KR101832995B1 - Earthquake-proof pipe hanger of three dimension seismic isolation structure - Google Patents

Abstract

The upper end of the spring holder is rotatably connected to the lower end of the upper bracket connected to the vertical rod fixed to the ceiling of the building and the lower end of the spring holder is connected to the horizontal 2 Dimensional direction and the lower end of the spring holder and the upper end of the lower bracket are rotatably connected so that the lower end of the lower bracket is perpendicular to the first direction of the horizontal two- The clamp is connected to the lower end of the lower bracket to support the pipe, and the spring has a structure in which the vertical distance between the lower end of the upper bracket and the upper end of the lower bracket is changed according to the expansion and contraction thereof, As it is received, a three-dimensional earthquake against the pipe can be achieved.

Description

  [0001] The present invention relates to an earthquake-proof pipe hanger having a three-dimensional seismic isolation structure,

To a seismic pipe hanger having a three-dimensional seismic function.

Generally, a ceiling of a building is provided with a plurality of pipes such as a gas pipe, a water pipe, a sewer pipe, a fire pipe, a cooling pipe, and the like. These pipes are supported horizontally by a plurality of pipe hanger hanging from the ceiling of the building and spaced apart from the ceiling at a certain distance. If the ground is shaken due to an earthquake or the like, the building will also shake on the ground. The vibrations of buildings caused by earthquakes are transmitted directly to the pipe hanger hanging on the ceiling of the building. As a result, the sheath of the wire in the pipe is peeled off or the pipe is broken and the electric wire inside the pipe is cut or the fluid flowing in the pipe is leaked have.

In order to solve such a problem, Korean Patent No. 10-1687663 entitled "Hanger for Plumbing Equipped with Dustproofing Apparatus" proposes a pipe hanger having a vibration preventing means such as a buffer spring or the like so as to absorb and absorb vibration transmitted from a building have. However, this has a problem that it is vulnerable to prevention of the horizontal vibration due to the provision of the vibration preventing means which can prevent only vertical vibration. Most of the conventional hinged pipe hanger including such a pipe hanger has a problem that it is vulnerable to preventing vibration in the horizontal direction by having a vibration preventing means capable of preventing only vertical vibration.

Korean Patent No. 10-1102908 discloses an anti-seismic spring safety hanger, which is constructed such that a fastening member for hanging a support bracket coupled to an upper end of a pipe band to a ceiling of a building is inserted into a spring The fastening member can be swung forward, backward, leftward and rightward in the fastening hole of the support bracket through the protruding structure, so that the impact due to the earthquake or the like applied to the pipe in the horizontal direction can be buffered. However, since the fastening member of the pipe hanger is capable of swinging in only one direction at any one point, the inertia of the swing causes the horizontal plane of the space in which the pipe is placed, that is, the two-dimensional plane including the longitudinal direction and the lateral direction of the pipe It is impossible to immediately react when the vibration direction of the building changes in the other direction, and consequently, there is a limit to quickly attenuate the horizontal direction component oscillating in an arbitrary direction on the two-dimensional plane.

The present invention provides a three-dimensional earthquake-proof seismic pipe hanger which can prevent various accidents due to vibration of a pipe because the building vibration is hardly transmitted to the pipe even if the building vibrates in any arbitrary direction. The present invention is not limited to the above-described technical problems and other technical problems may be derived from the following description.

The pipe hanger having a three-dimensional seam structure according to an aspect of the present invention includes: an upper bracket having an upper end fixed to a ceiling of a building and connected to a lower end of a downwardly extending vertical rod; A spring holder rotatably connected to a lower end of the upper bracket and having a lower end reciprocally moved in a first direction of a horizontal two-dimensional direction of a pipe installed in an upper space of the building due to vibration of the building; A lower bracket rotatably connected to a lower end of the spring holder and having a lower end reciprocally moved in a second direction orthogonal to the first direction among horizontal two-dimensional directions of the pipe by vibration of the building; A clamp connected to the lower end of the lower bracket for supporting the pipe in a manner to surround the pipe; And a spring accommodated in the spring holder and expanded and contracted in the vertical direction of the pipe by the vibration of the building, wherein the spring urges the vertical portion between the lower end of the upper bracket and the upper end of the lower bracket, And is accommodated in the spring holder in a structure in which the directional gap is changed.

Wherein the pipe hanger of the three-dimensional seam structure has a lower end of the upper bracket and an upper end of the spring holder penetrating in the second direction so that the lower end of the upper bracket and the spring holder And the upper end of the spring holder is reciprocated in the first direction by a structure in which the spring holder rotates about the upper shaft.

Wherein the upper bracket has a circular rotating hole formed therein and a rectangular slit hole is formed at an upper end of the spring holder, the upper shaft is rotatably supported by a slit hole at a lower end of the upper bracket and a slit hole at an upper end of the spring holder, The upper bracket and the upper end of the spring holder are inserted into the slit hole at the upper end of the spring holder in a state of being rotatably engaged with the lower end of the upper bracket, And the spring holder is reciprocated in the vertical direction in accordance with the vertical sliding movement of the upper shaft in the slit hole at the upper end of the spring holder while rotating about the upper shaft in the rotary hole at the lower end of the upper bracket, Can be moved.

The spring is housed in the spring holder with a structure in which the upper end of the spring is pressed on the outer peripheral surface of the upper shaft inserted into the rotary hole at the lower end of the upper bracket and the slit hole at the upper end of the spring holder in the second direction, The shaft can be reciprocated in the vertical direction in accordance with the expansion and contraction of the spring in the slit hole at the upper end of the spring holder in a state of being rotationally coupled to the lower end of the phase bracket.

And a lower shaft connecting the lower end of the spring holder and the upper end of the lower bracket in a state in which the axial direction is arranged in the first direction by passing the lower end of the spring holder and the upper end of the lower bracket in the first direction The lower bracket is rotatable about the lower shaft, and the lower end of the lower bracket can reciprocate in the second direction.

