CN215811503U - A automatic test piece conveyor for structure anti-seismic test - Google Patents

Abstract

The utility model provides an automatic test piece conveying device for a structural anti-seismic test, which comprises: the upper surface of the detection platform is a plane; the sliding rail component is provided with a sliding rail part and a sliding block part, the sliding rail part is arranged on the detection platform, one end of the sliding rail part is positioned on the detection platform, the other end of the sliding rail part extends to the outer side of the detection platform, and the sliding block part is slidably arranged on the sliding rail part; the mounting plate is fixed on the sliding block part and used for transferring the prefabricated part; the backup pad, the backup pad passes through flexible subassembly to be installed on testing platform, and the quantity of backup pad is two, and two backup pads are located slide rail assembly's length direction's both sides respectively. The technical effect of the scheme is as follows: the height of the prefabricated part in the vertical direction can be conveniently adjusted, and therefore the top of the prefabricated part can be conveniently clamped and fixed by the external clamping mechanism.

Description

A automatic test piece conveyor for structure anti-seismic test

Technical Field

The utility model relates to the field of civil engineering subject experimental instrument equipment, in particular to an automatic test piece conveying device for a structural earthquake resistance test.

Background

In the mechanical property detection test of the prefabricated part, the prefabricated part is generally installed by firstly hoisting the prefabricated part to the position near the upper support of the test bed by a travelling crane, and the prefabricated part cannot be hoisted in place at one time due to the blockage of the upper girder. The prefabricated member is manually pushed to the upper part of the support, and after falling down, the prefabricated member is pried a little by a crow bar and is slowly moved to the center of the support. After the detection test is finished, the prefabricated parts are tied up, a person holds the prefabricated parts to slowly lift the prefabricated parts, and the prefabricated parts are lifted away after being moved to the position under the lifting hook. The operation is difficult and has certain potential safety hazard. Meanwhile, for some prefabricated parts with higher height, the upper ends of the prefabricated parts are often provided with some supporting pieces, so that the prefabricated parts can meet the requirements of field operation only by adjusting the height of the prefabricated parts in real time, however, no corresponding technical scheme in the prior art can be used for reference, and therefore a new technical scheme is needed to solve the technical problems.

SUMMERY OF THE UTILITY MODEL

In order to solve the technical problem, the utility model provides an automatic test piece conveying device for a structural anti-seismic test, wherein a slide rail assembly drives a mounting plate to move and transfers a prefabricated part to an appointed station, and at the moment, a telescopic assembly works and drives a supporting plate to move upwards so as to jack up the prefabricated part; the height of the prefabricated part in the vertical direction is adjustable, wherein the prefabricated part is an inverted T-shaped part, the transverse part of the prefabricated part is installed on the installation plate, the longitudinal part of the prefabricated part is vertically arranged, the top of the longitudinal part of the prefabricated part is fixed by arranging a clamping mechanism, and the height of the prefabricated part is adjusted to facilitate the fixation of the prefabricated part.

Specifically, the utility model provides an automatic test piece conveying device for a structural seismic test, which comprises:

the upper surface of the detection platform is a plane;

the slide rail assembly is provided with a slide rail part and a slide block part, the slide rail part is arranged on the detection platform, one end of the slide rail part is positioned on the detection platform, the other end of the slide rail part extends to the outer side of the detection platform, and the slide block part is arranged on the slide rail part in a sliding manner;

the mounting plate is fixed on the sliding block part and used for transferring the prefabricated part;

the backup pad, the backup pad is passed through telescopic component and is installed on the testing platform, the quantity of backup pad is two, and two the backup pad is located respectively slide rail assembly's length direction's both sides.

The technical effect of the scheme is as follows: the slide rail assembly drives the mounting plate to move and transfers the prefabricated part to a designated station, and the telescopic assembly works at the moment and drives the supporting plate to move upwards so as to jack up the prefabricated part; the height of the prefabricated part in the vertical direction is adjustable, wherein the prefabricated part is an inverted T-shaped part, the transverse part of the prefabricated part is installed on the installation plate, the longitudinal part of the prefabricated part is vertically arranged, the top of the longitudinal part of the prefabricated part is fixed by arranging a clamping mechanism, and the height of the prefabricated part is adjusted to facilitate the fixation of the prefabricated part.

Preferably, the detection platform is provided with a holding tank for holding the telescopic assembly, and an opening surface of the holding tank is flush with the upper surface of the detection platform.

