CN217637234U - Nondestructive detection equipment for metal material reinspection - Google Patents

Abstract

The utility model discloses a nondestructive test equipment is used in metal material reinspection, comprising a base plate, the last surface symmetry fixed mounting of bottom plate has two fixed plates, one of them the fixed surface of fixed plate installs pneumatic telescopic link, pneumatic telescopic link's flexible end runs through the surface and the fixed mounting of fixed plate has ejector pin, another the surface rotation of fixed plate installs the pivot, the surface and the fixed mounting that the pivot runs through the fixed plate have three-jaw chuck. The utility model discloses an axle type work piece is in the pivoted, and test probe can slide on its surface, and when there was pit or protruding on axle type work piece surface, test probe will produce thereupon and reciprocate, makes laser sensor can detect test probe's removal to carry out automatic recording, thereby can detect axle type work piece surface's circularity and axiality, and then judge whether qualified axle type work piece, can effectual improvement to the detection efficiency of axle type work piece.

Description

Nondestructive detection equipment for metal material reinspection

Technical Field

The utility model relates to a metal detection equipment technical field especially relates to a non-destructive testing equipment is used in metal material reinspection.

Background

Nondestructive testing is a general term for all technical means for detecting whether a defect or unevenness exists in a test object by using characteristics such as sound, light, magnetism, and electricity without damaging or affecting the use performance of the test object, giving information such as the size, position, property, and number of the defect, and further determining the technical state of the test object.

The existing nondestructive detection equipment for metal material reinspection generally needs to manually use tools such as calipers to sequentially measure the surfaces of shaft workpieces in the process of detecting the roundness and the coaxiality of the shaft workpieces, so that the detection process is troublesome and the detection efficiency is low.

SUMMERY OF THE UTILITY MODEL

The utility model aims at solving the defects existing in the prior art and providing a nondestructive testing device for metal material reinspection.

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

the utility model provides a non-destructive check out test set for metal material reinspection, includes the bottom plate, the last surface symmetry fixed mounting of bottom plate has two fixed plates, one of them the outer fixed surface of fixed plate installs pneumatic telescopic link, pneumatic telescopic link's flexible end runs through the surface and the fixed mounting of fixed plate has the ejector pin, another the surface of fixed plate rotates installs the pivot, the pivot runs through the surface and the fixed mounting of fixed plate has three-jaw chuck, is close to the outer fixed surface of a fixed plate of pivot installs the L shaped plate, the outer fixed surface of L shaped plate installs the motor, the output of motor run through the surface of L shaped plate and with the terminal surface fixed mounting of pivot, two rotate between the fixed plate and install drive screw, drive screw's surface threaded connection has the movable block, the surface of movable block is equipped with detection mechanism, two be equipped with stop gear between fixed plate and the movable block, be equipped with drive mechanism between drive screw and the pivot.

As a further scheme of the utility model, detection mechanism is including setting up in the rectangle frame of movable block below, the bottom of rectangle frame is inserted and is equipped with detection probe, detection probe's top runs through the bottom and the fixed mounting of rectangle frame has the spacing ring, the roof fixed mounting of rectangle frame has laser sensor, detection probe's surface is equipped with reset assembly, the top of rectangle frame is equipped with adjusting part.

As a further aspect of the utility model, the subassembly that resets includes that fixed mounting is close to the solid fixed ring of its bottom surface in test probe, test probe's surface cover is equipped with compression spring, compression spring sets up between the lower surface of rectangle frame and solid fixed ring's upper surface.

As a further aspect of the utility model, the adjusting part includes fixed mounting in the lifting screw on rectangle frame top, lifting screw's top is run through the upper surface of movable block and rather than threaded connection, lifting screw's top fixed mounting has the rocking wheel.

As a further aspect of the present invention, the limiting mechanism includes a limiting rod fixedly installed between two fixing plates, the limiting rod runs through the outer surface of the moving block and is installed with the moving block in a sliding manner.

