CN218381362U - Multi-angle detection fixture tool for X-ray stress detector - Google Patents

Abstract

The utility model discloses a X ray stress detector multi-angle detects anchor clamps frock, it is including the connecting block that is used for installing whole anchor clamps frock on mobile device that connects gradually, be used for realizing that X ray stress detector makes a round trip gliding slide mechanism and be used for fixed X ray stress detector's mounting fixture along vertical direction including the gear steering mechanism that XYZ axle three-dimensional turned to, be used for realizing that stress detector makes a round trip to slide, run through on the mounting fixture has the fixed orifices that is used for fixed X ray stress detector. The X-ray stress detector is quickly positioned in the adaptable narrow space of the tool, the X-ray stress detector is not limited by space in the using process, the X-ray stress detector is turned along the three directions of the X axis and the Y axis through the gear steering mechanism, the stress detector slides back and forth along the vertical direction through the sliding mechanism, the multi-direction quick and effective positioning of the X-ray stress detector is realized, and the positioning precision of the X-ray stress detector is ensured.

Description

Multi-angle detection fixture tool for X-ray stress detector

Technical Field

The utility model belongs to stress detection equipment field, specifically speaking relates to a X ray stress detection appearance multi-angle detects anchor clamps frock.

Background

The X-ray stress detector is mainly used for measuring the residual stress of a metal member, can nondestructively measure the residual stress at a specified point and in a specified direction on the surface of a material in a short time, and has a function of measuring the magnitude and direction of the principal stress.

The X-ray stress detector needs to be matched with a clamp positioning tool to use in the using process, and the clamp positioning tool is used for realizing the rotation of a testing part of the X-ray stress detector along the XYZ direction and the movement of the testing part along the vertical direction, so that the detection and the positioning of the X-ray stress detector on a measured material are realized. The using state of the existing fixture positioning tool 200 is shown in fig. 1, the fixture positioning tool is complex in operation, when stress distribution of large and complex parts is detected, the X-ray detector 100 cannot be quickly and effectively positioned, the positioning accuracy of the X-ray stress detector cannot be guaranteed, the detection result of the X-ray stress detector is influenced, and in addition, the fixture positioning tool needs a large placing space and can not be adapted to quick positioning of the X-ray stress detector in a narrow space.

Accordingly, further developments and improvements are still needed in the art.

SUMMERY OF THE UTILITY MODEL

Aiming at various defects in the prior art, in order to solve the problems, the multi-angle detection fixture tool for the X-ray stress detector is provided, and the following technical scheme is provided:

the utility model provides a X ray stress detector multi-angle detects anchor clamps frock, it is including connecting gradually and being used for installing whole anchor clamps frock in the connecting block on the mobile device, be used for realizing that X ray stress detector turns to along XYZ axle three-dimensional gear steering mechanism, be used for realizing that X ray stress detector slides along vertical direction's slide mechanism and be used for the mounting fixture of fixed X ray stress detector, it has the fixed orifices that is used for fixed X ray stress detector to run through on the mounting fixture.

The utility model discloses further set up to: the gear steering mechanism comprises a steering block rotationally connected to the connecting block, a steering fixed block fixedly connected to the sliding mechanism, and a movable block arranged between the steering block and the steering fixed block, wherein two ends of the movable block are respectively connected to the steering block and the steering fixed block in a pivot mode.

The utility model discloses further set up to: the gear steering mechanism further comprises a first bevel gear shaft which is inserted into the connecting block and rotates on the connecting block, a first bevel gear which is arranged in the connecting block and sleeved on the first bevel gear shaft, a second bevel gear shaft which is inserted into the connecting block and rotates on the connecting block, and a second bevel gear which is arranged in the connecting block and sleeved on the second bevel gear shaft, wherein the second bevel gear shaft and the first bevel gear shaft are perpendicular to each other, the first bevel gear and the second bevel gear are meshed with each other, and one end, far away from the connecting block, of the second bevel gear shaft is fixedly connected to the steering block.

The utility model discloses further set up to: the gear steering mechanism further comprises a third bevel gear shaft for realizing the pivot connection of the movable block and the steering block, a third bevel gear arranged in the movable block and sleeved on the third bevel gear shaft, a fourth bevel gear shaft connected to the movable block in an inserting and rotating manner, and a fourth bevel gear arranged in the movable block and sleeved on the fourth bevel gear shaft, wherein the third bevel gear shaft is connected to the movable block in an inserting manner and rotatably connected to one side, far away from the second bevel gear shaft, of the steering block, the third bevel gear is meshed with the fourth bevel gear, and the third bevel gear shaft and the fourth bevel gear shaft are perpendicular to each other.

