CN221004334U

CN221004334U - Anti-seismic reinforcing device

Info

Publication number: CN221004334U
Application number: CN202322555060.7U
Authority: CN
Inventors: 张涛; 尹砚军; 陆世晴
Original assignee: Rizhao Emergency Management Bureau
Current assignee: Rizhao Emergency Management Bureau
Priority date: 2023-09-20
Filing date: 2023-09-20
Publication date: 2024-05-24
Anticipated expiration: 2033-09-20

Abstract

The utility model provides an anti-seismic reinforcing device, and belongs to the technical field of machinery. The anti-seismic reinforcing device comprises a main body mechanism and a reinforcing mechanism. The main structure comprises two groups of side frames and a sliding part, the top ends of the two groups of side frames are respectively welded with the two ends of the bottom of the sliding part, the reinforcing mechanism comprises two inserting and fixing parts and a plurality of clamping pieces, the opposite ends of the two inserting and fixing parts are respectively welded with the opposite ends of the two groups of side frames, and the plurality of clamping pieces are respectively arranged on the outer walls of the two groups of side frames at equal intervals.

Description

Anti-seismic reinforcing device

Technical Field

The application relates to the technical field of seismic detection equipment reinforcement, in particular to an earthquake-resistant reinforcement device.

Background

Seismic monitoring refers to the monitoring and measurement of seismic precursor anomalies and seismic activity before and after the occurrence of an earthquake. The system mainly comprises technical systems for observing, transmitting information, recording and processing earthquakes and main precursor phenomena thereof, and various stations and station networks constructed by the technical systems.

At present, traditional seismic monitoring equipment is all installed outdoors, and for example current bulletin number CN 209590285U's seismic monitoring equipment (China, authorized bulletin day 20191105), in the scheme, including the guard plate, guard plate top fixedly connected with device shell, device shell top sliding connection has the closing cap, the mounting groove has been seted up to the closing cap inboard, mounting groove inside wall bottom fixedly connected with first spring, first spring top fixedly connected with stopper, stopper bottom fixedly connected with dead lever, the spread groove has been seted up to the device shell, dead lever outside and spread groove sliding connection, the dead lever bottom rotates through the pivot and is connected with the fixture block, and in the utility model, through clamping lever, sub-piece, female piece and the driving lever that set up, carries out horizontal compensation to the device, guarantees the stability that the device used, and convenient device is used in outdoor installation, easy operation, design science avoids outdoor environment to the device installation influence, guarantees the approximate level of device, improves the monitoring effect of device. However, the above scheme still has certain defects, and the inventor has found that. The earthquake monitoring equipment has poor earthquake resistance, and can shake due to earthquake waves when an earthquake occurs, so that the earthquake monitoring equipment needs to be reinforced by the reinforcing device, and the earthquake monitoring equipment is prevented from toppling over.

Disclosure of utility model

In order to make up for the defects, the application provides an earthquake-resistant reinforcing device, which aims to solve the problem of poor earthquake resistance of the conventional earthquake monitoring equipment.

In order to achieve the above purpose, the technical scheme adopted by the utility model for solving the technical problems is as follows:

a seismic strengthening device comprises a main body mechanism and a strengthening mechanism.

The main structure comprises two groups of side frames and a sliding part, the top ends of the two groups of side frames are respectively welded with two ends of the bottom of the sliding part, the reinforcing mechanism comprises two inserting parts and a plurality of clamping parts, the opposite ends of the two inserting parts are respectively welded with the opposite ends of the two groups of side frames, and the plurality of clamping parts are respectively arranged on the outer walls of the two groups of side frames at equal intervals.

Further, insert the solid portion including fixed plate, two spliced eyes, two spliced poles, two L shape poles, two solid fixed rings and two cylinder poles, fixed plate one end with side bearer side wall welding, two have been seted up respectively at the surface both ends spliced eyes, two the spliced pole outer wall respectively with two inside grafting of spliced eye, two L shape pole bottom respectively with two spliced pole top welding, two gu fixed ring inner circle respectively with two spliced pole outer wall welding, two cylinder pole bottom respectively with two L shape pole surface one end welding.

