JP2008240335A - Floor structure and building unit - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a floor structure having a damper miniaturized and capable of providing stable sound isolation effect. <P>SOLUTION: In this floor structure C, small floor beams 15... are stretched between floor beams 12, 12, and a floor member 14 is installed on the small floor beams 15... for forming a floor. The damper 2 is installed on each of the small floor beams 15. The damper 2 is formed of a rectangular or square plate member 21, and installed on each of the small floor beams 15 along the center of the plate member 21 in the direction perpendicular to the axis of the small floor beam 15. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a floor structure that reduces impact noise and a building unit including the floor structure.

  Conventionally, an impact sound generated when a child jumps or drops an object on the upper floor is a problem as noise on the lower floor.

  As a method for reducing the impact sound, for example, a floor structure shown in Patent Document 1 is known. This floor structure is characterized by comprising a steel plate damper in which a steel plate having a weight function is installed between floor beams and a viscous material is interposed between the steel plate and floor beams.

  By configuring the steel plate damper in this manner, the steel plate damper absorbs floor vibration, so that the floor vibration attenuation becomes high and impact noise can be suppressed.

  In addition, the floor structure shown in Patent Document 2 includes a viscous mass damper in which a horizontal member is inserted in the approximate center of an opposing floor beam, and a weight is suspended from the horizontal member via a damper. It is characterized by providing.

By configuring the viscous mass damper in this way, it is possible to reduce the impact sound due to the synergistic effect of the fact that vibration is difficult because the natural frequencies of the floor beam and the weight are different and the damping by the damper.
JP 2003-247294 A JP 2001-65099 A

  On the other hand, in the floor structure provided with the steel plate damper described in Patent Document 1, it is necessary to lengthen the plate or add a weight in order to reduce the natural frequency of the damper.

  Moreover, in the floor structure provided with the viscous mass damper of the above-mentioned patent document 2, since the elasticity of the rubber upper plate depends on the temperature, a stable sound insulation effect may not be obtained.

  Accordingly, an object of the present invention is to provide a floor structure and a building unit including a damper that is small and can obtain a stable sound insulation effect.

  In order to achieve the above object, a floor structure according to the present invention is configured such that a floor beam is bridged over a floor beam, and a floor material is attached on the floor beam to form a floor. The damper is formed by a plate member, and is attached to the floor beam along the center of the plate member in the direction orthogonal to the axis of the floor beam. To do.

  Here, it is preferable that a mounting member protrudes along the center of the plate member in the direction orthogonal to the axis of the floor beam, and the mounting member is mounted along the floor beam. .

  Further, a floor beam is laid over the floor beam, a floor material is constructed on the floor beam to constitute a floor, and a damper is attached to the floor beam. In addition to being formed by a plate member, an attachment piece protrudes in the vicinity of the center point of the plate member, and the attachment piece is attached to the floor beam.

  Furthermore, it is preferable that any of the above-described dampers be installed in the vicinity of the antinode position of the vibration mode due to the impact sound of the floor.

  And the building unit or unit building of this invention is equipped with the above floor structures.

  Here, the flooring means floor joists, floor boards or floor finishing materials.

  As described above, the floor structure of the present invention includes a damper that is formed by a rectangular or square plate member and is attached to the floor beam along the center of the plate member in the direction perpendicular to the axis of the floor beam.

  Therefore, when an impact sound is generated on the floor, the vibration of the floor is transmitted to the floor beam, and the vibration of the floor beam is transmitted to the damper attached to the floor beam, near the center of the plate member constituting the damper. Vibrates.

  At this time, the vicinity of the center of the plate member receives the inertial force from the vicinity of both end portions sandwiching the center, so that the vibration is efficiently damped.

  Further, the mounting member protrudes along the center of the plate member in the direction perpendicular to the axis of the floor beam, and the mounting member is attached to the floor beam so that the plate member comes into contact with the floor beam to be integrated. Since vibration can be prevented, vibration can be attenuated more efficiently.

  Furthermore, a mounting piece protrudes near the center point of the plate member that constitutes the damper, and since this mounting piece is attached to the floor beam, it receives an inertial force from the entire periphery of the center point, so it vibrates efficiently. Can be attenuated.

