CN210834712U - X-ray steel pipe flaw detection device - Google Patents
X-ray steel pipe flaw detection device Download PDFInfo
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- CN210834712U CN210834712U CN202020302569.4U CN202020302569U CN210834712U CN 210834712 U CN210834712 U CN 210834712U CN 202020302569 U CN202020302569 U CN 202020302569U CN 210834712 U CN210834712 U CN 210834712U
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Abstract
The utility model belongs to the technical field of the detection device that detects a flaw and specifically relates to X-ray steel pipe detection device that detects a flaw. The flaw detection device comprises a rack, an X-ray flaw detector body, an X-ray tube, a first lifting mechanism, a second lifting mechanism, a rotating mechanism, a steel tube pushing mechanism and a platform body, wherein the first lifting mechanism is fixed on a cross beam of the rack, the second lifting mechanism and the X-ray flaw detector body are fixed at the lifting end of the first lifting mechanism, the X-ray flaw detector body is connected with the X-ray tube through a cable, the X-ray tube is fixed on an output shaft of the rotating mechanism, the body of the rotating mechanism is fixed at the lifting end of the second lifting mechanism, the platform body is arranged below the cross beam of the rack, and the steel tube pushing mechanism used for pushing the steel tube is installed in. The utility model discloses a height that adjusts the X-ray tube through elevating system one and elevating system two. The rotation mechanism adjusts the angle of the X-ray tube. The steel pipe is pushed to move by the steel pipe pushing mechanism. This application has improved the efficiency that the steel pipe detected.
Description
Technical Field
The utility model belongs to the technical field of the detection device that detects a flaw and specifically relates to X-ray steel pipe detection device that detects a flaw.
Background
An X-ray damage detector is a nondestructive inspection method for detecting defects in a substance by utilizing the characteristics of X-rays penetrating the substance and having attenuation in the substance. However, most of the existing flaw detectors are manually held, and the flaw detection efficiency is low.
SUMMERY OF THE UTILITY MODEL
In order to overcome the not enough of the inefficiency of detecting a flaw of current X ray damage detection machine, the utility model provides an X ray steel pipe detection device that detects a flaw.
The utility model provides a technical scheme that its technical problem adopted is: the utility model provides a X-ray steel pipe detection device that detects a flaw, includes frame, X-ray radiographic inspection machine organism, X-ray tube, elevating system one, elevating system two, rotary mechanism, steel pipe pushing mechanism and stage body, be fixed with elevating system one on the crossbeam of frame, the elevating system of elevating system one is fixed with X-ray radiographic inspection machine organism and elevating system two, and X-ray radiographic inspection machine organism passes through the cable and links to each other with the X-ray tube, and the X-ray tube is fixed on rotary mechanism's output shaft, and rotary mechanism's organism is fixed at the lift end of elevating system two, and the crossbeam below of frame is equipped with the stage body, installs the steel pipe pushing mechanism who is used for promoting the steel pipe in.
According to the utility model discloses a steel pipe pushing mechanism comprises push pedal, rack, gear and gear drive motor, and the rack sliding fit is connected in the inside horizontal spout of stage body, and the rack meshes with the gear mutually, and the gear is fixed on gear drive motor's output shaft, and gear drive motor fixes in the stage body, and the push pedal is located the stage body top, and the push pedal passes through the connecting plate and is fixed together with the rack.
According to the utility model discloses a further embodiment, further include be equipped with the straight line spout that is used for placing the steel pipe on the stage body.
According to the utility model discloses a further embodiment, further include elevating system one and elevating system two are cylinder or hydro-cylinder.
According to another embodiment of the present invention, it is further included that the rotating mechanism is a motor.
The beneficial effects of the utility model are that, this utility model adjusts the height of X-ray tube through elevating system one and elevating system two. The angle of the X-ray tube is adjusted by the rotating mechanism. The steel pipe is pushed to move by the steel pipe pushing mechanism. This application has improved the efficiency that the steel pipe detected.
Drawings
The present invention will be further explained with reference to the drawings and examples.
Fig. 1 is a schematic structural diagram of the present invention;
FIG. 2 is a schematic structural view of the stage of the present invention;
in the figure, 1, a machine frame, 2, an X-ray flaw detector body, 3, an X-ray tube, 4, a first lifting mechanism, 5, a second lifting mechanism, 6, a rotating mechanism, 7, a steel tube pushing mechanism, 8, a table body, 9, a linear sliding groove, 71, a push plate, 72, a rack, 73, a gear and 74, and a gear driving motor.
