CN219777372U - Bearing forging intensity detection device - Google Patents

Abstract

The utility model discloses a bearing forging strength detection device, which belongs to the technical field of forging detection, wherein a detection base is moved to the middle part of an annular forging, an electric hydraulic rod is controlled to extend to drive a sleeve to move downwards, three slide columns are extruded by three connecting rods in the process of downwards moving the sleeve to enable the three slide columns to be far away from each other, the slide columns drive rollers to be in close contact with the inner wall of the forging through pressure sensors, after the applied pressure reaches a preset value, the electric hydraulic rod stops working, a motor is controlled to work, the motor drives a driven gear to rotate through a driving gear, the driven gear drives a connecting shaft and the detection base to rotate through a fixed shaft, the detection base drives three rollers to roll on the inner wall of the forging, the pressure value is monitored in real time through the pressure sensor, the pressure application range of the rotating rollers to the inner wall of the forging is not limited, the detection area is comprehensive, and the accuracy of bearing forging strength detection is ensured.

Description

Bearing forging intensity detection device

Technical Field

The utility model belongs to the technical field of forge piece detection, and particularly relates to a bearing forge piece strength detection device.

Background

The bearing is an important part in modern mechanical equipment, and has the main functions of supporting a mechanical rotating body, reducing the friction coefficient in the motion process of the mechanical rotating body and ensuring the rotation precision of the mechanical rotating body, and the strength of a bearing forging piece is usually required to be detected in the bearing processing.

At present, in the bearing forging detection process, the bearing forging is usually subjected to multi-point pressure, the pressure application range is limited, the detection area is incomplete, the omission condition is easy to occur, and the accuracy of the bearing forging strength detection is difficult to ensure, so that the bearing forging strength detection device is provided for solving the problems.

Disclosure of Invention

In order to overcome the defects, the utility model provides the bearing forging strength detection device, which solves the problems that in the bearing forging detection process, the bearing forging is usually subjected to multi-point pressure, the pressure application range is limited, the detection area is incomplete, the omission condition is easy to occur, and the accuracy of the bearing forging strength detection is difficult to ensure.

In order to achieve the above purpose, the present utility model provides the following technical solutions: the utility model provides a bearing forging intensity detection device, includes the support frame, the top fixedly connected with top cap of support frame, the top is fixed with two electric putter in the top cap, and two electric putter runs through the support frame and is connected with the slide, be equipped with drive assembly on the slide, drive assembly's bottom fixedly connected with connecting axle, the bottom of connecting axle is equipped with detects the base, the connecting axle is equipped with intensity tester outward, the top is fixed with electronic hydraulic stem in the connecting axle, the bottom of electronic hydraulic stem is connected with the sleeve, the inside sliding connection of sleeve has the slide bar, the bottom of slide bar and the interior fixed connection of detection base, be equipped with three detection component outward of sleeve, three detection component runs through the detection base.

As a further aspect of the utility model: the driving assembly comprises a fixed shaft, the top end of the fixed shaft is fixedly connected with a driven gear, and a driving gear is meshed with the driven gear.

As a further aspect of the utility model: the driving gear is connected with a motor, the motor is fixed with the sliding plate, a shaft sleeve is sleeved outside the fixed shaft, and the shaft sleeve is clamped on the sliding plate.

As a further aspect of the utility model: the detection base is in a conical design, slide ways are arranged on two sides in the support frame, and the slide plates are connected in the two slide ways in a sliding mode.

As a further aspect of the utility model: the detection assembly comprises a sliding column, a sliding sleeve is sleeved outside the sliding column, the sliding sleeve is clamped on the detection base, one end, away from the detection base, of the sliding column is fixedly connected with a pressure sensor, and one end of the pressure sensor is fixedly provided with a roller.

As a further aspect of the utility model: one end of the pressure sensor is connected with a wire, the wire penetrates through the detection base and is connected with the strength tester, the other end of the sliding column is hinged with a connecting rod through a pin shaft, the top end of the connecting rod is hinged with the sleeve through the pin shaft, and the sliding column is in an I-shaped design.

Compared with the prior art, the utility model has the beneficial effects that:

1. this bearing forging intensity detection device, through removing the detection base to annular forging middle part, control electric hydraulic stem extension makes it drive sleeve downwardly moving, the sleeve is three travellers of in-process through three connecting rod extrusion that downwardly moves, make three traveller keep away from each other, the traveller then drives gyro wheel and forging inner wall in close contact through pressure sensor, after the pressure that applys reaches the default, electric hydraulic stem stop work, control motor work, the motor passes through the driving gear and drives driven gear rotation, driven gear passes through the fixed axle and drives the connecting axle and detect the base rotation, detect the base then through three traveller drive three gyro wheels at forging inner wall roll, and monitor the pressure value by pressure sensor in real time, apply pressure to the forging through rotatory gyro wheel, make the scope of exerting pressure to the forging inner wall unrestricted, and detection area is comprehensive, guarantee bearing forging intensity detection's accuracy.

