JP6013766B2 - Vibration isolator - Google Patents

Description

  The present invention relates to a vibration isolator that prevents vibration of an object from being transmitted to a support side that supports the object.

  2. Description of the Related Art Conventionally, a vibration isolator that prevents a vibration of an object from being transmitted to a support side that supports the object is known. As such a vibration isolator, for example, as disclosed in Patent Document 1, a vibration isolator that elastically supports an upper floor of a double floor with an elastic material such as rubber is known. The vibration isolator is disposed on the lower floor and elastically supports a support bolt fixed to the lower side of the upper floor.

  As another configuration of the vibration isolator, for example, as disclosed in Patent Document 2, a configuration in which a vibration isolating rubber is disposed on a concrete slab and a vibration damping board and a flooring are disposed thereon is also known. ing.

JP 2011-246906 A JP 2007-107209 A

  By the way, in the case of the vibration isolator arranged under the floor as in Patent Document 1, if an attempt is made to reduce the low frequency vibration that occurs when a person jumps on the floor, the elastic member of the vibration isolator can be easily It is necessary to have a deformable configuration. However, when a lump of rubber as in Patent Document 1 is used in a vibration isolator, sufficient rubber deformation cannot be obtained with respect to low frequency vibration in a state where a light load such as an upper floor is applied, There is a possibility that low frequency vibrations cannot be reduced.

  Therefore, as in Patent Document 2, a heavy ground such as a heavy board or concrete is formed on the vibration isolator, and a predetermined initial load is applied to the vibration isolator.

  In this way, if an anti-vibration device that can absorb vibrations at a low frequency is to be installed under the floor, it is necessary to form a heavy ground on the anti-vibration device, so the installation work of the anti-vibration device is complicated. In addition, large-scale construction is required.

  Therefore, an object of the present invention is to obtain a configuration of a vibration isolator that can reduce vibrations having a low frequency and can be installed by simple construction.

  A vibration isolator according to an embodiment of the present invention includes a columnar laminated body, and the laminated body has a plurality of elastic members formed in a flat plate shape and a longitudinal elastic modulus larger than that of the plurality of elastic members. A flat plate member, and the flat plate member is disposed so as to be sandwiched between the elastic member and the elastic member with respect to the plurality of elastic members, and at least one elastic member of the plurality of elastic members is: A recess is provided on at least one surface in the thickness direction (first configuration).

  In the above configuration, since the elastic member formed in a flat plate shape and the flat plate member having a longitudinal elastic modulus larger than that of the elastic member are alternately stacked in the thickness direction, a force is input to the stacked body in the stacking direction. The elastic member is likely to be deformed. Thereby, it becomes possible to reduce the vibration of a low frequency with a vibration isolator. Moreover, since at least one elastic member among the plurality of elastic members has a recess on at least one surface in the thickness direction, the surface area of the elastic member can be increased. Therefore, the elastic member is more likely to be deformed, and a vibration isolator capable of reducing vibrations having a lower frequency is obtained.

  In the first configuration, the concave portion is formed on the at least one elastic member so that rigidity in the stacking direction of the stacked body is equal over the entire periphery of the stacked body when viewed from the stacking direction of the stacked body. It is preferably formed (second configuration).

  Thereby, when a force is applied to the laminated body of the vibration isolator in the lamination direction of the laminated body, the laminated body is uniformly deformed in the lamination direction on the entire circumference thereof. Therefore, it is possible to realize a vibration isolator that can stably obtain a predetermined vibration reduction characteristic.

  Here, the rigidity of the laminated body in the stacking direction is the same throughout the entire circumference of the laminated body, not only when the rigidity is the same, but also within a range of rigidity that causes uniform deformation of the laminated body in the stacking direction over the entire circumference. means.

  In the first or second configuration, the recess is preferably formed on both surfaces in the thickness direction of the at least one elastic member (third configuration).

  By doing so, the elastic member can be easily deformed in the thickness direction. Therefore, a vibration isolator capable of reducing vibrations having a lower frequency can be obtained.

  In any one of the first to third configurations, the concave portion preferably includes a groove (fourth configuration). Thereby, the recessed part which makes a deformation | transformation of this elastic member easy can be continuously formed in an elastic member. Therefore, the elastic member can be easily deformed.

  In the fourth configuration, it is preferable that the concave portion includes a plurality of linear grooves formed in parallel to each other (fifth configuration). By doing so, the entire elastic member can be easily deformed in the thickness direction.

