JP2023124541A - Vibration control device - Google Patents

Abstract

To provide a vibration control device capable of effectively controlling vibration on a plurality of pieces of piping.SOLUTION: A vibration control device is to control vibration on a plurality of pieces of piping including: first piping which has a first horizontal section extended along a first direction; and second piping which has a second horizontal section extended along the first direction and arranged at a distance from the first horizontal section on one side thereof in a second direction orthogonal to the first direction. The vibration control device has: a first arm section which is fixed to the first horizontal section and extended from the first horizontal section to the second horizontal section; a second arm section which is fixed to the second horizontal section, extended from the second horizontal section to the first horizontal section, and configured to form a first gap along a third direction orthogonal to both the first and second directions between the first arm section and the second arm section; and a viscoelastic body which is installed in the first gap so that the same is brought into contact with the first and second arm sections.SELECTED DRAWING: Figure 2

Description

TECHNICAL FIELD The present disclosure relates to a vibration suppressing device for suppressing vibration of a plurality of pipes.

Pipes connected to ships, construction machinery, industrial machinery, vehicles, and the like vibrate due to fuel supply, engine rotation, and the like. Patent Document 1 discloses a vibration damping material made of an elastic body wound around the outer circumference of each pipe that is adjacent to each other, a connecting material that connects the vibration damping materials, and an additional mass that is connected to the connecting material and adds mass. A vibration damping device is disclosed having a body.

JP 2014-126122 A

The piping structure of an engine often has a structure in which a single main pipe is branched into a plurality of branch pipes. In particular, in the case of an engine with a large number of cylinders, the main pipe is arranged longitudinally along the engine, from which the branch pipes are arranged in a manner corresponding to each cylinder position. It is difficult to secure a space between each cylinder and the main pipe to attach parts that support the branch pipes. Moreover, the rigidity of the branch pipe is relatively low with respect to the weight of the branch pipe itself, and the natural frequency tends to be low.

On the other hand, the engine excitation force exists at a pitch frequency that is a multiple of the engine speed. In the case of an engine with a large number of cylinders, there is a risk that the engine's vibratory force will increase even to higher-order components. If the engine's vibratory force component and the natural frequency of the branch pipe are close to each other, the pipe will vibrate greatly due to resonance, which may lead to damage to the pipe.

According to the vibration suppressing device described in Patent Document 1, by wrapping a damping material made of an elastic material around the outer circumference of the pipe, it is possible to exhibit damping performance against vibrations in multiple directions. Structurally, it was difficult to effectively exhibit the damping capacity of the damping material, and there was a problem that the effect of suppressing vibration was low.

In view of the circumstances described above, at least one embodiment of the present invention aims to provide a vibration suppressing device capable of effectively suppressing vibration of a plurality of pipes.

A vibration suppression device according to at least one embodiment of the present invention includes:
A vibration suppression device for suppressing vibration of a plurality of pipes,
The plurality of pipes include a first pipe having a first horizontal portion extending along a first direction, and a second horizontal portion extending along the first direction, the first horizontal portion being more than the first horizontal portion. a second pipe having a second horizontal portion spaced apart on one side in a second direction orthogonal to the first direction,
The vibration suppressing device is
a first arm fixed to the first horizontal portion and extending from the first horizontal portion toward the second horizontal portion;
a second arm portion fixed to the second horizontal portion and extending from the second horizontal portion toward the first horizontal portion, the second arm portion being perpendicular to each of the first direction and the second direction; a second arm configured to form first gaps along three directions with the first arm;
a viscoelastic body provided in the first gap so as to abut on the first arm and the second arm.

According to at least one embodiment of the present invention, a vibration suppressing device is provided that can effectively suppress vibration of a plurality of pipes.

1 is a schematic perspective view of a plurality of pipes to which vibration suppression devices according to one embodiment are attached; FIG. 1 is a schematic cross-sectional view of a vibration suppression device according to one embodiment; FIG. 1 is a schematic cross-sectional view of a vibration suppression device according to one embodiment; FIG. 1 is a schematic cross-sectional view of a vibration suppression device according to one embodiment; FIG. 1 is a schematic cross-sectional view of a vibration suppression device according to one embodiment; FIG. 1 is a schematic cross-sectional view of a vibration suppression device according to one embodiment; FIG. 1 is a schematic cross-sectional view of a vibration suppression device according to one embodiment; FIG. 1 is a schematic cross-sectional view of a vibration suppression device according to one embodiment; FIG. 1 is a schematic cross-sectional view of a vibration suppression device according to one embodiment; FIG. 1 is a schematic cross-sectional view of a vibration suppression device according to one embodiment; FIG.

Several embodiments of the present invention will now be described with reference to the accompanying drawings. However, the dimensions, materials, shapes, relative arrangements, etc. of the components described as embodiments or shown in the drawings are not intended to limit the scope of the present invention, and are merely illustrative examples. do not have.

(multiple pipes)
FIG. 1 is a schematic perspective view of a plurality of pipes 2 to which a vibration suppressing device 1 according to one embodiment is attached. Each of FIGS. 2-10 is a schematic cross-sectional view of a vibration damping device according to one embodiment. In each of FIGS. 2-10, the first direction is perpendicular to the drawing plane. A vibration suppressing device 1 according to some embodiments is for suppressing vibration of a plurality of pipes 2 as shown in FIG.

As shown in FIG. 1, each of the plurality of pipes 2 has a horizontal portion extending along a first direction, and the horizontal portions are spaced apart along a second direction orthogonal to the first direction. are placed. Specifically, the plurality of pipes 2 includes a first pipe 21 having a first horizontal portion 22 extending along the first direction and a second pipe 21 having a second horizontal portion 24 extending along the first direction. 2 piping 23 and, at least. The second horizontal portion 24 is arranged on one side of the first horizontal portion 22 in the second direction (lower right side in the figure).

The plurality of pipes 2 may further include a third pipe 25 having a third horizontal portion 26 extending along the first direction, as shown in FIG. The third horizontal portion 26 is arranged on the other side (upper left side in the figure) opposite to the one side in the second direction from the first horizontal portion 22 .

In the illustrated embodiment, as shown in FIG. 1, each of the plurality of pipes 2 consists of a branch pipe 13 having one end 141 connected to a main pipe 12 extending along the second direction. The main pipe 12 extends along the direction in which the plurality of cylinders 11 arranged in a row in the engine 10 are arranged. The second direction is the direction in which the plurality of cylinders 11 are arranged.

In the illustrated embodiment, as shown in FIG. 1, each of the plurality of pipes 2 (branch pipes 13) intersects each of the first direction and the second direction from one end 141 connected to the main pipe 12 (Fig. In the illustrated example, it includes a first straight portion 14 extending along the orthogonal direction, and a second straight portion 15 extending along the first direction from the other end 142 of the first straight portion 14 . The second straight portion 15 has one end 151 connected to the other end 142 of the first straight portion 14 and the other end 152 connected to the cylinder 11 .

Hereinafter, the first horizontal portion 22 consists of the second straight portion 15 of the first pipe 21, the second horizontal portion 24 consists of the second straight portion 15 of the second pipe 23, and the third horizontal portion 26 consists of the second straight portion 15 of the second pipe 23. A case in which the second straight portion 15 of the three pipes 25 is formed will be described. In the present disclosure, the first horizontal portion 22 consists of the first straight portion 14 of the first pipe 21, the second horizontal portion 24 consists of the first straight portion 14 of the second pipe 23, and the third horizontal portion 26 can also be applied when the first straight portion 14 of the third pipe 25 is formed. Also, the present disclosure is applicable to cases where the plurality of pipes 2 are other than the branch pipes 13 .

