JP5603656B2 - Vibration control structure - Google Patents

Description

The present invention includes right and left two pillars adjacent to the rectangular framework constituted by the upper and lower pieces of horizontal members, such as foundations, beams, directed to damping structure for assembling the brace via a damper hardware .

In some cases, braces are assembled in a rectangular frame that is composed of two adjacent left and right pillars and two upper and lower horizontal members such as foundations and beams. Further, there is a case where a brace fitting as described in Patent Document 1 is provided between the end of the brace and the corner of the frame.
According to the invention described in Patent Document 1, vibration damping means such as an elastic body and a viscoelastic body provided between the bracing contact portion and the bracing fixing portion is provided between the bracing contact portion and the bracing fixing portion. Deformation is caused by misalignment, and the vibration can be attenuated by the deformation.

Japanese Patent No. 3684129

By the way, when the frame is deformed into a parallelogram due to an earthquake or the like, a pulling force is applied to the braces located between the two acute angle portions of the deformed frame along the axial direction of the braces.
At this time, the above-described vibration damping means is subjected to a pulling force along the axial direction of the braces and deforms so as to expand. Further, when the angle of the corner of the frame is narrowed from a right angle state to an acute angle state, a force is applied in the compression direction.
However, since the elastic body or viscoelastic body as the vibration damping means is provided between the bracing contact portion and the bracing fixing portion as a single unit, even if force is applied in the compression direction in this way, the compression direction It is extremely difficult to deform. Therefore, since vibration damping is mainly performed by deformation of the vibration damping means extending along the axial direction of the braces, the amount of deformation is relatively small and it may be difficult to exert a large damping force.

An object of the present invention has an object to provide an increased thereby vibration damping structure capable of improving the vibration damping function by brace the deformation amount of the vibration damping means.

The invention according to claim 1 is a vibration damping structure, for example, as shown in FIGS. 1 to 7, two adjacent left and right columns 2 and 2 and two upper and lower horizontal members such as a base and a beam. The braces 5 are arranged obliquely in a rectangular frame 1 that is composed of 3 and 4 so as to intersect with the diagonal line 1a of the frame 1 so as to be inclined in the vertical direction.
The opposite ends of the brace 5, the front Symbol corners 1b as a diagonal of the framework 1, are connected will be against the damper hardware 10, 10 fixed to the vicinity 1b,
The damper hardware 10, 10 includes a first fixing plate 12 fixed to the pillars 2, 2,
A second fixing plate 13 that is disposed at a distance from the first fixing plate 12 and is fixed to the horizontal members 3 and 4;
A connecting plate 14 to which an end of the brace 5 is fixed;
A plurality of viscoelastic bodies 11 provided between the connection plate 14 and the first fixed plate 12, and between the connection plate 14 and the second fixed plate 13, respectively.
The viscoelastic body 11 is disposed so as to be separated from both sides with respect to the longitudinal center line of the brace 5 and is deformed by relative displacement between the brace 5 and the frame 1 .

According to the invention described in claim 1, since both ends of the brace 5 are connected to the damper hardware 10, 10 via the viscoelastic body 11, the frame is parallelogram-shaped by an earthquake or the like. The viscoelastic body 11 is deformed in a direction extending along the axial direction of the brace 5 by applying a tensile force along the axial direction of the brace. Further, since the viscoelastic body 11 is divided into a plurality of parts and is arranged on both sides with respect to the longitudinal center line of the brace 5, the frame 1 is deformed and the corners 1 b and 1 b of the frame 1 are deformed. When the angle is narrowed from a right angle state to an acute angle state, the plurality of viscoelastic bodies 11 and 11 are deformed in a direction approaching each other. As a result, the amount of deformation can be increased and a large damping force can be exhibited as compared with the case where the viscoelastic body 11 is simply deformed in a direction extending along the axial direction of the brace 5. it can. Therefore, the vibration damping function can be improved as compared with the conventional case.
Further, in the rectangular frame 1 that is long in the vertical direction, the braces 5 are arranged obliquely so as to intersect with the diagonal line 1a of the frame 1 so as to incline in the vertical direction. Even when the angles of the corners 1b and 1b of the frame 1 are narrowed by the inclination of 2 and 2, it is possible to prevent the end of the brace 5 from hitting the pillars 2 and 2. Accordingly, the brace 5 and the damper hardware 10 can be reliably and effectively functioned.
Further, when the frame 1 is deformed by an earthquake or the like, the brace 5 is displaced, the first fixed plate 12 and the second fixed plate 13 are moved closer to or away from each other, and the displacement of the brace 5 is supported. The connecting plate 14 can be displaced, and the viscoelastic body 11 can be deformed in response to the displacement of each of these parts. Therefore, the connecting plate 14 is simply deformed in a direction extending along the axial direction of the brace 5. Compared to the case, the amount of deformation can be increased, and a large damping force can be exhibited. As a result, the vibration damping function can be improved as compared with the conventional case.

