CN213275167U - Steel strength detection device for building detection - Google Patents

Abstract

The utility model discloses a steel intensity detection device for building detection, including the support, top-down is provided with crossbeam and base in the support, and fixes being provided with the pneumatic cylinder on the crossbeam, and the cover that all slides in the crossbeam both ends is equipped with the lifter, and all overlaps on two lifters to be equipped with the one-level spring, and two lifters have the pressure boost plate that is connected with the pneumatic cylinder output jointly to weld. The utility model is provided with the ball screw driven by the motor, the nut of the ball screw is utilized to drive the slider to move horizontally through the traction rod, so that the mobile station connected with the slider through the steel cable can move horizontally on the guide table, and the guide rod and the secondary spring are utilized to provide guide limit for the guide table moving horizontally, thereby clamping and fixing the steel part on the guide table; the lifting rod and the first-stage spring which are connected in a sleeved mode are used for providing a guiding effect for the pressure increasing plate moving up and down, so that the pressure increasing plate moves down vertically under the driving of the hydraulic cylinder, and pressure is applied to steel materials to different degrees.

Description

Steel strength detection device for building detection

Technical Field

The utility model relates to a steel processing detects technical field, especially relates to a steel intensity detection device for building detection.

Background

Steel is the most common material component in production and life, and mainly plays a role in bearing and shaping protection, so that the requirement of a high standard on the strength and the hardness of the steel material is met.

In order to ensure that the strong hardness attribute of a steel component meets the requirement, related attributes must be detected before the steel component is used in the prior art, the traditional detection technology is difficult to limit and fix the steel with certain weight, so that the steel is extremely easy to generate elastic deformation and displacement falling accidents when being extruded by huge external force, the normal operation of detection work is not facilitated, and the safety threat to detection operators and related instruments is caused by forced movement of the steel more easily.

SUMMERY OF THE UTILITY MODEL

The utility model aims at solving the problem that is difficult to detect the strong hardness attribute of steel among the prior art, and the steel intensity detection device for building detection who provides.

In order to achieve the above purpose, the utility model adopts the following technical scheme:

a steel strength detection device for building detection comprises a support, wherein a cross beam, a guide table and a base are arranged in the support from top to bottom, a hydraulic cylinder is fixedly arranged on the cross beam, lifting rods are sleeved in two ends of the cross beam in a sliding manner, a primary spring is sleeved on each of the two lifting rods, a pressure increasing plate connected with the output end of the hydraulic cylinder is welded on each of the two lifting rods, a motor is fixedly arranged at the lower end of the guide table, a ball screw connected with the output end of the motor is rotatably arranged on the base, a nut is arranged on each ball screw, a sliding groove is formed in the base, a sliding block is sleeved in each sliding groove in a sliding manner, a traction rod is connected between each nut and each sliding block, a pulley is arranged at the lower end of the support, a moving table is sleeved on the guide table in a sliding manner, the sliding block is connected with a, and a secondary spring is fixedly sleeved on the guide rod.

Preferably, the hydraulic cylinder and the two lifting rods are arranged vertically, the fixed sleeve is arranged at the upper end of the lifting rod, the one-level spring is welded with the upper end of the cross beam, and the pressurizing plate welded with the lower end of the lifting rod is horizontally arranged between the cross beam and the guide table.

Preferably, the ball screw is vertically arranged between the guide table and the base, and the two sliding grooves are horizontally arranged on two sides of the ball screw.

Preferably, two ends of the traction rod are respectively connected with the nut and the sliding block in a rotating mode.

Preferably, the pulley is horizontally positioned between the guide table and the base.

Preferably, the guide rod is horizontally arranged between the cross beam and the guide table, and the free end of the secondary spring, which is far away from the moving table, is welded with the bracket.

Compared with the prior art, the utility model discloses possess following advantage:

1. the utility model discloses set up the ball screw by motor drive on the base, utilize the nut of ball screw to drive the slider horizontal migration through the traction lever, make the mobile station that is connected with the slider through the cable wire can carry out the horizontal migration on the guide table, thereby carry out the centre gripping to the steel part that is located on the guide table and fix; meanwhile, the guide rod and the secondary spring are used for providing guide limit for the guide table moving horizontally.