(First embodiment)
As shown in FIGS. 2 to 5, the vibration suppressing device 1 according to some embodiments includes a first arm portion 31 and a second arm portion 31 in which a first gap 41 is formed between the first arm portion 31 and the first arm portion 31 . An arm portion 32 and a viscoelastic body 51 provided in the first gap 41 so as to come into contact with each of the first arm portion 31 and the second arm portion 32 are provided.

(first arm)
The first arm portion 31 is fixed to the first horizontal portion 22 extending along the first direction and extends from the first horizontal portion 22 toward the second horizontal portion 24 .

In the illustrated embodiment, the vibration suppressing device 1 includes a first arc portion 311 that extends along the circumferential direction of the first horizontal portion 22 and covers a part of the outer circumference of the first horizontal portion 22 , and a first horizontal A second arc portion 312 that extends along the circumferential direction of the portion 22 and covers a part of the outer circumference of the first horizontal portion 22 , with the first horizontal portion 22 sandwiched between the first arc portion 311 and the second arc portion 312 . It further includes a second arc portion 312 arranged, and a first fastening member 16A for fastening one end portions of each of the first arc portion 311 and the second arc portion 312 . The first arm portion 31 has a base end 315 connected to the first arc portion 311 or the second arc portion 312 and extends from the base end 315 along the second direction.

In the embodiment shown in FIGS. 2 to 5, the vibration suppressing device 1 extends from one end (arc end) of the first arc portion 311 (the other side in the second direction in the illustrated example) to the first horizontal portion 22. A first projecting portion 313 projecting outward in the radial direction and a tip (arc end) of one of the second arc portions 312 (in the illustrated example, the other side in the second direction) to the outside of the first horizontal portion 22 in the radial direction. and a second projecting portion 314 projecting outward and abutting on the first projecting portion 313 . The first fastening member 16A may include a bolt 17A and a nut 18A configured to bolt the first protrusion 313 and the second protrusion 314 together.

(Second arm)
The second arm portion 32 is fixed to the second horizontal portion 24 and extends from the second horizontal portion 24 toward the first horizontal portion 22 . Second arm portion 32 is configured such that first gap 41 is formed between first arm portion 31 and first gap 41 along a third direction orthogonal to each of the first direction and the second direction. In other words, the second arm has a portion (tip) that overlaps with the first arm 31 in the second direction, and is arranged at a position shifted from the first arm 31 in the third direction.

In the illustrated embodiment, the vibration suppressing device 1 includes a third arc portion 321 extending along the circumferential direction of the second horizontal portion 24 and covering a part of the outer circumference of the second horizontal portion 24, and a second horizontal A fourth arc portion 322 that extends along the circumferential direction of the portion 24 and covers a part of the outer circumference of the second horizontal portion 24, and sandwiches the second horizontal portion 24 with the third arc portion 321. It further includes a fourth arc portion 322 arranged and a second fastening member 16B that fastens one end of each of the third arc portion 321 and the fourth arc portion 322 . The second arm portion 32 has a base end 325 connected to the third arc portion 321 or the fourth arc portion 322 and extends from the base end 325 along the second direction.

In the embodiment shown in FIGS. 2 to 5, the vibration suppressing device 1 extends from one end (arc end) of the third arc portion 321 (one side in the second direction in the illustrated example) to the second horizontal portion 24. The third projecting portion 323 projecting outward in the radial direction and the tip (arc end) of one of the fourth arc portions 322 (one side in the second direction in the illustrated example) to the outside of the second horizontal portion 24 in the radial direction. and a fourth protrusion 324 that protrudes outward and abuts on the third protrusion 323 . The second fastening member 16B may include a bolt 17B and a nut 18B configured to bolt the third protrusion 323 and the fourth protrusion 324 together.

In the illustrated embodiment, the viscoelastic body 51 provided in the first gap 41 can maintain its shape against gravity, expand and contract greatly in the direction of the applied force, and return to its original shape when the force is removed. It has a characteristic (elastic deformation) of returning to the shape of In the embodiment shown in FIGS. 2-5, the viscoelastic body 51 is composed of a rubber material. The viscoelastic body 51 has one end fixed to the first arm portion 31 via an adhesive and the other end fixed to the second arm portion 32 via an adhesive in the first gap 41 .

A first gap 41 is provided between the first arm portion 31 and the second arm portion 32 along the third direction. It is in contact with each of the second arms 32 . In this case, when the first pipe 21 or the second pipe 23 shifts in the second direction due to transmitted vibration and the distance between the first horizontal portion 22 and the second horizontal portion 24 increases or decreases, the first A viscoelastic body 51 provided in the gap 41 generates shear resistance. In this manner, by converting the relative motion generated between the first horizontal portion 22 and the second horizontal portion 24 into shear deformation that can effectively exhibit the damping capacity of the viscoelastic body 51, the viscoelastic body Vibration can be effectively damped by 51 . According to the above configuration, the shear resistance generated by the viscoelastic body 51 can suppress the displacement of the first horizontal portion 22 and the second horizontal portion 24 in the second direction. 23 vibration can be suppressed.

In some embodiments, as shown in FIG. 3, the vibration suppressing device 1 described above includes a third arm portion 33 and a fourth arm portion 33 in which a second gap 42 is formed between the third arm portion 33. and a viscoelastic body 52 provided in the second gap 42 so as to come into contact with the third arm portion 33 and the fourth arm portion 34, respectively.

(third arm)
The third arm portion 33 is fixed to the first horizontal portion 22 extending along the first direction and extends from the first horizontal portion 22 toward the third horizontal portion 26 . In the illustrated embodiment, the third arm portion 33 has a base end 316 connected to the first arc portion 311 or the second arc portion 312 and extends from the base end 316 along the second direction.

In the embodiment shown in FIG. 3, the first arm 31 is connected to the first arc 311 and the third arm 33 is connected to the second arc 312, but the first arm 31 and the third arm 31 are connected to the second arc 312. Both arms 33 may be connected to the first arc 311 or the second arc 312 .

In the embodiment shown in FIG. 3, the vibration suppressing device 1 is provided on the opposite side of each of the first circular arc portion 311 and the second circular arc portion 312 (one side in the second direction in the illustrated example). a third fastening member 16C that fastens the ends of the first arc portion 311, a fifth projecting portion 317 that projects outward in the radial direction of the first horizontal portion 22 from the other end (arc end) of the first arc portion 311, A sixth projecting portion 318 projects outward in the radial direction of the first horizontal portion 22 from the other tip (arc end) of the second arc portion 312 and contacts the fifth projecting portion 317 . The third fastening member 16C may include a bolt 17C and a nut 18C configured to bolt the fifth protrusion 317 and the sixth protrusion 318 together.

In the embodiment shown in FIG. 3, the vibration suppressing device 1 is provided on the other side opposite to the one of the third arc portion 321 and the fourth arc portion 322 (the other side in the second direction in the illustrated example). a fourth fastening member 16D that fastens together the ends of the third arc portion 321; An eighth protrusion 327 that protrudes radially outward from the second horizontal portion 24 from the other tip (arc end) of the four arc portions 322 and abuts on the seventh protrusion 326 . The fourth fastening member 16D may include a bolt 17D and a nut 18D configured to bolt the seventh protrusion 326 and the eighth protrusion 327 together.

(Fourth arm)
The fourth arm portion 34 is fixed to the third horizontal portion 26 extending along the first direction and extends from the third horizontal portion 26 toward the first horizontal portion 22 . The fourth arm portion 34 is configured such that a second gap 42 along the third direction is formed between the fourth arm portion 34 and the third arm portion 33 . In other words, the fourth arm portion 34 has a portion (tip) that overlaps with the third arm portion 33 in the second direction, and is arranged at a position shifted from the third arm portion 33 in the third direction.

