that rotates relative to the device main body is attached to the rotating shaft. For example, the opening / closing member is a toilet seat of a Western-style toilet. Thus, when an opening / closing member such as a toilet seat is attached to the rotating shaft of the fluid damper device, the rotational load of the opening / closing member can be increased. Therefore, a sudden operation of the opening / closing member can be suppressed.

  In the present invention, a contact portion that contacts the cover fixed to the opening of the case in the axial direction is formed in a part of the circumferential direction on the inner peripheral surface of the case of the fluid damper device. Therefore, when the cover is fixed by welding, the welded portion and the contact portion can be provided at different positions in the circumferential direction, so that the contact portion is less likely to be deformed by welding. Therefore, the cover can be accurately positioned in the axial direction, and the cover can be properly fixed.

It is explanatory drawing of the western style toilet unit provided with the western style toilet bowl in which the fluid damper apparatus to which this invention is applied is mounted. It is an external appearance perspective view of a fluid damper device. It is a disassembled perspective view of a fluid damper device. It is the cross-sectional perspective view which cut | disconnected the fluid damper apparatus in the surface which follows an axis. It is sectional drawing which cut | disconnected the fluid damper apparatus by the surface perpendicular | vertical with respect to the axis line. It is the front view which looked at the opening part of the case from the one side of the axial direction. It is the perspective view which looked at the opening part of the case from the one side of the axial direction. It is a fragmentary sectional view in the state where a case and a cover were separated. It is a fragmentary sectional view of the welding location of a fluid damper device.

  Hereinafter, embodiments for carrying out the present invention will be described with reference to the drawings. In the following description, the direction in which the rotating shaft 40 of the rotor 30 extends is defined as the direction of the axis L, and in the direction of the axis L, the side where the rotating shaft 40 protrudes from the case 20 is referred to as one side L1. The side opposite to the side protruding from the case 20 will be described as the other side L2.

(Equipment with damper)
FIG. 1 is an explanatory diagram of a Western-style toilet unit 100 including a Western-style toilet 1 equipped with a fluid damper device 10 to which the present invention is applied. A western toilet unit 100 shown in FIG. 1 includes a western toilet 1 (equipment with a damper) and a water tank 3. The western toilet 1 includes a toilet body 2 (device body), a resin toilet seat 5 (opening / closing member), a resin toilet lid 6 (opening / closing member), a unit cover 7, and the like. A fluid damper device 10 is built in the unit cover 7 for a valve seat and a valve lid, and the toilet seat 5 and the toilet lid 6 are respectively connected to the toilet body 2 via the fluid damper device 10. . Here, as the fluid damper device 10 connected to the toilet seat 5 and the fluid damper device 10 connected to the toilet lid 6, those of the same configuration can be used. In the following description, the fluid damper device 10 connected to the toilet seat 5 will be described.

FIG. 2 is a perspective view of the fluid damper device 10 as seen from one side L1. The fluid damper device 10 includes a columnar fluid damper device main body 10a extending in the direction of the axis L, and a connecting shaft 10b protruding from the fluid damper device main body 10a to one side L1. The connecting shaft 10 b is connected to the toilet seat 5. Since the opposing surfaces of the front end portion of the connecting shaft 10b are flat, the toilet seat 5 is prevented from spinning around the connecting shaft 10b. The fluid damper device 10 generates a force (rotational load) against the toilet seat 5 that is standing so as to fall over the toilet body 2 to reduce the speed at which the toilet seat 5 falls.

(Fluid damper device)
FIG. 3 is an exploded perspective view of the fluid damper device. 4 is a cross-sectional perspective view of the fluid damper device 10 cut along a plane along the axis L, and FIG. 5 is a cross-sectional view of the fluid damper device cut along a plane perpendicular to the axis L. The fluid damper device 10 includes a bottomed cylindrical case 20, a rotor 30 that is rotatably held by the case 20, and an annular cover 60 that closes an opening 29 of the case 20. In this embodiment, the case 20 and the cover 60 are resin molded products.

  The case 20 includes a cylindrical body portion 21 extending in the direction of the axis L, and a bottom portion 22 that closes an end portion of the other side L2 of the body portion 21. An opening 29 is formed at the end of one side L <b> 1 of the body 21. As shown in FIG. 4, a circular recess 24 that is recessed in the other side L <b> 2 is formed in the center of the bottom 22. A shaft portion 41 provided at the tip of the other side L2 of the rotating shaft 40 of the rotor 30 is inserted into the recess 24. The shaft portion 41 is rotatably held by the recess 24.

  As shown in FIG. 5, partitioning convex portions 26 projecting radially inward are formed on the inner peripheral surface of the body portion 21 at two positions shifted by 180 ° in the circumferential direction. The partitioning convex portion 26 extends in the direction of the axis L, and the end of the other side L2 of the partitioning convex portion 26 is connected to the bottom portion 22. The partition convex portion 26 has a circumferential dimension (thickness) that decreases from the radially outer side to the inner side. The partitioning convex portion 26 partitions the damper chamber 11 formed inside the trunk portion 21 in the circumferential direction.

  The rotor 30 includes a rotating shaft 40 having an end on the other side L2 disposed inside the case 20 and a valve body 50 held by the rotating shaft 40. The rotating shaft 40 is linear as a whole, and an annular flange portion 42 is formed at a position on the other side L2 from the center in the direction of the axis L. The flange portion 42 is formed on the entire circumference of the rotating shaft 40. A first shaft portion 43 having a smaller diameter than the flange portion 42 is provided on the other side L2 with respect to the flange portion 42. The first shaft portion 43 has a smaller diameter than the flange portion 42 on the one side L1 with respect to the flange portion 42 and the first side. A second shaft portion 44 having a diameter larger than that of the shaft portion 43 is provided. The shaft portion 41 inserted into the concave portion 24 of the case 20 protrudes from the center of the tip surface of the first shaft portion 43. Opposing flat surfaces are formed at the tip of the second shaft portion 44.