  And as above-mentioned, since a vibration can be attenuate | damped efficiently, a smaller board member can be used as a damper compared with the past.

  In addition, since a member whose properties change depending on temperature is not used, a stable sound insulation effect can be obtained.

  Further, by installing the damper in the vicinity of the antinode position of the vibration mode due to the impact sound of the floor, vibration can be absorbed at a position where the amplitude of the floor is large, so that the impact sound of the floor can be attenuated efficiently.

  Furthermore, by providing a damper as described above, it is possible to provide a building unit or unit building in which impact noise on the upper floor is reduced and noise transmitted to the lower floor is suppressed.

  The best mode for carrying out the present invention will be described below with reference to the drawings.

  First, the structure of the unit building U is demonstrated using FIG. This unit building U has a plurality of floors. That is, a plurality of building units 1A,... Serving as the first floor portion are installed on the foundation 3, and a plurality of building units 1, 2 serving as the second floor portion are disposed on the building unit 1A,. And the roof panel 4 is mounted on the building units 1.

  Next, the structure of the building unit 1 provided with the floor structure C of this Embodiment is demonstrated using FIG. This building unit 1 has four pillars 11,..., Four floor beams 12,... Connecting the lower ends of the pillars 11,. , And four ceiling beams 13,...

  Here, in the above frame structure, a square steel pipe or the like can be used as the pillars 11. Further, as the floor beam 12,... And the ceiling beam 13,.

  Further, a plurality of floor beams 15,... Are stretched substantially parallel to the opposing long side floor beams 12, 12, and a particle board or the like is placed on the floor beams 15,. The flooring 14 is attached to form a floor.

  Further, a plurality of ceiling edges 17,... Are bridged over the opposing long-side ceiling beams 13, 13, and a ceiling material 18 such as a gypsum board is attached under the ceiling edges 17,. The ceiling is formed.

  And in the place which provides an outer wall (not shown), the stud 19 is attached between the floor beam 12 and the ceiling beam 13, and an outer wall material and an inner wall material are attached to the outdoor side and the indoor side of the stud 19, respectively. A wall is formed by providing a heat insulating material such as glass wool between the outer wall material and the inner wall material.

  In the building unit 1, the flooring 14 is not limited to a single layer, but is made into a multilayer by pasting a soundproof sheet or the like, or a floor joist is provided between the floor beam and the particle board. It may be a thing.

  In this embodiment, the damper 2 is attached to the floor beam 15.

  As shown in FIG. 1, the damper 2 includes a plate member 21 and an attachment plate 22 as an attachment member for attaching the plate member 21 to the floor beam 15.

  The plate member 21 is formed in a rectangular plate shape by particle board or plywood, and a mounting plate 22 as a mounting member is attached along the center line 211 in the axis orthogonal direction of the floor beam 15 in the plate member 21. It has been.

  As shown in FIG. 4, a gap 26 is provided between the upper surface of the plate member 21 and the lower surface of the floor beam 15 so that the plate member 21 does not come into contact with the floor beam 15 when the plate member 21 vibrates. ing.

  The width of the gap 26 is preferably about 3 to 20 (mm) in consideration of the amplitude of the plate member 21 measured in the demonstration experiment described later, and is 5 (mm) in the present embodiment.

  When a particle board is used as the plate member 21, the thickness of the plate member 21 is preferably about 12 to 18 (mm), which is generally used. In the present embodiment, the thickness is 15 (mm). Is used.

  Further, the axial length of the floor beam 15 of the plate member 21 is 800 (mm) in the case of the standard building unit 1.

  The outline of the demonstration experiment conducted for obtaining the optimum length of the plate member 21 will be described below.

  In this experiment, as a building unit 1 having a standard shape and material, a damper is applied to a floor structure C including floor beams 12,..., Floor beams 15,. 2 are attached to the floor beam 15,.

  That is, the size of the floor structure C is set to a length L = 5640 (mm) in the long side direction, a width B = 2464 (mm) in the short side direction, and a grooved steel 150 × 75 is used as the floor beam 12. A rectangular steel pipe 125 × 75 is used as the floor beam 15, and a particle board having a thickness of 18 (mm) is used as the floor plate 14.

