KR20220001123A - Multiple seismic pipe mounting module and piping construction method using the same - Google Patents

Abstract

The present invention relates to a multi-seismic pipe mounting module capable of simplifying onsite work and shortening a construction period by constructing pipes through a pipe mounting module having a seismic structure, and a pipe construction method using the same. The multi-seismic pipe mounting module includes: a first frame comprising a horizontal frame, a first coupling frame and a second coupling frame; a second frame comprising a first vertical frame, a first mounting frame and a first placement frame; a third frame comprising a second vertical frame, a second mounting frame and a second placement frame; a fourth frame having one side placed in the first placement frame, and having the other side placed in the second placement frame; and at least one fixing part installed in a sliding groove extended in a longitudinal direction along an upper part of the fourth frame to be moved along the sliding groove, and fixing a pipe.

Description

Multiple seismic-resistant pipe mounting module and pipe construction method using the same

The present invention relates to a multi-seismic type pipe mounting module and a pipe construction method using the same, and more particularly, to simplify field work and shorten the construction period by constructing a pipe using a pipe mounting module having an earthquake-resistant structure. It relates to a multi-seismic type pipe mounting module and a pipe construction method using the same.

The vibration isolation structure, the vibration-proof structure, and the vibration suppression structure refer to the structure type that controls the vibration response of the structure, and there are various types of control methods for the vibration control method of the structure.

In general, vibration refers to all types of vibrations input to structures, such as mechanical vibrations and traffic vibrations, as well as vibrations of structures caused by earthquakes or winds.

Seismic design that controls these vibrations requires that the target structure and the components connected to it have certain strength to withstand earthquakes, as well as ductility to flexibly respond to the shaking of earthquakes. should make it

For example, in various building structures such as steel structures and concrete structures, pipes are installed to be used for water supply, drainage, hot water, and heating and cooling. A brace is being installed.

The anti-vibration support device of the pipe has one side connected to the building structure and the other side connected to the pipe to prevent the pipe from shaking due to an earthquake.

On the other hand, the above-mentioned background art is technical information that the inventor possessed for the purpose of derivation of the present invention or acquired during the derivation process of the present invention, and it cannot be said that it is necessarily known technology disclosed to the general public before the filing of the present invention. .

Korean Patent Publication No. 10-2020-0072459 Korean Patent Publication No. 10-2020-0033590

One aspect of the present invention provides a multi-seismic type pipe mounting module implemented to simplify field work and shorten air by constructing a pipe using a pipe mounting module having an earthquake-resistant structure, and a pipe construction method using the same.

The technical problems of the present invention are not limited to the technical problems mentioned above, and other technical problems not mentioned will be clearly understood by those skilled in the art from the following description.

" 형태로 형성되어 상기 수평 프레임의 일측 및 다른 일측에 형성되는 제1 체결 프레임 및 제2 체결 프레임으로 이루어지는 제1 프레임; 상하 수직 방향으로 연장 형성되는 제1 수직 프레임, 상기 제1 체결 프레임에 체결될 수 있도록 "ㄱ" 형태로 절곡되어 상기 제1 수직 프레임의 상측에 형성되는 제1 거치 프레임, 및 상기 제1 수직 프레임의 하측으로부터 돌출 형성되는 제1 안착 프레임으로 이루어지는 제2 프레임; 상하 수직 방향으로 연장 형성되는 제2 수직 프레임, 상기 제2 체결 프레임에 체결될 수 있도록 "ㄱ" 형태로 절곡되어 상기 제2 수직 프레임의 상측에 형성되는 제2 거치 프레임, 및 상기 제2 수직 프레임의 하측으로부터 상기 제2 프레임 방향으로 돌출 형성되는 제2 안착 프레임으로 이루어지는 제3 프레임; 일측이 상기 제1 안착 프레임에 안착되고, 다른 일측이 상기 제2 안착 프레임에 안착되는 제4 프레임; 및 상기 제4 프레임의 상부를 따라 길이 방향으로 연장 형성되는 슬라이딩 홈에 설치되어 상기 슬라이딩 홈을 따라 이동하며, 배관을 고정하는 적어도 하나 이상의 고정부;를 포함한다.A multi-seismic pipe mounting module according to an embodiment of the present invention includes a horizontal frame extending in a horizontal direction and fixedly installed on the ceiling of a building;

A first frame formed in the shape of a first fastening frame and a second fastening frame formed on one side and the other side of the horizontal frame; a first vertical frame extending in the vertical direction and fastened to the first fastening frame A second frame made of a first mounting frame that is bent in an “a” shape to be formed on the upper side of the first vertical frame, and a first seating frame that is formed to protrude from the lower side of the first vertical frame; vertical direction a second vertical frame extending from the second vertical frame, a second mounting frame bent in a “L” shape to be fastened to the second fastening frame and formed on the upper side of the second vertical frame, and from the lower side of the second vertical frame a third frame including a second seating frame protruding in the direction of the second frame; a fourth frame having one side mounted on the first seating frame and the other side mounted on the second seating frame; and the fourth frame and at least one fixing part installed in a sliding groove extending in the longitudinal direction along the upper part of the to move along the sliding groove and fixing the pipe.