As a further aspect of the present invention, the transmission mechanism includes two belt pulleys, two of which are respectively and fixedly installed on the outer surfaces of the rotating shaft and the transmission screw rod, the outer surface cover of the belt pulley is provided with a belt.

As a further proposal of the utility model, the upper surface of the bottom plate is evenly run through and is provided with a plurality of mounting holes.

The utility model has the advantages that:

1. the motor drives the rotating shaft to rotate, the rotating shaft can drive the shaft workpiece to rotate through the three-jaw chuck, when the rotating shaft rotates, the belt wheel fixedly mounted on the outer surface of the rotating shaft drives the transmission screw to rotate through the belt, the transmission screw drives the movable block in threaded connection with the outer surface of the transmission screw to move along the axis direction of the transmission screw, the rectangular frame arranged on the movable block drives the detection probe to move, the detection probe can be attached to the surface of the shaft workpiece to move in a horizontal moving mode, when the shaft workpiece rotates, the detection probe can slide on the surface of the shaft workpiece, when pits or bulges exist on the surface of the shaft workpiece, the detection probe can move up and down along with the shaft workpiece, the laser sensor can detect the movement of the detection probe and automatically record the movement of the detection probe, the roundness and the coaxiality of the surface of the shaft workpiece can be detected, whether the shaft workpiece is qualified or not can be judged, and the detection efficiency of the shaft workpiece can be effectively improved.

2. Before shaft workpieces with different diameters are detected, the lifting screw is driven to rotate through the rocking wheel, so that the lifting screw can drive the rectangular frame and the whole height of the detection probe to be adjusted, and the detection probe can abut against the surface of the shaft workpieces.

Drawings

Fig. 1 is a schematic diagram of a right-view structure of a nondestructive testing apparatus for metal material inspection according to the present invention;

fig. 2 is a left side view structural diagram of a nondestructive testing apparatus for metal material inspection according to the present invention;

fig. 3 is a schematic diagram of a right-view structure of a nondestructive testing apparatus for metal material inspection according to the present invention;

FIG. 4 is an enlarged view of the structure at A in FIG. 3;

fig. 5 is a schematic structural diagram of a bottom plate of the nondestructive testing device for metal material inspection according to the present invention.

In the figure: 1. a base plate; 2. a fixing plate; 3. a pneumatic telescopic rod; 4. a top rod; 5. a three-jaw chuck; 6. an L-shaped plate; 7. a motor; 8. a rotating shaft; 9. a drive screw; 10. a moving block; 11. a limiting rod; 12. a lifting screw; 13. rocking the wheel; 14. a rectangular frame; 15. detecting the probe; 16. a limiting ring; 17. a laser sensor; 18. a fixing ring; 19. a compression spring; 20. a pulley; 21. a belt; 22. and (7) installing holes.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments.

It should be noted that the embodiments and features of the embodiments in the present application may be combined with each other without conflict. The present invention will be described in detail below with reference to the accompanying drawings in conjunction with embodiments.

Example 1

Referring to fig. 1-4, a nondestructive testing device for metal material reinspection, including a bottom plate 1, two fixed plates 2 are symmetrically and fixedly mounted on the upper surface of the bottom plate 1, wherein a pneumatic telescopic rod 3 is fixedly mounted on the outer surface of one fixed plate 2, a telescopic end of the pneumatic telescopic rod 3 penetrates through the outer surface of the fixed plate 2 and is fixedly mounted with a push rod 4, a rotating shaft 8 is rotatably mounted on the outer surface of the other fixed plate 2, the rotating shaft 8 penetrates through the outer surface of the fixed plate 2 and is fixedly mounted with a three-jaw chuck 5, an L-shaped plate 6 is fixedly mounted on the outer surface of one fixed plate 2 close to the rotating shaft 8, a motor 7 is fixedly mounted on the outer surface of the L-shaped plate 6, an output end of the motor 7 penetrates through the outer surface of the L-shaped plate 6 and is fixedly mounted with the end surface of the rotating shaft 8, a transmission screw 9 is rotatably mounted between the two fixed plates 2, a movable block 10 is in threaded connection with the outer surface of the transmission screw 9, a detection mechanism is disposed on the outer surface of the movable block 10, a limit mechanism is disposed between the two fixed plates 2 and the movable block 10, and a transmission mechanism is disposed between the transmission screw 9 and the rotating shaft 8.