  In the fourth or fifth configuration, the stacked body includes a plurality of flat plate members, the plurality of elastic members each include the groove portion, and the plurality of elastic members are stacked in the stacked body. When viewed from the direction, the angle formed by the grooves formed in each of the pair of elastic members arranged with one flat plate member sandwiched between the plurality of flat plate members, and the other flat plate member among the plurality of flat plate members. It is preferable that the angles formed by the groove portions formed in the pair of elastic members that are sandwiched by each other are the same (sixth configuration).

  Thus, even when a linear groove is provided on at least one surface in the thickness direction of each elastic member, the rigidity in the stacking direction of the stacked body is substantially equal over the entire circumference of the stacked body as viewed from the stacking direction of the stacked body. It becomes possible to do. Therefore, with the above-described configuration, it is possible to realize a vibration isolator that can stably obtain a predetermined vibration reduction characteristic even when a linear groove is provided.

  In the fourth or fifth configuration, the groove is formed on both surfaces in the thickness direction of the at least one elastic member, and the groove formed on one surface in the thickness direction of the elastic member is As viewed from the stacking direction of the stacked body, it is preferable to intersect the groove formed on the other surface in the thickness direction of the elastic member (seventh configuration).

  Thereby, the dispersion | variation in the rigidity of the thickness direction of an elastic member can be reduced compared with the structure which provides a groove | channel only in the surface of one side of an elastic member. Therefore, it is possible to reduce the variation in rigidity in the stacking direction of the stacked body, and to realize a vibration isolator capable of obtaining a predetermined vibration reducing characteristic more stably.

  In any one of the first to seventh configurations, it is preferable that the stacked body has a through-hole penetrating the plurality of elastic members and the flat plate member (eighth configuration).

  Thus, the outer diameter of the laminate can be increased so that the laminate does not buckle without increasing the pressure receiving area where the laminate receives force. That is, if the outer diameter of the laminate is small, buckling is likely to occur. On the other hand, when the outer diameter of the laminated body is increased in order to prevent buckling, the pressure receiving area of the laminated body is increased and the laminated body is not easily deformed. On the other hand, the elastic member of the laminated body can be easily deformed while having an outer diameter that does not buckle by forming the laminated body with a through-hole as in the above-described configuration. . Therefore, with the above-described configuration, it is possible to achieve both prevention of buckling of the laminate and reduction of vibration at a low frequency.

  In the eighth configuration, a pair of support plates positioned at both ends in the stacking direction of the laminate, a connection member that connects the support plates to each other in the through hole of the laminate, the connection member, and the pair It is preferable to further include a vibration suppressing member that is disposed between at least one of the support plates and suppresses transmission of vibration between the pair of support plates (ninth configuration).

  When a large impact force is applied to the laminated body including the elastic member in the compression direction, there is a possibility that the elastic member and the flat plate member constituting the laminated body are separated in the lamination direction due to the reaction. On the other hand, the elastic member and the flat plate member of the laminated body are separated from each other in the laminating direction by connecting the pair of support plates positioned at both ends in the laminating direction of the laminated body with the connecting members as in the above-described configuration. Can be prevented. Therefore, it can prevent that the elastic member and flat plate member of a laminated body isolate | separate to a lamination direction by reaction of the impact applied to the laminated body in the compression direction.

  Moreover, since the vibration suppressing member is disposed between the connection member and at least one of the pair of support plates, it is possible to prevent vibration from being transmitted between the pair of support plates via the connection member.

  In the ninth configuration, at least one of the pair of support plates has a support portion extending inward of the through hole of the stacked body, and the connection member includes the support portion and the other support member. It is preferable to connect the support plate (tenth configuration).

  Thereby, it can prevent by a support part that the elastic member and flat plate member of a laminated body move to the direction which cross | intersects the lamination direction of this laminated body. Therefore, it can prevent by a support part that a laminated body collapses in the direction which cross | intersects a lamination direction.

  Moreover, with the above-described configuration, the support portion and the other support plate can be connected by a connection member that is shorter than the connection member used when the support portion is not provided.

  In the ninth configuration, each of the pair of support plates has a support portion extending inward of the through hole of the stacked body, and is provided on one of the pair of support plates. It is preferable that the support portion has a recess for preventing interference with the support portion provided on the other support plate (11th configuration).

  Thereby, it can prevent that the elastic member and flat plate member of a laminated body move to the direction which cross | intersects the lamination direction of this laminated body by the support part each provided in a pair of support plate. Therefore, the length of the support portion can be shortened compared to the configuration in which the inner surface of the laminate is supported by one support portion.

