JP5404080B2 - Floor structure - Google Patents

Description

  The present invention relates to a floor structure having a double floor.

  In the floor structure, for example, a double-floor structure of an assembled floor type is known in which steel materials such as large draws and joists are horizontally passed under a floor board (floor material) (see, for example, Patent Document 1). In such a double floor structure, in order to absorb floor impact sound, for example, an asphalt sheet (sound insulation sheet) may be laid on the floor board.

Japanese Utility Model Publication No. 8-475

  However, in this conventional floor structure, a heavy asphalt sheet is laid on the entire floor surface, and workability is poor.

  In view of the above facts, an object of the present invention is to obtain a floor structure that has good floor impact sound blocking performance and can improve workability.

The floor structure of the present invention described in claim 1 includes a floor slab, a plurality of support legs supported on the floor slab, a plurality of overhangs supported on the support legs, and the large structure. A floor support member that is passed and supported on the pull, a floor material that is supported on the floor support member and is spaced from the floor slab, and is disposed inside the large pull, An elastic member that is supported by the pull and is elastically deformable, and a dynamic vibration absorber that includes a mass body that is supported by the elastic member.

  According to the floor structure of the present invention described in claim 1, the floor material is supported on the large pull through the floor support member, and the elastic member of the dynamic vibration absorber is supported on the large pull. For this reason, when vibration is applied to the floor material, this vibration is transmitted to the elastic member of the dynamic vibration absorber via the floor support member and the large pull. As a result, the elastic member of the dynamic vibration absorber is elastically deformed, and the mass body supported by the elastic member in the dynamic vibration absorber moves up and down so as to absorb vibration, so that the vibration from the floor material to the floor slab is attenuated. The Since the pull is supported on the floor slab via a plurality of support legs, the damped vibration is transmitted from the pull to the floor slab via the support legs.

In addition, since the dynamic vibration absorber is disposed inside the large pull, interference between the underfloor structure disposed between the floor slab and the floor material and the dynamic vibration absorber is avoided. For this reason, workability is good.

A floor structure according to a second aspect of the present invention is the structure according to the first aspect, wherein the large drawing is made of C-shaped steel that opens downward in the installed state, and penetrates the lower opening of the large drawing. A mounting bolt and a first receiving seat which is disposed on the upper surface side of the bottom of the large pull and fixed to an intermediate portion in the axial direction of the mounting bolt, and the elastic member is fixed to the upper surface And a nut disposed on the lower side of the large pull and screwed into a lower end portion of the mounting bolt, disposed on a lower side of the large pull, fixed to the upper surface of the nut and penetrated by the mounting bolt. And a second receiving seat for tightening the bottom portion of the large pull between the nut and the first receiving seat by screwing the nut into the lower end portion of the mounting bolt.

According to the floor structure of the present invention described in claim 2 , when attaching the dynamic vibration absorber to the large drawing, the operator can move the dynamic vibration absorber and the second vibration absorber from one end side in the longitudinal direction of the large drawing to the inside of the large drawing. After placing one receiving seat and placing the mounting bolt so that it passes through the lower opening of the large pull, move the dynamic vibration absorber, the first receiving seat and the mounting bolt to the position along the longitudinal direction of the large pull Can be made. Then, the operator screws the nut from the lower side of the large pull to the lower end of the mounting bolt and tightens the bottom of the large pull between the first receiving seat and the second receiving seat, thereby The vessel can be fixed in a large amount.

  As described above, according to the floor structure of the present invention, there is an excellent effect that the floor impact sound blocking performance is good and the workability can be improved.

Is a perspective view showing a floor structure according to the first embodiment (Reference Example) (. Shown in a transparent state the top floor material). It is a longitudinal sectional view showing a floor structure according to the first embodiment (Reference Example). It is a sectional view showing a mounted state of the dynamic vibration reducer in the floor structure according to the second embodiment (Reference Example). It is a sectional view showing a mounted state of the dynamic vibration reducer in the floor structure according to the third embodiment (reference example). It is a longitudinal sectional view showing a floor structure according to a fourth embodiment (reference example). It is an expanded sectional view of the arrow 6 direction arrow of FIG. It is a longitudinal sectional view showing a floor structure according to the fifth embodiment (Reference Example). It is an expanded sectional view of the arrow 8 direction of FIG. Sixth Embodiment is a vertical sectional view showing a floor structure according to (an embodiment of the present invention). It is an expanded sectional view of the arrow 10X direction arrow of FIG.