In this embodiment, the detection mechanism includes a rectangular frame 14 disposed below the moving block 10, a detection probe 15 is inserted into the bottom of the rectangular frame 14, and the detection probe 15 is disposed right above the axis direction of the ejector rod 4, so that when the detection probe 15 detects the surface of the shaft workpiece, the detection probe 15 can be perpendicular to the axis of the shaft workpiece, and the detection accuracy is improved; the top end of the detection probe 15 penetrates through the bottom of the rectangular frame 14 and is fixedly provided with a limiting ring 16, the top wall of the rectangular frame 14 is fixedly provided with a laser sensor 17, the outer surface of the detection probe 15 is provided with a reset assembly, and the top end of the rectangular frame 14 is provided with an adjusting assembly.

In this embodiment, reset unit is including fixed mounting in detecting probe 15 near the solid fixed ring 18 of its bottom surface, detecting probe 15's surface cover is equipped with compression spring 19, compression spring 19 sets up between the lower surface of rectangle frame 14 and the upper surface of solid fixed ring 18, when examining axle class work piece, detecting probe 15 offsets with the surface of axle class work piece, make compression spring 19 compressed to certain length, so that detecting probe 15 can move down when meetting axle class work piece surperficial pit, make laser sensor 17 can detect detecting probe 15's removal.

In this embodiment, the adjusting assembly includes a lifting screw 12 fixedly mounted on the top end of the rectangular frame 14, the top end of the lifting screw 12 penetrates through the upper surface of the moving block 10 and is in threaded connection with the upper surface, and the top end of the lifting screw 12 is fixedly mounted with a rocking wheel 13.

In this embodiment, the limiting mechanism includes a limiting rod 11 fixedly installed between the two fixing plates 2, and the limiting rod 11 penetrates through the outer surface of the moving block 10 and is installed in a sliding manner with the outer surface, so that the moving block 10 can slide along the axial direction of the limiting rod 11 when moving, and the moving block 10 is prevented from rotating.

In this embodiment, the transmission mechanism includes two belt wheels 20 respectively fixedly mounted on the outer surfaces of the rotating shaft 8 and the transmission screw 9, and a belt 21 is sleeved on the outer surfaces of the two belt wheels 20.

From the above description, it can be seen that the above-mentioned embodiments of the present invention achieve the following technical effects: when shaft workpieces are detected, the shaft workpieces are clamped and fixed through the three-jaw chuck 5, the end parts of the shaft workpieces are tightly abutted through the push rods 4 pushed by the pneumatic telescopic rods 3, and the shaft workpieces are prevented from swinging when rotating; the motor 7 drives the rotating shaft 8 to rotate, so that the rotating shaft 8 can drive the shaft workpiece to rotate through the three-jaw chuck 5, while the rotating shaft 8 rotates, the belt pulley 20 fixedly arranged on the outer surface of the rotating shaft 8 drives the transmission screw 9 to rotate through the belt 21, so that the transmission screw 9 drives the moving block 10 in threaded connection with the outer surface to move along the axis direction, the rectangular frame 14 arranged on the moving block 10 drives the detection probe 15 to move, the detection probe 15 can be in translation close to the surface of the shaft workpiece, so that the shaft workpiece can rotate and the detection probe 15 can slide on the surface of the shaft workpiece, when the surface of the shaft workpiece has pits or bulges, the detection probe 15 can move up and down along with the surface of the shaft workpiece, the laser sensor 17 can detect the movement of the detection probe 15 and automatically record the movement of the detection probe 15, the roundness and the coaxiality of the surface of the shaft workpiece can be detected, whether the shaft workpiece is qualified or not can be further judged, and the detection efficiency of the shaft workpiece can be effectively improved; before detecting shaft workpieces with different diameters, the rocking wheel 13 drives the lifting screw 12 to rotate, so that the lifting screw 12 can drive the rectangular frame 14 and the whole height of the detection probe 15 to be adjusted, the detection probe 15 can be abutted against the surface of the shaft workpiece, and the specific connection mode and the working principle of a plurality of electrical components are well known in the art and are not described in detail herein.