  The dampers 2,... Are placed on three floor beams 15,... In the vicinity of a position that divides the girder direction of the floor of the building unit 1 into approximately four equal parts, which are antinode positions of vibration modes to be described later. It is attached.

  In addition, the method specified in Japanese Industrial Standard A1419-2 “Evaluation Method of Sound Insulation Performance of Buildings and Building Materials-Part 2: Floor Impact Sound Isolation Performance” can be used as a method for generating and measuring floor impact sound. Used.

  FIG. 9 shows that the width of the plate member 21 of the damper 2 is fixed to 600 (mm) and the length of the plate member 21 is set to 600, 800, 900, 1350, 1800 (mm) under the above experimental conditions. The results of measuring the amount of attenuation (dB) of the impact sound in the case of the above are shown.

  As can be seen from FIG. 9, when the length of the plate member 21 is 800 (mm), the attenuation amount is about 6 (dB), and it can be seen that the attenuation effect is the largest.

  When the length is 600 (mm), the attenuation is less than 5 (dB). When the length is 1350 (mm) or 1800 (mm), the attenuation is 5 ( dB).

  This indicates that when the length of the plate member 21 is short, the plate member 21 itself that vibrates is small and the inertial force of the plate member 21 is also small, so that the damping effect is small.

  On the other hand, when the plate member 21 is long, the vibrating plate member 21 itself becomes large, so that the natural frequency of the plate member 21 approaches the natural frequency of the floor beam 15. The floor beam 15 vibrates together, and the damping effect is reduced.

  Similarly, in the case of the standard building unit 1, the width orthogonal to the axial direction of the floor beam 15 of the plate member 21 is set to 500 (mm) or 600 (mm).

  FIG. 10 is a graph showing the results of a demonstration experiment conducted to determine the width of the plate member 21.

  This experiment was performed under substantially the same conditions as the experiment shown in FIG. 9, but the length of the plate member 21 was fixed to 900 (mm) contrary to the experiment of FIG. The experimental results when the width of the plate member 21 is 500, 600, and 700 (mm) are shown.

  As can be seen from FIG. 10, when the width of the plate member 21 is 500 (mm) or 600 (mm), the attenuation is about 6 (dB), and it can be seen that the attenuation effect is large.

  On the other hand, when the width is 700 (mm), the attenuation is about 3 (dB), and the natural frequency of the plate member 21 approaches the natural frequency of the floor beam 15 so that the plate member It can be seen that 21 and the floor beam 15 vibrate together to reduce the damping effect.

  Further, the mounting plate 22 of the present embodiment is formed of L-shaped steel, and is attached along the side surface of the floor beam 15 by welding along the center line in the long side direction of the plate member 21. And a horizontal plate 222 attached by tapping screws 25.

  The vertical plate 221 may be attached to the floor beam 15 by using bolts and nuts in addition to welding. The horizontal plate 222 may be attached to the plate member 21 by using bolts and nuts in addition to the tapping screws 25. Nails and adhesives may be used.

  On the other hand, it is known that the floor structure C constituted by the floor beams 12,..., The floor beams 15,.

  The vibration waveform of the floor structure C at this resonance frequency is called a vibration mode of the floor structure C, a position where the amplitude of the vibration mode is maximum is called an antinode, and a position where the amplitude is zero is called a node.

  And the damper 2 of this Embodiment is attached to the floor beam 15 near the antinode positions A1, A2 of the vibration modes M1, M2 of the floor structure C in the building unit 1 as shown in FIG.

  In particular, the floor structure C is preferably installed at the antinode position of the walking vibration mode and the antinode position of the weight impact vibration mode.

  For example, it is assumed that the antinode position A1 of the walking vibration mode M1 is near the approximate center of the floor girder direction, and the antinode position A2 of the weight impact vibration mode M2 is the position of approximately four equal points in the girder direction of the floor.

  In this case, the dampers 2 are installed at three positions of the four equally divided points on the floor, but when the floor beam 15 is not installed at positions corresponding to the antinode positions A1, A2, A2, the antinode position A1. , A2 and A2, and the damper 2 is attached to the closer floor beam 15 of the floor beams 15 and 15 on both sides.

