CN220063948U - Pipeline stress nondestructive ultrasonic testing equipment - Google Patents

Abstract

The utility model relates to the technical field of pipeline stress testing equipment, and provides pipeline stress nondestructive ultrasonic testing equipment, which comprises a monitoring equipment shell, wherein a winding disc is movably connected to one side of the monitoring equipment shell; the utility model is beneficial to the fact that when the detector is used, a worker starts the motor, the motor starts the winding disc to rotate to unwind the cable, the detector enters the pipeline, the winding disc rotates to enable the limiting ring to rotate in the limiting groove and limit the winding disc, the winding disc rotates to extrude the clamping head, the clamping head is pressed into the button to extrude the spring, the button is gradually compressed, after the detector descends to a specified position, the winding disc rotates to overlap with the nearest clamping groove, the clamping head loses pressure, the spring gradually rebounds, the clamping head is sprung into the clamping groove, the clamping groove clamps and limits the winding disc, and the clamping head is matched with the limiting ring, and the winding disc is more stable.

Description

Pipeline stress nondestructive ultrasonic testing equipment

Technical Field

The utility model relates to the technical field of pipeline stress testing equipment, in particular to pipeline stress nondestructive ultrasonic testing equipment.

Background

In the pipeline use, need to be to its stress test, current pipeline stress nondestructive ultrasonic testing equipment mainly includes check out test set and winding mechanism, secondly still includes actuating mechanism and limit structure etc. and the concrete process is put in the pipeline with check out test set through the cable, and staff accessible winding mechanism adjusts check out test set's height, and is spacing to the winding dish through limit structure, avoids rocking.

The publication No. CN113932958A discloses a pipeline stress nondestructive testing method based on ultrasound, which comprises the following steps: preparing a pipeline to be tested, placing the pipeline on a detection table, and then arranging a transmitting probe and a receiving probe of ultrasonic detection equipment at corresponding positions of the pipeline; during testing, the detection equipment sends out ultrasonic waves through the transmitting probe, and the ultrasonic waves pass through the pipeline and are received by the receiving probe; the ultrasonic receiving probe receives the ultrasonic wave and then amplifies the received sound wave, the amplified signal is transmitted to the data acquisition module, and the data acquisition module is arranged in the inspection equipment; when the detection device analyzes the collected signals. According to the utility model, the stress of the pipeline is detected by ultrasonic waves in the ultrasonic detection equipment, so that the efficiency of pipeline stress detection is improved, meanwhile, the detection equipment is small in size and convenient to carry, the stress of the pipeline can be detected anytime and anywhere, and the limitation of the stress detection of the traditional pipeline is solved.

However, the existing pipeline stress nondestructive ultrasonic testing is incomplete in structural design, in the use process, the height of the detector is adjusted through the winding device, then the electromagnet is started, so that the magnetic force communicated with the magnet is generated, the rack is used for limiting the gear on the winding disc in a meshed mode, and the rack is pushed by the magnetic force, the thrust generated by the magnetic force is unstable, so that when the detector detects, the winding disc is rocked due to the shaking generated by collision with the pipe wall, and the winding disc is rocked.

Disclosure of Invention

The utility model provides pipeline stress nondestructive ultrasonic testing equipment, which solves the problems that racks in the related art are mutually pushed by magnetism, and the pushing force generated by the magnetism is unstable, so that a take-up reel is driven to shake when a detector detects shake generated by collision with a pipe wall, and the take-up reel shakes the racks.

The technical scheme of the utility model is as follows: the utility model provides a pipeline stress nondestructive ultrasonic testing equipment, includes the monitoring facilities shell, one side swing joint of monitoring facilities shell has the rolling dish, the middle part fixedly connected with spacing ring that the rolling dish is close to monitoring facilities shell one side, and spacing ring and monitoring facilities shell swing joint, the draw-in groove has been seted up to the outside annular array that the rolling dish is located the spacing ring, the monitoring facilities shell is located the relative one side annular array fixedly connected with button of draw-in groove, the inside fixedly connected with spring of button, one side fixedly connected with limiting plate that the spring is close to the draw-in groove, and limiting plate and button swing joint, one side fixedly connected with dop that the limiting plate is close to the draw-in groove, and dop and draw-in groove joint.

Preferably, the top fixedly connected with display screen of monitoring facilities shell one side, equal fixedly connected with control key in monitoring facilities shell one side, the outside fixedly connected with rolling case that monitoring facilities shell is located the rolling case, the outlet has been seted up to the middle part annular array of rolling case.

Preferably, the limit groove is formed in the joint of the shell of the monitoring device and the limit ring, and the limit groove is movably connected with the limit ring.

Preferably, the middle part fixedly connected with bull stick that the rolling dish is close to monitoring facilities shell one side, and bull stick runs through monitoring facilities shell, rather than swing joint.

Preferably, the one end that the bull stick kept away from the reel is fixedly connected with first gear, one side of first gear meshes with the second gear.