Example 2

Referring to fig. 5, a nondestructive testing device for metal material reinspection, including a base plate 1, two fixed plates 2 are symmetrically and fixedly mounted on the upper surface of the base plate 1, wherein a pneumatic telescopic rod 3 is fixedly mounted on the outer surface of one fixed plate 2, a telescopic end of the pneumatic telescopic rod 3 penetrates through the outer surface of the fixed plate 2 and is fixedly mounted with a push rod 4, a rotating shaft 8 is rotatably mounted on the outer surface of the other fixed plate 2, the rotating shaft 8 penetrates through the outer surface of the fixed plate 2 and is fixedly mounted with a three-jaw chuck 5, an L-shaped plate 6 is fixedly mounted on the outer surface of one fixed plate 2 close to the rotating shaft 8, a motor 7 is fixedly mounted on the outer surface of the L-shaped plate 6, an output end of the motor 7 penetrates through the outer surface of the L-shaped plate 6 and is fixedly mounted with the end surface of the rotating shaft 8, a transmission screw 9 is rotatably mounted between the two fixed plates 2, the outer surface of the transmission screw 9 is in threaded connection with a moving block 10, a detection mechanism is arranged on the outer surface of the moving block 10, a limit mechanism is arranged between the two fixed plates 2 and the moving block 10, and a transmission mechanism is arranged between the transmission screw 9 and the rotating shaft 8.

In this embodiment, the detection mechanism includes a rectangular frame 14 disposed below the moving block 10, a detection probe 15 is inserted into the bottom of the rectangular frame 14, and the detection probe 15 is disposed right above the axis direction of the ejector rod 4, so that when the detection probe 15 detects the surface of the shaft workpiece, the detection probe 15 can be perpendicular to the axis of the shaft workpiece, and the detection accuracy is improved; the top of detecting probe 15 runs through the bottom of rectangular frame 14 and fixed mounting has spacing ring 16, and the roof fixed mounting of rectangular frame 14 has laser sensor 17, and the surface of detecting probe 15 is equipped with reset assembly, and the top of rectangular frame 14 is equipped with adjusting part.

In this embodiment, reset unit is including fixed mounting in detecting probe 15 near the solid fixed ring 18 of its bottom surface, detecting probe 15's surface cover is equipped with compression spring 19, compression spring 19 sets up between the lower surface of rectangle frame 14 and the upper surface of solid fixed ring 18, when examining axle class work piece, detecting probe 15 offsets with the surface of axle class work piece, make compression spring 19 compressed to certain length, so that detecting probe 15 can move down when meetting axle class work piece surperficial pit, make laser sensor 17 can detect detecting probe 15's removal.

In this embodiment, the adjusting assembly includes a lifting screw 12 fixedly mounted on the top end of the rectangular frame 14, the top end of the lifting screw 12 penetrates through the upper surface of the moving block 10 and is in threaded connection with the upper surface, and the top end of the lifting screw 12 is fixedly mounted with a rocking wheel 13.

In this embodiment, the limiting mechanism includes a limiting rod 11 fixedly installed between the two fixing plates 2, and the limiting rod 11 penetrates through the outer surface of the moving block 10 and is installed in a sliding manner with the outer surface, so that the moving block 10 can slide along the axial direction of the limiting rod 11 when moving, and the moving block 10 is prevented from rotating.

