JP5777117B2 - Hydraulic damper - Google Patents

Description

  The present invention relates to a hydraulic damper that is attached to a structure such as a building and reduces the shaking of the structure by an external force such as an earthquake.

  Conventional hydraulic dampers include those shown in FIG. 5, for example.

  This conventional hydraulic damper 140 includes a cylindrical cylinder 142 closed at both ends, and a first oil chamber 144 and a second oil chamber 146 that are housed in the cylinder 142 and filled with hydraulic oil. And pistons 148 formed on both sides.

  The piston 148 has two piston rods 150 and 152 extending from the both end faces 148a and 148b to the outside in the axial direction (left and right direction in FIG. 5). Each end portion protruded from the both end surfaces 142a, 142b of 142 to the outside in the axial direction. And the front-end | tip part of the piston rod 152 was accommodated in the internal space of the extension member 154 extended from the end surface 142b of the cylinder 142 to the outer side of the axial direction.

  The conventional hydraulic damper 140 includes a first oil chamber 144 in the middle of oil passages 148c and 148d communicating between the first oil chamber 144 and the second oil chamber 146 provided in the solid interior of the piston 148. , Hydraulic valves 156 and 158 for controlling the flow state of the hydraulic oil between the second oil chambers 146 are provided. In the internal space of the piston rod 152, an accumulator 160 that stably absorbs the expansion and contraction of the hydraulic oil in the first oil chamber 144 and the second oil chamber 146 and operates the hydraulic damper 140 stably is provided.

  The accumulator 160 is formed in one of the two spaces, the accumulator piston 164 dividing the internal space of the piston rod 152 into two spaces, and communicates with the first oil chamber 144 and the second oil chamber 146 in the cylinder 142. The accumulator oil chamber 162 and the spring 166 that is housed in the other of the two spaces and presses the accumulator piston 164 toward the accumulator oil chamber 162 are configured.

  An oil passage that communicates between the first oil chamber 144 and the second oil chamber 146 in the cylinder 142 and the accumulator oil chamber 162 communicates from the piston 148 through the piston rod 150 to the accumulator oil chamber 162 provided in the piston rod 152. It was formed like this.

  Such a hydraulic damper is attached to a structure such as a building, and when an external force such as an earthquake acts on the structure such as a building and an interlayer displacement occurs, the piston in the cylinder of the hydraulic damper moves. The hydraulic oil plays a role of protecting a structure such as a building by generating a damping force when moving from the oil chamber to the oil chamber through the oil passage.

JP 2004-36677 A

  It is desirable that such a hydraulic damper can record how it operates when an external force such as an earthquake actually acts on a structure such as a building and an interlayer displacement occurs.

  For this reason, it is conceivable to install a displacement meter or load meter that operates by electricity on a hydraulic damper, but it is expensive to use such a meter, and since such a meter is an electrical component, it is fragile. Is a difficult point. In addition, since it is difficult to maintain every time it is broken, it is desirable to make it possible to measure without maintenance, without breaking for many years. This is because a hydraulic damper is attached to a structure such as a building and has a life span of several tens of years. It is desirable to be able to record how it worked.

  Therefore, the present invention can easily and inexpensively record over a period of several decades how the hydraulic damper has operated when an external force such as an earthquake acts on a structure such as a building and an interlayer displacement occurs. It is a problem to be able to do.

In order to solve the above problems, the present invention provides:
A cylinder,
A piston housed in the cylinder;
Two oil chambers formed on both sides of the piston in the cylinder;
In a hydraulic damper comprising a piston rod formed on the piston,
A displacement recording device having a scribing needle and a scribing plate, which records a relative displacement between the piston rod or a portion that moves substantially integrally with the piston rod and a portion that moves substantially integrally with the cylinder or the cylinder. It is characterized by having.

The present invention also provides:
A cylinder,
A piston housed in the cylinder;
Two oil chambers formed on both sides of the piston in the cylinder;
In a hydraulic damper comprising a piston rod formed on the piston,
A first cylinder that operates in conjunction with a relative displacement between the piston rod or a portion that moves substantially integrally with the piston rod, and a portion that moves substantially integrally with the cylinder or the cylinder;
A second cylinder that operates in conjunction with the flow of liquid or gas in the first cylinder;
A displacement recording device having a scribing needle and a scribing plate provided so as to record the deformation operation of the second cylinder is provided.

