CN219201117U - Jacking simulation structure for steel strand testing tool - Google Patents

Abstract

The application relates to a jacking simulation structure for steel strand wires test fixture belongs to steel strand wires test field, and it includes the control assembly who is connected with the test jig, and control assembly is connected with the steel strand wires body, and one side that control assembly is close to the test jig is equipped with the supporting seat, and the supporting seat is connected with the test jig through adjusting part. The adjusting part conveniently adjusts the distance between the control part and the steel strand body so that the control part can control the steel strand body to move more stably, and meanwhile, under the action of the adjusting part, the step of changing the control part in different travel ranges by an operator is reduced, and the efficiency of detecting the steel strand body by the operator is improved.

Description

Jacking simulation structure for steel strand testing tool

Technical Field

The application relates to the field of steel strand wires test, in particular to a jacking simulation structure for a steel strand wires test fixture.

Background

The steel strand is a steel product formed by twisting a plurality of steel wires, and a galvanized layer, a zinc-aluminum alloy layer, an aluminum-clad layer, a copper-clad layer, epoxy resin and the like can be added on the surface of the carbon steel according to requirements. Steel strands are commonly used for messenger wires, guys, reinforcement cores, etc.

In the related art, an operator applies a steel strand to a photovoltaic bracket to connect two adjacent photovoltaic panels. Before an operator uses the steel strand, the operator needs to place the steel strand on a strength test tool for testing. The strength test fixture mainly comprises a test frame, an anchorage device for fixing two ends of a steel strand and a linear driving mechanism for jacking the steel strand, wherein the linear driving mechanism is fixed on the test frame through bolts, and the output end of the linear driving mechanism is fixed with the steel strand through a clamping plate. An operator uses an anchorage device to fix the two ends of the steel strand on the test frame respectively, then fixes the photovoltaic panel on the steel strand, then uses a bolt to fix the linear driving mechanism on the test frame, and then uses a clamping plate to fix the output end of the linear driving mechanism with the steel strand. The operator starts the linear driving mechanism, and the linear driving mechanism drives the steel stranded wires and the photovoltaic plates to move up and down so as to simulate the working states of the photovoltaic plates and the steel stranded wires, and accordingly structural strength of the steel stranded wires is judged.

Aiming at the related technology, the inventor finds that when an operator tests steel strands with different sizes, the operator needs to measure the distances between the steel strands and the test frame in advance, then selects linear driving mechanisms with different travel ranges, and then uses the bolt linear driving mechanisms to fix the linear driving mechanisms on the test frame, so that the operation is complicated, and the improvement is needed.

Disclosure of Invention

In order to improve the problem, the application provides a jacking simulation structure for a steel strand testing tool.

The application provides a steel strand wires test fixture is with jacking analog structure adopts following technical scheme:

the jacking simulation structure for the steel strand testing tool comprises a control assembly connected with a testing frame, wherein the control assembly is connected with a steel strand body, a supporting seat is arranged on one side, close to the testing frame, of the control assembly, and the supporting seat is connected with the testing frame through an adjusting assembly.

Through adopting above-mentioned technical scheme, operating personnel fixes control assembly on the supporting seat, will use adjusting part to adjust the distance between control assembly and the steel strand wires body again, after the regulation is accomplished, operating personnel fixes control assembly and steel strand wires body mutually again to control assembly comparatively stably controls the steel strand wires body and removes, simultaneously, under adjusting part's effect, for the distance between operating personnel regulation control assembly and the steel strand wires body provides convenience.

Preferably, the adjusting assembly comprises a plurality of adjusting rods, each adjusting rod is correspondingly arranged at four corners of the supporting seat, a plurality of adjusting holes are formed in the test frame, each adjusting rod correspondingly slides in each adjusting hole, one end of each adjusting rod is connected with the supporting seat through a nut, and the other end of each adjusting rod is connected with the test frame through a nut

Through adopting above-mentioned technical scheme, when need adjusting the distance between control assembly and the steel strand wires body, operating personnel control supporting seat removes, the supporting seat removes and mobilizes each regulation pole and remove, after the regulation is accomplished, operating personnel reuse nut will adjust the both ends of pole respectively with supporting seat and test jig mutually fixed, accomplish the regulation of the distance between control assembly and the steel strand wires body this moment, so that control assembly is comparatively stable to control the steel strand wires body follow-up, the step of operating personnel change control assembly has been reduced simultaneously, the convenience of operating personnel detection steel strand wires body has been improved.

