CN116878555A

CN116878555A - Eddy current sensor adjusts support

Info

Publication number: CN116878555A
Application number: CN202311112524.5A
Authority: CN
Inventors: 李盼盼; 杨子江; 李华伟; 钟恒昌; 夏军; 陈虎; 张永清; 宋晓东; 谭敏霞
Original assignee: Jiangyin Quansheng Automation Instrument Co ltd
Current assignee: Jiangyin Quansheng Automation Instrument Co ltd
Priority date: 2023-08-31
Filing date: 2023-08-31
Publication date: 2023-10-13
Anticipated expiration: 2043-08-31
Also published as: CN116878555B

Abstract

The utility model discloses an eddy current sensor adjusting support, which belongs to the technical field of sensor installation and aims to solve the problems that in order to ensure normal use of an eddy current sensor, the eddy current sensor is usually required to be installed on the support for fixing after being checked by a checking device, the whole process is required to operate the checking device and the support at the same time, the installation efficiency is low, the use cost and the operation difficulty of the eddy current sensor are improved.

Description

Eddy current sensor adjusts support

Technical Field

The utility model relates to the technical field of sensor installation, in particular to an electric vortex sensor adjusting support.

Background

The eddy current sensor can measure the distance between the measured metal conductor and the probe surface in a static and dynamic non-contact mode with high linearity and high resolution. In order to facilitate the disassembly and assembly of the eddy current sensor, a support is generally used for installing and fixing the eddy current sensor, and the probe position of the eddy current sensor is conveniently moved and adjusted.

In document CN203869713U, an eddy current sensor adjusting support is disclosed, which comprises a rectangular bottom plate, wherein two sides of the bottom plate are vertically connected with side plates, the top of each side plate is connected with a top baffle, the bottom plate, the side plates and the top baffle are integrally formed, and sliding grooves are formed on two sides of the bottom plate; the two ends of the top baffle are provided with bayonets, and the end baffle is fixed on the bottom plate through the bayonets; the bottom plate is also provided with a sensor mounting bracket, two sides of the sensor mounting bracket are clamped into the sliding groove and are positioned between two end baffle plates, one end baffle plate is connected to the sensor mounting bracket through a spring, and the other end baffle plate is connected to the sensor mounting bracket through a screw. The utility model changes the traditional adjusting mode of the mounting position of the sensor, and changes the original adjustment of the mounting position of the sensor by adjusting the nuts on the sensor body into the adjustment of the mounting position of the sensor support, and only the screws on two sides and two ends are needed to be adjusted.

Furthermore, in document CN214121260U, a verification device of an eddy current sensor is disclosed, which comprises: comprising the following steps: the device comprises a bracket component, an eddy current sensor, a micrometer, a metal disc, a signal amplifier, a voltmeter and a power supply. According to the utility model, the metal disc is arranged at the end part of the micrometer, the relative motion of the micrometer and the eddy current sensor is utilized, so that the metal disc and the eddy current sensor relatively move, the feedback voltage generated by the relative motion is displayed in the voltmeter through the signal amplifier, the feedback voltage can be observed and recorded by adjusting the distance between the metal disc and the eddy current sensor through the signal amplifier and the voltmeter, and whether the eddy current sensor meets the requirements can be judged through the relation between the feedback voltage and the distance change.

In the installation process of the eddy current sensor disclosed in the prior art, after the eddy current sensor is usually required to be verified by the verification device, the eddy current sensor is installed on the support to be fixed, the whole process is not only required to operate the verification device, but also required to operate the support, the installation is very troublesome, the installation efficiency is low, and the use cost and the operation difficulty of the eddy current sensor are improved, so that the eddy current sensor is inconvenient to use.

In order to solve the problems, an eddy current sensor adjusting support is provided.

Disclosure of Invention

The utility model aims to provide an eddy current sensor adjusting support which adopts the device to work, so that the problems that in the background, in order to ensure the normal use of an eddy current sensor, the eddy current sensor is usually required to be checked by a checking device and then is installed on the support to be fixed, the checking device is required to be operated in the whole process, and meanwhile, the support is required to be operated, the installation is very troublesome, the installation efficiency is low, and the use cost and the operation difficulty of the eddy current sensor are improved.