[First Embodiment]
A first embodiment of a floor structure will be described with reference to the drawings. The first embodiment is not an embodiment of the present invention but a reference example. In addition, an arrow UP in the figure indicates an upward direction in the floor structure.

  FIG. 1 is a perspective view of the floor structure 10 as seen through the upper floor material 14. The floor structure 10 shown in FIG. 1 is a double-floor structure of a set floor type, and can be applied to, for example, a gymnasium.

  As shown in FIG. 1, the floor structure 10 has a floor support structure 10 </ b> A (floor base structure portion) interposed between a concrete floor slab 12 serving as a frame floor and an upper floor material 14. A space is formed between the floor slab 12 and the upper floor material 14 by interposing the floor support structure 10A.

  The floor support structure 10 </ b> A includes a plurality of support legs 16 that are supported on the floor slab 12. The lower part of the support leg 16 is comprised by the metal (it is steel in this embodiment) support stand 18, and this support stand 18 is made into the substantially hat shape by the front view by which the floor slab 12 side was open | released. Yes. In the present embodiment, the lower portion of the support leg 16 is constituted by the support base 18, but the lower portion of the support leg 16 may be constituted by a columnar bundle (bundle column). The pair of flange portions 18A of the support base 18 are disposed on the floor slab 12 and fixed to the floor slab 12 by a fixing means. Further, the top wall portion 18 </ b> B of the support base 18 is penetrated by the adjustment bolt 20.

  The adjustment bolt 20 is screwed by an adjustment nut 22 that is in contact with the top wall portion 18B of the support base 18, and is supported by the support base 18 in an upright state. An upper end portion that is one end side in the axial direction of the adjustment bolt 20 is screwed by an adjustment nut 24 (see FIG. 2) and is connected to the large receiving metal fitting 26.

  The large receiving metal fitting 26 is formed in a groove shape (channel shape) in which a pair of side walls 26A face each other. A cushioning material 28 (an element grasped as an “elastic body” in a broad sense) is fixed to the bottom 26 </ b> B side inside the large receiving metal fitting 26. The cushioning material 28 is made of rubber and can be elastically deformed, so that vibration is attenuated.

  The support leg 16 includes the support base 18, the adjustment bolt 20, the adjustment nuts 22 and 24 (see FIG. 2), the large metal fitting 26, and the cushioning material 28 described above.

  Inside the large receiving metal fitting 26, a metal (in this embodiment, steel) large drawing 30 (which is an element grasped as “beam material” in a broad sense) is disposed on the cushioning material 28. ing. The large pull 30 has a rectangular tube shape with a rectangular closed cross section, and is passed horizontally on the plurality of support legs 16 (a direction parallel to the floor slab 12). In addition, the plurality of pawls 30 supported on the support legs 16 are arranged in parallel to each other with a predetermined interval.

  A joist 32 (an element grasped as a “beam material” in a broad sense) as a plurality of floor support members is handed over and supported on the large pull 30. The extending direction of the joists 32 intersects (orthogonally) with respect to the extending direction of the draw 30. The joist 32 is made of metal (in the present embodiment, made of steel) and has a substantially hat-shaped cross section, and the flange portions 32B and 32C are fixed to the large pull 30 by fixing means such as screws.

  Further, the top 32A of the joist 32 is fixed to the upper flooring 14 by a fixing means such as a screw. The upper flooring 14 is supported on the joists 32 and is arranged with a space between the upper flooring 14 and the floor slab 12. The upper floor material 14 has a laminated structure in which a flooring material 14B (single-layer flooring or composite flooring), which is a floor finishing material, is provided on the discarding plate 14A, as well as a discarding plate 14A of plywood.

  As shown in FIG. 2, a dynamic vibration absorber 34 (also referred to as “dynamic damper device”, “vibration damper”, or the like) is disposed below the large forehead 30. The dynamic vibration absorber 34 includes an elastic member 40 (damper rubber) and a mass body 42 (weight), which will be described later, and is suspended with respect to each pulling 30. In the present embodiment, the support legs 16 adjacent to each other are adjacent to each other. A plurality (three in total in the vicinity of the support legs 16 and in the central portion between the support legs 16 in this embodiment) are installed.

