CN214662889U - A earthquake-resistant structure for new forms of energy building pipeline installation - Google Patents

Abstract

The application relates to an anti-seismic structure for installing a new energy building pipeline, which comprises an upper clamping ring and a lower clamping ring positioned below the upper clamping ring, wherein a connecting assembly is arranged between the upper clamping ring and the lower clamping ring; an upper air bag is fixedly connected to the inner peripheral surface of the upper clamping ring, a lower air bag is fixedly connected to the inner peripheral surface of the lower clamping ring, two ends of the upper air bag are respectively abutted to two ends of the lower air bag, a pipeline is arranged between the upper air bag and the lower air bag, a supporting mechanism for supporting the pipeline is mounted on the inner peripheral surface of the lower clamping ring, and supporting legs are fixedly connected to the outer peripheral surface of the lower clamping ring. The application has the effect of prolonging the service life of the pipeline.

Description

A earthquake-resistant structure for new forms of energy building pipeline installation

Technical Field

The application relates to the technical field of building earthquake-resistant structures, in particular to an earthquake-resistant structure for installing new energy building pipelines.

Background

The line means a pipe for connecting a pump, a valve, a control system, or the like, for transferring liquid, gas, or solid ground into powder, a general term for various pipes and electric wires, cables, or the like. In order to resist the influence of the outside on the pipeline vibration, an anti-seismic structure is often installed on the pipeline.

The utility model discloses a chinese utility model patent that present grant bulletin number is CN208997477U discloses a civil engineering antidetonation structure, including first mounting panel and second mounting panel, first mounting panel and second mounting panel symmetry installation, and the bolted connection through the symmetry installation, the inner wall center department swing joint of first mounting panel and second mounting panel has positioning mechanism, and the equal welded fastening in non-adjacent one side of first mounting panel and second mounting panel has the shock attenuation post, and one side welded fastening of shock attenuation post has fixed establishment.

With respect to the related art in the above, the inventors consider that: among the above-mentioned technical scheme, horizontal shock attenuation can be realized to the antidetonation structure, and when the pipeline gave birth to longitudinal vibration, the pipeline was easy because vibrations take place to break to the life of pipeline has been reduced.

SUMMERY OF THE UTILITY MODEL

In order to prolong the service life of pipeline, this application provides an earthquake-resistant structure that is used for new forms of energy building pipeline installation.

The application provides a seismic structure for new forms of energy building pipeline installation adopts following technical scheme:

an anti-seismic structure for installing a new energy building pipeline comprises an upper clamping ring and a lower clamping ring positioned below the upper clamping ring, wherein a connecting assembly is arranged between the upper clamping ring and the lower clamping ring; the air bag structure comprises an upper clamping ring and a lower clamping ring, wherein an upper air bag is fixedly connected to the inner peripheral surface of the upper clamping ring, a lower air bag is fixedly connected to the inner peripheral surface of the lower clamping ring, two ends of the upper air bag are respectively abutted to two ends of the lower air bag, a pipeline is arranged between the upper air bag and the lower air bag, a supporting mechanism used for supporting the pipeline is installed on the inner peripheral surface of the lower clamping ring, and supporting legs are fixedly connected to the outer peripheral surface of the lower clamping ring.

Through adopting above-mentioned technical scheme, when the pipeline takes place vibrations, because the pipeline is cliied by last gasbag and lower gasbag, the pipeline can be to the arbitrary orientation vibrations of two gasbags, and the gasbag can play the cushioning effect to the pipeline for the difficult emergence of pipeline is broken, thereby can prolong the life of pipeline.

Optionally, the connecting assembly includes a first connecting plate and a second connecting plate, and the first connecting plate is two and fixedly connected to the outer peripheral surface of the upper clamping ring and located at two ends of the upper clamping ring; the two connecting plates are fixedly connected to the outer peripheral surface of the lower clamping ring and located at two ends of the lower clamping ring, and the two connecting plates are connected with the two connecting plates through bolts.

Through adopting above-mentioned technical scheme, when fixing the pipeline, with connecting plate one butt on connecting plate two, carry out bolted connection with connecting plate one and connecting plate two again, the pipeline is by last gasbag and lower gasbag extrusion, alright fix the pipeline.