Preferably, the control assembly comprises a linear driving mechanism, the linear driving mechanism is arranged on the supporting seat along the vertical direction, and the output end of the linear driving mechanism is connected with the steel strand body through the connecting assembly.

Through adopting above-mentioned technical scheme, operating personnel fixes sharp actuating mechanism on the supporting seat, and the distance between sharp actuating mechanism and the steel strand wires body is adjusted to the rethread adjusting part, and rethread coupling assembling is fixed with the steel strand wires body mutually, and operating personnel can use sharp actuating mechanism control steel strand wires body reciprocates this moment, provides convenience for operating personnel's simulation steel strand wires body's behavior.

Preferably, the connecting assembly comprises a first connecting plate and a second connecting plate, the first connecting plate is arranged at the output end of the linear driving mechanism, the second connecting plate is arranged at one side, far away from the linear driving mechanism, of the first connecting plate, the steel strand body is arranged between the first connecting plate and the second connecting plate, the first connecting plate and the second connecting plate are all in butt joint with the steel strand body, and the first connecting plate and the second connecting plate are connected through bolts.

Through adopting above-mentioned technical scheme, operating personnel fixes first connecting plate on linear drive mechanism's output for first connecting plate and steel strand wires body looks butt, operating personnel places the second connecting plate on the steel strand wires body again, and reuse bolt is fixed first connecting plate and second connecting plate mutually, accomplishes the connection between steel strand wires body and the linear drive mechanism this moment, thereby provides convenience for the quality of operating personnel test steel strand wires body.

Preferably, a first connecting groove is formed in one side, close to the second connecting plate, of the first connecting plate, a second connecting groove is formed in one side, close to the first connecting plate, of the second connecting plate, the first connecting groove and the second connecting groove are matched and form a clamping space, and the steel strand body is arranged in the clamping space.

Through adopting above-mentioned technical scheme, after operating personnel fixes first connecting plate and second connecting plate mutually, the steel strand wires body is in the centre gripping space that first spread groove and second spread groove formed, at this moment under the effect of first spread groove and second spread groove, increased the area of contact between first connecting plate and second connecting plate and the steel strand wires body, improved the spacing ability of first connecting plate and second connecting plate to the steel strand wires body to linear drive mechanism measures the steel strand wires body comparatively steadily.

Preferably, the adjusting assembly further comprises an adjusting seat and a plurality of adjusting columns, the adjusting seat is arranged on the test frame through the supporting frame, the adjusting seat is arranged on one side, close to the test frame, of the supporting seat, a plurality of adjusting grooves are formed in one side, close to the test frame, of the adjusting seat along the vertical direction, one adjusting column correspondingly slides in each adjusting groove, one side, far away from the adjusting seat, of each adjusting column is connected with the supporting seat, and an adjusting piece for controlling synchronous movement of each adjusting column is arranged in the adjusting seat.

Through adopting above-mentioned technical scheme, when needs are adjusted the distance between sharp drive structure and the steel strand wires body, operating personnel starts the regulating part, and the regulating part drives each adjusting column synchronous movement to control sharp drive mechanism and be close to or keep away from the steel strand wires body and remove, at this moment under the effect of regulating part, realized the function that each adjusting column moved in step, improved the stability when operating personnel adjusted the distance between sharp drive mechanism and the steel strand wires body on the one hand, on the other hand improved the degree of accuracy that operating personnel detected the steel strand wires body.

