CN215492893U

CN215492893U - High toughness alloy steel hardness detection device based on special type processing

Info

Publication number: CN215492893U
Application number: CN202121809019.2U
Authority: CN
Inventors: 柏承业; 高曙刚; 王鹏飞; 吴祥; 尹欣杰
Original assignee: Changzhou Guanqun Electromechanical Technology Co ltd
Current assignee: Changzhou Guanqun Electromechanical Technology Co ltd
Priority date: 2021-08-04
Filing date: 2021-08-04
Publication date: 2022-01-11
Anticipated expiration: 2031-08-04

Abstract

The utility model discloses a hardness detection device for high-toughness alloy steel based on special processing, which comprises an operation table, wherein a side plate is fixed on the operation table, a top plate is fixed on the side plate, a first cylinder body is fixedly embedded in the top plate, an extrusion head is fixed on a piston rod of the first cylinder body, a pressure sensor is fixed on the operation table, a support plate is paved on the pressure sensor, a first plate body is placed on the support plate, the extrusion head is arranged in contact with the first plate body, and the pressure sensor is connected with a computer host through a data line and can observe pressure change in real time. Drive the extrusion head through first cylinder body and carry out the extrusion measurement to first panel body, can detect the withstand voltage effect of alloy steel, fall in the twinkling of an eye through the tup and can detect the impact-resistant impact effect in the twinkling of an eye of alloy steel to the impact of second panel body.

Description

High toughness alloy steel hardness detection device based on special type processing

Technical Field

The utility model belongs to the technical field of hardness detection for alloy steel, and particularly relates to a hardness detection device for high-toughness alloy steel based on special processing.

Background

The alloy steel is iron and carbon-free, and is added with other alloy elements, namely alloy steel, and a proper amount of one or more alloy elements are added on the basis of common carbon steel to form iron-carbon alloy.

According to the difference of the added elements and by adopting a proper processing technology, the high strength, high toughness, wear resistance, corrosion resistance, low temperature resistance and high temperature resistance can be obtained.

The hardness of the existing alloy steel needs to be detected after the production is finished, and if the hardness does not reach the standard, safety accidents are easily caused when the alloy steel is used in some practical important areas.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide a hardness detection device for high-toughness alloy steel based on special machining, which aims to solve the problem of detection of the hardness of the alloy steel.

In order to achieve the purpose, the utility model provides the following technical scheme: the utility model provides a based on hardness detection device for special type processing high tenacity alloy steel, includes the operation panel, be fixed with the curb plate on the operation panel, be fixed with the roof on the curb plate, fixed embedding has first cylinder body on the roof, be fixed with the extrusion head on the piston rod of first cylinder body, be fixed with pressure sensor on the operation panel, pressure sensor upper berth is equipped with the backup pad, first panel body has been put in the backup pad, the extrusion head sets up with the body contact of first panel, and pressure sensor passes through the data line and is connected with the computer mainframe, but the real-time observation pressure change.

Preferably, a second cylinder body is fixed on the supporting plate, clamping seats are fixed on a piston rod of the second cylinder body, the two clamping seats are arranged in contact with the first plate body, and the left position and the right position of the first plate body can be extruded and positioned.

Preferably, a threaded sleeve is fixedly embedded in the clamping seat, a threaded knob is arranged in the threaded sleeve in a threaded mode, a pressing plate in contact with the first plate body is fixed on the threaded knob, and the upper position and the lower position of the first plate body can be extruded and pressed tightly.

Preferably, still be fixed with the stand on the operation panel, be fixed with the diaphragm on the stand, the slip cover is equipped with the sliding sleeve on the stand, is fixed with the heavy object piece on the sliding sleeve, is fixed with the tup on the heavy object piece, can carry out the hammering test to the second panel body.

Preferably, be provided with the thread groove on the stand, the thread groove internal thread is provided with the screw pin, and the screw pin is hugged closely with the sliding sleeve contact, can be when not using the tup, can rise fixedly with the tup.

