CN222952140U - Prevent crooked flange hardness check out test set - Google Patents

Abstract

The utility model discloses anti-skew flange hardness detection equipment which comprises a mounting frame, a flange body, a Reed hardness detector and a detection mechanism, wherein a base is fixedly connected to the inner wall of the bottom of the mounting frame, a mounting plate is fixedly connected to the top of the base, a plurality of sliding holes are formed in one side of the mounting plate, a first sliding block is connected in a sliding mode in the sliding holes, a clamping rod is connected to one end of the first sliding block in a rotating mode, a plurality of motors are fixedly connected to the outer wall of the circumference of the mounting plate, a threaded rod is connected to the output end of each motor in a key mode, and the threaded rod is in threaded connection with the first sliding block. According to the flange body, the flange body is clamped on the bearing seat to support the flange body, and then the threaded rod is driven by the motor to rotate, so that the first sliding block is driven to move in the sliding hole, the clamping rod is driven to move, the clamping rod is further tensioned from the inside of the flange body, the flange body is fixed, and therefore deflection of the flange body during detection is prevented.

Description

Prevent crooked flange hardness check out test set

Technical Field

The utility model relates to the technical field of flange detection, in particular to anti-skew flange hardness detection equipment.

Background

When the flange is produced, the quality detection of the finished product is very important, wherein whether the hardness of the flange meets the standard is an important factor influencing the service life of the flange.

At present, when the hardness is detected, the existing flange is mostly detected by using a Richter hardness tester, but the flange plate is not easy to fix, so that a gap or skew is easily formed between the detection end and the flange, and the detection structure is not accurate enough, so that the detection effect of the hardness of the flange is affected.

Disclosure of utility model

The utility model aims to solve the defects that in the prior art, when the hardness of the existing flange is detected, the hardness of the flange is detected by using a Richter hardness tester, but the flange plate is not easy to fix, so that a gap or skew is easy to occur between a detection end and the flange, a detection structure is inaccurate, and the detection effect of the hardness of the flange is affected.

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

The utility model provides a prevent crooked flange hardness check out test set, includes mounting bracket, flange body, brinell hardness tester and detection mechanism, the bottom inner wall fixedly connected with base of mounting bracket, the top fixedly connected with mounting disc of base, one side of mounting disc is equipped with a plurality of slide holes, and the downthehole sliding connection of slide has first slider, and the one end rotation of first slider is connected with the clamping lever, the circumference outer wall fixedly connected with of mounting disc a plurality of motors, the output key connection of motor have the threaded rod, and the threaded rod is pegged graft with first slider screw thread, one side fixedly connected with two first guide bars at base top, sliding sleeve has the bearing seat between two first guide bars, and flange body card is on the bearing seat, and threaded grafting has fastening screw between bearing seat and the base.

Further, the detection mechanism comprises a pneumatic push rod, the pneumatic push rod is fixed at the top of the mounting frame through a bolt, the bottom end of the pneumatic push rod is fixedly connected with a slide way, a second slide block is connected in the slide way in a sliding manner, and the Brinell hardness detector is fixed at the bottom of the second slide block through a bolt.

Further, an adjusting screw rod is inserted between the two ends of the slide rail in a rotating mode, the adjusting screw rod is in threaded insertion with the second sliding block, and one end of the adjusting screw rod is fixedly connected with an adjusting disc.

Further, two second guide rods are fixedly connected between the bottom inner wall and the top inner wall of the mounting frame, and the slide rail is in sliding sleeve joint with the second guide rods.

Further, one side of the mounting frame is fixedly connected with a control panel.

Further, the control panel is electrically connected with the motor and the Rich hardness detector.

The beneficial effects of the utility model are as follows:

1. Through supporting flange body card on the bearing seat, then, the threaded rod rotates under the drive of motor to drive first slider and remove in the slide opening, thereby drive the clamping lever and remove, and then follow the inside tensioning of flange body, then fix the flange body, thereby prevent that the flange body detects time skew.