The invention according to claim 2 is the vibration damping structure according to claim 1, for example, as shown in FIG.
The damper hardware 10 is fixed to both the pillar 2 and the horizontal member 3 (4) at the corner 1 b of the frame 1.

  According to the second aspect of the present invention, when the frame 1 is deformed by an earthquake or the like and the brace 5 is displaced, the damper hardware 10 is reliably displaced corresponding to the deformation of the frame 1. Further, since the viscoelastic body 11 can be reliably deformed in response to the displacement of the brace 5, the damping force by the viscoelastic body 11 can be more reliably exhibited. .

The invention according to claim 3 is the vibration damping structure according to claim 1 or 2,
A pair of the braces 5 are arranged in the frame 1, and the pair of braces 5, 5 fixes damper hardware 10 near the four corners 1 b of the frame 1, and between the damper hardware 10. It is hung by erection.

  According to the third aspect of the present invention, the damper hardware 10 is fixed in the vicinity of the four corners 1b of the frame 1, and the pair of braces 5 and 5 are installed between the damper hardware 10 to connect the pair of braces. By attaching the braces 5 and 5 by hooking in the frame 1, it is possible to form the frame 1 having a higher proof strength than the frame 1 in which the single brace 5 is arranged.

The invention according to claim 4 is the vibration damping structure according to any one of claims 1 to 3 , for example, as shown in FIGS.
An interval between the first fixing plate 12 and the second fixing plate 13 is formed so as to gradually increase from the corner 1b of the frame 1 toward the brace 5.

According to the fourth aspect of the present invention, the horizontal member 3 and the horizontal member 4 are separated along the horizontal direction by vibration such as an earthquake, and the columns 2 and 2 are inclined accordingly. When the frame 1 is deformed into a parallelogram shape, the first fixed plate 12 and the second fixed plate 13 are moved around the corner 1b side end portions of the first fixed plate 12 and the second fixed plate 13. The shaft can be rotated to approach. As a result, it is possible to avoid the first fixed plate 12 and the second fixed plate 13 from contacting each other as much as possible, and the first fixed plate 12 and the second fixed plate 13 can be made sufficiently close to each other. The deformation amount of the viscoelastic body 11 can be reliably increased.

The invention according to claim 5 is the vibration damping structure according to any one of claims 1 to 4 , for example, as shown in FIG.
An insertion hole 14c for inserting a screw 14b for fixing the end of the brace 5 is provided in the region 14a of the connection plate 14 where the end of the brace 5 overlaps the region 14a. It is characterized in that a plurality are formed in parallel with each other.

According to the fifth aspect of the present invention, a plurality of insertion holes 14c corresponding to a portion where the connecting plate 14 and the end of the brace 5 overlap from a plurality of insertion holes 14c formed in the region 14a. The braces 5 can be fixed to the connecting plate 14 by appropriately selecting them and inserting the screws 14b through the selected insertion holes 14c. Accordingly, even if the attachment angle of the brace 5 is different for each building to be constructed, it is not necessary to change the number and position of the insertion holes 14c formed in the connection plate 14, and they can be used in common. As a result, an increase in component costs can be suppressed.

According to the present invention, since both ends of the brace are connected to the damper hardware via the viscoelastic body, the frame is deformed into a parallelogram by an earthquake or the like, and the tensile force is along the axial direction of the brace. As a result, the viscoelastic body is deformed in a direction extending along the axial direction of the braces. In addition, the viscoelastic body is divided into a plurality of parts and spaced apart on both sides with respect to the longitudinal center line of the brace, so that the frame is deformed and the angle of the corner of this frame is When narrowing to an acute angle state, the plurality of viscoelastic bodies are deformed in directions approaching each other. As a result, the amount of deformation can be increased and a large damping force can be exhibited as compared with the case where the viscoelastic body is simply deformed in a direction extending along the axial direction of the braces. Therefore, the vibration damping function can be improved as compared with the conventional case.
In addition, the braces are diagonally arranged in the rectangular frame that is long in the vertical direction so as to intersect with the diagonal of the frame in a vertical direction. Even when the angle of the corner of the frame is narrowed, it is possible to prevent the end of the bracing from hitting the pillar. As a result, the braces and damper hardware can be functioned reliably and effectively.

It is a front view which shows an example of the damping structure which concerns on this invention. It is an enlarged front view which shows the corner part vicinity of a framework. It is AA sectional drawing in FIG. It is the schematic which shows the state which a frame deform | transforms with a vibration. (A) shows the deformation | transformation state of the damper metal fitting accompanying a deformation | transformation of a framework, (b) is a B arrow view of (a), and shows the viscoelastic body accompanying the deformation | transformation of a damper metal fitting in the case of including a connection plate. It is the schematic which shows a deformation | transformation state. It is the schematic which shows the deformation | transformation state of the viscoelastic body accompanying the displacement of bracing. It is the schematic which shows the deformation | transformation state of a damper metal fitting and a viscoelastic body accompanying the displacement of bracing. It is a figure which shows the hysteresis loop at the time of performing the sine wave vibration which produces the shear deformation of a viscoelastic body. It is a figure for demonstrating the shear strain rate (gamma) of a viscoelastic body.

