CN219417020U - Tensile detection device for shock insulation support - Google Patents

Abstract

The utility model relates to the technical field of detection of a shock insulation support, in particular to a shock insulation support tensile detection device which is used for detecting the tensile strength of the shock insulation support, wherein the shock insulation support is provided with an upper end face and a lower opposite end face, and is characterized by comprising the following components: the supporting device is sleeved on the shock insulation support, the upper part of the supporting device is fixedly connected with the upper end face of the shock insulation support, and the lower part of the supporting device is arranged at intervals with the lower end face of the shock insulation support; the pressure conversion device is sleeved on the shock insulation support, the lower part of the pressure conversion device is positioned between the shock insulation support and the lower part of the supporting device, the lower end face of the shock insulation support is fixedly connected with the lower end face of the pressure conversion device, and the upper part of the pressure conversion device is a pressure bearing surface. According to the tension detection device for the shock insulation support, the shock insulation support is placed into the support device and the pressure conversion device, pressure is applied to the pressure conversion device, the pressure is converted into the tensile force through force conversion, the purpose of tension detection of the shock insulation support can be achieved, and the tension detection device is simple and easy to operate.

Description

Tensile detection device for shock insulation support

Technical Field

The utility model relates to the technical field of detection of shock insulation supports, in particular to a device for detecting tensile strength of a shock insulation support.

Background

Because the frequent earthquake at home and abroad causes the problem of safety and stability of the building, in order to resist the earthquake and reduce the adverse effect brought by load impact, the earthquake reduction and isolation technology has been developed, in numerous earthquake reduction and isolation measures, the earthquake reduction and isolation support plays an important role, and is widely applied to important structural members such as bridges, houses and the like, and under the action of load circulation, the long-term use of the earthquake reduction and isolation support can cause the performance degradation thereof, so that the earthquake reduction and isolation support needs to be detected regularly to determine the safe working state thereof, and the support mainly has the following problems:

(a) The vertical compressive rigidity and bearing capacity of the support are high, and the tensile rigidity and the tensile bearing capacity are low.

(b) The detection of the compressive strength is focused and the detection of the tensile strength is ignored.

(c) The existing tensile detection mainly comprises the steps of fixing a support with an upper pressing plate and a lower pressing plate respectively, is complex in operation, has limitation of detection means and methods, and has a certain difficulty in detecting tensile strength.

Disclosure of Invention

The utility model aims to solve the technical problems that: the method aims to solve the technical problem that the detection means and the detection method of the seismic isolation bearing are limited in the prior art. The utility model provides a tension detection device for a shock insulation support, which is characterized in that the shock insulation support is placed into a supporting device and a pressure conversion device, pressure is applied to the pressure conversion device, and the pressure is converted into a tensile force through force conversion, so that the purpose of tension detection of the shock insulation support can be realized. The technical scheme adopted for solving the technical problems is as follows: the utility model provides a shock insulation support tensile detection device for detect shock insulation support's tensile strength, shock insulation support has upper and lower two relative terminal surfaces, includes:

the support device is sleeved on the shock insulation support, the upper part of the support device is fixedly connected with the upper end face of the shock insulation support, and the lower part of the support device is arranged at intervals with the lower end face of the shock insulation support;

the pressure conversion device is sleeved on the shock insulation support, the lower part of the pressure conversion device is positioned between the shock insulation support and the lower part of the supporting device, the lower end face of the shock insulation support is fixedly connected with the lower end face of the pressure conversion device, and the upper part of the pressure conversion device is a bearing surface.

According to the tension detection device for the shock insulation support, the shock insulation support is placed into the support device and the pressure conversion device, pressure is applied to the pressure conversion device, the pressure is converted into the tensile force through force conversion, the purpose of tension detection of the shock insulation support can be achieved, the detection method is simple, operation is convenient, and detection of shock insulation supports with different sizes can be adapted.

Further, for convenience of use, the supporting device includes:

a base;

the first frames are arranged at intervals along the length direction of the base in sequence, the first frames are fixedly arranged above the base, and the shock insulation support is arranged on the first frames.

Further, in order to increase the stability of the device, the first frame body comprises a first transverse plate, a second transverse plate and a first longitudinal plate and a second longitudinal plate, wherein the first transverse plate and the second transverse plate are oppositely arranged, one end of the first longitudinal plate and one end of the second longitudinal plate are respectively connected with two ends of the first transverse plate, the other end of the first longitudinal plate and the other end of the second longitudinal plate are respectively connected with two ends of the second transverse plate, and the second transverse plate is fixedly arranged on the base.

Specifically, the up end of shock insulation support is fixed to be set up on first diaphragm, the preceding terminal surface of shock insulation support is fixed to be set up the upper portion of first vertical board, the rear end of shock insulation support is fixed to be set up the upper portion of second vertical board.