Wherein a circular slit hole is formed in the lower end of the spring holder, and a circular rotation hole is formed in the upper end of the lower bracket, and the lower shaft is engaged with the slit hole at the lower end of the spring holder and the slit hole at the upper end of the lower bracket Wherein the lower end of the spring holder and the upper end of the lower bracket pass through the slit hole at the lower end of the spring holder in the first direction so as to be rotatably engaged with the upper rotation hole of the lower bracket, And the lower bracket rotates about the lower shaft in the rotating hole at the upper end of the lower bracket and reciprocates in the vertical direction in accordance with the vertical sliding movement of the lower shaft in the slit hole at the lower end of the spring holder, Can be moved.

Wherein the spring is accommodated in the spring holder with a structure in which the lower end of the spring is pressed on the outer peripheral surface of the lower shaft inserted in the first direction in the slit hole at the lower end of the spring holder and in the rotation hole at the upper end of the lower bracket, The shaft can be reciprocated in the vertical direction in accordance with the expansion and contraction of the spring in the slit hole at the lower end of the spring holder in a state of being rotationally coupled to the rotation hole at the upper end of the lower bracket.

An upper shaft connecting a lower end of the upper bracket and an upper end of the spring holder with the lower end of the upper bracket and the upper end of the spring holder penetrating in the second direction so that the axial direction is arranged in the second direction; And a lower shaft connecting the lower end of the spring holder and the upper end of the lower bracket in a state in which the axial direction is arranged in the first direction by passing the lower end of the spring holder and the upper end of the lower bracket in the first direction And the spring is inserted between the upper shaft and the lower shaft so as to be inserted into the spring holder, the vertical distance between the lower end of the upper bracket and the upper end of the lower bracket is changed according to the expansion and contraction of the spring .

The lower end of the upper bracket and the upper end of the spring holder are rotatably connected so that the lower end of the spring holder reciprocates in a first one of the horizontal two-dimensional directions of the pipe by the vibration of the building, The lower end of the spring holder and the upper end of the lower bracket are rotatably connected so that the lower end of the lower bracket is moved in a second direction orthogonal to the first direction of the horizontal two- The component corresponding to the second direction of vibration of the building is hardly transmitted to the pipe.

The spring is stretched in the vertical direction of the pipe due to vibration of the building, and the vertical distance between the lower end of the upper bracket and the upper end of the lower bracket is changed according to the expansion of the pipe. The component corresponding to the direction is hardly transmitted to the pipe. As described above, the horizontal two-dimensional direction component and the vertical direction component of the building vibration, that is, the omni-directional component, are hardly transmitted to the pipe, so that the three-dimensional vibration isolation can be performed on the pipe. As a result, even if the building vibrates in any arbitrary direction, the building vibration is hardly transmitted to the pipe, so that various accidents due to vibration of the pipe can be completely prevented.

The upper shaft is reciprocally moved in the vertical direction within the slit hole at the upper end of the spring holder in a state of being rotationally coupled to the lower rotary shaft of the upper bracket so that seam in the transverse direction and seam in the vertical direction can be simultaneously made. The lower shaft is reciprocally moved in the vertical direction within the slit hole at the lower end of the spring holder in a state of being rotationally coupled to the upper rotary shaft of the lower bracket so that the vertical seam of the pipe and the vertical seam of the pipe can be simultaneously achieved. As described above, it is possible to provide a seismic pipe hanger that realizes three-dimensional seismic isolation with a very simple structure by making it possible to perform seismic isolation in different directions using a common member.

As the outer circumferential surface of the upper shaft is pressed against the upper end of the spring and reciprocates in the vertical direction according to the expansion and contraction of the spring in the slit hole at the upper end of the spring holder, Can be made independently at the same time. As the outer peripheral surface of the lower shaft is pressed to the lower end of the spring and reciprocates in the vertical direction according to the expansion and contraction of the spring within the slit hole at the lower end of the spring holder, The vertical isolation can be made independently at the same time. Since the isolation of the pipe in the three-dimensional direction can be made independently for each direction, the vibration of the pipe can be quickly and greatly attenuated.

The spring is accommodated in the spring holder by being inserted between the upper shaft and the lower shaft so that the vertical distance between the lower end of the upper bracket and the upper end of the lower bracket is changed in accordance with the expansion and contraction of the spring. Accordingly, the upper shaft and the lower shaft are always in close contact with the upper and lower ends of the spring, respectively, due to the restoring force of the spring. Since the vertical distance between the lower end of the upper bracket and the upper end of the lower bracket is changed in accordance with the expansion and contraction of the spring, the impact due to the vertical vibration of the pipe can be mitigated by the elasticity of the spring. In addition, in order for the pipe to rise, the inserted spring compressed between the upper shaft and the lower shaft must be further compressed, so that the up-and-down vibration width of the pipe is reduced, so that the impact due to the lowering of the pipe can be largely mitigated.

1 is a perspective view of a seismic resistant pipe hanger 1 according to an embodiment of the present invention.
2 is a front view of the anti-seize pipe hanger 1 shown in Fig.
Fig. 3 is a side view of the anti-seize pipe hanger 1 shown in Fig.
4 is an enlarged perspective view of the anti-seize pipe hanger 1 shown in Figs. 1-3.
5 is an enlarged side view of the anti-seizeable pipe hanger 1 shown in Figs. 1-3.
6 is an enlarged cross-sectional view of the anti-seize pipe hanger 1 shown in Figs. 1-3.
Fig. 7 is a view showing a three-dimensional seismic isolation operation of the seismic pipe hanger 1 shown in Figs. 4-6.
Fig. 8-9 is a view showing various installation examples of the seismic resistant pipe hanger 1 shown in Figs. 4-6.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. The following embodiments relate to a pipe hanger for hanging on a ceiling of a building and supporting various kinds of pipes such as a gas pipe, a water pipe, a sewer pipe, a fire extinguishing device, a pipe for flowing fluid such as a cooling device, And particularly to an earthquake-resistant pipe hanger having an earthquake-resistant means for preventing vibration of a building due to an earthquake or the like from being transmitted to the pipe. Hereinafter, with reference to the drawings, the up, down, left, and right directions of the members constituting the seismic pipe hanger are determined based on the position of the pipe installed in the upper space of the building.