The present invention also provides:
A cylinder,
A piston housed in the cylinder;
Two oil chambers formed on both sides of the piston in the cylinder;
In a hydraulic damper comprising a piston rod formed on the piston,
A first cylinder that operates in conjunction with pressure fluctuations of hydraulic oil in the cylinder;
A load recording device having a scribing needle and a scribing plate provided so as to record the deformation operation of the first cylinder is provided.

The present invention also provides:
A cylinder,
A piston housed in the cylinder;
Two oil chambers formed on both sides of the piston in the cylinder;
In a hydraulic damper comprising a piston rod formed on the piston,
Recording the relative displacement between the piston rod or the portion that moves substantially integrally with the piston rod and the cylinder or the portion that moves substantially integrally with the cylinder;
A displacement load recording device having a scribing needle and a scribing plate is provided so as to record the deformation operation of the first cylinder that operates in conjunction with the pressure fluctuation of the hydraulic oil in the cylinder. Is.

According to the present invention as described above,
A cylinder,
A piston housed in the cylinder;
Two oil chambers formed on both sides of the piston in the cylinder;
In a hydraulic damper comprising a piston rod formed on the piston,
A displacement recording device having a scribing needle and a scribing plate, which records a relative displacement between the piston rod or a portion that moves substantially integrally with the piston rod and a portion that moves substantially integrally with the cylinder or the cylinder. By preparing,
When an external force such as an earthquake acts on a structure such as a building and an interlayer displacement occurs, it is possible to easily and inexpensively record how the hydraulic damper is operated over a period of several decades.

Moreover, according to the present invention,
A cylinder,
A piston housed in the cylinder;
Two oil chambers formed on both sides of the piston in the cylinder;
In a hydraulic damper comprising a piston rod formed on the piston,
A first cylinder that operates in conjunction with a relative displacement between the piston rod or a portion that moves substantially integrally with the piston rod, and a portion that moves substantially integrally with the cylinder or the cylinder;
A second cylinder that operates in conjunction with the flow of liquid or gas in the first cylinder;
By including a displacement recording device having a scribing needle and a scribing plate provided to record the deformation operation of the second cylinder,
When an external force such as an earthquake acts on a structure such as a building and an interlayer displacement occurs, it is possible to easily and inexpensively record how the hydraulic damper is operated over a period of several decades.
Further, since the second cylinder can be attached at a position away from the hydraulic damper body, it is possible to record displacement at a position away from the hydraulic damper body.

Moreover, according to the present invention,
A cylinder,
A piston housed in the cylinder;
Two oil chambers formed on both sides of the piston in the cylinder;
In a hydraulic damper comprising a piston rod formed on the piston,
A first cylinder that operates in conjunction with pressure fluctuations of hydraulic oil in the cylinder;
By including a load recording device having a scribing needle and a scribing plate provided to record the deformation operation of the first cylinder,
When an external force such as an earthquake acts on a structure such as a building and an interlayer displacement occurs, it is possible to easily and inexpensively record how the hydraulic damper is operated over a period of several decades.

Moreover, according to the present invention,
A cylinder,
A piston housed in the cylinder;
Two oil chambers formed on both sides of the piston in the cylinder;
In a hydraulic damper comprising a piston rod formed on the piston,
Recording the relative displacement between the piston rod or the portion that moves substantially integrally with the piston rod and the cylinder or the portion that moves substantially integrally with the cylinder;
By providing a displacement load recording device having a scribing needle and a scribing plate provided to record the deformation operation of the first cylinder that operates in conjunction with the pressure fluctuation of the hydraulic oil in the cylinder,
When an external force such as an earthquake acts on a structure such as a building and an interlayer displacement occurs, it is possible to easily and inexpensively record how the hydraulic damper is operated over a period of several decades.

