CN217683637U - Double-end shockproof support for preventing mounting surface from bending failure - Google Patents

Abstract

The utility model discloses a prevent support that takes precautions against earthquakes of double-end of installation face bending failure, include: the cable support comprises a support cross beam, wherein the top of the support cross beam is embedded with symmetrically distributed horizontal clamping blocks, a bridge frame for placing cables is arranged between the horizontal clamping blocks in a fitting manner to form a limiting structure, and the bottom surface of the bridge frame is arranged on the upper surface of the support cross beam in a fitting manner; further comprising: and the side screw rods are fixedly arranged on the side wall of the bridge frame, the two side screw rods are symmetrically arranged relative to the axis of the bridge frame, the side screw rods are attached to the inside of the through guide groove formed in the horizontal clamping block, the end parts of the side screw rods are in threaded connection with side nuts, and the side nuts are attached to the outer wall of the horizontal clamping block to form a fastening structure. This prevent double-end support that takes precautions against earthquakes of installation face bending failure, it sets up the ascending location structure of level and vertical dual orientation to improve the fastening ability of device to the crane span structure, and the fixed stay structure of device adopts double-end anchoring mode more firm.

Description

Double-end shockproof support for preventing mounting surface from bending failure

Technical Field

The utility model relates to a support technical field takes precautions against earthquakes specifically is a prevent support takes precautions against earthquakes of double-end of installation face bending failure.

Background

In the process of installing the cable bridge, the bridge needs to be fixed through the shockproof support, so that the risk that the bridge falls off due to external shock is reduced, and the existing shockproof support still has some problems.

For example, the shockproof support disclosed in the publication No. CN215221606U comprises a base, wherein four corners of the lower surface of the base are respectively provided with a damping mechanism, the left side and the right side of the upper surface of the base are respectively and fixedly connected with one end of a supporting column, the other end of the supporting column is fixedly connected with a supporting plate, the upper surface of the supporting plate is provided with a mounting plate, and the upper surface of the mounting plate is provided with a placing groove \8230 \ 8230and \ 8230. The device is only provided with a single horizontal positioning structure, the device has poor fastening capacity on the bridge, and if the horizontal limiting structure of the device is bent and deformed due to external force, the bridge on the device is not positioned any more.

In order to solve the problems, innovative design is urgently needed on the basis of the original shockproof support.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a prevent crooked became invalid double-end support that takes precautions against earthquakes of installation face to solve above-mentioned background art and propose current support that takes precautions against earthquakes, it only is provided with single horizontal direction location structure, and the device is relatively poor to the fastening capacity of crane span structure, if the limit structure of device horizontal direction takes place crooked deformation because of external force, then the problem that the crane span structure on the device will no longer be fixed a position.

In order to achieve the above purpose, the utility model provides a following technical scheme: a double-ended shock mount for resisting mounting surface buckling failure, comprising:

the cable support comprises a support cross beam, wherein horizontal clamping blocks which are symmetrically distributed are embedded in the top of the support cross beam, a bridge frame for placing a cable is arranged between the horizontal clamping blocks in a fitting manner to form a limiting structure, and the bottom surface of the bridge frame is arranged on the upper surface of the support cross beam in a fitting manner;

further comprising:

the side screw rods are fixedly arranged on the side wall of the bridge frame, the two side screw rods are symmetrically arranged relative to the axis of the bridge frame, the side screw rods are attached to and arranged in the through guide grooves formed in the horizontal clamping blocks, the end parts of the side screw rods are in threaded connection with side nuts, and the side nuts are attached to and arranged on the outer wall of the horizontal clamping blocks to form a fastening structure;

and the fixed support plates are positioned right above the supporting cross beam, two ends of each fixed support plate are respectively and vertically connected to the side walls of the corresponding connecting columns, and the bottom surfaces of the two connecting columns are respectively and fixedly installed on two sides of the top of the supporting cross beam.

Preferably, the horizontal clamping block is of a T-shaped structure, the horizontal clamping block is embedded in the supporting cross beam to form a sliding guide structure, the supporting cross beam is rotatably provided with a transmission screw rod in a penetrating mode, a convex ring arranged at the center of the transmission screw rod is embedded in the supporting cross beam to form a rotating limiting structure, and the transmission screw rod can rotate on the supporting cross beam.

Preferably, the end face of the transmission screw is fixedly connected with a coaxially arranged hand wheel, two thread grooves with equal length and opposite rotation directions are formed in the transmission screw, and the two thread grooves are respectively provided with the corresponding horizontal clamping blocks to form a transmission structure, so that the transmission screw can drive the two horizontal clamping blocks to synchronously move.