Optionally, a placing groove is formed in the inner peripheral surface of the lower clamping ring, the placing groove is communicated with the inner peripheral surface of the lower air bag, the supporting mechanism includes a first supporting plate and a first elastic spring, the first supporting plate is located in the placing groove, and a side surface of the first supporting plate, which is far away from one side of the bottom of the placing groove, extends out of the inner peripheral surface of the lower air bag and abuts against the outer wall of the pipeline; elastic spring one end rigid coupling in the tank bottom of standing groove, the one end rigid coupling that elastic spring kept away from the standing groove tank bottom is close to in the backup pad one the side of standing groove tank bottom one side, install in the standing groove and be used for hindering a backup pad roll-off the locating part one of standing groove.

Through adopting above-mentioned technical scheme, when placing the pipeline between last clamp ring and lower clamp ring, place the pipeline in backup pad one, elastic spring one supports backup pad one to can alleviate the pipeline and to the long-time extrusion of gasbag down, be favorable to gasbag under the protection.

Optionally, the first limiting part comprises two limiting plates, the two limiting plates are symmetrically and fixedly connected to the side wall of the first supporting plate, and a first limiting groove matched with the two limiting plates is formed in the side wall of the placing groove.

Through adopting above-mentioned technical scheme, when the pipeline vibrations on backup pad one, the limiting plate slides in limiting groove one, utilizes the limiting plate can hinder outside the backup pad roll-off standing groove.

Optionally, two ends of the supporting plate are semicircular.

Through adopting above-mentioned technical scheme, because a backup pad both ends are semicircle form for backup pad one more even with lower gasbag contact, thereby can reduce a edges and corners of backup pad and to the wearing and tearing of gasbag down, and then can further protect gasbag down.

Optionally, a spring groove is formed in the inner peripheral surface of the upper clamping ring, a second elastic spring is fixedly connected to the groove bottom of the spring groove, a second support plate is fixedly connected to one end, far away from the groove bottom of the spring groove, of the second elastic spring, the second support plate penetrates through the upper air bag and abuts against the outer wall of the pipeline, and a second limiting part used for blocking the second support plate from sliding out of the spring groove is installed in the spring groove.

Through adopting above-mentioned technical scheme, when the pipeline shakes between last gasbag and lower gasbag, pipeline extrusion backup pad two, elastic spring two receives the extrusion, contracts to the spring inslot, and gasbag on the pipeline extrusion afterwards utilizes backup pad two can alleviate the pipeline and excessively extrude last gasbag to can reduce the pipeline to the damage that the gasbag extrusion led to the fact on.

Optionally, the second limiting part comprises a limiting block, the limiting block is fixedly connected to the circumferential surface of the second supporting plate, and a second limiting groove matched with the limiting block is formed in the side wall of the spring groove.

Through adopting above-mentioned technical scheme, when backup pad two slided in the spring groove, the stopper slided in spacing groove two, utilizes the stopper can hinder backup pad two roll-off spring groove outsidely.

Optionally, the end face of one end of the support leg, which is far away from the lower clamping ring, is fixedly connected with a pin.

Through adopting above-mentioned technical scheme, because the terminal surface rigid coupling that the supporting leg kept away from lower clamp ring one end has to participate in, participate in and inject the bottom surface to can improve antidetonation structural stability.

In summary, the present application includes at least one of the following beneficial technical effects:

when the pipeline vibrates, the pipeline can vibrate towards any direction of the two air bags because the pipeline is clamped by the upper air bag and the lower air bag, and the air bags can buffer the pipeline, so that the pipeline is not easy to break, and the service life of the pipeline can be prolonged;

when the pipeline is placed between the upper clamping ring and the lower clamping ring, the pipeline is placed on the first supporting plate, and the first elastic spring supports the first supporting plate, so that the long-time extrusion of the pipeline on the lower air bag can be reduced, and the lower air bag can be protected;

when the pipeline shakes between the upper air bag and the lower air bag, the second pipeline extrusion supporting plate is extruded, the second elastic spring is extruded and shrinks towards the inside of the spring groove, then the upper air bag is extruded by the pipeline, the excessive extrusion of the upper air bag by the pipeline can be relieved by the second supporting plate, and therefore the damage to the upper air bag caused by the extrusion of the pipeline can be reduced.