Further, the fastener includes circular slot, spring, fixture block and a plurality of draw-in hole, the side bearer lateral wall has been seted up the circular slot, the spring both ends respectively with circular slot in bottom with fixture block bottom fixed connection, the fixture block is installed inside the circular slot, the side bearer lateral wall is still equidistant to have seted up a plurality of the draw-in hole, just card Kong Najuan with fixture block outer wall joint.

Further, the side bearer comprises a U-shaped rod, two supporting rods and two sleeves, wherein two sleeves are respectively arranged at the top end of the U-shaped rod, a plurality of clamping holes are formed in the side wall at equal intervals, the bottom ends of the two supporting rods are respectively sleeved with the two sleeves, the top ends of the supporting rods are welded with the bottoms of the sliding parts, and the circular grooves are formed in the side wall.

Further, the sliding part comprises a sleeve plate, an inserting plate, two sliding grooves and two sliding blocks, wherein an opening of the sleeve plate is sleeved with one end of the inserting plate, two sliding grooves are respectively formed in two sides of the sleeve plate, opposite ends of the two sliding blocks are respectively welded with two sides of the inserting plate, separated ends of the sliding blocks are respectively connected with the two sliding grooves in a sliding mode, and support rods are welded at the bottoms of the sleeve plate and the inserting plate.

Further, the main body mechanism further comprises a soft cushion part, and the soft cushion part is adhered to the bottoms of the U-shaped rod and the sleeve plate.

Further, the cushion part comprises two U-shaped rubber pads and a silica gel pad, the separated ends of the two U-shaped rubber pads are respectively adhered to the opposite ends of the two U-shaped rods, and the surface of the silica gel pad is adhered to the bottom of the sleeve plate.

The beneficial effects are that: the application provides an earthquake-resistant reinforcing device, which is welded on the outer walls of two groups of side frames through two inserting and fixing parts and is matched with a plurality of clamping pieces arranged on the two groups of side frames, so that earthquake detection equipment clamped by the two groups of side frames can be fixed on the ground, the bottom of a fixed ring is tightly attached to the surface of a fixed plate through the rotary insertion of an inserting rod into the ground, and the sleeving degree between a U-shaped rod and two supporting rods can be adjusted through the matching of a spring, a clamping block and a clamping hole, so that the top end of the earthquake detection equipment is clamped by the side frames through a sliding and fixing part, and the problem of poor earthquake resistance of the existing earthquake monitoring equipment can be effectively solved.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present application, the drawings that are needed in the embodiments will be briefly described below, it being understood that the following drawings only illustrate some examples of the present application and therefore should not be considered as limiting the scope, and other related drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

FIG. 1 is a schematic view of a seismic reinforcement device according to an embodiment of the present application;

FIG. 2 is a schematic structural diagram of a main mechanism according to an embodiment of the present application;

FIG. 3 is a schematic diagram of a structure of a fastener according to an embodiment of the present application;

fig. 4 is a schematic structural view of a fixing portion according to an embodiment of the present application.

In the figure: 10-a body mechanism; 110-side frames; 120-slide fastening part; 130-cushion portion; 20-a reinforcement mechanism; 210-an insertion part; 220-a fastener; 211-a fixed plate; 212-plug holes; 213-plug rod; 214-L-shaped rod; 215-a securing ring; 216-cylinder rod; 221-a circular groove; 222-a spring; 223-clamping block; 224-a snap hole; a 111-U-shaped rod; 112-supporting rods; 113-a sleeve; 121-sleeve plate; 122-plugboard; 123-sliding grooves; 124-a slider; 131-U-shaped rubber pads; 132-silicone pad.

Detailed Description

The following description of the embodiments of the present application will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present application, but not all embodiments.

Referring to fig. 1, the present application provides an anti-seismic reinforcement device, a main body mechanism 10 and a reinforcement mechanism 20.

Wherein, the main body mechanism 10 is used for holding the earthquake monitoring equipment, and the reinforcing mechanism 20 is used for reinforcing the earthquake monitoring equipment.