In the illustrated embodiment, the vibration suppressing device 1 includes a fifth arc portion 341 extending along the circumferential direction of the third horizontal portion 26 and covering a part of the outer circumference of the third horizontal portion 26, and a third horizontal A sixth arc portion 342 that extends along the circumferential direction of the portion 26 and covers a part of the outer circumference of the third horizontal portion 26, and sandwiches the third horizontal portion 26 with the fifth arc portion 341. A sixth arc portion 342 arranged, and a fifth fastening member 16E that fastens one end of each of the fifth arc portion 341 and the sixth arc portion 342 (the other side in the second direction in the illustrated example). , is further provided. The fourth arm portion 34 has a base end 345 connected to the fifth arc portion 341 or the sixth arc portion 342 and extends from the base end 345 along the second direction.

In the embodiment shown in FIG. 3, the vibration suppressing device 1 includes a ninth protruding portion 343 that protrudes outward in the radial direction of the third horizontal portion 26 from the one end (arc end) of the fifth arc portion 341; A tenth projecting portion 344 that projects outward in the radial direction of the third horizontal portion 26 from the one tip (arc end) of the sixth arc portion 342 and contacts the ninth projecting portion 343 . The fifth fastening member 16E may include a bolt 17E and a nut 18E configured to bolt the ninth protrusion 343 and the tenth protrusion 344 together.

In the embodiment shown in FIG. 3, the vibration suppressing device 1 is provided on the opposite side of the one of the fifth arc portion 341 and the sixth arc portion 342 (one side in the second direction in the illustrated example). a sixth fastening member 16F that fastens the ends of each other; an eleventh projecting portion 346 that projects outward in the radial direction of the third horizontal portion 26 from the other end (arc end) of the fifth arc portion 341; A twelfth projecting portion 347 that projects radially outward from the third horizontal portion 26 from the other tip (arc end) of the six arc portions 342 and contacts the eleventh projecting portion 346 . The sixth fastening member 16F may include a bolt 17F and a nut 18F configured to bolt the eleventh protrusion 346 and the twelfth protrusion 347 together.

In the illustrated embodiment, the viscoelastic body 52 provided in the second gap 42 is able to maintain its shape against gravity, expands and contracts significantly in the direction of the applied force, and returns to its original shape when the force is removed. It has a characteristic (elastic deformation) of returning to the shape of In the embodiment shown in FIG. 3, the viscoelastic body 52 is constructed from a rubber material. The viscoelastic body 52 has one end fixed to the third arm portion 33 via an adhesive and the other end fixed to the fourth arm portion 34 via an adhesive in the second gap 42 .

A second gap 42 along the third direction is provided between the third arm portion 33 and the fourth arm portion 34, and the viscoelastic body 52 provided in the second gap 42 extends between the third arm portion 33 and the fourth arm portion 34. It is in contact with each of the fourth arm portions 34 . In this case, when the first pipe 21 or the third pipe 25 shifts in the second direction due to transmitted vibration and the distance between the first horizontal portion 22 and the third horizontal portion 26 increases or decreases, the second A viscoelastic body 52 provided in the gap 42 generates shear resistance. Due to the shear resistance generated by the viscoelastic bodies 51 and 52 provided in the first gap 41 and the second gap 42, the first horizontal portion 22, the second horizontal portion 24 and the third horizontal portion 26 are displaced in the second direction. can be suppressed, the vibration of the first pipe 21, the second pipe 23, and the third pipe 25 can be effectively suppressed.

As shown in FIG. 3, the vibration suppressing device 1 is in contact with a pair of arms extending toward the adjacent pipes 2 from each horizontal portion of the pipes 2 adjacent to each other. By adding a viscoelastic body provided in a gap provided between a pair of arms according to the number of a plurality of pipes 2, three or more pipes 2 can be fixed to each other, and these Vibration of the pipe 2 can be suppressed.

In some embodiments, as shown in FIG. 3, the first arm 31 described above consists of either a fifth protrusion 317 or a sixth protrusion 318 (fifth protrusion 317 in the illustrated example). . The second arm portion 32 described above is composed of either the seventh projecting portion 326 or the eighth projecting portion 327 (the seventh projecting portion 326 in the illustrated example). The above-described third arm portion 33 is composed of either the first projecting portion 313 or the second projecting portion 314 (the second projecting portion 314 in the illustrated example). The above-described fourth arm portion 34 is composed of either the eleventh projecting portion 346 or the twelfth projecting portion 347 (the eleventh projecting portion 346 in the illustrated example). In these cases, the arm portions 31 to 34 of the vibration suppressing device 1 also serve as projecting portions, so that the structure of the vibration suppressing device 1 can be prevented from becoming complicated.

In some embodiments, as shown in FIGS. 4 and 5, the vibration suppressing device 1 described above includes: a fifth arm portion 35 having a third gap 43 formed between it and the second arm portion 32; and a viscoelastic body 53 provided in the third gap 43 so as to abut on the second arm portion 32 and the fifth arm portion 35 .

(Fifth arm)
The fifth arm portion 35 is fixed to the first horizontal portion 22 and extends from the first horizontal portion 22 toward the second horizontal portion 24 . The fifth arm portion 35 has a third gap 43 along the third direction formed on the side opposite to the first gap 41 with the second arm portion 32 interposed therebetween in the third direction. is configured to be formed in the The fifth arm portion 35 has a portion (tip) that overlaps with the second arm portion 32 in the second direction.

In the illustrated embodiment, the fifth arm portion 35 is connected at its base end 351 to the first arc portion 311 or the second arc portion 312 and extends from the base end 351 along the second direction. 4 and 5, the first arm 31 is connected to the first arc 311 and the fifth arm 35 is connected to the second arc 312, but the first arm 31 and the fifth arm portion 35 may be connected to the first arc portion 311 or the second arc portion 312 .

In the illustrated embodiment, the viscoelastic body 53 provided in the third gap 43 can maintain its shape against gravity, expand and contract greatly in the direction of the applied force, and return to its original shape when the force is removed. It has a characteristic (elastic deformation) of returning to the shape of In the embodiment shown in Figures 4 and 5, the viscoelastic body 53 is made of a rubber material. The viscoelastic body 53 has one end fixed to the second arm portion 32 via an adhesive and the other end fixed to the fifth arm portion 35 via an adhesive in the third gap 43 .

A third gap 43 is provided between the second arm portion 32 and the fifth arm portion 35 along the third direction. It is in contact with each of the fifth arms 35 . In this case, when the first pipe 21 or the second pipe 23 shifts in the second direction due to transmitted vibration and the distance between the first horizontal portion 22 and the second horizontal portion 24 increases or decreases, the first Each of the viscoelastic bodies 51 and 53 provided in the gap 41 and the third gap 43 generates shear resistance. According to the above configuration, compared to the case where the viscoelastic body 51 is provided only in the first gap 41, the total shear resistance generated by the viscoelastic bodies 51 and 53 can be increased. This can effectively suppress the displacement of the first horizontal portion 22 and the second horizontal portion 24 in the second direction, and can effectively suppress the vibration of the first pipe 21 and the second pipe 23 .

In some embodiments, as shown in FIG. 5, the vibration suppressing device 1 described above includes a sixth arm portion 36 having a fourth gap 44 formed between itself and the first arm portion 31, and a first arm portion a viscoelastic body 54 provided in the fourth gap 44 so as to abut on the portion 31 and the sixth arm portion 36, respectively.

(6th arm)
The sixth arm portion 36 is fixed to the second horizontal portion 24 and extends from the second horizontal portion 24 toward the first horizontal portion 22 . The sixth arm portion 36 has a fourth gap 44 along the third direction formed on the side opposite to the first gap 41 with the first arm portion 31 interposed therebetween in the third direction. is configured to be formed in the The sixth arm portion 36 has a portion (tip) that overlaps with the first arm portion 31 in the second direction.