Embodiments of the present invention will be described below with reference to the drawings.
FIG. 1 is a front view showing an example of a vibration control structure according to the present invention.
In FIG. 1, reference numeral 1 denotes a framework. This framework 1 constitutes a wall of a building such as a house, and is composed of two adjacent pillars 2 and 2 and two horizontal members 3 and 4 such as a base and a beam. Yes. The frame 1 is formed in a rectangular shape that is long in the vertical direction when viewed from the front, that is, a vertically long rectangular shape. A portion where the pillars 2 and 2 and the horizontal members 3 and 4 intersect in the framework 1 is referred to as a corner 1b.
Furthermore, the braces 5 are diagonally arranged in the framework 1 so as to intersect with the diagonal line 1a of the framework 1 while being inclined in the vertical direction.
Both ends of the brace 5 are connected to damper hardware 10 and 10 fixed in the vicinity of corners 1b and 1b that are opposite to the frame 1.

The horizontal member 3 is a beam, and the horizontal member 4 is a base. Further, the horizontal member 4 as a base is fixed to the foundation 6 with anchor bolts 6a. The horizontal member 4 is not limited to a base, but may be a base or a beam.
And the said pillars 2 and 2 and the horizontal members 3 and 4 are joined using the joining metal object 7 formed in the front view V shape.

The damper hardwares 10 of the present embodiment are fixed to the pillars 2 and 2 and the horizontal members 3 and 4 at the corners 1b and 1b of the frame 1, respectively.
Further, the damper hardware 10 is arranged with a first fixing plate 12 fixed to the pillars 2 and 2, an interval (gap 15) from the first fixing plate 12, and the horizontal member 3. 4, the connection plate 14 to which the end of the bracing 5 is fixed, and between the connection plate 14 and the first fixed plate 12, the connection plate 14 and the second fixing plate 12. Viscoelastic bodies 11 provided between the fixed plate 13 and the fixed plate 13 are provided.

As shown in FIG. 2, the first fixing plate 12 and the second fixing plate 13 are formed and arranged so as to be symmetrical with respect to a gap 15 between them.
The first fixed plate 12 and the second fixed plate 13 are shaped such that one corner of a right triangle plate is cut in a front view. The first fixed plate 12 and the second fixed plate 13 are arranged such that the cut portions are located on the center side of the frame 1.
The sides constituting the cut portions of the first fixed plate 12 and the second fixed plate 13 are arranged in a straight line before the frame 1 is deformed as shown in FIGS. The both ends of the brace 5 are in a state of being cut obliquely along the sides arranged on these straight lines. That is, the diagonally cut side surfaces of both ends of the brace 5 are opposed to the side surfaces of the sides constituting the cut portions of the first fixed plate 12 and the second fixed plate 13 before the frame 1 is deformed. .

The distance between the first fixed plate 12 and the second fixed plate 13 is formed so as to gradually increase from the corner 1b of the frame 1 toward the brace 5.
In the present embodiment, the fixing plate that is fixed to the pillars 2 and 2 is the first fixing plate 12, and the fixing plate that is fixed to the horizontal members 3 and 4 is the second fixing plate. 13

In addition, the first fixed plate 12 and the second fixed plate 13 include contact plate portions 12a and 13a that contact the pillar 2 and the horizontal member 3 (4) that contact each other. The first fixed plate 12 and the second fixed plate 13 are formed by inserting screws 12b and 13b through insertion holes (not shown) formed in the contact plate portions 12a and 13a, and the columns 2 and the horizontal members. It is fixed to the pillar 2 and the horizontal member 3 (4) by being screwed into 3 (4).
Further, as shown in FIGS. 2 and 3, the contact plate portions 12 a and 13 b are both from the column 2 side end and the horizontal members 3 and 4 side end of the first and second fixing plates 12 and 13. It is provided so as to protrude toward one side in the wall thickness direction.

  The connection plate 14 is disposed so as to overlap the vicinity of the cut portions of the first fixed plate 12 and the second fixed plate 13, and between the connection plate 14 and the first fixed plate 12. The viscoelastic body 11 is provided between the connecting plate 14 and the second fixed plate 13.