In one embodiment, the multi-seismic type pipe mounting module according to an embodiment of the present invention is configured such that the first mounting frame is mounted so as to buffer vibration or shock transmitted from the first frame to the second frame. It may further include an upper seismic resistance portion installed on the mounting surface of the first fastening frame.

In one embodiment, the upper seismic resistance portion, a pedestal for supporting the first mounting frame; an elevating slider that is formed in a cylindrical shape and is rotatably connected to the lower side of the pedestal, and forms a first screw thread in a spiral direction along an outer circumferential surface; It is installed on the mounting surface of the first fastening frame, and forms a seating groove having a shape corresponding to the shape of the elevating slider so that the elevating slider is seated and sliding in the up-down direction, and the elevating slider rotates up and down a support body in which a second screw thread is formed in a helical direction for connection and installation of the first screw thread along an inner circumferential surface of the seating groove so as to be moved in the direction; A third gear mountain in the form of a spur gear is formed along the outer circumferential surface and connected to the lower side of the elevating slider, and when the elevating slider descends more than a preset depth in the seating groove, it rotates together with the elevating slider. descending support gear; a gear support spring connected to the lower side of the support gear and configured to support the support gear by using an elastic force from the lower side of the seating groove; Horizontally installed in the lower part of the seating groove and connected to the third gear mountain of the support gear, the rotation of the support gear is prevented by using an elastic force so as to block the descent of the elevating slider. brake; and installed on the support body, and is compressed in the vertical direction as the pedestal descends so as to be in close contact with the first screw thread as the second screw thread is expanded in the vertical direction to brake the rotation of the first screw thread, and is compressed in the internal space It may include a; vertical braking unit for supplying the fluid accommodated in each of the second thread.

In one embodiment, the first screw thread, rollers may be installed to reduce frictional force along the upper and lower sides.

In one embodiment, the horizontal braking unit, the horizontal rack gear installed in the horizontal direction from the lower portion of the seating groove is engaged with the third gear mountain and is installed to move in the left and right horizontal direction as the third gear mountain rotates; and a horizontal spring installed at one end of the horizontal rack gear to prevent the rack gear from moving in one direction by using an elastic force.

In one embodiment, the support gear, the plunger is formed in the shape of a cylinder and installed on the lower side of the elevating slider; a lower screw thread extending along a lower outer circumferential surface of the plunger; and a third gear mountain in the form of a spur gear is formed along the lower outer circumferential surface to engage the horizontal braking unit, is supported by the gear support spring, and the plunger is inserted and rotated to move up and down in the upper part. and a gear body in which a rotation groove having a shape corresponding to the plunger is formed, and an internal thread for engaging the lower screw thread extends along an inner circumferential surface of the rotation groove.

In one embodiment, the gear body may start rotating after the plunger descends to the bottom surface of the rotation groove.

In one embodiment, the second screw thread may be formed by installing a plurality of gear blocks spaced apart from each other at regular intervals along an inner circumferential surface of the seating groove to form rows in a helical direction.

In one embodiment, the gear block, the upper side of the screw thread lower forming the lower part of the thread formed in the form of a flat right-angled inverted triangle; an upper screw thread connected to the upper rear end of the lower screw thread so that the rear end is rotatable to form an upper part of the screw thread; an expansion pouch seated in an installation groove formed at an upper portion of the lower portion of the screw thread and expanded by the fluid supplied from the vertical brake unit to elevate the upper portion of the screw thread in an upward direction; and a rear end support installed on the inner circumferential surface of the seating groove and supporting the rear end of the upper portion of the screw thread by using an elastic force.

In one embodiment, the vertical braking unit is installed upright so that the upper portion is exposed to the upper side of the support body, the vertical bar is pressed downward as the pedestal descends; a fluid tank installed under the vertical bar and compressed as the vertical bar descends to supply a fluid accommodated in the internal space; and a supply line for transferring the fluid supplied from the fluid tank to each gear block.

In one embodiment, the multi-seismic pipe mounting module according to an embodiment of the present invention is an upper surface of the first mounting frame so as to buffer vibration or shock transmitted from the second frame to the fourth frame. It may further include; a lower seismic resistance portion installed on the.