Generally, seismic isolation means to prevent the vibration of the ground from being transmitted to the object by inserting a means for blocking vibration such as an elastic body between the ground and the object to protect an object from an earthquake. Damping refers to setting up a means for controlling the vibration of an object and canceling the effect of the earthquake by applying a reaction force to the vibration. Dustproofing refers to preventing the vibration generated by a device corresponding to a vibration source from being transmitted to the outside, but it may also be used to mean vibration isolation and vibration suppression. Hereinafter, the seismic countermeasure of the pipe hanger according to the present embodiment will be referred to as "three-dimensional seismic isolation ". The seismic isolation may be referred to as being mixed with "dustproof ".

Fig. 1 is a perspective view of a seismic resistant pipe hanger 1 according to an embodiment of the present invention, Fig. 2 is a front view of a seismic resistant pipe hanger 1 shown in Fig. 1, Side pipe hanger 1. Fig. 1-3, each of the plurality of vertical rods 3 is formed in the form of a bolt, and the upper end of the vertical rods 3 is fixed to the ceiling of the building by being coupled with an anchor bolt 4 embedded in the ceiling of the building, . The lower end of each of the vertical rods 3 is connected to the upper end of the seismic pipe hanger 1 and the lower end of the seismic pipe hanger 1 is formed as a clamp structure to support the pipe 2 installed in the upper space of the building do.

Fig. 4 is an enlarged perspective view of the seismic pipe hanger 1 shown in Figs. 1-3, Fig. 5 is an enlarged side view of the seismic pipe hanger 1 shown in Figs. 1-3, 3 is an enlarged cross-sectional view of the vibration-proof pipe hanger 1 shown in Fig. Referring to Figs. 4-6, the anti-seize pipe hanger 1 shown in Fig. 1 includes an upper bracket 10, a spring holder 20, a lower bracket 30, a clamp 40, a spring 50, (60), and a lower shaft (70). Hereinafter, in the process of describing the seismic pipe hanger 1 shown in Figs. 4-6, the seismic pipe hanger 1 may further include other components in addition to the above-mentioned components. 4-6 illustrate an example in which the upper shaft 60 and the lower shaft 70 are fixed using wire clips, but they may be fixed in other ways.

Seismic waves are classified as surface waves propagating along the surface of the crust and crust, starting from the origin and propagating through the interior of the crust. The actual wave is classified into a primary wave oscillating in the direction of its propagation and a secondary wave oscillating perpendicular to the propagation direction. A surface wave is classified into a rayleigh wave oscillating while drawing an elliptical orbit in a vertical plane of its traveling direction and a love wave vibrating horizontally in a horizontal plane of the traveling direction. Due to this diversity of seismic waves, when an earthquake occurs, the building vibrates in any direction in the three-dimensional space in which it is installed. The arbitrary direction vibration of the building in the three-dimensional space is transmitted to the horizontal direction component which oscillates in an arbitrary direction on the horizontal plane of the space where the pipe 2 is placed, that is, on the two-dimensional plane including the longitudinal direction and the transverse direction of the pipe 2, Can be divided into vertical components oscillating in the height direction of the substrate 2.

1-3, the first direction of the horizontal two-dimensional direction of the pipe 2 described above is referred to as the lateral direction of the pipe 2, the direction of the pipe 2, And the second direction of the horizontal two-dimensional direction is specified as the longitudinal direction of the pipe 2. [ The seismic pipe hanger 1 can be installed in a state in which the left and right direction of the seismic pipe hanger 1 shown in Figs. 1-3 is somewhat slanted during installation work, and can be installed by turning 90 degrees. For example, the first one of the horizontal two-dimensional directions of the pipe 2 of the present invention is the longitudinal direction of the pipe 2, and the second one of the horizontal two-dimensional directions of the pipe 2 is the lateral direction of the pipe 2 . Here, the longitudinal direction of the pipe 2 may be expressed in the longitudinal direction of the pipe 20, and the lateral direction of the pipe 2 may be expressed in the width direction of the pipe 20.

The upper bracket 10 is a bracket of longitudinal section "U" shape, the upper end of which is connected to the lower end of one of the plurality of vertical rods 3. The upper bracket 10 is composed of an upper plate 11 in the form of a rectangular plate and two downward side plates 12 extending from both ends of the upper plate 11 and bent at right angles. A nut hole 13 is formed at the center of the upper plate 11 of the upper bracket 10 and a circular turn hole 14 is formed at the lower end of each of the downward side plates 12. The two downward side plates 12 of the upper bracket 10 extend from both ends of the upper plate 11 and are bent at right angles to face each other. Since the circular rotation holes 14 are formed in the lower ends of the respective lower side plates 12, two circular rotation holes 14 are formed on the two lower side plates 12 of the upper bracket 10 so as to face each other .

A nut hole 13 is formed in the center of the upper plate 11 of the upper bracket 10 in such a manner that the nut is welded or fastened to the center hole of the upper plate 11 of the upper bracket 10, The upper plate 11 of the upper bracket 10 may be formed in such a manner that the inner peripheral surface of the center hole of the upper plate 11 of the upper bracket 10 is formed in a female thread. And a nut hole 13 may be formed at the center of the hole.

The spring holder 20 is formed in the shape of a pipe in which the spring 50 can be embedded and the upper end thereof is rotatably connected to the lower end of the upper bracket 10 so that the lower end thereof is connected to the pipe 2 in the horizontal direction. The spring holder 20 is formed in the shape of a circular tube, and two rectangular slit holes 21 opposed to each other are formed at an upper end thereof. Two rectangular slit holes 22 are formed at the lower ends thereof. The opposite directions of the two slit holes 21 at the upper end of the spring holder 20 and the opposite directions of the two slit holes 22 at the lower end of the spring holder 20 are perpendicular to each other. The spring holder 20 may be formed in the shape of a round tube as shown in FIGS. 4-6, or may be formed in a pipe shape of a different type such as a square tube or a hexagonal tube.