Preferably, a built-in sleeve is fixedly embedded in the transverse plate, a steel wire rope connected with the heavy object block penetrates through the built-in sleeve in a sliding mode, a fixed pulley is fixed on the transverse plate, the steel wire rope is connected with a handle through the fixed pulley, and the hammer head can be driven to move up and down by pulling the handle.

Preferably, be fixed with the board seat on the operation panel, placed the second panel body in the board seat, be fixed with the third cylinder body on the stand, be fixed with the spheroid on the third cylinder body, spheroid and second panel body extrusion contact can compress tightly to the second panel body and support the reality.

Compared with the prior art, the utility model has the beneficial effects that: drive the extrusion head through first cylinder body and carry out the extrusion measurement to first panel body, can detect the withstand voltage effect of alloy steel, fall in the twinkling of an eye through the tup and can detect the impact-resistant impact effect in the twinkling of an eye of alloy steel to the impact of second panel body.

Drawings

FIG. 1 is a schematic view of a first plate body according to the present invention;

FIG. 2 is a schematic view of the overall structure of the present invention;

FIG. 3 is an enlarged view of the utility model at a;

fig. 4 is an enlarged schematic view of the utility model at b.

In the figure: 1. an operation table; 11. a side plate; 12. a top plate; 13. an extrusion head; 14. a first cylinder; 15. a pressure sensor; 16. a support plate; 17. a first plate body; 2. a second cylinder; 21. a holder; 22. a threaded sleeve; 23. a threaded knob; 3. a column; 31. a transverse plate; 32. a sliding sleeve; 33. a heavy material block; 34. a hammer head; 4. a built-in sleeve; 41. a wire rope; 42. a fixed pulley; 43. a handle; 5. a plate base; 51. a second plate body; 52. a third cylinder; 53. a sphere.

Detailed Description

Referring to fig. 1 and 2, a hardness detection device for high-toughness alloy steel based on special processing comprises an operation table 1, a side plate 11 is fixed on the operation table 1, a top plate 12 is fixed on the side plate 11, a first cylinder 14 is fixedly embedded in the top plate 12, an extrusion head 13 is fixed on a piston rod of the first cylinder 14, a pressure sensor 15 is fixed on the operation table 1, a support plate 16 is laid on the pressure sensor 15, a first plate body 17 is placed on the support plate 16, the extrusion head 13 is in contact with the first plate body 17, and the pressure sensor 15 is connected with a computer host through a data line, so that pressure change can be observed in real time.

Referring to fig. 2, a second cylinder 2 is fixed on the supporting plate 16, a clamping seat 21 is fixed on a piston rod of the second cylinder 2, and the two clamping seats 21 are disposed in contact with the first plate body 17, so as to extrude and position the left and right positions of the first plate body 17.

Referring to fig. 2 and 3, a threaded sleeve 22 is fixedly embedded in the clamping seat 21, a threaded knob 23 is disposed in the threaded sleeve 22, and a pressing plate 24 contacting with the first plate body 17 is fixed on the threaded knob 23, so as to press and compact the upper and lower positions of the first plate body 17.

Referring to fig. 2, the operating table 1 is further fixed with an upright post 3, the upright post 3 is fixed with a transverse plate 31, the upright post 3 is sleeved with a sliding sleeve 32 in a sliding manner, the sliding sleeve 32 is fixed with a heavy object block 33, and the heavy object block 33 is fixed with a hammer 34 and can be used for performing hammering test on the second plate body 51.

Referring to fig. 2 and 4, a threaded groove 35 is formed in the upright column 3, a threaded pin 36 is arranged in the threaded groove 35, and the threaded pin 36 is in contact with the sliding sleeve 32 and can lift and fix the hammer 34 when the hammer 34 is not used.

Referring to fig. 2, the transverse plate 31 is fixedly embedded with the built-in sleeve 4, a steel wire rope 41 connected with the weight block 33 penetrates through the built-in sleeve 4 in a sliding manner, the transverse plate 31 is fixedly provided with a fixed pulley 42, the steel wire rope 41 is connected with a handle 43 through the fixed pulley 42, and the handle 43 is pulled to drive the hammer head 34 to move up and down.