In one embodiment, the lower earthquake-resistant unit, an upper support for supporting one side of the fourth frame; a lower support seated on an upper surface of the first mounting frame; A first inclined frame with an upper part connected to be rotatably connected to one side of the lower side of the upper support and installed to be inclined in the other direction, and an upper part connected to be rotatably connected to a lower side of the first inclined frame, and a lower part of the support A first intermediate support comprising a first upright frame that is installed and connected to be upright rotatably on one side of the upper part; A second inclined frame, the upper part is connected to be rotatably connected to the other side of the lower part of the upper support and installed to be inclined in one direction, and the upper part is connected to the lower part of the second inclined frame so that the upper part is rotatably connected to the lower part of the support. a second intermediate support comprising a second upright frame that is installed and connected to be upright rotatably on the other side of the upper part; The lower part is formed in a rotatable "V" shape, and at least one connection is installed between the first intermediate support and the second intermediate support, and the upper support is lowered between the first intermediate support and the second intermediate support. "V"-shaped support for supporting using elastic force when the distance between the two is narrowed; a first horizontal support that passes through a lower portion of the first inclined frame and a lower portion of the second inclined frame in a horizontal direction and is installed in a horizontal direction to support an upper side of the “V”-shaped support; a second horizontal support that passes through each of the first upright frame and the second upright frame in a horizontal direction and is installed in a horizontal direction to support a lower side of the "V"-shaped support; and between one side of the first horizontal support and one side of the second horizontal support, and between the other side of the first horizontal support and the other side of the second horizontal support, respectively, the first horizontal support and the second It may include a; gap support elastic body that pulls between the horizontal supports using an elastic force.

In one embodiment, the "V"-shaped support is installed so that the upper portion is rotatably connected to the portion where the first inclined frame and the first upright frame are connected and installed, and the lower portion is installed to be inclined in the other direction. 1 support bar; The lower part is connected to be rotatably connected to the first support bar, and the upper part is installed so as to be inclined in the other direction to the upper part of the first support bar of another "V"-shaped support or the second inclined frame and the second upright frame. a second support bar that is connected and installed so as to be rotatably connected to the part where it is connected; The first support bar and the second support bar are connected and installed so as to be rotatably connected to a rotational part where they are connected and installed. lower connecting gear moving along; and an intermediate elastic body installed between the first support bar and the second support bar to support between the first support bar and the second support bar by using an elastic force.

In one embodiment, when the "V"-shaped support is connected to another "V"-shaped support and installed, the upper part of the second support bar and the upper part of the first support bar of the other "V"-shaped supporter rotate an upper connection gear that is connected and installed so as to be rotatably connected to a rotational part that is connected and installed to be able to be connected, and is connected to and installed with an upper rack gear installed along a lower surface of the first horizontal support to move along the upper rack gear; and an addition installed between the second support bar and the first support bar of the other "V"-shaped support to support between the second support bar and the first support bar of the other "V"-shaped support by using an elastic force It may further include an intermediate elastic body.

The piping construction method according to an embodiment of the present invention uses a multi-seismic type pipe mounting module according to an embodiment of the present invention.

According to one aspect of the present invention described above, it is possible to easily construct a pipe in the field using an individual pipe module that has been pre-worked and modularized, and it is possible to shorten the construction period by minimizing field work, and to simplify the use of the pipe module. By allowing installation work to be performed, it is possible to prevent safety accidents at the site and provide the effect of minimizing the input of construction manpower.

The effects of the present invention are not limited to the above-mentioned effects, and various effects may be included within the range apparent to those skilled in the art from the following description.

1 and 2 are diagrams schematically showing the configuration of a multi-seismic pipe mounting module according to an embodiment of the present invention.
3 to 5 are views showing the connection relationship of the multiple earthquake-resistant pipe mounting module according to an embodiment of the present invention of FIG. 1 .
FIG. 6 is a view showing the upper seismic resistance part of FIG. 2 .
FIG. 7 is a view showing the support gear of FIG. 6 .
FIG. 8 is a view showing an embodiment of the second screw thread of FIG. 6 .
FIG. 9 is a view showing the gear block of FIG. 8 .
FIG. 10 is a view showing the lower seismic resistance part of FIG. 2 .
11 and 12 are views showing an embodiment of the “V”-shaped support of FIG. 10 .

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS [0012] DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS [0010] DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS [0010] Reference is made to the accompanying drawings, which show by way of illustration specific embodiments in which the present invention may be practiced. These embodiments are described in sufficient detail to enable those skilled in the art to practice the present invention. It should be understood that the various embodiments of the present invention are different but need not be mutually exclusive. For example, certain shapes, structures, and characteristics described herein with respect to one embodiment may be implemented in other embodiments without departing from the spirit and scope of the invention. In addition, it should be understood that the location or arrangement of individual components within each disclosed embodiment may be changed without departing from the spirit and scope of the present invention. Accordingly, the detailed description set forth below is not intended to be taken in a limiting sense, and the scope of the present invention, if properly described, is limited only by the appended claims, along with all scope equivalents as those claimed. Like reference numerals in the drawings refer to the same or similar functions throughout the various aspects.

Hereinafter, preferred embodiments of the present invention will be described in more detail with reference to the drawings.

1 and 2 are diagrams schematically showing the configuration of a multi-seismic pipe mounting module according to an embodiment of the present invention.

Referring to FIG. 1 , the multi-seismic type pipe mounting module 10 according to an embodiment of the present invention includes a first frame 100 , a second frame 200 , a third frame 300 , and a fourth frame ( 600 ) and at least one fixing part 700 .