In order to achieve the above purpose, the present utility model provides the following technical solutions: the utility model provides an eddy current sensor adjusts support, includes base and horizontal slidable mounting T type installation piece in the base inner chamber, runs through fixed mounting on the T type installation piece and has eddy current sensor, middle part one side department movable mounting of base inner chamber has the screw thread actuating lever, and the screw thread actuating lever runs through the screw thread and installs in the T type installation piece, embedding slidable mounting has the metal sheet in the one end inner chamber of base, and flexible subassembly is installed to the bottom of metal sheet, the movable mounting of other end department of base revolves and twists the gear wheel, installs fastening screw through the screw grafting on the opposite side outer wall of T type installation piece, embedding longitudinal sliding mounting has the extrusion push pedal on the middle part outer wall of base opposite side.

Further, the base includes bottom plate and embedding fixed mounting income board in bottom plate one end department, and the other end department embedding fixed mounting of bottom plate has the connecting plate, and the top surface middle part department of bottom plate is provided with protruding tee bend groove, is provided with the arc spout on the both sides inner wall of bottom plate inner chamber respectively, is provided with outer wide groove on the middle part outer wall of bottom plate opposite side, and is provided with interior narrow groove on the middle part lateral wall of outer wide groove inner chamber.

Further, be provided with T type change groove and T type round hole on the middle part outer wall of connecting plate outer end respectively, and T type round hole sets up in one side department of T type change groove, be the intercommunication setting between T type round hole and the T type change groove, top surface one end middle part department of income board is provided with L type groove, and bottom surface one end department of L type groove inner chamber is provided with T type spout, be provided with T type vertical spout on the opposite side inner wall of L type groove inner chamber other end, be provided with circular through hole on the middle part one side outer wall of income board other end, and the periphery fixed mounting of circular through hole inner chamber opening part has multiple triangle snap ring.

Further, the T-shaped mounting block comprises a lower sliding block and a lower clamping block fixedly mounted on the top surface of the lower sliding block, an upper clamping block is mounted on the lower clamping block, tightening screws are respectively mounted on two sides of the upper clamping block in a penetrating mode, the output ends of the tightening screws are mounted on the lower clamping block in a threaded inserting mode, a threaded round hole is formed in the outer wall of one side of the middle of the other end of the lower sliding block, and a threaded round groove is formed in the outer wall of the middle of the other side of the lower sliding block.

Further, the screw driving rod comprises a screw sleeve column and a transformation sliding column which penetrates through the screw sleeve column and is slidably mounted in an inner cavity of the screw sleeve column, a split gear is movably mounted at one end portion of the screw sleeve column, a T-shaped bulge is arranged at one end portion of the screw sleeve column, a penetrating sliding hole is formed in the middle portion of the screw sleeve column, the transformation sliding column penetrates through the penetrating sliding hole, an inner square groove is formed in one end portion of the penetrating sliding hole in a communicating mode, a T-shaped connecting groove is formed in the outer wall of the middle portion of the other end of the split gear, a T-shaped bulge is movably mounted in the T-shaped connecting groove, an inner clamping groove is formed in the side wall of the middle portion of the inner cavity of the T-shaped connecting groove, an embedded groove is formed in the outer peripheral outer wall of the other end of the split gear, and a trapezoid clamping block is mounted at the opening of the inner cavity of the embedded groove in an elastic sliding mode through a spring group.

Further, the transformation slide column comprises a hexagonal nut and a middle slide column fixedly mounted on the outer wall of the middle part of one end of the hexagonal nut, a square clamping block is fixedly mounted at one end of the middle slide column, a pinion is fixedly sleeved on the outer peripheral wall of the other end of the middle slide column, an elastic groove is formed in the outer peripheral wall of one end of the hexagonal nut, an elastic slide column is mounted at an inner cavity opening of the elastic groove in an elastic sliding manner through a connecting spring, and an anti-abrasion ball is mounted at one end of the elastic slide column.

Further, the bottom surface middle part department of metal sheet is provided with T type kerve, flexible subassembly includes X type telescopic link and the T type restriction slider of movable mounting in X type telescopic link four corners department respectively, the T type restriction slider that is located the upper end slides respectively and sets up in T type kerve, the T type restriction slider that is located the lower extreme slides respectively and sets up in T type spout, movable mounting has square splicing block on the other end outer wall of the T type restriction slider that is located X type telescopic link one side lower extreme, square splicing block passes through lateral wall spring elasticity longitudinal sliding mounting on the inner chamber bottom surface of L type groove, fixed mounting has the rack on the opposite side middle part outer wall of square splicing block, and meshing connection between components of a whole that can function independently gear and the rack, the opposite side fixed mounting of rack has the jack post, and fixed mounting has T type vertical slider on the other end outer wall of jack post opposite side, and T type vertical slider slides and sets up in T type vertical spout, the jack post passes through bottom spring elasticity mounting on the inner chamber bottom surface of L type groove.

