JP6560958B2 - Concrete mass for damping damper and damping damper - Google Patents

Description

  The present invention relates to a concrete mass for damping damper and a damping damper.

Patent Document 1 describes a leaf spring vibration damping device (vibration damper) having an iron ingot mass. The mass is fixed to the free end of the leaf spring with a bolt.
Patent Document 2 describes a vibration damper having a concrete mass. The concrete mass is sandwiched between the flange portion of the member fixed to the spring element and the mounting plate by bolts.

Japanese Patent No. 5386209 Japanese Patent No. 4389098

The mass of the iron ingot has a good initial design, but the material cost is high. Further, the mass of the iron ingot is deteriorated in design due to rusting with the passage of time, so that painting and plating are required.
In addition, concrete mass generally has pores by mixing material with air as a measure for preventing frost damage. Therefore, the concrete mass is not good in design. In order to prevent the concrete mass from being exposed, it is conceivable to cover it separately with a case. However, the case is expensive.

  An object of the present invention is to provide a concrete mass for a damping damper and a damping damper that are inexpensive and have good design properties.

  The damping damper concrete mass is a resin case having a housing space, a bolt fastened at one end to a spring element of the damping damper, the bolt supported on the inner surface of the housing space, and the housing space. A concrete mass main body that is filled in a site, embeds a part of the bolt, and is integrally connected to the resin case via the bolt.

  The resin case functions as a case that covers the surface of the concrete mass body to improve the design, and also functions as a mold for molding the concrete mass body. Therefore, the design of the mass is improved by the resin case. Furthermore, since the molding mold itself is used as a resin case, it is not necessary to remove the mass body from the molding mold and it is not necessary to attach it to another case. Therefore, the manufacturing cost is low.

  Here, the resin case, the bolt, and the mass body need to be connected. In a conventional concrete mass, individual members are individually molded and then connected by bolts. However, in the concrete mass according to the present invention, bolts are embedded when the concrete mass body is molded with a resin case. Therefore, the resin case, the mass body, and the bolt are connected (integrated) simultaneously with the molding of the mass body. That is, the manufacturing cost is reduced by reducing the number of manufacturing steps.

  The vibration damping damper includes a spring element attached to a vibration damping object and the above-described concrete mass for the damping damper attached to a portion of the spring element that vibrates with respect to the vibration damping object. As a result, the vibration damper has a good design and is inexpensive.

It is a longitudinal cross-sectional view of the damping damper of this embodiment, Comprising: It is F1-F1 sectional drawing of FIG. It is the figure which looked at the damping damper of FIG. 1 from the downward direction. It is the figure which looked at the damping damper of FIG. 1 from F3 direction. It is an expansion perspective view of the concrete mass which comprises the damping damper of FIG. It is a perspective view of the remaining part except the mass main body among the concrete masses of FIG. It is a top view of a concrete mass. It is F7-F7 sectional drawing of FIG. It is F8-F8 sectional drawing of FIG. It is F9-F9 sectional drawing of FIG.

(1. Configuration of damping damper 1)
The vibration damper 1 of this embodiment will be described with reference to FIGS. The damping damper 1 will be described by taking a leaf spring damping damper as an example. However, the concrete mass for damping damper of the present invention can be applied to other damping dampers of leaf spring type damping damper.

  The vibration damper 1 is a device that is fixed to, for example, the floor of the upper floor of a house and reduces out-of-plane vibration generated in the flooring 2. That is, when the flooring 2 vibrates in the out-of-plane vibration direction, the vibration damper 1 reduces the out-of-plane vibration of the flooring 2.

  The vibration damper 1 includes a leaf spring member 10, a concrete mass 20, a viscoelastic body 30, a mass fixing nut 40, and a floor fixing bolt 50. That is, the vibration damper 1 is a dynamic vibration absorber that uses a composite spring of the leaf spring member 10 and the viscoelastic body 30 as a spring element. When the concrete mass 20 vibrates in the out-of-plane vibration direction of the flooring 2, the out-of-plane vibration of the flooring 2 is reduced.