  Moreover, it can prevent that the support parts each provided in a pair of support plate interfere by providing a recessed part in the support part provided in one support plate.

  In any one of the first to eleventh configurations, the vibration isolator is preferably arranged between the upper floor and the lower floor of the dry double floor (a twelfth configuration).

  Even in the case of a dry double floor where the weight of the upper floor is relatively light, vibrations having a low frequency can be removed by the vibration isolator having the first to eleventh configurations.

  According to the vibration isolator which concerns on one Embodiment of this invention, while forming a laminated body by laminating | stacking alternately the elastic member and flat plate member which were formed in flat form, at least 1 elastic member is thickness direction. At least one surface has a recess. Thereby, the elastic member can be easily deformed, and even when the compressive load of the laminate is small, it is possible to efficiently reduce the vibration having a low frequency. Therefore, the vibration isolator which can reduce the vibration of a low frequency and can be installed by simple construction is obtained.

FIG. 1 is a perspective view showing an overall configuration of a vibration isolator according to an embodiment of the present invention. FIG. 2 is a cross-sectional view of the dry double floor showing a state in which the vibration isolator is installed in the dry double floor. 3 is a cross-sectional view taken along line III-III in FIG. 4A and 4B are (a) a top view of the rubber plate and (b) a side view of the rubber plate, respectively. FIG. 5 is a diagram showing the extending direction of the groove formed in each rubber plate with arrows in the top view of the laminate. FIG. 6 is a top view of the vibration isolator showing the positional relationship between the upper support portion and the lower support portion. FIG. 7 is an exploded perspective view of the vibration isolator.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. The same or corresponding parts in the drawings are denoted by the same reference numerals and description thereof will not be repeated.

(overall structure)
FIG. 1 is a diagram showing a schematic configuration of a vibration isolator 1 according to an embodiment of the present invention. As shown in FIG. 2, the vibration isolator 1 is used for a dry double floor 2, for example. Specifically, the vibration isolator 1 is disposed between the lower floor 3 and the upper floor 4 of the dry double floor 2 and elastically supports the upper floor 4 with respect to the lower floor 3. The vibration isolator 1 is fixed to the concrete lower floor 3 with an adhesive or the like, and is connected to a beam-like structural member 5 that supports the upper floor 4 from below by bolts or the like.

  In the present embodiment, the vibration isolator 1 is applied to a dry double floor. However, the present invention is not limited to this, and the vibration isolator 1 may be used to support other structures.

  As shown in FIG. 1, the vibration isolator 1 is formed in a substantially cylindrical shape as a whole. Specifically, the vibration isolator 1 includes a substantially cylindrical laminated body 10, and an upper support 20 and a lower support 25 that are positioned at both ends of the laminated body 10 in the stacking direction. That is, the upper support body 20 and the lower support body 25 are respectively disposed so as to cover the end faces of the stacked body 10 in the stacking direction.

  As shown in FIGS. 1 and 3, the laminate 10 is formed by alternately laminating rubber plates 11 (elastic members) and hard plates 12 (flat plate members) formed in a ring shape in the thickness direction. Composed. That is, the hard plate 12 is disposed between the rubber plate 11 and the rubber plate 11 with respect to the plurality of rubber plates 11. The rubber plate 11 and the hard plate 12 may be bonded by an adhesive or may be in a state where they are simply in contact with each other.

  The rubber plate 11 and the hard plate 12 are circular flat plates each having through holes 11a and 12a in the center portion. These through holes 11a and 12a are respectively formed in the rubber plate 11 and the hard plate 12 at positions corresponding to the stacking direction of the stacked body 10 (center portion when the stacked body 10 is viewed from the stacking direction). Thereby, the laminated body 10 comprised by laminating | stacking the rubber plate 11 and the hard board 12 has the through-hole 10a extended in a lamination direction. That is, the through hole 10 a of the laminate 10 passes through the rubber plate 11 and the hard plate 12.

  In the laminated body 10 having such a through hole 10a, when a force is applied in the laminating direction, the pressure receiving area is reduced, while the surface area of the laminated body 10 is increased, and therefore, deformation easily occurs. Therefore, with the above-described configuration, it is possible to obtain the vibration isolator 1 that can reduce the vibration of a low frequency (for example, 10 Hz or less) that occurs when a person jumps on the floor.