  As shown in the partially enlarged view of FIG. 2, a mounting plate 36 is disposed on the lower surface side of the large pull 30 for mounting the dynamic vibration absorber 34. The mounting plate 36 is fixed to the bottom 30 </ b> B of the large drawer 30 by fixing means such as a screw 37. One end portion (upper end portion) of the attachment bolt 38 in the axial direction is attached to the center portion of the attachment plate 36.

  A receiving seat 39 arranged substantially horizontally is attached to the other end (lower end) in the axial direction of the mounting bolt 38. A cylindrical elastic member 40 disposed on the outer peripheral side of the mounting bolt 38 is fixed on the receiving seat 39. Thereby, the elastic member 40 is supported by the large pull 30 via the receiving seat 39, the mounting bolt 38, the mounting plate 36, and the like. The elastic member 40 is made of rubber or the like and can be elastically deformed to attenuate vibrations.

  On the elastic member 40, the receiving member 41 penetrated by the mounting bolt 38 is disposed. The receiving member 41 includes a cylindrical portion 41A that is arranged coaxially with the mounting bolt 38 to form a cylindrical shape, and the receiving seat portion 41B is coaxially and integrally formed from one end (lower end) in the axial direction of the cylindrical portion 41A. It extends toward the outside in the direction.

  The lower surface of the receiving seat portion 41B of the receiving member 41 is fixed to the upper surface of the elastic member 40 by vulcanization adhesion or the like. In addition, a male screw portion is formed on the outer peripheral surface of the cylindrical portion 41A. A female screw portion formed on the inner peripheral surface of the insertion hole 42A at the upper center of the mass body 42 is screwed into the male screw portion of the cylindrical portion 41A, and the mass body is placed on the receiving seat portion 41B of the receiving member 41. The upper part of 42 is arrange | positioned. That is, the mass body 42 is supported by the elastic member 40 via the receiving member 41.

  The mass body 42 is made of metal (in the present embodiment, made of steel) and has a substantially bottomed cylindrical shape with an opening on the lower side. The elastic member 40 described above is disposed inside the concave portion of the mass body 42. Accordingly, the mass body 42 is displaced by elastic deformation of the elastic member 40 to attenuate the vibration.

(Construction procedure)
Next, a construction procedure for constructing the double floor structure 10 shown in FIG. 1 will be described.

  First, the plurality of support legs 16 are fixed on the floor slab 12. Next, the large pull 30 is arranged on the plurality of support legs 16, and the height position of the large receiving metal fitting 26 is adjusted by the adjustment bolt 20 and the adjustment nut 22 of the support leg 16. Next, the dynamic vibration absorber 34 is suspended and fixed to the lower surface of the large pull 30.

  Next, the joists 32 are arranged and fixed on the pullers 30 such that the extending directions of the joists 32 are orthogonal to the extending directions of the pullers 30. Next, the discard plate 14A is laid on the joists 32, and finally the flooring 14B is laid on the discard plate 14A. The double floor structure 10 is configured as described above.

  In this embodiment, the dynamic vibration absorber 34 is fixed to the large pull 30 after the large pull 30 is disposed on the support leg 16. For example, the dynamic vibration absorber 34 is fixed to the large pull 30 in advance. Then, the large pull 30 may be disposed on the support leg 16, and in this case, the number of installation steps on site is reduced.

(Action / Effect)
Next, the operation and effect of the above embodiment will be described.

  As shown in FIG. 2, in the floor structure 10 according to the present embodiment, the upper flooring 14 is supported on the large pull 30 via a joist 32, and the large pull 30 is connected to the large pull 30 via a mounting bolt 38 or the like. The elastic member 40 of the dynamic vibration absorber 34 is supported. Therefore, when vibration is applied to the upper floor material 14, this vibration is transmitted to the elastic member 40 of the dynamic vibration absorber 34 through the joist 32, the large pull 30, the mounting bolt 38, and the like. As a result, the elastic member 40 of the dynamic vibration absorber 34 is elastically deformed, and the mass body 42 supported by the elastic member 40 in the dynamic vibration absorber 34 moves up and down so as to absorb vibration. The vibration to 12 is damped. Since the large pull 30 is supported on the floor slab 12 via the plurality of support legs 16, the damped vibration is transmitted from the large pull 30 to the floor slab 12 via the support legs 16.