  The flange portion 42 includes a first flange portion 421 and a second flange portion 422 that are arranged at a predetermined interval in the direction of the axis L, and an annular shape is provided between the first flange portion 421 and the second flange portion 422. The circumferential groove 423 (see FIG. 4) is formed. An O-ring 49 is attached to the circumferential groove 423. When the rotor 30 is assembled to the case 20, the O-ring 49 comes into contact with the cylindrical inner peripheral surface 27 of the case 20 and is crushed. Therefore, the gap between the case 20 and the flange portion 42 is sealed, and the damper chamber 11 sealed from the outside is formed between the bottom portion 22 and the flange portion 42 of the case 20. The damper chamber 11 is filled with a fluid 12 (viscous fluid) such as oil.

  Thereafter, the fluid damper device 10 is configured by inserting the cover 60 between the second shaft portion 44 of the rotating shaft 40 and the body portion 21 of the case 20 and fixing the cover 60 to the opening 29 of the case 20. At that time, an annular washer 48 is disposed between the cover 60 and the second flange portion 422 of the rotating shaft 40. In this state, the shaft portion 41 provided at the end portion on the other side L2 of the rotating shaft 40 is rotatably supported by the recess 24 formed in the bottom portion 22 of the case 20, and the second shaft portion 44 covers the second shaft portion 44. It is rotatably supported inside a through hole 61 formed in 60. Moreover, a part of 2nd axial part 44 penetrates the through-hole 61 of the cover 60, and protrudes to the one side L1, and the connection shaft 10b is comprised.

  The contact surface on which the washer 48 and the second flange portion 422 are in contact is a sliding surface that slides when the rotor 30 rotates. That is, in the rotor 30, the surface on the one side L <b> 1 of the second flange portion 422 is a sliding surface that slides with the washer 48. Wear of the sliding surface can be suppressed by making the washer 48 made of metal. It is preferable to apply a lubricant such as grease to the sliding surface.

(Damper room)
As shown in FIG. 5, an annular damper chamber 11 is provided between the trunk portion 21 and the first shaft portion 43. An inner peripheral side end surface 262 of the partitioning convex portion 26 protruding inward from the inner peripheral surface of the body portion 21 is in contact with the outer peripheral surface of the first shaft portion 43. Accordingly, the damper chamber 11 is partitioned into two chambers having the same shape by the two partitioning convex portions 26. On the outer peripheral surface of the first shaft portion 43, valve body holding portions 46 are formed at two locations that are 180 ° apart in the circumferential direction. The two valve body holding portions 46 have the same shape, and project radially outward from the outer peripheral surface of the first shaft portion 43. Further, the valve body holding portion 46 extends to the end portion on the other side L <b> 2 of the first shaft portion 43, and the end portion on the one side L <b> 1 is connected to the first flange portion 421.

  The valve body 50 is held in each of the two valve body holding portions 46. The valve body holding portion 46 has a circumferential width that is narrower on the radially inner side than on the radially outer side. A valve body holding groove 461 that is recessed radially inward is formed at the radially outer end of the valve body holding section 46. The valve body holding groove 461 is formed between the first convex portion 462 located on one side in the circumferential direction and the second convex portion 463 located on the other side in the circumferential direction, and is linear in the axis L direction. Extend. The valve body holding groove 461 has an arc shape whose inner peripheral surface is curved over an angular range exceeding about 180 °.

  The valve body 50 includes a base portion 51 held in the valve body holding groove 461 and a distal end portion 52 that protrudes radially outward from the base portion 51. The distal end portion 52 of the valve body 50 protrudes in a direction inclined with respect to the radial direction, and contacts the cylindrical inner peripheral surface 27. In the present embodiment, the first convex portion 462 has a smaller radial outward projection size than the second convex portion 463, and the tip portion 52 of the valve body 50 covers the outer peripheral side of the first convex portion 462. Tilted.

  In the fluid damper device 10, the rotor 30 (rotating shaft 40) rotates about the axis L in the first direction R <b> 1 (see FIG. 5) during the closing operation in which the toilet seat 5 illustrated in FIG. 1 rotates from the standing posture to the flat posture. . The first direction R <b> 1 is a direction in which the rotor 30 rotates on the side where the distal end portion 52 is positioned with respect to the base portion 51 of the valve body 50. In this case, in the valve body 50, the tip 52 of the valve body 50 is pressed against the cylindrical inner peripheral surface 27 by the pressure from the fluid 12. For this reason, the fluid 12 cannot pass between the valve body 50 and the cylindrical inner peripheral surface 27, and a rotational load is applied to the rotor 30 (rotating shaft 40). However, even in this case, there is a slight gap between the bottom 22 of the case 20 and the valve body 50, so that the fluid is slightly allowed to move. Accordingly, the rotor 30 is allowed to rotate in the first direction R1 at a low speed although a rotational load is applied.

  Further, during the opening operation in which the toilet seat 5 shown in FIG. 1 rotates from the flat posture to the standing posture, the rotor 30 (rotating shaft 40) rotates around the axis L in the second direction R2 (see FIG. 5). The second direction R2 is opposite to the first direction R1. In this case, the tip 52 of the valve body 50 is separated from the cylindrical inner peripheral surface 27 by the pressure from the fluid 12, so that the fluid 12 can pass between the valve body 50 and the cylindrical inner peripheral surface 27. . Therefore, the rotational load of the rotor 30 is small.