Preferably, fixed mounting has the foot rest of symmetric distribution on the top lateral wall of spliced pole, and slides in the mounting hole that the foot rest top was seted up and run through and be provided with set screw to be provided with the horizontally reinforcing plate directly over the spliced pole, fixedly connected with between the lateral wall of two foot rests moreover the reinforcing plate is used for improving device structural strength, and the slope of foot rest sets up simultaneously, constitutes the double-end fixed stay structure of device.

Preferably, a control hand rod vertically penetrates through the center of the fixed support plate, the control hand rod and the fixed support plate form a threaded connection relation, the bottom end of the control hand rod is rotatably embedded in the positioning plate, guide pillars are vertically arranged on two sides of the upper surface of the positioning plate, the guide pillars slidably penetrate through the fixed support plate to form a guide limiting structure, and the moving direction of the positioning plate is controlled through the guide pillars.

Preferably, the positioning plate is provided with top screws in the symmetrically distributed sliding grooves in an attached manner, the bottom ends of the top screws are fixedly mounted at the top of the bridge, the upper surface of the bridge is in contact with the bottom surface of the positioning plate, the top ends of the top screws are in threaded connection with top nuts, and the top nuts are attached to the top of the positioning plate to form a fastening structure, so that the positioning plate is fixed above the bridge.

Compared with the prior art, the beneficial effects of the utility model are that: this prevent installation face crooked disappearance double-end support that takes precautions against earthquakes, it sets up the ascending location structure of level and vertical dual orientation to improve the fastening ability of device to the crane span structure, and the fixed stay structure of device adopts double-end anchoring mode more firm, and its concrete content is as follows:

1. a bridge frame used for placing cables is arranged between the horizontal clamping blocks in an attaching mode to form a limiting structure, side screws are fixedly installed on the side walls of the bridge frame and are arranged in penetrating guide grooves formed in the horizontal clamping blocks in an attaching mode, side nuts connected with the end portions of the side screws in a threaded mode are arranged on the outer walls of the horizontal clamping blocks in an attaching mode, and a horizontal positioning structure of the bridge frame is formed through the structure;

2. the control handle bar sticiss the locating plate at the top of crane span structure, and the laminating is provided with the top screw rod in the spout of symmetric distribution on the locating plate, and the bottom fixed mounting of top screw rod has a top nut at the top of crane span structure, top screw rod's top threaded connection, and the laminating of top nut sets up at the top of locating plate for the locating plate can closely fix the crane span structure on supporting beam, forms vertical limit structure.

Drawings

FIG. 1 is a schematic view of the overall external structure of the present invention;

fig. 2 is a schematic view of the bridge mounting structure of the present invention;

FIG. 3 is a schematic view of the control lever mounting structure of the present invention;

FIG. 4 is a schematic view of the mounting structure of the positioning plate of the present invention;

FIG. 5 is a schematic view of the side screw mounting structure of the present invention;

FIG. 6 is a schematic view of the installation structure of the horizontal clamping block of the present invention;

FIG. 7 is a schematic view of the mounting structure of the driving screw of the present invention;

fig. 8 is a schematic view of the hand wheel mounting structure of the present invention.

In the figure: 1. a supporting beam; 2. a horizontal clamping block; 3. a bridge frame; 4. a side screw; 5. a side nut; 6. a drive screw; 7. a hand wheel; 8. connecting columns; 9. a foot rest; 10. a set screw; 11. a reinforcing plate; 12. fixing a support plate; 13. a control lever; 14. positioning a plate; 15. a guide post; 16. a screw rod is pushed; 17. and (4) a top nut.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Referring to fig. 1-8, the present invention provides a technical solution: a double-ended shock mount for resisting mounting face buckling failure, comprising:

the cable support comprises a support beam 1, wherein horizontal clamping blocks 2 which are symmetrically distributed are embedded in the top of the support beam 1, a bridge frame 3 for placing cables is attached between the horizontal clamping blocks 2 to form a limiting structure, and the bottom surface of the bridge frame 3 is attached to the upper surface of the support beam 1;

further comprising:

the side screws 4 are fixedly arranged on the side wall of the bridge frame 3, the two side screws 4 are symmetrically arranged relative to the axis of the bridge frame 3, the side screws 4 are attached to and arranged in through guide grooves formed in the horizontal clamping block 2, the end parts of the side screws 4 are in threaded connection with side nuts 5, and the side nuts 5 are attached to and arranged on the outer wall of the horizontal clamping block 2 to form a fastening structure;

and the fixed support plates 12 are positioned right above the supporting beam 1, two ends of each fixed support plate 12 are respectively and vertically connected to the side walls of the corresponding connecting columns 8, and the bottom surfaces of the two connecting columns 8 are respectively and fixedly installed on two sides of the top of the supporting beam 1.