  Further, the damper 2 is attached in the vicinity of the center of the floor beam 15 where the vibration amplitude of the floor beam 15 becomes the largest in the wife direction.

  Next, the effect | action of the floor structure C of this Embodiment is demonstrated.

  As described above, the floor structure C of the present embodiment is a floor structure C in which the damper 2 is attached to the floor beam 15, and the damper 2 is formed by the rectangular plate member 21 and the plate member 21. Is attached to the floor beam 15 via the mounting plate 22 along a center line 211 in the center of the floor beam 15 in the direction orthogonal to the axis.

  When an impact sound is generated on the flooring 14 due to a child jumping or the like, the vibration is transmitted to the floor beam 15, and the vibration of the floor beam 15 is transmitted to the plate member 21 constituting the damper 2 via the mounting plate 22. Communicated.

  At this time, since the mounting plate 22 has high rigidity in the vertical direction that is the vibration direction, the vibration of the floor beam 15 at the location where the mounting plate 22 is mounted is transmitted to the plate member 21 with almost no attenuation.

  Then, the vibration of the floor beam 15 is transmitted in the vicinity of the center line 211 in the direction perpendicular to the axis of the floor beam 15 in the plate member 21 attached to the mounting plate 22, and in conjunction with the floor beam 15. It will vibrate up and down.

  On the other hand, since the law of inertia works in the vicinity of the end portions 213 and 213 sandwiching the center line 211, it tries to stay at the original stationary position even if vibration is transmitted.

  However, the end portions 213 and 213 and the vicinity of the center line 211 are formed from the same plate member 21 and are connected to each other.

  Accordingly, when the vicinity of the center line 211 vibrates, the ends 213 and 213 that are relatively stationary with respect to the vicinity of the center line 211 apply a force in a direction opposite to the vibration to attenuate the vibration.

  As shown in FIG. 6B, the plate member 21 constituting the damper 2 of the present embodiment receives inertial forces from both ends 213 and 213 sandwiching the center line 211, so that it is more than the conventional structure. Vibration can be damped efficiently.

  That is, in the conventional structure shown in FIG. 6A, since the plate member 21 is bridged over the floor beams 15 and 15, both ends 213 and 213 of the plate member 21 vibrate (waveform WA). The inertial force is received only from the vicinity of the center line 211 of the plate member 21.

  On the other hand, in the floor structure C of the present embodiment shown in FIG. 6B, only the vicinity of the center line 211 of the plate member 21 vibrates (waveform WB). Inertial force is received from the vicinity of 213.

  That is, since the number of places receiving inertial force is increased from one place to two places, vibration can be attenuated more efficiently.

  Since the vibration of the plate member 21 constituting the damper 2 is attenuated in this way, the vibration of the floor beam 15 to which the plate member 21 is attached is attenuated. Impact noise can be reduced.

  And as a damper 2 can be more compactly damped by efficiently attenuating vibration as described above.

  That is, in order to obtain the sound insulation effect equivalent to the sound insulation effect that can be obtained by the conventional structure, the damper 2 of the present embodiment that absorbs vibration more efficiently than before can be used. 2 can be used.

  On the contrary, if the damper 2 having the same size as that of the conventional structure is used, the damper 2 having a greater sound insulation effect than the conventional structure can be obtained.

  Further, since a member whose properties change depending on the temperature is not used, a stable sound insulation effect can be obtained at both high and low temperatures.

  That is, since the damper 2 does not use a member whose properties change depending on the temperature, such as rubber, the rubber is softened at a high temperature as in the conventional case, and the natural frequency of the damper is reduced or the temperature is lowered. Sometimes, the rubber does not harden and the natural frequency of the damper does not increase, so that it always has a constant natural frequency and a stable sound insulation effect can be obtained.

  Then, a mounting plate 22 is projected along the center of the plate member 21 in the direction perpendicular to the axis of the floor beam 15, and the mounting plate 22 is attached to the floor beam 15 so that the plate member 21 is connected to the floor beam 15. Since it can prevent coming into contact and vibrating integrally, vibration can be attenuated more efficiently.