2. The flange body is driven to move by pulling the bearing seat so that the transverse center of the flange body is aligned with the Brinell hardness tester, then the adjusting disc is screwed to drive the adjusting screw rod to rotate, so that the Brinell hardness tester is driven to move, the longitudinal center of the flange body is aligned with the Brinell hardness tester, and the accuracy of flange detection is improved.

Drawings

Fig. 1 is a schematic perspective view of an anti-skew flange hardness testing device according to the present utility model;

fig. 2 is a schematic bottom view of a flange hardness testing device with anti-skew function according to the present utility model;

Fig. 3 is a schematic perspective view of a part of a flange hardness testing device for preventing skew according to the present utility model.

In the figure, 1, a mounting rack; 2, a base, 3, a mounting plate, 4, a sliding hole, 5, a first sliding block, 6, a threaded rod, 7, a motor, 8, a clamping rod, 9, a fastening screw, 10, a bearing seat, 11, a first guide rod, 12, a flange body, 13, a slideway, 14, an adjusting screw rod, 15, a second sliding block, 16, an adjusting plate, 17, a Brinell hardness detector, 18, a second guide rod, 19, a pneumatic push rod, 20 and a control panel.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments.

Referring to fig. 1-3, an anti-skew flange hardness testing device comprises a mounting rack 1, a flange body 12, a brinell hardness tester 17 and a testing mechanism, wherein a base 2 is fixed on the inner wall of the bottom of the mounting rack 1 through bolts, a mounting plate 3 is fixed on the top of the base 2 through bolts, a plurality of sliding holes 4 are formed in one side of the mounting plate 3, a first sliding block 5 is connected in a sliding manner in the sliding holes 4, a clamping rod 8 is connected at one end of the first sliding block 5 in a rotating manner, a plurality of motors 7 are fixed on the outer circumferential wall of the mounting plate 3 through bolts, a threaded rod 6 is connected with the first sliding block 5 through bolts, the threaded rod 6 is in threaded connection with the threaded rod 6 under the driving of the motors 7, so that the first sliding block 5 moves in the sliding holes 4, the clamping rod 8 is driven to move, the flange body 12 is further tensioned from the inside of the flange body 12, two first guiding rods 11 are welded on one side of the top of the base 2, a clamping seat 10 is arranged between the two first guiding rods 11, the flange body 12 is clamped on the seat 10, the first guiding rod 11 is pulled to move along the first guiding rod 11, the first guiding rod 12 is driven by the first guiding rod 11, the flange body is driven by the threaded rod 10 to move, and the flange body is fastened by the flange body 10 to the flange body is fastened by the screw 9, and the flange body is fastened by the screw 9 to the flange body, and the flange body is fastened by the screw 9.

The detecting mechanism comprises a pneumatic push rod 19, the pneumatic push rod 19 is fixed at the top of the mounting frame 1 through bolts, a slide way 13 is fixed at the bottom end of the pneumatic push rod 19 through bolts, the slide way 13 moves downwards under the driving of the pneumatic push rod 19, so that the Lishi hardness detector 17 moves downwards, the flange body 12 is further subjected to hardness detection, a second slide block 15 is connected in a sliding manner in the slide way 13, the Lishi hardness detector 17 is fixed at the bottom of the second slide block 15 through bolts, an adjusting screw 14 is inserted between the two ends of the slide way 13 in a rotating manner, the adjusting screw 14 is in threaded insertion with the second slide block 15, one end of the adjusting screw 14 is welded with an adjusting disc 16, the adjusting disc 16 is screwed to drive the adjusting screw 14 to rotate, so that the second slide block 15 is driven to move in the slide way 13, the Lishi hardness detector 17 is driven to move, so that the longitudinal center of the flange body 12 is aligned with the Lishi hardness detector 17, two second guide rods 18 are welded between the inner walls at the bottom and the top of the mounting frame 1, the slide way 13 and the second guide rods 18 are in a sliding sleeve joint, so that the stability of the flange hardness detection is improved, one side of the mounting frame 1 is provided with a panel 20 through a fixed motor, and a panel 20 is electrically connected with the Lishi hardness detector 17, and the panel 20.