2. The utility model discloses set up the pressure boost board by pneumatic cylinder traction motion on the crossbeam to utilize the cover to establish the lifter of connection and one-level spring and provide the guide effect for the pressure boost board that reciprocates, thereby utilize the pressure boost board of lapse to exert pressure to the steel of rigidity.

To sum up, the utility model is provided with the ball screw driven by the motor, the nut of the ball screw is utilized to drive the slider to move horizontally through the traction rod, so that the mobile station connected with the slider through the steel cable can move horizontally on the guide table, and the guide rod and the secondary spring are utilized to provide guide limit for the guide table moving horizontally, thereby clamping and fixing the steel parts on the guide table; the lifting rod and the first-stage spring which are connected in a sleeved mode are used for providing a guiding effect for the pressure increasing plate moving up and down, so that the pressure increasing plate moves down vertically under the driving of the hydraulic cylinder, and pressure is applied to steel materials to different degrees.

Drawings

Fig. 1 is a schematic structural view of a steel strength detection device for building detection provided by the utility model;

fig. 2 is an enlarged schematic view of a part a of the structure of the steel strength detecting device for building detection provided by the utility model;

fig. 3 is the utility model provides a mobile station and guide bar connection structure sketch of steel intensity detection device for building detection.

In the figure: the device comprises a support 1, a cross beam 2, a guide table 3, a base 4, a hydraulic cylinder 5, a lifting rod 6, a primary spring 7, a pressure increasing plate 8, a motor 9, a ball screw 10, a nut 11, a sliding chute 12, a sliding block 13, a traction rod 14, a pulley 15, a mobile table 16, a steel cable 17, a guide rod 18 and a secondary spring 19.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments.

Referring to fig. 1-3, a steel strength detecting device for building detection comprises a support 1, a beam 2, a guide table 3 and a base 4 are arranged in the support 1 from top to bottom, a hydraulic cylinder 5 is fixedly arranged on the beam 2, the hydraulic cylinder 5 can adopt hydraulic equipment with model number of HANDA YGS 70X 30X 520, lifting rods 6 are slidably sleeved in two ends of the beam 2, a primary spring 7 is sleeved on each of the two lifting rods 6, the primary spring 7 is a tension spring and can play a role of buffering for the lifting rod 6 moving vertically downwards so as to ensure the stability of the downward movement of the pressure increasing plate 8, the two lifting rods 6 are welded with a pressure increasing plate 8 connected with the output end of the hydraulic cylinder 5, a motor 9 is fixedly arranged at the lower end of the guide table 3, the motor 9 is a servo motor with model number of HC-KFS13B, and a ball screw 10 connected with the output end of the motor 9 is rotatably arranged on the base 4, a nut 11 is arranged on the ball screw 10, the nut 11 moves up and down along with the rotation of the ball screw 10, a slide block 13 is drawn by a draw bar 17, a sliding groove 12 is arranged on the base 4, a sliding block 13 is sleeved in the sliding groove 12 in a sliding way, a traction rod 14 is connected between the nut 11 and the sliding block 13, a pulley 15 is arranged at the lower end of the bracket 1, and a moving platform 16 is slidably sleeved on the guide platform 3, the sliding block 13 pulls the moving platform 16 through a steel cable 17 in the horizontal moving process, so that the movable platform can move stably on the movable platform 3, the sliding block 13 is connected with a steel cable 17 through a pulley 15 and a movable platform 16, a guide rod 18 which is sleeved in the bracket 1 in a sliding way is welded on the movable platform 16, and a second-stage spring 19 is fixedly sleeved on the guide rod 18, the second-stage spring 19 is a tension spring, the two moving tables 16 are close to each other under the action of the tensile force thereof to clamp and fix the steel.

The hydraulic cylinder 5 and the two lifting rods 6 are all vertically arranged, the fixed sleeve is arranged on the one-level spring 7 at the upper end of each lifting rod 6 and welded with the upper end of the cross beam 2, the pressurizing plate 8 welded with the lower end of each lifting rod 6 is horizontally arranged between the cross beam 2 and the guide table 3, and the pressurizing plate 8 moving vertically downwards can repeatedly apply pressure to steel under the guide effect of the lifting rods 6.

The ball screw 10 is vertically arranged between the guide table 3 and the base 4, and two chutes 12 are horizontally arranged on two sides of the ball screw 10, and the sliding block 13 can be dragged and moved by the nut 11 moving up and down.