" 형태로 형성되어 수평 프레임(110)의 일측 및 다른 일측에 형성되는 제1 체결 프레임(120) 및 제2 체결 프레임(130)으로 이루어진다.The first frame 100 is formed extending in the horizontal direction to the lower side so that the horizontal frame 110 fixedly installed on the ceiling of the building, the first mounting frame 220 and the second mounting frame 320 can be mounted. bent "

It consists of a first fastening frame 120 and a second fastening frame 130 formed in a "shape and formed on one side and the other side of the horizontal frame 110 .

The second frame 200 is bent in a "L" shape so that it can be fastened to the first vertical frame 210 extending in the vertical direction and the first fastening frame 120 to form the first vertical frame 210 . The first mounting frame 220 formed on the upper side, and the first mounting frame 230 protruding from the lower side of the first vertical frame 210 so that one side 620 of the fourth frame 600 can be mounted. is done

The third frame 300 is bent in a “L” shape so as to be fastened to the second vertical frame 310 extending in the vertical direction and the second fastening frame 130 , so that the second vertical frame 310 is formed. The second mounting frame 320 formed on the upper side, and the other side 630 of the fourth frame 600 are formed to protrude from the lower side of the second vertical frame 310 to the second frame 200 direction. and a second seating frame 330 that is

The fourth frame 600, one side 620 is seated on the first mounting frame 230, the other side 630 is seated on the second mounting frame 330, extending along the upper side in the longitudinal direction. At least one fixing part 700 is installed along the sliding groove 640 .

The fixing unit 700 is installed in the sliding groove 640 extending in the longitudinal direction along the upper portion of the fourth frame 600 and moves along the sliding groove 710 to fix the pipe P.

The multiple earthquake-resistant pipe mounting module 10 according to an embodiment of the present invention having the configuration as described above may further include an upper earthquake-resistant part 400 .

The upper seismic portion 400 is a first fastening frame 120 on which the first mounting frame 220 is mounted so as to buffer vibration or shock transmitted from the first frame 100 to the second frame 200 . installed on the surface of

Here, the upper earthquake-resistant part 400 may be installed 400 - 1 on the mounting surface of the first fastening frame 120 as shown in FIGS. 3 and 4 , as well as of the second fastening frame 130 . As also installed on the mounting surface (400-2), both are made of the same component, and in order to avoid duplication of description, the case where the installation (400-2) is installed on the mounting surface of the second fastening frame 130 will be omitted. do.

The multiple earthquake-resistant pipe mounting module 10 according to an embodiment of the present invention having the configuration as described above may further include a lower earthquake-resistant part 500 .

The lower seismic-resistant part 500 is installed on the upper surface of the first seating frame 230 to buffer vibration or shock transmitted from the second frame 200 to the fourth frame 600 .

Here, the lower earthquake-resistant part 500 may be installed (500-1) on the first seating frame 230 as shown in FIG. 3 , and also installed on the second seating frame 330 (500-) 2), in order to avoid duplication of description as both are made of the same component, the case where the second mounting frame 330 is also installed (500-2) will be omitted.

The multi-seismic type pipe mounting module 10 according to an embodiment of the present invention having the configuration as described above can easily construct the pipe P in the field using a pre-worked and modularized individual pipe module, The construction period can be shortened by minimizing on-site work, and by performing simplified installation work using the pipe (P) module, safety accidents at the site can be prevented and construction manpower input can be minimized.

FIG. 6 is a view showing the upper seismic resistance part of FIG. 2 .

Referring to FIG. 6 , the upper seismic part 400 includes a pedestal 410 , an elevating slider 420 , a support body 430 , a support gear 440 , a gear support spring 450 , and a horizontal brake part 460 . ) and a vertical brake unit 470 .

The pedestal 410 supports the first mounting frame 220 , and is connected to the lower side so that the elevating slider 420 is rotatably installed.

In one embodiment, the pedestal 410 is a support plate 411 formed of a circular plate or a square plate, an extension bar 412 extending from the lower side of the support plate 411 and an elevating slider 420 on the upper side. It may include a rotation bar 413 installed below the extension bar 412 so as to be rotatable in the formed rotation groove 421 .

The elevating slider 420 is formed in a cylindrical shape and is rotatably connected to the lower side of the pedestal 410 , and forms a first screw thread S1 in a spiral direction along the outer circumferential surface to form a seating groove of the support body 430 . It is seated on the 431 and descends from the seating groove 431 while rotating as the pedestal 410 descends by the pressure transmitted to the pipe P through the first mounting frame 220 .

In one embodiment, the first screw thread (S1), the roller (R) may be installed to reduce the frictional force along the upper and lower sides.

The support body 430 is installed on the mounting surface (ie, the inner surface) of the first fastening frame 120 , and has a shape of the elevating slider 420 so that the elevating slider 420 is seated and slid in the up-down direction. A seating groove 431 having a shape corresponding to A second screw thread (S2) to be installed is formed in a spiral direction.