The contact area between the spring holder 20 and the upper bracket 10 and the contact area between the spring holder 20 and the lower bracket 30 increase when the spring holder 20 is formed in the shape of a square tube, . This increase in the contact area leads to an increase in the frictional force at the contact portion, so that the reciprocal movement of the spring holder 20 and the lower bracket 30 for reducing the vibration of the pipe 2 due to vibration of the building, It may not be smoothly stretched or shrunk. The contact area between the spring holder 20 and the upper bracket 10 and the contact area between the spring holder 20 and the lower bracket 30 can be minimized when the spring holder 20 is formed in the shape of a circular tube, The reciprocating movement of the spring holder 20 and the lower bracket 30 due to the vibration and the expansion and contraction of the spring 50 can be smoothly performed.

When the building vibrates in the lateral direction of the pipe 2 due to an earthquake or the like, the pipe 2 tends to maintain its current position due to its inertia, and therefore, as one of the members supporting the load of the pipe 2, 2 is subjected to the load of the spring holder 20 moves toward the direction opposite to the vibration direction of the building. That is, when the ceiling of the building moves to the left side of the pipe 2 due to an earthquake or the like, the spring holder 20 moves in the right direction of the pipe 2 and the ceiling of the building moves in the right direction of the pipe 2 The spring holder 20 moves in the left direction of the pipe 2 so that the component corresponding to the lateral direction of the pipe 2 is hardly transmitted to the pipe 2 during the horizontal vibration of the building.

The lower bracket 30 is a bracket of an upper longitudinal section "II" shape and a lower longitudinal section "V" shape, the upper end of which is rotatably connected to the lower end of the spring holder 20, And reciprocates in the longitudinal direction of the pipe 2 orthogonal to the transverse direction of the pipe 2. The lower bracket 30 is composed of a left side plate 31 having a vertical section which is downwardly folded downward to a right side and a right side plate 32 having a vertical section which is downwardly folded downward to a left side by a rectangular plate. A circular rotation hole 34 is formed at the upper ends of the left and right side plates 31 and 32 of the lower bracket 30 and circular fastening holes 33 are formed at the lower ends of the circular holes 34 respectively.

As shown in Figs. 4-6, the left side plate 31 and the right side plate 32 of the lower bracket 30 are arranged symmetrically with respect to each other. A circular rotation hole 34 is formed at the upper ends of the left side plate 31 and the right side plate 32 arranged symmetrically with each other and circular fastening holes 33 are formed at the lower ends of the circular holes 34 The lower bracket 30 is formed with the two circular turning holes 34 facing each other and the two circular fastening holes 33 facing each other are formed.

When the building vibrates in the longitudinal direction of the pipe 2 due to an earthquake or the like, the pipe 2 tends to maintain its current position due to its inertia, so that any one of the members supporting the load of the pipe 2 2 is subjected to the load of the lower bracket 30 moves toward the direction opposite to the vibration direction of the building. That is, when the ceiling of the building moves toward the front side of the pipe 2 due to an earthquake or the like, the lower bracket 30 moves toward the rear side of the pipe 2, and the ceiling of the building moves toward the rear side of the pipe 2 The lower lower bracket 30 moves in the forward direction of the pipe 2 so that the component corresponding to the longitudinal direction of the pipe 2 is hardly transmitted to the pipe 2 during the horizontal vibration of the building.

The clamp 40 is a clamp having a longitudinal band circular band structure, and the upper end of the clamp 40 is connected to the lower end of the lower bracket 30 to support the pipe 2 in such a manner as to surround the pipe 2. The clamp 40 is composed of a left band 41, a right band 42, and a fastening member 43. The left band 41 is a longitudinally-left semicircular band having both ends of a rectangular piece, and circular fastening holes are formed on both ends of the rectangular piece. The right band 42 is a longitudinally semicircular band having both ends of a rectangular piece, and circular fastening holes are formed on both ends of the rectangular piece. The fastening member 43 fastens the upper end of the left band 41, the upper end of the right band 42 and the lower end of the lower bracket 30 arranged in the form of wrapping the pipe 2, And the lower end of the right band 42 are fastened together. The fastening between the lower bracket 30, the clamp 40 and the pipe 2 can be accomplished by the following process.

Referring to Figures 4-6, the pipe 2 is fastened to the left band (not shown) of the clamp 40 until both ends of the left band 41 of the clamp 40 and both ends of the right band 42 are brought into contact with each other 41 and the right band 42 are in close contact with each other. The upper end of the left band 41 and the upper end of the right band 42 are inserted between the lower end of the left side plate 31 of the lower bracket 30 and the lower end of the right side plate 32 . Subsequently, the lower end of the left side plate 31 and the lower end of the right side plate 32 of the lower bracket 30, the upper end of the left band 41 of the clamp 40, The lower end of the left band 41 of the clamp 40 and the lower end of the right band 42 are tightened so that the clamp 40 encircles the pipe 2 and clamps 40 is fixedly connected to the lower end of the lower bracket 30. [

The spring 50 is accommodated in the spring holder 20 by a spring of a compression coil type and is expanded and contracted in the vertical direction of the pipe 2 by the vibration of the building. The spring 50 is accommodated in the spring holder 20 in such a structure that the vertical distance between the lower end of the upper bracket 10 and the upper end of the lower bracket 30 is changed as the spring 50 expands and shrinks. If the building vibrates in the vertical direction of the pipe 2 due to an earthquake or the like, the pipe 2 tends to maintain its current position due to its inertia, so that any one of the members supporting the load of the pipe 2 2, the vertical spacing between the lower end of the upper bracket 10 and the upper end of the lower bracket 30 is changed toward the direction of vibration of the building so that the spring 50 also opposes the vibration direction of the building .

That is, when the ceiling of the building moves upward in the pipe 2 due to an earthquake or the like, the gap between the lower end of the upper bracket 10 and the upper end of the lower bracket 30 becomes wider, The lower bracket 30 is compressed so that the vibration component in the vertical direction of the building is transmitted to the pipe 2 through the pipe 2. [ (2). Thus, when the vertical distance between the lower end of the upper bracket 10 and the upper end of the lower bracket 30 is changed due to the vibration of the building, the vertical direction length of the seismic pipe hanger 1 against the vibration direction of the building The height of the pipe 2 can be kept substantially constant, so that an isolation in the vertical direction with respect to the pipe 2 can be achieved.