In this embodiment, the transmission mechanism includes two belt wheels 20 respectively fixedly installed on the outer surfaces of the rotating shaft 8 and the transmission screw 9, and a belt 21 is sleeved on the outer surfaces of the two belt wheels 20.

In this embodiment, a plurality of mounting holes 22 have evenly been seted up in the upper surface of bottom plate 1 through, and when using, the convenient to use bolt passes mounting hole 22 and fixes bottom plate 1 on testing platform, and is more stable when making this equipment use.

From the above description, it can be seen that the above-mentioned embodiments of the present invention achieve the following technical effects: when shaft workpieces are detected, the shaft workpieces are clamped and fixed through the three-jaw chuck 5, the end parts of the shaft workpieces are tightly abutted through the push rod 4 pushed by the pneumatic telescopic rod 3, and the shaft workpieces are prevented from swinging when rotating; the motor 7 drives the rotating shaft 8 to rotate, so that the rotating shaft 8 can drive the shaft-type workpiece to rotate through the three-jaw chuck 5, while the rotating shaft 8 rotates, the belt pulley 20 fixedly arranged on the outer surface of the rotating shaft 8 drives the transmission screw 9 to rotate through the belt 21, so that the transmission screw 9 drives the movable block 10 in threaded connection with the outer surface of the movable block to move along the axis direction, the rectangular frame 14 arranged on the movable block 10 drives the detection probe 15 to move, so that the detection probe 15 can be attached to the surface of the shaft-type workpiece to translate, while the shaft-type workpiece rotates, the detection probe 15 can slide on the surface of the shaft-type workpiece, when the surface of the shaft-type workpiece has pits or bulges, the detection probe 15 moves up and down, so that the laser sensor 17 can detect the movement of the detection probe 15 and automatically record, thereby detecting the roundness and coaxiality of the surface of the shaft-type workpiece, and further judging whether the shaft-type workpiece is qualified; before shaft workpieces with different diameters are detected, the rocking wheel 13 drives the lifting screw 12 to rotate, so that the lifting screw 12 can drive the rectangular frame 14 and the whole height of the detection probe 15 to be adjusted, so that the detection probe 15 can be abutted against the surface of the shaft workpieces, and the specific connection mode and the working principle of a plurality of electrical components are well known in the art and are not described in detail herein.

For ease of description, spatially relative terms such as "over 8230," "upper surface," "above," and the like may be used herein to describe the spatial positional relationship of one device or feature to other devices or features as illustrated in the figures. It will be understood that the spatially relative terms are intended to encompass different orientations of the device in use or operation in addition to the orientation depicted in the figures. For example, if a device in the figures is turned over, devices described as "above" or "on" other devices or configurations would then be oriented "below" or "under" the other devices or configurations. Thus, the exemplary terms "at 8230; \8230; 'above" may include both orientations "at 8230; \8230;' above 8230; 'at 8230;' below 8230;" above ". The device may be otherwise oriented (rotated 90 degrees or at other orientations) and the spatially relative descriptors used herein interpreted accordingly.

It is noted that the terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of exemplary embodiments according to the present application. As used herein, the singular forms "a", "an", and "the" are intended to include the plural forms as well, and it should be understood that when the terms "comprises" and/or "comprising" are used in this specification, they specify the presence of stated features, steps, operations, devices, components, and/or combinations thereof, unless the context clearly indicates otherwise.

It should be noted that the terms "first," "second," and the like in the description and claims of this application and in the drawings described above are used for distinguishing between similar elements and not necessarily for describing a particular sequential or chronological order. It is to be understood that the data so used may be interchanged under appropriate circumstances such that, for example, embodiments of the application described herein may be implemented in sequences other than those illustrated or described herein. Furthermore, the terms "comprises," "comprising," and "having," and any variations thereof, are intended to cover a non-exclusive inclusion, such that a process, method, system, article, or apparatus that comprises a list of steps or elements is not necessarily limited to those steps or elements expressly listed, but may include other steps or elements not expressly listed or inherent to such process, method, article, or apparatus.