  The leaf spring member 10 is cantilevered by the floor material 2 to be controlled, and vibrates the free end side in the out-of-plane vibration direction of the floor material 2 (the normal direction of the floor material 2) with respect to the floor material 2. . That is, the free end side of the leaf spring member 10 is a portion that vibrates with respect to the flooring 2 that is a vibration suppression target. The leaf spring member 10 is formed in a long shape, and has one end side as a portion fixed to the flooring 2 and the other end side as a free end side as a portion fixing the concrete mass 20. That is, the concrete mass 20 is attached to a portion that vibrates with respect to the floor material 2 as a vibration suppression target in the leaf spring member 10. Here, the leaf spring member 10 is formed by punching and pressing a flat steel plate. In the present embodiment, the plate spring member 10 is formed by punching and pressing a steel plate. However, a simple flat plate may be used as the plate spring member 10.

  The leaf spring member 10 includes a base portion 11, an inclined portion 12, a parallel portion 13, a pair of standing wall portions 14 and 14, and a pair of flange portions 15 and 15. The leaf spring member 10 is formed symmetrically with respect to the center plane in the width direction (direction perpendicular to the longitudinal direction).

  The base 11 is a part formed in a rectangular flat plate shape, and is fixed in a state where it is in contact with the back surface of the flooring 2. The base 11 is located on the base end side (the side opposite to the free end) of the leaf spring member 10. A plurality of through holes 11 a are formed in the base 11. The floor fixing bolt 50 is screwed to the floor material 2 in a state where the floor fixing bolt 50 is inserted into the through hole 11a. The floor fixing bolt 50 is not limited to the case where the floor fixing bolt 50 is screwed to the floor material 2, and may be fastened to the floor material 2.

  The inclined portion 12 is formed in a trapezoidal flat plate shape, is continuous with the base portion 11 in the longitudinal direction of the leaf spring member 10, and is inclined with respect to the flooring 2. That is, it leaves | separates from the flooring 2 as it goes to the opposite side from the base 11 side of the inclination part 12. As shown in FIG. The trapezoidal parallel short side in the inclined portion 12 is bent with respect to the base portion 11 in a state where it is connected to the base portion 11.

  The parallel part 13 is formed in a rectangular flat plate shape, and is continuous in the longitudinal direction of the leaf spring member 10 with respect to a part (a trapezoidal parallel long side) opposite to the base part 11 of the inclined part 12. The parallel portion 13 is located substantially parallel to the flooring 2 and is bent with respect to the inclined portion 12. The length of the parallel portion 13 in the longitudinal direction can be appropriately changed according to the frequency of the vibration control target.

  A gourd-type through hole 13 a is formed in the parallel portion 13. A viscoelastic body 30 is detachably attached to the gourd-type through hole 13a. The formation position of the gourd-type through-hole 13a can be appropriately changed according to the frequency to be suppressed.

  The pair of standing wall portions 14 and 14 are erected in a rib shape from the respective ends in the width direction of the base portion 11, the inclined portion 12, and the parallel portion 13 in a direction away from the flooring 2. In the pair of standing wall portions 14, 14, end portions on the side far from the floor material 2 are linear and are formed substantially parallel to the floor material 2. That is, the height of the pair of standing wall portions 14 and 14 is high on the base 11 side and low on the parallel portion 13 side.

  A pair of flange parts 15 and 15 are formed so that it may extend outside in the width direction from each edge part (end part far from flooring 2) of a pair of standing wall parts 14 and 14 in the width direction. . The pair of flange portions 15 and 15 are formed in a substantially planar shape. Circular through holes 15 a and 15 a are formed on the free end sides of the pair of flange portions 15 and 15.

  The concrete mass 20 is fixed to the free end side of the leaf spring member 10. Specifically, the concrete mass 20 is fixed to the formation site of the through holes 15 a and 15 a of the pair of flange portions 15 and 15 by the mass fixing nut 40. The concrete mass 20 vibrates in the out-of-plane vibration direction with respect to the flooring 2 with the vibration on the free end side of the leaf spring member 10. The concrete mass 20 is formed into a certain mass so as to have a predetermined mass. In the present embodiment, the concrete mass 20 includes a concrete mass main body 24, and the mass main body 24 is accommodated in the resin case 21.