Further, an embedded side groove is formed in the outer wall of the middle of the other side of the square connecting block, an embedded vertical sliding block is fixedly arranged at one side end of the rack, and the embedded vertical sliding block is elastically and slidably arranged in the embedded side groove through a reset spring.

Further, the screwing large gear comprises a hexagonal screwing head and a large gear fixedly arranged on the output end of the hexagonal screwing head, and the large gear is in meshed connection with the small gear.

Further, the extrusion push plate comprises a push plate main body and a trapezoid lower push block fixedly installed on the outer wall of the middle part of one side of the push plate main body, the front end part of the trapezoid lower push block is arranged at the other side of the telescopic column, and the output end of the fastening screw penetrates through the push plate main body.

Compared with the prior art, the utility model has the following beneficial effects: when the eddy current sensor needs to be calibrated, the eddy current sensor can be fixedly installed on the T-shaped installation block, then the screw driving rod is pushed forward and screwed by using the wrench, the telescopic component is driven to jack up the metal plate upwards by the screw driving rod in the process, the metal plate moves to the position opposite to the eddy current sensor, then the operator can directly screw the screw driving rod by removing the front pushing force of the screw driving rod, the eddy current sensor can be pushed to move and calibrate, after calibration, the position of the eddy current sensor can be further regulated by screwing the screw driving rod, the structure is ingenious, the position regulation of the eddy current sensor and the regulation of the metal plate can be respectively realized by different forces and driving modes of the screw driving rod, the use function of the regulating support is improved, the calibration and installation efficiency of the eddy current sensor is greatly improved, and the use experience is good.

Drawings

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

FIG. 2 is a schematic top view of the overall cross-section of the present utility model;

FIG. 3 is a schematic top view of a base of the present utility model;

FIG. 4 is an enlarged view of FIG. 3A in accordance with the present utility model;

FIG. 5 is a schematic cross-sectional view of a threaded drive rod of the present utility model;

FIG. 6 is a schematic perspective view of a split gear according to the present utility model;

FIG. 7 is a schematic perspective view of a screw-on large gear of the present utility model;

FIG. 8 is a schematic plan view of a telescopic assembly according to the present utility model;

FIG. 9 is a schematic cross-sectional view of one end of the base of the present utility model;

FIG. 10 is a schematic view of the square joint and rack connection structure of the present utility model;

fig. 11 is a schematic diagram of a split structure of a T-shaped mounting block according to the present utility model.

In the figure: 1. a base; 11. a bottom plate; 111. a convex three-way groove; 112. an arc chute; 113. an outer wide groove; 114. an inner narrow groove; 12. a connecting plate; 121. a T-shaped rotary groove; 122. a T-shaped round hole; 13. a receiving plate; 131. an L-shaped groove; 132. a T-shaped chute; 133. a circular through hole; 134. multiple triangular snap rings; 135. t-shaped vertical sliding grooves; 2. a T-shaped mounting block; 21. a lower slide block; 211. a threaded round hole; 212. a thread circular groove; 22. a lower clamping block; 23. an upper clamping block; 24. tightening a screw; 3. an eddy current sensor; 4. a threaded drive rod; 41. a threaded sleeve column; 411. t-shaped bulges; 412. penetrating the sliding hole; 413. an inner square groove; 42. a conversion slide column; 421. a hexagonal nut; 422. a middle slide column; 423. a pinion gear; 424. an elastic groove; 425. an elastic strut; 426. a connecting spring; 427. wear-resistant balls; 428. a square clamping block; 43. a split gear; 431. a T-shaped connecting groove; 432. an inner clamping groove; 433. embedding the groove; 434. a trapezoidal clamping block; 435. a spring set; 5. a metal plate; 51. a T-shaped bottom groove; 6. a telescoping assembly; 61. an X-shaped telescopic rod; 62. a T-shaped limit slider; 63. square connecting blocks; 631. embedding the side grooves; 64. a side wall spring; 65. a rack; 651. embedding a vertical sliding block; 652. a return spring; 66. a telescopic column; 67. t-shaped vertical sliding blocks; 68. a bottom spring; 7. screwing the large gear; 71. hexagonal screwing head; 72. a large gear; 8. a fastening screw; 9. extruding a push plate; 91. a push plate body; 92. the trapezoid pushes down the block.