Further, in order to increase the stability of the device, a plurality of reinforcing ribs are arranged on the base and positioned between the adjacent second transverse plates.

Further, the pressure conversion device includes:

at least two second frameworks, two the second frameworks are arranged at intervals along the length direction of the shock insulation support, two the second frameworks are located below the pressure bearing surface, and two the second frameworks are fixedly connected with the pressure bearing surface.

Further, in order to increase the stability of the device, the second housing includes:

the device comprises a third transverse plate, a fourth transverse plate, a third longitudinal plate and a fourth longitudinal plate, wherein the third transverse plate and the fourth transverse plate are oppositely arranged, one end of the third longitudinal plate and one end of the fourth longitudinal plate are respectively connected with two ends of the third transverse plate, the other end of the third longitudinal plate and the other end of the fourth longitudinal plate are respectively connected with two ends of the fourth transverse plate, and the third transverse plate is fixedly connected with the bearing surface.

Specifically, the front end face of the shock insulation support is fixedly arranged on the third longitudinal plate, the rear end face of the shock insulation support is fixedly arranged on the fourth longitudinal plate, and the lower end face of the shock insulation support is fixedly connected with the fourth transverse plate through a flange ring.

Further, the flange surface of the flange ring is fixedly connected with the fourth transverse plate, and the lower end surface of the shock insulation support is fixedly connected with the ring surface opposite to the flange surface.

Further, for ease of installation, the flange ring is composed of two flange half rings.

The tension detection device for the shock insulation support has the beneficial effects that the shock insulation support is placed into the support device and the pressure conversion device, pressure is applied to the pressure conversion device, the pressure is converted into tension through force conversion, the shock insulation support is driven to pull downwards, the purpose of tension detection of the shock insulation support can be achieved, the detection method is simple, the operation is convenient, and the tension detection device can be suitable for detection of shock insulation supports with different sizes.

Drawings

The utility model will be further described with reference to the drawings and examples.

FIG. 1 is a schematic diagram of a shock-insulating support tensile testing device of the present utility model;

FIG. 2 is a schematic diagram of a pressure conversion device of the shock-insulating support tensile detection device of the present utility model;

FIG. 3 is a schematic diagram showing the cooperation of the support device and the shock-insulating support of the shock-insulating support tensile detection device of the utility model.

In the figure:

10. a shock insulation support; 11. an upper end surface; 13. a front end face; 20. a support device; 21. a base; 211. reinforcing ribs; 22. a first frame; 221. a first cross plate; 222. a second cross plate; 223. a first longitudinal plate; 224. a second longitudinal plate; 30. a pressure conversion device; 31. a pressure bearing surface; 32. a second frame; 321. a third cross plate; 322. a fourth cross plate; 323. a third longitudinal plate; 324. a fourth vertical plate; 33. a flange ring; 331. and a flange surface.

Detailed Description

The utility model will now be described in further detail with reference to the accompanying drawings. The drawings are simplified schematic representations which merely illustrate the basic structure of the utility model and therefore show only the structures which are relevant to the utility model.

In the description of the present utility model, it should be understood that the terms "center", "longitudinal", "lateral", "length", "width", "thickness", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", "clockwise", "counterclockwise", "axial", "radial", "circumferential", etc. indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings are merely for convenience in describing the present utility model and simplifying the description, and do not indicate or imply that the device or element being referred to must have a specific orientation, be configured and operated in a specific orientation, and therefore should not be construed as limiting the present utility model. Furthermore, features defining "first", "second" may include one or more such features, either explicitly or implicitly. In the description of the present utility model, unless otherwise indicated, the meaning of "a plurality" is two or more.

In the description of the present utility model, it should be noted that, unless explicitly specified and limited otherwise, the terms "mounted," "connected," and "connected" are to be construed broadly, and may be either fixedly connected, detachably connected, or integrally connected, for example; can be mechanically or electrically connected; can be directly connected or indirectly connected through an intermediate medium, and can be communication between two elements. The specific meaning of the above terms in the present utility model will be understood in specific cases by those of ordinary skill in the art.

As shown in fig. 1 to 3, a device for detecting the tensile strength of a shock-absorbing support 10, the shock-absorbing support 10 having two opposite end surfaces, including: a support device 20 and a pressure conversion device 30.

The supporting device 20 is sleeved on the shock insulation support 10, the upper part of the supporting device 20 is fixedly connected with the upper end face 11 of the shock insulation support 10, the lower part of the supporting device 20 is arranged at intervals with the lower end face of the shock insulation support 10, the pressure conversion device 30 is sleeved on the shock insulation support 10, the lower part of the pressure conversion device 30 is positioned between the shock insulation support 10 and the lower part of the supporting device 20, the lower end face of the shock insulation support 10 is fixedly connected with the lower end face of the pressure conversion device 30, and the upper part of the pressure conversion device 30 is a pressure bearing surface 31.

