CN214197752U - Antidetonation support with high stability - Google Patents

Abstract

The utility model discloses an anti-seismic support with high stability, the utility model relates to the technical field of anti-seismic supports, the anti-seismic support with high stability comprises an anti-seismic main support, an anti-seismic diagonal support I and an anti-seismic diagonal support II, wherein the anti-seismic diagonal support I is positioned at the right side of the anti-seismic main support, the anti-seismic diagonal support II is positioned at the rear side of the anti-seismic main support, a left mounting plate is fixedly connected above the anti-seismic main support, inner cavities are formed in the anti-seismic main support, the anti-seismic diagonal support I and the anti-seismic diagonal support II, movable plates are all embedded in the inner cavities, a buffer spring is fixedly connected between the upper surface of the movable plates and the top surface of the inner cavity inner wall, the lower end of the movable plates is fixedly connected with movable rods, a first spring is sleeved outside the movable rods, and the upper and lower ends of the first springs are respectively fixedly connected with the lower surface of the movable plates and the bottom surface of the inner cavity inner wall; the beneficial effects of the utility model reside in that: the pipeline vibration damping device has the advantages that vibration received by the pipeline in all directions can be conveniently slowed down, the stability of the anti-vibration support is high, and the pipeline is well protected.

Description

Antidetonation support with high stability

Technical Field

The utility model belongs to the technical field of antidetonation support technique and specifically relates to an antidetonation support with high stability is related to.

Background

The anti-seismic support limits the displacement of an attached electromechanical engineering facility, controls the vibration of the facility and transmits load to various components or devices on a bearing structure, the existing anti-seismic support generally considers the gravity action of resisting a pipeline and ensures the use function of the pipeline, the existing anti-seismic support rarely considers that when an earthquake or other disasters occur, the vibration borne by the pipeline generally comes from all directions, and the existing anti-seismic support is weaker in the vibration action corresponding to other directions, so that the pipeline is easily damaged.

SUMMERY OF THE UTILITY MODEL

The utility model aims at the problem that exists with not enough above-mentioned, provide an antidetonation support with high stability, be convenient for slow down the vibrations that pipeline all directions received, the stability of antidetonation support is higher, better protection the pipeline.

In order to achieve the purpose, the adopted technical scheme is as follows:

an anti-seismic support with high stability comprises an anti-seismic main support, an anti-seismic diagonal support I and an anti-seismic diagonal support II, wherein the anti-seismic diagonal support I is positioned on the right side of the anti-seismic main support, and the anti-seismic diagonal support II is positioned on the rear side of the anti-seismic main support;

a left mounting plate is fixedly connected above the anti-seismic main support, inner cavities are formed in the anti-seismic main support, the anti-seismic diagonal support I and the anti-seismic diagonal support II, a moving plate is embedded in each inner cavity, a buffer spring is fixedly connected between the upper surface of the moving plate and the top surface of the inner wall of the inner cavity, the lower end of the moving plate is fixedly connected with a moving rod, a spring I is sleeved on the outer side of the moving rod, the upper end and the lower end of the spring I are fixedly connected with the lower surface of the moving plate and the bottom surface of the inner wall of the inner cavity respectively, the lower ends of the three moving rods penetrate through the anti-seismic main support, the anti-seismic diagonal support I and the anti-seismic diagonal support II respectively, connecting rods are fixedly connected at the upper ends of the anti-seismic diagonal support I and the anti-seismic diagonal support II, a right mounting plate is arranged on the right side of the left mounting plate, the upper end of the connecting rod on the anti-seismic diagonal support I is hinged with the left side of the lower surface of the left mounting plate, the lower end of the moving rod positioned on the anti-seismic main support is fixedly connected with an inserting plate, the lower surfaces of the inserting plate and the lower end of the moving rod positioned on the anti-seismic diagonal support II are fixedly connected with lower mounting plates, and the lower end of the moving rod positioned on the anti-seismic diagonal support I is hinged with the right end of the upper surface of the inserting plate;

an upper pipe clamp is fixed below the lower mounting plate, lower pipe clamps which are vertically symmetrical to the upper pipe clamp are arranged below the upper pipe clamp, bolts I are in threaded connection with the left side and the right side of the upper pipe clamp, and the upper pipe clamp is fixedly connected with the lower pipe clamps through the bolts I.