1 is an overall view of a hydraulic damper according to a first embodiment of the present invention. It is a general view of the hydraulic damper which concerns on 2nd embodiment of this invention. It is a general view of the hydraulic damper which concerns on 3rd embodiment of this invention. It is a general view of the hydraulic damper which concerns on 4th embodiment of this invention. It is a general view of the conventional hydraulic damper.

  Hereinafter, the best mode for carrying out the hydraulic damper according to the present invention will be specifically described with reference to the drawings. FIG. 1 is an overall view of a hydraulic damper according to a first embodiment. Since the configuration other than the displacement recording device is the same as that of the conventional hydraulic damper, the description thereof is omitted.

  As shown in FIG. 1, in the present embodiment, a scribing plate 14 is attached to the joint portion 8. The scribing board 14 is a metal board such as iron or aluminum. Further, a rod-like member 10 with a scribing needle 12 attached to the tip is attached to the cylinder 4 of the hydraulic damper 2. The marking needle 12 is a tool for drawing a line by scratching a flat surface of a metal material such as iron or aluminum. The scribing needle 12 is placed in contact with the scribing plate 14.

  When an external force such as an earthquake acts on a structure such as a building to cause an inter-layer displacement, the hydraulic damper 2 is actuated to cause a displacement between the cylinder 4 and the piston 6. When moving in the direction of A, the tip of the scribing needle 12 also moves in the direction of arrow P with respect to the scribing plate, and the scribing needle 14 is damaged by the scribing needle 12 due to the movement, and between the piston 6 and the cylinder 4 The relative displacement is recorded. Similarly, when the piston 6 moves in the opposite direction with respect to the cylinder 4, the relative displacement between the piston 6 and the cylinder 4 is recorded on the marking plate 14.

  Thus, by attaching the displacement recording device having the scribing plate 14 and the rod-like member 10 with the scribing needle 12 at the tip to the hydraulic damper, an external force such as an earthquake is applied to the building or the like over a period of several decades. It is possible to easily and inexpensively measure how the hydraulic damper 2 is operated when an interlayer displacement occurs when acting on this structure.

  The rod-shaped member with the marking needle is installed in the cylinder so that it moves in conjunction with the cylinder. However, the marking plate does not necessarily have to be attached to the joint of the hydraulic damper. You may install it directly. Moreover, you may install the rod-shaped member and scribing board which attached the scribing needle upside down.

  FIG. 2 is an overall view of the hydraulic damper 16 according to the second embodiment. Since the configuration other than the displacement recording device is the same as that of the conventional hydraulic damper, the description thereof is omitted. The displacement recording apparatus in the second embodiment is mainly composed of two cylinders and pistons and piston rods stored in the respective cylinders.

  As shown in FIG. 2, a cylindrical cylinder 24 whose both ends are closed is attached to the joint portion 22. Inside the cylinder 24 are housed pistons 26 that form an oil chamber 28 and an oil chamber 30 filled with hydraulic oil on both sides thereof.

  The piston 26 has two piston rods 32 and 34 that extend outward in the axial direction (left and right direction in FIG. 2) from both end faces thereof, and both the piston rods 32 and 34 are arranged at both ends of the cylinder 24. Each tip portion protrudes outward from the surface in the axial direction. One piston rod 32 is fixed to the cylinder 18 of the hydraulic damper 16.

  A piston 42 that forms oil chambers 44 and 46 filled with hydraulic fluid on both sides thereof is also housed in a cylindrical cylinder 40 whose other ends are closed.

  The piston 42 also has two piston rods 48 and 50 extending from the both end surfaces to the outside in the axial direction (left and right direction in FIG. 2). Each tip portion protrudes outward from the surface in the axial direction. A marking needle 52 is attached to the tip of one piston rod 50 so as to contact the marking plate 54.

  The oil chamber 28 of the cylinder 24 and the oil chamber 44 of the cylinder 40 and the oil chamber 30 of the cylinder 24 and the oil chamber 46 of the cylinder 40 are connected by hoses 36 and 38, respectively. The oil chamber 30 and the oil chamber 46 communicate with each other. The hoses 36 and 38 are also filled with hydraulic oil.