Referring to fig. 1, 2, 3 and 4, the main body mechanism 10 includes two sets of side frames 110 and a sliding portion 120, wherein the top ends of the two sets of side frames 110 are welded to two ends of the bottom of the sliding portion 120, and the two sets of side frames 110 can be mutually close by using the sliding portion 120 through the side frames 110 welded to two ends of the bottom of the sliding portion 120, and simultaneously the sliding portion 120 is close to the top of the earthquake monitoring device by using the two sets of side frames 110, so as to achieve the purpose of clamping the earthquake monitoring device.

In a specific embodiment, the side frames 110 include a U-shaped rod 111, two support rods 112 and two sleeves 113, two sleeves 113 are respectively provided at the top ends of the U-shaped rod 111, a plurality of clamping holes 224 are provided on the side walls at equal intervals, the bottom ends of the two support rods 112 are respectively sleeved with the two sleeves 113, the top ends are welded with the bottom of the sliding and fixing part 120, and circular grooves 221 are provided on the side walls, wherein the side frames are placed on the ground through the U-shaped rod 111, and the distance between the sliding and fixing part 120 and the earthquake monitoring equipment is adjusted by sleeved with the sleeves 113 provided at the top ends of the U-shaped rod 111 through the support rods 112, so that the earthquake monitoring equipment can be clamped by matching the two groups of side frames 110 and the sliding and fixing part 120.

In a specific embodiment, the sliding portion 120 includes a sleeve plate 121, a plugboard 122, two sliding grooves 123 and two sliding blocks 124, the opening of the sleeve plate 121 is sleeved with one end of the plugboard 122, two sliding grooves 123 are respectively formed in two sides of the sleeve plate 121, opposite ends of the two sliding blocks 124 are respectively welded with two sides of the plugboard 122, the opposite ends are respectively connected with the two sliding grooves 123 in a sliding manner, support rods 112 are welded at bottoms of the sleeve plate 121 and the plugboard 122, wherein the distance between two groups of side frames 110 can be adjusted by sleeving the sleeve plate 121 and the plugboard 122, and the plugboard 122 can be limited inside the sleeve plate 121 by sliding connection of the sliding blocks 124 in the sliding grooves 123.

In a specific embodiment, the body mechanism 10 further comprises a cushion portion 130, wherein the cushion portion 130 is adhered to the bottom of the U-shaped rod 111 and the sleeve plate 121, and wherein the cushion portion 130 adhered to the bottom of the sleeve plate 121 and the inner wall of the U-shaped rod 111 enables the side frame 110 to better clamp the earthquake monitoring device with the sliding portion 120.

In a specific embodiment, the cushion part 130 includes two U-shaped rubber pads 131 and a silicone pad 132, the opposite ends of the two U-shaped rubber pads 131 are respectively adhered to the opposite ends of the two U-shaped rods 111, and the surface of the silicone pad 132 is adhered to the bottom of the sleeve plate 121, wherein the U-shaped rubber pads 131 and the silicone pad 132 adhered to the inner wall of the U-shaped rods 111 and the bottom of the sleeve plate 121 can protect the casing of the earthquake monitoring device by using the flexibility of the U-shaped rubber pads 131 and the silicone pad 132.

Referring to fig. 1, 2 and 3, the reinforcing mechanism 20 includes two inserting and fixing portions 210 and a plurality of fastening members 220, opposite ends of the two inserting and fixing portions 210 are welded to opposite ends of the two sets of side frames 110 respectively, the plurality of fastening members 220 are installed on outer walls of the two sets of side frames 110 at equal intervals, wherein the two inserting and fixing portions 210 are welded on the outer walls of the two sets of side frames 110 and are matched with the plurality of fastening members 220 installed on the two sets of side frames 110, the earthquake detection device clamped by the two sets of side frames 110 can be fixed on the ground, the bottom of the fixing ring 215 is tightly attached to the surface of the fixing plate 211 through inserting and fixing rods 213 in a rotating manner, and the sleeving degree between the U-shaped rod 111 and the two support rods 112 can be adjusted through matching of springs 222 and fastening members 223, so that the top end of the earthquake detection device is clamped by the side frames 110 through the sliding and fixing portions 120, and the problem of poor earthquake resistance of the existing earthquake monitoring device can be effectively solved.