The utility model discloses further set up to: the gear steering mechanism further comprises a fifth bevel gear shaft for realizing the pivot connection between the movable block and the steering fixed block, a fifth bevel gear arranged in the movable block and sleeved on the fifth bevel gear shaft, a sixth bevel gear shaft connected to the movable block in an inserting and rotating manner, and a sixth bevel gear arranged in the movable block and sleeved on the sixth bevel gear shaft, wherein the fifth bevel gear is meshed with the sixth bevel gear, the fifth bevel gear shaft and the sixth bevel gear shaft are perpendicular to each other, the fifth bevel gear shaft is inserted in the movable block, one end of the third bevel gear shaft is far away from the movable block, and the fifth bevel gear shaft is rotatably connected to one side, far away from the sliding mechanism, of the steering fixed block.

The utility model discloses further set up to: the sliding mechanism comprises a sliding rail and a sliding strip which are mutually matched and slidably connected in the vertical direction, and a reverse bolt which is arranged between the fixing clamp and the steering fixing block and is in threaded connection with the fixing clamp, wherein one of the sliding rail and the sliding strip is arranged on the fixing clamp, the other one of the sliding rail and the sliding strip is arranged on the steering fixing block, and the reverse bolt is rotated to enable the fixing clamp to vertically move relative to the steering fixing block.

The utility model discloses further set up to: and a sliding travel limiting part is arranged on the steering fixing block and opposite to one side of the fixing clamp.

The utility model discloses further set up to: the sliding rails are arranged on the fixing clamp, the sliding strips are arranged on the steering fixing block, two groups of sliding rails and two groups of sliding strips are arranged on the two sides of the reverse bolt in a symmetrical mode, and the sliding stroke limiting part is located at the bottom between the two sliding strips.

The utility model discloses further set up to: and a clamping hole penetrates through the upper edge of the fixing clamp in the direction perpendicular to the fixing hole.

The utility model discloses further set up to: and a connecting hole for connecting with the movable equipment is formed in the connecting block.

To sum up, the utility model discloses compare and have following beneficial effect in prior art:

(1) The utility model provides a X ray stress detector multi-angle detects anchor clamps frock can realize being connected with any mobile device through setting up the connecting block, drives X ray stress detector multi-angle through mobile device and detects anchor clamps frock and carry out moving as a whole to the X ray stress detector who fixes on the drive mounting fixture removes. The tool is simple in structure and convenient to operate, the X-ray stress detector is quickly positioned in an adaptable narrow space, the X-ray stress detector is turned along the three directions of the X axis and the Y axis through the gear steering mechanism, the stress detector slides back and forth along the vertical direction through the sliding mechanism, the X-ray stress detector is not limited by the space, the X-ray stress detector is quickly and effectively positioned at multiple directions and multiple angles, and the positioning precision of the X-ray stress detector is guaranteed.

(2) The X-ray stress detector can be adjusted and positioned in multiple directions and multiple angles by arranging the gear steering mechanism, the positioning precision of the X-ray stress detector is improved, the operation is simple, and the adjustment is convenient.

(3) The X-ray stress detector moves along the vertical direction by arranging the sliding mechanism, so that the X-ray stress detector is adjusted in the vertical direction, the operation is simple, and the adjustment is convenient. Through setting up the stroke locating part, guarantee that X ray stress detector moves the end security along vertical direction.

Drawings

FIG. 1 is a schematic structural view of a clamping and positioning tool in the background art;

FIG. 2 is a schematic structural diagram of a multi-angle inspection fixture for an X-ray stress inspection apparatus according to embodiment 1 of the present invention;

fig. 3 is a schematic structural diagram of the multi-angle detection fixture tool of the X-ray stress detector in the embodiment 1 of the present invention at another view angle;

fig. 4 is a top view of the multi-angle detection fixture of the X-ray stress detector in embodiment 1 of the present invention.

Detailed Description

In order to make those skilled in the art better understand the technical solution of the present invention, the following embodiments of the present invention are combined to make clear and complete description of the technical solution of the present invention, and based on the embodiments in the present application, other similar embodiments obtained by those skilled in the art without creative efforts shall all belong to the scope of protection of the present application. In addition, directional terms such as "upper", "lower", "left", "right", etc. in the following embodiments are directions with reference to the drawings only, and thus, the directional terms are used for illustration and not for limitation of the present invention.