The support gear 440 forms a third gear mountain S3 in the form of a spur gear along the outer circumferential surface, is connected to the lower side of the elevating slider 420 , and the elevating slider 420 is provided with a seating groove 431 . When it descends more than a preset depth (that is, the distance corresponding to the depth until the plunger 441 descends to the bottom surface of the rotation groove 4431), it descends while rotating with the elevating slider 420, and the gear is supported It is supported by a spring 450 .

The gear support spring 450 is connected to the lower side of the support gear 440 to support the support gear 440 by using an elastic force from the lower side of the seating groove 431 .

In one embodiment, the gear support spring 450 is installed at least one lower side of the rotation seat 452 and the rotation seat 452 on which the support gear 440 is rotatably seated to rotate using an elastic force. It may include a support spring 451 for supporting the seat 452 .

The horizontal braking unit 460 is installed in the horizontal direction from the lower portion of the seating groove 431 to engage and connect to the third gear mountain S3 of the support gear 440 , and to block the descent of the elevating slider 420 . The rotation of the support gear 440 is prevented by using an elastic force.

In an embodiment, the horizontal brake unit 460 may include a horizontal rack gear 461 and a horizontal spring 462 .

The horizontal rack gear 461 is installed in the horizontal direction from the lower part of the seating groove 431 and is connected to the third gear mountain S3 to move in the left and right horizontal directions as the third gear mountain S3 rotates. .

The horizontal spring 462 is installed at one end of the horizontal rack gear 461 to prevent the rack gear from moving in one direction by using an elastic force.

The vertical braking unit 470 is installed on the support body 430 and is in close contact with the first screw thread S1 as the second screw thread S2 is spread in the vertical direction to brake the rotation of the first screw thread S1. As the pedestal 410 descends so that the fluid is compressed in the vertical direction and accommodated in the internal space, the fluid is supplied to each of the second threads S2.

In one embodiment, the vertical brake 470 includes a vertical bar 471 , a fluid tank 472 and a supply line 473 .

The vertical bar 471 is installed upright so that the upper portion is exposed to the upper side of the support body 430 , and as the pedestal 410 descends, it is pressed downward to compress the fluid tank 472 .

The fluid tank 472 is installed on the lower side of the vertical bar 471, and as the vertical bar 471 descends, the fluid is compressed and accommodated in the internal space through the supply line 473 with a second thread (S2). It is transmitted to each gear block 480 constituting the.

The supply line 473 consists of individual supply pipes from the fluid tank 472 to each gear block 480 , and delivers the fluid supplied from the fluid tank 472 to each gear block 480 .

The upper seismic resistance parts 400-1 and 400-2 having the configuration as described above by buffering vibrations or shocks transmitted to the pipe P via the second frame 200 or the third frame 300 Even when the building is shaken due to earthquakes, etc., it is possible to minimize the vibration or shock transmitted to the pipe (P) to minimize the damage to the pipe (P).

FIG. 7 is a view showing the support gear of FIG. 6 .

Referring to FIG. 7 , the support gear 440 includes a plunger 441 , a lower thread 442 , and a gear body 443 .

The plunger 441 is formed in a cylindrical shape and is installed below the elevating slider 420 , and moves in the vertical direction while rotating in the rotating groove 4431 .

The lower thread 442 is formed extending along the lower outer circumferential surface of the plunger 441 so that the plunger 441 can move in the vertical direction while rotating along the rotation groove 4431, and is engaged with the internal thread 4432 and is installed .

The gear body 443 forms a third gear mountain S3 in the form of a spur gear along the lower outer circumferential surface so as to be engaged with the horizontal braking unit 460, is supported by a gear support spring 450, and a plunger ( A rotation groove 4431 having a shape corresponding to the plunger 441 is formed in the upper portion so that the 441 is inserted and moved in the vertical direction while rotating, and an internal thread 4432 for engaging the lower screw thread 442 is a rotation groove is formed extending along the inner circumferential surface of

In one embodiment, the gear body 443 may start rotating after the plunger 441 descends to the bottom surface of the rotation groove 4431 .

That is, when the plunger 441 is initially seated, only a part is inserted and seated on the upper side of the rotation groove 4431, so that even when the plunger 441 rotates, the gear body 443 cannot rotate, and the plunger 441 rotates. While being seated on the bottom surface of the rotation groove 4431, the gear body 443 is rotated by the rotational force.

FIG. 8 is a view showing an embodiment of the second screw thread of FIG. 6 .

Referring to FIG. 8 , in the second screw thread S2 according to an embodiment, a plurality of gear blocks 480a and 480b are spaced apart from each other at regular intervals along the inner circumferential surface of the seating groove 431 to form rows in a spiral direction. installed and formed.

In the case of FIG. 8 , only two gear blocks 480a and 480b are illustrated, but the second screw thread S2 according to an embodiment is installed in a plurality of rows along the inner circumferential surface of the seating groove 431 , so that the first The screw thread S1 may be engaged to form a screw thread for connection and installation.