The technical effect of the scheme is as follows: be convenient for hold flexible subassembly, when flexible subassembly shrink to holding tank in, the height of backup pad is lower, makes things convenient for prefabricated component to install in the backup pad more.

Preferably, the telescopic assembly comprises:

the mounting end of the oil cylinder is fixedly provided with a bottom plate, the output end of the oil cylinder is fixed on the supporting plate, and the bottom plate is fixed in the accommodating groove;

and one end of the sliding guide rod is fixed on the bottom plate, and the other end of the sliding guide rod is fixed on the supporting plate.

The technical effect of the scheme is as follows: a particular solution is proposed to find a telescopic assembly which is able to smoothly bring the support plate in a vertical movement.

Preferably, the sliding guide includes:

the sleeve is vertically fixed on the mounting plate, and the upper end face of the sleeve is provided with a mounting hole extending downwards;

and the upper end of the sliding rod is fixed on the mounting plate, and the lower end of the sliding rod is slidably arranged in the mounting hole of the sleeve.

The scheme has the advantages that: a sliding guide rod is provided.

Preferably, the slide rail assembly further has a driving assembly, the driving assembly including:

more than two chain wheels are arranged on the detection platform through chain wheel supports;

the chain is arranged on the chain wheel and is fixed with the mounting plate through a connecting piece;

the driving part is provided with an output shaft capable of rotating, and the output shaft and the chain wheel are coaxially fixed.

The driving part can be a servo motor, and can drive the mounting plate to move when the servo motor rotates, so that the device has the advantage of simple structure and long stroke, has lower cost relative to a linear motor, and is more suitable for the test field of building structures.

Preferably, the detection platform is provided with a first strip-shaped groove and a second strip-shaped groove, the length direction of the first strip-shaped groove and the length direction of the second strip-shaped groove are consistent with the length direction of the slide rail part, the first strip-shaped groove is used for accommodating the chain, and the second strip-shaped groove is used for accommodating the slide rail part;

the detection platform is further provided with a mounting seat, a mounting groove is formed in the mounting seat and used for mounting the driving part, and the mounting groove is communicated with the first strip-shaped groove and the second strip-shaped groove respectively.

The technical effect of the scheme is as follows: for concealing the chain and the drive element.

Preferably, the device further comprises an electric control cabinet, and the electric control cabinet is used for controlling the sliding rail assembly to work.

Preferably, the electric control cabinet is provided with a control hand disc.

Preferably, the hydraulic oil pump is further included and used for providing hydraulic oil for the oil cylinder.

Drawings

In order to more clearly illustrate the technical solutions in the embodiments of the present invention, the drawings used in the embodiments or the description of the prior art will be briefly described below.

FIG. 1 is a schematic structural diagram of a slide rail assembly in an automated specimen conveying apparatus for structural seismic testing according to the present embodiment;

FIG. 2 is a schematic diagram of the loading of prefabricated components by the automated specimen transport apparatus for structural seismic testing proposed in this embodiment;

FIG. 3 is a schematic view showing the construction of the prefabricated parts moved to the supporting plate according to the present embodiment;

fig. 4 is a schematic perspective view of the telescopic assembly of the present embodiment.

Wherein the reference numbers referred to in the figures are as follows:

11-a detection platform; 12-a slide rail assembly; 13-a slide rail portion; 14-a slider portion; 15-mounting a plate; 16-a support plate; 17-a telescopic assembly; 18-a holding tank; 19-oil cylinder; 20-a base plate; 21-a sleeve; 22-a slide bar; 23-a sprocket; 24-a chain; 25-a drive member; 26-a first bar-shaped groove; 27-a second strip groove; 28-an electric control cabinet; 29-control hand disc; 30-a hydraulic oil pump; 31-a mounting seat; 32-mounting grooves; 33-prefabricated parts.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings.

As shown in fig. 1 to 4, the present embodiment proposes an automated specimen conveying apparatus for structural seismic testing, including:

the upper surface of the detection platform 11 is a plane;

the slide rail assembly 12, the slide rail assembly 12 has a slide rail portion 13 and a slide block portion 14, the slide rail portion 13 is disposed on the detection platform 11, one end of the slide rail portion 13 is located on the detection platform 11, and the other end of the slide rail portion 13 extends to the outside of the detection platform 11, the slide block portion 14 is slidably disposed on the slide rail portion 13;

a mounting plate 15, the mounting plate 15 being fixed to the slider portion 14, and the mounting plate 15 being used for transporting the prefabricated part 33;

the supporting plates 16 are installed on the detection platform 11 through the telescopic assemblies 17, the number of the supporting plates 16 is two, and the two supporting plates 16 are respectively located on two sides of the sliding rail assembly 12 in the length direction.