  That is, as shown in FIG. 6B, when the floor beam 15 is displaced downward by vibration, the end portions 213 and 213 on both sides of the plate member 21 are relatively deformed upward. It becomes.

  In FIGS. 6 (a) and 6 (b), the displacement of the floor beam 15 is exaggerated so that it can be easily understood how it vibrates. However, the displacement is actually very small.

  Even when the plate member 21 is deformed in this way, the gap 26 is provided between the upper surface of the plate member 21 and the lower surface of the floor beam 15 by attaching the plate member 21 to the floor beam 15 via the mounting plate 22. Never touch.

  As a result, the range in the vicinity of both end portions 213 and 213 for applying the inertial force to the plate member 21 to be attenuated is widened, so that a larger inertial force can be applied.

  Furthermore, since the damper 2 is attached via the attachment plate 22 as described above, the damper 2 can be easily attached even when a square steel pipe or the like is used as the floor beam 15.

  That is, by attaching the horizontal plate 222 of the attachment plate 22 to the plate member 21 in advance, the vertical plate 221 of the attachment plate 22 is attached to the side surface of the floor beam 15 so as to overlap the surface as shown in FIG. Therefore, attachment work such as welding becomes easy.

  As described above, the damper 2 has a very simple structure formed by the plate member 21 and the mounting plate 22.

  Therefore, when the building unit 1 is produced in the factory, the damper 2 can be attached in the process of installing the floor beam 15,... Without installing the damper 2 by installing a new process. .

  Furthermore, since the plate member 21 is rectangular or square, it can be easily processed by cutting a commercially available rectangular particle board, plywood or the like according to a predetermined dimension. It becomes damper 2.

  In addition, since the damper 2 is mainly composed of an inexpensive plate member 21, it can be made cheaper than a viscous mass damper having a complicated and mechanical structure as in the prior art.

  Moreover, since the damper 2 is mainly composed of the thin plate member 21, the thickness can be reduced as compared with the conventional damper. Therefore, the floor of the building unit 1 on the second floor and the ceiling of the building unit 1A on the first floor. The damper 2 can be installed even in a small space between the two.

  Since the damper 2 is installed in the vicinity of the antinode positions A1 and A2 of the vibration modes M1 and M2 due to the impact sound of the floor structure C, the vibration can be attenuated at a position with a large amplitude, so that the vibration can be efficiently absorbed. it can.

  Furthermore, by providing the damper 2 as described above, it is possible to reduce the impact sound on the upper floor and to make the building unit 1 that suppresses the noise transmitted to the lower floor.

  And the unit building U provided with such a building unit 1 becomes a comfortable unit building U that blocks noise generated on the upper floor and does not transmit it to the lower floor.

  Next, a floor structure C1 including a damper 2A having a form different from that of the above embodiment will be described with reference to FIG. The description of the same or equivalent parts as those described in the above embodiment will be given the same reference numerals.

  In the above embodiment, the case where the damper 2 includes the mounting plate 22 as the mounting member in addition to the plate member 21 has been described. However, in this embodiment, the case where the mounting plate 22 is not provided will be described.

  As shown in FIG. 7, the floor structure C <b> 1 of this embodiment includes a floor beam 15 and a damper 2 </ b> A attached to the floor beam 15.

  The floor beam 15 is formed of channel steel having a flange 151 which is a lower surface in the attached state, and is spanned between the floor beams 12 and 12 having long sides facing each other.

  In addition, as this floor beam 15, as long as it has the flange 151 used as a lower surface in the attached state, members of any shape, such as H-section steel and L-section steel, may be used.

  The damper 2 </ b> A is formed by the plate member 21, and a tapping screw is attached to the flange 151 on the lower side of the floor beam 15 along the center line 211 in the axis orthogonal direction of the floor beam 15 in the plate member 21. 25, ... are attached.

  The plate member 21 is formed in a rectangular or square shape by particle board or plywood, and is tapped on the flange 151 of the floor beam 15 along the center line 211 in the center of the plate member 21 in the direction perpendicular to the axis of the beam beam 15. It is attached with screws 25.