Further, in this connection plate 14, an insertion hole 14 c for inserting a screw 14 b for fixing the end of the brace 5 is provided in the region 14 a where the connection plate 14 and the end of the brace 5 overlap. A plurality are formed in parallel in 14a. Therefore, a plurality of insertion holes 14c corresponding to a portion where the connecting plate 14 and the end of the brace 5 overlap are appropriately selected from the plurality of insertion holes 14c formed in the region 14a. Screws 14b... Can be inserted into the insertion holes 14c.
As shown in FIG. 1, before the deformation of the frame 1, the connecting plate 14 is arranged so that the center line thereof coincides with the substantially middle angle of the corner 1b, that is, the angle of 45 degrees. Has been. The center line of the connection plate 14 refers to a center line that can be divided into the left and right sides of the connection plate 14 on one viscoelastic body 11 side and the other viscoelastic body 11 side.
That is, the first fixed plate 12 and the second fixed plate 13 are formed to have a symmetrical shape, and the connecting plate 14 is arranged as described above. Even if the frame 1 is deformed and the angle of the corner 1b is narrowed, it is difficult to hit the pillar 2 or the horizontal member 3. As described above, the connecting plate 14 is less likely to hit the pillar 2 or the horizontal member 3, so that it is possible to prevent both ends of the brace 5 from hitting the pillars 2 and 2. Accordingly, the brace 5 and the damper hardware 10 can be reliably and effectively functioned.

  The viscoelastic body 11 is formed in a quadrangular prism shape, and is bonded to the surface of the connection plate 14, the surface of the first fixing plate 12, and the surface of the second fixing plate 13 by an adhesive or vulcanization adhesion. Bonded and fixed.

  In the viscoelastic body 11 of the present embodiment, 100 to 150 parts by weight of silica is added to 100 parts by weight of the base rubber having a C—C bond in the main chain, and 10 to 30 silane compounds are added to the silica. It is formed of a high damping rubber blended in weight percent.

Below, a viscoelastic material is demonstrated.
A general viscoelastic material increases in rigidity and resistance as the amplitude increases. If a viscoelastic body having the property that the rigidity increases as the amplitude increases, the acceleration response of the building and the stress of each part are excessively increased. Therefore, it is desirable to use a viscoelastic body having a property that the increase in rigidity reaches a peak even when the amplitude increases. In particular, in the present invention, since the viscoelastic body is subjected to a large shear deformation as compared with the amplitude of the vibration acting on the building, the effect of using the above-mentioned property with respect to strain dependency is great.

Also, since it is necessary to function in a wide range of amplitudes from environmental vibrations such as traffic vibrations to wind fluctuations during typhoons and large earthquakes, viscoelastic bodies with low strain dependence are used. That is, a material that exhibits a stable vibration energy absorption ability from a small strain to a large strain is used.
Specifically, a stable energy absorption capability of Heq> 0.20 is required in the region of 0.01 ≦ γ ≦ 3.5. Therefore, Keq / (S / D) decreases as γ increases in a region where γ> 1.0 so that the resistance force does not increase in the large amplitude region. For example, 0.45 ≦ { It is preferable to use a viscoelastic body of Keq / (S / D) _{(γ = 3.0)} } / {Keq / (S / D) _{(γ = 1.0)} } <0.75.

Here, γ is a shear strain rate, and is obtained by dividing the shear deformation amount d of the viscoelastic body by the height t of the viscoelastic body, as shown in FIG. The equivalent viscous damping coefficient (equivalent damping constant) (Heq) and the equivalent shear modulus (Geq = Keq / (S / D)) in the dynamic viscoelasticity test are sine waves that cause shear deformation of the viscoelastic material. Excitation is performed, a history loop (hysteresis curve) at that time is measured, and calculation is performed based on the result. If it demonstrates based on FIG. 9, Heq is a numerical value calculated by the following formula (Formula 1), and Keq / (S / D) is a numerical value calculated by the following formula (Formula 2).
Heq = ΔW / 2πW (Equation 1),
W: elastic energy of shear deformation (area of two triangles shown in FIG. 9, unit is kgf · cm),
ΔW = total energy absorbed by shear deformation (area surrounded by hysteresis curve shown in FIG. 9, unit is kgf · cm),
Keq / (S / D) = F / U _pressure / (S / D) (Equation 2),
F: Load when giving maximum displacement (unit is kgf),
U _Be : Maximum displacement (unit: cm),
S / D: Shape factor of the test sample (sample shear area / sample shear gap, unit is cm)

In general viscoelastic materials, Geq (= Keq / (S / D)) [N / mm ² ] significantly increases with an increase in vibration frequency. For example, in a general viscoelastic body, at 20 ° C., the value of Geq increases 2 to 3 times at 0.1 Hz and at 2.0 Hz. The dominant frequency of traffic vibration is distributed between 4Hz and 7Hz, and the ground vibration is distributed between 0.1Hz and 20Hz, so viscoelasticity has relatively stable properties in terms of rigidity and damping performance against these frequencies. It is desirable to use the body. Specifically, it is necessary to deal with earthquake motions that have a wider input frequency distribution region. The damping performance imparted to the house by the damping material is generally the product of the rigidity of the damping material (here, the equivalent shear modulus (Geq)) and the damping constant (here, the equivalent viscous damping constant (equivalent damping constant) Heq). Can be expressed as Evaluation of frequency dependence may be performed within a range of ± 50% within the range of 0.1 Hz to 20 Hz of the above-described ground vibration with reference to the time when the value of the product is a certain frequency under a certain temperature condition. .