Detailed description of the preferred embodiment 1

2-4, the multi-angle detection fixture tool comprises a connecting block 310, a gear steering mechanism 320, a sliding mechanism 350 and a fixing fixture 330, wherein the connecting block 310 is used for installing the whole fixture tool on movable equipment, the gear steering mechanism 320 is used for achieving three-way steering of an X-ray stress detector along an XYZ axis, the sliding mechanism 350 is used for achieving sliding of the X-ray stress detector along the vertical direction, the fixing fixture 330 is used for fixing the X-ray stress detector, and a fixing hole 331 is formed in the fixing fixture 330 in a penetrating mode and used for fixing the X-ray stress detector.

Specifically, the fixing hole 331 is a threaded hole, a threaded hole corresponding to the threaded hole on the fixing clamp 330 is provided on the fixing portion of the conventional X-ray stress detector, and the X-ray stress detector is fixedly connected to the fixing clamp 330 through the matching of a bolt and the two threaded holes.

The multi-angle detection fixture tool of the X-ray stress detector can be connected with any movable device by arranging the connecting block 310, the movable device drives the multi-angle detection fixture tool of the X-ray stress detector to integrally move, so that the X-ray stress detector fixed on the fixing fixture 330 is driven to move, the positioning in a narrow space can be fixed, the three-direction steering of the X-ray stress detector along an X-Y axis is realized by arranging the gear steering mechanism 320, the stress detector slides back and forth along a vertical direction by arranging the sliding mechanism 350, the X-ray stress detector is guaranteed not to be limited by space, the multi-direction and multi-angle quick and effective positioning of the X-ray stress detector is realized, and the positioning precision of the X-ray stress detector is guaranteed.

The gear steering mechanism 320 includes a steering block 321 rotatably connected to the connecting block 310, a steering fixed block 322 fixedly connected to the sliding mechanism 350, and a movable block 323 disposed between the steering block 321 and the steering fixed block 322 and having two ends pivotally connected to the steering block 321 and the steering fixed block 322, respectively. The turning block 321 is a concave block, two side plates of the concave block are provided with a first mounting hole in a pair manner, one end of the movable block 323 is rotatably connected in the first mounting hole of the concave block, and the bottom plate of the concave block is rotatably connected with the connecting block 310.

The gear steering mechanism 320 further comprises a first bevel gear shaft inserted and rotated on the connecting block 310, a first bevel gear arranged in the connecting block 310 and sleeved on the first bevel gear shaft, a second bevel gear shaft inserted and rotated on the connecting block 310, and a second bevel gear arranged in the connecting block 310 and sleeved on the second bevel gear shaft, wherein the second bevel gear shaft and the first bevel gear shaft are arranged in a mutually perpendicular manner, the first bevel gear and the second bevel gear are mutually meshed, and one end of the second bevel gear shaft, which is far away from the connecting block 310, is fixedly connected to the steering block 321.

The first rotating handle 341 is sleeved on the first bevel gear shaft protruding out of the connecting block 310, and the first rotating handle 341 is screwed to drive the first bevel gear shaft to rotate, so that the first bevel gear and the second bevel gear meshed with the first bevel gear are driven to rotate, the rotation of the steering block 321 relative to the connecting block 310 in the Z-axis direction is realized, and the rotation of the X-ray stress detector in the Z-axis direction is realized.

The gear steering mechanism 320 further comprises a third bevel gear shaft for realizing the pivotal connection between the movable block 323 and the steering block 321, a third bevel gear arranged in the movable block 323 and sleeved on the third bevel gear shaft, a fourth bevel gear shaft connected to the movable block 323 in an inserting and rotating manner, and a fourth bevel gear arranged in the movable block 323 and sleeved on the fourth bevel gear shaft, wherein the third bevel gear shaft is connected to the movable block 323 in an inserting manner and rotatably connected to one side of the steering block 321 away from the second bevel gear shaft, the third bevel gear and the fourth bevel gear are meshed with each other, and the third bevel gear shaft and the fourth bevel gear shaft are arranged perpendicularly to each other.

The second rotating handle 342 is sleeved on a fourth bevel gear shaft protruding out of the connecting block 310, and the fourth bevel gear shaft is driven to rotate by screwing the second rotating handle 342, so that the fourth bevel gear and a third bevel gear meshed with the fourth bevel gear are driven to rotate, the movable block 323 rotates relative to the steering block 321 along the Y-axis direction, and the X-ray stress detector rotates along the Y-axis direction.