In a specific embodiment, the plugging and fixing portion 210 includes a fixing plate 211, two plugging holes 212, two plugging rods 213, two L-shaped rods 214, two fixing rings 215 and two cylindrical rods 216, one end of the fixing plate 211 is welded to the side wall of the side frame 110, two plugging holes 212 are respectively formed at two ends of the surface, the outer ends of the two plugging rods 213 are plugged into the two plugging holes 212, the bottom ends of the two L-shaped rods 214 are respectively welded to the top ends of the two plugging rods 213, the inner rings of the two fixing rings 215 are respectively welded to the outer walls of the two plugging rods 213, the bottom ends of the two cylindrical rods 216 are respectively welded to one end of the surface of the two L-shaped rods 214, wherein the plugging holes 212 formed in the surface of the fixing plate 211 welded by the side wall of the U-shaped rod 111 are convenient for the plugging rods 213 to penetrate, a user holds the cylindrical rods 216 to be matched with the L-shaped rods 214, so that the bottom of the fixing rings 215 is tightly attached to the surface of the fixing plate 211, at this time, the bottom ends of the plugging rods 213 are firmly drilled into the ground, the fixing plate 211 is fixed on the ground, thus the outer wall of the seismic monitoring equipment is reinforced, and the purpose is achieved, and the bottom wall 213 is provided with a threaded plugging and the plugging and connecting rod 213 can be inserted into the ground.

In a specific embodiment, the clamping piece 220 comprises a circular groove 221, a spring 222, a clamping block 223 and a plurality of clamping holes 224, the circular groove 221 is formed in the side wall of the side frame 110, two ends of the spring 222 are respectively fixedly connected with the bottom in the circular groove 221 and the bottom end of the clamping block 223, the clamping block 223 is installed in the circular groove 221, the side wall of the side frame 110 is also provided with a plurality of equally spaced clamping holes 224, the inner ring of the clamping hole 224 is clamped with the outer wall of the clamping block 223, the circular groove 221 formed in the outer wall of the supporting rod 112 is used for conveniently installing the spring 222 and the clamping block 223, the clamping hole 224 formed in the side wall of the U-shaped rod 111 is used for conveniently clamping the supporting rod 112, limiting of the supporting rod 112 is completed by compressing the spring 222 by the clamping block 223, and when the clamping block 223 reaches a specified position, the clamping block 223 is clamped with the clamping hole 224 by the aid of the resilience force of the spring 222, the distance between the sliding and the sliding part 120 and the earthquake monitoring equipment is adjusted, and the supporting rod 112 is fixed.

The working principle of the anti-seismic reinforcing device is as follows: when the device is used, the device is placed on the ground and the earthquake monitoring equipment is covered, the sliding block 124 slides in the sliding groove 123, the inserting plate 122 is inserted into the sleeve plate 121, the two groups of side frames 110 are clamped at opposite ends of the earthquake monitoring equipment, the clamping block 223 is not clamped in the clamping hole 224 by pressing down the clamping block 223 to compress the spring 222, the supporting rod 112 can be sleeved with the sleeve 113 arranged at the top end of the U-shaped rod 111, the sliding solid part 120 is used for pressing the top end of the earthquake monitoring equipment, the spring 222 rebounds to enable the clamping block 223 to be clamped with the clamping hole 224 again, a user holds the cylindrical rod 216 and the L-shaped rod 214 again to rotate the inserting rod 213 in a matching manner, the inserting rod 213 drills into the ground until the bottom of the fixing ring 215 is attached to the surface of the fixing plate 211, the fixing plate 211 is firmly fixed on the ground, and the purpose of reinforcing the earthquake monitoring equipment is achieved.

It should be noted that, the specific model specification of the plugging rod 213 needs to be determined by selecting a model according to the actual specification of the device, and the specific model selection calculation method adopts the prior art in the field, so that detailed description is omitted.