In the illustrated embodiment, the sixth arm portion 36 has a base end 361 connected to the third arc portion 321 or the fourth arc portion 322 and extends from the base end 361 along the second direction. In the embodiment shown in FIG. 5, the second arm 32 is connected to the third arc 321 and the sixth arm 36 is connected to the fourth arc 322; Both arms 36 may be connected to the third arc 321 or the fourth arc 322 .

In the illustrated embodiment, the viscoelastic body 54 provided in the fourth gap 44 can maintain its shape against gravity, expand and contract significantly in the direction of the applied force, and return to its original shape when the force is removed. It has a characteristic (elastic deformation) of returning to the shape of In the embodiment shown in FIG. 5, the viscoelastic body 54 is constructed from a rubber material. The viscoelastic body 54 has one end fixed to the sixth arm portion 36 with an adhesive and the other end fixed to the first arm portion 31 with an adhesive in the fourth gap 44 .

A fourth gap 44 is provided between the first arm portion 31 and the sixth arm portion 36 along the third direction. It is in contact with each of the sixth arm portions 36 . In this case, when the first pipe 21 or the second pipe 23 shifts in the second direction due to transmitted vibration and the distance between the first horizontal portion 22 and the second horizontal portion 24 increases or decreases, the first Each of the viscoelastic bodies 51 and 54 provided in the gap 41 and the fourth gap 44 generates shear resistance. According to the above configuration, compared to the case where the viscoelastic body 51 is provided only in the first gap 41, the total shear resistance generated by the viscoelastic bodies 51 and 54 can be increased. This can effectively suppress the displacement of the first horizontal portion 22 and the second horizontal portion 24 in the second direction, and can effectively suppress the vibration of the first pipe 21 and the second pipe 23 . Note that this embodiment can also be applied to the vibration suppression device 1 that does not include the viscoelastic body 53 provided in the third gap 43 .

In some embodiments, as shown in FIGS. 2-5, each of the viscoelastic bodies 51, 52, 53 and 54 described above is constructed from a rubber material. The viscoelastic body 51 is configured separately from the viscoelastic bodies 52, 53 and 54, respectively.

According to the above configuration, each of the viscoelastic bodies 51, 52, 53, and 54 is made of a rubber material, so that it deforms according to the vibration applied from the outside, and returns to its original state when the vibration applied from the outside disappears. return to the shape of Therefore, each of the viscoelastic bodies 51, 52, 53 and 54 made of a rubber material can immediately exhibit shear resistance against vibrations applied from the outside. Further, even if each of the viscoelastic bodies 51, 52, 53, and 54 is deformed by vibrations applied from the outside, the viscoelasticity can be maintained in the gaps (first gap 41, etc.) provided with the viscoelasticity. , the viscoelasticity can exhibit repeated shear resistance against externally applied vibrations. Thereby, the vibration of the plurality of pipes 2 can be effectively suppressed.

(Second embodiment)
As shown in FIGS. 6 and 7, the vibration suppressing device 1 according to some embodiments has a first gap 41 formed between the above-described first arm portions 31 and the first arm portions 31. The second arm portion 32 described above, the viscoelastic body 61 made of a viscous material having fluidity, and the casing 7 provided with the first gap 41 inside and filled with the viscoelastic body 61 are provided. .

In the embodiment shown in FIGS. 6 and 7, the casing 7 has a first insertion hole 71 for inserting the distal end of the first arm portion 31 (the end opposite to the base end 315) inside the casing 7. , and a second insertion hole 72 for inserting the tip of the second arm portion 32 (the end opposite to the base end 325 ) into the casing 7 . A first gap 41 is provided inside the casing 7 by inserting the tip of the first arm portion 31 and the tip of the second arm portion 32 into the casing 7 . The inside of the casing 7 is filled with a viscoelastic body 61 made of a viscous material having fluidity, and a part of the viscoelastic body 61 constitutes the viscoelastic body 51 described above. The viscoelastic body 51 is made of a fluid viscous material.

In the embodiment shown in FIG. 7, the casing 7 includes a third insertion hole 73 for inserting the distal end of the fifth arm portion 35 (the end opposite to the proximal end 351) inside the casing 7, and a sixth insertion hole 73. A fourth insertion hole 74 for inserting the distal end of the arm portion 36 (the end opposite to the proximal end 361 ) into the casing 7 is further formed. A third gap 43 and a fourth gap 44 are provided inside the casing 7 by inserting the tip of the fifth arm 35 and the tip of the sixth arm 36 into the casing 7 . A portion of the viscoelastic body 61 filled inside the casing 7 constitutes the viscoelastic bodies 51, 53, and 54, respectively. Each of the viscoelastic bodies 53 and 54 is made of a fluid viscous material. The viscoelastic body 51 is configured integrally with each of the viscoelastic bodies 53 and 54 . Note that the viscoelastic body 52 described above may also be made of a viscous material having fluidity, like the viscoelastic body 51 .

In the embodiment shown in FIGS. 6 and 7, the casing 7 has a first side portion 75, a second side portion 76, a third side portion 77, and a fourth side portion in a cross section perpendicular to the first direction. 78 and .

The first side portion 75 extends along the second direction on the side opposite to the first arm portion 31 across the second arm portion 32 in the third direction. The second side portion 76 extends along the second direction on the side opposite to the second arm portion 32 across the first arm portion 31 in the third direction. The third side portion 77 extends along the third direction on one side (the other side in the second direction) of the tip of the second arm portion 32 in the second direction, and one end is connected to the first side portion 75 . and the other end is connected to the second side portion 76 . The first insertion hole 71 and the third insertion hole 73 are formed in the third side portion 77 . The fourth side portion 78 extends along the third direction on the other side (the one side in the second direction) of the tip of the first arm portion 31 in the second direction, and one end is connected to the first side portion 75 . and the other end is connected to the second side portion 76 .

In the embodiment shown in FIG. 6, a gap 70A is provided between the first side portion 75 and the second arm portion 32 along the third direction. A gap 70B is provided between the second side portion 76 and the first arm portion 31 along the third direction. A part of the viscoelastic body 61 is filled in each of the gaps 70A and 70B. Since the viscoelastic body 61 filled in the first gap 41 and the gaps 70A and 70B is made of a fluid viscous material, the viscoelastic body 61 is deformed in response to vibration applied from the outside, Shear resistance can be exhibited immediately. When the first pipe 21 or the second pipe 23 shifts in the second direction due to transmitted vibration and the distance between the first horizontal portion 22 and the second horizontal portion 24 increases or decreases, the first gap 41 and the gap 70A , 70B generate shear resistance.

In the embodiment shown in FIG. 7, a gap 70C is provided between the first side portion 75 and the fifth arm portion 35 along the third direction. A gap 70</b>D is provided between the second side portion 76 and the sixth arm portion 36 along the third direction. A part of the viscoelastic body 61 is filled in each of the gaps 70C and 70D. The viscoelastic body 61 filled in each of the first gap 41, the third gap 43, the fourth gap 44, and the gaps 70C and 70D is made of a viscous material having fluidity. It deforms according to the applied vibration and can immediately exhibit shear resistance. When the first pipe 21 or the second pipe 23 shifts in the second direction due to transmitted vibration and the distance between the first horizontal portion 22 and the second horizontal portion 24 increases or decreases, the first gap 41 and the third The viscoelastic bodies 61 filled in the gap 43, the fourth gap 44, and the gaps 70C and 70D generate shear resistance.

According to the above configuration, the viscoelastic body 61 filled in the first gap 41 and the gap between the casing 7 and the arm (such as the first arm 31) is made of a viscous material having fluidity. Therefore, the viscoelastic body 61 deforms according to the vibration applied from the outside. Therefore, the viscoelastic body 61 can immediately exhibit shear resistance against vibration applied from the outside of the viscoelastic body 61 . When the vibration transmitted to the first pipe 21 or the second pipe 23 shifts in the second direction and the distance between the first horizontal portion 22 and the second horizontal portion 24 increases or decreases, the viscoelastic body 61 generates Since the shear resistance can prevent the first horizontal portion 22 and the second horizontal portion 24 from shifting in the second direction, the vibration of the first pipe 21 and the second pipe 23 can be suppressed. Thereby, the vibration of the plurality of pipes 2 can be effectively suppressed.