  The viscoelastic body 30 is formed of an elastomer made of a rubber material or a resin material having rubber-like elasticity. The viscoelastic body 30 is fixed to the parallel portion 13 and strikes the back surface of the flooring 2 when the flooring 2 vibrates in the out-of-plane vibration direction. Specifically, the viscoelastic body 30 includes a main body portion 31 and an engagement portion 32.

  The main body 31 is formed in an inverted truncated cone shape. The small diameter end face of the main body 31 is located on the flooring 2 side. The engaging part 32 is provided on the large-diameter end face of the main body part 31 and is formed in a mushroom shape. The engaging portion 32 engages in a state where the engaging portion 32 is inserted into the gourd-type through hole 13 a of the parallel portion 13 of the leaf spring member 10.

  In the initial state where the viscoelastic body 30 is fixed to the leaf spring member 10, the main body 31 may be in a state where a slight preload is applied to the flooring 2, or the flooring 2 and the main body 31 are so-called. A zero touch state (a state in which no pressure is applied) may be used, or a slight gap may be provided between the floor material 2 and the floor material 2. These can be appropriately changed according to the purpose of vibration control.

(2. Detailed configuration of concrete mass 20)
A detailed configuration of the concrete mass 20 will be described with reference to FIGS. As shown in FIGS. 4 and 5, the concrete mass 20 includes a resin case 21, a bolt 22, a support member 23, and a mass body 24.

  As shown in FIGS. 5 to 9, the resin case 21 is formed in a cup shape having an accommodation space 21 a with a thermoplastic resin. That is, the resin case 21 has a bottom portion 21b and an outer peripheral portion 21c formed with a predetermined plate thickness, and further has an opening portion 21d. The resin case 21 is formed in a substantially rectangular parallelepiped shape with rounded corners.

  The resin case 21 further includes a concave engagement portion 21e that stands up toward the opening 21d side at the center on the inner surface side of the bottom portion 21b. The concave engaging portion 21e includes a pair of locking claws that function as an elastic clip, and has a facing space between the pair of locking claws. That is, the pair of locking claws are elastically deformed so that the front end side can be expanded.

  The resin case 21 further includes a plurality (two in this embodiment) of annular holding portions 21f that are provided on the inner surface side of the bottom portion 21b and are erected toward the opening portion 21d. The plurality of annular holding portions 21f are provided at positions separated by a predetermined distance across the concave engaging portion 21e. The plurality of annular holding portions 21f include a circular hole at the center that extends toward the opening 21d. The annular holding portion 21f includes a plurality of ribs on the outer peripheral side. The plurality of ribs exhibit a function of preventing the annular holding portion 21f from falling down.

  Each of the plurality of bolts 22 is made of metal and fastened to the leaf spring member 10 as a spring element. Furthermore, the some volt | bolt 22 is supported by the inner surface of the accommodation space 21a of the resin case 21, as shown in FIGS. The bolt 22 includes a bolt portion 22a, a tip shaft portion 22b, an intermediate shaft portion 22c, a first flange 22d, and a second flange 22e.

  The bolt part 22 a is located at one end of the bolt 22 and protrudes outward from the opening 21 d of the resin case 21. The bolt portion 22a is screwed into the mass fixing nut 40 while being inserted into the through holes 15a, 15a of the pair of flange portions 15, 15 of the leaf spring member 10. The tip shaft portion 22 b is located at the other end of the bolt 22 and is inserted into the circular hole of the annular holding portion 21 f of the resin case 21. The bolt 22 is positioned with respect to the resin case 21 by the tip shaft portion 22b being inserted into the annular holding portion 21f. The intermediate shaft portion 22c is located between the bolt portion 22a and the tip shaft portion 22b. The intermediate shaft portion 22c is a portion that is held by a support member 23 described later.

  The first flange 22d is formed in a disk shape, is provided between the bolt portion 22a and the intermediate shaft portion 22c, and projects radially outward from the outer peripheral surfaces of the bolt portion 22a and the intermediate shaft portion 22c. The bolt 22 is fixed to the leaf spring member 10 by sandwiching the first flange 22d and the mass fixing nut 40 between the pair of flange portions 15 and 15 of the leaf spring member 10. The first flange 22 d is located outward from the opening 21 d of the resin case 21.