Preferably, the adjusting part comprises a control rod and a driving gear, an adjusting space is reserved between the adjusting seat and the test frame, a control groove is formed in one side, close to the test frame, of the adjusting seat, the control rod is arranged in the control groove along the vertical direction, the control rod is rotationally connected in the control groove, the driving gear is coaxially arranged on the control rod, a connecting column is rotationally connected in each adjusting groove, a yielding groove is formed in each adjusting column, the connecting columns are in threaded connection with the corresponding yielding grooves, and the connecting columns are all extended into the control groove and are coaxially provided with driven gears which are meshed with the driving gear.

Through adopting above-mentioned technical scheme, when needs are adjusted the distance between sharp actuating mechanism and the steel strand wires body, the operation rotates the control lever, the control lever drives the driving gear and rotates, the driving gear drives each driven gear and rotates, each driven gear drives the spliced pole that corresponds again and rotates, at this moment under the effect of adjustment tank, each spliced pole drives the spliced pole that corresponds and removes, at this moment under the cooperation of driving gear and each driven gear, the synchronous movement of each spliced pole has been realized, the stability when having improved the operating personnel and adjusted sharp actuating mechanism position, the possibility that the position emergence skew between sharp actuating mechanism and the steel strand wires body is caused to each spliced pole displacement distance difference has been reduced, thereby the precision when operating personnel detects the steel strand wires body has been improved.

Preferably, the control groove is connected with an adjusting plate in a sliding manner, the control rod is connected to one side, close to the test frame, of the adjusting plate in a rotating manner, the adjusting plate is connected with an adjusting seat through a fixing assembly, and each connecting column extends out of the adjusting seat and is coaxially provided with a rotating disc.

Through adopting above-mentioned technical scheme, when needs are adjusted alone adjusting the post, operating personnel promotes the control lever towards the direction of keeping away from the test frame, and the control lever drives driving gear and regulating plate and moves towards the direction of keeping away from the test frame, after driving gear and each driven gear separation, operating personnel can be through rotating the rolling disc that corresponds in order to adjust alone adjusting the post to the different detection conditions of adaptation.

Preferably, a level gauge is arranged on each of the four side walls of the supporting seat.

Through adopting above-mentioned technical scheme, operating personnel accessible spirit level observes the levelness of supporting seat, has reduced the possibility that exists from the angle difference between straight line actuating mechanism and the steel strand wires body to further improved the degree of accuracy that operating personnel detected the steel strand wires body.

In summary, the present application includes at least one of the following beneficial technical effects:

1. through setting up adjusting part, adjusting part makes things convenient for operating personnel to adjust the distance between sharp actuating mechanism and the steel strand wires body, has reduced the step of operating personnel's change sharp actuating mechanism of different strokes on the one hand, on the other hand makes sharp actuating mechanism comparatively steadily control the steel strand wires body to the degree of accuracy that operating personnel detected the steel strand wires body has been improved;

2. the clamping space formed by the first connecting groove and the second connecting groove increases the contact area between the steel strand body and the first connecting plate and the second connecting plate, improves the limit capability of the first connecting plate and the second connecting plate on the steel strand body, further improves the stability of the linear driving mechanism for controlling the steel strand body, and further improves the accuracy of detecting the steel strand body by operators;

3. through setting up adjusting column and regulating part, each adjusting column synchronous movement of regulating part control has improved the stability when operating personnel adjusts the distance between sharp actuating mechanism and the steel strand wires body, has reduced the possibility that there is the angle difference between sharp actuating mechanism and the steel strand wires body.

Drawings

FIG. 1 is a schematic overall structure of a first embodiment of the present application;

FIG. 2 is an enlarged schematic view of the portion A in FIG. 1;

FIG. 3 is a schematic structural diagram showing a positional relationship between an adjusting assembly and a test rack according to a second embodiment of the present disclosure;

FIG. 4 is an enlarged schematic view of the portion B in FIG. 3;

fig. 5 is a schematic structural diagram of a second embodiment of the present application for embodying a positional relationship between an adjusting seat and a supporting frame;

FIG. 6 is a schematic structural diagram showing a positional relationship between an adjusting component and a fixing component according to a second embodiment of the present disclosure;

fig. 7 is an enlarged schematic view of the portion C in fig. 6.