  The rubber plate 11 is a ring-shaped flat plate member made of natural rubber having a rubber hardness of 50 degrees, for example. As shown in FIG. 4, a plurality of grooves 11 b (concave portions) are formed on one surface in the thickness direction of the rubber plate 11, and a plurality of grooves 11 b (concave portions) are formed on the other surface in the thickness direction of the rubber plate 11. A groove 11c (concave portion) is formed. That is, a plurality of grooves 11b and 11c are formed on both surfaces in the thickness direction of the rubber plate 11, respectively. Thus, by providing the groove portions 11b and 11c on both surfaces in the thickness direction of the rubber plate 11, the surface area of the rubber plate 11 can be increased, and the rubber plate 11 can be easily deformed.

  The groove portions 11b and 11c are each formed in a straight line when viewed from the thickness direction of the rubber plate 11, and are formed substantially parallel to the adjacent groove portions 11b and 11c. By providing such groove portions 11b and 11c on the rubber plate 11, a plurality of linear convex portions 11d and 11e extending substantially in parallel are formed between the groove portions 11b and between the groove portions 11c, respectively. (See FIG. 4 (b)).

  As shown in FIG. 4A, the groove 11b is formed on the rubber plate 11 so as to be orthogonal to the groove 11c formed on the other surface of the rubber plate 11 when viewed from the thickness direction of the rubber plate 11. Is formed. That is, when viewed from the thickness direction of the rubber plate 11, the groove portions 11 b and 11 c formed on both surfaces of the rubber plate 11 are orthogonal to each other. Thereby, compared with the structure which provides a groove part only in the single side | surface of the rubber plate 11, the dispersion | variation in the rigidity of the thickness direction of the rubber plate 11 can be reduced. In the present embodiment, the groove portion 11b and the groove portion 11c are orthogonal to each other when viewed from the thickness direction of the rubber plate 11, but this is not restrictive, and the groove portion 11b and the groove portion 11c are viewed from the thickness direction of the rubber plate 11. As long as s intersect, they may intersect at any angle.

  The hard plate 12 is a flat plate made of metal such as stainless steel, and is formed in a ring shape having an inner and outer diameter equivalent to that of the rubber plate 11. The hard plate 12 is made of a material having a larger longitudinal elastic modulus than the rubber plate 11.

  The laminated body 10 is formed by alternately laminating the plurality of rubber plates 11 and the hard plates 12 in the thickness direction so that the hard plates 12 are sandwiched between the rubber plates 11 having the above-described configuration.

  At this time, as shown in FIG. 5, the plurality of rubber plates 11 are formed so that the groove portions 11 b of the rubber plates 11 extend in different directions (directions of arrows in FIG. 5) when viewed from the stacking direction of the stacked body 10. Have been placed. Specifically, the plurality of rubber plates 11 are viewed from the stacking direction at an angle formed by the groove portions 11b formed on one surface of the pair of rubber plates 11 arranged with the hard plate 12 interposed therebetween (solid line arrow in FIG. 5). And the angle between the groove portions 11b formed on one surface of a pair of rubber plates 11 arranged with another hard plate 12 interposed therebetween (the broken line arrow and the one-dot chain line arrow in FIG. 5). Are stacked on each other so that they are equal to each other. In the case of the present embodiment, since the rubber plate 11 is laminated in three layers, the angle formed by the groove portions 11b of the pair of rubber plates 11 arranged with the hard plate 12 sandwiched when viewed from the lamination direction of the laminate 10. Is 120 degrees. In FIGS. 1 to 3 and 7, the illustration of the groove portions 11 b and 11 c formed on the surface of the rubber plate 11 is omitted.

  As described above, by arranging the plurality of rubber plates 11, the rigidity in the stacking direction of the stacked body 10 can be made equal over the entire circumference of the stacked body 10 when viewed from the stacking direction of the stacked body 10. Thereby, even if force is applied to the stacked body 10 in the stacking direction of the stacked body 10, the stacked body 10 can be uniformly deformed in the stacking direction on the entire circumference. Accordingly, the vibration isolator 1 can more reliably reduce the low frequency vibration input to the vibration isolator 1.

  As shown in FIG. 3, the upper support 20 and the lower support 25 are disposed at the end of the substantially cylindrical laminate 10. The laminated body 10 is sandwiched between the upper support 20 and the lower support 25 by connecting the upper support 20 and the lower support 25 with the bolts 30.