It will be evident to those skilled in the art that the application is not limited to the details of the foregoing illustrative embodiments, and that the present application may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. The present embodiments are, therefore, to be considered in all respects as illustrative and not restrictive, the scope of the application being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Claims

1. An earthquake-resistant reinforcement device, comprising:

The main body mechanism (10), the main body mechanism (10) comprises two groups of side frames (110) and a sliding fixing part (120), and the top ends of the two groups of side frames (110) are respectively welded with the two ends of the bottom of the sliding fixing part (120);

The reinforcing mechanism (20), the reinforcing mechanism (20) comprises two inserting and fixing parts (210) and a plurality of clamping pieces (220), the opposite ends of the two inserting and fixing parts (210) are welded with the separated ends of the two groups of side frames (110) respectively, and the plurality of clamping pieces (220) are installed on the outer walls of the two groups of side frames (110) at equal intervals respectively.

2. The anti-seismic reinforcing device according to claim 1, wherein the plugging and fixing portion (210) comprises a fixing plate (211), two plugging holes (212), two plugging rods (213), two L-shaped rods (214), two fixing rings (215) and two cylindrical rods (216), wherein one end of the fixing plate (211) is welded with the side wall of the side frame (110), two plugging holes (212) are respectively formed in two ends of the surface, the outer walls of the two plugging rods (213) are respectively plugged into the two plugging holes (212), the bottom ends of the two L-shaped rods (214) are respectively welded with the top ends of the two plugging rods (213), the inner rings of the two fixing rings (215) are respectively welded with the outer walls of the two plugging rods (213), and the bottom ends of the two cylindrical rods (216) are respectively welded with one ends of the surface of the two L-shaped rods (214).

3. The anti-seismic reinforcement device according to claim 2, wherein the clamping piece (220) comprises a circular groove (221), a spring (222), a clamping block (223) and a plurality of clamping holes (224), the circular groove (221) is formed in the side wall of the side frame (110), two ends of the spring (222) are fixedly connected with the inner bottom of the circular groove (221) and the bottom of the clamping block (223) respectively, the clamping block (223) is installed inside the circular groove (221), the plurality of clamping holes (224) are formed in the side wall of the side frame (110) at equal intervals, and the inner ring of the clamping holes (224) is clamped with the outer wall of the clamping block (223).

4. A shock-resistant reinforcing apparatus according to claim 3, wherein the side frame (110) comprises a U-shaped rod (111), two support rods (112) and two sleeves (113), wherein the two sleeves (113) are respectively arranged at the top ends of the U-shaped rod (111), a plurality of clamping holes (224) are formed in the side walls at equal intervals, the bottom ends of the two support rods (112) are respectively sleeved with the two sleeves (113), the top ends of the two support rods are welded with the bottoms of the sliding parts (120), and the circular grooves (221) are formed in the side walls.

5. The anti-seismic reinforcement device according to claim 4, wherein the sliding portion (120) comprises a sleeve plate (121), an inserting plate (122), two sliding grooves (123) and two sliding blocks (124), the opening of the sleeve plate (121) is sleeved with one end of the inserting plate (122), two sliding grooves (123) are respectively formed in two sides of the sleeve plate, opposite ends of the two sliding blocks (124) are respectively welded to two sides of the inserting plate (122), the opposite ends are respectively connected with the two sliding grooves (123) in a sliding mode, and the supporting rods (112) are welded to the bottoms of the sleeve plate (121) and the inserting plate (122).

6. An earthquake-resistant reinforcement device according to claim 5, characterized in that the body mechanism (10) further comprises a cushion portion (130), the cushion portion (130) being adhered to the bottom of the U-shaped bar (111) and the sleeve plate (121).

7. The earthquake-resistant reinforcement device according to claim 6, wherein the cushion portion (130) comprises two U-shaped rubber pads (131) and a silicone pad (132), the two U-shaped rubber pads (131) are respectively adhered to opposite ends of the two U-shaped rods (111) at their opposite ends, and the surface of the silicone pad (132) is adhered to the bottom of the sleeve plate (121).