(Sealing structure in the direction of the axis L of the damper chamber)
The valve body 50 is in contact with the first flange portion 421 at one end L1. For this reason, there is almost no gap between the valve body 50 and the first flange portion 421. Therefore, the fluid 12 does not pass between the valve body 50 and the first flange portion 421. On the other hand, the end portion on the other side L2 of the valve body 50 is positioned slightly on the one side L1 from the end surface on the other side L2 of the valve body holding portion 46. For this reason, on the other side L <b> 2 with respect to the valve body 50, a slight gap is left between the end portion on the other side L <b> 2 of the valve body 50 and the bottom portion 22 of the case 20. Thus, the fluid 12 can pass slightly through the gap.

  The rotating shaft 40 forms a surface in which the end surface on the other side L2 of the first shaft portion 43 and the end surface on the other side L2 of the valve body holding portion 46 are continuous. Here, there may be a gap between the first shaft portion 43 and the end face of the other side L2 of the valve body holding portion 46 and the bottom portion 22 of the case 20, but the first shaft portion 43 and the valve body holding portion may be present. A rib (not shown) extending in the radial direction is formed on the end surface of the other side L2 of 46. When the fluid damper device 10 is configured, such a rib is crushed to a state corresponding to the gap between the first shaft portion 43 and the end face on the other side L2 of the valve body holding portion 46 and the bottom portion 22 of the case 20. For this reason, the fluid 12 does not pass between the end surface of the other side L2 of the first shaft portion 43 and the valve body holding portion 46 and the bottom portion 22 of the case 20.

  FIG. 6 is a front view of the opening 29 of the case 20 as viewed from one side L1 in the axis L direction, and FIG. 7 is a perspective view of the opening 29 of the case 20 as viewed from one side L1 in the axis L direction. As shown in FIGS. 6 and 7, a rib 261 extending in the radial direction is formed on the end face on one side L <b> 1 of the partitioning convex portion 26. The rib 261 is connected to the cylindrical inner peripheral surface 27 of the body portion 21 and extends linearly from the cylindrical inner peripheral surface 27 to the inner peripheral side end surface 262 of the partitioning convex portion 26. When the fluid damper device 10 is configured, the rib 261 is crushed to a state corresponding to the gap between the end surface on one side L1 of the partitioning convex portion 26 and the first flange portion 421 of the rotating shaft 40. For this reason, the fluid 12 does not pass between the end face on the one side L1 of the partitioning convex portion 26 and the first flange portion 421 of the rotating shaft 40.

(Cover fixing structure)
As shown in FIGS. 3 and 4, the cover 60 has an annular shape as a whole, and a circular through hole 61 for passing the second shaft portion 44 of the rotor 30 is formed at the center. The cover 60 includes a bowl-shaped large-diameter portion 62 formed at one end L1 in the axis L direction, and a small-diameter portion 63 protruding from the center of the large-diameter portion 62 to the other side L2. The outer diameter of the small-diameter portion 63 is substantially constant, and an annular end surface 631 facing the other side L2 in the axis L direction is formed at the tip of the small-diameter portion 63. The large-diameter portion 62 faces the opening end surface 291 provided at the end portion on one side L1 in the axis L direction of the case 20 in the axis L direction, and covers the opening end surface 291 from the one side L1 in the axis L direction. Yes.

  As shown in FIG. 4, in the case 20, a thin portion 28 is formed at the end portion on one side L <b> 1 in the axis L direction of the body portion 21. The inner peripheral surface of the body portion 21 is provided with a cylindrical inner peripheral surface 27 on which partitioning convex portions 26 are formed, and a thin portion 28 is formed on one side L1 of the cylindrical inner peripheral surface 27 in the axis L direction. ing. A contact portion 70 is formed between the cylindrical inner peripheral surface 27 and the thin portion 28 so as to face the one side L1 in the direction of the axis L, and the inner peripheral surface of the thin portion 28 is interposed via the contact portion 70. Are connected to the cylindrical inner peripheral surface 27. The cover 60 is positioned in the direction of the axis L by bringing the annular end surface 631 of the small diameter portion 63 into contact with the contact portion 70. Further, as will be described later, the small diameter portion 63 and the thin portion 28 are welded to the cover 60 at a position different from the contact portion 70 in the circumferential direction.

As shown in FIGS. 6 and 7, a contact portion 70 is formed in a part of the circumferential direction on the inner peripheral surface of the thin portion 28. In this embodiment, the contact portions 70 are formed at four locations at equal angular intervals. The contact portion 70 extends in an arc shape in a predetermined angular range in the circumferential direction. The inner peripheral edge of the contact portion 70 is chamfered in an R shape and is connected to the cylindrical inner peripheral surface 27. Further, the outer peripheral edge of the contact portion 70 is connected to an arcuate inner peripheral surface 71 rising on one side L1 in the axis L direction. The arc-shaped inner peripheral surface 71 is an inner peripheral surface of the thin portion 28 and is an arc-shaped surface centered on the central axis (axis line L) of the case 20. The cover 60 is positioned in a direction orthogonal to the axis L when the outer peripheral surface of the small-diameter portion 63 and the arc-shaped inner peripheral surface 71 abut on each other in the radial direction. The arcuate inner peripheral surface 71 is connected to an open end surface 291 that is an end surface on one side L1 of the case 20 in the axis L direction. In the opening end surface 291, a portion connected to the arcuate inner peripheral surface 71 is a wide portion 72 having a larger radial width than other portions. The opening end surface 291 of the case 20 is entirely covered from the one side L1 in the axis L direction by the large diameter portion 62 of the cover 60, including the wide portion 72. In this embodiment, the positioning of the cover 60 and the case 20 in the axis L direction is performed at a portion where the contact portion 70 and the small diameter portion 63 abut. Therefore, the opening end surface 291 and the large diameter portion 62 of the case 20 are not in contact with each other in the direction of the axis L, and are opposed to each other with a gap.