Reference numerals illustrate: 1. a test rack; 11. an adjustment aperture; 12. adjusting the space; 2. a control assembly; 21. a linear driving mechanism; 3. a support base; 4. an adjustment assembly; 41. an adjusting rod; 42. an adjusting seat; 421. an adjustment tank; 422. a control groove; 423. a connecting column; 424. dovetail-shaped sliding grooves; 425. a waist-shaped hole; 43. an adjusting column; 431. a relief groove; 432. dovetail-shaped sliding blocks; 44. an adjusting member; 441. a control lever; 442. a drive gear; 45. a driven gear; 46. a limiting disc; 47. an adjusting plate; 5. a connection assembly; 51. a first connection plate; 511. a first connection groove; 52. a second connecting plate; 521. a second connecting groove; 53. a clamping space; 6. a steel strand body; 7. a support frame; 8. a level gauge; 9. a fixing assembly; 91. and fixing the column.

Detailed Description

The present application is described in further detail below in conjunction with figures 1-7.

Embodiment one:

the embodiment of the application discloses a jacking simulation structure for a steel strand testing tool. Referring to fig. 1 and 2, a jacking simulation structure for steel strand wires test fixture, including the control assembly 2 that test frame 1 is connected, control assembly 2 includes linear drive mechanism 21, and linear drive mechanism 21 is close to one side of test frame 1 and is fixed with supporting seat 3, and one side that linear drive mechanism 21 kept away from supporting seat 3 is connected with steel strand wires body 6 through coupling assembling 5, and supporting seat 3 is connected with test frame 1 through adjusting part 4.

Referring to fig. 1 and 2, the linear driving mechanism 21 is provided as an electric cylinder in the embodiment of the present application.

The adjusting assembly 4 comprises a plurality of adjusting rods 41, in the embodiment of the application, four adjusting rods 41 are arranged, and the four adjusting rods 41 are respectively fixed at four corners of the supporting seat 3. Four adjusting holes 11 matched with the adjusting rods 41 are formed in the test frame 1, one adjusting rod 41 corresponds to each adjusting hole 11, each adjusting rod 41 is slidably connected to the corresponding adjusting hole 11, one end of each adjusting rod 41 is fixed with the supporting seat 3 through a nut, and the other end of each adjusting rod 41 is fixed with the test frame 1 through a nut.

The connection assembly 5 includes a first connection plate 51 and a second connection plate 52, the first connection plate 51 is fixed on the output end of the electric cylinder, the second connection plate 52 is disposed on a side of the first connection plate 51 away from the electric cylinder, and the second connection plate 52 is fixed with the first connection plate 51 by bolts. The steel strand body 6 is disposed between the first connecting plate 51 and the second connecting plate 52, and the steel strand body 6 abuts against the first connecting plate 51 and the second connecting plate 52.

After the electric cylinder is fixed on the supporting seat 3 by an operator, the supporting seat 3 is moved by the operator, the supporting seat 3 is moved to drive the adjusting rods 41 to move so as to adjust the distance between the supporting seat 3 and the steel strand body 6, the supporting seat 3 is further driven by the electric cylinder to move close to or away from the steel strand body 6, after the distance between the electric cylinder and the steel strand body 6 is adjusted by the operator, the adjusting rods 41 are limited by using nuts by the operator, two ends of the adjusting rods 41 are respectively fixed with the supporting seat 3 and the testing frame 1, and at the moment, the supporting seat 3 and each adjusting rod 41 provide support for the electric cylinder so that the electric cylinder can subsequently drive the steel strand body 6 to move.

After the distance between the electric cylinder and the steel strand body 6 is adjusted, the first connecting plate 51 is abutted against the steel strand body 6, an operator abuts against the second connecting plate 52 on the steel strand body 6, and the second connecting plate 52 is fixed with the first connecting plate 51 by using bolts, so that the connection between the electric cylinder and the steel strand body 6 is completed. At this time, under the action of the first connecting plate 51 and the second connecting plate 52, the connection stability between the electric cylinder and the steel strand body 6 is improved, thereby improving the accuracy of the subsequent operator when detecting the steel strand body 6.

