Shockproof high-strength sentry box stand column

By introducing fixed installation and support connection mechanisms into the short-term guard booth columns, the problems of incomplete welding and missing welding between the columns and the frame were solved, enhancing wind pressure resistance and seismic performance and ensuring structural stability.

CN224351487UActive Publication Date: 2026-06-12ZHEJIANG JIANGNAN OUTDOOR PROD CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
ZHEJIANG JIANGNAN OUTDOOR PROD CO LTD
Filing Date
2025-06-13
Publication Date
2026-06-12

AI Technical Summary

Technical Problem

The existing short-term guard posts have problems with incomplete welding and missing welding of the columns and frames, resulting in poor wind pressure and seismic performance. They may deform or break under high wind pressure, or even collapse.

Method used

The system employs a fixed installation mechanism and a support connection mechanism, including a mounting base, mounting plate, anti-vibration guide rod, reinforcing plate, and anti-vibration spring. Through the support connection between multiple column bodies and the mounting frame, the stability and seismic resistance of the columns are enhanced.

Benefits of technology

This improves the wind pressure and earthquake resistance of short-term guard posts, preventing the columns from deforming or breaking under high wind pressure and ensuring structural stability.

✦ Generated by Eureka AI based on patent content.

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Abstract

The utility model belongs to the technical field of sentry box stand column, especially a shockproof high strength sentry box stand column, including stand column main part, the surface of stand column main part is provided with fixed mounting mechanism and support connecting mechanism respectively, fixed mounting mechanism includes the mounting base, and the mounting base realizes the action of fixed mounting of stand column main part with ground, and support connecting mechanism includes the mounting frame, realizes the action that a plurality of stand column main bodies support the connection of mounting frame, this shockproof high strength sentry box stand column, through setting up fixed mounting mechanism and support connecting mechanism, fixed mounting mechanism includes the mounting base, and the mounting base realizes the action of fixed mounting of stand column main part with ground, and support connecting mechanism includes the mounting frame, realizes the action that a plurality of stand column main bodies support the connection of mounting frame, solved the existing short-term sentry box use metal plate thickness thinner, the welding of stand column and frame exists the problem such as false welding, missed welding when the overall wind pressure resistance and anti-seismic performance are poor technical problem.
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Description

Technical Field

[0001] This utility model relates to the field of guard booth column technology, and in particular to a shock-resistant high-strength guard booth column. Background Technology

[0002] Guard booths are buildings used to provide work and rest places for staff. They are widely used in various places such as railway lines, train yards, station areas, and construction sites. Guard booths are also divided into long-term guard booths and short-term guard booths. Long-term guard booths are used in a fixed location, while short-term guard booths are used at construction sites or construction sites. Once a project is completed, they will be moved.

[0003] In actual use, some short-term guard booths use relatively thin metal plates. If there are problems such as incomplete welding or missing welding in the welding of the columns and frames, it may reduce the overall wind pressure resistance and seismic performance. Under high wind pressure, there may be a risk of deformation or breakage, and in extreme cases, it may cause structural collapse, making it inconvenient to use. Utility Model Content

[0004] Based on the technical problems of existing short-term guard booths using thin metal plates and poor overall wind pressure and seismic performance due to issues such as incomplete welding and missing welding in the welding of the columns and frames, this utility model proposes a high-strength, earthquake-resistant guard booth column.

[0005] This utility model proposes a shockproof high-strength guardhouse column, which includes a column body, and the surface of the column body is respectively provided with a fixing installation mechanism and a support connection mechanism.

[0006] The supporting connection mechanism is located above the fixed installation mechanism.

[0007] The fixed installation mechanism includes a mounting base, which enables the column body to be fixedly installed to the ground.

[0008] The support connection mechanism includes a mounting frame, which enables the multiple column bodies to support and connect to the mounting frame.

[0009] Preferably, the fixed installation mechanism further includes a fixed installation plate, the surface of which is fixedly connected to the surface of the mounting base. The surface of the mounting base is provided with a fixed installation hole, and the surface of the fixed installation plate is provided with a rotating groove. The lower end of the column body is fixedly connected to a fixed rotating shaft and a rotating guide shaft, respectively. The two ends of the fixed rotating shaft are rotatably connected to the surface of the fixed installation plate, and the surface of the rotating guide shaft is slidably connected to the surface of the rotating groove.