(Third embodiment)
As shown in FIGS. 8 and 9, the vibration suppressing device 1 according to some embodiments includes a first fixing portion 320 and a first gap 41A formed between the first fixing portion 320 and the first gap 41A. An arm portion 31A and a viscoelastic body 51A provided in the first gap 41A so as to contact the first arm portion 31A and the first fixing portion 320, respectively.

(First fixed part)
The first fixing portion 320 covers the outer periphery of the second horizontal portion 24 and is fixed to the second horizontal portion 24 . In the illustrated embodiment, the first fixing portion 320 includes the above-described third arc portion 321, the above-described fourth arc portion 322, and the above-described second fastening member 16B.

(first arm)
The first arm portion 31A is fixed to the first horizontal portion 22 extending along the first direction and extends from the first horizontal portion 22 toward the second horizontal portion 24 . In the illustrated embodiment, the vibration suppression device 1 further includes the above-described first arc portion 311, the above-described second arc portion 312, and the above-described fastening member 16A. The first arm portion 31A has a proximal end 315A connected to the first circular arc portion 311 or the second circular arc portion 312, and extends from the proximal end 315A along the second direction.

The first arm portion 31A is configured such that a first gap 41A along the third direction is formed between the first arm portion 31A and the first fixing portion 320 . In other words, the first arm portion 31A has a portion (tip) that overlaps with the first fixing portion 320 in the second direction, and is arranged at a position shifted from the first fixing portion 320 in the third direction. In the illustrated embodiment, the base end 315A of the first arm portion 31A is connected to the first arc portion 311, and the tip end opposite to the base end 315A is in contact with the outer peripheral surface of the fourth arc portion 322. 41 A of 1st clearance gaps are formed between.

In the illustrated embodiment, the viscoelastic body 51A provided in the first gap 41A can maintain its shape against gravity, expands and contracts greatly in the direction of the applied force, and returns to its original shape when the force is removed. It has a characteristic (elastic deformation) of returning to the shape of In the embodiment shown in FIGS. 8 and 9, the viscoelastic body 51A is made of a rubber material. The viscoelastic body 51A has one end fixed to the first arm portion 31A via an adhesive in the first gap 41A, and the other end fixed to the outer peripheral surface of the fourth arc portion 322 via an adhesive.

A first gap 41A is provided between the first arm portion 31A and the first fixing portion 320 along the third direction. It is in contact with each of the first fixing portions 320 . In this case, when the first pipe 21 or the second pipe 23 shifts in the second direction due to transmitted vibration and the distance between the first horizontal portion 22 and the second horizontal portion 24 increases or decreases, the first A viscoelastic body 51A provided in the gap 41A generates shear resistance. In this manner, by converting the relative motion generated between the first horizontal portion 22 and the second horizontal portion 24 into shear deformation that can effectively exhibit the damping capacity of the viscoelastic body 51A, the viscoelastic body Vibration can be effectively damped by 51A. According to the above configuration, it is possible to prevent the first horizontal portion 22 and the second horizontal portion 24 from shifting in the second direction due to the shear resistance generated by the viscoelastic body 51A. 23 vibration can be suppressed.

As shown in FIG. 9, the vibration suppressing device 1 according to some embodiments includes a second fixing portion 340 and a second arm portion 32A in which a second gap 42A is formed between the second fixing portion 340 and the second fixing portion 340. and a viscoelastic body 52A provided in the second gap 42A so as to come into contact with the second arm portion 32A and the second fixing portion 340, respectively.

(Second fixed part)
The second fixing portion 340 covers the outer periphery of the third horizontal portion 26 and is fixed to the third horizontal portion 26 . In the illustrated embodiment, the second fixing portion 340 includes the above-described fifth arc portion 341, the above-described sixth arc portion 342, and the above-described fifth fastening member 16E.

(Second arm)
The second arm portion 32A is fixed to the first horizontal portion 22 extending along the first direction and extends from the first horizontal portion 22 toward the third horizontal portion 26 . In the illustrated embodiment, the second arm portion 32A has a base end 328 connected to the first arc portion 311 or the second arc portion 312 and extends from the base end 328 along the second direction.

The second arm portion 32A is configured such that a second gap 42A along the third direction is formed between the second arm portion 32A and the second fixing portion 340 . In other words, the second arm portion 32A has a portion (tip) that overlaps with the second fixing portion 340 in the second direction, and is arranged at a position shifted from the second fixing portion 340 in the third direction. In the illustrated embodiment, the base end 328 of the second arm portion 32A is connected to the second arc portion 312, and the tip, which is the end opposite to the base end 328, is in contact with the outer peripheral surface of the fifth arc portion 341. 42 A of 2nd clearance gaps are formed between.

In the illustrated embodiment, the viscoelastic body 52A provided in the second gap 42A can maintain its shape against gravity, expand and contract greatly in the direction of the applied force, and return to its original shape when the force is removed. It has a characteristic (elastic deformation) of returning to the shape of In the embodiment shown in FIG. 9, the viscoelastic body 52A is made of a rubber material. The viscoelastic body 52A has one end fixed to the second arm portion 32A via an adhesive and the other end fixed to the outer peripheral surface of the fifth arc portion 341 via an adhesive in the second gap 42A.

A second gap 42A along the third direction is provided between the second arm portion 32A and the second fixing portion 340, and the viscoelastic body 52A provided in the second gap 42A extends between the second arm portion 32A and the second fixing portion 340. It is in contact with each of the second fixing portions 340 . When the vibration transmitted to the first pipe 21 or the third pipe 25 shifts in the second direction and the distance between the first horizontal portion 22 and the third horizontal portion 26 increases or decreases, the The viscoelastic body 52A generates shear resistance. According to the above configuration, shear resistance generated by the viscoelastic bodies 51A and 52A provided in the first gap 41A and the second gap 42A causes the first horizontal portion 22, the second horizontal portion 24, and the third horizontal portion 26 can be suppressed from shifting in the second direction, vibrations of the first pipe 21, the second pipe 23, and the third pipe 25 can be effectively suppressed.

In some embodiments, as shown in FIGS. 8 and 9, each of the viscoelastic bodies 51A and 52A described above is made of a rubber material. The viscoelastic body 51A is configured separately from the viscoelastic body 52A.

According to the above configuration, each of the viscoelastic bodies 51A and 52A is made of a rubber material, so that they are deformed in response to vibrations applied from the outside, and return to their original shapes when the vibrations applied from the outside are removed. . Therefore, each of the viscoelastic bodies 51A and 52A made of a rubber material can immediately exhibit shear resistance against vibrations applied from the outside. Further, even if the viscoelastic bodies 51A and 52A are deformed by vibrations applied from the outside, the viscoelastic bodies can be maintained in the gaps provided with the viscoelasticity (the first gap 41A, etc.). It can repeatedly exhibit shear resistance against vibration applied from the outside of the elastic body. Thereby, the vibration of the plurality of pipes 2 can be effectively suppressed.

(Fourth embodiment)
As shown in FIG. 10 , the vibration suppressing device 1 according to some embodiments includes the above-described first fixing portion 320 and the above-described first fixing portion 320 in which the first gap 41A is formed between the first fixing portions 320 . It includes one arm portion 31A, a viscoelastic body 61A made of a fluid viscous material, and a casing 8 having a first gap 41A therein and filled with the viscoelastic body 61A.