  The contact portions 70 are arranged at an angular interval of 90 ° with reference to the axis L that is the center of the cylindrical inner peripheral surface 27. Further, the contact portion 70 is formed at a circumferential position corresponding to the partition convex portion 26. As shown in FIG. 6, among the four degree portions 70, the two degree portions 70 that are 180 degrees apart have the center in the circumferential direction coincident with the center in the circumferential direction of the partitioning convex portion 26. A rib 261 is formed at the center in the circumferential direction of the partitioning convex portion 26. Therefore, the center in the circumferential direction of the two contact portions 70 coincides with the angular position of the rib 261. By providing the contact portion 70 at the angular position of the rib 261, the cover 60 is positioned in the axis L direction at the angular position of the rib 261. That is, the positional accuracy of the cover 60 in the axis L direction is improved at the angular position of the rib 261. Thereby, the sealing accuracy of the damper chamber 11 is improved.

  As shown in FIGS. 6 and 7, the inner peripheral surface of the thin portion 28 is a recess in which a region between the contact portions 70 adjacent to each other in the circumferential direction is recessed in the radially outer side and the other side L2 in the axis L direction. 73 is formed. In this embodiment, four concave portions 73 are formed on the inner peripheral surface of the thin portion 28 at equal angular intervals. The inner circumferential surface of the recess 73 includes an arcuate inner circumferential surface 74 facing radially inward, a pair of side end surfaces 75 rising radially inward from both circumferential sides of the arcuate inner circumferential surface 74, and an arcuate inner circumferential surface 74 and an arc-shaped stepped surface 76 connected to the edge of the other side L2 of the side end surface 75 in the axis L direction. The recess 73 is recessed from the contact portion 70 to the position on the other side L2 in the axis L direction. Therefore, the arc-shaped step surface 76 is located on the other side L2 in the axis L direction from the contact portion 70. The arc-shaped step surface 76 is a flat surface facing the one side L1 in the axis L direction, and is located on the other side L2 in the axis L direction with respect to the contact portion 70.

  In the four concave portions 73, welding convex portions 80 are formed, respectively. That is, welding convex portions 80 are formed at four positions at equal angular intervals on the thin-walled portion 28, and the welding convex portions 80 are formed at circumferential positions different from the contact portion 70. When the welding convex portion 80 inserts the small-diameter portion 63 of the cover 60 into the thin-walled portion 28 and ultrasonically welds, the welding convex portion 80 comes into contact with the small-diameter portion 63 and is welded, and the small-diameter portion 63 is not welded. I have. That is, the whole welding convex part 80 is not a part welded to the small diameter part 63, but a part of the welding convex part 80 is a part welded to the small diameter part 63. The welding projection 80 protrudes radially inward from the arcuate inner peripheral surface 74 and rises from the arcuate stepped surface 76 of the recess 73 to one side L1 in the axis L direction. The welding protrusion 80 extends at a predetermined height in the direction of the axis L, one end of the welding protrusion 80 in the direction of the axis L, the contact portion 70, and the direction of the axis L of the welding protrusion 80. Are arranged in the order of the axis L in this order. That is, the welding convex portion 80 is formed in a range including the position of the contact portion 70 in the axis L direction. The inner peripheral surface of the welding convex portion 80 is an arc-shaped inner peripheral surface 81 centering on the axis L, and this surface is located radially inward from the arc-shaped inner peripheral surface 74 of the contact portion 70. The radially inner portion of the welding convex portion 80 is a portion that is melted and softened when the small diameter portion 63 of the cover 60 is fixed by ultrasonic welding (integrated with the small diameter portion 63). is there.

FIG. 8 is a partial cross-sectional view showing a state where the case 20 and the cover 60 are separated. FIG. 9 is a partial cross-sectional view of a welding location of the fluid damper device 10. In FIG. 9, the welding white portion of the welding convex portion 80 is indicated by the symbol W. In this embodiment, after inserting the tip of the small-diameter portion 63 of the cover 60 into the inner peripheral side of the thin-walled portion 28 to bring the welding convex portion 80 and the small-diameter portion 63 into contact, from the outside of the case 20 and the cover 60. Then, an ultrasonic welding horn (not shown) is brought into contact with an angular position corresponding to the welding convex portion 80 to apply ultrasonic vibration, and the contact portion between the welding convex portion 80 and the small diameter portion 63 is melted and softened. Let In this state, when the cover 60 is pressed toward the case 20 and the small-diameter portion 63 is pushed into the other side L2 in the direction of the axis L, the cover 60 is pushed to a position where the annular end surface 631 of the small-diameter portion 63 contacts the contact portion 70. be able to. Thereby, the cover 60 is positioned in the direction of the axis L. When the cover 60 is positioned in the axis L direction by the contact portion 70, the second flange portion 422 of the rotary shaft 40 is moved in the axis L direction via the washer 48 by the inner peripheral portion of the annular end surface 631 of the small diameter portion 63. Is positioned. That is, the pressing amount of the cover 60 into the case 20 is controlled by the contact portion 70. Further, the height of the damper chamber 11 in the direction of the axis L is controlled by the contact portion 70.