[0010] Preferably, the column body is located inside the fixed mounting plate, and a shock-absorbing guide rod is slidably connected to the surface of the fixed mounting plate. Multiple shock-absorbing guide rods are linearly arrayed along the axis of the width direction of the fixed mounting plate. Anti-detachment plates and fixed base plates are fixedly connected to the surfaces of the shock-absorbing guide rods respectively. The anti-detachment plates are located on the outside of the fixed mounting plate, and the fixed base plates are located inside the fixed mounting plate. A shock-absorbing spring is provided on the outside of the shock-absorbing guide rod. The two ends of the shock-absorbing spring are elastically connected to the surface of the fixed base plate and the inner wall of the fixed mounting plate respectively. One end of the shock-absorbing guide rod is rotatably connected to a shock-absorbing push plate, and the surface of the shock-absorbing push plate is slidably connected to the surface of the column body.

[0011] Preferably, the supporting connection mechanism further includes a guard booth roof plate, the surface of the mounting frame is slidably connected to the upper end of the column body, a plurality of column bodies are symmetrically distributed about the axis of the length direction of the mounting frame, a reinforcing plate and a connecting column are fixedly connected to the surface of the mounting frame respectively, a plurality of reinforcing plates and a plurality of connecting columns are symmetrically distributed about the axis of the length direction of the mounting frame, and the upper ends of a plurality of connecting columns are fixedly connected to the lower surface of the guard booth roof plate.

[0012] Preferably, a connecting sleeve is provided below the mounting frame, and a connecting slide rod is slidably connected to both ends of the connecting sleeve. The two connecting slide rods are symmetrically distributed with the axis in the width direction of the connecting sleeve as the center. One end of the two connecting slide rods is slidably connected to the upper end of the two column bodies respectively. The multiple connecting sleeves are symmetrically distributed with the axis in the length direction of the mounting frame as the center.

[0013] Preferably, the surface of the connecting sleeve is provided with a connecting groove, and the other end of the connecting slide rod is fixedly connected to a fixed slider. Both ends of the fixed slider are slidably connected to the surface of the connecting groove. An anti-vibration spring is provided on the outer side of the connecting slide rod, and both ends of the anti-vibration spring are elastically connected to the surface of the fixed slider and the inner wall of the connecting sleeve, respectively.

[0014] The beneficial effects of this utility model are as follows:

[0015] By setting up a fixed installation mechanism and a support connection mechanism, the fixed installation mechanism includes an installation base, which fixes the column body to the ground. The support connection mechanism includes an installation frame, which supports and connects multiple column bodies to the installation frame. This solves the technical problem that the existing short-term guard booths have poor overall wind pressure resistance and seismic performance due to the thin metal plates used and the problems of incomplete welding and missing welding between the columns and the frame. Attached Figure Description

[0016] Figure 1This is a schematic diagram of a high-strength, earthquake-resistant guard post column proposed in this utility model;

[0017] Figure 2 This is a front view of a connecting sleeve structure for a high-strength, earthquake-resistant guardhouse column proposed in this utility model;

[0018] Figure 3 This is a three-dimensional view of the mounting frame structure for a high-strength, earthquake-resistant guard booth column proposed in this utility model;

[0019] Figure 4 This is a three-dimensional view of the installation base structure of a shockproof high-strength guard booth column proposed in this utility model.

[0020] In the diagram: 1. Main column; 2. Mounting base; 3. Mounting bracket; 201. Fixed mounting plate; 202. Fixed mounting hole; 203. Rotating slide; 204. Fixed rotating shaft; 205. Rotating guide shaft; 206. Anti-vibration guide rod; 207. Anti-detachment plate; 208. Fixed base plate; 209. Anti-vibration spring; 210. Anti-vibration push plate; 301. Guard booth roof plate; 302. Reinforcing plate; 303. Connecting column; 304. Connecting sleeve; 305. Connecting slide rod; 306. Connecting slide; 307. Fixed slider; 308. Anti-vibration spring. Detailed Implementation

[0021] The technical solutions of the present utility model will be clearly and completely described below with reference to the accompanying drawings of the embodiments of the present utility model. Obviously, the described embodiments are only some embodiments of the present utility model, and not all embodiments.