According to the present embodiment, it is possible to simultaneously perform seepage in the lateral direction of the pipe 2, seam in the longitudinal direction of the pipe 2, and seam in the vertical direction of the pipe 2. By virtue of such a three-dimensional seismic isolation structure, the horizontal direction component and the vertical direction component of the building vibration, that is, the forward direction component, are hardly transmitted to the pipe 2. As a result, even if the building vibrates in any arbitrary direction, since the building vibration is hardly transmitted to the pipe 2, various accidents due to vibration of the pipe 2 can be completely prevented. For example, the vibration of the pipe 2 can completely prevent the accident that the wire covering in the pipe is peeled off or the pipe is broken, the wire inside the pipe is cut off, or the fluid flowing in the pipe is leaked.

Fig. 7 is a view showing a three-dimensional seismic isolation operation of the seismic pipe hanger 1 shown in Figs. 4-6. 7 (a) is a view showing a state in which the spring holder 20 reciprocates in the lateral direction of the pipe 2 during the three-dimensional seismic operation of the seismic pipe hanger 1, Operation is shown. 7 (b) is a plan view of the horizontal two-dimensional direction in which the lower bracket 30 reciprocates in the longitudinal direction of the pipe 2 during the three-dimensional seam operation of the seismic pipe hanger 1, Operation is shown.

7 (c) and 7 (d) show a state in which the lower end of the upper bracket 10 and the lower bracket 30 (FIG. 7 In the vertical direction is shown by changing the vertical interval between the upper ends of the two frames. Particularly, Fig. 7 (c) shows the upward and downward movement of the spring holder 20 in accordance with the expansion and contraction of the spring 50 in the spring holder 20. Fig. 7 (d) Up and down movement of the lower bracket 30 as the spring 50 expands and contracts. 7 shows a state in which the spring holder 20 and the lower bracket 30 are moved up and down separately. However, in actual seismic operation, the spring holder 20 and the lower bracket 30 are simultaneously moved up and down .

The upper shaft 60 passes through the upper bracket 10 and the upper end of the spring holder 20 in the longitudinal direction of the pipe 2 so that the axial direction thereof is arranged in the longitudinal direction of the pipe 2, 10 and the upper end of the spring holder 20 are connected to each other. 7 (a), the spring holder 20 rotates about the upper shaft 60 passing through the lower end of the upper bracket 10 and the upper end of the spring holder 20 in the longitudinal direction of the pipe 2 The lower end thereof reciprocates in the transverse direction of the pipe 2 orthogonal to the longitudinal direction of the pipe 2 which is the axial direction of the upper shaft 60.

Since the axial direction of the upper shaft 60 and the axial direction of the lower shaft 70 are orthogonal to each other, the rotation of the spring holder 20 at the center of the upper shaft 60 and the rotation of the lower bracket 30 at the center of the lower shaft 70 mutually It does not affect and operates independently. Accordingly, when the lower end of the spring holder 20 reciprocates in the transverse direction of the pipe 2 due to the vibration of the building, the lower bracket 30 rotatably connected to the lower end of the spring holder 20 is also engaged with the spring holder 20 And is reciprocally moved in the lateral direction of the pipe 2 in the same manner. As a result, the clamp 40 fixedly connected to the lower bracket 30 and the pipe 2 supported by the clamp 40 are moved together with the spring holder 20 and the lower bracket 30 in the transverse direction of the pipe 2 So that it is possible to perform seismic isolation in the transverse direction with respect to the pipe 2.

The lower shaft 70 passes through the lower end of the spring holder 20 and the upper end of the lower bracket 30 in the transverse direction of the pipe 2 so that the axial direction of the spring holder 20 And the upper end of the lower bracket 30 are connected to each other. 7 (b), the lower bracket 30 is rotated about the lower shaft 70 which penetrates the lower end of the spring holder 20 and the upper end of the lower bracket 30 in the transverse direction of the pipe 2 And the lower end thereof reciprocates in the longitudinal direction of the pipe 2 orthogonal to the transverse direction of the pipe 2 which is the axial direction of the lower shaft 70.

When the lower end of the lower bracket 30 reciprocates in the longitudinal direction of the pipe 2 due to the vibration of the building, the clamp 40 fixedly connected to the lower bracket 30 is also connected with the lower bracket 30, In the longitudinal direction. As a result, the pipe 2 supported by the clamp 40 also reciprocates in the longitudinal direction of the pipe 2 together with the lower bracket 30 and the clamp 40, An earthquake in the direction can be achieved.

As described above, the upper bracket 10 is provided at the lower end thereof with two circular rotating holes 14 facing each other. Two rectangular slit holes 21 are formed at the upper end of the spring holder 20, . The upper shaft 60 is inserted into the slit hole 21 at the upper end of the spring holder 20 in the longitudinal direction of the pipe 2 in the upper bracket 10, And the upper end of the spring holder 20 in the longitudinal direction of the pipe 2. Each of the rotary holes 14 at the lower end of the upper bracket 10 has a diameter such that the upper shaft 60 can smoothly rotate without clearance, Each slit hole 21 has a width such that the upper shaft 60 inserted into the slit hole 21 smoothly slides without clearance and reciprocates in the vertical direction. The length of each slit hole 21 at the upper end of the spring holder 20 is a distance at which the upper shaft 60 can reciprocate.

 The upper shaft 60 reciprocally moves in the vertical direction within the slit hole 412 at the upper end of the spring holder 20 while being rotatably engaged with the rotary hole 14 at the lower end of the upper bracket 10. The spring holder 20 rotates about the upper axis 60 in the rotation hole 14 at the lower end of the upper bracket 10 and rotates about the upper axis in the slit hole 412 at the upper end of the spring holder 20 60 in the vertical direction. 7 (a) and 7 (c), the spring holder 20 has a structure in which the lower end of the spring bracket 10 rotates about the upper axis 60 in the rotation hole 14, 2 reciprocating in the vertical direction in accordance with the sliding movement of the upper shaft 60 in the vertical direction within the slit hole 412 at the upper end of the spring holder 20.