  Here, a supplementary explanation will be made while comparing with the comparison structure. For example, in a comparison structure in which an asphalt sheet is laid on the upper floor material in order to ensure the performance of blocking floor impact sound, a heavy asphalt sheet is laid on the entire floor surface. As a result, the workability is poor and the cost is greatly increased. In addition, the increase in weight increases the burden in terms of building strength. On the other hand, in the floor structure 10 according to the present embodiment, it is not necessary to lay a heavy asphalt sheet on the entire floor surface, so these problems can be solved, and weight reduction and improvement in workability are realized. The

  As described above, according to the floor structure 10 according to the present embodiment, the floor impact sound blocking performance is good and the workability can be improved.

[Second Embodiment]
Next , the floor structure according to the second embodiment will be described with reference to FIG. Note that the second embodiment is not an embodiment of the present invention but a reference example. FIG. 3 is a cross-sectional view showing the mounting state of the dynamic vibration absorber 34 in the floor structure according to the second embodiment.

  As shown in this figure, the floor structure according to the present embodiment is the floor structure according to the first embodiment in that the mounting bolt 38 is fixed to the large pull 30 in a state of vertically passing through the large pull 30. Different from structure 10 (see FIG. 2). Other configurations are substantially the same as those of the first embodiment. Therefore, components that are substantially the same as those of the first embodiment are denoted by the same reference numerals and description thereof is omitted.

  As shown in FIG. 3, bolt insertion holes 130 </ b> A and 130 </ b> B are formed through the top 30 </ b> A and bottom 30 </ b> B of the large pull 30, and mounting bolts 38 are inserted through these bolt insertion holes 130 </ b> A and 130 </ b> B. . A flange-shaped receiving plate 45 is fixed integrally with the mounting bolt 38 at an intermediate portion in the axial direction of the mounting bolt 38. The receiving plate 45 is disposed on the lower surface side of the bottom 30 </ b> B of the large drawer 30. On the other hand, a pressing plate 46 is disposed on the upper surface side of the top portion 30 </ b> A of the large pull 30, and the pressing plate 46 is penetrated by a mounting bolt 38. Further, on the holding plate 46, a nut 48 is disposed that is screwed to one end (upper end) of the mounting bolt 38 in the axial direction.

  In this structure, the large pull 30 is tightened between the pressing plate 46 and the receiving plate 45 by screwing the nut 48 to the mounting bolt 38. By this tightening (fastening), the dynamic vibration absorber 34 is attached in a state where it is suspended from the large pull 30. Thereby, the elastic member 40 is supported by the large pull 30 via the receiving seat 39, the mounting bolt 38, the nut 48, and the like.

  The construction procedure for constructing the floor structure according to the present embodiment is the same as the construction procedure in the first embodiment. Also, with the configuration of the present embodiment, the same operations and effects as those of the first embodiment described above can be obtained.

[Third Embodiment]
Next , a floor structure according to a third embodiment will be described with reference to FIG. The third embodiment is not an embodiment of the present invention but a reference example. FIG. 4 is a cross-sectional view showing the mounting state of the dynamic vibration absorber 34 in the floor structure according to the third embodiment.

  As shown in this figure, in the floor structure according to the present embodiment, the dynamic vibration absorber 34 is suspended from the large pull 30 via an L-shaped steel 52 (an element grasped as a “connecting member” in a broad sense). It differs from the floor structure 10 (refer FIG. 2) which concerns on 1st Embodiment by the point lowered. Other configurations are substantially the same as those of the first embodiment. Therefore, components substantially the same as those in the first and second embodiments are denoted by the same reference numerals and description thereof is omitted.

  As shown in FIG. 4, an L-shaped steel 52 is disposed on the side of the draw 30. The L-shaped steel 52 is formed by pressing a steel plate into a substantially L shape in a longitudinal sectional view, and the vertical plate portion 52A is fixed to the side portion 30C (side surface) of the large drawing 30 by fixing means such as a screw 51. ing.