When the hydraulic damper 16 is actuated during an earthquake or the like and the cylinder 18 and the piston 20 are displaced, for example, when the piston 20 moves in the direction of arrow A with respect to the cylinder 18, the piston 26 of the cylinder 24 moves in the direction of arrow P. The oil in the oil chamber 30 flows into the oil chamber 46 of the cylinder 40 through the hose 38, and the piston 42 of the cylinder 40 moves in the direction of arrow R. As the piston 42 of the cylinder 40 moves, the displacement is recorded on the marking plate 54 by the marking needle 52 attached to the tip of the piston rod 50.
Further, when the piston 20 moves in the opposite direction with respect to the cylinder 18, the relative displacement between the piston 20 and the cylinder 18 is similarly recorded on the scribing plate 54.

  By attaching such a displacement recording device to a hydraulic damper, over a period of several decades, how the hydraulic damper operated when an external force such as an earthquake acts on a structure such as a building and an interlayer displacement occurs. Can be easily and inexpensively measured.

  In the second embodiment, the cylinder on which the scribing needle is attached to the piston rod can be attached at a position away from the hydraulic damper body, so that the cylinder is displaced at a position away from the hydraulic damper body. It is possible to keep a record.

  FIG. 3 is an overall view of a hydraulic damper 56 according to the third embodiment. Since the configuration other than the load recording device is the same as that of the conventional hydraulic damper, the description thereof is omitted. The load recording apparatus according to the third embodiment mainly includes a cylinder, a piston accommodated in the cylinder, a piston rod coupled to the piston, a marking needle attached to one of the piston rods, and a marking plate.

  As shown in FIG. 3, a piston 76 that forms oil chambers 78 and 80 filled with hydraulic oil on both sides is accommodated in a cylindrical cylinder 74 whose both ends are closed.

  The oil chamber 78 is communicated with the first oil chamber 62 of the hydraulic damper 56 main body by the hose 70. The oil chamber 80 is communicated with the second oil chamber 64 of the hydraulic damper 56 main body by a hose 72.

  Springs 86 and 88 are installed inside the oil chambers 78 and 80. The springs 86 and 88 may or may not be connected to the piston 76, but the oil chamber 78 having the same pressure as the first oil chamber 62 of the hydraulic damper 56 main body and the second of the hydraulic damper 56 main body. Adjustment is made so that the displacement of the piston 76 in the cylinder 74 changes in accordance with the pressure difference in the oil chamber 80 that has the same pressure as the oil chamber.

  The piston 76 has two piston rods 82 and 84 extending from both ends thereof in the axial direction (left and right direction in FIG. 3), and both the piston rods 82 and 84 are both end surfaces of the cylinder 74. Each tip protrudes from the outer side in the axial direction. A marking needle 90 is attached to the tip of one piston rod 84. The tip of the marking needle 90 is disposed so as to contact the marking plate 92.

  When an external force such as an earthquake acts on a structure such as a building to cause a displacement between layers, the hydraulic damper 56 operates. For example, when the piston 60 moves in the direction of arrow A with respect to the cylinder 58, the hydraulic damper 56 main body Since the oil chamber 80 having the same pressure as the second oil chamber 64 has a higher pressure than the oil chamber 78 having the same pressure as the first oil chamber 62 of the hydraulic damper 56 body, a pressure difference is generated. The hydraulic oil enters the oil chamber 80 from the second oil chamber 64 of the damper 56 main body through the hose 72, and the piston 76 in the cylinder 74 moves in the arrow P direction. As the piston 76 of the cylinder 74 moves, the spring is adjusted as in paragraph 0039, so that the load is recorded on the scribing plate 92 by the marking needle 90 attached to the tip of the piston rod 84. .

  By attaching such a load recording device to a hydraulic damper, over a period of several decades, how the hydraulic damper worked when external forces such as earthquakes acted on structures such as buildings and caused displacement between layers. Can be easily and inexpensively measured.