Drawings

Fig. 1 is a schematic structural view of an earthquake-resistant structure according to an embodiment of the present application.

Fig. 2 is an exploded view of the seismic structure of an embodiment of the present application.

Description of reference numerals: 1. an upper clamping ring; 11. an upper air bag; 12. a spring slot; 111. a pipeline; 13. a second limiting groove; 2. a lower clamping ring; 21. a lower air bag; 22. supporting legs; 221. a pin; 23. a placement groove; 24. a first limiting groove; 3. a connecting assembly; 31. a first connecting plate; 32. a second connecting plate; 4. a support mechanism; 41. a first support plate; 42. a first elastic spring; 5. a first limiting part; 51. a limiting plate; 61. a second elastic spring; 62. a second support plate; 7. a second limiting part; 71. and a limiting block.

Detailed Description

The present application is described in further detail below with reference to figures 1-2.

The embodiment of the application discloses an earthquake-resistant structure for new energy building pipeline installation. Referring to fig. 1, the anti-seismic structure comprises an upper clamping ring 1 and a lower clamping ring 2, the upper clamping ring 1 and the lower clamping ring 2 are both in a semi-annular shape, the upper clamping ring 1 is positioned above the lower clamping ring 2, and a connecting assembly 3 is arranged between the upper clamping ring 1 and the lower clamping ring 2; two supporting legs 22 are vertically and fixedly connected to the outer peripheral surface of the lower clamping ring 2, the two supporting legs 22 are uniformly distributed on the outer peripheral surface of the lower clamping ring 2, a pin 221 is fixedly connected to the end face of one end, away from the lower clamping ring 2, of each supporting leg 22, and the stability of an anti-seismic structure can be improved by using the pin 221; the inner peripheral surface of the lower clamping ring 2 is fixedly connected with a lower air bag 21, the lower air bag 21 is in a semi-ring shape, the inner peripheral surface of the upper clamping ring 1 is fixedly connected with an upper air bag 11, the upper air bag 11 is in a semi-ring shape, a pipeline 111 is connected between the upper air bag 11 and the lower air bag 21 in a butting mode, and the inner peripheral surface of the lower clamping ring 2 is provided with a supporting mechanism 4 used for supporting the pipeline 111.

Referring to fig. 1, the connecting assembly 3 includes a first connecting plate 31 and a second connecting plate 32, the first connecting plate 31 is rectangular, two first connecting plates 31 are provided, one end of each first connecting plate 31 is vertically and fixedly connected to the outer circumferential surface of the upper clamping ring 1, and the first connecting plates 31 are respectively located at two ends of the upper clamping ring 1; the second connecting plates 32 are cuboid, the number of the second connecting plates 32 is two, one ends of the two second connecting plates 32 are vertically and fixedly connected to the outer peripheral surface of the lower clamping ring 2, the two second connecting plates 32 are respectively located at two ends of the lower clamping ring 2, and the two first connecting plates 31 are in bolt connection with the two second connecting plates 32.

The first connecting plate 31 abuts against the second connecting plate 32, then the first connecting plate 31 is connected with the second connecting plate 32 through bolts, and the pipeline 111 is extruded by the upper air bag 11 and the lower air bag 21, so that the pipeline 111 can be fixed; when the pipeline 111 vibrates, because the pipeline 111 is clamped by the upper air bag 11 and the lower air bag 21, the pipeline 111 can vibrate towards any direction of the two air bags, and the air bags can play a role in buffering the pipeline 111, so that the pipeline 111 is not easy to break, and the service life of the pipeline can be prolonged.