  The central portion of the horizontal portion 52 </ b> B constituting the lower portion of the L-shaped steel 52 is penetrated by the mounting bolt 38. A receiving plate 53 that is penetrated by the mounting bolt 38 is disposed on the lower surface side of the horizontal portion 52B. A nut 54 is disposed on the lower surface of the receiving plate 53, and this nut 54 is screwed to the mounting bolt 38. A pressing plate 46 and a nut 48 are disposed on the upper surface side of the horizontal portion 52B.

  In this structure, the horizontal portion 52 </ b> B of the L-shaped steel 52 is fastened between the pressing plate 46 and the receiving plate 53 by screwing the nuts 48 and 54 to the mounting bolt 38. By this tightening (fastening), the dynamic vibration absorber 34 is attached in a state of being suspended from the L-shaped steel 52, and the dynamic vibration absorber 34 is attached to the large pull 30 via the L-shaped steel 52. That is, the L-shaped steel 52 connects the dynamic vibration absorber 34 and the large pull 30. Thereby, the elastic member 40 is supported by the large pull 30 via the receiving seat 39, the mounting bolt 38, the nut 48, the L-shaped steel 52, and the like. A plurality of dynamic vibration absorbers 34 may be attached to the L-shaped steel 52, or one piece may be attached.

  The construction procedure for constructing the floor structure according to the present embodiment is substantially the same as the construction procedure in the second embodiment. However, if a plurality of dynamic vibration absorbers 34 are attached to the L-shaped steel 52 in advance, the construction procedure is the same. The number of mounting steps can be reduced. The configuration of the present embodiment also provides substantially the same operations and effects as those of the first embodiment described above.

[Fourth Embodiment]
Next , a floor structure 60 according to a fourth embodiment will be described with reference to FIGS. Note that the fourth embodiment is not an embodiment of the present invention but a reference example. 5 shows a floor structure 60 according to the fourth embodiment in a longitudinal sectional view. FIG. 6 shows an enlarged sectional view of a part of the floor structure 60 as viewed in the direction of arrow 6 in FIG. Is shown.

  As shown in these drawings, the floor structure 60 according to the fourth embodiment is a suspension member for attaching the dynamic vibration absorber 34 to the large pull 30 instead of the L-shaped steel 52 (see FIG. 4). This is different from the floor structure according to the third embodiment in that it includes a hanging bracket 62 (which is an element grasped as a “connecting member” in a broad sense). Other configurations are substantially the same as those of the third embodiment. Therefore, components substantially the same as those in the first to third embodiments are denoted by the same reference numerals and description thereof is omitted.

  As shown in FIG. 5, a plurality of suspension brackets 62 (in the present embodiment, a total of three in the vicinity of the support legs 16 and in the central portion between the support legs 16) are attached between the support legs 16. It has been. As shown in FIG. 6, the hanging metal fitting 62 has a substantially C-shaped cross-sectional shape, and includes a side plate portion 62 </ b> A arranged with a surface including the vertical direction as a surface direction.

  The upper portion of the side plate portion 62A is disposed along the outer surface of one side portion 30D of the large pull 30. In addition, the top plate portion 62B bent at a right angle from the upper end of the side plate portion 62A is disposed on the top portion 30A of the large pull 30. Further, the flange portion 62D bent at a right angle from the front end of the top plate portion 62B is disposed in contact with the outer surface of the upper end portion of the other side portion 30C of the large pull 30. That is, the hanging bracket 62 is formed with a substantially hook-shaped locking portion 64 that can be hooked to the large pull 30 by the upper portion of the side plate portion 62A, the top plate portion 62B, and the flange portion 62D. In the locking part 64, the upper part of the side plate part 62 </ b> A is fixed by a fixing means such as a screw 63 while being in contact with the outer surface of one side part 30 </ b> D of the large pull 30. Thereby, the hanging metal fitting 62 is attached in a state of being suspended from the large pull 30.

  On the other hand, the bottom plate portion 62C bent at a right angle from the lower end of the side plate portion 62A is disposed in parallel to the top plate portion 62B, and the flange portion 62E bent at a right angle from the tip of the bottom plate portion 62C has a flange portion 62D. It extends in the direction approaching. A bolt insertion hole 162 </ b> C is formed through the center of the bottom plate portion 62 </ b> C for insertion of the mounting bolt 38. In addition, a weld nut 66 is fixed to the outer surface of the bolt insertion hole 162C in advance on the upper surface of the bottom plate portion 62C. The weld nut 66 is screwed to one end (upper end) of the mounting bolt 38 in the axial direction.