  FIG. 4 is an overall view of a hydraulic damper 94 according to the fourth embodiment. Since the configuration other than the displacement load recording device is the same as that of the conventional hydraulic damper, the description thereof is omitted. In the displacement load recording apparatus according to the fourth embodiment, a scribing plate 130 is provided in the cylinder 96 of the hydraulic damper 94 body, and the cylinder / piston rod of the hydraulic damper load recording apparatus according to the third embodiment. The axial direction is arranged so as to be orthogonal to the axial direction of the cylinder / piston rod of the hydraulic damper 94 main body.

  By combining the scribing board and the load recording device, the displacement is recorded in the left-right direction in the figure and the load is recorded in the up-down direction in the figure. Can take.

  In this way, by attaching a displacement load recording device that combines a scribing board and a load recording device to a hydraulic damper, an external force such as an earthquake acts on a structure such as a building over a period of several decades, causing interlaminar displacement. It is possible to easily and inexpensively record the displacement of the piston of the hydraulic damper main body with respect to the cylinder of the hydraulic damper main body and the load generated. it can.

2 Hydraulic damper 4 Cylinder 6 Piston 8 Joint part 10 Bar-shaped member 12 Scribing needle 14 Scribing plate 16 Hydraulic damper 18 Cylinder 20 Piston 22 Joint part 24 Cylinder 26 Piston 28 Oil chamber 30 Oil chamber 32 Piston rod 34 Piston rod 36 Hose 38 Hose 40 Cylinder 42 Piston 44 Oil chamber 46 Oil chamber 48 Piston rod 50 Piston rod 52 Marking needle 54 Marking plate 56 Hydraulic damper 58 Cylinder 60 Piston 62 Oil chamber 64 Oil chamber 66 Hole 68 Hole 70 Hose 72 Hose 74 Cylinder 76 Piston 78 Oil chamber 80 Oil chamber 82 Piston rod 84 Piston rod 86 Spring 88 Spring 90 Scribing needle 92 Scribing plate 94 Hydraulic damper 96 Cylinder 98 Piston 100 Oil chamber 102 Oil chamber 104 Hole 106 Hole 108 Hose 1 0 hose 112 cylinder 114 piston 116 oil chamber 118 oil chamber 120 piston rod 122 piston rod 124 spring 126 spring 128 scribing needle 130 scribing plate 140 hydraulic damper 142 cylinder 142a end surface 142b end surface 144 first oil chamber 146 second oil chamber 148 Piston 148a End surface 148b End surface 148c Oil passage 148d Oil passage 150 Rod side piston rod 152 Head side piston rod 154 Extension member 156 Hydraulic valve 158 Hydraulic valve 160 Accumulator 162 Accumulator oil chamber 164 Accumulator piston 166 Spring

Claims (3)

A cylinder,
A piston housed in the cylinder;
Two oil chambers formed on both sides of the piston in the cylinder;
In a hydraulic damper comprising a piston rod formed on the piston,
A first cylinder that operates in conjunction with a relative displacement between the piston rod or a portion that moves substantially integrally with the piston rod, and a portion that moves substantially integrally with the cylinder or the cylinder;
A second cylinder that operates in conjunction with the flow of liquid or gas in the first cylinder;
A displacement recording device having a scribing needle and a scribing plate provided so as to record the deformation operation of the second cylinder,
Hydraulic damper. A cylinder,
A piston housed in the cylinder;
Two oil chambers formed on both sides of the piston in the cylinder;
In a hydraulic damper comprising a piston rod formed on the piston,
A first cylinder that operates in conjunction with pressure fluctuations of hydraulic oil in the cylinder;
A load recording device having a scribing needle and a scribing plate provided so as to record the deformation operation of the first cylinder,
Hydraulic damper. A cylinder,
A piston housed in the cylinder;
Two oil chambers formed on both sides of the piston in the cylinder;
In a hydraulic damper comprising a piston rod formed on the piston,
Recording the relative displacement between the piston rod or the portion that moves substantially integrally with the piston rod and the cylinder or the portion that moves substantially integrally with the cylinder;
Provided to record the deformation operation of the first cylinder that operates in conjunction with the pressure fluctuation of the hydraulic oil in the cylinder
A displacement load recording device having a scribing needle and a scribing plate is provided,
Hydraulic damper.