2. This bearing forging intensity detection device carries out spacingly through setting up the slide bar to the sleeve, improves the sleeve and drives the stability that the slide column removed through the connecting rod, and sleeve downwardly moving then pushes down the connecting rod, makes three gyro wheel keep away from each other, and electronic hydraulic stem shrink makes the sleeve upwards move, makes three gyro wheel be close to each other, through the synchronous regulation to three gyro wheel position, satisfies the detection work to different specification bearing forgings, makes the device application scope wide.

Drawings

FIG. 1 is a schematic view of a three-dimensional structure of the present utility model;

FIG. 2 is a schematic view of the connection of the driving assembly and the connecting shaft according to the present utility model;

FIG. 3 is a schematic view of a cross section of a test base according to the present utility model;

FIG. 4 is a schematic diagram of a detecting assembly according to the present utility model;

in the figure: 1. a support frame; 2. a top cover; 3. an electric push rod; 4. a slide plate; 5. a drive assembly; 501. a fixed shaft; 502. a driven gear; 503. a shaft sleeve; 6. a drive gear; 7. a motor; 8. a connecting shaft; 9. an intensity tester; 10. an electric hydraulic rod; 11. a sleeve; 12. a slide bar; 13. detecting a base; 14. a detection assembly; 141. a spool; 142. a sliding sleeve; 143. a pressure sensor; 144. a roller; 145. a wire; 146. a connecting rod; 15. and a slideway.

Detailed Description

The technical scheme of the patent is further described in detail below with reference to the specific embodiments.

As shown in fig. 1-4, the present utility model provides a technical solution: the utility model provides a bearing forging intensity detection device, including support frame 1, the top fixedly connected with top cap 2 of support frame 1, top is fixed with two electric putter 3 in the top cap 2, two electric putter 3 run through support frame 1 and are connected with slide 4, be equipped with drive assembly 5 on the slide 4, drive assembly 5 includes fixed axle 501, the top fixedly connected with driven gear 502 of fixed axle 501, the meshing has driving gear 6 on the driven gear 502, be connected with motor 7 on the driving gear 6, motor 7 is fixed with slide 4, the fixed axle 501 overcoat has axle sleeve 503, axle sleeve 503 joint is on slide 4, it is rotatory to drive driven gear 502 through driving gear 6, driven gear 502 passes through fixed axle 501 and drives connecting axle 8 and detect base 13 rotation, detect base 13 then drive three gyro wheel 144 through three slide 141 and roll at the forging inner wall, the detection area is comprehensive, guarantee bearing forging intensity detection's accuracy.

The detection base 13 is of a conical design, the slide ways 15 are arranged on two sides in the support frame 1, the slide plates 4 are slidably connected in the two slide ways 15, and the slide ways 15 are arranged to limit the slide plates 4, so that the slide plates cannot deviate from the positions, the movement stability of the detection base 13 is improved, and meanwhile, the detection accuracy is guaranteed.

The bottom fixedly connected with connecting axle 8 of drive assembly 5, the bottom of connecting axle 8 is equipped with detects base 13, and connecting axle 8 is equipped with intensity tester 9 outward, and the top is fixed with electronic hydraulic stem 10 in the connecting axle 8, and the bottom of electronic hydraulic stem 10 is connected with sleeve 11, and sleeve 11 inside sliding connection has slide bar 12, carries out spacingly to sleeve 11 through setting up slide bar 12, improves sleeve 11 and drives the stability that the strut 141 removed through connecting rod 146.

The bottom of slide bar 12 and detect bottom fixed connection in the base 13, sleeve 11 is equipped with three detection component 14 outward, three detection component 14 runs through and detects the base 13, detection component 14 includes the traveller 141, the traveller 141 overcoat has sliding sleeve 142, sliding sleeve 142 joint is on detecting the base 13, the one end fixedly connected with pressure sensor 143 of traveller 141 keeping away from detecting the base 13, pressure sensor 143's one end is fixed with gyro wheel 144, drive three gyro wheels 144 through three traveller 141 and roll at the forging inner wall, and monitor the pressure value in real time by pressure sensor 143, exert pressure to the forging through rotatory gyro wheel 144, make the scope of exerting pressure to the forging inner wall unrestricted.