Preferably, a rotating shaft is fixedly connected to one side, away from the winding disc, of the second gear.

Preferably, one end of the rotating shaft far away from the winding disc is movably connected with a motor.

Preferably, the bottom fixedly connected with supporting shoe of motor, and the bottom and the monitoring facilities shell fixed connection of supporting shoe.

The utility model has the technical effects and advantages that:

1. the utility model is beneficial to the fact that when the detector is used, a worker starts the motor, the motor starts the winding disc to rotate to unwind the cable, the detector enters the pipeline, the winding disc rotates to enable the limiting ring to rotate in the limiting groove and limit the winding disc, the winding disc rotates to extrude the clamping head, the clamping head is pressed into the button to extrude the spring, the button is gradually compressed, after the detector descends to a specified position, the winding disc rotates to overlap with the nearest clamping groove, the clamping head loses pressure, the spring gradually rebounds, the clamping head is sprung into the clamping groove, the clamping groove clamps and limits the winding disc, and the clamping head is matched with the limiting ring, and the winding disc is more stable.

Drawings

Fig. 1 is a schematic diagram of the overall structure of the present utility model.

Fig. 2 is a schematic overall sectional structure of the present utility model.

Fig. 3 is an exploded view of the winding disc of the present utility model.

Fig. 4 is a schematic cross-sectional structure of the button of the present utility model.

The reference numerals are: 1. monitoring a device housing; 11. a display screen; 12. a control key; 2. a winding box; 21. a wire outlet; 3. a reel; 31. a clamping groove; 32. a limiting ring; 33. a rotating rod; 34. a first gear; 4. a button; 41. a spring; 42. a limiting plate; 43. a chuck; 5. a motor; 51. a rotating shaft; 52. a second gear; 53. and a supporting block.

Detailed Description

The technical solutions of the embodiments of the present utility model will be clearly and completely described below in conjunction with the embodiments of the present utility model, and it is apparent that the described embodiments are only some embodiments of the present utility model, not all embodiments. All other embodiments, which can be made by one of ordinary skill in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

Referring to fig. 2-4, the utility model provides a pipeline stress nondestructive ultrasonic testing device, which comprises a monitoring device shell 1, a winding disc 3 is movably connected to one side of the monitoring device shell 1, a limiting ring 32 is fixedly connected to the middle part of one side of the winding disc 3, which is close to the monitoring device shell 1, the limiting ring 32 is movably connected with the monitoring device shell 1, a clamping groove 31 is formed in an annular array on the outer side of the limiting ring 32, the monitoring device shell 1 is fixedly connected with a button 4 on the opposite side of the clamping groove 31, a spring 41 is fixedly connected to the inner side of the button 4, a limiting plate 42 is fixedly connected to one side of the spring 41, which is close to the clamping groove 31, and the limiting plate 42 is movably connected with the button 4, a clamping head 43 is fixedly connected to one side of the clamping groove 31, and the clamping head 43 is clamped with the clamping groove 31, when the winding disc is in use, a worker starts a motor 5, the motor 5 starts to rotate and unwinds a cable 3, a detector enters a pipeline, the limiting ring 32 rotates in the limiting groove, the winding disc 3 limits the winding disc 3, the winding disc 3 rotates in the clamping groove, and presses the clamping head 43 to the button 3, the button 43 is pressed into the clamping groove, the clamping disc 3 gradually and the button 43 is pressed down to be more stably, the clamping the button 43 is pressed into the clamping groove 31, and the clamping groove 43 is gradually, and the button 43 is pressed into the nearest to the clamping groove 31, and the winding disc 3, and the winding disc is gradually pressed into the clamping groove 3, and the clamping 3, and the winding disc 43 is gradually pressed by the pressing the button 3, and the pressing the button 3.

Referring to fig. 1, 2 and 3, the top of one side of the monitor housing 1 is fixedly connected with the display screen 11, one side of the monitor housing 1 is fixedly connected with the control key 12, the outside of the monitor housing 1, which is located at the winding box 2, is fixedly connected with the winding box 2, the annular array of the middle part of the winding box 2 is provided with the wire outlet 21, the junction of the monitor housing 1, which is located at the limiting ring 32, is provided with the limiting groove, which is movably connected with the limiting ring 32, the middle part of one side of the winding disk 3, which is close to the monitor housing 1, is fixedly connected with the rotating rod 33, the rotating rod 33 penetrates through the monitor housing 1 and is movably connected with the rotating rod, one end of the rotating rod 33, which is far away from the winding disk 3, is fixedly connected with the first gear 34, one side of the first gear 34 is meshed with the second gear 52, one side of the second gear 52, which is far away from the winding disk 3, is fixedly connected with the rotating shaft 51, the one end swing joint that pivot 51 kept away from reel 3 has motor 5, the bottom fixedly connected with supporting shoe 53 of motor 5, and the bottom and the monitoring facilities shell 1 fixed connection of supporting shoe 53, when using, the staff is connected the detector through the cable, will carry out the rolling through reel 3 with the cable afterwards, then the staff puts in the pipeline with the detector, then the staff will start motor 5, motor 5 starts and drives pivot 51, pivot 51 rotates and drives the second gear 52 and rotate, because second gear 52 is the meshing with first gear 34, the second gear 52 rotates and drives first gear 34 and rotate, then first gear 34 rotates and drives bull stick 33 and rotate, then bull stick 33 rotates and drives reel 3 and rotate, and reel 3 rotates and unreels the cable.