Referring to fig. 1 and 2, in order to enhance the limiting effect of the first and second connection plates 51 and 52 on the strand body 6, a first connection groove 511 is formed at a side of the first connection plate 51 adjacent to the second connection plate 52, a second connection groove 521 is formed at a side of the second connection plate 52 adjacent to the first connection plate 51, the strand body 6 is disposed in the first and second connection grooves 511 and 521, and the strand body 6 is abutted against the groove bottom of the first connection groove 511 and the groove bottom of the second connection groove 521, and the first and second connection grooves 511 and 521 are engaged and form a clamping space 53 for clamping the strand body 6. At this time, under the action of the clamping space 53 formed by the cooperation of the first connecting groove 511 and the second connecting groove 521, the connection stability between the electric cylinder and the steel strand body 6 is further improved, thereby further improving the accuracy of detecting the steel strand body 6 by the operator.

The implementation principle of the first embodiment of the application is as follows: the distance between supporting seat 3 and steel strand wires body 6 is adjusted to operating personnel's use adjusting part 4 to the distance between adjustment straight line actuating mechanism 21 and the steel strand wires body 6 has improved the stability when follow-up straight line actuating mechanism 21 control steel strand wires body 6 removes on the one hand, has reduced the step of operating personnel's change straight line actuating mechanism 21 of different strokes on the other hand, has improved the convenience that operating personnel detected steel strand wires body 6.

Embodiment two:

referring to fig. 3 and 4, the first embodiment of the present application is different from the first embodiment in that: in order to improve the stability of the operator when adjusting the distance between the linear driving mechanism 21 and the steel strand body 6, the adjusting assembly 4 further comprises an adjusting seat 42 and a plurality of adjusting columns 43, wherein the adjusting seat 42 is arranged on one side of the supporting seat 3, which is close to the test stand 1, and the adjusting seat 42 is fixed on the test stand 1 through the supporting frame 7. One side of the adjusting seat 42, which is close to the supporting seat 3, is provided with a plurality of adjusting grooves 421, each adjusting groove 421 is correspondingly connected with an adjusting column 43 in a sliding manner, one end of the adjusting column 43, which is far away from the adjusting seat 42, is connected with the supporting seat 3, and an adjusting piece 44 for controlling each adjusting column 43 to synchronously move is arranged in the adjusting seat 42.

Referring to fig. 3 and 5, an adjusting space 12 is provided between the adjusting seat 42 and the test rack 1, and a control slot 422 is provided at a side of the adjusting seat 42 near the test rack 1, and an adjusting member 44 is provided in the control slot 422.

Referring to fig. 4 and 5, connecting posts 423 are rotatably connected in the vertical direction in each adjusting groove 421, yielding grooves 431 are respectively provided in the vertical direction at one end of each adjusting post 43, which is close to the adjusting seat 42, and each connecting post 423 is respectively in threaded connection with a corresponding yielding groove 431. The adjusting member 44 includes a control rod 441 and a driving gear 442, the control rod 441 is disposed along a vertical direction and rotates in the control slot 422, the driving gear 442 is disposed in the control slot 422 and coaxially fixed on the control rod 441, each connecting post 423 extends into the control slot 422 and coaxially fixes the driven gear 45, and each driven gear 45 is meshed with the driving gear 442.

Referring to fig. 6 and 7, in order to reduce the possibility of the driven gear 45 being separated from the driving gear 442, two limiting plates 46 disposed opposite to each other are coaxially fixed to the connecting post 423, one limiting plate 46 is disposed in the adjusting groove 421 and abuts against the inner wall of the adjusting groove 421, and the other limiting plate 46 is disposed in the control groove 422 and abuts against the inner wall of the control groove 422.