The technical effect of the scheme is as follows: the slide rail assembly 12 drives the mounting plate 15 to move, the prefabricated part 33 is transferred to a designated station, and at the moment, the telescopic assembly 17 works and drives the support plate 16 to move upwards, so that the prefabricated part 33 is jacked up; this is advantageous in that the height of the prefabricated part 33 is adjustable in the vertical direction, wherein the prefabricated part 33 is an inverted T-shaped member, wherein the lateral portion of the prefabricated part 33 is mounted on the mounting plate 15, the longitudinal portion of the prefabricated part 33 is vertically disposed, and the top of the longitudinal portion of the prefabricated part 33 is fixed by providing a clamping mechanism, thereby facilitating the fixing of the prefabricated part 33 by adjusting the height of the prefabricated part 33.

As an implementation manner of this embodiment, the detection platform 11 is provided with a receiving groove 18 for receiving the telescopic assembly 17, and an opening surface of the receiving groove 18 is flush with an upper surface of the detection platform 11.

The technical effect of the scheme is as follows: the telescopic assembly 17 is conveniently accommodated, and when the telescopic assembly 17 is contracted into the accommodating groove 18, the height of the supporting plate 16 is lower, so that the prefabricated part 33 is more conveniently installed on the supporting plate 16.

As an embodiment of the present embodiment, the telescopic assembly 17 includes:

the mounting end of the oil cylinder 19 is fixed with a bottom plate 20, the output end of the oil cylinder 19 is fixed on the support plate 16, and the bottom plate 20 is fixed in the accommodating groove 18;

and one end of the sliding guide rod is fixed on the bottom plate 20, and the other end of the sliding guide rod is fixed on the support plate 16.

The technical effect of the scheme is as follows: a particular solution is proposed for a telescopic assembly 17 which allows to smoothly bring the support plate 16 in a vertical movement.

As an embodiment of this embodiment, the slide guide includes:

the sleeve 21 is vertically fixed on the mounting plate 15, and the upper end face of the sleeve 21 is provided with a mounting hole extending downwards;

and a sliding rod 22, wherein the upper end of the sliding rod 22 is fixed on the mounting plate 15, and the lower end of the sliding rod 22 is slidably arranged in the mounting hole of the sleeve 21.

The scheme has the advantages that: a sliding guide rod is provided.

Preferably, the slide rail assembly 12 also has a drive assembly comprising:

more than two chain wheels 23 are arranged on the detection platform 11 through chain wheel supports;

the chain 24 is arranged on the chain wheel 23, and the chain 24 is fixed with the mounting plate 15 through a connecting piece;

and a driving part 25, wherein the driving part 25 is provided with a rotatable output shaft, and the output shaft and the chain wheel 23 are coaxially fixed.

The driving part 25 can be a servo motor, and can drive the mounting plate 15 to move when the servo motor rotates, so that the structure is simple, the stroke is long, the cost is low compared with that of a linear motor, and the linear motor is suitable for the test field of building structures.

As an implementation manner of this embodiment, the detection platform 11 is provided with a first strip-shaped groove 26 and a second strip-shaped groove 27, the length direction of the first strip-shaped groove 26 and the length direction of the second strip-shaped groove 27 are the same as the length direction of the slide rail portion 13, the first strip-shaped groove 26 is used for accommodating the chain 24, and the second strip-shaped groove 27 is used for accommodating the slide rail portion 13;

the detection platform 11 is further provided with a mounting seat 31, the mounting seat 31 is provided with a mounting groove 32, the mounting groove 32 is used for mounting the driving component 25, and the mounting groove 32 is respectively communicated with the first strip-shaped groove 26 and the second strip-shaped groove 27.

The technical effect of the scheme is as follows: for concealing the chain 24 and the drive member 25.

As an implementation manner of this embodiment, the device further includes an electric control cabinet 28, and the electric control cabinet 28 is used for controlling the operation of the sliding rail assembly 12.

As an implementation manner of the present embodiment, the electric control cabinet 28 is provided with a control handwheel 29.

As an embodiment of the present embodiment, a hydraulic oil pump 30 is further included, and the hydraulic oil pump 30 is used for supplying hydraulic oil to the oil cylinder 19.