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. All other embodiments, which can be made by those skilled 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.

In order to solve the technical problems that in order to ensure the normal use of the eddy current sensor 3, after the eddy current sensor is usually required to be subjected to the verification by the verification device, the eddy current sensor is installed on the support to be fixed, the verification device is required to be operated in the whole process, the support is required to be operated simultaneously, the installation is very troublesome, the installation efficiency is low, the use cost and the operation difficulty of the eddy current sensor 3 are also improved, and as shown in fig. 1-11, the following preferable technical scheme is provided:

the utility model provides an eddy current sensor adjusts support, including base 1 and horizontal slidable mounting T type installation piece 2 in the inner chamber of base 1, run through fixed mounting on the T type installation piece 2 and have eddy current sensor 3, middle part one side department movable mounting of base 1 inner chamber has screw thread drive pole 4, and screw thread drive pole 4 runs through the installation in T type installation piece 2 through the screw thread, embedding slidable mounting has metal sheet 5 in the one end inner chamber of base 1, and telescopic subassembly 6 is installed to the bottom of metal sheet 5, movable mounting of the other end department of base 1 is revolved and is twisted gear wheel 7, install fastening screw 8 through the screw grafting on the opposite side outer wall of T type installation piece 2, embedding longitudinal sliding mounting has extrusion push pedal 9 on the middle part outer wall of base 1 opposite side.

The base 1 comprises a bottom plate 11 and a receiving plate 13 embedded and fixedly installed at one end of the bottom plate 11, a connecting plate 12 is embedded and fixedly installed at the other end of the bottom plate 11, a convex three-way groove 111 is arranged in the middle of the top surface of the bottom plate 11, arc-shaped sliding grooves 112 are respectively arranged on the inner walls of two sides of the inner cavity of the bottom plate 11, an outer wide groove 113 is arranged on the outer wall of the middle of the other side of the bottom plate 11, an inner narrow groove 114 is arranged on the middle side wall of the inner cavity of the outer wide groove 113, the inner narrow groove 114 is communicated with the convex three-way groove 111, the extrusion push plate 9 is longitudinally and slidably installed in the outer wide groove 113 through balls, the T-shaped installation block 2 is transversely and slidably installed in the convex three-way groove 111 through the balls, the output end of a fastening screw 8 is penetratingly arranged in the outer wide groove 113 and the inner narrow groove 114, an operator can drive the T-shaped installation block 2 to slide on the base 1 through screwing a threaded driving rod 4, an operator can screw the fastening screw 8 by a screw driver, the T-shaped mounting block 2 can be fixed by pressing the nut of the fastening screw 8 on the inner wall of the inner cavity of the outer wide groove 113, thus fixing the eddy current sensor 3, a T-shaped rotary groove 121 and a T-shaped round hole 122 are respectively arranged on the outer wall of the middle part of the outer end of the connecting plate 12, the T-shaped round hole 122 is arranged at one side of the T-shaped rotary groove 121, the T-shaped round hole 122 and the T-shaped rotary groove 121 are communicated, the screwing large gear 7 is movably arranged in the T-shaped rotary groove 121, an L-shaped groove 131 is arranged at the middle part of one end of the top surface of the collecting plate 13, a T-shaped sliding groove 132 is arranged at one end of the bottom surface of the inner cavity of the L-shaped groove 131, a T-shaped vertical sliding groove 135 is arranged on the inner wall of the other side of the other end of the inner cavity of the L-shaped groove 131, a round through hole 133 is arranged on the outer wall of one side of the middle part of the other end of the collecting plate 13, and the periphery of the opening of the inner cavity of the circular through hole 133 is fixedly provided with a plurality of triangular snap rings 134, the side wall of one end of the inner cavity of the outer wide groove 113 is communicated with the L-shaped groove 131, and one end part of the threaded driving rod 4 is movably penetrated and installed in the circular through hole 133 through a ball.