In general, viscoelastic bodies have high rigidity at low temperatures and low rigidity at high temperatures. In Japan, it is desirable to use a viscoelastic body having a relatively stable property in terms of rigidity and damping performance over a temperature range of about −10 ° C. to 40 ° C. since the temperature changes greatly throughout the year.
For example, if the use environment of the vibration damping structure according to the present invention is −10 ° C. to 40 ° C., the equivalent shear modulus when the low temperature side is −10 ° C. is based on Geq (equivalent shear modulus) at 20 ° C. Ratio of Geq (t = −10 ° C.) to equivalent shear modulus Geq (t = 20 ° C.) at 20 ° C., Geq (t = −10 ° C.) / Geq (t = 20 ° C.) ≦ 2.2 The high temperature side is the ratio of the equivalent shear modulus Geq (t = 40 ° C.) at 40 ° C. to the equivalent shear modulus Geq (t = 20 ° C.) at 20 ° C., Geq (t = 40 ° C.) / It is preferable that Geq (t = 20 ° C.) ≧ 0.6.

In the present embodiment, the viscoelastic body has, for example, silica based on 100 parts by weight of the base rubber having a C—C bond in the main chain in order to have the above-described strain dependency, frequency dependency, and temperature dependency. 100 to 150 parts by weight is added, and a high damping rubber containing 10 to 30% by weight of a silane compound based on the silica is used. As an example of such a suitable viscoelastic body, 135 parts by weight of silica is added to 100 parts by weight of the base rubber, and 17% by weight of a silane compound is added to the silica. According to this viscoelastic body, the above-described strain dependency, frequency dependency, and temperature dependency can be provided, and the function of the above-described vibration damping structure can be sufficiently exhibited.
In particular, the performance at 20 ° C. is in the range of Heq ≧ 0.2, 0.35 ≦ Geq ≦ 6.0 (N / mm ² ), and the temperature dependence of Geq is −10 ° C./20° C. ≦ 2.2, 40 ° C./20° C. ≧ 0.6 (both at a frequency of 0.1 Hz and a shear strain of ± 100%), and as described above, the viscoelastic body of the damping member is greatly shear deformed. The functions of the vibration damping structure can be fully exhibited.

〔式中、R¹、R²、R³およびR⁴のうち少なくとも１つはアルコキシ基、またはハロゲン原子を示し、他は同一または異なって水素原子、アルキル基またはアリール基を示す。〕で表されるシラン化合物とを含有するゴム組成物の加硫成形により形成される。また、基材ゴムとしては、主鎖にC−C結合を有する種々のゴムがいずれも使用可能である。具体的には天然ゴム（NR）の他、イソプレンゴム（IR）、ブタジエンゴム（BR）、スチレン−ブタジエン共重合ゴム（SBR）、エチレン−プロピレン共重合ゴム（EPM）、アクリロニトリル−ブタジエン共重合ゴム（NBR）、ブチルゴム（IIR）などが挙げられる。これらはそれぞれ単独で使用される他、２種類以上を併用することもできる。 The silane compound has the following general formula:

[Wherein, at least one of R ¹ , R ² , R ³ and R ⁴ represents an alkoxy group or a halogen atom, and the other represents the same or different and represents a hydrogen atom, an alkyl group or an aryl group. It is formed by vulcanization molding of a rubber composition containing a silane compound represented by the formula: As the base rubber, any of various rubbers having a C—C bond in the main chain can be used. Specifically, in addition to natural rubber (NR), isoprene rubber (IR), butadiene rubber (BR), styrene-butadiene copolymer rubber (SBR), ethylene-propylene copolymer rubber (EPM), acrylonitrile-butadiene copolymer rubber. (NBR), butyl rubber (IIR) and the like. These may be used alone or in combination of two or more.

As the silica added to the base rubber, various hydrophilic or hydrophobic silicas used as rubber reinforcing agents can be used. The addition amount of the silica is limited to 10 to 150 parts by weight with respect to 100 parts by weight of the base rubber. The reason for this is as described above.
In the silane compound represented by the general formula (1), examples of the alkoxy group corresponding to R ^{1 to} R ⁴ include those having various carbon numbers represented by C _n H _{2n + 1} O. Preferable examples include methoxy and ethoxy having 1 to 2 carbon atoms. Examples of the halogen atom include fluorine, chlorine, bromine and the like.

Examples of the alkyl group include those having various carbon numbers represented by C _n H _{2n + 1} , and the carbon number is particularly preferably about 1 to 20. Examples of the alkyl group include methyl, ethyl, n-propyl, isopropyl, n-butyl, isobutyl, secondary butyl, tertiary butyl, pentyl, hexyl, octyl, nonyl, decyl, undecyl, dodecyl and the like. It is done.
Examples of the aryl group include phenyl, tolyl, xylyl, biphenyl, o-terphenyl, naphthyl, anthryl, phenanthryl and the like. Specific examples of such silane compounds include, but are not limited to, n-hexyltrimethoxysilane, triethoxyphenylsilane, diethoxydimethylsilane, dimethyldichlorosilane, methyldichlorosilane, and the like.