FIG. 9 is a view showing the gear block of FIG. 8 .

Referring to FIG. 9 , the gear block 480 includes a lower threaded portion 481 , a threaded upper portion 482 , an inflation pouch 483 , and a rear end support 484 .

The threaded lower part 481 forms the lower part of the thread by the gear block 480 formed in the form of a right-angled inverted triangle with a flat upper side.

The threaded upper part 482 is connected to the upper rear end of the threaded lower part 481 so that the rear end is rotatable to form the upper part of the thread by the gear block 480, and the expansion pouch 483 installed on the lower side expands. Accordingly, it is lifted in close contact with the first screw thread S1 to brake the rotation of the elevating slider 420 .

The expansion pouch 483 is seated in the installation groove 4811 formed on the upper portion of the screw thread lower portion 481 , and is expanded by the fluid supplied from the vertical braking unit 470 to elevate the screw thread upper portion 482 upward. do it

The rear end support 484 is installed on the inner circumferential surface of the seating groove 431 and supports the rear end of the screw thread upper portion 482 by using an elastic force.

FIG. 10 is a view showing the lower seismic resistance part of FIG. 2 .

Referring to FIG. 10 , the lower earthquake-resistant part 500 includes an upper support 510 , a lower support 520 , a first intermediate support 530 , a second intermediate support 540 , and a “V”-shaped support 550 . , a first horizontal support 560 , a second horizontal support 570 , and a gap support elastic body 580 .

The upper support 510 supports one side 620 of the fourth frame 600 , and is supported by the first intermediate support 530 and the second intermediate support 540 installed on the lower side of the vibration transmitted from the object. It transmits the shock or the like to the first intermediate support 530 and the second intermediate support 540 .

The lower support 520 is seated on the upper surface of the first seating frame 230 , and the lower sides of the first intermediate support 530 and the second intermediate support 540 are connected to be rotatably installed.

The first intermediate support 530 includes a first inclined frame 531 having an upper portion connected to be rotatably connected to one lower side of the upper support 510 and installed to be inclined in the other one direction, and an upper portion of the first inclined frame ( 531) is rotatably connected to the lower side, and the lower part is made up of a first upright frame 532 that is connected and installed so as to be rotatably connected to the upper side of the support.

The second intermediate support 540 includes a second inclined frame 541 having an upper portion connected to be rotatably connected to the lower other side of the upper support 510 and installed to be inclined in one direction, and a second inclined frame having an upper portion ( 541) is rotatably connected to the lower side, and the lower part consists of a second upright frame 542 that is installed and connected so as to be rotatably connected to the upper other side of the support.

The "V" type support 550 is formed in a "V" shape with a rotatable lower portion, and at least one or more is connected and installed between the first intermediate support 530 and the second intermediate support 540 , and the upper support 510 ) is lowered and the gap between the first intermediate support 530 and the second intermediate support 540 is narrowed, and the support is performed using an elastic force.

That is, when the upper support 510 descends by vibration or impact transmitted from the fourth frame 600, the gap between the first intermediate support 530 and the second intermediate support 540 is reduced, and the The "V"-shaped support 550 that is supported absorbs the vibration or shock transmitted from the fourth frame 600 to reduce the vibration or shock.

The first horizontal support 560 passes through the lower portion of the first inclined frame 531 and the lower portion of the second inclined frame 541 in the horizontal direction, respectively, and is installed in the horizontal direction to the upper side of the “V”-shaped supporter 550 . support the

The second horizontal support 570 passes through the first upright frame 532 and the second upright frame 542 in the horizontal direction, respectively, and is installed in the horizontal direction to support the lower side of the "V"-shaped supporter 550 .

The gap support elastic body 580 is between one side of the first horizontal support 560 and one side of the second horizontal support 570 , and the other side of the first horizontal support 560 and the other of the second horizontal support 570 . It is installed between one side, respectively, and pulls between the first horizontal support 560 and the second horizontal support 570 by using an elastic force.

The lower seismic-resistant parts 500-1 and 500-2 having the above-described configuration are primarily buffered by the upper seismic-resistant parts 400-1 and 400-2 to secondary buffer the reduced vibrations or shocks. Even when the building is shaken due to the occurrence of such a phenomenon, it is possible to minimize the damage to the pipe P by further reducing vibration or shock transmitted to the pipe P.

11 and 12 are views showing an embodiment of the “V”-shaped support of FIG. 10 .

11 and 12 , the "V"-shaped support 550 according to an embodiment includes a first support bar 551 , a second support bar 552 , a lower connecting gear 553 and an intermediate elastic body ( 554).

The first support bar 551 is connected so that the upper part is rotatably connected to the part V1 where the first inclined frame 531 and the first upright frame 532 are connected and installed, and the lower part is inclined in the other direction. It is installed so as to be rotatably connected to the lower portion of the second support bar 552 .