  As shown in FIG. 9, the small diameter portion 63 and the welding convex portion 80 of the cover 60 are welded in a predetermined range in the axis L direction. Hereinafter, the welding range in the direction of the axis L is indicated by the symbol X. Further, the end on one side L1 in the axis L direction of the welding range X is defined as one side end X1, and the end on the other side L2 in the axis L direction of the welding range X is defined as the other side end X2. As shown in FIG. 9, the other side end portion X <b> 2 of the welding range X is the same height as the annular end surface 631 of the small diameter portion 63 and the same height as the contact portion 70. The welding convex portion 80 extends from the other end portion X2 of the welding range X to the other side L2 in the axis L direction. That is, the welding convex portion 80 is formed in a range including the position in the axis L direction of the other side end portion X2 of the welding range X.

  Moreover, the welding convex part 80 is extended from the one side edge part X1 of the welding range X to the one side L1 of the axis line L direction. A taper surface 82 connected to the arcuate inner peripheral surface 81 and an arcuate end surface 83 extending radially outward from the taper surface 82 are formed at one end of the welding projection 80 in the axis L direction. The taper surface 82 is inclined in the direction toward the radially outer side as it goes toward the one side L1 in the axis L direction. As shown in FIG. 9, the one end X <b> 1 of the welding range X is an intermediate position in the direction of the axis L of the tapered surface 82. The arc-shaped end surface 83 is a flat surface facing the one side L1 in the axis L direction, and is provided at a position one step lower than the opening end surface 291 of the case 20 on the other side L2 in the axis L direction. The arc-shaped end surface 83 is connected to a midway position in the direction of the axis L of the arc-shaped inner peripheral surface 74 of the recess 73. That is, a step portion is formed by the arc-shaped end surface 83 and the arc-shaped inner peripheral surface 74 at the end portion on the one side L1 in the axis L direction of the welding convex portion 80.

(Outflow prevention department and outflow regulation department)
The case 20 of this embodiment is provided with an outflow prevention portion 90 for holding a molten resin (melted material) melted and softened by ultrasonic vibration at a position adjacent to the welding convex portion 80. When the molten resin (molten material) protrudes, the outflow prevention unit 90 functions as a welding burr pool that accommodates the molten resin (molten material). The outflow prevention unit 90 may hold the molten resin (molten material) or may remain as a space without overflowing the molten resin (molten material). The case 20 has an outflow restricting portion 95 for restricting the molten resin from flowing out to the O-ring 49 side that seals the damper chamber 11 on the other side L2 of the outflow preventing portion 90 in the axis L direction. Is provided. Specifically, the arc-shaped step surface 76 of the concave portion 73 in which the welding convex portion 80 is formed functions as the outflow restricting portion 95. Since the arc-shaped step surface 76 (outflow restricting portion 95) is provided between the welding convex portion 80 and the O-ring 49, the molten resin (melting material) protruding from the welding convex portion 80 is the O-ring 49. Regulate reaching. In addition, although the R-shaped chamfered part is provided in the inner periphery of the circular arc-shaped step surface 76, the outflow control part 95 shall also include this chamfered part.

In this embodiment, as the outflow prevention portion 90, first outflow prevention portions 91L and 91R are provided at positions adjacent to the welding convex portion 80 in the circumferential direction. As shown in FIG. 7, the first outflow prevention portion 91L
, 91R are groove-like gaps provided on both sides of the welding projection 80 in the circumferential direction. The first outflow prevention portions 91 </ b> L and 91 </ b> R are provided between the welding convex portion 80 and the side end surface 75 of the concave portion 73. The first outflow prevention portions 91L and 91R are continuous in the direction of the axis L in the range from the opening end surface 291 provided at the end on one side L1 of the case 20 in the direction of the axis L to the arc-shaped stepped surface 76 of the recess 73. Is provided.

  Moreover, as shown in FIG. 9, as another outflow prevention portion 90, a second outflow prevention portion 92 provided on the radially inner side of the other side L2 portion of the welding convex portion 80 in the axis L direction, and welding A third outflow prevention portion 93 provided on one side L1 of the convex portion 80 in the axis L direction is formed. The arcuate inner peripheral surface 81 of the welding convex portion 80 is provided at a position retracted radially outward from the cylindrical inner peripheral surface 27 of the case 20. For this reason, on the other side L2 in the axis L direction from the welding range X, on the radially inner side of the welding convex portion 80, between the arcuate inner peripheral surface 81 and the flange portion 42 of the rotary shaft 40, the radial direction. A second outflow prevention portion 92 that is a gap is formed.

  Both ends in the circumferential direction of the second outflow prevention part 92 are connected to the first outflow prevention parts 91L and 91R described above, and the other side in the axis L direction of the first outflow prevention parts 91L and 91R and the second outflow prevention part 92. L2 is provided with an arc-shaped step surface 76 (outflow restricting portion 95). When the molten resin (melted material) melted and softened at the time of ultrasonic welding protrudes to both sides in the circumferential direction of the welding convex portion 80, it is held by the first outflow prevention portions 91L and 91R. Similarly, when the molten resin (molten material) melted and softened during ultrasonic welding protrudes radially inward of the welding convex portion 80 on the other side L2 of the small diameter portion 63 of the cover 60 in the axis L direction, It is held by the second outflow prevention unit 92. The molten resin (melted material) held in the first outflow prevention portions 91L and 91R and the second outflow prevention portion 92 is on the other side in the axis L direction of the first outflow prevention portions 91L and 91R and the second outflow prevention portion 92. The provided arc-shaped step surface 76 (outflow restricting portion 95) is held so as not to protrude to the position of the O-ring 49. Therefore, there is little possibility that the O-ring 49 is deformed by the molten resin (molten material).