The working principle of the utility model is as follows: firstly, when in use, a worker connects the detector through the cable, then the cable is wound through the winding disc 3, then the worker puts the detector into the pipeline, then the worker starts the motor 5, the motor 5 starts to drive the rotating shaft 51, the rotating shaft 51 rotates to drive the second gear 52 to rotate, the second gear 52 is meshed with the first gear 34, the second gear 52 rotates to drive the first gear 34 to rotate, then the first gear 34 rotates to drive the rotating rod 33 to rotate, then the rotating rod 33 rotates to drive the winding disc 3 to rotate, the winding disc 3 rotates to unwind the cable, the detector enters the pipeline, the winding disc 3 rotates to drive the limiting ring 32 to rotate at the same time, the limiting ring 32 rotates in the limiting groove, the winding disc 3 is limited, the clamping head 43 is extruded when the winding disc 3 rotates, the clamping head 43 is pressed into the button 4, the spring 41 is extruded, the button 4 is gradually compressed, after the worker descends the detector to a specified position, the winding disc 3 rotates to the clamping head 43 to be overlapped with the nearest clamping groove 31, the spring 43 gradually loses the pressure of the clamping head 31, and the spring 43 is gradually clamped in the limiting groove 31, and the spring 3 is more stably matched with the limiting ring 32, and the limiting ring 31 is clamped in the limiting groove.

The foregoing description of the preferred embodiments of the utility model is not intended to be limiting, but rather is intended to cover all modifications, equivalents, alternatives, and improvements that fall within the spirit and scope of the utility model.

Claims (8)

1. The utility model provides a pipeline stress nondestructive ultrasonic testing equipment, includes monitoring facilities shell (1), a serial communication port, one side swing joint of monitoring facilities shell (1) has rolling dish (3), the middle part fixedly connected with spacing ring (32) of rolling dish (3) near monitoring facilities shell (1) one side, and spacing ring (32) and monitoring facilities shell (1) swing joint, draw-in groove (31) have been seted up to the outside annular array that rolling dish (3) are located spacing ring (32), monitoring facilities shell (1) are located draw-in groove (31) opposite side annular array fixedly connected with button (4), the inside fixedly connected with spring (41) of button (4), one side fixedly connected with limiting plate (42) that spring (41) are close to draw-in groove (31), and limiting plate (42) and button (4) swing joint, one side fixedly connected with chuck (43) that limiting plate (42) are close to draw-in groove (31), and chuck (43) and draw-in groove (31) joint.

2. The pipeline stress nondestructive ultrasonic testing device according to claim 1, wherein a display screen (11) is fixedly connected to the top end of one side of the monitoring device shell (1), control keys (12) are fixedly connected to one side of the monitoring device shell (1), a winding box (2) is fixedly connected to the outer side of the monitoring device shell (1) located in the winding box (2), and a wire outlet (21) is formed in a middle annular array of the winding box (2).

3. The pipeline stress nondestructive ultrasonic testing device according to claim 1, wherein the limiting groove is formed in the joint of the limiting ring (32) of the monitoring device shell (1), and the limiting groove is movably connected with the limiting ring (32).

4. The pipeline stress nondestructive ultrasonic testing device according to claim 1, wherein a rotating rod (33) is fixedly connected to the middle of one side of the winding disc (3) close to the monitoring device shell (1), and the rotating rod (33) penetrates through the monitoring device shell (1) and is movably connected with the monitoring device shell.

5. The pipeline stress nondestructive ultrasonic testing device according to claim 4, wherein a first gear (34) is fixedly connected to one end of the rotating rod (33) away from the rolling disc (3), and a second gear (52) is meshed to one side of the first gear (34).

6. The pipeline stress nondestructive ultrasonic testing device according to claim 5, wherein a rotating shaft (51) is fixedly connected to one side of the second gear (52) away from the rolling disc (3).

7. The pipeline stress nondestructive ultrasonic testing device according to claim 6, wherein one end of the rotating shaft (51) far away from the rolling disc (3) is movably connected with a motor (5).

8. The pipeline stress nondestructive ultrasonic testing device according to claim 7, wherein a supporting block (53) is fixedly connected to the bottom end of the motor (5), and the bottom end of the supporting block (53) is fixedly connected with the monitoring device shell (1).