  In addition to the above, the rubber composition includes, for example, a vulcanizing agent, a vulcanization accelerator, a vulcanization acceleration aid, a vulcanization retarder, a reinforcing agent other than silica, a filler, a softening agent, a plasticizer, and a tackifier. In addition, various additives may be added. Among these, examples of the vulcanizing agent include sulfur, organic sulfur-containing compounds, and organic peroxides. Among these, examples of the organic sulfur-containing compound include N, N′-dithiobismorpholine. Examples of organic peroxides include benzoyl peroxide and dicumyl peroxide.

  Examples of the vulcanization accelerator include thiuram vulcanization accelerators such as tetramethylthiuram disulfide and tetramethylthiuram monosulfide, zinc dibutyldithiocarbamate, zinc diethyldithiocarbamate, sodium dimethyldithiocarbamate, Dithiocarbamic acids such as tellurium diethyldithiocarbamate, thiazoles such as 2-mercaptobenzothiazole and N-cyclohexyl-2-benzothiazolesulfenamide, thioureas such as trimethylthiourea and N, N′-diethylthiourea Organic promoters, or inorganic promoters such as slaked lime, magnesium oxide, titanium oxide, and risurge (PbO) can be used.

  Examples of the vulcanization acceleration aid include fatty acids such as stearic acid, oleic acid and cottonseed fatty acid, and metal oxides such as zinc white. Examples of the vulcanization retarder include aromatic organic acids such as salicylic acid, phthalic anhydride, and benzoic acid, N-nitrosodiphenylamine, N-nitroso-2,2,4-trimethyl-1,2-dihydroquinone, and N-nitrosophenyl. And nitroso compounds such as -β-naphthylamine.

  The total amount of the vulcanizing agent, vulcanization accelerator, vulcanization acceleration aid and vulcanization retarder is preferably about 4 to 15 parts by weight with respect to 100 parts by weight of the base rubber. Examples of the antioxidant include imidazoles such as 2-mercaptobenzimidazole, phenyl-α-naphthylamine, N, N′-di-β-naphthyl-p-phenylenediamine, and N-phenyl-N′-isopropyl-p-. Examples thereof include amines such as phenylenediamine, and phenols such as di-t-butyl-p-cresol and styrenated phenol.

  The blending amount of the antioxidant is preferably about 1.5 to 5 parts by weight with respect to 100 parts by weight of the base rubber. Carbon black is mainly used as a reinforcing agent other than silica, and inorganic reinforcing agents such as silicate-based white carbon, zinc white, surface-treated precipitated calcium carbonate, magnesium carbonate, talc, clay, or the like. Organic reinforcing agents such as malon indene resin, phenol resin, and high styrene resin (styrene-butadiene copolymer having a high styrene content) can also be used.

Examples of the filler include calcium carbonate, clay, barium sulfate, and diatomaceous earth. The blending amount of the reinforcing agent and / or filler other than silica is preferably about 5 to 50 parts by weight with respect to 100 parts by weight of the base rubber. Examples of the softener include vegetable oil-based, mineral oil-based, and synthetic softeners such as fatty acids (stearic acid, lauric acid, etc.), cottonseed oil, tall oil, asphalt substances, and paraffin wax.
The blending amount of the softening agent is preferably about 10 to 100 parts by weight with respect to 100 parts by weight of the base rubber. Examples of the plasticizer include various plasticizers such as dibutyl phthalate, dioctyl phthalate, and tricresyl phosphate. As for the compounding quantity of a plasticizer, about 5-20 weight part is preferable with respect to 100 weight part of base rubber.
Furthermore, examples of the tackifier include coumarone / indene resin, aromatic resin, aromatic / aliphatic mixed resin, rosin resin, and cyclopentadiene resin. The compounding amount of the tackifier is preferably about 5 to 50 parts by weight with respect to 100 parts by weight of the base rubber.

  In addition to the above, for example, a dispersant, a solvent and the like may be appropriately blended in the rubber composition. The rubber composition is produced by kneading the above components using, for example, a closed kneader. The viscoelastic body is formed, for example, by molding the rubber composition into a sheet shape using a roller head extruder or the like, punching out the sheet so as to have a predetermined shape, and then cutting the punched sheet into a predetermined thickness. Thus, in a state where a plurality of sheets are laminated, they are manufactured by heating and vulcanization molding in a predetermined mold.

The damper hardware 10, 10 provided with the viscoelastic body 11 as described above includes the frame 1 by attaching the first fixed plate 12 to the columns 2, 2 and the second fixed plate 13 to the horizontal members 3, 4. Are fixed to the corners 1b and 1b which are opposite to each other.
Further, since the gap 15 is formed between the first fixed plate 12 and the second fixed plate 13 and the gap 15 is formed between the first fixed plate 12 and the second fixed plate 13, rolling occurs in the building. The damper hardware 10, 10 has a mounting structure that does not suppress the relative deformation angle between the columns 2, 2 and the horizontal members 3, 4.
And both ends of the brace 5 are attached to the damper hardwares 10 and 10 via the viscoelastic body 11 and the connecting plate 14, respectively.