The above description is only a preferred embodiment of the present invention and is not intended to limit the present invention, and various modifications and changes may be made by those skilled in the art. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (7)

1. A nondestructive testing device for metal material reinspection comprises a base plate (1), it is characterized in that two fixing plates (2) are symmetrically and fixedly arranged on the upper surface of the bottom plate (1), the outer surface of one of the fixed plates (2) is fixedly provided with a pneumatic telescopic rod (3), the telescopic end of the pneumatic telescopic rod (3) penetrates through the outer surface of the fixed plate (2) and is fixedly provided with a mandril (4), the outer surface of the other fixed plate (2) is rotatably provided with a rotating shaft (8), the rotating shaft (8) penetrates through the outer surface of the fixing plate (2) and is fixedly provided with a three-jaw chuck (5), the outer surface of one fixing plate (2) close to the rotating shaft (8) is fixedly provided with an L-shaped plate (6), the outer surface of the L-shaped plate (6) is fixedly provided with a motor (7), the output end of the motor (7) penetrates through the outer surface of the L-shaped plate (6) and is fixedly arranged with the end surface of the rotating shaft (8), a transmission screw (9) is rotatably arranged between the two fixing plates (2), the outer surface of the transmission screw (9) is connected with a movable block (10) in a threaded manner, the outer surface of the moving block (10) is provided with a detection mechanism, a limit mechanism is arranged between the two fixed plates (2) and the moving block (10), and a transmission mechanism is arranged between the transmission screw rod (9) and the rotating shaft (8).

2. The nondestructive testing device for metal material reinspection according to claim 1, wherein the detection mechanism comprises a rectangular frame (14) disposed below the moving block (10), a detection probe (15) is inserted into a bottom of the rectangular frame (14), a top end of the detection probe (15) penetrates through the bottom of the rectangular frame (14) and is fixedly provided with a limit ring (16), a laser sensor (17) is fixedly mounted on a top wall of the rectangular frame (14), a reset component is disposed on an outer surface of the detection probe (15), and an adjusting component is disposed on the top end of the rectangular frame (14).

3. The nondestructive testing device for metal material reinspection according to claim 2, wherein the reset assembly comprises a fixing ring (18) fixedly mounted on the outer surface of the detection probe (15) near the bottom thereof, the outer surface of the detection probe (15) is sleeved with a compression spring (19), and the compression spring (19) is arranged between the lower surface of the rectangular frame (14) and the upper surface of the fixing ring (18).

4. The nondestructive testing device for metal material reinspection according to claim 2, wherein the adjusting component comprises a lifting screw (12) fixedly mounted at the top end of a rectangular frame (14), the top end of the lifting screw (12) penetrates through the upper surface of the moving block (10) and is in threaded connection with the upper surface, and a rocking wheel (13) is fixedly mounted at the top end of the lifting screw (12).

5. The nondestructive testing device for metal material reinspection according to claim 1, wherein the limiting mechanism comprises a limiting rod (11) fixedly installed between two fixing plates (2), and the limiting rod (11) penetrates through the outer surface of the moving block (10) and is slidably installed with the moving block.

6. The nondestructive testing device for metal material reinspection according to claim 1, wherein the transmission mechanism includes two belt wheels (20) fixedly mounted on the outer surfaces of the rotating shaft (8) and the transmission screw (9), respectively, and a belt (21) is sleeved on the outer surfaces of the two belt wheels (20).

7. The nondestructive testing device for metal material reinspection according to claim 1, wherein a plurality of mounting holes (22) are uniformly formed through the upper surface of the base plate (1).

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