  The second flange 22e is formed in a disc shape, is provided between the tip shaft portion 22b and the intermediate shaft portion 22c, and projects radially outward from the outer peripheral surfaces of the tip shaft portion 22b and the intermediate shaft portion 22c. The second flange 22e is disposed in contact with the end surface of the annular holding portion 21f of the resin case 21. Further, the second flange 22e protrudes radially outward from the outer peripheral edge of the end surface of the annular holding portion 21f.

  The support member 23 is formed of a thermoplastic resin and is fixed to the inner surface of the resin case 21. Further, the support member 23 holds the plurality of bolts 22 and maintains the relative posture of the plurality of bolts. As shown in FIGS. 5 to 9, the support member 23 includes a plate-like main body portion 23 a, convex engagement portions 23 b, a plurality of ribs 23 c, and a plurality of elastic clips 23 d.

  The plate-like main body portion 23 a is erected on the inner surface of the bottom portion 21 b of the resin case 21. The plate-like main body 23a includes notches 23a1 to 23a4 at the corners on both sides on the bottom 21b side of the resin case 21 and the side edges on both sides.

  The convex engaging portion 23b is provided on the bottom portion 21b side of the resin case 21 of the plate-like main body portion 23a, and engages with the concave engaging portion 21e. The support member 23 is fixed to the resin case 21 by the convex engagement portion 23b being elastically engaged with the concave engagement portion 21e. The convex engagement portion 23b is formed in a columnar shape or a prismatic shape close to the columnar shape so as to be easily attached to the concave engagement portion 21e as an elastic clip.

  In the present embodiment, the resin case 21 is provided with the concave engagement portion 21e and the support member 23 is provided with the convex engagement portion 23b. However, the resin case 21 is provided with the convex engagement portion and is supported. The member 23 may be provided with a concave engaging portion.

  The plurality of ribs 23c are formed to protrude from both surfaces of the plate-like main body portion 23a. The plurality of ribs 23c are formed in a lattice shape. That is, the plurality of ribs 23 c include a portion that extends in the direction from the bottom 21 b of the resin case 21 toward the opening 21 d and a portion that extends in a direction parallel to the bottom 21 b of the resin case 21. And the site | part extended in the direction parallel to the bottom part 21b among several ribs 23c protrudes in the direction orthogonal to the opening direction of the resin case 21. As shown in FIG.

  The plurality of elastic clips 23d are formed in a C shape and are provided on both side edges of the plate-like main body portion 23a. The plurality of elastic clips 23d are provided on the bottom portion 21b side and the opening portion 21d side of the cutout portions 23a3 and 23a4 on the side of the plate-like main body portion 23a. Two elastic clips 23 d on the same axis sandwich the intermediate shaft portion 22 c of one bolt 22. Since the plurality of elastic clips 23d sandwich the plurality of bolts 22, the posture of the plurality of bolts 22 can be maintained.

  Here, the two elastic clips 23 d on the same axis are provided corresponding to the distance between the first flange 22 d and the second flange 22 e of the bolt 22. Therefore, the bolt 22 is positioned with respect to the support member 23 by being clamped by the two elastic clips 23 d on the same axis. Furthermore, the bolt 22 in the direction from the bottom 21b of the resin case 21 toward the opening 21d is sandwiched between the elastic clip 23d on the bottom 21b side and the annular holding portion 21f of the resin case 21 to hold the second flange 22e. Is positioned.

  The mass body 24 is made of concrete. As shown in FIGS. 4 and 6 to 9, the mass body 24 is filled in the accommodation space 21 a of the resin case 21. The mass body 24 is formed by pouring ready-mixed concrete into the accommodation space 21a of the resin case 21 with the bolts 22 and the support members 23 attached to the resin case 21, and solidifying the ready-mixed concrete. That is, the resin case 21 is used as a mold for molding the mass body 24.

  The mass body 24 embeds a part of the bolt 22 and a part of the support member 23. The notches 23 a 1 to 23 a 4 of the support member 23 and the plurality of ribs 23 c of the support member 23 function as engagement portions that engage with the mass body 24 in the opening direction of the resin case 21. Further, the second flange 22 e of the bolt 22 also functions as an engaging portion that engages with the mass body 24 in the opening direction of the resin case 21. In this way, the mass body 24 is integrally connected to the resin case 21 via the bolt 22 and the support member 23.