The T-shaped mounting block 2 comprises a lower sliding block 21 and a lower clamping block 22 fixedly mounted on the top surface of the lower sliding block 21, an upper clamping block 23 is mounted on the lower clamping block 22, tightening screws 24 are respectively installed on two sides of the upper clamping block 23 in a penetrating manner, the output ends of the tightening screws 24 are mounted on the lower clamping block 22 in a penetrating manner through threads, grooves matched with the eddy current sensor 3 are respectively formed in the inner side of the lower clamping block 22 and the inner side of the upper clamping block 23, after the eddy current sensor 3 is placed in the grooves in a penetrating manner, mutual compression fixation between the lower clamping block 22 and the upper clamping block 23 can be achieved through screwing the tightening screws 24, so that the eddy current sensor 3 can be clamped between the lower clamping block 22 and the upper clamping block 23, the tightening screws 24 are reversely screwed when the eddy current sensor 3 is dismounted, the mounting and dismounting are convenient, a threaded round hole 211 is formed in the outer wall of one side of the middle of the other end of the lower sliding block 21, a threaded round groove 212 is formed in the outer wall of the middle of the other side of the lower sliding block 21, and a threaded driving rod 4 is arranged in the threaded round hole 211 in the threaded round groove 211 in a penetrating manner through threads, and the output ends of the fastening 8 are mounted in the threaded round groove 212.

The screw driving rod 4 comprises a screw sleeve column 41 and a transformation slide column 42 penetrating and sliding in the inner cavity of the screw sleeve column 41, a split gear 43 is movably arranged at one end part of the screw sleeve column 41, the split gear 43 is arranged in an L-shaped groove 131, a T-shaped bulge 411 is arranged at one end part of the screw sleeve column 41, a penetrating slide hole 412 is arranged at the middle part of the screw sleeve column 41, the transformation slide column 42 penetrates and slides in the penetrating slide hole 412, one end part of the penetrating slide hole 412 is communicated with an inner square groove 413, a T-shaped connecting groove 431 is arranged on the outer wall of the middle part of the other end of the split gear 43, the T-shaped bulge 411 is movably arranged in the T-shaped connecting groove 431, an inner clamping groove 432 is arranged on the side wall of the middle part of the inner cavity of the T-shaped connecting groove 431, an embedded groove 433 is arranged on the outer peripheral outer wall of the other end of the split gear 43, a trapezoid clamping block 434 is elastically and slidably arranged at the opening of the inner cavity of the embedded groove 433 through a spring group, the trapezoid clamping blocks 434 are clamped and arranged on the multiple triangular clamping rings 134, through the clamping and matching arrangement between the trapezoid clamping blocks 434 and the multiple triangular clamping rings 134, the split gear 43 can only rotate clockwise but cannot rotate anticlockwise, so that after the metal plate 5 is supported, the metal plate 5 is prevented from being reset, the conversion sliding column 42 comprises a hexagonal nut 421 and a middle sliding column 422 fixedly arranged on the outer wall of the middle part of one end of the hexagonal nut 421, one end part of the middle sliding column 422 is fixedly provided with a square clamping block 428, the outer wall of the outer periphery of the other end of the middle sliding column 422 is fixedly sleeved with a pinion 423, the outer wall of the outer periphery of one end of the hexagonal nut 421 is provided with an elastic groove 424, an inner cavity opening of the elastic groove 424 is elastically and slidably provided with an elastic sliding column 425 through a connecting spring 426, one end part of the elastic sliding column 425 is provided with an anti-wear ball 427, by providing the anti-wear ball 427, when the hexagonal nut 421 is pressed and screwed on the surface of the connecting plate 12, the sliding abrasion and sliding friction between the hexagonal nut 421 and the surface of the connecting plate 12 can be reduced.

When the operator pushes the hexagonal nut 421 forward, the elastic sliding column 425 is pressed into the elastic groove 424, the connecting spring 426 is compressed, and when the operator releases the hexagonal nut 421, the whole transforming sliding column 42 is automatically reset under the elastic force of the connecting spring 426.

A T-shaped bottom groove 51 is provided at the middle of the bottom surface of the metal plate 5.