Accordingly, when the lower end of the spring holder 20 reciprocates in the horizontal direction while reciprocating in the vertical direction by the vibration of the building, the lower bracket 30 rotatably connected to the lower end of the spring holder 20 Together with the spring holder 20, reciprocate in the vertical direction while reciprocally moving in the transverse direction of the pipe 2. As a result, the clamp 40 connected to the lower bracket 30, the pipe 2 supported by the clamp 40, as well as the spring holder 20 and the lower bracket 30, So that it is possible to simultaneously perform the seam in the transverse direction and the seam in the vertical direction with respect to the pipe 2.

As described above, two rectangular slit holes 22 opposed to each other are formed at the lower end of the spring holder 20. Two round holes 34 opposed to each other are formed at the upper end of the lower bracket 30 Respectively. The lower shaft 70 is inserted into the slit hole 22 at the lower end of the spring holder 20 and the rotating hole 34 at the upper end of the lower bracket 30 in the transverse direction of the pipe 2, And the upper end of the lower bracket 30 is passed through the pipe 2 in the lateral direction. 4-6, each slit hole 22 at the lower end of the spring holder 20 has a width such that the lower shaft 70 inserted in the slit hole 22 can smoothly slide without any clearance and reciprocate in the vertical direction, Each of the rotating holes 34 at the upper end of the lower bracket 30 has a diameter such that the lower shaft 70 inserted therein can smoothly rotate without clearance. The length of each slit hole 22 at the lower end of the spring holder 20 is a distance at which the lower shaft 70 can reciprocate.

The lower shaft 70 reciprocally moves in the vertical direction within the slit hole 22 at the lower end of the spring holder 20 while being rotatably engaged with the turn hole 34 at the upper end of the lower bracket 30. [ The lower bracket 30 rotates about the lower shaft 70 in the turn hole 34 at the upper end of the lower bracket 30 so as to rotate the lower bracket 30 in the slit hole 22 at the lower end of the spring holder 20 70 in the vertical direction. 7 (b) and 7 (d), the lower bracket 30 has a structure in which the lower end of the lower bracket 30 rotates about the lower shaft 70 in the turn hole 34 at the upper end of the lower bracket 30, 2 so as to move reciprocally in the vertical direction in accordance with the sliding movement of the lower shaft 70 in the vertical direction within the slit hole 22 at the lower end of the spring holder 20. [

Thus, when the lower end of the lower bracket 30 reciprocates in the vertical direction of the pipe 2 due to the vibration of the building, the clamp 40 fixed to the lower bracket 30 is also moved to the lower bracket 30 30 in the vertical direction while reciprocating in the longitudinal direction of the pipe 2 in the same manner. As a result, the clamp 40 connected to the lower bracket 30, the pipe 2 supported by the clamp 40, as well as the lower bracket 30 and the clamp 40, extend in the longitudinal direction of the pipe 2 The pipe 2 is reciprocated in the vertical direction while being reciprocated, so that the pipe 2 can be simultaneously subjected to the seam in the longitudinal direction and the seam in the vertical direction.

The horizontal component of the building vibration can be divided into the lateral component and the longitudinal component of the pipe 2 which are orthogonal to each other because it is a component that vibrates in an arbitrary direction on a two-dimensional plane corresponding to the horizontal plane of the pipe 2. [ As described above, the lateral reciprocation of the lower end of the spring holder 20 due to the rotation of the spring holder 20 about the upper shaft 60 makes it possible to segregate in the lateral direction of the pipe 2, ) Of the lower bracket 30 in accordance with the rotation of the lower bracket 30 at the center of the pipe 2 in the horizontal direction. With this two-dimensional seismic structure, the horizontal component of the building vibration is hardly transmitted to the pipe 2.

The connection structure between the rotation hole 14 at the lower end of the upper bracket 10 and the slit hole 21 at the upper end of the spring holder 20 by the above- It is possible to simultaneously perform the seam in the lateral direction and the seam in the vertical direction and the rotation hole 34 at the upper end of the lower bracket 30 by the lower shaft 70 and the slit hole 22 at the lower end of the spring holder 20, It is possible to simultaneously perform an isolation in the longitudinal direction of the pipe 2 and an isolation in the vertical direction thereof.

The three-dimensional seismic isolation structure of this embodiment is not a structure in which the seismic isolation of each dimension is made by a separate member, but the seismic isolation in the lateral direction and the seismic isolation in the vertical direction are made by the same member, Is made by the same member. As described above, according to the present embodiment, it is possible to provide a seismic pipe hanger for realizing three-dimensional seismic isolation with a very simple structure by enabling seismic isolation in different directions by using a common member, Thereby increasing the manufacturing cost and minimizing the maintenance burden.

The spring 50 is attached to the outer peripheral surface of the upper shaft 60 inserted in the longitudinal direction of the pipe 2 in the slit hole 21 at the upper end of the spring holder 20 and the turn hole 14 at the lower end of the upper bracket 10 And is housed in the spring holder 20 in such a structure that the upper end of the spring 50 is squeezed. The washer may be inserted between the outer peripheral surface of the upper shaft 60 and the upper end of the spring 50 as shown in Figures 5-6 so that the upper end of the spring 50 can be stably pressed onto the outer peripheral surface of the upper shaft 60 have. The upper shaft 60 rotates along the extension and retraction of the spring 50 in the slit hole 21 at the upper end of the spring holder 20 in a state of being rotatably engaged with the rotation hole 14 at the lower end of the upper bracket 10 Thereby reciprocating in the vertical direction. The spring holder 20 has a structure in which the lower end of the spring holder 20 rotates about the upper shaft 60 inserted in the longitudinal direction of the pipe 2 in the turn hole 14 at the lower end of the upper bracket 10, And also reciprocates in the vertical direction of the pipe 2. [0050]

That is, the lower end of the spring holder 20 moves upward as it moves away from the vertical state of the spring holder 20 as it reciprocates in the transverse direction of the pipe 2, and as the spring holder 20 approaches the vertical state of the spring holder 20 . Thus, the rotational movement of the spring holder 20 for seepage in the transverse direction relative to the pipe 2 causes the vibration of the spring holder 20 in the vertical direction of the pipe 2. The outer circumferential surface of the upper shaft 60 is pressed against the upper end of the spring 50 and is reciprocated in the vertical direction in accordance with the expansion and contraction of the spring 50 in the slit hole 21 at the upper end of the spring holder 20. [ The elasticity of the spring 50 incorporated in the spring holder 20 can absorb the vibration of the spring holder 20 in the vertical direction of the pipe 2 thus induced. As described above, it is possible to independently perform the isolation of the pipe 2 in the transverse direction and the isolation of the pipe 2 in the vertical direction, without interfering with each other.