  Further, the mass body 24 has a function of restricting the concave engaging portion 21e of the resin case 21 from expanding in a state where the ready-mixed concrete is solidified. Accordingly, the support member 23 is fixed to the resin case 21 by the mass body 24.

  Furthermore, the surface of the mass body 24 is positioned slightly on the bottom 21 b side from the opening 21 d of the resin case 21. Therefore, the surface of the mass body 24 is located at a position slightly away from the first flange 22 d of the bolt 22.

(3. Manufacturing method of concrete mass 20)
Next, a method for manufacturing the concrete mass 20 will be described. The plurality of bolts 22 are attached to the plurality of elastic clips 23 d of the support member 23. Subsequently, the tip shaft portion 22b of the bolt 22 is inserted into the annular holding portion 21f, and at the same time, the convex engagement portion 23b of the support member 23 is engaged with the concave engagement portion 21e of the resin case 21. In this state, the plurality of bolts 22 and the support member 23 are fixed to the resin case 21. At this time, the bolt portion 22 a of the bolt 22 is located outward from the opening portion 21 d of the resin case 21.

  Subsequently, ready-mixed concrete as a raw material of the mass body 24 is poured into the accommodation space 21 a of the resin case 21. That is, using the resin case 21 as a mold, the ready-mixed concrete is solidified and the mass body 24 is formed. As described above, the solidified mass body 24 is integrally fixed to the bolt 22, the support member 23, and the resin case 21 by engaging with the bolt 22 and the support member 23.

(4. Effect)
As described above, the concrete mass 20 used in the vibration damper 1 of the present embodiment includes the resin case 21 having the accommodation space 21a and the bolt 22 that is fastened to the spring element (10) of the vibration damper 1 at one end. Yes, a bolt 22 supported on the inner surface of the accommodation space 21 a, and a concrete that is filled in the accommodation space 21 a, embeds a part of the bolt 22, and is integrally connected to the resin case 21 via the bolt 22. The mass body 24 is provided.

  The resin case 21 functions as a case that covers the surface of the concrete mass body 24 to improve the design, and also functions as a mold for molding the concrete mass body 24. Therefore, the design of the concrete mass 20 is improved by the resin case 21. Furthermore, since the molding form itself is used as the resin case 21, it is not necessary to detach the mass body 24 from the molding form, and it is not necessary to attach it to another case. Therefore, the manufacturing cost is low.

  Here, the resin case 21, the bolt 22, and the mass body 24 need to be connected. The concrete mass 20 according to the present embodiment has bolts 22 embedded when the concrete mass body 24 is molded with the resin case 21. Accordingly, the resin case 21, the mass body 24, and the bolts 22 are connected (integrated) simultaneously with the formation of the mass body 24. That is, the manufacturing cost is reduced by reducing the number of manufacturing steps.

  The concrete mass 20 includes a plurality of bolts 22 and a support member 23 that is fixed to the inner surface of the resin case 21 and holds the plurality of bolts 22 to maintain the relative posture of the plurality of bolts 22. Thereby, the some volt | bolt 22 can be reliably positioned to a desired attitude | position. In particular, when the ready-mixed concrete that is the raw material of the mass body 24 is poured into the resin case 21, the postures of the plurality of bolts 22 can be reliably maintained. Furthermore, by making the support member 23 separate from the resin case 21, the resin case 21 itself can be easily conveyed. That is, since the inner surface of the resin case 21 does not have a protrusion corresponding to the support member 23, a plurality of resin cases 21 can be overlapped. By superimposing the plurality of resin cases 21, the total volume of the plurality of resin cases 21 in the conveyance state is reduced, and the conveyance is facilitated.

  Further, the support member 23 includes engaging portions (23 a 1 to 23 a 4, 23 c) that engage with the mass body 24 in the opening direction of the resin case 21. As a result, the engagement portion of the support member 23 and the mass body 24 engage with each other, so that the support member 23 and the mass body 24 can be reliably connected.