Referring to fig. 2, a placing groove 23 is formed in the middle of the inner circumferential surface of the lower clamping ring 2, the placing groove 23 is communicated with the inner circumferential surface of the lower air bag 21, the supporting mechanism 4 includes a first supporting plate 41 and a first elastic spring 42, the first supporting plate 41 is a rectangular parallelepiped, and the two ends of the first supporting plate are semicircular, so that abrasion of edges and corners of the first supporting plate 41 to the lower air bag 21 can be reduced, the first supporting plate 41 is slidably connected to the placing groove 23, the side of the first supporting plate 41, which is far away from the bottom side of the placing groove 23, extends out of the inner circumferential surface of the lower air bag 21 and abuts against the outer wall of the pipeline 111, the number of the elastic springs is three, one end of the first three elastic springs 42 is fixedly connected to the bottom of the placing groove 23, the other end of the first elastic springs 42 is fixedly connected to the side of the first supporting plate 41, which is close to the bottom side of the placing groove 23, and a first limiting part 5 for blocking the first supporting plate 41 from sliding out of the placing groove 23 is installed in the placing groove 23.

Referring to fig. 2, the first limiting member 5 includes two limiting plates 51, the limiting plates 51 are rectangular solids, the two limiting plates 51 are symmetrically and fixedly connected to the end surfaces of the two ends of the first supporting plate 41, the limiting plates 51 are close to the bottom of the placing groove 23, and a first limiting groove 24 matched with the two limiting plates 51 is formed in the side wall of the placing groove 23.

When the pipeline 111 is placed between the upper clamping ring 1 and the lower clamping ring 2, the pipeline 111 is placed on the first support plate 41, and the first elastic spring 42 supports the first support plate 41, so that the long-time extrusion of the pipeline 111 on the lower air bag 21 can be relieved, and the lower air bag 21 can be protected; when the pipe 111 shakes on the first support plate 41, the limit plate 51 slides in the first limit groove 24, and the limit plate 51 can prevent the support plate from sliding out of the placing groove 23.

Referring to fig. 2, two spring grooves 12 are formed in the inner circumferential surface of the upper clamping ring 1, the two spring grooves 12 are uniformly distributed along the inner circumferential surface of the upper clamping ring 1, an elastic spring II 61 is fixedly connected to the bottom of the spring groove 12, a supporting plate II 62 is fixedly connected to one end, away from the bottom of the spring groove 12, of the elastic spring II 61, the supporting plate II 62 is cylindrical, the supporting plate II 62 is located in the spring groove 12, and one end, away from the elastic spring II 61, of the supporting plate II 62 extends out of the inner circumferential surface of the upper air bag 11 and abuts against the outer wall of the pipeline 111; the second limiting part 7 used for blocking the second support plate 62 to slide out of the spring groove 12 is installed in the spring groove 12, the second limiting part 7 comprises a limiting block 71, the limiting block 71 is a cuboid, the limiting block 71 is fixedly connected to the circumferential surface of the second support plate 62, and a second limiting groove 13 matched with the limiting block 71 is formed in the side wall of the spring groove 12.

When the pipeline 111 vibrates between the upper air bag 11 and the lower air bag 21, the pipeline 111 presses the second support plate 62, the second elastic spring 61 is pressed and shrinks into the spring groove 12, then the pipeline 111 presses the upper air bag 11, and the second support plate 62 can relieve the excessive pressing of the pipeline 111 on the upper air bag 11, so that the damage caused by the pressing of the pipeline 111 on the upper air bag 11 can be reduced; when the second support plate 62 slides in the spring slot 12, the second limit block 71 slides in the second limit slot 13, and the second support plate 62 can be prevented from sliding out of the spring slot 12 by the second limit block 71.

The implementation principle of the anti-seismic structure for the installation of the new energy building pipelines is as follows: when the pipeline 111 vibrates between the upper air bag 11 and the lower air bag 21, the first support plate 41 supports the pipeline 111, the first elastic spring 42 supports the first support plate 41, the first support plate 41 can relieve long-time extrusion of the pipeline 111 on the lower air bag 21, when the pipeline 111 is extruded upwards, the second support plate 62 is extruded by the pipeline 111, the second elastic spring 61 is extruded and shrinks towards the spring groove 12, then the pipeline 111 extrudes the upper air bag 11, and the second support plate 62 can relieve excessive extrusion of the pipeline 111 on the upper air bag 11, so that the lower air bag 21 can be protected.

The above embodiments are preferred embodiments of the present application, and the protection scope of the present application is not limited by the above embodiments, so: all equivalent changes made according to the structure, shape and principle of the present application shall be covered by the protection scope of the present application.