The telescopic assembly 6 comprises an X-shaped telescopic rod 61 and T-shaped limiting sliding blocks 62 which are movably arranged at four corners of the X-shaped telescopic rod 61 respectively, the T-shaped limiting sliding blocks 62 at the upper end are respectively and slidably arranged in T-shaped bottom grooves 51, the T-shaped limiting sliding blocks 62 at the lower end are respectively and slidably arranged in T-shaped sliding grooves 132, square connecting blocks 63 are movably arranged on the outer walls of the other ends of the T-shaped limiting sliding blocks 62 at the lower ends of one sides of the X-shaped telescopic rod 61, the square connecting blocks 63 are elastically and longitudinally slidably arranged on the bottom surfaces of inner cavities of the L-shaped grooves 131 through side wall springs 64, racks 65 are fixedly arranged on the outer walls of the middle parts of the other sides of the square connecting blocks 63, meshed with the racks 65 are connected, telescopic columns 66 are fixedly arranged at the other ends of the racks 65, T-shaped vertical sliding blocks 67 are fixedly arranged on the outer walls of the other sides of the telescopic columns 66, the T-shaped vertical sliding blocks 67 are slidably arranged in the T-shaped vertical sliding grooves 135, the telescopic columns 66 are elastically arranged on the bottom surfaces of the inner cavities of the L-shaped grooves 131 through the bottom springs 68, the X-shaped telescopic rods 61 are arranged, the lifting distance of the metal plates 5 can be lifted, accordingly, the metal plates 5 can be guaranteed to be lifted, the metal plates 5 can be directly face the position of a reset sensor 63 and are embedded into the side of the vertical sliding blocks 631, and are embedded into the side grooves 631, and the side grooves are embedded into the side grooves 631 through the side grooves which are arranged.

When the electric vortex sensor 3 needs to be calibrated, the electric vortex sensor 3 can be fixedly installed on the T-shaped installation block 2, afterwards, the hexagonal nut 421 is pushed forward by using a wrench, the square clamping block 428 can be pulled out from the inner square groove 413 and inserted into the inner clamping groove 432 in the process, an operator can screw the hexagonal nut 421 at this time and drive the split gear 43 to rotate on the premise of not driving the threaded sleeve column 41, the split gear 43 can drive the rack 65 to move to the other side, the square connecting block 63 can follow the rack 65 to move to the other side together, the telescopic column 66 can be shortened, the X-shaped telescopic rod 61 can be extended under the driving of the square connecting block 63, so that the metal plate 5 can be jacked up upwards, the metal plate 5 can be moved to the dead position of the electric vortex sensor 3, then an operator can directly rotate the hexagonal nut 421 by releasing the front thrust of the hexagonal nut 421, the electric vortex sensor 3 can be pushed to move and calibrated, after calibration, the position of the electric vortex sensor 3 can be further adjusted by screwing the hexagonal nut 421, the position of the hexagonal nut 3 can be further adjusted by screwing the hexagonal nut 421, and the electric vortex sensor 3 can be well adjusted by adjusting the position of the electric vortex sensor 3, and the electric vortex sensor 3 can be well adjusted by adjusting the electric vortex sensor 3.

In order to solve the technical problem of how to realize the fine adjustment of the positions of the T-shaped mounting block 2 and the eddy current sensor 3, as shown in fig. 2 to 7, the following preferred technical scheme is provided:

the screwing large gear 7 includes a hexagonal screwing head 71 and a large gear 72 fixedly mounted on an output end of the hexagonal screwing head 71, and the large gear 72 is engaged with the small gear 423, and a diameter of the large gear 72 is set to be much larger than a diameter of the small gear 423.

When an operator needs to finely adjust the position of the eddy current sensor 3, the hexagonal screwing head 71 can be screwed by using a wrench, the hexagonal screwing head 71 can drive the large gear 72 to rotate, the large gear 72 can drive the small gear 423 to rotate rapidly, the rapid rotation of the screw sleeve 41 can be realized under the clamping limit between the inner square groove 413 and the square clamping block 428, the T-shaped mounting block 2 and the eddy current sensor 3 can be driven to be quickly adjusted to a preset approximate position, then the hexagonal screwing head 71 is unscrewed to screw the hexagonal nut 421, the fine adjustment of the position of the eddy current sensor 3 can be completed, the fine adjustment of the position of the eddy current sensor 3 is realized while the adjustment efficiency is high, and the calibration and the later position adjustment of the eddy current sensor 3 are facilitated.

In order to solve the technical problem of how to complete automatic recovery of the metal plate 5 while fixing the positions of the T-shaped mounting block 2 and the eddy current sensor 3, as shown in fig. 5, 6 and 8-10, the following preferred technical scheme is provided:

the extrusion push plate 9 comprises a push plate main body 91 and a trapezoid lower push block 92 fixedly installed on the outer wall of the middle part of one end of the push plate main body 91, the front end part of the trapezoid lower push block 92 is arranged at the other side of the telescopic column 66, and the output end of the fastening screw 8 is arranged on the push plate main body 91 in a penetrating manner.