The gear steering mechanism 320 further comprises a fifth bevel gear shaft for realizing the pivotal connection between the movable block 323 and the steering fixed block 322, a fifth bevel gear arranged in the movable block 323 and sleeved on the fifth bevel gear shaft, a sixth bevel gear shaft connected to the movable block 323 in an inserting and rotating manner, and a sixth bevel gear arranged in the movable block 323 and sleeved on the sixth bevel gear shaft, wherein the fifth bevel gear is meshed with the sixth bevel gear, the fifth bevel gear shaft and the sixth bevel gear shaft are arranged vertically, and the fifth bevel gear shaft is connected to the movable block 323 in an inserting manner, is far away from one end of the third bevel gear shaft, and is rotatably connected to one side of the steering fixed block 322, which is far away from the sliding mechanism 350.

A third rotating handle 343 is sleeved on a sixth bevel gear shaft protruding from the connecting block 310, and by screwing the third rotating handle 343, the sixth bevel gear shaft is driven to rotate, so that the sixth bevel gear and a fifth bevel gear meshed therewith are driven to rotate, the movable block 323 is driven to rotate along the X-axis direction relative to the steering fixing block 322, and the X-ray stress detector is driven to rotate along the X-axis direction.

The sliding mechanism 350 includes a sliding rail 351 and a sliding bar 352 which are mutually matched and slidably connected in the vertical direction, and a reverse bolt 353 which is arranged between the fixing clamp 330 and the steering fixing block 322 and is in threaded connection with the fixing clamp 330, wherein one of the sliding rail 351 and the sliding bar 352 is arranged on the fixing clamp 330, the other one of the sliding rail 351 and the sliding bar 352 is arranged on the steering fixing block 322, and the fixing clamp 330 is vertically moved relative to the steering fixing block 322 by rotating the reverse bolt 353.

The rotation-direction fixing block 322 is provided with a sliding travel limiting member 354 at a side opposite to the fixing clamp 330. The sliding travel of the slide bar 352 and the slide rail 351 is limited by providing a sliding travel limit piece 354. The slide rails 351 are disposed on the fixing clamp 330, the slide bars 352 are disposed on the steering fixing block 322, two sets of slide rails 351 and two sets of slide bars 352 are disposed on the slide rails 351 and the slide bars 352 correspondingly, the two sets of slide rails 351 and the two sets of slide bars 352 are symmetrically disposed on two sides of the reverse bolt 353, and the sliding stroke limiting member 354 is disposed at the bottom between the two sets of slide bars 352.

In this embodiment, the sliding stroke limiting member 354 is a limiting post vertically connected to one side of the rotating fixing block opposite to the movable block 323, two limiting posts are arranged in parallel, and when the sliding rail 351 moves to the sliding end along the sliding bar 352, the limiting posts abut against the bottom end of the sliding rail 351 to prevent the sliding rail 351 from continuously moving downward, thereby effectively protecting the X-ray stress detector.

Preferably, a sliding travel limiting piece 354 is also arranged at the top between the two sliding bars 352, so that the sliding rail 351 is prevented from sliding out of the sliding bars 352 when sliding to the sliding end, and the X-ray stress detector is effectively protected.

The top of the reverse bolt 353 is provided with a fourth rotating handle 344, and the reverse bolt 353 is lifted by rotating the fourth rotating handle 344, so that the fixing clamp 330 is driven to vertically slide along the sliding rail 351.

A clamping hole 332 penetrates through the fixing clamp 330 in the direction perpendicular to the fixing hole 331, the fixing portion of the X-ray stress detector penetrates into the clamping hole 332, and the fixing portion of the X-ray stress detector is fixed on the fixing clamp through a bolt, so that the clamping and fixing stability of the X-ray stress detector on the fixing clamp 330 is improved.

The connecting hole 311 is formed in the connecting block 310, the whole fixture is mounted on the movable device through the connecting hole 311 of the connecting block 310, the movable device drives the whole fixture to move, and therefore the X-ray stress detector fixed on the fixture is driven to move. The coupling hole 311 is provided at the opposite side with respect to the second bevel shaft. The coupling hole 311 is a threaded hole.

When the multi-angle detection fixture tool for the X-ray stress detector is used, the multi-angle detection fixture tool is connected to any movable equipment through a threaded hole in the connecting block 310, a fixing portion of the X-ray stress detector penetrates into a clamping hole 332 in the fixing fixture 330, and the X-ray stress detector is fixed on the fixing fixture 330 through a bolt. The rotation angle of the X-ray stress detector in the XYZ-axis direction and the moving distance of the X-ray stress detector in the vertical direction can be realized by rotating the first rotating handle 341, the second rotating handle 342, the third rotating handle 343 and the fourth rotating handle 344, so that the multi-angle detection clamp of the X-ray stress detector can be quickly positioned in multiple angles, and is not limited by space conditions.

The above description is only a preferred embodiment of the present invention, and should not be taken as limiting the scope of the invention, i.e. the present invention is intended to cover all equivalent variations and modifications within the scope of the present invention.