[0022] Reference Figures 1-4 A high-strength, earthquake-resistant guard post column includes a column body 1, with a fixing installation mechanism and a support connection mechanism respectively provided on the surface of the column body 1.

[0023] The supporting connection mechanism is located above the fixed installation mechanism.

[0024] To facilitate the disassembly, assembly, and relocation of temporary guard posts, and to prevent the risk of deformation or breakage of the guard post pillars under high wind pressure conditions, a fixed installation mechanism is installed, such as... Figures 1-2 and Figure 4 The fixed installation mechanism includes a mounting base 2, which enables the column body 1 to be fixedly installed to the ground.

[0025] The fixed installation mechanism also includes a fixed installation plate 201, the surface of which is fixedly connected to the surface of the mounting base 2. The surface of the mounting base 2 is provided with a fixed installation hole 202, and the surface of the fixed installation plate 201 is provided with a rotating groove 203. The lower end of the column body 1 is fixedly connected to a fixed rotating shaft 204 and a rotating guide shaft 205, respectively. The two ends of the fixed rotating shaft 204 are rotatably connected to the surface of the fixed installation plate 201, and the surface of the rotating guide shaft 205 is slidably connected to the surface of the rotating groove 203.

[0026] Furthermore, the surface of the mounting base 2 is fixedly connected to the ground by opening multiple fixing holes 202, and the lower end of the column body 1 is rotatably connected to the fixing plate 201 set above the mounting base 2 to avoid breakage and deformation.

[0027] The column body 1 is located inside the fixed mounting plate 201. The surface of the fixed mounting plate 201 is slidably connected to the shock-absorbing guide rod 206. Multiple shock-absorbing guide rods 206 are linearly arrayed along the axis of the width direction of the fixed mounting plate 201. The surface of the shock-absorbing guide rod 206 is fixedly connected to the anti-detachment plate 207 and the fixed base plate 208, respectively. The anti-detachment plate 207 is located on the outside of the fixed mounting plate 201, and the fixed base plate 208 is located inside the fixed mounting plate 201. The outside of the shock-absorbing guide rod 206 is provided with a shock-absorbing spring 209. The two ends of the shock-absorbing spring 209 are elastically connected to the surface of the fixed base plate 208 and the inner wall of the fixed mounting plate 201, respectively. One end of the shock-absorbing guide rod 206 is rotatably connected to the shock-absorbing push plate 210. The surface of the shock-absorbing push plate 210 is slidably connected to the surface of the column body 1.

[0028] Furthermore, the anti-vibration guide rod 206 provided on the surface of the fixed mounting plate 201 drives the anti-vibration push plate 210 through the anti-vibration spring 209 to push the upper end of the column body 1 to rotate outward, so as to prevent the guard post column from collapsing inward under high wind pressure.

[0029] To provide stable support for the guard post, its multiple pillars are connected to prevent collapse under high wind pressure conditions. A support connection mechanism is installed, such as... Figures 1-3 The supporting connection mechanism includes a mounting frame 3, which enables multiple column bodies 1 to support and connect to the mounting frame 3.

[0030] The supporting connection mechanism also includes a guard booth roof plate 301. The surface of the mounting frame 3 is slidably connected to the upper end of the column body 1. Multiple column bodies 1 are symmetrically distributed around the axis of the length direction of the mounting frame 3. Reinforcing plates 302 and connecting columns 303 are fixedly connected to the surface of the mounting frame 3. Multiple reinforcing plates 302 and multiple connecting columns 303 are symmetrically distributed around the axis of the length direction of the mounting frame 3. The upper ends of multiple connecting columns 303 are fixedly connected to the lower surface of the guard booth roof plate 301.

[0031] Furthermore, multiple column bodies 1 are connected by the mounting frame 3 to jointly support the mounting frame 3, and a reinforcing plate 302 is provided on the surface of the mounting frame 3 to prevent deformation of the mounting frame 3.

[0032] A connecting sleeve 304 is provided below the mounting bracket 3. Both ends of the connecting sleeve 304 are slidably connected to connecting slide rods 305. The two connecting slide rods 305 are symmetrically distributed with the axis in the width direction of the connecting sleeve 304 as the center. One end of the two connecting slide rods 305 is slidably connected to the upper end of the two column bodies 1 respectively. The multiple connecting sleeves 304 are symmetrically distributed with the axis in the length direction of the mounting bracket 3 as the center.