After the electric vortex sensor 3 is calibrated and the position is adjusted by an operator, the fixing screw 8 can be screwed, the final adjustment positions of the T-shaped mounting block 2 and the electric vortex sensor 3 are fixed, when the fastening screw 8 moves in the inner cavity of the outer wide groove 113, the push plate main body 91 is pushed to move inwards by the nut on the fastening screw 8, the push plate main body 91 drives the trapezoid push block 92 to press on the telescopic column 66, the rack 65 can be driven to move downwards by the telescopic column 66, when the rack 65 and the split gear 43 are separated, the X-shaped telescopic rod 61 can be automatically retracted under the elastic force of the side wall spring 64, the metal plate 5 can be automatically retracted until the nut on the fastening screw 8 is pressed and fastened on the inner cavity wall of the outer wide groove 113, the structure is ingenious, the recovery of the metal plate 5 can be automatically completed when the position of the electric vortex sensor 3 is fixed, and multiple effects can be simultaneously completed by one action, so that the installation calibration efficiency of the electric vortex sensor 3 and the use experience of a support are improved.

After the fastening screw 8 is screwed and loosened, the rack 65 can automatically reset under the action of the elasticity of the bottom spring 68, and the rack 65 and the split gear 43 are in meshed connection again, so that the next adjustment is convenient, the whole process is automatically realized, manual adjustment and reset are not needed, and the use experience is good.

It is noted that relational terms such as first and second, and the like are used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Moreover, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

Although embodiments of the present utility model have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made therein without departing from the principles and spirit of the utility model, the scope of which is defined in the appended claims and their equivalents.

Claims

1. The utility model provides an eddy current sensor adjusts support, includes base (1) and horizontal slidable mounting T type installation piece (2) in base (1) inner chamber, runs through fixed mounting on T type installation piece (2) has eddy current sensor (3), its characterized in that: the novel plastic base is characterized in that a threaded driving rod (4) is movably mounted on one side of the middle part of an inner cavity of the base (1), the threaded driving rod (4) is installed in a T-shaped installation block (2) in a penetrating mode through threads, a metal plate (5) is embedded in the inner cavity of one end of the base (1), a telescopic component (6) is installed at the bottom of the metal plate (5), a screwing large gear (7) is movably mounted at the other end of the base (1), a fastening screw (8) is installed on the outer wall of the other side of the T-shaped installation block (2) in a penetrating mode through threads, and an extrusion push plate (9) is longitudinally and slidably installed on the outer wall of the middle part of the other side of the base (1).

2. An eddy current sensor adjustment support as set forth in claim 1 wherein: the base (1) comprises a bottom plate (11) and a receiving plate (13) embedded and fixedly arranged at one end of the bottom plate (11), and a connecting plate (12) is embedded and fixedly arranged at the other end of the bottom plate (11);

convex three-way grooves (111) are formed in the middle of the top surface of the bottom plate (11), arc-shaped sliding grooves (112) are formed in the inner walls of the two sides of the inner cavity of the bottom plate (11), outer wide grooves (113) are formed in the outer wall of the middle of the other side of the bottom plate (11), and inner narrow grooves (114) are formed in the side walls of the middle of the inner cavity of the outer wide grooves (113).

3. An eddy current sensor adjustment support according to claim 2, characterized in that: the middle outer wall of the outer end of the connecting plate (12) is respectively provided with a T-shaped rotating groove (121) and a T-shaped round hole (122), the T-shaped round hole (122) is arranged at one side of the T-shaped rotating groove (121), and the T-shaped round hole (122) and the T-shaped rotating groove (121) are communicated;

an L-shaped groove (131) is formed in the middle of one end of the top surface of the receiving plate (13), a T-shaped sliding groove (132) is formed in one end of the bottom surface of the inner cavity of the L-shaped groove (131), a T-shaped vertical sliding groove (135) is formed in the inner wall of the other side of the other end of the inner cavity of the L-shaped groove (131), a circular through hole (133) is formed in the outer wall of one side of the middle of the other end of the receiving plate (13), and multiple triangular clamping rings (134) are fixedly mounted on the periphery of the opening of the inner cavity of the circular through hole (133).