  For example, the support member 23 includes notches 23a1 to 23a4 as engaging portions. Thereby, an engaging part can be easily formed in the support member 23. The support member 23 protrudes in a direction orthogonal to the opening direction of the resin case 21 and includes a plurality of ribs 23c as engaging portions. Also in this case, the engaging portion can be easily formed on the support member 23.

  Further, the support member 23 has a plurality of elastic clips 23 d that sandwich the intermediate shaft portions 22 c of the plurality of bolts 22. Thereby, it becomes easy to attach the bolt 22 to the support member 23. Furthermore, by filling the mass body 24, the elastic clip 23d of the support member 23 and the intermediate shaft portion 22c of the bolt 22 are reliably connected.

  One of the resin case 21 and the support member 23 has a convex engagement portion 23b, and the other has a concave engagement portion 21e that is elastically engaged with the convex engagement portion 23b. Thereby, the support member 23 is reliably fixed to the resin case 21.

  Further, the bolt 22 includes a second flange 22 e that engages with the mass body 24 in the opening direction of the resin case 21. As a result, the bolts 22 are engaged with the mass body 24, so that the two are reliably connected together.

  The resin case 21 includes an annular holding portion 21f through which the other end of the bolt 22 is inserted. The bolt 22 is positioned with respect to the resin case 21 by the annular holding portion 21f. Therefore, when the ready-mixed concrete that is the raw material of the mass body 24 is poured into the resin case 21, the posture of the bolt 22 can be reliably maintained.

  Although the concrete mass 20 alone has the above-described effects, the damping damper 1 as a whole including the concrete mass 20 has the same effects. That is, since the damping damper 1 has the concrete mass 20 with a good design, the design properties of the damping damper 1 as a whole are good. Further, by making the concrete mass 20 alone inexpensive, the vibration damping damper 1 as a whole becomes inexpensive.

1: Damping damper, 2: Floor material, 10: Leaf spring member (spring element), 20: Concrete mass, 21: Resin case, 21a: Housing space, 21b: Bottom, 21c: Outer part, 21d: Opening 21e: concave engaging portion, 21f: annular holding portion, 22: bolt, 22a: bolt portion, 22b: tip shaft portion, 22c: intermediate shaft portion, 22d: first flange, 22e: second flange, 23: support Member, 23a: plate-shaped main body, 23a1-23a4: notch (engagement), 23b: convex engagement, 23c: rib (engagement), 23d: elastic clip, 24: mass body, 30: Viscoelastic body, 40: Mass fixing nut

Claims (10)

A resin case having a housing space;
A bolt fastened at one end to the spring element of the damping damper, and the bolt supported on the inner surface of the housing cavity;
A concrete mass body that is filled in the housing space, embeds a part of the bolt, and is integrally connected to the resin case via the bolt;
A concrete mass for vibration dampers. The concrete mass for the vibration damper is
A plurality of the bolts;
A support member fixed to the inner surface of the resin case and holding a plurality of the bolts to maintain a relative posture of the plurality of bolts;
The concrete mass for vibration dampers according to claim 1, comprising:   The said support member is a concrete mass for damping dampers of Claim 2 provided with the engaging part engaged with the said mass main body in the opening direction of the said resin case.   The said support member is a concrete mass for damping dampers of Claim 3 provided with the notch part as said engaging part.   The said support member is a concrete mass for damping dampers of Claim 3 or 4 which protrudes in the direction orthogonal to the opening direction of the said resin case, and is provided with the some rib as said engaging part.   The said support member is a concrete mass for damping dampers as described in any one of Claims 2-5 which has several elastic clip which clamps each intermediate shaft part of the said some volt | bolt.   One of the resin case and the support member has a convex engagement portion, and the other has a concave engagement portion elastically engaged with the convex engagement portion. The concrete mass for damping dampers according to one item.   The concrete mass for a vibration damper according to any one of claims 1 to 7, wherein the bolt includes a flange that engages with the mass body in an opening direction of the resin case.   The said resin case is a concrete mass for damping dampers as described in any one of Claims 1-8 provided with the cyclic | annular holding | maintenance part by which the other end of the said bolt is penetrated. A spring element to be attached to the object to be controlled;
A concrete mass for a damping damper according to any one of claims 1 to 9, which is attached to a portion that vibrates with respect to the damping object in the spring element,
A vibration damper equipped with

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