[0033] Furthermore, the upper ends of two adjacent column bodies 1 are slidably connected to the two ends of the connecting sleeve 304 via connecting slide rods 305.

[0034] The surface of the connecting sleeve 304 is provided with a connecting groove 306. The other end of the connecting slide rod 305 is fixedly connected to a fixed slider 307. Both ends of the fixed slider 307 are slidably connected to the surface of the connecting groove 306. An anti-vibration spring 308 is provided on the outside of the connecting slide rod 305. Both ends of the anti-vibration spring 308 are elastically connected to the surface of the fixed slider 307 and the inner wall of the connecting sleeve 304, respectively.

[0035] Furthermore, the outer side of the connecting slide bar 305 is elastically connected to the inner wall of the connecting sleeve 304 through the anti-vibration spring 308, which absorbs the impact vibration of the guard booth under high wind pressure and improves the structural strength of the guard booth.

[0036] By setting up a fixed installation mechanism and a support connection mechanism, the fixed installation mechanism includes an installation base 2, which fixes the column body 1 to the ground. The support connection mechanism includes an installation frame 3, which supports and connects multiple column bodies 1 to the installation frame 3. This solves the technical problem that the existing short-term guard booths have poor overall wind pressure resistance and seismic performance when the metal plates used are thin and there are problems such as incomplete welding and missing welding between the columns and the frame.

[0037] Working principle:

[0038] Before use, determine the installation positions of multiple column bodies 1 at the location where the guard booth needs to be set up. Fix the mounting base 2 to the ground through multiple fixing mounting holes 202 on the surface of the mounting base 2. A fixing mounting plate 201 is set on top of the mounting base 2. Flip the column body 1 inside the fixing mounting plate 201 to make the column body 1 vertical. The fixing rotating shaft 204 set at the lower end of the column body 1 drives the column body 1 to rotate around the axis of the fixing rotating shaft 204. The rotating guide shaft 205 set at the lower end of the column body 1 slides along the surface of the rotating slide groove 203. The anti-vibration push plate 210 set inside the fixing mounting plate 201 and the column body 1 rotate around the axis of the fixing rotating shaft 204. The surface of the column body 1 is slidably connected, and the surface of the anti-vibration push plate 210 is rotatably connected to one end of multiple guide rods, which facilitates the adjustment of the angle of the anti-vibration push plate 210 to maintain parallelism with the surface of the column body 1. The surfaces of the guide rods are respectively provided with a fixed base plate 208 and an anti-detachment plate 207. The surface of the fixed base plate 208 is elastically connected to the surface of the fixed mounting plate 201 through an anti-vibration spring 209. The surface of the guide rod is slidably connected to the surface of the fixed mounting plate 201. The anti-vibration spring 209 absorbs the vibration of the column body 1 through the anti-vibration push plate 210. The anti-detachment plate 207 at the other end of the guide rod is located on the outside of the fixed mounting plate 201 to prevent the column body from detaching. When placed horizontally, the guide rod detaches from the fixed mounting plate 201. The upper ends of two adjacent column bodies 1 are slidably connected to the outer sides of the connecting slide rods 305 at both ends of the connecting sleeve 304. Two connecting slide rods 305 are provided at the upper end of the column body 1, which are respectively connected to the upper ends of two adjacent column bodies 1. A mounting frame 3 is provided above the connecting slide rods 305. The mounting frame 3 is supported by the upper ends of multiple column bodies 1 slidingly connected to the surface of the mounting frame 3. Doors and windows are provided between adjacent column bodies 1 to isolate the interior of the guard booth. A reinforcing plate 302 is provided on the surface of the mounting plate to enhance the seismic resistance of the mounting frame 3. The upper part of the mounting frame 3... A connecting column 303 is provided, and a guard booth roof plate 301 is provided above the connecting column 303. The mounting frame 3 is connected to the guard booth roof plate 301 through multiple connecting columns 303. The connecting column 303 facilitates the air circulation inside the guard booth. The two ends of the connecting sleeve 304 are connected to the upper ends of the two column bodies 1 through connecting slide rods 305 respectively. One end of the connecting slide rod 305 slides along the connecting groove 306 opened on the surface of the connecting sleeve 304 through the fixed slider 307. The inner wall of the connecting sleeve 304 is elastically connected to the surface of the fixed slider 307 through the anti-vibration spring 308, which enhances the anti-vibration performance of the column body 1.