Claims (10)

1. The utility model provides a multi-angle of X ray stress detector detects anchor clamps frock, its characterized in that, including the connecting block that is used for installing whole anchor clamps frock on mobile device that connects gradually, be used for realizing that X ray stress detector turns to along XYZ axle three-dimensional gear steering, be used for realizing that X ray stress detector makes a round trip the gliding sliding mechanism of slip along vertical direction and be used for fixed X ray stress detector's mounting fixture, it has the fixed orifices that is used for fixed X ray stress detector to run through on the mounting fixture.

2. The multi-angle detection fixture tool for the X-ray stress detector according to claim 1, wherein the gear steering mechanism comprises a steering block rotatably connected to the connecting block, a steering fixed block fixedly connected to the sliding mechanism, and a movable block arranged between the steering block and the steering fixed block and having two ends pivotally connected to the steering block and the steering fixed block, respectively.

3. The multi-angle detection fixture tool of the X-ray stress detector of claim 2, wherein the gear steering mechanism further comprises a first bevel gear shaft inserted and rotated on the connecting block, a first bevel gear arranged in the connecting block and sleeved on the first bevel gear shaft, a second bevel gear shaft inserted and rotated on the connecting block, and a second bevel gear arranged in the connecting block and sleeved on the second bevel gear shaft, the second bevel gear shaft and the first bevel gear shaft are arranged perpendicular to each other, the first bevel gear and the second bevel gear are meshed with each other, and one end of the second bevel gear shaft, which is far away from the connecting block, is fixedly connected to the steering block.

4. The multi-angle detection fixture tool of the X-ray stress detector of claim 3, wherein the gear steering mechanism further comprises a third bevel gear shaft for pivotally connecting the movable block and the steering block, a third bevel gear arranged in the movable block and sleeved on the third bevel gear shaft, a fourth bevel gear shaft connected to the movable block in an inserting manner, and a fourth bevel gear arranged in the movable block and sleeved on the fourth bevel gear shaft, wherein the third bevel gear shaft is connected to the movable block in an inserting manner and rotatably connected to one side of the steering block away from the second bevel gear shaft, the third bevel gear is meshed with the fourth bevel gear, and the third bevel gear shaft and the fourth bevel gear shaft are arranged perpendicularly to each other.

5. The multi-angle detection fixture tool for the X-ray stress detector according to claim 4, wherein the gear steering mechanism further comprises a fifth bevel gear shaft for pivotally connecting the movable block and the steering fixed block, a fifth bevel gear disposed in the movable block and sleeved on the fifth bevel gear shaft, a sixth bevel gear shaft connected to the movable block in an inserting and rotating manner, and a sixth bevel gear disposed in the movable block and sleeved on the sixth bevel gear shaft, wherein the fifth bevel gear is meshed with the sixth bevel gear, the fifth bevel gear shaft and the sixth bevel gear shaft are perpendicular to each other, and the fifth bevel gear shaft is inserted into one end of the movable block, which is far away from the third bevel gear shaft, and is rotatably connected to one side of the steering fixed block, which is far away from the sliding mechanism.

6. The multi-angle detection fixture tool for the X-ray stress detector according to claim 2, wherein the sliding mechanism comprises a sliding rail and a sliding strip which are matched and slidably connected with each other in the vertical direction, and a reverse bolt which is arranged between the fixing fixture and the steering fixing block and is in threaded connection with the fixing fixture, one of the sliding rail and the sliding strip is arranged on the fixing fixture, the other one of the sliding rail and the sliding strip is arranged on the steering fixing block, and the reverse bolt is rotated to enable the fixing fixture to vertically move relative to the steering fixing block.

7. The multi-angle detection fixture tool for the X-ray stress detector according to claim 6, wherein a sliding stroke limiting part is arranged on the steering fixing block and opposite to one side of the fixing fixture.

8. The multi-angle detection fixture tool for the X-ray stress detector according to claim 6, wherein the slide rails are arranged on the fixing fixture, the slide bars are arranged on the steering fixing block, two sets of slide rails and two sets of slide rails are arranged corresponding to the slide bars and symmetrically arranged on two sides of the reverse bolt, and the slide stroke limiting part is arranged at the bottom between the two slide bars.

9. The multi-angle detection fixture tool of the X-ray stress detector according to claim 1, wherein a clamping hole penetrates through the fixing fixture along a direction perpendicular to the fixing hole.

10. The multi-angle detection fixture tool for the X-ray stress detector according to claim 1, wherein a connecting hole for connecting with a movable device is formed in the connecting block.

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