  In this way, by providing the plate member 21 directly to the floor beam 15 without providing the attachment plate 22 as the attachment member, the damper 2A having a very simple structure is obtained, so that assembly and attachment are easy and inexpensive. The damper 2A can be used.

  Further, since the damper 2A is formed only by the plate member 21, the damper 2A has an extremely thin structure, and also in an extremely narrow space between the ceiling of the building unit 1A on the first floor and the floor of the building unit 1 on the second floor. Can be attached.

  Other configurations and operational effects are substantially the same as those in the above-described embodiment, and thus the description thereof is omitted.

  Next, a floor structure C2 provided with a damper 2B having a form different from that of the embodiment and the example 1 will be described with reference to FIG. The description of the same or equivalent parts as those described in the embodiment and Example 1 will be given with the same reference numerals.

  In the above-described embodiment and Example 1, the case where the plate member 21 is attached to the floor beam 15 along the center of the plate member 21 in the direction perpendicular to the axis of the beam beam 15 has been described. A case will be described in which the plate member 21 is attached to the floor beam 15 via the attachment piece 23 protruding in the vicinity of the center point 212 of the surface of the member 21.

  As shown in FIG. 8, the floor structure C <b> 2 of this example includes a floor beam 15 and a damper 2 </ b> B attached to the floor beam 15.

  The floor beam 15 is formed of a square steel pipe, and is spanned between opposing long-side floor beams 12 and 12.

  The damper 2 </ b> B includes a square plate member 21 and an attachment piece 23.

  The plate member 21 is formed in a square plate shape by particle board or plywood, and a mounting piece 23 projects from the center point 212 of the surface.

  The attachment piece 23 is formed by cutting L-shaped steel or the like, and has a vertical piece 231 and a horizontal piece 22. The vertical piece 231 is attached to the floor beam 15 by welding, and is also horizontal. The piece 232 is attached to the plate member 21 by tapping screws 25 and 25.

  Further, the length of one side of the square plate member 21 is 600 (mm) in the case of the standard building unit 1.

  FIG. 11 is a graph showing the results of a demonstration experiment conducted to determine the length of one side of the square plate member 21.

  This experiment was performed under substantially the same conditions as the experiment shown in FIG. 9 described in the above embodiment.

  As can be seen from FIG. 11, when the thickness of the particle board is 18 (mm) and the length of one side is 600 (mm), the attenuation is about 6 (dB), and the attenuation effect is large. Recognize.

  On the other hand, when the length of one side is 500 (mm), the amount of attenuation is about 4 (dB), and since the planar dimension of the plate member 21 is small, the mass is reduced and the inertial force is also reduced. It can be seen that the attenuation effect is reduced.

  FIG. 11 also shows the result when the length of one side is 600 (m) and the thickness of the particle board is 15 (mm). In this case, the mass of the plate member 21 is small. Thus, it can be seen that the inertial force is reduced.

  As described above, the mounting piece 23 protrudes in the vicinity of the center point 212 of the plate member 21 constituting the damper 2B, and the mounting piece 23 is attached to the floor beam 15 so that the plate member 21 has the center point. Since the inertial force is received from the entire periphery in the vicinity of 212, vibration can be efficiently absorbed.

  Since the plate member 21 is formed in a square shape, the distance to the periphery of the center point 212 of the plate member 21 becomes uniform, and the inertia force is received almost uniformly from the entire periphery, so that the vibration is efficiently damped. be able to.

  Other configurations and functions and effects are substantially the same as those of the above-described embodiment or Example 1, and thus description thereof is omitted.

  Although the best embodiment of the present invention has been described in detail with reference to the drawings, the specific configuration is not limited to this embodiment or example, and the design does not depart from the gist of the present invention. Such modifications are included in the present invention.

  For example, in the above-described embodiment and Example 2, the case where the mounting plate 22 or the mounting piece 23 formed of L-shaped steel is used as the mounting member has been described. However, the present invention is not limited to this, and itself is a vibration. The shape and material can be arbitrarily selected as long as they have appropriate rigidity.