The second support bar 552 is installed so that the lower part is rotatably connected to the lower part of the first support bar 551, and the upper part is installed to be inclined in the other direction, so that the first of the other "V"-shaped supporters 550a. The upper portion of the support bar 551a or the second inclined frame 541 and the second upright frame 542 are connected and installed so as to be rotatably connected to each other.

The lower connection gear 553 is rotatably connected to the rotation portion V2 where the first support bar 551 and the second support bar 552 are connected and installed, and the upper surface of the second horizontal supporter 570 . It is installed in engagement with the lower rack gear 521 installed along the , and moves along the lower rack gear 521 .

The intermediate elastic body 554 is installed between the first support bar 551 and the second support bar 552 to support between the first support bar 551 and the second support bar 552 using an elastic force.

The "V"-shaped support 550 according to an embodiment having the configuration as described above may further include an upper connecting gear 555 and an additional intermediate elastic body 556 .

The upper connection gear 555 is connected to the upper portion of the second support bar 552 and the upper portion of the first support bar 551a of the other "V"-shaped supporter 550a in a rotational portion V3 that is installed to be rotatable. It is connected and installed to be rotatable, and is connected to and installed with the upper rack gear 561 installed along the lower side of the first horizontal support 560 to move along the upper rack gear 561 .

The additional intermediate elastic body 556 is installed between the second support bar 552 and the first support bar 551a of the other "V"-shaped supporter 550a and is different from the second support bar 552 by using an elastic force. It supports between the first support bars of the "V"-shaped supporter 550 .

In addition, the pipe construction method according to an embodiment of the present invention is performed using the multiple earthquake-resistant pipe mounting module 10 as described above.

The above-described embodiments are for illustration, and those of ordinary skill in the art to which the above-described embodiments pertain can easily transform into other specific forms without changing the technical idea or essential features of the above-described embodiments. you will understand Therefore, it should be understood that the above-described embodiments are illustrative in all respects and not restrictive. For example, each component described as a single type may be implemented in a dispersed form, and likewise components described as distributed may be implemented in a combined form.

The scope to be protected through this specification is indicated by the claims below rather than the detailed description, and should be construed to include all changes or modifications derived from the meaning and scope of the claims and their equivalents. .

10: Multiple seismic type pipe mounting module
100: first frame
200: second frame
300: third frame
400: upper seismic part
500: lower seismic part
600: fourth frame
700: fixed part

Claims (10)

A horizontal frame that extends in the horizontal direction and is fixedly installed on the ceiling of a building;