  The upper support 20 is made of a metal material such as stainless steel. The upper support 20 includes a disk-shaped top plate 21 (support plate) and an upper support portion 22 (support portion) provided on one surface side of the top plate 21. The upper support 20 is disposed with respect to the stacked body 10 so that the top plate 21 contacts the upper surface of the stacked body 10 and the upper support portion 22 is positioned inward of the stacked body 10.

  The top plate 21 is a disk-shaped member having an outer diameter larger than the outer diameter of the laminated body 10. A through hole 21a through which the bolt 30 passes when the vibration isolator 1 is assembled is formed in the central portion of the top plate 21. Further, as shown in FIG. 1, the top plate 21 has two through holes 21b at positions sandwiching the through holes 21a in plan view. Although not particularly illustrated, the top plate 21 is fixed to the structural member 5 or the like that supports the upper floor 2 by bolts or the like inserted into the through holes 21b.

  As shown in FIGS. 3 and 7, the upper support portion 22 includes a rectangular bottom portion 22 a and a pair of rectangular side walls 22 b that support the bottom portion 22 a with respect to the top plate 21. The pair of side walls 22b extend in the direction orthogonal to the bottom 22a from the opposite sides of the bottom 22a. Each side wall 22b is connected to the lower surface of the top plate 21 by welding or the like on the side opposite to the bottom 22a. Thus, the upper support portion 22 is formed in a substantially U shape with the bottom portion 22a positioned on the lower side when viewed from the side surface of the stacked body 10. The upper support portion 22 has an outer shape of the bottom portion 22 a that is smaller than the through hole 10 a of the stacked body 10 so that the upper support portion 22 can be disposed inside the stacked body 10.

  A through hole 22c is formed in the center portion of the bottom portion 22a of the upper support portion 22. A part of the rubber bush 31 into which the bolt 30 is inserted is disposed in the through hole 22c.

  The rubber bush 31 (vibration suppressing member) has a cylindrical large-diameter portion 31a and a cylindrical small-diameter portion 31b having an outer diameter smaller than that of the large-diameter portion 31a, and is on one end surface of the large-diameter portion 31a. The small diameter portion 31b is integrally formed. The small diameter portion 31 b of the rubber bush 31 is inserted into a through hole 22 c provided in the bottom portion 22 a of the upper support portion 22. Further, the rubber bush 31 is formed with a through-hole 31c so as to penetrate the central portions of the large-diameter portion 31a and the small-diameter portion 31b. The shaft portion of the bolt 30 is inserted into the through hole 31c. The rubber bush 31 is also made of natural rubber having a rubber hardness of 50 degrees, for example, as with the rubber plate 11 described above.

  Thereby, it can prevent that the volt | bolt 30 contacts the bottom part 22a of the upper side support part 22 directly. Therefore, the rubber bush 31 can prevent the vibration transmitted from the upper floor 3 to the upper support portion 22 via the structural member 5 from being transmitted to the lower support portion 25 via the bolt 30. That is, the rubber bush 31 functions as a vibration suppressing member that prevents vibration from being transmitted from the upper support portion 22 to the lower support body 25 via the bolt 30.

  In a state where no load is applied to the vibration isolator 1, the rubber bush 31 is in contact with the head of a bolt 30 fastened to a nut 28 described later, while a predetermined load is applied to the vibration isolator 1. In this state, the bolt 30 has such a thickness that the head of the bolt 30 is separated. Thus, in a state where the upper floor 4 and the like are supported by the vibration isolator 1 and a predetermined load is applied to the vibration isolator 1, vibration is generated from the upper support portion 22 to the lower support portion 25 via the bolt 30. Can be prevented more reliably. FIG. 3 shows a state in which a predetermined load is applied to the vibration isolator 1.

  The lower support 25 is made of a metal material such as stainless steel, for example, like the upper support 20. As shown in FIG. 7, the lower support 25 includes a disk-shaped bottom plate 26 (support plate) and a pair of lower support portions 27 (support portions) provided on the bottom plate 26. The lower support body 25 is disposed with respect to the stacked body 10 so that the bottom plate 26 contacts the lower surface of the stacked body 10 and the lower support portion 27 is positioned inward of the stacked body 10.

  As shown in FIGS. 3 and 7, the bottom plate 26 is provided with a nut 28 to which a screw portion of the bolt 30 is fastened at a central portion of the upper surface. The nut 28 is attached to the bottom plate 26 with the opening portion facing upward so that the screw portion of the bolt 30 can be fastened. In addition, an adhesive may be put between the nut 28 and the bolt 30 so that the fastening between the nut 28 and the bolt 30 is not loosened, or the nut 28 may be a double nut.