When the distance between the linear driving mechanism 21 and the steel strand body 6 needs to be adjusted, an operator rotates the control rod 441, the control rod 441 drives the driving gear 442 to rotate, the driving gear 442 drives each driven gear 45 to rotate, the driven gear 45 drives the corresponding connecting column 423 to rotate, at the moment, under the limiting effect of the adjusting groove 421, the connecting column 423 drives the corresponding adjusting column 43 to move, the function of synchronous movement of the adjusting column 43 is achieved, and therefore stability of the operator when the operator moves the linear driving mechanism 21 is improved, and convenience is provided for the follow-up operator to detect the steel strand body 6.

Referring to fig. 7, in order to further improve the stability of the moving of the adjusting posts 43, each adjusting post 43 is fixed with a dovetail sliding block 432, and the inner wall of the adjusting slot 421 corresponding to each adjusting post 43 is provided with a dovetail sliding slot 424, and in the process of rotating the connecting post 423, the dovetail sliding block 432 and the dovetail sliding slot 424 further provide a limit for the adjusting post 43, so that the connecting post 423 relatively stably drives the corresponding adjusting post 43 to move.

Referring to fig. 6, in order to intuitively observe the levelness of the supporting seat 3, a level meter 8 is fixed on four side walls of the supporting seat 3, and at this time, under the action of the level meter 8, an operator can observe the levelness of the supporting seat 3 so as to determine the position accuracy between the linear driving mechanism 21 and the steel strand body 6.

Referring to fig. 6 and 7, the control slot 422 is slidably connected with the adjusting plate 47, the control lever 441 is rotatably connected to one side of the adjusting plate 47 near the test stand 1, the adjusting plate 47 is fixed to the adjusting seat 42 by the fixing assembly 9, and each connecting post 423 extends into the adjusting space 12 and is coaxially fixed with a rotating disc.

The fixing component 9 comprises fixing columns 91, two opposite waist-shaped holes 425 are formed in the adjusting seat 42 along the vertical direction, the two waist-shaped holes 425 are communicated with the control groove 422, the fixing columns 91 are arranged in two and are respectively fixed on two opposite side walls of the adjusting plate 47, the fixing columns 91 extend into the corresponding waist-shaped holes 425 and slide along the waist-shaped holes 425, and the fixing columns 91 are fixed with the adjusting seat 42 through nuts.

When the operator observes that the levelness of the supporting seat 3 deviates, the operator moves the control rod 441 towards the direction away from the test frame 1, the control rod 441 drives the driving gear 442 and the adjusting plate 47 to move towards the direction away from the test frame 1, the adjusting plate 47 drives the fixing column 91 to move along the waist-shaped hole 425, when the driving gear 442 is separated from the driven gear 45, the operator fixes the adjusting column 43 and the adjusting seat 42 by using nuts, at the moment, the operator can rotate the corresponding rotating disc to control the corresponding connecting column 423 to rotate, and the connecting column 423 drives the adjusting column 43 at the corresponding position to move, so that the supporting seat 3 is in a flatter position, and convenience is provided for the supporting seat 3 to stably support the linear driving mechanism 21.

The implementation principle of the second embodiment of the application is as follows: the operator uses the adjusting piece 44 to control the synchronous movement of each adjusting column 43, so that the stability of the operator when adjusting the distance between the linear driving mechanism 21 and the steel strand body 6 is improved, and the subsequent linear driving mechanism 21 can control the steel strand body 6 to move more stably.

The foregoing are all preferred embodiments of the present application, and are not intended to limit the scope of the present application in any way, therefore: all equivalent changes in structure, shape and principle of this application should be covered in the protection scope of this application.

Claims (9)

1. A jacking simulation structure for a steel strand testing tool is characterized in that: the test rack comprises a control assembly (2) connected with the test rack (1), the control assembly (2) is connected with a steel strand body (6), a supporting seat (3) is arranged on one side, close to the test rack (1), of the control assembly (2), and the supporting seat (3) is connected with the test rack (1) through an adjusting assembly (4).