  In the present embodiment, the damper hardware 10, 10 includes a viscoelastic body 11, a first fixing plate 12, a second fixing plate 13, and a connecting plate 14, respectively. Although the corners 1b and 1b are fixed to the pillars 2 and 2 and the horizontal members 3 and 4, the present invention is not limited to this. That is, the damper hardwares 10 and 10 may have different forms and may be fixed to the horizontal members 3 and 4 with a space from the pillars 2 and 2, and conversely with the horizontal members 3 and 4. It is good also as a form fixed to the pillars 2 and 2. However, even if different types of damper hardware are used, the brace 5 is arranged in the frame 1 so as to intersect the diagonal line 1 a of the frame 1.

Further, in the present embodiment, one brace 5 is arranged in the frame 1, but the present invention is not limited to this, and a pair of braces 5, 5 are arranged in the frame 1. The pair of braces 5 and 5 may be hooked by laying between damper hardware 10 fixed in the vicinity of the four corners 1b of the frame 1.
As a result, it is possible to form the frame 1 having higher proof strength than the frame 1 in which one brace 5 is arranged. Therefore, the braces 5 can be hooked at places where high proof stress is required in the building frame.
In addition, by thickening one brace 5, it is possible to act on both compression and tension. As a result, the frame 1 having a high yield strength can be formed even with the frame 1 in which one brace 5 is arranged.

Further, the columns 2 and 2 and the horizontal members 3 and 4 of the present embodiment are made of wood, and the framework 1 composed of the columns 2 and 2 and the horizontal members 3 and 4 is a building housing of a wooden house. It is considered as an element that composes. That is, the vibration damping structure of the present embodiment is introduced into a wooden house.
Moreover, it is not restricted to this, You may introduce the damping structure of this Embodiment also to a steel-framed house.

Next, the operation of the vibration damping structure of the present embodiment will be described.
First, the state shown in FIGS. 1 to 3 is a state where no earthquake occurs, the brace 5 is not displaced, and the viscoelastic body 11 is not deformed.
And when a vibration generate | occur | produces in a building by an earthquake, a deformation | transformation will arise in the frame surface enclosed by the pillars 2 and 2 and the horizontal members 3 and 4. That is, as shown in FIG. 4, the horizontal member 3 and the horizontal member 4 are separated along the horizontal direction by vibration such as an earthquake, and the columns 2 and 2 are inclined accordingly. The frame 1 is deformed into a parallelogram shape.

At this time, as shown in FIG. 5A, the first fixed plate 12 and the second fixed plate 13 use the gap 15 to make corners of the first fixed plate 12 and the second fixed plate 13. It approaches so that it may rotate centering on the part 1b side edge part vicinity.
Further, as shown in FIG. 5B, the viscoelastic bodies 11 and 11 are deformed so as to approach each other in response to the approach of the first fixed plate 12 and the second fixed plate 13. become.

  Further, as shown in FIG. 4, the bracing 5 is in a state where it intersects with a diagonal line 1 a arranged between one corner 1 b of the frame 1 and the other corner 1 b while being inclined in the vertical direction. The force is applied in the pulling direction.

Further, the connecting plates 14 and 14 fixed to both ends of the brace 5 move in a direction away from the first fixed plate 12 and the second fixed plate 13.
In response to this, the viscoelastic bodies 11, 11 are deformed so as to extend in the diagonal line 1a direction as shown in FIG.

That is, the viscoelastic bodies 11 and 11 are deformed so as to approach each other in response to the approach of the first fixed plate 12 and the second fixed plate 13 and extend along the axial direction of the brace 5. 7 and deformed in such a manner that it is twisted in opposite directions as shown in FIG.
Immediately after deformation occurs in the viscoelastic bodies 11 and 11, the viscoelastic bodies 11 and 11 absorb vibration energy, so that vibration can be suppressed.

According to the present embodiment, the viscoelastic body 11 extends along the axial direction of the brace 5 by deforming the frame into a parallelogram shape due to an earthquake or the like and applying a tensile force along the brace axial direction. Deforms in the direction of extension. Further, the viscoelastic bodies 11 and 11 are deformed in a direction approaching each other. As a result, the amount of deformation can be increased and a large damping force can be exhibited as compared with the case where the viscoelastic bodies 11 and 11 are simply deformed in a direction extending along the axial direction of the brace 5. be able to. Therefore, the vibration damping function can be improved as compared with the conventional case.
Further, in the rectangular frame 1 that is long in the vertical direction, the braces 5 are arranged obliquely so as to intersect with the diagonal line 1a of the frame 1 so as to be inclined in the vertical direction. Even when the angles of the corners 1b and 1b of the frame 1 are narrowed by the inclination of 2 and 2, it is possible to prevent the end of the brace 5 from hitting the pillars 2 and 2. Accordingly, the brace 5 and the damper hardware 10 can be reliably and effectively functioned.