The spring 50 is provided on the outer peripheral surface of the lower shaft 70 inserted into the slit hole 22 at the lower end of the spring holder 20 and the rotating hole 34 at the upper end of the lower bracket 30 in the transverse direction of the pipe 2 And the lower end of the spring 50 is compressed. The lower shaft 70 is rotated in the slit hole 22 at the lower end of the spring holder 20 in the state of being rotatably engaged with the rotating hole 34 at the upper end of the lower bracket 30 Thereby reciprocating in the vertical direction. The lower bracket 30 has a structure in which the lower bracket 30 rotates around a lower shaft 70 inserted in the transverse direction of the pipe 2 at the turn hole 34 at the upper end of the lower bracket 30, And also reciprocates in the vertical direction of the pipe 2. [0050]

That is, the lower end of the lower bracket 30 moves upward as it moves away from the vertical state of the lower bracket 30 as it reciprocates in the longitudinal direction of the pipe 2, and the closer to the vertical state of the lower bracket 30 . Thus, the rotation of the lower bracket 30 for isolating the pipe 2 in the longitudinal direction thereof causes the vibration of the lower bracket 30 in the vertical direction of the pipe 2. The outer peripheral surface of the lower shaft 70 is pressed against the lower end of the spring 50 to be reciprocated in the vertical direction in accordance with the expansion and contraction of the spring 50 in the slit hole 22 at the lower end of the spring holder 20. [ The elasticity of the spring 50 incorporated in the spring holder 20 can absorb the vibration of the lower bracket 30 in the vertical direction of the pipe 2 thus induced. In this way, it is possible to independently perform the isolation of the pipe 2 in the longitudinal direction and the isolation of the pipe 2 in the vertical direction, without interfering with each other.

Korean Patent No. 10-1687663 "" Hanger for Piping with Dustproofing Device" and the like, most of the conventional seismic pipe hanger have vibration preventing means capable of preventing only vertical vibration, There was a problem of being vulnerable. Korean Patent No. 10-1102908 discloses an anti-seismic spring safety hanger, which is constructed such that a fastening member for hanging a support bracket coupled to an upper end of a pipe band to a ceiling of a building is inserted into a spring A pipe hanger having a protruding structure is proposed. Through such a structure, the fastening member can swing back and forth, right and left in the fastening hole of the support bracket, so that an impact due to an earthquake or the like applied to the pipe in the horizontal direction can be buffered.

However, since the fastening members of the seismic pipe hanger are capable of swinging in only one direction at any point, the inertia of the swing causes the horizontal surface of the space in which the pipe is placed, that is, There is a limitation in rapidly attenuating the horizontal component that vibrates in an arbitrary direction on the two-dimensional plane. According to the present embodiment, since the isolation of the pipe 2 in the three-dimensional direction can be independently performed in each direction without interfering with each other, the vibration of the building can be instantaneously So that the vibration of the pipe 2 can be quickly and greatly attenuated.

The vertical direction of the pipe 2 is a direction coinciding with the gravity direction thereof, unlike its lateral direction and its longitudinal direction, and its load is applied to its maximum. The load of the pipe 2 in the state where the fluid flows or the electric wire is embedded is considerable. When the pipe 2 vibrates in the vertical direction due to the vibration of the building, the load of the pipe 2 is added at the moment when the pipe 2 descends. As described above, in order to install the pipe 2 in the indoor upper space of the building, several anchor bolts 4 are buried in the ceiling of the building. As the vertical vibration width of the pipe 2 is increased, the pipe 2 descends from a higher position, so that the impact applied to the anchor bolt 4 embedded in the ceiling of the building becomes very large.

When the impact applied to the anchor bolt 4 due to the descent of the pipe 2 exceeds the fastening force between the ceiling of the building and the anchor bolt 4, an anchor bolt 4 is pulled out of the ceiling of the building. The spring 50 is accommodated in the spring holder 20 in such a structure that the spring 50 is inserted between the upper shaft 60 and the lower shaft 70 so that the lower end of the upper bracket 10 And the upper end of the lower bracket 30 is changed. The upper shaft 60 and the lower shaft 70 are always brought into close contact with the upper end and the lower end of the spring 50 by the restoring force of the spring 50. [

Since the vertical distance between the lower end of the upper bracket 10 and the upper end of the lower bracket 30 changes in accordance with the expansion and contraction of the spring 50 as described above, The impact caused by the impact can be mitigated. In addition, in order for the pipe 2 to rise, the inserted spring 50 is further compressed between the upper shaft 60 and the lower shaft 70 so that the vertical vibration width of the pipe 2 is reduced, Can be significantly reduced. Particularly, since the spring 50 is received in the spring holder 20 in such a structure that the spring 50 is pressed and inserted between the upper shaft 60 and the lower shaft 70, not only the spring 50 can be protected from external impact, So that the operation reliability can be improved.

Fig. 8-9 is a view showing various installation examples of the seismic resistant pipe hanger 1 shown in Figs. 4-6. Fig. 8 shows an example in which the seismic pipe hanger 1 is applied to all of the plurality of vertical rods 3. Fig. On the other hand, Fig. 9 shows an example in which a plurality of vertical load 3 is applied one by one to the seismic resistant pipe hanger 1 in order to reduce the installation cost of the seismic resistant pipe hanger 1. In the example shown in Fig. 9, since the vibration of the building is transmitted to the pipe 2 through the vertical rod 3 to which the earthed pipe hanger 1 is not applied, the three- And the three-dimensional earthquake for the pipe 2 is operated only when the vertical rod 3 not subjected to the vibration-proof pipe hanger 1 is dropped or broken from the ceiling of the building due to the vibration of the building, The vertical rods 3 to which the pipe hanger 1 is applied are supported by the pipe 2 alone. In this case, the eccentric pipe hanger 1 plays the role of temporarily supporting the pipe 2 until an accident is found by the manager and the repair is completed.