According to the vibration isolation support tensile detection device, the vibration isolation support 10 is placed into the supporting device 20 and the pressure conversion device 30, pressure is applied to the pressure bearing surface 31 at the upper part of the pressure conversion device 30, the vibration isolation support 10 is driven to pull downwards through force conversion, the pressure is converted into tensile force, the purpose of tension detection of the vibration isolation support 10 can be achieved, the detection method is simple, operation is convenient, and detection of the vibration isolation support 10 with different sizes can be adapted.

According to one embodiment of the present utility model, as shown in fig. 3, the supporting means 20 includes: the base 21 and a plurality of first frame bodies 22, a plurality of first frame bodies 22 are arranged at intervals along the length direction of the base 21 in sequence, the plurality of first frame bodies 22 are fixedly arranged above the base 21, and the shock insulation support 10 is arranged on the plurality of first frame bodies 22, and in the utility model, the number of the first frame bodies 22 is four.

In the present utility model, the plurality of first frames 22 each include a first transverse plate 221 and a second transverse plate 222 which are oppositely disposed, and a first longitudinal plate 223 and a second longitudinal plate 224 which are oppositely disposed, wherein one end of the first longitudinal plate 223 and one end of the second longitudinal plate 224 are respectively connected to two ends of the first transverse plate 221, the other end of the first longitudinal plate 223 and the other end of the second longitudinal plate 224 are respectively connected to two ends of the second transverse plate 222, the second transverse plate 222 is fixedly disposed on the base 21, and the first transverse plate 221, the second transverse plate 222, the first longitudinal plate 223 and the second longitudinal plate 224 are surrounded to form a rectangular first frame 22.

According to an embodiment of the present utility model, the upper end face 11 of the shock insulation support 10 is fixedly disposed on the first transverse plate 221, the front end face 13 of the shock insulation support 10 is fixedly disposed on the upper portion of the first longitudinal plate 223, and the rear end face of the shock insulation support 10 is fixedly disposed on the upper portion of the second longitudinal plate 224.

According to an embodiment of the present utility model, a plurality of reinforcing ribs 211 are disposed on the base 21 and between the adjacent second transverse plates 222, and the reinforcing ribs 211 fix the plurality of second transverse plates 222, thereby increasing the overall stability of the detection device.

In the present utility model, as shown in fig. 2, the pressure conversion device 30 includes: the two second frames 32, the two second frames 32 are arranged at intervals along the length direction of the shock insulation support 10, the two second frames 32 are located below the pressure bearing surface 31, and the two second frames 32 are fixedly connected with the pressure bearing surface 31.

In the present utility model, the second housing 32 includes: the third transverse plate 321, the fourth transverse plate 322, the third longitudinal plate 323 and the fourth longitudinal plate 324 which are oppositely arranged, one end of the third longitudinal plate 323 and one end of the fourth longitudinal plate 324 are respectively connected with two ends of the third transverse plate 321, the other end of the third longitudinal plate 323 and the other end of the fourth longitudinal plate 324 are respectively connected with two ends of the fourth transverse plate 322, the third transverse plate 321 is fixedly connected with the pressure bearing surface 31, and the third transverse plate 321, the fourth transverse plate 322, the third longitudinal plate 323 and the fourth longitudinal plate 324 encircle the rectangular second frame 32.

According to an embodiment of the present utility model, the front end face 13 of the shock absorbing support 10 is fixedly disposed on the third vertical plate 323, the rear end face of the shock absorbing support 10 is fixedly disposed on the fourth vertical plate 324, the lower end face of the shock absorbing support 10 is fixedly connected to the fourth horizontal plate 322 through the flange ring 33, and the lower end face of the shock absorbing support 10 and the fourth horizontal plate 322 are connected to each other through the flange ring 33, so that the area of the fixed contact between the shock absorbing support 10 and the pressure conversion device 30 can be increased.

In the present utility model, the flange surface 331 of the flange ring 33 is fixedly connected to the fourth cross plate 322, and the lower end surface of the shock insulation support 10 is fixedly connected to the annular surface opposite to the flange surface 331.

In the present utility model, the flange ring 33 is composed of two flange half rings in order to be able to facilitate installation.

According to the vibration isolation support tensile detection device, the vibration isolation support 10 is placed into the supporting device 20 and the pressure conversion device 30, pressure is applied to the pressure bearing surface 31 at the upper part of the pressure conversion device 30, the vibration isolation support 10 is driven to pull downwards through force conversion, the pressure is converted into tensile force, the purpose of tension detection of the vibration isolation support 10 can be achieved, the detection method is simple, operation is convenient, and detection of the vibration isolation support 10 with different sizes can be adapted.