  The third outflow prevention portion 93 is located above the outer peripheral surface of the small diameter portion 63 of the cover 60 and the concave portion 73 of the case 20 above the arcuate end surface 83 provided on one side L1 of the welding projection 80 in the axis L direction. It is a radial gap provided between the arcuate inner peripheral surface 74. When the molten resin (molten material) melted and softened during ultrasonic welding protrudes to one side of the welding projection 80 in the axis L direction, it is held by the third outflow prevention portion 93. As described above, the stepped portion is provided between the opening end surface 291 of the case 20 and the welding convex portion 80 to secure the third outflow prevention portion 93, whereby the opening end surface 291 of the case 20 and the large diameter portion of the cover 60. It is possible to prevent the molten resin (molten material) from protruding to the outside from the gap with 62, and to prevent the molten resin (molten material) from protruding to the outside of the case 20 and the cover 60 to form a welding burr. .

  The opening end surface 291 of the case 20 is covered by the large diameter portion 62 of the cover 60 from the one side L1 in the axis L direction. Further, the third outflow prevention portion 93 provided on the inner peripheral side of the opening end surface 291 and the first outflow prevention portions 91L and 91R provided on both sides in the circumferential direction are also axis L by the large diameter portion 62 of the cover 60. Covered from one side L1 in the direction. That is, the large diameter portion 62 functions as a blind plate that covers the first outflow prevention portions 91L and 91R and the third outflow prevention portion 93. Further, as described above, the large diameter portion 62 of the cover 60 is not in contact with the opening end surface 291 of the case 20, and between the opening end surface 291 of the case 20 and the large diameter portion 62 of the cover 60, A gap is formed so that the molten resin can protrude into a minute amount.

Here, in FIG. 9, the radial position of the sealing position by the O-ring 49 (that is, the position where the O-ring 49 abuts on the cylindrical inner peripheral surface 27 of the case 20) is denoted by reference numeral A <b> 1. The radial position of the arcuate inner peripheral surface 81 is denoted by reference symbol A2, the radial position of the outer peripheral surface of the small diameter portion 63 is denoted by reference symbol A3, and the radial position of the arcuate inner peripheral surface 74 of the recess 73 is denoted by reference symbol A4. As shown, the radial positions A1, A2, A3, A4 are arranged in this order from the radially inner side to the radially outer side. The first outflow prevention portions 91L and 91R are gaps extending in the range from the radial position A1 to A4 on the other side L2 in the axis L direction from the other side end portion X2 of the welding range X. On one side of the axis L direction from the side end X2, there is a gap in the range from the radial position A3 to A4. The second outflow prevention part 92 is a gap in the range from the radial position A1 to A2, and the third outflow prevention part 93 is a gap in the range from the radial position A3 to A4. In this embodiment, the arc-shaped stepped surface 76 that is a plane functioning as the outflow restricting portion 95 is formed within the range from the radial position A1 to A2 in the angular range where the second outflow preventing portion 92 is provided. . Further, the angle range in which the first outflow prevention portions 91L and 91R are provided is formed within the range from the radial position A1 to A4.

(Main effects of this form)
As described above, the fluid damper device 10 (fluid damper device) of the present embodiment has the axial line and the small diameter portion 63 of the cover 60 fixed to the opening 29 of the case 20 on the inner peripheral surface of the thin portion 28 of the case 20. A contact portion 70 that is in contact with the L direction is formed in a part of the circumferential direction. Accordingly, when the cover 60 is fixed by welding, the contact portion 70 and the contact portion 70 can be provided at different positions in the circumferential direction, so that the contact portion 70 is less likely to be deformed due to the influence of welding. For example, even if the welding height varies, if the circumferential position is shifted, deformation of the contact portion 70 due to welding can be avoided. Therefore, the cover 60 can be accurately positioned in the direction of the axis L, and the cover 60 can be appropriately fixed. As a result, the dimensional accuracy of the damper chamber 11 in the direction of the axis L can be improved, and variations in damper performance can be suppressed.

  In this embodiment, the partition convex portion 26 that partitions the damper chamber 11 in the circumferential direction is formed on the inner peripheral surface of the case 20, but the contact portion 70 is a circumferential position corresponding to the partition convex portion 26. Is formed. Therefore, it is possible to accurately position the cover 60 in the axis L direction at the position of the partitioning convex portion 26. In particular, in this embodiment, the contact portion 70 is formed in a range including the angular position of the rib 261 formed on one end face in the axis L direction of the partition convex portion 26, and the circumferential direction of the contact portion 70 A rib 261 is formed at the center. Thereby, the position of the cover 60 in the axis L direction can be accurately performed at the position of the rib 261 for improving the sealing accuracy of the damper chamber 11. Therefore, the sealing accuracy of the damper chamber 11 can be increased.

  In this embodiment, the contact portions 70 are formed at four equiangular intervals with reference to the axis L that is the center of the case 20 in the radial direction, and two of these four locations are arranged on the opposite side in the radial direction. Is formed in a range including the angular position of the rib 261 of the partitioning convex portion 26. That is, since the contact portion 70 is formed evenly in the circumferential direction, the cover 60 can be accurately positioned in the axis L direction, and the inclination of the cover 60 can be suppressed. Further, since the case 20 and the cover 60 can be welded at a position where the contact portion 70 is not provided, the welded portion can be provided evenly in the circumferential direction. Therefore, it is possible to provide the welded portion with a good balance in the circumferential direction.