Detailed Description
Fig. 1 is the structural schematic diagram of the utility model, fig. 2 is the structural schematic diagram of the stage of the utility model, an X-ray steel pipe detection device that detects a flaw, including frame 1, X-ray radiographic inspection machine organism 2, X-ray tube 3, elevating system 4, elevating system two 5, rotary mechanism 6, steel pipe pushing mechanism 7 and stage 8, be fixed with elevating system 4 on the crossbeam of frame 1, the elevating system 4's elevating system is fixed with X-ray radiographic inspection machine organism 2 and elevating system two 5, and X-ray radiographic inspection machine organism 2 passes through the cable and links to each other with X-ray tube 3, and X-ray tube 3 fixes on rotary mechanism 6's output shaft, and rotary mechanism 6's organism is fixed at the lift end of elevating system two 5, and frame 1's crossbeam below is equipped with stage 8, installs the steel pipe pushing mechanism 7 that is used for promoting the steel pipe in the stage 8. The steel tube pushing mechanism 7 is composed of a push plate 71, a rack 72, a gear 73 and a gear driving motor 74, wherein the rack 72 is connected in a sliding manner in a horizontal sliding groove in the table body 8, the rack 72 is meshed with the gear 73, the gear 73 is fixed on an output shaft of the gear driving motor 74, the gear driving motor 74 is fixed in the table body 8, the push plate 71 is positioned above the table body 8, and the push plate 71 is fixed with the rack 72 through a connecting plate. The table body 8 is provided with a linear chute 9 for placing a steel pipe. The first lifting mechanism 4 and the second lifting mechanism 5 are cylinders or oil cylinders. The rotating mechanism 6 is a motor.
Referring to fig. 1 and 2, a steel pipe is first placed in the linear sliding groove 9, the left and right sides of the steel pipe are attached to the linear sliding groove 9, and the steel pipe can move back and forth along the linear sliding groove 9. When the steel pipe is pushed, the output shaft of the gear driving motor 74 drives the gear 73 to rotate, the rotating gear 73 can drive the rack 72 engaged with the rotating gear to perform horizontal linear movement along the horizontal sliding groove, and the rack 72 drives the push plate 71 to perform horizontal linear movement. The push plate 71 is attached to a portion of the steel pipe higher than the linear sliding groove 9, and pushes the steel pipe horizontally and linearly.
The piston rod of the lifting mechanism I4 can drive the X-ray flaw detector body 2 and the X-ray tube 3 to lift up and down by stretching. The piston rod of the second lifting mechanism 5 can drive the X-ray tube 3 to further lift. The rotation mechanism 6 can drive the X-ray tube 3 to rotate by a certain angle. Thereby allowing for more comprehensive and efficient detection.
When the steel pipe is pushed horizontally, the X-ray tube 3 with the adjusted height and angle can be aligned with the steel pipe below for whole body detection.
Claims (5)
1. An X-ray steel tube flaw detection device is characterized by comprising a rack (1), an X-ray flaw detector body (2), an X-ray tube (3), a first lifting mechanism (4), a second lifting mechanism (5), a rotating mechanism (6), a steel tube pushing mechanism (7) and a table body (8), be fixed with elevating system (4) on the crossbeam of frame (1), the elevating system of elevating system (4) is fixed with X-ray radiographic inspection machine organism (2) and elevating system two (5), X-ray radiographic inspection machine organism (2) link to each other with X-ray tube (3) through the cable, X-ray tube (3) are fixed on the output shaft of rotary mechanism (6), the organism of rotary mechanism (6) is fixed at the elevating system of two (5) and is held, the crossbeam below of frame (1) is equipped with stage body (8), install steel pipe pushing mechanism (7) that are used for promoting the steel pipe in stage body (8).
2. The X-ray steel pipe flaw detection device of claim 1, wherein the steel pipe pushing mechanism (7) is composed of a pushing plate (71), a rack (72), a gear (73) and a gear driving motor (74), the rack (72) is connected in a sliding manner in a horizontal sliding groove in the table body (8), the rack (72) is meshed with the gear (73), the gear (73) is fixed on an output shaft of the gear driving motor (74), the gear driving motor (74) is fixed in the table body (8), the pushing plate (71) is positioned above the table body (8), and the pushing plate (71) is fixed with the rack (72) through a connecting plate.
3. The X-ray steel tube flaw detection apparatus according to claim 1, wherein the table body (8) is provided with a linear chute (9) for placing a steel tube.
4. The X-ray steel pipe flaw detection apparatus according to claim 1, wherein the first lifting mechanism (4) and the second lifting mechanism (5) are air cylinders or oil cylinders.
5. The X-ray steel pipe flaw detection apparatus according to claim 1, wherein the rotating mechanism (6) is a motor.
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
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CN202020302569.4U CN210834712U (en) | 2020-03-12 | 2020-03-12 | X-ray steel pipe flaw detection device |
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
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CN202020302569.4U CN210834712U (en) | 2020-03-12 | 2020-03-12 | X-ray steel pipe flaw detection device |
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CN210834712U true CN210834712U (en) | 2020-06-23 |
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CN202020302569.4U Active CN210834712U (en) | 2020-03-12 | 2020-03-12 | X-ray steel pipe flaw detection device |
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2020
- 2020-03-12 CN CN202020302569.4U patent/CN210834712U/en active Active
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