In the embodiment shown in FIG. 10, the casing 8 is attached to the outer circumference of the first fixing portion 320 (fourth arc portion 322 in the illustrated example), so that the inside thereof is filled with the viscoelastic body 51A (61A). An internal space 80 is formed. The casing 8 is formed with an insertion hole 81 for inserting the tip of the first arm portion 31A (the end opposite to the base end 315A) inside the casing 8 . A first gap 41A is provided inside the casing 8 by inserting the tip of the first arm 31A inside the casing 8 . The inside of the casing 8 is filled with a viscoelastic body 61A made of a viscous material having fluidity, and a part of this viscoelastic body 61A constitutes the above-described viscoelastic body 51A. The viscoelastic body 51A is made of a fluid viscous material.

In the embodiment shown in FIG. 10, the casing 8 includes a first side portion 82, a second side portion 83, and a third side portion 84 in a cross section perpendicular to the first direction.

The first side portion 82 extends along the second direction on the side opposite to the fourth arc portion 322 across the tip of the first arm portion 31A in the third direction. The second side portion 83 extends along the third direction on one side (the one side in the second direction) from the tip of the first arm portion 31A in the second direction, and is connected to the first side portion 82 at one end. and the other end is connected to the fourth arc portion 322 . The third side portion 84 extends along the third direction on the other side (the other side in the second direction) of the tip of the first arm portion 31A in the second direction, and one end is connected to the first side portion 82. and the other end is connected to the fourth arc portion 322 . The insertion hole 81 is formed in the third side portion 84 .

In the embodiment shown in FIG. 10, a gap 80A is provided between the first side portion 82 and the first arm portion 31A along the third direction. The internal space 80 includes a gap 80A, and the gap 80A is also partially filled with the viscoelastic body 61A. Since the viscoelastic body 61A filled in the first gap 41A and the gap 80A is made of a viscous material having fluidity, it deforms according to the vibration applied from the outside of the viscoelastic body 61A, and immediately Can exhibit shear resistance. When the first pipe 21 or the second pipe 23 shifts in the second direction due to transmitted vibration and the distance between the first horizontal portion 22 and the second horizontal portion 24 increases or decreases, the first gap 41A or the gap 80A A viscoelastic body 61A filled in each generates shear resistance.

According to the above configuration, the viscoelastic body 61A filled in the first gap 41A and the gap between the casing 8 and the first arm portion 31 is made of a viscous material having fluidity. It deforms according to the vibration applied from the outside of 61A. Therefore, the viscoelastic body 61A can immediately exhibit shear resistance against vibration applied from the outside of the viscoelastic body 61A. When the vibration transmitted to the first pipe 21 or the second pipe 23 shifts in the second direction and the distance between the first horizontal portion 22 and the second horizontal portion 24 increases or decreases, the viscoelastic body 61A generates Since the shear resistance can prevent the first horizontal portion 22 and the second horizontal portion 24 from shifting in the second direction, the vibration of the first pipe 21 and the second pipe 23 can be suppressed. Thereby, the vibration of the plurality of pipes 2 can be effectively suppressed.

In some embodiments, as shown in FIG. 1, each of the plurality of pipes 2 described above consists of a branch pipe 13 having one end 141 connected to a main pipe 12 extending along the second direction. According to the above configuration, each of the plurality of branch pipes 13 having one end 141 connected to the main pipe 12 tends to deform along the second direction in which the main pipe 12 extends due to vibration transmitted from the main pipe 12 . be. Therefore, by providing the vibration suppressing device 1 for the plurality of branch pipes 13, the vibration of the plurality of branch pipes 13 can be effectively suppressed.

In some embodiments, as shown in FIG. 1, each of the above-described plurality of pipes 2 includes the above-described first straight portion 14 and second straight portion 15, and the first horizontal portion 22 includes a first The second horizontal portion 24 consists of the second straight portion 15 of the pipe 21 , and the second straight portion 15 of the second pipe 23 . Also, the third horizontal portion 26 consists of the second straight portion 15 of the third pipe 25 .

According to the above configuration, the shear resistance generated by the viscoelastic bodies 51 and 51A causes the first horizontal portion 22 (the second straight portion 15 of the first pipe 21) and the second horizontal portion 24 (the second pipe 23). Since the second linear portion 15) of the can be suppressed from being displaced in the second direction, vibration of the first pipe 21 and the second pipe 23 can be suppressed.

In addition, each of the first arc portion 311, the second arc portion 312, the third arc portion 321, and the fourth arc portion 322 is preferably arranged at a position where the vibration amplitude is the largest in order to enhance the vibration suppressing effect. In the embodiment shown in FIG. 1, the first arc portion 311 and the second arc portion 312 are arranged on the side of one end 151 of the second straight portion 15 of the first pipe 21 (the side connected to the first straight portion 14). preferably. Also, the third arc portion 321 and the fourth arc portion 322 are preferably arranged on the one end 151 side of the second straight portion 15 of the second pipe 23 (the side connected to the first straight portion 14).

As used herein, expressions such as "in a certain direction", "along a certain direction", "parallel", "perpendicular", "central", "concentric" or "coaxial", etc. express relative or absolute arrangements. represents not only such arrangement strictly, but also the state of being relatively displaced with a tolerance or an angle or distance to the extent that the same function can be obtained.
For example, expressions such as "identical", "equal", and "homogeneous", which express that things are in the same state, not only express the state of being strictly equal, but also have tolerances or differences to the extent that the same function can be obtained. It shall also represent the existing state.
Further, in this specification, expressions representing shapes such as a quadrilateral shape and a cylindrical shape not only represent shapes such as a quadrilateral shape and a cylindrical shape in a geometrically strict sense, but also within the range in which the same effect can be obtained. , a shape including an uneven portion, a chamfered portion, and the like.
Moreover, in this specification, the expressions “comprising”, “including”, or “having” one component are not exclusive expressions excluding the presence of other components.

The present disclosure is not limited to the above-described embodiments, and includes modifications of the above-described embodiments and modes in which these modes are combined as appropriate.

The contents described in the several embodiments described above are understood as follows, for example.

1) A vibration suppression device (1) according to at least one embodiment of the present disclosure,
A vibration suppression device (1) for suppressing vibration of a plurality of pipes (2),
The plurality of pipes (2) includes a first pipe (21) having a first horizontal portion (22) extending along the first direction, and a second horizontal portion (21) extending along the first direction ( 24), a second pipe (23) having a second horizontal portion (24) spaced from the first horizontal portion (22) on one side in a second direction orthogonal to the first direction; , including
The vibration suppressing device (1) includes:
a first arm (31) fixed to said first horizontal portion (22) and extending from said first horizontal portion (22) towards said second horizontal portion (24);
a second arm (32) fixed to said second horizontal portion (24) and extending from said second horizontal portion (24) toward said first horizontal portion (22), said first A second arm (32) configured such that a first gap (41) along a third direction orthogonal to each of the direction and the second direction is formed between the first arm (31) and the )and,
a viscoelastic body (51) provided in the first gap (41) so as to contact the first arm (31) and the second arm (32), respectively.

According to the above configuration 1), the first gap (41) is provided along the third direction between the first arm (31) and the second arm (32). ) is in contact with each of the first arm (31) and the second arm (32). In this case, the vibration transmitted to the first pipe (21) and the second pipe (23) shifts in the second direction, and the distance between the first horizontal portion (22) and the second horizontal portion (24) increases or decreases, the viscoelastic body (51) provided in the first gap (41) generates shear resistance. According to the above configuration 1), the shear resistance generated by the viscoelastic body (51) can suppress the displacement of the first horizontal portion (22) and the second horizontal portion (24) in the second direction. Vibration of the first pipe (21) and the second pipe (23) can be effectively suppressed.