In addition, the contact portion 70 and the welding convex portion 80 can be provided not in four places but in three places or two places. Also, five or more locations can be provided. In any case, it is desirable to provide them at equiangular intervals, but arrangements other than equiangular intervals may be used. For example, when two places are provided, they may be on the opposite side with respect to the radial center of the case 20, and a predetermined angle from two places on the straight line extending in the diameter direction of the case (that is, two places 180 ° apart). It may be shifted. Further, when three places are provided, two of the three places and the remaining one place can be arranged on the opposite side with respect to the radial center of the case 20. For example, the contact portions 70 can be arranged at three locations that are the positions of the vertices of an isosceles triangle. Further, when four places are provided, two of the first straight line and the second straight line extending in the diameter direction of the case 20 and intersecting each other on the opposite side with respect to the center of the case 20 in the radial direction on the first straight line. It can be provided at a total of four locations including two locations on the second straight line with reference to the radial center of the case 20 on the second straight line. In this case, it is desirable that the two locations on the first straight line overlap with the rib 261. Moreover, it is desirable to provide the contact portion 70 and the welding convex portion 80 at different positions in the circumferential direction.

  The cover 60 of this embodiment includes a small diameter portion 63 inserted into the end portion (thin wall portion 28) of the case 20 and a large diameter portion 62 having a larger diameter than the small diameter portion 63, and the small diameter portion 63 is inserted into the case 20. Then, it is positioned in a direction perpendicular to the direction of the axis L by an arcuate inner circumferential surface 71 formed at a circumferential position different from the welding convex portion 80. Therefore, the cover 60 and the case 20 can be positioned coaxially at a circumferential position different from the welding location. Further, the large-diameter portion 62 of the cover 60 includes the opening end surface 291 of the case 20 and the first outflow prevention portions 91L and 91R and the third outflow prevention portion 93 formed on the inner peripheral side thereof from one side in the axis L direction. Covering. Therefore, since the molten resin that has protruded from the first outflow prevention portions 91L and 91R and the third outflow prevention portion 93 is not directly visible from the outside, the appearance is good. Further, even if the molten resin protrudes from the first outflow prevention portions 91L and 91R and the third outflow prevention portion 93 and a welding burr is formed, the welding burr is covered with the large diameter portion 62 and is not directly visible. There is little risk of increasing the number of steps for removing weld burrs. Furthermore, since the large diameter portion 62 is not in contact with the opening end surface 291, there is little possibility that a situation such as the cover 60 being pushed up by the molten resin that protrudes will occur. Therefore, there is little possibility that the position accuracy of the cover 60 in the direction of the axis L is lowered.

  In this embodiment, the welding convex portion 80 welded to the cover 60 is formed on the inner peripheral surface of the case 20 at a circumferential position different from the contact portion 70, and the welding convex portion 80 corresponds to the contact portion 70. It is formed in a range including the position in the axis L direction. If the welding convex portion 80 and the contact portion 70 are formed at different circumferential positions, the welding height is a range including the position in the axis L direction of the contact portion 70 (the height in the axis L direction). There is little possibility that the contact portion 70 is deformed. Therefore, the positioning of the cover 60 with respect to the case 20 in the axis L direction can be performed with high accuracy. Further, the size of the fluid damper device 10 in the direction of the axis L can be reduced as compared with the case where the welding convex portion 80 and the contact portion 70 are provided by being shifted in the direction of the axis L.

  In this embodiment, the welding projection 80 has a shape including an arcuate inner peripheral surface 81 centering on the axis L that is the rotation center of the rotor 30. Therefore, the small diameter part 63 and the welding convex part 80 of the cover 60 can be made to contact equally in the circumferential direction, and can be made to weld uniformly in the circumferential direction.

  In this embodiment, an outflow prevention portion 90 that can hold the molten resin protruding from the welding range is provided at a position adjacent to the welding convex portion 80 and radially inward from the inner peripheral surface of the case 20. Specifically, first outflow prevention portions 91L and 91R are provided at positions adjacent to the welding convex portion 80 in the circumferential direction. Further, a second outflow prevention portion 92 is provided on the other side L2 in the axis L direction from the welding range X and radially inward from the arcuate inner peripheral surface 81 of the welding convex portion 80. Further, a third outflow prevention part 93 is provided on one side in the axis L direction from the welding range X. Therefore, the molten resin that protrudes from the welding range can be held, and there is little possibility that the molten resin protrudes outside the case 20 and the cover 60 to form a welding burr. Therefore, there is little possibility that the process of removing the welding burr will increase.

  In this embodiment, the outflow restricting portion 95 is provided on the other side L2 of the outflow preventing portion 90 in the axis L direction. For example, an arc-shaped step surface 76 that functions as the outflow restricting portion 95 is provided on the other side L2 in the axis L direction of the first outflow preventing portions 91L and 91R and the second outflow preventing portion 92. The outflow restricting portion 95 (arc-shaped stepped surface 76) is provided on one side L1 in the axis L direction from the O-ring 49. Therefore, it is possible to reduce the possibility that the molten material reaches the O-ring 49 and reduces the sealing performance of the damper chamber 11.