Claims (8)

1. The utility model provides an earthquake-resistant structure for new forms of energy building pipeline installation which characterized in that: the clamping device comprises an upper clamping ring (1) and a lower clamping ring (2) positioned below the upper clamping ring (1), wherein a connecting assembly (3) is arranged between the upper clamping ring (1) and the lower clamping ring (2); the inner peripheral surface of the upper clamping ring (1) is fixedly connected with an upper air bag (11), the inner peripheral surface of the lower clamping ring (2) is fixedly connected with a lower air bag (21), two ends of the upper air bag (11) are respectively abutted to two ends of the lower air bag (21), a pipeline (111) is arranged between the upper air bag (11) and the lower air bag (21), a supporting mechanism (4) used for supporting the pipeline (111) is installed on the inner peripheral surface of the lower clamping ring (2), and supporting legs (22) are fixedly connected to the outer peripheral surface of the lower clamping ring (2).

2. An earthquake-resistant structure for new energy building pipeline installation according to claim 1, characterized in that: the connecting component (3) comprises a first connecting plate (31) and a second connecting plate (32), wherein the first connecting plate (31) is provided with two connecting plates, fixedly connected to the peripheral surface of the upper clamping ring (1) and positioned at two ends of the upper clamping ring (1); the two connecting plates (32) are fixedly connected to the outer peripheral surface of the lower clamping ring (2) and located at two ends of the lower clamping ring (2), and the two connecting plates (31) are connected with the two connecting plates (32) through bolts.

3. An earthquake-resistant structure for new energy building pipeline installation according to claim 1, characterized in that: a placing groove (23) is formed in the inner peripheral surface of the lower clamping ring (2), the placing groove (23) is communicated with the inner peripheral surface of the lower air bag (21), the supporting mechanism (4) comprises a first supporting plate (41) and a first elastic spring (42), the first supporting plate (41) is located in the placing groove (23), and the side surface, away from the bottom side of the placing groove (23), of the first supporting plate (41) extends out of the inner peripheral surface of the lower air bag (21) and abuts against the outer wall of the pipeline (111); one end of the elastic spring (42) is fixedly connected with the bottom of the placing groove (23), one end of the elastic spring (42) far away from the bottom of the placing groove (23) is fixedly connected with one side of the bottom of the placing groove (23) close to one side of the bottom of the supporting plate (41), and the placing groove (23) is internally provided with a limiting part (5) used for blocking the sliding-out of the supporting plate (41) from the placing groove (23).

4. An earthquake-resistant structure for new energy building pipeline installation according to claim 3, characterized in that: the first limiting part (5) comprises two limiting plates (51), the two limiting plates (51) are symmetrically and fixedly connected to the side wall of the first supporting plate (41), and a first limiting groove (24) matched with the two limiting plates (51) is formed in the side wall of the placing groove (23).

5. An earthquake-resistant structure for new energy building pipeline installation according to claim 3, characterized in that: two ends of the first support plate (41) are semicircular.

6. An earthquake-resistant structure for new energy building pipeline installation according to claim 1, characterized in that: go up clamp ring (1) inner peripheral surface and seted up spring groove (12), the tank bottom rigid coupling of spring groove (12) has two elastic spring (61), two elastic spring (61) keep away from the one end rigid coupling of spring groove (12) tank bottom has two backup pad (62), two backup pad (62) pass go up gasbag (11), and the butt in pipeline (111) outer wall, install in spring groove (12) and be used for hindering two backup pad (62) roll-offs two (7) of locating part of spring groove (12).

7. An earthquake-resistant structure for new energy building pipeline installation according to claim 6, wherein: the second limiting part (7) comprises a limiting block (71), the limiting block (71) is fixedly connected to the peripheral surface of the second supporting plate (62), and a second limiting groove (13) matched with the limiting block (71) is formed in the side wall of the spring groove (12).

8. An earthquake-resistant structure for new energy building pipeline installation according to claim 1, characterized in that: the end surface of one end of the supporting leg (22) far away from the lower clamping ring (2) is fixedly connected with a pin (221).

Images