  As shown in FIG. 7, the pair of lower support portions 27 are disposed on the upper surface of the bottom plate 26 so as to sandwich the nut 28. Each lower support portion 27 includes a prismatic bottom portion 27a and a pair of prismatic protrusion portions 27b extending from both ends in the longitudinal direction of the bottom portion 27a so as to be orthogonal to the bottom portion 27a. Thereby, the lower side support part 27 is formed in the substantially U shape as a whole.

  Each lower support portion 27 has a bottom portion 27a connected to the upper surface of the bottom plate 26 by welding or the like. Therefore, the protruding portion 27 b of each lower support portion 27 protrudes upward from the bottom plate 26. The length of the protruding portion 27b of the lower support portion 27 is such that it does not come into contact with the top plate 21 even when a force is applied to the vibration isolator 1 in the stacking direction of the stacked body 10 and the stacked body 10 is compressed. That's it. The pair of lower support portions 27 are disposed on the bottom plate 26 at a predetermined interval so as to be disposed inside the stacked body 10.

  As shown in FIG. 3, the upper support 20 and the lower support 25 configured as described above are arranged at both ends in the stacking direction of the stacked body 10, and the upper support 22 and the lower support 27 are It is positioned inside the laminate 10. Moreover, the upper support portion 22 and the lower support portion 27 are provided so as to overlap in the stacking direction of the stacked body 10 inside the stacked body 10. That is, in the state of FIG. 3, the side wall 22 b of the upper support portion 22 and the protruding portion 27 b of the lower support portion 27 overlap in the stacking direction of the stacked body 10.

  As shown in FIG. 6, the upper support portion 22 and the lower support portion 27 are such that the corner portion of the upper support portion 22 (the portion where the corner portions of the bottom portion 22 a and the side wall 22 b are combined) is the protruding portion of the lower support portion 27. It arrange | positions in the laminated body 10 so that it may not interfere with 27b. Specifically, by providing the protruding portions 27b of the lower support portion 27 apart from each other, the lower support portion 27 is formed with a recess 29 for preventing interference with the upper support portion 22. Then, the upper support 20 and the lower support 25 are combined with the stacked body 10 so that the corners of the upper support 22 are positioned in the recesses 29 (between the protrusions 27b of the lower support 27). It is. In the case of the present embodiment, the upper support 22 and the lower support 27 have substantially the same angle between the side wall 22b of the upper support 22 and the bottom 27a of the lower support 27 when viewed from the stacking direction of the stacked body 10. It arrange | positions so that it may become 45 degree | times (refer FIG. 6).

  Accordingly, as described above, the side wall 22b of the upper support portion 22 and the protruding portion 27b of the lower support portion 27 can be arranged in the stacked body 10 so as to overlap in the stacking direction of the stacked body 10. . Therefore, the upper support 20 and the lower support 25 can be arranged more compactly in the stacking direction with respect to the stacked body 10, and the compact vibration isolator 1 can be obtained.

(Effect of embodiment)
The laminated body 10 is formed by alternately laminating a plurality of ring-shaped rubber plates 11 and a plurality of ring-shaped hard plates 12 in the thickness direction thereof. Thereby, the surface area which can deform | transform the rubber plate 11 can be increased, making the pressure receiving area of the laminated body 10 small. Therefore, the stacked body 10 can be easily deformed in the stacking direction.

  Moreover, by providing the groove portions 11b and 11c on both surfaces in the thickness direction of the rubber plate 11, the rubber plate 11 can be easily deformed in the thickness direction. Therefore, since the laminated body 10 is easily deformed in the lamination direction, the vibration isolator 1 can more effectively reduce the vibration having a low frequency.

  Moreover, the plurality of rubber plates 11, as viewed from the stacking direction of the laminated body 10, have an angle formed by the groove portions 11 b of the pair of rubber plates 11 disposed with the hard plate 12 interposed therebetween, and another hard plate 12 interposed therebetween. It arrange | positions so that the angle which groove part 11b of a pair of rubber plate 11 arrange | positions may make equal. Accordingly, when vibration is input to the vibration isolator 1 in the stacking direction of the stacked body 10, the stacked body 10 can be uniformly deformed in the stacking direction on the entire circumference, and therefore vibration with a low frequency can be generated. It can reduce more reliably.