Preferably, the outer wall of the moving plate is attached with a rubber pad, and the rubber pad is attached to the inner wall of the inner cavity.

Preferably, the inner walls of the upper pipe clamp and the lower pipe clamp are respectively attached with a cushion pad.

Preferably, the right side threaded connection has a bolt three below the right side mounting panel, bolt three is located the connecting rod right side, the equal threaded connection in side has a bolt two around the left side mounting panel below, the bolt is two in antidetonation main tributary strut and the second outside of antidetonation bracing.

Preferably, the lower mounting plates on the front side and the rear side are fixedly connected with connecting blocks on the sides close to each other.

Preferably, the rear end of the front connecting block is fixedly connected with an inserting rod, the front of the rear connecting block is provided with a groove, the rear end of the inserting rod is embedded into the groove, and a second spring is fixedly connected between the rear end of the inserting rod and the rear of the inner wall of the groove.

By adopting the technical scheme, the beneficial effects are as follows:

when a user uses the anti-seismic support, the right mounting plate and the left mounting plate are fixed by using the third bolt and the second bolt, so that the whole anti-seismic support is mounted on a ceiling, the pipeline is limited and fixed by the front and the back groups of upper pipe clamps and lower pipe clamps, and the anti-seismic support and the pipeline are mounted, the upper end of each upper pipe clamp is fixedly connected with the lower mounting plate, the upper end of each lower mounting plate is fixedly connected with an inserting plate, the left side of the upper end of each inserting plate is fixedly connected with the lower end of a connecting rod of an anti-seismic main support, the right side of the upper end of each inserting plate is hinged with the lower end of a connecting rod of an anti-seismic diagonal support I, so that when the pipeline is vibrated, the vibration of the pipeline can be transmitted to the connecting rods through the lower mounting plates, and the movable plates can slide in the inner cavities when the lower mounting plates are vibrated, and the first springs stretch along with the up-down movement of the movable plates, the utility model discloses a pipeline support, including the movable plate, the mounting panel receives, because fixedly connected with buffer spring between the movable plate and the inner chamber inner wall top surface, so buffer spring also can stretch out and draw back when the movable plate slides in the inner chamber, further slow down the vibrations that movable plate and lower mounting panel received, thereby increase the holistic stability of antidetonation support, because antidetonation bracing one is located antidetonation main tributary, antidetonation bracing two is located antidetonation main tributary, the antidetonation main tributary can slow down the vibrations of pipeline upper and lower direction, the vibrations of pipeline left and right sides direction can effectively be slowed down to antidetonation bracing one, the vibrations of pipeline fore-and-aft direction can be slowed down to antidetonation bracing two, the holistic anti-seismic performance of support has been strengthened greatly in antidetonation main tributary, the stability of antidetonation support is higher, better protection the pipeline.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings of the embodiments of the present invention will be briefly described below. The drawings are intended to depict only some embodiments of the invention, and not all embodiments of the invention are limited thereto.

Fig. 1 is a schematic view of the overall front view cross-sectional structure of the present invention;

FIG. 2 is a schematic view of the overall left-side cross-sectional structure of the present invention;

fig. 3 is a schematic view of a partially enlarged structure a of fig. 1 according to the present invention;

fig. 4 is a schematic diagram of a partially enlarged structure B of fig. 2 according to the present invention.

The labels in the figure are: the anti-seismic main support comprises an anti-seismic main support 1, a left mounting plate 101, a buffer spring 102, a moving rod 103, a first spring 104, a lower mounting plate 105, an inserting plate 106, an upper pipe clamp 107, a lower pipe clamp 108, a first bolt 109, a buffer pad 110, a second bolt 111, an inner cavity 112, a moving plate 113, a rubber pad 114, a connecting block 115, an inserting rod 116, a groove 117, a second spring 118, a first anti-seismic inclined support 2, a right mounting plate 201, a third bolt 202, a connecting rod 203 and a second anti-seismic inclined support 3.