2. The jacking simulation structure for a steel strand test fixture according to claim 1, wherein: the adjusting assembly (4) comprises a plurality of adjusting rods (41), each adjusting rod (41) is correspondingly arranged at four corners of the supporting seat (3), a plurality of adjusting holes (11) are formed in the test frame (1), each adjusting rod (41) correspondingly slides in each adjusting hole (11), one end of each adjusting rod (41) is connected with the supporting seat (3) through a nut, and the other end of each adjusting rod is connected with the test frame (1) through a nut.

3. The jacking simulation structure for a steel strand test fixture according to claim 2, wherein: the control assembly (2) comprises a linear driving mechanism (21), the linear driving mechanism (21) is arranged on the supporting seat (3) along the vertical direction, and the output end of the linear driving mechanism (21) is connected with the steel strand body (6) through the connecting assembly (5).

4. The jacking simulation structure for a steel strand test fixture according to claim 3, wherein: the connecting assembly (5) comprises a first connecting plate (51) and a second connecting plate (52), the first connecting plate (51) is arranged at the output end of the linear driving mechanism (21), the second connecting plate (52) is arranged on one side, far away from the linear driving mechanism (21), of the first connecting plate (51), the steel strand body (6) is arranged between the first connecting plate (51) and the second connecting plate (52), the first connecting plate (51) and the second connecting plate (52) are all in butt joint with the steel strand body (6), and the first connecting plate (51) and the second connecting plate (52) are connected through bolts.

5. The jacking simulation structure for the steel strand testing fixture of claim 4, wherein: the steel strand clamping device is characterized in that a first connecting groove (511) is formed in one side, close to the second connecting plate (52), of the first connecting plate (51), a second connecting groove (521) is formed in one side, close to the first connecting plate (51), of the second connecting plate (52), the first connecting groove (511) and the second connecting groove (521) are matched and form a clamping space (53), and the steel strand body (6) is arranged in the clamping space (53).

6. The jacking simulation structure for a steel strand test fixture according to claim 1, wherein: the adjusting assembly (4) further comprises an adjusting seat (42) and a plurality of adjusting columns (43), the adjusting seat (42) is arranged on the test frame (1) through the supporting frame (7), the adjusting seat (42) is arranged on one side, close to the test frame (1), of the supporting seat (3), a plurality of adjusting grooves (421) are formed in one side, close to the test frame (1), of the adjusting seat (42) in a vertical direction, one adjusting column (43) correspondingly slides in each adjusting groove (421), one side, far away from the adjusting seat (42), of each adjusting column (43) is connected with the supporting seat (3), and an adjusting piece (44) for controlling synchronous movement of each adjusting column (43) is arranged in the adjusting seat (42).

7. The jacking simulation structure for the steel strand testing fixture of claim 6, wherein: the utility model provides an adjusting part (44) is including control lever (441) and driving gear (442), there is regulation space (12) between regulation seat (42) and test frame (1), one side that regulation seat (42) is close to test frame (1) is equipped with control groove (422), control lever (441) set up in control groove (422) along vertical direction, control lever (441) rotates to be connected in control groove (422), driving gear (442) coaxial setting is on control lever (441), each all rotate in regulation groove (421) to be connected with a spliced pole (423), each all offer one and give way groove (431) on regulation post (43), each spliced pole (423) all threaded connection is in corresponding giving way groove (431), each spliced pole (423) all extends to in control groove (422) and is equipped with a driven gear (45) coaxial, each driven gear (45) all meshes with driving gear (442).

8. The jacking simulation structure for the steel strand testing fixture of claim 7, wherein: the control groove (422) is internally and slidably connected with an adjusting plate (47), the control rod (441) is rotatably connected to one side, close to the test frame (1), of the adjusting plate (47), the adjusting plate (47) is connected with an adjusting seat (42) through a fixing assembly (9), and each connecting column (423) extends out of the adjusting seat (42) and is coaxially provided with a rotating disc.

9. The jacking simulation structure for the steel strand testing fixture of claim 8, wherein: four side walls of the supporting seat (3) are respectively provided with a level meter (8).

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