The present invention has been described with reference to the preferred embodiments. It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims. Therefore, the disclosed embodiments should be considered in an illustrative rather than a restrictive sense. The scope of the present invention is defined by the appended claims rather than by the foregoing description, and all differences within the scope of equivalents thereof should be construed as being included in the present invention.

1 ... pipe hanger
10 ... phase bracket
11 ... upper plate 12 ... lower side plate
20 ... spring holder
21, 22 ... slit ball
30 ... lower bracket
31 ... left plate 32 ... right plate
13 ... nut ball 33 ... fastener
14, 34 ...
40 ... Clamp
41 ... left band 42 ... right band
43 ... fastening member
50 ... spring
60 ... square
70 ... undercarriage
2 ... pipe
3 ... vertical load
4 ... anchor bolt

Claims (8)

In a pipe hanger having a three-dimensionally grounded structure,
An upper bracket 10 fixed to a ceiling of a building and connected to a lower end of a vertical rod 3 which is downwardly extended;
And a lower end rotatably connected to a lower end of the upper bracket 10 so as to reciprocate in a first direction of a horizontal two-dimensional direction of the pipe 2 installed in an upper space of the building by vibration of the building, (20);
And a lower end rotatably connected to a lower end of the spring holder 20 so that an upper end thereof is reciprocally moved in a second direction orthogonal to the first direction among horizontal two-dimensional directions of the pipe 2 due to vibration of the building A bracket 30;
A clamp (40) connected to the lower end of the lower bracket (30) to support the pipe (2) so as to surround the pipe (2); And
And a spring (50) received in the spring holder (20) and stretched and contracted in the vertical direction of the pipe (2) by the vibration of the building,
The spring 50 has a structure in which the vertical distance between the lower end of the upper bracket 10 and the upper end of the lower bracket 30 varies according to the expansion and contraction of the spring 50, Accommodated,
The lower bracket 10 and the spring holder 20 are inserted in the second direction with the lower end of the upper bracket 10 and the upper end of the spring holder 20 passing in the second direction, 20), wherein the upper shaft (60)
The spring holder 20 has a structure in which the spring holder 20 is rotated about the upper shaft 60, the lower end of the spring holder 20 reciprocates in the first direction,
A circular rotating hole 14 is formed in the lower end of the upper bracket 10 and a rectangular slit hole 21 is formed in the upper end of the spring holder 20,
The upper shaft 60 is inserted into the slit hole 21 at the lower end of the upper bracket 10 and the upper end of the spring holder 20 in the second direction so that the upper bracket 10 Of the upper end of the spring holder 20 and the upper end of the spring holder 20 in the second direction so as to be rotatably engaged with the rotation hole 14 at the lower end of the upper bracket 10, Reciprocates vertically in the hole 21,
The spring holder 20 rotates about the upper axis 60 in the rotation hole 14 at the lower end of the upper bracket 10 and rotates about the upper axis of the slit hole 21 at the upper end of the spring holder 20 60 reciprocate in the vertical direction in accordance with the vertical sliding movement of the pipe hanger. delete delete The method according to claim 1,
The spring 50 is mounted on the outer peripheral surface of the upper shaft 60 inserted in the second direction in the slit hole 21 at the upper end of the spring holder 20 and the turn hole 14 at the lower end of the upper bracket 10 The spring 50 is received in the spring holder 20 in a structure in which the upper end of the spring 50 is compressed,
The upper shaft 60 is rotatably coupled to the rotation hole 14 at the lower end of the upper bracket 10 so as to be rotatable in the expansion and contraction of the spring 50 in the slit hole 21 at the upper end of the spring holder 20 And reciprocates in the vertical direction. The method according to claim 1,
The lower end of the spring holder (20) and the lower bracket (30) are inserted through the lower end of the spring holder (20) and the upper end of the lower bracket 30), wherein the lower end of the lower portion (70)
Wherein the lower bracket (30) rotates about the lower shaft (70), and the lower end of the lower bracket (30) reciprocates in the second direction. 6. The method of claim 5,
A rectangular slit hole 22 is formed in the lower end of the spring holder 20. A circular turn hole 34 is formed in the upper end of the lower bracket 30,
The lower shaft 70 is inserted into the slit hole 22 at the lower end of the spring holder 20 and the rotation hole 34 at the upper end of the lower bracket 30 in the first direction, The lower end of the lower bracket 30 and the upper end of the lower bracket 30 penetrate in the first direction so as to be rotatably engaged with the turn hole 34 at the upper end of the lower bracket 30, Reciprocates vertically in the hole 22,
The lower bracket 30 rotates about the lower shaft 70 in the rotation hole 34 at the upper end of the lower bracket 30 and rotates about the lower shaft 30 in the slit hole 22 at the lower end of the spring holder 20 70 reciprocate in the vertical direction in accordance with the vertical sliding movement of the pipe hanger. The method according to claim 6,
The spring 50 is inserted into the outer peripheral surface of the lower shaft 70 inserted into the slit hole 22 at the lower end of the spring holder 20 and the rotation hole 34 at the upper end of the lower bracket 30 in the first direction The lower end of the spring (50) is compressed and housed in the spring holder (20)
The lower shaft 70 is rotatably engaged with the rotation hole 34 at the upper end of the lower bracket 30 so as to be rotatable about the extension and retraction of the spring 50 in the slit hole 22 at the lower end of the spring holder 20 And reciprocates in the vertical direction. The method according to claim 1,
The lower end of the spring holder (20) and the lower bracket (30) are inserted through the lower end of the spring holder (20) and the upper end of the lower bracket 30), wherein the lower end of the lower portion (70)
The spring 50 is inserted between the upper shaft 60 and the lower shaft 70 so as to be inserted into the spring holder 20 so that the upper bracket 10, And the vertical distance between the lower end of the lower bracket (30) and the upper end of the lower bracket (30) is changed.

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