Detailed Description

In order to make the purpose, technical features and technical effects of the technical solution of the present invention clearer, the drawings of the embodiments of the present invention are combined together, and the example solution of the embodiments of the present invention is clearly and completely described.

Referring to fig. 1 to 4, the application is an anti-seismic support with high stability, which comprises an anti-seismic main support 1, an anti-seismic diagonal support one 2 and an anti-seismic diagonal support two 3, wherein the anti-seismic diagonal support one 2 is located on the right side of the anti-seismic main support 1, and the anti-seismic diagonal support two 3 is located on the rear side of the anti-seismic main support 1;

a third bolt 202 is connected to the right side below the right mounting plate 201 in a threaded manner, the third bolt 202 is located on the right side of the connecting rod 203, a second bolt 111 is connected to the front side and the rear side below the left mounting plate 101 in a threaded manner, and the second bolt 111 is located on the outer sides of the anti-seismic main support 1 and the anti-seismic diagonal support 3;

an upper pipe clamp 107 is fixed below the lower mounting plate 105, a lower pipe clamp 108 which is vertically symmetrical with the upper pipe clamp 107 is arranged below the upper pipe clamp 107, the left side and the right side of the upper surface of the upper pipe clamp 107 are both in threaded connection with a first bolt 109, and the upper pipe clamp 107 is fixedly connected with the lower pipe clamp 108 through the first bolt 109;

specifically, a user can fix the right mounting plate 201 and the left mounting plate 101 on a ceiling through the third bolt 202 and the second bolt 111 to mount the anti-seismic support, then unscrew the first bolt 109, place a pipeline needing to be mounted with the anti-seismic support between the front and rear two sets of upper pipe clamps 107 and lower pipe clamps 108, and then fix the upper pipe clamps 107 and the lower pipe clamps 108 through the first bolt 109, so that the pipeline is clamped between the pipe clamps 107 and the lower pipe clamps 108, and the pipeline is limited and fixed, so that the mounting of the anti-seismic support and the pipeline is completed;

a left mounting plate 101 is fixedly connected above the anti-seismic main support 1, inner cavities 112 are formed in the anti-seismic main support 1, the anti-seismic diagonal support one 2 and the anti-seismic diagonal support two 3, a moving plate 113 is embedded in the inner cavity 112, a buffer spring 102 is fixedly connected between the upper surface of the moving plate 113 and the top surface of the inner wall of the inner cavity 112, a moving rod 103 is fixedly connected to the lower end of the moving plate 113, a first spring 104 is sleeved on the outer side of the moving rod 103, the upper end and the lower end of the first spring 104 are fixedly connected with the lower surface of the moving plate 113 and the bottom surface of the inner wall of the inner cavity 112 respectively, the lower ends of the three moving rods 103 penetrate through the anti-seismic main support 1, the anti-seismic diagonal support one 2 and the anti-seismic diagonal support two 3 respectively, connecting rods 203 are fixedly connected to the upper ends of the first anti-seismic diagonal support 2 and the anti-seismic diagonal support two 3, a right mounting plate 201 is arranged on the right side of the left mounting plate 101, the upper end of the connecting rod 203 on the first anti-seismic diagonal support 2 is hinged to the lower side of the right mounting plate 201, the upper end of the connecting rod 203 on the second anti-seismic diagonal brace 3 is hinged with the rear end of the lower surface of the left mounting plate 101, the lower end of the moving rod 103 on the main anti-seismic brace 1 is fixedly connected with an inserting plate 106, the lower end of the moving rod 103 on the second anti-seismic diagonal brace 3 and the lower end of the inserting plate 106 are fixedly connected with a lower mounting plate 105, and the lower end of the moving rod 103 on the first anti-seismic diagonal brace 2 is hinged with the right end of the upper surface of the inserting plate 106;