  Accordingly, the dynamic vibration absorber 34 is attached in a state of being suspended from the hanging bracket 62, and is attached to the large pull 30 via the hanging bracket 62. That is, the hanging metal fitting 62 connects the dynamic vibration absorber 34 and the large pull 30. Thereby, the elastic member 40 is supported by the large pull 30 via the receiving seat 39, the mounting bolt 38, the weld nut 66, the suspension fitting 62, and the like.

  As a modification of the present embodiment, the flange portion 62D of the hanging bracket 62 extends to a position where it contacts the outer surface of the lower end portion of the side portion 30C of the large pull 30 and contacts the outer surface of the side portion 30C of the large pull 30. The flange portion 62D in the above state may be fixed to the side portion 30C by fixing means such as a screw (the same applies to the fifth embodiment described later).

  The construction procedure for constructing the double floor structure 60 shown in FIG. 5 is substantially the same as the construction procedure in the third embodiment, and after placing the large pull 30, the dynamic vibration absorber 34 is attached in advance. The suspended hanging bracket 62 is fixed to the large pull 30. At that time, the operator first hangs the latching portion 64 of the hanging fitting 62 shown in FIG. 6 by hanging it on the large pull 30 (hanging with one touch), and then the upper portion of the side plate portion 62A of the hanging fitting 62. Is fixed to the side portion 30D of the large pull 30 by a fixing means such as a screw 63. For this reason, it becomes easy to attach the dynamic vibration absorber 34 to the large pull 30 via the hanging metal fitting 62, and the removal is also easy. The configuration of the present embodiment also provides substantially the same operations and effects as those of the first embodiment described above.

[Fifth Embodiment]
Next , a floor structure 70 according to a fifth embodiment will be described with reference to FIGS. Note that the fifth embodiment is not an embodiment of the present invention but a reference example. 7 shows a floor structure 70 according to the fifth embodiment in a longitudinal sectional view, and FIG. 8 shows an enlarged sectional view of a part of the floor structure 70 as viewed in the direction of arrow 8 in FIG. Is shown.

  As shown in these drawings, the floor structure 70 includes a dynamic vibration absorber 72 (also referred to as “dynamic damper device”, “vibration damper”, or the like) instead of the dynamic vibration absorber 34 (see FIG. 6). This is different from the floor structure 60 (see FIG. 5) according to the fourth embodiment. Other configurations are substantially the same as those of the fourth embodiment. Therefore, components substantially similar to those in the first and fourth embodiments are denoted by the same reference numerals and description thereof is omitted.

  A dynamic vibration absorber 72 is disposed on the bottom plate portion 62 </ b> C of the hanging bracket 62. The dynamic vibration absorber 72 includes an elastic member 80 (damper rubber) and a mass body 82 (weight) which will be described later.

  As shown in FIG. 8, the center portion of the bottom plate portion 62 </ b> C of the hanging metal fitting 62 is penetrated by the mounting bolt 74. A nut 76 is screwed to one end (lower end) in the axial direction of the mounting bolt 74, and a receiving seat 77 is integrally fixed to the upper surface of the nut 76. The receiving seat 77 is penetrated by the mounting bolt 74 and is disposed below the bottom plate portion 62 </ b> C of the hanging bracket 62.

  On the other hand, a receiving seat 78 is disposed on the upper side of the bottom plate portion 62 </ b> C of the hanging bracket 62. The receiving seat 78 is integrally fixed to an intermediate portion in the axial direction of the mounting bolt 74, and is disposed coaxially with the mounting bolt 74. In this structure, the bottom plate portion 62 </ b> C of the hanging bracket 62 is fastened between the receiving seats 77 and 78 by screwing the nut 76 to the mounting bolt 74. Thereby, the dynamic vibration absorber 72 is attached to the hanging bracket 62.