With the above-described preferred embodiments according to the present utility model as an illustration, the above-described descriptions can be used by persons skilled in the relevant art to make various changes and modifications without departing from the scope of the technical idea of the present utility model. The technical scope of the present utility model is not limited to the description, but must be determined as the scope of the claims.

Claims (10)

1. The utility model provides a shock insulation support tensile detection device for detect the tensile strength of shock insulation support (10), shock insulation support (10) have upper and lower two relative terminal surfaces, its characterized in that includes:

the support device (20) is sleeved on the shock insulation support (10), the upper part of the support device (20) is fixedly connected with the upper end face (11) of the shock insulation support (10), and the lower part of the support device (20) is arranged at intervals with the lower end face of the shock insulation support (10);

the pressure conversion device (30), the pressure conversion device (30) cover is established on shock insulation support (10), the lower part of pressure conversion device (30) is located shock insulation support (10) with support device (20) lower part between, shock insulation support (10) lower terminal surface with the lower terminal surface fixed connection of pressure conversion device (30), the upper portion of pressure conversion device (30) is pressure-bearing surface (31).

2. The shock-absorbing support tensile testing device according to claim 1, wherein the supporting means (20) comprises:

a base (21);

the vibration isolation support comprises a plurality of first frame bodies (22), wherein the plurality of first frame bodies (22) are sequentially arranged at intervals along the length direction of a base (21), the plurality of first frame bodies (22) are fixedly arranged above the base (21), and the vibration isolation support (10) is arranged on the plurality of first frame bodies (22).

3. The vibration isolation support tensile detection device according to claim 2, wherein the plurality of first frames (22) comprise a first transverse plate (221) and a second transverse plate (222) which are oppositely arranged, and a first longitudinal plate (223) and a second longitudinal plate (224) which are oppositely arranged, one end of the first longitudinal plate (223) and one end of the second longitudinal plate (224) are respectively connected with two ends of the first transverse plate (221), the other end of the first longitudinal plate (223) and the other end of the second longitudinal plate (224) are respectively connected with two ends of the second transverse plate (222), and the second transverse plate (222) is fixedly arranged on the base (21).

4. A shock-insulating support tensile testing device according to claim 3, wherein an upper end face (11) of the shock-insulating support (10) is fixedly arranged on the first transverse plate (221), a front end face (13) of the shock-insulating support (10) is fixedly arranged on the upper portion of the first longitudinal plate (223), and a rear end face of the shock-insulating support (10) is fixedly arranged on the upper portion of the second longitudinal plate (224).

5. A device for detecting the tensile strength of a shock-insulating support according to claim 3, characterized in that a plurality of reinforcing ribs (211) are arranged on the base (21) and between the adjacent second transverse plates (222).

6. The shock-absorbing support tensile testing device according to claim 4, wherein said pressure conversion device (30) comprises:

at least two second frameworks (32), two second frameworks (32) are arranged at intervals along the length direction of the shock insulation support (10), two second frameworks (32) are located below the pressure bearing surface (31), and two second frameworks (32) are fixedly connected with the pressure bearing surface (31).

7. The shock-absorbing support tensile testing device according to claim 6, wherein the second frame (32) comprises:

the device comprises a third transverse plate (321) and a fourth transverse plate (322) which are oppositely arranged, and a third longitudinal plate (323) and a fourth longitudinal plate (324) which are oppositely arranged, wherein one end of the third longitudinal plate (323) and one end of the fourth longitudinal plate (324) are respectively connected with two ends of the third transverse plate (321), the other end of the third longitudinal plate (323) and the other end of the fourth longitudinal plate (324) are respectively connected with two ends of the fourth transverse plate (322), and the third transverse plate (321) is fixedly connected with the pressure bearing surface (31).

8. The device for detecting the tensile strength of the shock-insulating support according to claim 7, wherein the front end surface (13) of the shock-insulating support (10) is fixedly arranged on the third vertical plate (323), the rear end surface of the shock-insulating support (10) is fixedly arranged on the fourth vertical plate (324), and the lower end surface of the shock-insulating support (10) is fixedly connected with the fourth transverse plate (322) through a flange ring (33).

9. The device for detecting the tensile strength of the shock-insulating support according to claim 8, wherein the flange surface (331) of the flange ring (33) is fixedly connected with the fourth transverse plate (322), and the lower end surface of the shock-insulating support (10) is fixedly connected with the opposite annular surface of the flange surface (331).

10. The device for detecting the tensile strength of a shock-insulating support according to claim 9, characterized in that said flange ring (33) consists of two flange half rings.