furthermore, because the upper end of the upper pipe clamp 107 is fixedly connected with the lower mounting plate 105, the upper end of the front lower mounting plate 105 is fixedly connected with the inserting plate 106, the left side of the upper end of the inserting plate 106 is fixedly connected with the lower end of the connecting rod 203 of the anti-seismic main support 1, and the right side of the upper end of the inserting plate 106 is hinged with the lower end of the connecting rod 203 of the anti-seismic diagonal support one 2, when the pipeline is vibrated, the vibration of the pipeline can be transmitted to the connecting rod 203 through the lower mounting plate 105, because the upper end of the connecting rod 203 is fixedly connected with the moving plate 113, the moving plate 113 is embedded into the inner cavity 112, the outer side of the connecting rod 203 is sleeved with the spring one 104, the upper end and the lower end of the spring one 104 are respectively fixedly connected with the lower surface of the moving plate 113 and the bottom surface of the inner wall of the inner cavity 112, when the lower mounting plate 105 is vibrated, the moving plate 113 can slide in the inner cavity 112, the spring one 104 can extend and retract along with the up and down movement of the moving plate 113, so as to slow down the vibration received by the lower mounting plate 105, because the buffer spring 102 is fixedly connected between the upper surface of the movable plate 113 and the top surface of the inner wall of the inner cavity 112, the buffer spring 102 can also stretch when the movable plate 113 slides in the inner cavity 112, so that the vibration of the movable plate 113 and the lower mounting plate 105 is further reduced, and the stability of the whole anti-seismic support is improved;

a rubber pad 114 is attached to the outer wall of the moving plate 113, the rubber pad 114 is attached to the inner wall of the inner cavity 112, cushion pads 110 are attached to the inner walls of the upper pipe clamp 107 and the lower pipe clamp 108, connecting blocks 115 are fixedly connected to the sides, close to each other, of the lower mounting plates 105 on the front side and the rear side, the rear end of the connecting block 115 in the front is fixedly connected with an inserting rod 116, a groove 117 is formed in the front of the connecting block 115 in the rear, the rear end of the inserting rod 116 is embedded into the groove 117, and a second spring 118 is fixedly connected between the rear end of the inserting rod 116 and the rear of the inner wall of the groove 117;

furthermore, because the rubber pad 114 is attached to the outer wall of the moving plate 113, and the rubber pad 114 is attached to the inner wall of the inner cavity 112, the rubber pad 114 can be squeezed in the process that the moving plate 113 moves up and down, thereby reducing the impact on the moving plate 113 when moving up and down, thereby increasing the stability of the moving plate 113 when moving up and down, and further enhancing the stability of the anti-seismic support, because the inner walls of the upper pipe clamp 107 and the lower pipe clamp 108 are both attached with the buffer pad 110, when the upper pipe clamp 107 and the lower pipe clamp 108 clamp the pipeline, the buffer pad 110 can reduce the friction and impact between the pipeline and the upper pipe clamp 107 and the lower pipe clamp 108, so that the pipeline is more stably limited and fixed, because the sides of the lower mounting plates 105 at the front side and the rear side, which are close to each other, are both fixedly connected, the rear end of the inserted bar 116 is embedded into the groove 117, and the second spring 118 is fixedly connected between the rear end of the inserted bar 116 and the inner wall of the groove 117, so that when the pipeline vibrates in the front-back direction, the second spring 118 can stretch along with the front-back vibration of the pipeline, the vibration of the pipeline is further reduced, and the stability of the anti-vibration support is further enhanced.

In the present specification, each embodiment is described with emphasis on differences from other embodiments, and the same or similar parts between the embodiments may be referred to each other.

Exemplary embodiments of the present invention have been described in detail with reference to the preferred embodiments, however, it will be understood by those skilled in the art that various modifications and changes may be made to the above specific embodiments without departing from the scope of the present invention, and various combinations of the technical features and structures of the present invention may be implemented without departing from the scope of the present invention, which is defined by the appended claims.