Horizontal clamp splice 2 is "T" font structure, and horizontal clamp splice 2 inlays and establishes and form the slip guide structure on supporting beam 1, and rotate on supporting beam 1 and run through and install drive screw 6, and the bulge loop that drive screw 6 center department set up inlays and establishes and form rotation limit structure on supporting beam 1, fixedly connected with coaxial setting's hand wheel 7 on drive screw 6's the terminal surface, and set up two sections length and equal the opposite thread groove of turning round on drive screw 6, and install corresponding horizontal clamp splice 2 formation drive structure on two thread grooves respectively, twist off side nut 5 from side screw 4, rotate hand wheel 7, hand wheel 7 drives drive screw 6 synchronous rotation, utilize drive screw 6 to drive two horizontal clamp splices 2 and keep away from each other, make horizontal clamp splice 2 no longer with the contact of side screw 4.

The top side wall of the connecting column 8 is fixedly provided with symmetrically distributed foot rests 9, a fixing screw 10 penetrates through a mounting hole formed in the top of each foot rest 9 in a sliding mode, a horizontal reinforcing plate 11 is arranged right above the connecting column 8, the reinforcing plate 11 is fixedly connected between the side walls of the two foot rests 9 and used for improving the structural strength of the device, meanwhile, the foot rests 9 are arranged in an inclined mode, a control hand rod 13 vertically penetrates through the center of the fixing support plate 12, the control hand rod 13 and the horizontal reinforcing plate form a threaded connection relation, the bottom end of the control hand rod 13 is embedded on the positioning plate 14 in a rotating mode, guide columns 15 are vertically arranged on two sides of the upper surface of the positioning plate 14, the guide columns 15 penetrate through the fixing support plate 12 in a sliding mode to form a guiding limiting structure, top screw rods 16 are arranged in symmetrically distributed sliding grooves in the positioning plate 14 in a laminating mode, the bottom ends of the top screw rods 16 are fixedly installed on the top of the bridge frame 3, the upper surface of the bridge 3 is in contact with the bottom surface of the positioning plate 14, top nuts 17 are connected with the top ends of the top screw rods 16, the top nuts 17 are arranged on the top of the positioning plate 14 in a laminating mode, the top of the positioning plate 14, the fixing screw rods 10 to form a fastening structure, the fixing screw structures, the fixing structure, the control hand rods 13, and the positioning plate 14 are synchronously pulled by the fixing screw rods 13, and the positioning plate 14.

The working principle is as follows: when the double-ended shockproof support for preventing the bending failure of the mounting surface is used, firstly, referring to fig. 1-8, fixing screws 10 are driven into the top of a building through an electric drill, so that the fixing screws 10 can fix foot rests 9, the top of connecting columns 8 is fixedly provided with the symmetrically distributed foot rests 9 to form a double-ended fixed shockproof structure, a reinforcing plate 11 is fixedly connected between the side walls of the two foot rests 9, the reinforcing plate 11 is utilized to improve the structural strength of the device so as to prevent the deformation of the mounting structure formed by the foot rests 9, horizontal clamping blocks 2 are attached to and arranged on two sides of a bridge frame 3 to form a limiting structure, side screws 4 mounted on the side walls of the bridge frame 3 are attached to and arranged in guide grooves formed in the horizontal clamping blocks 2, side nuts 5 in threaded connection with the end portions of the side screws 4 are attached to and arranged on the outer wall of the horizontal clamping blocks 2, a horizontal positioning structure of the bridge frame 3 is formed through the structure, meanwhile, hand levers 13 are controlled to tightly press the top of the bridge frame 14 on the top of the positioning plates, top nuts 17 symmetrically distributed in a manner are attached, top of the positioning plates 14, the top screws 16 are fixedly arranged on the top of the positioning plates 14, the top of the positioning plates, the top screw 16, and the vertical limiting structure of the bridge frame 3 is formed;