  A cylindrical elastic member 80 disposed on the outer peripheral side of the mounting bolt 74 is fixed on the receiving seat 78. Thus, the elastic member 80 is fixed to the bottom plate portion 62C of the hanging bracket 62 and is supported by the large pull 30 via the receiving seat 78, the hanging bracket 62, and the like. In other words, the hanging bracket 62 connects the dynamic vibration absorber 72 and the large pull 30. The elastic member 80 is made of rubber or the like and can be elastically deformed to attenuate vibrations.

  A receiving seat 81 that is penetrated by the mounting bolt 74 is arranged on the elastic member 80, and a mass body 82 is arranged on the receiving seat 81. That is, the mass body 82 is supported by the elastic member 80 via the receiving seat 81. The mass body 82 is made of metal (in the present embodiment, made of steel), and the other axial end portion (upper end portion) of the mounting bolt 74 is inserted into the lower portion thereof so as to be relatively movable. Accordingly, the mass body 82 is displaced by elastic deformation of the elastic member 80 to attenuate the vibration.

  The construction procedure for constructing the floor structure 70 according to the present embodiment is the same as the construction procedure in the fourth embodiment. The configuration of the present embodiment also provides substantially the same operations and effects as those of the first embodiment described above.

[Sixth Embodiment]
Next , a floor structure 90 according to a sixth embodiment will be described with reference to FIGS. 9 and 10. The sixth embodiment is an embodiment of the present invention. 9 shows a floor structure 90 according to the sixth embodiment in a longitudinal sectional view, and FIG. 10 shows an enlarged sectional view of a part of the floor structure 90 as viewed in the direction of the arrow 10X in FIG. Is shown.

  As shown in these drawings, the floor structure 90 is different from the floor structure 70 according to the fifth embodiment in that the dynamic vibration absorber 72 is disposed inside the large pull 92 (installed in the internal space). . Other configurations are substantially the same as those of the fifth embodiment. Therefore, components substantially the same as those in the first and fifth embodiments are denoted by the same reference numerals and description thereof is omitted.

  The large drawing 92 shown in FIG. 9 is disposed in the same manner as the large drawing 30 shown in the other embodiments. That is, the plurality of large pulls 92 are respectively transferred and supported on the support legs 16, and the plurality of joists 32 are transferred and supported on the respective large pulls 92.

As shown in FIG. 10, the large fork 92 is made of C-shaped steel that opens downward in the installed state. From the both ends in the direction perpendicular to the longitudinal direction of the top portion 92A and the top portion 92A. Side portions 92B and 92C which are bent at right angles (hang down) and parallel to each other, and bottom portions 92D and 92E which are bent at right angles in a direction approaching each other from the lower ends of the side portions 92B and 92C are provided. The front end of the bottom portion 92D and the front end of the bottom portion 92E are spaced apart from each other at a constant interval, thereby forming a through portion 94 (lower opening) .

  As shown in FIGS. 9 and 10, a plurality of dynamic vibration absorbers 72 are arranged inside the large pull 92. As shown in FIG. 9, in this embodiment, a plurality of dynamic vibration absorbers 72 are provided between the support legs 16 adjacent to each other for the large pull 92 (in this embodiment, the vicinity of the support legs 16 and the support legs). A total of three are installed in the center between 16).

As shown in FIG. 10, the through portion 94 of the large pull 92 is penetrated by the mounting bolt 74. A nut 76 is screwed to one end (lower end) in the axial direction of the mounting bolt 74, and a receiving seat 77 as a second receiving seat is integrally fixed to the upper surface of the nut 76. The receiving seat 77 is penetrated by the mounting bolt 74 and is disposed below the bottom portions 92D and 92E of the large pull 92.

On the other hand, a receiving seat 78 as a first receiving seat is disposed above the bottom portions 92D and 92E of the large pull 92. The receiving seat 78 is integrally fixed to an intermediate portion in the axial direction of the mounting bolt 74, and is disposed coaxially with the mounting bolt 74. Here, in this embodiment, when the nut 76 is screwed onto the mounting bolt 74, the bottom portions 92D and 92E of the large pull 92 are strongly tightened (tightened) between the receiving seats 77 and 78.

  Further, an elastic member 80, a receiving seat 81, and a mass body 82 are arranged on the upper side of the receiving seat 78 with the same configuration as that of the fifth embodiment. Thereby, the elastic member 80 is supported by the large pull 92 through the receiving seat 78.