Claims (6)

1. The utility model provides an antidetonation support with high stability, includes antidetonation main tributary strut (1), antidetonation bracing one (2) and antidetonation bracing two (3), its characterized in that:

the first anti-seismic diagonal brace (2) is positioned on the right side of the main anti-seismic brace (1), and the second anti-seismic diagonal brace (3) is positioned on the rear side of the main anti-seismic brace (1);

a left mounting plate (101) is fixedly connected above the anti-seismic main support (1), inner cavities (112) are formed in the anti-seismic main support (1), the anti-seismic diagonal support I (2) and the anti-seismic diagonal support II (3), a movable plate (113) is embedded in the inner cavity (112), a buffer spring (102) is fixedly connected between the upper surface of the movable plate (113) and the top surface of the inner wall of the inner cavity (112), a movable rod (103) is fixedly connected with the lower end of the movable plate (113), a spring I (104) is sleeved on the outer side of the movable rod (103), the upper end and the lower end of the spring I (104) are respectively fixedly connected with the lower surface of the movable plate (113) and the bottom surface of the inner wall of the inner cavity (112), the lower ends of the three movable rods (103) penetrate through the anti-seismic main support (1), the anti-seismic diagonal support I (2) and the anti-seismic diagonal support II (3) respectively, connecting rods (203) are fixedly connected with the upper ends of the anti-seismic diagonal support I (2) and the anti-seismic diagonal support II (3), the left mounting plate (101) is provided with a right mounting plate (201) on the right side, the upper end of the connecting rod (203) on the first anti-seismic inclined strut (2) is hinged to the left side below the right mounting plate (201), the upper end of the connecting rod (203) on the second anti-seismic inclined strut (3) is hinged to the rear end below the left mounting plate (101), the lower end of the moving rod (103) on the main anti-seismic strut (1) is fixedly connected with an inserting plate (106), the lower ends of the moving rod (103) below the inserting plate (106) and on the second anti-seismic inclined strut (3) are fixedly connected with a lower mounting plate (105), and the lower end of the moving rod (103) on the first anti-seismic inclined strut (2) is hinged to the right end above the inserting plate (106);

be fixed with lower pipe clamp (107) below lower mounting panel (105), be equipped with below upper pipe clamp (107) rather than longitudinal symmetry's lower pipe clamp (108), the equal threaded connection in the left and right sides has bolt one (109) above upper pipe clamp (107), upper pipe clamp (107) are through bolt one (109) and lower pipe clamp (108) fixed connection.

2. An earthquake-resistant support with high stability according to claim 1, characterized in that: a rubber pad (114) is attached to the outer wall of the moving plate (113), and the rubber pad (114) is attached to the inner wall of the inner cavity (112).

3. An earthquake-resistant support with high stability according to claim 1, characterized in that: the inner walls of the upper pipe clamp (107) and the lower pipe clamp (108) are respectively attached with a cushion pad (110).

4. An earthquake-resistant support with high stability according to claim 1, characterized in that: the utility model discloses a seismic main bracing support, including right side mounting panel (201), right side threaded connection has bolt three (202) below right side mounting panel (201), bolt three (202) are located connecting rod (203) right side, the equal threaded connection in side has bolt two (111) around left side mounting panel (101) below, bolt two (111) are located the seismic main bracing (1) and the seismic diagonal bracing two (3) outsides.

5. An earthquake-resistant support with high stability according to claim 1, characterized in that: and the side, close to each other, of the lower mounting plate (105) at the front side and the rear side is fixedly connected with a connecting block (115).

6. An earthquake-resistant support with high stability according to claim 5, characterized in that: the rear end of the front connecting block (115) is fixedly connected with an inserting rod (116), a groove (117) is formed in the front of the rear connecting block (115), the rear end of the inserting rod (116) is embedded into the groove (117), and a second spring (118) is fixedly connected between the rear end of the inserting rod (116) and the rear surface of the inner wall of the groove (117).

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