  Furthermore, the upper support 20 and the lower support 25 positioned at both ends in the stacking direction of the stacked body 10 are connected by bolts 30. Thereby, it can prevent that the rubber plate 11 and the hard board 12 of the laminated body 10 isolate | separate in a lamination direction. That is, when a strong impact is applied to the vibration isolator 1, the rubber plate 11 of the laminate 10 is separated from the hard plate 12 by the reaction, and the behavior of the rubber plate 11 can be suppressed by the bolt 30.

  Further, since the upper support 20 and the lower support 25 have the upper support 22 and the lower support 27 that are located inward of the laminated body 10, respectively, the upper support 22 and the lower support 27 support the upper support 20 and the lower support 25. The lateral displacement of the laminate 10 can be prevented. In addition, the length of the bolt 30 can be shortened by connecting the upper support portion 22 and the bottom plate 26 of the lower support body 25 with the bolt 30, and bending stress, shearing force, etc. acting on the bolt 30 are reduced. can do.

  In addition, since the rubber bush 31 is disposed between the upper support portion 22 and the bolt 30, vibration applied to the upper support 20 can be prevented from being transmitted to the lower support 25 via the bolt 30.

  The upper support 20 and the lower support 25 are attached to the stacked body 10 such that the corners of the upper support 22 are located between the protrusions 27b of the lower support 27. Thereby, it can prevent that the upper side support part 22 and the lower side support part 27 interfere. Therefore, since the upper side support part 22 and the lower side support part 27 can be arrange | positioned so that it may overlap with the lamination direction of the laminated body 10, compactization of the lamination direction of the laminated body 10 can be achieved in the vibration isolator 1. FIG.

  Further, the upper support portion 22 prevents the lateral shift of the upper portion of the stacked body 10, and the lower support portion 27 prevents the lateral shift of the lower portion of the stacked body 10. That is, when a lateral shift occurs in the laminate 10, the upper support 22 contacts the upper hard plate 12 among the plurality of hard plates 12 of the laminate 10, and the lower support 27 is below the laminate 10. It contacts the hard plate 12 located on the side. Thereby, it can prevent that the hard board 12 of the laminated body 10 contacts both the upper side support part 22 and the lower side support part 27. FIG. Therefore, it is possible to more reliably prevent vibration from being transmitted between the upper support portion 22 and the lower support portion 27.

(Other embodiments)
Although the embodiments of the present invention have been described above, the above-described embodiments are merely examples for carrying out the present invention. Therefore, the present invention is not limited to the above-described embodiment, and the above-described embodiment can be appropriately modified and implemented without departing from the spirit of the invention.

  In the said embodiment, the laminated body 10 is set as the structure which has the three-layer rubber board 11 and the two-layer hard board 12. FIG. However, the rubber plate 11 used for the laminate 10 may be two layers or four or more layers. Further, the hard plate 12 may be one layer or three or more layers.

  In the said embodiment, the groove parts 11b and 11c are provided in both surfaces of the thickness direction of each rubber plate 11. As shown in FIG. However, the groove portions may be provided only on one surface of each rubber plate 11 in the thickness direction. Moreover, a groove part may be provided in a part of surface of each rubber plate 11 in the thickness direction, and a groove part may be provided in at least a part of the side surface of each rubber plate 11. Furthermore, a groove part may be provided only in a part of the plurality of rubber plates 11.

  In the above-described embodiment, the linear groove portions 11b and 11c that are parallel to each other are provided on the surface in the thickness direction of the rubber plate 11. However, the groove portions may be any shape, and may be a recess other than the groove portion. Also good. For example, a groove portion may be provided so as to extend radially from the central portion of the rubber plate 11, or irregularities such as dimples may be provided. Moreover, the groove part or recessed part provided in the rubber plate 11 may be one.

  In the embodiment, the upper support 20 and the lower support 25 are connected by the bolt 30. However, without connecting the upper support 20 and the lower support 25, the rubber plate 11, the hard plate 12, the upper support 20, and the lower support 25 may be bonded to each other with an adhesive or the like. Moreover, you may connect the upper support body 20 and the lower support body 25 by connection members other than a volt | bolt. Furthermore, the connection member such as the bolt 30 may not be provided, and the rubber plate 11, the hard plate 12, the upper support 20, and the lower support 25 may not be bonded. In this case, in order to prevent the rubber plate 11 and the hard plate 12 from separating in the stacking direction, for example, members that sandwich the vibration isolator may be connected.