Referring to fig. 2, a plate seat 5 is fixed on the operating table 1, a second plate body 51 is placed in the plate seat 5, a third cylinder 52 is fixed on the upright post 3, a sphere 53 is fixed on the third cylinder 52, and the sphere 53 is in contact with the second plate body 51 in a squeezing manner, so that the second plate body 51 can be pressed and compacted.

The working principle of the scheme is as follows: when the first plate body 17 needs to be subjected to pressure-resistant detection, the first plate body 17 is placed on the supporting plate 16, then the piston rod of the second cylinder body 2 stretches out and draws back, so that the clamping seats 21 on the two sides clamp the first plate body 17 to be clamped and positioned, the threaded knob 23 is rotated, the pressing plate 24 is driven by the threaded knob to extrude the first plate body 17 from top to bottom, then the piston rod of the first cylinder body 14 is pushed in, the extrusion head 13 can perform stamping detection on the first plate body 17, and the pressure sensor 15 can sense the vertical stamping.

When the second plate body 51 needs to be subjected to an impact test, the second plate body 51 is placed into the plate seat 5, then the piston rod of the third cylinder 52 is pushed forward, so that the ball 53 extrudes and supports the second plate body 51, then one worker holds the handle 43 to ensure that the position of the hammer head 34 is stable, and the other worker rotates the threaded pin 36 to separate the threaded pin from the threaded groove 35, so that the sliding sleeve 32 can be released, and the hammer head 34 can hammer the second plate body 51.

Claims

1. The utility model provides a based on high toughness of special type processing alloy steel is with hardness detection device, includes operation panel (1), its characterized in that: be fixed with curb plate (11) on operation panel (1), be fixed with roof (12) on curb plate (11), fixed embedding has first cylinder body (14) on roof (12), be fixed with extrusion head (13) on the piston rod of first cylinder body (14), be fixed with pressure sensor (15) on operation panel (1), pressure sensor (15) upper berth is equipped with backup pad (16), first panel body (17) have been put in backup pad (16), extrusion head (13) and first panel body (17) contact setting.

2. The special machining-based high-toughness alloy steel hardness detection device as claimed in claim 1, wherein: a second cylinder body (2) is fixed on the supporting plate (16), clamping seats (21) are fixed on a piston rod of the second cylinder body (2), and the two clamping seats (21) are arranged in contact with the first plate body (17).

3. The special machining-based high-toughness alloy steel hardness detection device as claimed in claim 2, wherein: the clamp seat (21) is fixedly embedded with a threaded sleeve (22), a threaded knob (23) is arranged in the threaded sleeve (22), and a pressing plate (24) in contact with the first plate body (17) is fixed on the threaded knob (23).

4. The special machining-based high-toughness alloy steel hardness detection device as claimed in claim 1, wherein: still be fixed with stand (3) on operation panel (1), be fixed with diaphragm (31) on stand (3), sliding sleeve is equipped with sliding sleeve (32) on stand (3), is fixed with heavy object piece (33) on sliding sleeve (32), is fixed with tup (34) on heavy object piece (33).

5. The special machining-based high-toughness alloy steel hardness detection device according to claim 4, characterized in that: the upright post (3) is provided with a thread groove (35), a thread pin (36) is arranged in the thread groove (35) in a threaded manner, and the thread pin (36) is in contact and clinging to the sliding sleeve (32).

6. The special machining-based high-toughness alloy steel hardness detection device according to claim 5, characterized in that: the transverse plate (31) is fixedly embedded with a built-in sleeve (4), a steel wire rope (41) connected with the heavy object block (33) penetrates through the built-in sleeve (4) in a sliding mode, a fixed pulley (42) is fixed on the transverse plate (31), and the steel wire rope (41) is connected with a handle (43) through the fixed pulley (42).

7. The special machining-based high-toughness alloy steel hardness detection device according to claim 6, characterized in that: a plate seat (5) is fixed on the operating table (1), a second plate body (51) is placed in the plate seat (5), a third cylinder body (52) is fixed on the upright post (3), a ball body (53) is fixed on the third cylinder body (52), and the ball body (53) is in extrusion contact with the second plate body (51).