  The construction procedure for constructing the double floor structure 90 shown in FIG. 9 is the same as that of the fifth embodiment except for the step of attaching the dynamic vibration absorber 72 to the large pull 92. When attaching the dynamic vibration absorber 72 to the large pull 92, the operator inserts the dynamic vibration absorber 72 into the large pull 92 from one longitudinal end side of the large pull 92 arranged at a predetermined position. Is moved to the arrangement position along the longitudinal direction of the penetrating portion 94 (see FIG. 10). Next, the nut 76 is screwed into the axial direction one end (lower end) of the mounting bolt 74 from the lower side of the large pull 92 to fix the dynamic vibration absorber 72 to the large pull 92.

  In this embodiment, the dynamic vibration absorber 72 is fixed to the large pull 92 after the large pull 92 is disposed at a predetermined position on the support leg 16. However, the dynamic vibration absorber 72 is fixed to the large pull 92 in advance. After that, the large pull 92 may be arranged at a predetermined position on the support leg 16, and in this way, the number of installation steps at the site can be reduced. In this embodiment, the large pull 92 is made of C-shaped steel. However, the large pull has a rectangular tube shape with a rectangular closed cross section, and the mounting bolt 74 is inserted at a position where the dynamic vibration absorber 72 is disposed. It may be a large pull through which a bolt insertion hole is formed.

  Also with the configuration of the present embodiment, substantially the same operations and effects as those of the first embodiment described above can be obtained. Further, in the present embodiment, the dynamic vibration absorber 72 is disposed inside the large pull 92, so that the underfloor structure (such as a ventilation duct) disposed between the floor slab 12 and the upper flooring 14 and the dynamic vibration absorber 72 are disposed. Since interference with the vibration absorber 72 is avoided, the workability is very good and the floor can be lowered.

[Supplementary explanation of the embodiment]
In the above embodiment, the case where the elastic members 40 and 80 are made of rubber has been described as an example, but the elastic member is another elastic member that can be elastically deformed, such as a compression coil spring, for example. Also good.

In addition , the floor structure of the present invention applies, for example, a deck plate in which a metal plate such as a steel plate is formed into a substantially rectangular corrugated shape by press working as a floor support member, and the deck plate is handed over to the fork. The structure may be applied to a structure in which a floor material is supported on the deck plate.

  Further, the number of the dynamic vibration absorbers 34 and 72 disposed between the support legs 16 in the large pulls 30 and 92 is not limited to the example of the above embodiment. The number of installation of the dynamic vibration absorbers 34 and 72 can be set according to the required improvement amount of the floor impact sound blocking performance. In other words, in the said embodiment, it is the structure which can control the improvement amount of the interruption | blocking performance of a floor impact sound by increasing the installation number of the dynamic vibration absorbers 34 and 72. FIG.

12 Floor slabs 14 Upper flooring (flooring)
16 support legs 32 joist (floor support member)
72 Dynamic vibration absorber
74 Mounting bolt
76 nuts
77 Receiving seat (second receiving seat)
78 Receiving seat (first receiving seat)
80 Elastic member 82 Mass body 90 Floor structure 92 Large pull
94 Through part (lower opening)

Claims (2)

Floor slabs,
A plurality of support legs supported on the floor slab;
A plurality of pawls that are passed and supported on the support legs;
A floor support member that is passed and supported on the fork;
Floor material supported on the floor support member and disposed with a space between the floor slab,
A dynamic vibration absorber that is disposed inside the large pull, includes an elastic member that is elastically deformable by being supported by the large pull, and a mass body that is supported by the elastic member;
With floor structure. It is composed of C-shaped steel that is open on the lower side in the installed state.
A mounting bolt that penetrates the lower opening of the large pull,
A first receiving seat which is disposed on the upper surface side of the bottom of the large pull inside the large pull and is fixed to an intermediate portion in the axial direction of the mounting bolt, and the elastic member is fixed to the upper surface;
A nut disposed on the lower side of the large pull and screwed into the lower end of the mounting bolt;
It is arranged on the lower side of the large pull, is fixed to the upper surface of the nut and is penetrated by the mounting bolt, and the nut is screwed into the lower end portion of the mounting bolt, thereby lowering the bottom of the large pull. A second pedestal clamped between the first pedestal and
The floor structure according to claim 1.

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