  In the embodiment, natural rubber having a rubber hardness of 50 degrees is used for the rubber plate 11 and the rubber bush 31. However, the present invention is not limited to this, and other elastic materials or rubber materials having different rubber hardness may be used. May be.

  In the above-described embodiment, the hard plate 12 is a stainless steel plate. However, the present invention is not limited to this, and any material can be used for the hard plate 12 as long as the material has a higher longitudinal elastic modulus than the elastic member such as the rubber plate 11 used in the laminate 10. Such a material may be used.

  In the said embodiment, the lower side support part 27 is formed in the substantially U shape as a whole with the prism-shaped member. However, the lower support portion may have any configuration as long as it can support the lower side of the laminate 10. Moreover, in the said embodiment, the upper side support part 22 is also formed in the substantially U shape as a whole. However, the upper support portion may have any configuration as long as it can support the upper side of the laminate 10. In the vibration isolator, only one of the upper support portion 22 and the lower support portion 27 may be provided, or a support portion capable of supporting the entire laminated body 10 may be provided. Moreover, it is not necessary to provide a support part in the vibration isolator.

  INDUSTRIAL APPLICABILITY The present invention can be used for a vibration isolator having a laminated body in which flat elastic members and flat plate members are alternately laminated.

DESCRIPTION OF SYMBOLS 1 Vibration isolator 2 Dry type double floor 10 Laminated body 10a Through-hole 11 Rubber board (elastic member)
11a Through hole 11b, 11c Groove part 12 Hard plate (flat plate member)
12a Through-hole 20 Upper support 21 Top plate (support plate)
22 Upper support (support)
25 Lower support body 26 Bottom plate (support plate)
27 Lower support part (support part)
29 Recess 30 Bolt (connecting member)
31 Rubber bushing (vibration suppression member)

Claims (10)

It has a columnar laminate,
The laminate is
A plurality of elastic members formed in a flat plate shape;
A flat plate member having a larger longitudinal elastic modulus than the plurality of elastic members,
The flat plate member is disposed so as to be sandwiched between the elastic member and the elastic member with respect to the plurality of elastic members,
Wherein all of the plurality of elastic members, have a recess on both sides in the thickness direction,
The anti-vibration device, wherein the recess is formed in the elastic member such that rigidity in the stacking direction of the stacked body is equal over the entire circumference of the stacked body as viewed from the stacking direction of the stacked body . The vibration isolator according to claim 1 ,
The said recessed part is a vibration isolator containing a groove part. The vibration isolator according to claim 2 ,
The said recessed part is a vibration isolator containing the several linear groove part formed in parallel with each other. The vibration isolator according to claim 2 or 3 ,
The laminate has a plurality of flat plate members,
Each of the plurality of elastic members has the groove.
The plurality of elastic members, when viewed from the stacking direction of the laminate, an angle formed by grooves formed in a pair of elastic members disposed between one flat plate member among the plurality of flat plate members, The vibration isolator which is arrange | positioned so that the angle which the groove parts each formed in a pair of elastic member arrange | positioned on both sides of another flat plate member among the several flat plate members may become equivalent. In the vibration isolator as described in any one of Claim 2 or 3 ,
The groove is formed on both surfaces in the thickness direction of the at least one elastic member,
The groove formed on one surface in the thickness direction of the elastic member intersects the groove formed on the other surface in the thickness direction of the elastic member when viewed from the stacking direction of the laminate. Anti-vibration device. In the vibration isolator as described in any one of Claim 1 to 5 ,
The said laminated body is a vibration isolator which has a through-hole which penetrates these elastic members and the said flat plate member. The vibration isolator according to claim 6 ,
A pair of support plates located at both ends in the stacking direction of the stack;
A connection member for connecting the support plates to each other in the through hole of the laminate;
An anti-vibration device further comprising: a vibration suppressing member that is disposed between the connection member and at least one of the pair of support plates and suppresses transmission of vibration between the pair of support plates. The vibration isolator according to claim 7 ,
At least one of the pair of support plates has a support portion extending inward of the through hole of the laminate,
The said connection member is a vibration isolator which connects the said support part and the other support plate. The vibration isolator according to claim 7 ,
Each of the pair of support plates has a support portion extending inward of the through hole of the laminate,
The vibration isolator, wherein the support portion provided on one of the pair of support plates has a recess for preventing interference with the support portion provided on the other support plate. In the vibration isolator as described in any one of Claim 1 to 9 ,
An anti-vibration device placed between the upper and lower floors of the dry double floor.

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