referring to fig. 1-8, when a user needs to detach the bridge frame 3, the jacking nut 17 is detached from the jacking screw 16, then the control hand lever 13 is rotated to move the control hand lever 13 on the fixing support plate 12 in threaded connection, the control hand lever 13 pulls the positioning plate 14 to move upwards, the guide post 15 installed on the positioning plate 14 synchronously slides on the fixing support plate 12, then the side nut 5 is unscrewed from the side screw 4, then the hand wheel 7 is rotated, the hand wheel 7 drives the transmission screw 6 to synchronously rotate, because the transmission screw 6 is provided with threaded grooves with equal length and opposite rotation directions, and the horizontal clamping blocks 2 are installed on the two threaded grooves, at this moment, the transmission screw 6 drives the two horizontal clamping blocks 2 to be away from each other, and when the horizontal clamping blocks 2 are not in contact with the side screw 4, the bridge frame 3 can be detached.

Although the present invention has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that modifications may be made to the embodiments or portions thereof without departing from the spirit and scope of the invention.

Claims (6)

1. A double-ended shock mount for resisting mounting face buckling failure, comprising:

the cable fixing device comprises a supporting beam (1), wherein horizontal clamping blocks (2) which are symmetrically distributed are embedded in the top of the supporting beam, a bridge (3) used for placing cables is arranged between the horizontal clamping blocks (2) in a fitting mode to form a limiting structure, and the bottom surface of the bridge (3) is arranged on the upper surface of the supporting beam (1) in a fitting mode;

it is characterized by also comprising:

the side screws (4) are fixedly mounted on the side wall of the bridge (3), the two side screws (4) are symmetrically arranged relative to the axis of the bridge (3), the side screws (4) are attached to and arranged in through guide grooves formed in the horizontal clamping block (2), the end parts of the side screws (4) are in threaded connection with side nuts (5), and the side nuts (5) are attached to and arranged on the outer wall of the horizontal clamping block (2) to form a fastening structure;

the fixing support plate (12) is located right above the supporting cross beam (1), two ends of the fixing support plate (12) are respectively and vertically connected to the side walls of the corresponding connecting columns (8), and the bottom surfaces of the two connecting columns (8) are respectively and fixedly installed on two sides of the top of the supporting cross beam (1).

2. The double-ended anti-seismic bracket for preventing mounting surface bending failure according to claim 1, characterized in that: horizontal clamp splice (2) are "T" font structure, and horizontal clamp splice (2) inlay and establish form sliding guide structure on supporting beam (1) to rotate on supporting beam (1) and run through and install drive screw (6), the bulge loop that sets up in drive screw (6) center department moreover inlays and establishes form rotation limit structure on supporting beam (1).

3. The double-ended anti-seismic bracket for preventing mounting surface buckling failure of claim 2, wherein: the end face of the transmission screw rod (6) is fixedly connected with a hand wheel (7) which is coaxially arranged, two thread grooves which are equal in length and opposite in rotation direction are formed in the transmission screw rod (6), and the two thread grooves are respectively provided with the corresponding horizontal clamping blocks (2) to form a transmission structure.

4. The double-ended anti-seismic bracket for preventing mounting surface bending failure according to claim 1, characterized in that: fixed mounting has symmetric distribution's foot rest (9) on the top lateral wall of spliced pole (8), and slides in the mounting hole that foot rest (9) top was seted up and run through and be provided with set screw (10) to be provided with horizontally reinforcing plate (11) directly over spliced pole (8), fixedly connected with between the lateral wall of two foot rests (9) moreover reinforcing plate (11) are used for improving device structural strength, and foot rest (9) slope sets up simultaneously.

5. The double-ended anti-seismic bracket for preventing mounting surface bending failure according to claim 1, characterized in that: the center of the fixed support plate (12) is vertically penetrated with a control hand rod (13), the control hand rod and the control hand rod form a threaded connection relation, the bottom end of the control hand rod (13) is rotatably embedded in the positioning plate (14), guide pillars (15) are vertically arranged on two sides of the upper surface of the positioning plate (14), and the guide pillars (15) slidably penetrate through the fixed support plate (12) to form a guide limiting structure.

6. The double-ended anti-seismic bracket for preventing mounting surface bending failure according to claim 5, wherein: the positioning plate is characterized in that top screws (16) are arranged in symmetrically distributed sliding grooves in a fitted mode, the bottom ends of the top screws (16) are fixedly installed at the top of the bridge (3), the upper surface of the bridge (3) is in contact with the bottom surface of the positioning plate (14), top threads of the top screws (16) are connected with top nuts (17), and the top nuts (17) are fitted and arranged at the top of the positioning plate (14) to form a fastening structure.

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