During operation, the prefabricated part 33 is placed on the mounting plate 15, then the electric control cabinet 28 is started, the driving part 25 drives the chain wheel 23 to rotate, the mounting plate 15 drives the prefabricated part 33 to move right above the supporting plate 16, then the oil cylinder 19 stretches, and drives the supporting plate 16 to move upwards and jack up the prefabricated part 33 to a certain height. Finally, the driving part 25 drives the mounting plate 15 to reset.

It will be apparent to those skilled in the art that various changes and modifications can be made without departing from the inventive concept thereof, and these changes and modifications can be made without departing from the spirit and scope of the utility model.

Claims (9)

1. The utility model provides an automatic test piece conveyor for structural seismic testing which characterized in that includes:

the detection platform (11), wherein the upper surface of the detection platform (11) is a plane;

the slide rail assembly (12), the slide rail assembly (12) has a slide rail portion (13) and a slide block portion (14), the slide rail portion (13) is arranged on the detection platform (11), one end of the slide rail portion (13) is located on the detection platform (11), the other end of the slide rail portion (13) extends to the outer side of the detection platform (11), and the slide block portion (14) is slidably arranged on the slide rail portion (13);

a mounting plate (15), wherein the mounting plate (15) is fixed on the sliding block part (14), and the mounting plate (15) is used for transporting prefabricated parts;

the support plate (16), install through flexible subassembly (17) backup pad (16) on detecting platform (11), the quantity of backup pad (16) is two, and two backup pad (16) are located respectively slide rail assembly (12)'s length direction's both sides.

2. The automated test piece conveying device for the structural seismic test is characterized in that the detection platform (11) is provided with a containing groove (18) for containing the telescopic assembly (17), and an opening surface of the containing groove (18) is flush with the upper surface of the detection platform (11).

3. The automated specimen transport apparatus for structural seismic testing according to claim 2, wherein the telescoping assembly (17) comprises:

the mounting end of the oil cylinder (19) is fixedly provided with a bottom plate (20), the output end of the oil cylinder (19) is fixed on the supporting plate (16), and the bottom plate (20) is fixed in the accommodating groove (18);

one end of the sliding guide rod is fixed on the bottom plate (20), and the other end of the sliding guide rod is fixed on the support plate (16).

4. The automated specimen transport apparatus for structural seismic testing according to claim 3, wherein the sliding guide comprises:

the sleeve (21) is vertically fixed on the mounting plate (15), and the upper end face of the sleeve (21) is provided with a mounting hole extending downwards;

the upper end of the sliding rod (22) is fixed on the mounting plate (15), and the lower end of the sliding rod (22) is slidably arranged in the mounting hole of the sleeve (21).

5. The automated specimen transport apparatus for structural seismic testing according to claim 1, wherein the slide assembly (12) further has a drive assembly comprising:

the more than two chain wheels (23) are arranged on the detection platform (11) through chain wheel supports;

the chain (24) is arranged on the chain wheel (23), and the chain (24) is fixed with the mounting plate (15) through a connecting piece;

a drive member (25), said drive member (25) having a rotatable output shaft, said output shaft and said sprocket (23) being coaxially fixed.

6. The automatic test piece conveying device for the structural earthquake-resistant test is characterized in that a first strip-shaped groove (26) and a second strip-shaped groove (27) are formed in the detection platform (11), the length directions of the first strip-shaped groove (26) and the second strip-shaped groove (27) are consistent with the length direction of the sliding rail part (13), the first strip-shaped groove (26) is used for accommodating the chain (24), and the second strip-shaped groove (27) is used for accommodating the sliding rail part (13);

still be provided with mount pad (31) on detection platform (11), be equipped with mounting groove (32) on mount pad (31), mounting groove (32) are used for the installation driver part (25), mounting groove (32) respectively with first bar groove (26) with second bar groove (27) link up.

7. The automated specimen transport apparatus for structural seismic testing according to claim 1, further comprising an electronic control cabinet (28), the electronic control cabinet (28) being configured to control operation of the slide assembly (12).

8. The automated specimen transport apparatus for structural seismic testing according to claim 7, characterized in that a control hand disc (29) is provided on the electronic control cabinet (28).

9. The automated test piece conveying device for the structural seismic test according to claim 3, further comprising a hydraulic oil pump (30), wherein the hydraulic oil pump (30) is used for providing hydraulic oil for the oil cylinder (19).

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