DESCRIPTION OF SYMBOLS 1 ... Western-style toilet (equipment with a damper), 2 ... Toilet body (equipment main body), 3 ... Water tank, 5 ... Toilet seat (opening / closing member), 6 ... Toilet lid (opening / closing member), 7 ... Unit cover, 10 ... Fluid damper Device, 10a ... Fluid damper device main body, 10b ... Connecting shaft, 11 ... Damper chamber, 12 ... Fluid, 20 ... Case, 21 ... Body, 22 ... Bottom, 24 ... Recess, 26 ... Partition convex, 27 ... Cylindrical Inner peripheral surface, 28 ... thin part, 29 ... opening, 30 ... rotor, 40 ... rotating shaft, 41 ... shaft part, 42 ... flange part, 43 ... first shaft part, 44 ... second shaft part, 46 ... Valve body holding portion, 48 ... washer, 49 ... O-ring (sealing member), 50 ... valve body, 51 ... base portion, 52 ... tip portion, 60 ... cover, 61 ... through hole, 62 ... large diameter portion, 63 ... Small diameter portion, 70 ... contact portion, 71 ... arc-shaped inner peripheral surface, 72 ... wide portion, 73 ... concave portion, 74 ... Arc-shaped inner peripheral surface, 75 ... side end surface, 76 ... arc-shaped step surface, 80 ... welding convex portion, 81 ... arc-shaped inner peripheral surface, 82 ... tapered surface, 83 ... arc-shaped end surface, 90 ... outflow prevention portion, 91L 91R ... first outflow prevention part, 92 ... second outflow prevention part, 93 ... third outflow prevention part, 95 ... outflow restriction part, 100 ... Western toilet unit, 261 ... rib, 262 ... inner peripheral side end face, 291 ... Open end surface, 421 ... first flange portion, 422 ... third flange portion, 423 ... circumferential groove, 461 ... valve element holding groove, 462 ... first convex portion, 463 ... second convex portion, 631 ... annular end surface, L ... Axis, L1... One side, L2... The other side, W .. welding sill, X .. welding range, X1 .. one end of welding range, X2.

Claims (21)

A bottomed cylindrical case that opens on one side in the axial direction;
A rotor including a rotating shaft and a valve body inserted into a damper chamber formed in the case;
Fluid filled into the damper chamber;
A cover provided with a through hole through which the rotor passes, and fixed to the opening of the case;
A sealing member that seals a gap between the outer peripheral surface of the rotor and the inner peripheral surface of the case;
The fluid damper device according to claim 1, wherein a contact portion that is in contact with the cover in the axial direction is formed in a part of the circumferential direction on the inner peripheral surface of the case. On the inner peripheral surface of the case, a partition convex portion that partitions the damper chamber in the circumferential direction is formed,
The fluid damper device according to claim 1, wherein the contact portion is formed at a circumferential position corresponding to the partitioning convex portion. A rib extending in the radial direction is formed on one end face in the axial direction of the partitioning convex portion,
The fluid damper device according to claim 2, wherein the contact portion is formed in a range including an angular position of the rib.   4. The fluid damper device according to claim 1, wherein the contact portion is formed at two locations on the opposite side with respect to a center in a radial direction of the case. 5.   5. The contact portion is formed in two places on a straight line extending in the diameter direction of the case and on the opposite side with respect to the center in the radial direction of the case. The fluid damper device described. The contact portion is formed at three locations separated in the circumferential direction,
The two of the three locations are arranged on the opposite side of the remaining one of the three locations with reference to the radial center of the case. The fluid damper device according to any one of the above.   The fluid damper device according to claim 6, wherein the contact portion is formed at three equiangular intervals with a radial center of the case as a reference. The contact portion is formed at four locations separated in the circumferential direction,
Two of the four locations are two on the first straight line extending in the diametrical direction of the case on the opposite side with respect to the radial center of the case, and the rib and the axial direction It is a position that overlaps with
The remaining two of the four locations extend in the diametrical direction of the case, and are on the opposite side with respect to the radial center of the case on a second straight line that intersects the first straight line. The fluid damper device according to claim 3, wherein there are two locations.   9. The fluid damper device according to claim 8, wherein the contact portion is formed at four equiangular intervals with reference to a radial center of the case. On the inner peripheral surface of the case, a welding convex portion to be welded to the cover is formed at a circumferential position different from the contact portion,
The welding convex portion extends in the axial direction,
The one end of the welding projection in the axial direction, the contact portion, and the other end of the welding projection in the axial direction are arranged in this order in the axial direction. The fluid damper device according to any one of 1 to 9.   The fluid damper device according to claim 10, wherein an inner peripheral surface of the welding convex portion has an arc shape centering on a rotation center of the rotor. The cover includes a small diameter portion to be inserted into the case,
The case is provided with an arcuate inner circumferential surface centered on the rotation center of the rotor at a circumferential position different from the welding convex portion,
The fluid damper device according to claim 10 or 11, wherein the small-diameter portion is positioned in a direction orthogonal to the axial direction by the arc-shaped inner peripheral surface.   The flow-out prevention part is provided in the radial direction inner side from the inner peripheral surface of the said case in at least one part of the position adjacent to the said welding convex part, It is any one of Claim 10 to 12 characterized by the above-mentioned. The fluid damper device described.   The fluid damper device according to claim 13, wherein the outflow prevention portion is provided at a position adjacent to at least the welding convex portion in the circumferential direction. The case and the cover are welded in a predetermined range in the axial direction,
The fluid damper according to claim 13 or 14, wherein an outflow restricting portion located on the other side in the axial direction of the outflow preventing portion is provided on the other side in the axial direction from the predetermined range. apparatus.   The outflow prevention portion is provided continuously from the end portion on one side in the axial direction of the case to the outflow restriction portion at a position adjacent to the welding convex portion in the circumferential direction. The fluid damper device according to claim 15.   The said outflow prevention part is provided in the radial direction inner side from the inner peripheral surface of the said welding convex part in the other side of the said axial direction of the said predetermined range, The Claim 15 or 16 characterized by the above-mentioned. Fluid damper device.   The fluid damper device according to any one of claims 15 to 17, wherein the outflow restricting portion is provided on one side in the axial direction from the sealing member.   The fluid damper device according to any one of claims 15 to 18, wherein the outflow prevention portion is provided on one side of the predetermined range in the axial direction. A damper-equipped device comprising the fluid damper device according to any one of claims 1 to 19,
A damper-equipped device, wherein an opening / closing member that is rotationally moved with respect to the device main body is attached to the rotating shaft.   The apparatus with a damper according to claim 20, wherein the opening / closing member is a toilet seat of a Western-style toilet.

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