  Further, since the damper hardware 10 and 10 are fixed to the pillars 2 and 2 and the horizontal members 3 and 4 at the corners 1b and 1b of the frame 1, respectively, the frame 1 is deformed by an earthquake or the like. When the brace 5 is displaced, the damper hardware 10 can be reliably displaced or deformed corresponding to the deformation of the frame 1, and the viscoelastic body 11 is Since it can be reliably deformed corresponding to the displacement, the damping force by the viscoelastic body 11 can be more reliably exhibited.

  The damper hardware 10 is disposed at a distance from the first fixed plate 12 fixed to the pillars 2 and 2 and the first fixed plate 12 and is fixed to the horizontal members 3 and 4. A second fixing plate 13, a connecting plate 14 to which an end of the brace 5 is fixed, and between the connecting plate 14 and the first fixing plate 12, the connecting plate 14 and the second fixing plate 13 Since the viscoelastic body 11 is provided between the first fixing plate 12 and the second fixing plate, the bracing 5 is displaced when the frame 1 is deformed by an earthquake or the like. 13 can be moved closer to or away from each other, or the connecting plate 14 can be displaced in response to the displacement of the brace 5. The viscoelastic body 11 can be moved in accordance with the displacement of these parts. Since it is possible to form simply as compared with the case where deformed in a direction extending along the axial direction of the braces 5 can be the amount of deformation can be increased, it exerts a large damping force. As a result, the vibration damping function can be improved as compared with the conventional case.

  Further, since the distance between the first fixed plate 12 and the second fixed plate 13 is formed so as to gradually increase from the corner 1b of the frame 1 to the brace 5, When the horizontal member 3 and the horizontal member 4 are separated from each other in the horizontal direction due to vibrations such as, the frame 1 is deformed into a parallelogram so that the columns 2 and 2 are inclined. In addition, the first fixed plate 12 and the second fixed plate 13 can be brought closer to each other so as to rotate around the corner 1b side end portions of the first fixed plate 12 and the second fixed plate 13. . As a result, it is possible to avoid the first fixed plate 12 and the second fixed plate 13 from contacting each other as much as possible, and the first fixed plate 12 and the second fixed plate 13 can be made sufficiently close to each other. The deformation amount of the viscoelastic body 11 can be reliably increased.

  Further, in the connecting plate 14, an insertion hole 14 c for inserting a screw 14 b for fixing the end of the brace 5 is provided in a region 14 a where the connecting plate 14 and the end of the brace 5 overlap. A plurality of insertion holes 14c are formed so as to be arranged in parallel in 14a, so that the insertion corresponding to the portion where the connection plate 14 and the end of the brace 5 overlap is inserted from the plurality of insertion holes 14c formed in the region 14a. A plurality of holes 14c are appropriately selected, and the braces 5 can be fixed to the connecting plate 14 by inserting the screws 14b... Into the selected plurality of insertion holes 14c. Accordingly, even if the attachment angle of the brace 5 is different for each building to be constructed, it is not necessary to change the number and position of the insertion holes 14c formed in the connection plate 14, and they can be used in common. As a result, an increase in component costs can be suppressed.

DESCRIPTION OF SYMBOLS 1 Frame 1a Diagonal line 1b Corner part 2 Column 3 Horizontal member 4 Horizontal member 5 Bracing 10 Damper hardware 11 Viscoelastic body

Claims (5)

In a vertically long rectangular frame composed of two adjacent left and right pillars and two upper and lower horizontal members such as foundations and beams, it intersects diagonally with respect to the diagonal of this frame. The braces are arranged diagonally,
The opposite ends of the brace is made are coupled by pairs before Symbol damper hardware that is fixed to the vicinity of the corner portion serving as a diagonal of the framework,
The damper hardware is a first fixing plate fixed to the pillar,
A second fixed plate that is disposed at a distance from the first fixed plate and is fixed to the horizontal member;
A connecting plate to which the ends of the braces are fixed;
A plurality of viscoelastic bodies provided between the connection plate and the first fixed plate, and between the connection plate and the second fixed plate, respectively,
The viscoelastic body is disposed on both sides with respect to the longitudinal center line of the brace and is deformed by relative displacement between the brace and the frame . In the vibration damping structure according to claim 1,
The damper hardware is fixed to both the pillar and the horizontal member at a corner of the frame. In the vibration damping structure according to claim 1 or 2,
A pair of the braces are arranged in the frame, and the pair of braces are hooked by fixing damper hardwares near the four corners of the frame and laying between the damper hardwares. Characteristic damping structure. In the damping structure as described in any one of Claims 1-3 ,
The damping structure according to claim 1, wherein an interval between the first fixed plate and the second fixed plate is formed so as to gradually increase from a corner of the frame toward a brace. In the damping structure as described in any one of Claims 1-4 ,
In the connection plate, a plurality of insertion holes for inserting screws for fixing the end of the brace are formed in a region where the connection plate and the end of the brace overlap. Damping structure characterized by being made.

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