4. An eddy current sensor adjustment support as claimed in claim 3 wherein: the T-shaped mounting block (2) comprises a lower sliding block (21) and a lower clamping block (22) fixedly mounted on the top surface of the lower sliding block (21), an upper clamping block (23) is mounted on the lower clamping block (22), two sides of the upper clamping block (23) are respectively provided with a tightening screw (24) in a penetrating manner, and the output tail end of the tightening screw (24) is mounted on the lower clamping block (22) in a threaded insertion manner;

a threaded round hole (211) is formed in the outer wall of one side of the middle of the other end of the lower sliding block (21), and a threaded round groove (212) is formed in the outer wall of the middle of the other side of the lower sliding block (21).

5. An eddy current sensor adjustment support as set forth in claim 4 wherein: the screw driving rod (4) comprises a screw sleeve column (41) and a conversion sliding column (42) which penetrates through the inner cavity of the screw sleeve column (41) and is slidably arranged in the inner cavity of the screw sleeve column (41), and a split gear (43) is movably arranged at one end part of the screw sleeve column (41);

one end of the thread sleeve column (41) is provided with a T-shaped bulge (411), the middle part of the thread sleeve column (41) is provided with a penetrating slide hole (412), the transforming slide column (42) is arranged in the penetrating slide hole (412) in a penetrating sliding manner, one end of the penetrating slide hole (412) is communicated with an inner square groove (413), the outer wall of the middle part of the other end of the split gear (43) is provided with a T-shaped connecting groove (431), the T-shaped bulge (411) is movably arranged in the T-shaped connecting groove (431), the middle side wall of the inner cavity of the T-shaped connecting groove (431) is provided with an inner clamping groove (432), the outer peripheral outer wall of the other end of the split gear (43) is provided with an embedded groove (433), and the opening of the inner cavity of the embedded groove (433) is provided with a trapezoid clamping block (434) through a spring group (435) in an elastic sliding manner.

6. An eddy current sensor adjustment support as set forth in claim 5 wherein: the transformation slide column (42) comprises a hexagonal nut (421) and a middle slide column (422) fixedly mounted on the outer wall of the middle part of one end of the hexagonal nut (421), a square clamping block (428) is fixedly mounted at one end of the middle slide column (422), a pinion (423) is fixedly sleeved on the outer wall of the outer periphery of the other end of the middle slide column (422), an elastic groove (424) is formed in the outer wall of one end of the hexagonal nut (421), an elastic slide column (425) is mounted at the opening of an inner cavity of the elastic groove (424) in an elastic sliding manner through a connecting spring (426), and an anti-abrasion ball (427) is mounted at one end of the elastic slide column (425).

7. An eddy current sensor adjustment support as set forth in claim 6 wherein: the bottom surface middle part department of metal sheet (5) is provided with T type kerve (51), telescopic assembly (6) include X type telescopic link (61) and respectively movable mounting T type restriction slider (62) in X type telescopic link (61) four corners department, T type restriction slider (62) in upper end slide respectively set up in T type kerve (51), T type restriction slider (62) in lower extreme slide respectively set up in T type spout (132), movable mounting has square splicing block (63) on the other end outer wall of X type telescopic link (61) one side lower extreme T type restriction slider (62), square splicing block (63) pass through lateral wall spring (64) elasticity longitudinal sliding mounting on the inner chamber bottom surface of L type groove (131), fixed mounting rack (65) on the opposite side middle part outer wall of square splicing block (63), and be connected between components of a whole that can function independently gear (43) and rack (65), and fixed mounting has T type vertical slider (67) on the other end outer wall of telescopic column (66) opposite side, and vertical sliding mounting is in the inner chamber bottom surface (68) of L type groove (131).

8. An eddy current sensor adjustment support as set forth in claim 7 wherein: an embedded side groove (631) is formed in the outer wall of the middle of the other side of the square connecting block (63), an embedded vertical sliding block (651) is fixedly arranged at one side end of the rack (65), and the embedded vertical sliding block (651) is elastically and slidably arranged in the embedded side groove (631) through a reset spring (652).

9. An eddy current sensor adjustment support as set forth in claim 5 wherein: the screwing large gear (7) comprises a hexagonal screwing head (71) and a large gear (72) fixedly arranged on the output end of the hexagonal screwing head (71), and the large gear (72) is in meshed connection with the small gear (423).

10. An eddy current sensor adjustment support as set forth in claim 7 wherein: the extrusion push plate (9) comprises a push plate main body (91) and a trapezoid lower push block (92) fixedly installed on the outer wall of the middle part of one end of the push plate main body (91), the front end part of the trapezoid lower push block (92) is arranged at the other side of the telescopic column (66), and the output end of the fastening screw (8) is arranged on the push plate main body (91) in a penetrating mode.