2) In some embodiments, the vibration damping device (1) according to 1) above,
The plurality of pipes (2) are arranged on a third horizontal portion (26) extending along the first direction and spaced apart from the first horizontal portion (22) on the other side in the second direction. further comprising a third pipe (25) having a third horizontal portion (26) connected to
The vibration suppressing device (1) includes:
a third arm (33) fixed to said first horizontal portion (22) and extending from said first horizontal portion (22) towards said third horizontal portion (26);
a fourth arm (34) fixed to said third horizontal portion (26) and extending from said third horizontal portion (26) toward said first horizontal portion (22), said third a fourth arm (34) configured such that a second longitudinal gap (42) is formed between said third arm (33);
A viscoelastic body (52) provided in the second gap (42) so as to contact the third arm (33) and the fourth arm (34).

According to the configuration of 2) above, the first horizontal portion (22) and the third horizontal portion (26) are displaced in the second direction due to transmitted vibrations of the first pipe (21) and the third pipe (25). The viscoelastic body (52) provided in the second gap (42) generates shear resistance when the distance between the two increases or decreases. According to the configuration 2) above, the first horizontal portion (22), Since the second horizontal portion (24) and the third horizontal portion (26) can be suppressed from being displaced in the second direction, vibration of the first pipe (21), the second pipe (23) and the third pipe (25) can be suppressed. can be effectively suppressed.

3) In some embodiments, the vibration damping device (1) according to 1) or 2) above,
a fifth arm (35) fixed to said first horizontal portion (22) and extending from said first horizontal portion (22) toward said second horizontal portion (24), said first A third gap (43) along the third direction is formed between the second arm (32) and the gap (41), which is formed on the opposite side of the second arm (32). a fifth arm (35) configured to
and a viscoelastic body (53) provided in the third gap (43) so as to abut on the second arm (32) and the fifth arm (35).

According to the configuration of 3) above, the vibration transmitted to the first pipe (21) and the second pipe (23) shifts in the second direction, and the first horizontal portion (22) and the second horizontal portion (24) are displaced. Each of the viscoelastic bodies (51, 53) provided in the first gap (41) and the third gap (43) generates shear resistance when the distance between them increases or decreases. According to the above configuration 3), the total shear resistance generated by each viscoelastic body (51, 53) can be increased compared to the case where the viscoelastic body (51) is provided only in the first gap (41). As a result, the first horizontal portion (22) and the second horizontal portion (24) can be effectively suppressed from being displaced in the second direction, and the vibration of the first pipe (21) and the second pipe (23) can be effectively suppressed. can be suppressed to

4) In some embodiments, the vibration damping device (1) according to any one of 1) to 3) above,
a sixth arm (36) fixed to said second horizontal portion (24) and extending from said second horizontal portion (24) toward said first horizontal portion (22), said first A fourth gap (44) along the third direction is formed between the gap (41) and the first arm (31). a sixth arm (36) configured to
a viscoelastic body (54) provided in the fourth gap (44) so as to contact the first arm (31) and the sixth arm (36), respectively.

According to the configuration 4) above, the first horizontal portion (22) and the second horizontal portion (24) are displaced in the second direction due to the transmitted vibration of the first pipe (21) and the second pipe (23). Each of the viscoelastic bodies (51, 54) provided in the first gap (41) and the fourth gap (44) generates shear resistance when the distance between them increases or decreases. According to the above configuration 4), the total shear resistance generated by each viscoelastic body (51, 54) can be increased compared to the case where the viscoelastic body (51) is provided only in the first gap (41). As a result, the first horizontal portion (22) and the second horizontal portion (24) can be effectively suppressed from being displaced in the second direction, and the vibration of the first pipe (21) and the second pipe (23) can be effectively suppressed. can be suppressed to

5) A vibration suppression device (1) according to at least one embodiment of the present disclosure,
A vibration suppression device (1) for suppressing vibration of a plurality of pipes (2),
The plurality of pipes (2) includes a first pipe (21) having a first horizontal portion (22) extending along the first direction, and a second horizontal portion (21) extending along the first direction ( 24), a second pipe (23) having a second horizontal portion (24) spaced from the first horizontal portion (22) on one side in a second direction orthogonal to the first direction; , including
The vibration suppressing device (1) includes:
a first fixing part (320) covering the outer periphery of the second horizontal part (24) and fixed to the second horizontal part (24);
A first arm (31A) fixed to the first horizontal portion (22) and extending from the first horizontal portion (22) toward the second horizontal portion (24), A first arm portion (31A) configured to form a first gap (41A) along a third direction perpendicular to each of the direction and the second direction between the first fixing portion (320) and the first arm portion (31A). )and,
a viscoelastic body (51A) provided in the first gap (41A) so as to come into contact with the first arm (31A) and the first fixing portion (320).

According to the configuration 5) above, the first gap (41A) is provided along the third direction between the first arm (31A) and the first fixing part (320). ) is in contact with each of the first arm (31A) and the first fixing portion (320). In this case, the vibration transmitted to the first pipe (21) and the second pipe (23) shifts in the second direction, and the distance between the first horizontal portion (22) and the second horizontal portion (24) increases or decreases, the viscoelastic body (51A) provided in the first gap (41A) generates shear resistance. According to the above configuration 5), the shear resistance generated by the viscoelastic body (51A) can suppress the displacement of the first horizontal portion (22) and the second horizontal portion (24) in the second direction. Vibration of the first pipe (21) and the second pipe (23) can be effectively suppressed.

6) In some embodiments, the vibration damping device (1) according to 5) above,
The plurality of pipes (2) are arranged on a third horizontal portion (26) extending along the first direction and spaced apart from the first horizontal portion (22) on the other side in the second direction. further comprising a third pipe (25) having a third horizontal portion (26) connected to
The vibration suppressing device (1) includes:
a second fixing part (340) covering the outer periphery of the third horizontal part (26) and fixed to the third horizontal part (26);
a second arm (32A) fixed to the first horizontal portion (22) and extending from the first horizontal portion (22) toward the third horizontal portion (26), a second arm (32A) configured such that a second longitudinal gap (42A) is formed between the second fixing portion (340);
A viscoelastic body (52A) provided in the second gap (42A) so as to contact the second arm (32A) and the second fixing part (340).

According to the configuration of 6) above, the first horizontal portion (22) and the third horizontal portion (26) are displaced in the second direction due to the transmitted vibration of the first pipe (21) and the third pipe (25). The viscoelastic body (52A) provided in the second gap (42A) generates shear resistance when the distance between the two increases or decreases. According to the configuration 6) above, the first horizontal portion (22), Since the second horizontal portion (24) and the third horizontal portion (26) can be suppressed from being displaced in the second direction, vibration of the first pipe (21), the second pipe (23) and the third pipe (25) can be suppressed. can be effectively suppressed.

7) In some embodiments, the vibration damping device (1) according to any one of 1) to 6) above,
The viscoelastic bodies (51, 51A) provided in the first gaps (41, 41A) are made of a rubber material.

According to the above configuration 7), the viscoelastic bodies (51, 51A) provided in the first gaps (41, 41A) are made of a rubber material. It deforms in response to applied vibration and returns to its original shape when the external vibration is removed. Therefore, the viscoelastic bodies (51, 51A) made of a rubber material can immediately exhibit shear resistance against vibrations applied from the outside of the viscoelastic bodies (51, 51A). Further, even if the viscoelastic bodies (51, 51A) are deformed by vibrations applied from the outside, the viscoelastic bodies (51, 51A) can be maintained in the first gap. It can exhibit repeated shear resistance against vibrations applied from As a result, vibration of the plurality of pipes (2) can be effectively suppressed.

8) In some embodiments, the vibration damping device (1) according to any one of 1) to 6) above,
The viscoelastic bodies (51, 51A) provided in the first gaps (41, 41A) are made of a viscous material having fluidity,
The vibration suppressing device (1) includes casings (7, 8) in which the first gaps (41, 41A) are provided and the viscoelastic bodies (51 (61), 51A (61A)) are filled. Prepare more.