A first frame formed in the shape of a first fastening frame and a second fastening frame formed on one side and the other side of the horizontal frame;
A first vertical frame extending in a vertical vertical direction, a first mounting frame bent in a “L” shape to be fastened to the first fastening frame and formed on the upper side of the first vertical frame, and the first vertical frame a second frame comprising a first seating frame protruding from the lower side of the;
A second vertical frame extending in a vertical vertical direction, a second mounting frame bent in a “L” shape to be fastened to the second fastening frame and formed above the second vertical frame, and the second vertical frame a third frame comprising a second seating frame protruding from the lower side of the second frame in the direction of the second frame;
a fourth frame having one side mounted on the first mounting frame and the other side mounted on the second mounting frame; and
At least one fixing part installed in a sliding groove extending in the longitudinal direction along the upper portion of the fourth frame, moving along the sliding groove, and fixing a pipe; including, a multi-seismic type pipe mounting module.
According to claim 1,
An upper seismic resistant part installed on the mounting surface of the first fastening frame on which the first mounting frame is mounted so as to buffer vibration or shock transmitted from the first frame to the second frame; Jinhyeong pipe mounting module.
The method of claim 2, wherein the upper seismic resistant portion,
a pedestal for supporting the first mounting frame;
an elevating slider that is formed in a cylindrical shape and is rotatably connected to the lower side of the pedestal, and forms a first screw thread in a spiral direction along an outer circumferential surface;
It is installed on the mounting surface of the first fastening frame, and forms a seating groove having a shape corresponding to the shape of the elevating slider so that the elevating slider is seated and sliding in the up-down direction, and the elevating slider rotates up and down a support body in which a second screw thread is formed in a helical direction for connection and installation of the first screw thread along an inner circumferential surface of the seating groove so as to be moved in the direction;
A third gear mountain in the form of a spur gear is formed along the outer circumferential surface and connected to the lower side of the elevating slider, and when the elevating slider descends more than a preset depth in the seating groove, it rotates together with the elevating slider. descending support gear;
a gear support spring connected to the lower side of the support gear and configured to support the support gear by using an elastic force from the lower side of the seating groove;
Horizontally installed in the lower part of the seating groove and connected to the third gear mountain of the support gear, the rotation of the support gear is prevented by using an elastic force so as to block the descent of the elevating slider. brake; and
It is installed on the support body and is compressed in the vertical direction as the pedestal descends so as to be in close contact with the first screw thread as the second screw thread is spread in the vertical direction to brake the rotation of the first screw thread, and is compressed in the internal space. A multi-seismic pipe mounting module including; a vertical braking unit for supplying the accommodated fluid to each of the second threads.
According to claim 3, wherein the support gear,
a plunger formed in a cylindrical shape and installed below the elevating slider;
a lower screw thread extending along a lower outer circumferential surface of the plunger; and
A third gear mountain in the form of a spur gear is formed along the lower outer circumferential surface to be engaged with the horizontal braking unit, is supported by the gear support spring, and the plunger is inserted and rotated to move up and down in the upper part. A multi-seismic type pipe mounting module including; a gear body in which a rotation groove having a shape corresponding to the plunger is formed, and an internal thread for engaging the lower thread is extended along the inner circumferential surface of the rotation groove.
4. The method of claim 3,
The second screw thread,
A plurality of gear blocks are spaced apart from each other at regular intervals along the inner circumferential surface of the seating groove and are installed and installed in a spiral direction,
The gear block is
a lower screw thread forming a lower portion of the screw thread formed in the form of a right-angled inverted triangle having a flat upper side;
an upper screw thread connected to the upper rear end of the lower screw thread so that the rear end is rotatable to form an upper part of the screw thread;
an expansion pouch seated in an installation groove formed at an upper portion of the lower portion of the screw thread and expanded by the fluid supplied from the vertical brake unit to elevate the upper portion of the screw thread in an upward direction; and
A multi-seismic type pipe mounting module including; a rear end support installed on the inner circumferential surface of the seating groove and supporting the rear end of the upper screw thread by using an elastic force.
According to claim 1,
The multiple earthquake-resistant pipe mounting module further comprising; a lower seismic-resistant part installed on the upper surface of the first seating frame so as to buffer vibration or shock transmitted from the second frame to the fourth frame.
The method of claim 6, wherein the lower seismic resistance portion,
an upper support for supporting one side of the fourth frame;
a lower support seated on an upper surface of the first mounting frame;
A first inclined frame having an upper part connected to be rotatably connected to one side of the lower side of the upper support and installed to be inclined in the other direction, an upper part connected to a rotatable lower side of the first inclined frame, and a lower part of the support A first intermediate support consisting of a first upright frame that is installed and connected to be upright rotatable on one side of the upper part;
A second inclined frame, the upper part is connected to be rotatably connected to the other side of the lower part of the upper support and installed to be inclined in one direction, and the upper part is connected and installed so as to be rotatable to the lower side of the second inclined frame, and the lower part is the lower part of the support. a second intermediate support comprising a second upright frame that is installed and connected to be upright rotatably on the other side of the upper part;
The lower part is formed in a rotatable "V" shape, and at least one connection is installed between the first intermediate support and the second intermediate support, and the upper support is lowered between the first intermediate support and the second intermediate support. "V"-shaped support for supporting using elastic force when the distance between the two is narrowed;
a first horizontal support that passes through a lower portion of the first inclined frame and a lower portion of the second inclined frame in a horizontal direction and is installed in a horizontal direction to support an upper side of the “V”-shaped support;
a second horizontal support that passes through each of the first upright frame and the second upright frame in a horizontal direction and is installed in a horizontal direction to support a lower side of the "V"-shaped support; and
Installed between one side of the first horizontal support and one side of the second horizontal support, and between the other side of the first horizontal support and the other side of the second horizontal support, respectively, the first horizontal support and the second horizontal support Including, a multi-seismic type pipe mounting module;
According to claim 7, wherein the "V"-shaped support,
a first support bar having an upper portion rotatably connected to a portion where the first inclined frame and the first upright frame are connected and installed, and having a lower portion inclined in the other direction;
The lower part is connected to be rotatably connected to the first support bar, and the upper part is installed so as to be inclined in the other direction to the upper part of the first support bar of another "V"-shaped support or the second inclined frame and the second upright frame. a second support bar that is connected and installed so as to be rotatably connected to the part where it is connected;
The first support bar and the second support bar are connected and installed so as to be rotatably connected to a rotational part where they are connected and installed. lower connecting gear moving along; and
An intermediate elastic body installed between the first support bar and the second support bar to support between the first support bar and the second support bar by using an elastic force; including, a multi-seismic type pipe mounting module.
The method of claim 8, wherein the "V"-shaped support,
If installed in connection with other "V"-shaped supports,
The upper portion of the second support bar and the upper portion of the first support bar of the other "V"-shaped support are rotatably connected and installed in a pivoting part to be rotatably connected, and installed along the lower surface of the first horizontal support. an upper connecting gear that is installed in engagement with the upper rack gear and moves along the upper rack gear; and
An additional intermediate provided between the second support bar and the first support bar of the other "V"-shaped support to support between the second support bar and the first support bar of the other "V"-shaped support by using an elastic force An elastic body; further comprising, a multi-seismic pipe mounting module.
A piping construction method using the multiple earthquake-resistant piping mounting module according to any one of claims 1 to 9.

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