  Moreover, in the said embodiment and Example 2, although the case where the attachment member and the floor beam 15 were fixed by welding was demonstrated, it is not limited to this, A bolt and nut, spot welding, a screw, etc. Any method may be used as long as it can be fixed.

  Moreover, in the said embodiment and Example 1, 2, although the optimal value calculated | required by experiment was demonstrated as a dimension of the plate member 21, the dimension of the plate member 21 is not limited to this, It is experimental. When it is desired to obtain a sound insulation effect other than the impact sound in the assumed frequency band, a plate having a different size can be used.

  Furthermore, in the above-described embodiment and Examples 1 and 2, the case where the flooring 14 is directly installed on the floor beam 15 has been described. However, the present invention is not limited to this. The joist may be installed on the floor and the flooring 14 may be installed on the joist.

  And in the said embodiment and Example 1, although the case where the plate member 21 was a rectangle was demonstrated, it is not limited to this, The plate member 21 may be a square, a polygon, a circle, etc. Any shape may be used as long as it is a line-symmetric figure.

  On the contrary, in the second embodiment, the case where the plate member 21 is square has been described. However, the present invention is not limited to this, and the plate member 21 may be rectangular, polygonal, circular, or the like. Any shape may be used as long as it is a line-symmetrical or point-symmetrical figure.

  In the above embodiment, the case where the width of the plate member is 500 (mm) or 600 (mm) and the length is 800 (mm) is described, but the present invention is not limited to this, and the material of the plate member In some cases, the width is 300 to 600 (mm) and the length is 300 to 1200 (mm).

  Furthermore, in the second embodiment, the case where the length of one side of the square plate member is 600 (mm) has been described. However, the length is not limited to this, and the length of one side depends on the material of the plate member. Is most suitable when it is 300-1200 (mm).

It is a perspective view explaining the structure of the damper arrange | positioned at the floor structure of the best embodiment of this invention. It is a perspective view explaining the schematic structure of a unit building. It is a perspective view explaining a structure of the building unit of the best embodiment of the present invention in a partially broken manner. It is sectional drawing explaining the installation position of the damper arrange | positioned at the best embodiment of this invention. It is explanatory drawing explaining the installation position of the damper in a floor structure. It is explanatory drawing explaining the vibration waveform of a floor beam and a plate member. (A) is a vibration waveform of a prior art example, (b) is a vibration waveform of this invention. It is a perspective view explaining the structure of the damper arrange | positioned at the floor structure of Example 1. FIG. It is a perspective view explaining the structure of the damper arrange | positioned at the floor structure of Example 2. FIG. It is the graph which showed the result of the experiment which calculates | requires the optimal length of a board member. It is the graph which showed the result of the experiment which calculates | requires the optimal width | variety of a plate member. It is the graph which showed the result of the experiment which calculates | requires the optimal side length of a square board member.

Explanation of symbols

1,1A Building unit C, C1, C2 Floor structure 12 Floor beam 14 Floor material 15 Floor beam 2, 2A, 2B Damper 21 Plate member 211 Center line (center)
212 Center point 22 Mounting plate (Mounting member)
23 Mounting piece M1, M2 Vibration mode A1, A2 Abdominal position

Claims (5)

A floor structure in which a floor beam is bridged over the floor beam, a floor material is mounted on the floor beam to constitute a floor, and a damper is mounted on the floor beam,
The floor structure is characterized in that the damper is formed by a plate member and is attached to the floor beam along the center of the plate member in the direction perpendicular to the axis of the floor beam.   An attachment member projects from the damper along the center of the plate member in the direction perpendicular to the axis of the floor beam, and the attachment member is attached along the floor beam. Item 2. The floor structure according to Item 1. A floor structure in which a floor beam is bridged over the floor beam, a floor material is mounted on the floor beam to constitute a floor, and a damper is mounted on the floor beam,
The floor is characterized in that the damper is formed by a plate member, and an attachment piece protrudes near the center point of the plate member, and the attachment piece is attached to the floor beam.   The floor structure according to any one of claims 1 to 3, wherein the damper is installed in the vicinity of an antinode position of a vibration mode caused by an impact sound of the floor. A building unit or a unit building comprising the floor structure according to any one of claims 1 to 4.

Images