One end of the pressure sensor 143 is connected with a wire 145, the wire 145 penetrates through the detection base 13 to be connected with the strength tester 9, the other end of the sliding column 141 is hinged with a connecting rod 146 through a pin shaft, the top end of the connecting rod 146 is hinged with the sleeve 11 through the pin shaft, the sliding column 141 is of an I-shaped design, the wire 145 on the pressure sensor 143 can penetrate through the detection base 13 to be connected with the strength tester 9, meanwhile, the detection base 13 can be communicated with the outside, heat can be rapidly dissipated, the sleeve 11 moves downwards to press the connecting rod 146 through the mutual matching between the sleeve 11, the connecting rod 146 and the sliding column 141, the three rollers 144 are far away from each other, the sleeve 11 moves upwards due to shrinkage of the electric hydraulic rod 10, the three rollers 144 are close to each other, and the detection work of bearing forgings with different specifications is met through synchronous adjustment of the positions of the three rollers 144.

The working principle of the utility model is as follows:

when the intelligent detection device is used, the bearing forgings are arranged below the detection base 13, the two electric push rods 3 are controlled to extend, the sliding plate 4 drives the detection base 13 to move downwards through the driving component 5 and the connecting shaft 8, three rollers 144 on the detection base 13 are located in the bearing forgings, the electric hydraulic rods 10 are controlled to extend to drive the sleeves 11 to move downwards, the three sliding columns 141 are extruded through the three connecting rods 146 in the process of downwards moving the sleeves 11, the three sliding columns 141 are far away from each other, the sliding columns 141 drive the rollers 144 to be in close contact with the inner wall of the forgings through the pressure sensor 143, after the applied pressure reaches a preset value, the electric hydraulic rods 10 stop working, the electric hydraulic rods can be observed and debugged through the strength tester 9, the motor 7 is controlled to work, the driven gear 502 is driven to rotate through the driving gear 6, the driven gear 502 drives the connecting shaft 8 and the detection base 13 through the fixing shaft 501, the three rollers 144 are driven by the three sliding columns 141 to roll on the inner wall of the forgings, and the pressure value is monitored in real time through the pressure sensor 143.

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 can be understood by those of ordinary skill in the art in a specific case.

While the preferred embodiments of the present patent have been described in detail, the present patent is not limited to the above embodiments, and various changes may be made without departing from the spirit of the present patent within the knowledge of one of ordinary skill in the art.

Claims (6)

1. Bearing forging intensity detection device, including support frame (1), its characterized in that: the top fixedly connected with top cap (2) of support frame (1), top is fixed with two electric putter (3) in top cap (2), and two electric putter (3) run through support frame (1) and are connected with slide (4), be equipped with drive assembly (5) on slide (4), the bottom fixedly connected with connecting axle (8) of drive assembly (5), the bottom of connecting axle (8) is equipped with detects base (13), be equipped with intensity tester (9) outward on connecting axle (8), the top is fixed with electric hydraulic stem (10) in connecting axle (8), the bottom of electric hydraulic stem (10) is connected with sleeve (11), sleeve (11) inside sliding connection has slide bar (12), the bottom of slide bar (12) and detect base (13) in bottom fixed connection, be equipped with three detection component (14) outward in sleeve (11), three detection component (14) run through and detect base (13).

2. The bearing forging strength detection device as recited in claim 1, wherein: the driving assembly (5) comprises a fixed shaft (501), a driven gear (502) is fixedly connected to the top end of the fixed shaft (501), and a driving gear (6) is meshed with the driven gear (502).

3. The bearing forging strength detection device as recited in claim 2, wherein: the driving gear (6) is connected with a motor (7), the motor (7) is fixed with the sliding plate (4), a shaft sleeve (503) is sleeved outside the fixed shaft (501), and the shaft sleeve (503) is clamped on the sliding plate (4).

4. The bearing forging strength detection device as recited in claim 1, wherein: the detection base (13) is in a conical design, sliding ways (15) are formed in two sides in the support frame (1), and the sliding plate (4) is connected in the two sliding ways (15) in a sliding mode.

5. The bearing forging strength detection device as recited in claim 1, wherein: the detection assembly (14) comprises a sliding column (141), a sliding sleeve (142) is sleeved outside the sliding column (141), the sliding sleeve (142) is clamped on the detection base (13), one end, away from the detection base (13), of the sliding column (141) is fixedly connected with a pressure sensor (143), and one end of the pressure sensor (143) is fixedly provided with a roller (144).

6. The bearing forging strength testing device as recited in claim 5, wherein: one end of the pressure sensor (143) is connected with a wire (145), the wire (145) penetrates through the detection base (13) and is connected with the strength tester (9), the other end of the sliding column (141) is hinged with a connecting rod (146) through a pin shaft, the top end of the connecting rod (146) is hinged with the sleeve (11) through the pin shaft, and the sliding column (141) is in an I-shaped design.