[0039] The above description is only a preferred embodiment of the present utility model, but the protection scope of the present utility model is not limited thereto. Any equivalent substitutions or changes made by those skilled in the art within the technical scope disclosed in the present utility model, based on the technical solution and the inventive concept of the present utility model, should be included within the protection scope of the present utility model.

Claims

1. A high-strength, earthquake-resistant guard post column, comprising a column body (1), characterized in that: The surface of the column body (1) is respectively provided with a fixing installation mechanism and a support connection mechanism; The supporting connection mechanism is located above the fixed installation mechanism; The fixed installation mechanism includes a mounting base (2), which performs the action of fixing the column body (1) to the ground; The support connection mechanism includes a mounting frame (3) to enable the multiple column bodies (1) to support and connect to the mounting frame (3).

2. The earthquake-resistant high-strength guardhouse column according to claim 1, characterized in that: The fixed installation mechanism also includes a fixed installation plate (201), the surface of which is fixedly connected to the surface of the mounting base (2), the surface of which is provided with a fixed installation hole (202), the surface of which is provided with a rotating groove (203), the lower end of the column body (1) is fixedly connected with a fixed rotating shaft (204) and a rotating guide shaft (205), the two ends of which are rotatably connected to the surface of the fixed installation plate (201), and the surface of the rotating guide shaft (205) is slidably connected to the surface of the rotating groove (203).

3. The earthquake-resistant high-strength guardhouse column according to claim 2, characterized in that: The column body (1) is located inside the fixed mounting plate (201). A shock-absorbing guide rod (206) is slidably connected to the surface of the fixed mounting plate (201). Multiple shock-absorbing guide rods (206) are linearly arrayed along the axis of the fixed mounting plate (201) in the width direction. Anti-detachment plates (207) and fixed base plates (208) are respectively fixedly connected to the surfaces of the shock-absorbing guide rods (206). The anti-detachment plates (207) are located on the outer side of the fixed mounting plate (201). The fixed base plate (208) is located inside the fixed mounting plate (201). An anti-vibration spring (209) is provided on the outside of the anti-vibration guide rod (206). The two ends of the anti-vibration spring (209) are elastically connected to the surface of the fixed base plate (208) and the inner wall of the fixed mounting plate (201), respectively. An anti-vibration push plate (210) is rotatably connected to one end of the anti-vibration guide rod (206). The surface of the anti-vibration push plate (210) is slidably connected to the surface of the column body (1).

4. The earthquake-resistant high-strength guardhouse column according to claim 1, characterized in that: The supporting connection mechanism also includes a guard booth top plate (301). The surface of the mounting frame (3) is slidably connected to the upper end of the column body (1). Multiple column bodies (1) are symmetrically distributed around the axis of the length direction of the mounting frame (3). The surface of the mounting frame (3) is fixedly connected with reinforcing plates (302) and connecting columns (303). Multiple reinforcing plates (302) and multiple connecting columns (303) are symmetrically distributed around the axis of the length direction of the mounting frame (3). The upper ends of multiple connecting columns (303) are fixedly connected to the lower surface of the guard booth top plate (301).

5. The earthquake-resistant high-strength guardhouse column according to claim 1, characterized in that: A connecting sleeve (304) is provided below the mounting bracket (3). Both ends of the connecting sleeve (304) are slidably connected to connecting slide rods (305). The two connecting slide rods (305) are symmetrically distributed with the axis of the width direction of the connecting sleeve (304) as the center. One end of the two connecting slide rods (305) is slidably connected to the upper end of the two column bodies (1). The multiple connecting sleeves (304) are symmetrically distributed with the axis of the length direction of the mounting bracket (3) as the center.

6. The earthquake-resistant high-strength guardhouse column according to claim 5, characterized in that: The surface of the connecting sleeve (304) is provided with a connecting groove (306), and the other end of the connecting slide rod (305) is fixedly connected to a fixed slider (307). Both ends of the fixed slider (307) are slidably connected to the surface of the connecting groove (306). An anti-vibration spring (308) is provided on the outside of the connecting slide rod (305), and both ends of the anti-vibration spring (308) are elastically connected to the surface of the fixed slider (307) and the inner wall of the connecting sleeve (304), respectively.