Two ends of the traction rod 14 are respectively connected with the nut 11 and the slide block 13 in a rotating way.

The pulley 15 is located horizontally between the guide table 3 and the base 4 to provide a supporting steering action for the cable 17.

The guide rod 18 is horizontally arranged between the cross beam 2 and the guide table 3, the free end of the second-stage spring 19, which is far away from the moving table 16, is welded with the bracket 1, and the moving table 16 can clamp and limit steel materials under the action of the tension of the second-stage spring 19.

The utility model discloses its functional principle is explained to following mode of operation of accessible:

controlling the motor 9 to be started, driving the ball screw 10 to rotate by the output end of the motor 9, and driving the nut 11 to vertically move upwards by the ball screw 10;

the nut 11 pulls the sliding block 13 through the traction rod 14, so that the sliding block 13 moves in the sliding groove 12, and pulls the steel cable 17, so that the steel cable 17 moves on the pulley 15;

the moving wire rope 17 pulls the moving table 16, so that the moving table 16 moves horizontally on the guide table 3;

the mobile station 16 drives the guide rod 18 to slide in the bracket 1 and stretches the secondary spring 19;

until the two moving tables 16 move to a proper distance, and placing steel between the two moving tables 16 to clamp and fix the steel;

the hydraulic cylinder 5 is controlled to be opened on the cross beam 2, the output end of the hydraulic cylinder 5 drives the pressure increasing plate 8 to vertically move downwards in the process of extending, and in the process, the lifting rod 6 moving downwards extrudes the primary spring 7, so that the primary spring 7 is forced to be condensed;

the pressurizing plate 8 can repeatedly apply pressure to the steel material with fixed position in the downward moving process.

The above, only be the concrete implementation of the preferred embodiment of the present invention, but the protection scope of the present invention is not limited thereto, and any person skilled in the art is in the technical scope of the present invention, according to the technical solution of the present invention and the utility model, the concept of which is equivalent to replace or change, should be covered within the protection scope of the present invention.

Claims (6)

1. A steel strength detection device for building detection comprises a support (1) and is characterized in that a cross beam (2), a guide table (3) and a base (4) are arranged in the support (1) from top to bottom, a hydraulic cylinder (5) is fixedly arranged on the cross beam (2), lifting rods (6) are sleeved in two ends of the cross beam (2) in a sliding mode, a primary spring (7) is sleeved on each of the two lifting rods (6), a pressure increasing plate (8) connected with the output end of the hydraulic cylinder (5) is welded on the two lifting rods (6) together, a motor (9) is fixedly installed at the lower end of the guide table (3), a ball screw (10) connected with the output end of the motor (9) is rotatably installed on the base (4), a nut (11) is installed on the ball screw (10), a sliding chute (12) is formed in the base (4), and a sliding block (13) slides in the sliding chute (12), be connected with traction lever (14) between nut (11) and slider (13), pulley (15) are installed to support (1) lower extreme, and sliding sleeve is equipped with mobile station (16) on guide table (3), slider (13) are connected with cable wire (17) through pulley (15) and mobile station (16), the welding has guide bar (18) that the slip cap was located in support (1) on mobile station (16), and fixed cover is equipped with second grade spring (19) on guide bar (18).

2. The steel strength detection device for building detection according to claim 1, wherein the hydraulic cylinder (5) and the two lifting rods (6) are vertically arranged, the fixed sleeve is arranged on a primary spring (7) at the upper end of the lifting rod (6) and welded with the upper end of the cross beam (2), and the pressure increasing plate (8) welded with the lower end of the lifting rod (6) is horizontally arranged between the cross beam (2) and the guide table (3).

3. The steel strength detecting device for building detection according to claim 2, wherein the ball screw (10) is vertically disposed between the guide table (3) and the base (4), and the two chutes (12) are horizontally disposed on both sides of the ball screw (10).

4. The steel strength detection device for building detection according to claim 1, wherein both ends of the drawbar (14) are rotatably connected to the nut (11) and the slider (13), respectively.

5. The steel strength detecting device for building inspection according to claim 1, wherein the pulley (15) is horizontally positioned between the guide table (3) and the base (4).

6. The steel strength detection device for building detection according to claim 5, wherein the guide rod (18) is horizontally arranged between the cross beam (2) and the guide table (3), and the free end of the secondary spring (19) far away from the moving table (16) is welded with the bracket (1).

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