When the working principle of the embodiment is used, firstly, the flange body 12 is clamped on the bearing seat 10, then, the bearing seat 10 is pulled to move along the first guide rod 11, so that the flange body 12 is driven to move, the transverse center of the flange body 12 is aligned with the Richter hardness detector 17, then, the bearing seat 10 is fixed by the fastening screw 9, then, the threaded rod 6 is driven by the motor 7 to rotate, so that the first sliding block 5 is driven to move in the sliding hole 4, the clamping rod 8 is driven to move, the flange body 12 is tensioned, the flange body 12 is fixed, then, the adjusting disc 16 is driven to rotate the adjusting screw 14, so that the second sliding block 15 is driven to move in the sliding way 13, the Richter hardness detector 17 is driven to move, the longitudinal center of the flange body 12 is aligned with the Richter hardness detector 17, and then, the sliding way 13 is driven to move downwards by the pneumatic push rod 19, so that the Richter hardness detector 17 is driven to move downwards, and the flange body 12 is further tested for hardness.

The foregoing is only a preferred embodiment of the present utility model, but the scope of the present utility model is not limited thereto, and any person skilled in the art, who is within the scope of the present utility model, should make equivalent substitutions or modifications according to the technical scheme of the present utility model and the inventive concept thereof, and should be covered by the scope of the present utility model.

Claims (6)

1. The utility model provides an anti-skew flange hardness check out test set, includes mounting bracket (1), flange body (12), reevesii hardness tester (17) and detection mechanism, a serial communication port, the bottom inner wall fixedly connected with base (2) of mounting bracket (1), the top fixedly connected with mounting disc (3) of base (2), one side of mounting disc (3) is equipped with a plurality of slide holes (4), sliding connection has first slider (5) in slide hole (4), the one end rotation of first slider (5) is connected with clamping lever (8), the circumference outer wall fixedly connected with of mounting disc (3) a plurality of motors (7), the output key-type of motor (7) is connected with threaded rod (6), threaded rod (6) and first slider (5) screw-in, one side fixedly connected with two first guide bars (11) at base (2) top, sliding sleeve has between two first guide bars (11) bearing seat (10), flange body (12) card is on bearing seat (10), screw (9) are pegged graft to screw thread between bearing seat (10) and base (2).

2. The anti-skew flange hardness detection device according to claim 1, wherein the detection mechanism comprises a pneumatic push rod (19), the pneumatic push rod (19) is fixed at the top of the mounting frame (1) through a bolt, a slide way (13) is fixedly connected to the bottom end of the pneumatic push rod (19), a second slide block (15) is slidably connected to the slide way (13), and the brinell hardness detector (17) is fixed at the bottom of the second slide block (15) through a bolt.

3. The anti-skew flange hardness detection device according to claim 2, wherein an adjusting screw (14) is rotatably inserted between two ends of the slideway (13), the adjusting screw (14) is in threaded insertion with the second sliding block (15), and one end of the adjusting screw (14) is fixedly connected with an adjusting disc (16).

4. The anti-skew flange hardness detection device according to claim 1, wherein two second guide rods (18) are fixedly connected between the bottom inner wall and the top inner wall of the mounting frame (1), and the slideway (13) is in sliding sleeve connection with the second guide rods (18).

5. The anti-skew flange hardness testing device according to claim 1, wherein a control panel (20) is fixedly connected to one side of the mounting frame (1).

6. The anti-skew flange hardness testing apparatus according to claim 5, wherein the control panel (20) is electrically connected to the motor (7) and the hardness tester (17).