According to the configuration of 8) above, the viscoelastic bodies (61, 61, 61, 61, 61) filled in the first gaps (41, 41A) and gaps between the casings (7, 8) and the arms (first arm 31, etc.) 61A) is made of a viscous material having fluidity, so it deforms according to vibration applied from the outside of the viscoelastic bodies (61, 61A). Therefore, the viscoelastic bodies (61, 61A) can immediately exhibit shear resistance against vibrations applied from the outside of the viscoelastic bodies (61, 61A). As a result, vibration of the plurality of pipes (2) can be effectively suppressed.

9) In some embodiments, the vibration damping device (1) according to any one of 1) to 8) above,
Each of the plurality of pipes (2) consists of a branch pipe (13) having one end (141) connected to a main pipe (12) extending along the second direction.

According to the configuration of 9) above, each of the plurality of branch pipes (13), one end (141) of which is connected to the main pipe (12), is caused by the vibration transmitted from the main pipe (12) to extend the main pipe (12). It tends to deform along the second direction in which it lies. Therefore, by providing the vibration suppressing device (1) for the plurality of branch pipes (13), the vibration of the plurality of branch pipes (13) can be effectively suppressed.

10) In some embodiments, the vibration damping device (1) of 9) above,
Each of the plurality of pipes (2) is a first straight line extending from the one end (141) connected to the main pipe (12) along a direction intersecting each of the first direction and the second direction. a portion (14) and a second straight portion (15) extending along the first direction from the other end (142) of the first straight portion (14),
The first horizontal portion (22) is composed of the second straight portion (15) of the first pipe (21),
Said second horizontal portion (24) consists of said second straight portion (15) of said second pipe (23).

According to the above configuration 10), the shear resistance generated by the viscoelastic bodies (51, 51A) causes the first horizontal portion (22, the second straight portion 15 of the first pipe 21) and the second horizontal portion (24) to move. , the second straight portion 15) of the second pipe 23 can be restrained from being displaced in the second direction, so that the vibration of the first pipe (21) and the second pipe (23) can be effectively restrained.

1 Vibration suppression device 2 Piping 7, 8 Casing 10 Engine 11 Cylinder 12 Main pipe 13 Branch pipe 14 First straight portion 15 Second straight portion 16A-16F Fastening member 17A-17F Bolt 18A-18F Nut 21 First pipe 22 First horizontal Part 23 Second pipe 24 Second horizontal part 25 Third pipe 26 Third horizontal part 31, 31A First arm 32, 32A Second arm 33 Third arm 34 Fourth arm 35 Fifth arm 36 Six arm portions 41, 41A First gaps 42, 42A Second gap 43 Third gap 44 Fourth gaps 51, 51A, 52, 52A, 53, 54, 61, 61A Viscoelastic body 311 First arc portion 312 Second arc Part 313 First projecting part 314 Second projecting parts 315 and 316 Base end 317 Fifth projecting part 318 Sixth projecting part 321 Third arc part 322 Fourth arc part 323 Third projecting part 324 Fourth projecting part 325 Base end 326 Seventh protrusion 327 Eighth protrusion 341 Fifth arc 342 Sixth arc 343 Ninth protrusion 344 Tenth protrusion 345 Base end 346 Eleventh protrusion 347 Twelfth protrusion

Claims (10)

A vibration suppression device for suppressing vibration of a plurality of pipes,
The plurality of pipes include a first pipe having a first horizontal portion extending along a first direction, and a second horizontal portion extending along the first direction, the first horizontal portion being more than the first horizontal portion. a second pipe having a second horizontal portion spaced apart on one side in a second direction orthogonal to the first direction,
The vibration suppressing device is
a first arm fixed to the first horizontal portion and extending from the first horizontal portion toward the second horizontal portion;
a second arm portion fixed to the second horizontal portion and extending from the second horizontal portion toward the first horizontal portion, the second arm portion being perpendicular to each of the first direction and the second direction; a second arm configured to form first gaps along three directions with the first arm;
and a viscoelastic body provided in the first gap so as to be in contact with the first arm and the second arm. The plurality of pipes have a third horizontal portion extending along the first direction and spaced apart from the first horizontal portion on the other side in the second direction. 3 piping,
The vibration suppressing device is
a third arm fixed to the first horizontal portion and extending from the first horizontal portion toward the third horizontal portion;
a fourth arm portion fixed to the third horizontal portion and extending from the third horizontal portion toward the first horizontal portion, wherein a second gap along the third direction is the third arm portion; a fourth arm configured to be formed between the
2. The vibration suppressing device according to claim 1, further comprising: a viscoelastic body provided in said second gap so as to come into contact with said third arm portion and said fourth arm portion. A fifth arm portion fixed to the first horizontal portion and extending from the first horizontal portion toward the second horizontal portion, the fifth arm portion being opposite to the first gap across the second arm portion a fifth arm configured such that a third gap along the third direction formed on the side is formed between the second arm and the fifth arm;
3. The vibration suppressing device according to claim 1, further comprising: a viscoelastic body provided in said third gap so as to abut against said second arm portion and said fifth arm portion. A sixth arm portion fixed to the second horizontal portion and extending from the second horizontal portion toward the first horizontal portion, the sixth arm portion being opposite to the first gap across the first arm portion a sixth arm configured such that a fourth gap along the third direction formed on the side is formed between the first arm and the sixth arm;
The vibration suppressing device according to any one of claims 1 to 3, further comprising: a viscoelastic body provided in the fourth gap so as to come into contact with the first arm portion and the sixth arm portion. A vibration suppression device for suppressing vibration of a plurality of pipes,
The plurality of pipes include a first pipe having a first horizontal portion extending along a first direction, and a second horizontal portion extending along the first direction, the first horizontal portion being more than the first horizontal portion. a second pipe having a second horizontal portion spaced apart on one side in a second direction orthogonal to the first direction,
The vibration suppressing device is
a first fixing portion covering the outer periphery of the second horizontal portion and fixed to the second horizontal portion;
A first arm portion fixed to the first horizontal portion and extending from the first horizontal portion toward the second horizontal portion, the first arm portion being perpendicular to each of the first direction and the second direction. a first arm portion configured to form first gaps along three directions with the first fixing portion;
and a viscoelastic body provided in the first gap so as to abut on the first arm portion and the first fixing portion. The plurality of pipes have a third horizontal portion that extends along the first direction and that is spaced apart from the first horizontal portion toward the other side in the second direction. 3 piping,
The vibration suppressing device is
a second fixing portion covering the outer periphery of the third horizontal portion and fixed to the third horizontal portion;
A second arm portion fixed to the first horizontal portion and extending from the first horizontal portion toward the third horizontal portion, wherein the second gap along the third direction is the second fixing portion. a second arm configured to be formed between the
6. The vibration suppressing device according to claim 5, further comprising: a viscoelastic body provided in said second gap so as to come into contact with said second arm portion and said second fixing portion. Each of the viscoelastic bodies is composed of a rubber material,
The vibration suppressing device according to any one of claims 1 to 6. Each of the viscoelastic bodies is composed of a fluid viscous material,
The vibration suppressing device further includes a casing provided with the first gap therein and filled with the viscoelastic body,
The vibration suppressing device according to any one of claims 1 to 6. each of the plurality of pipes comprises a branch pipe having one end connected to a main pipe extending along the second direction;
The vibration suppression device according to any one of claims 1 to 8. Each of the plurality of pipes has a first straight portion extending from the one end connected to the main pipe along a direction crossing each of the first direction and the second direction; a second straight portion extending along the first direction from the other end,
The first horizontal portion is composed of the second straight portion of the first pipe,
The second horizontal portion is composed of the second straight portion of the second pipe,
The vibration suppressing device according to claim 9.

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