CN113203381B

CN113203381B - Automobile inductor inner diameter inspection and test device and method thereof

Info

Publication number: CN113203381B
Application number: CN202110356611.XA
Authority: CN
Inventors: 刘毅
Original assignee: Anshun Xixiu Paibo Auto Repair Factory
Current assignee: Anshun Xixiu Paibo Auto Repair Factory
Priority date: 2021-04-01
Filing date: 2021-04-01
Publication date: 2022-11-01
Anticipated expiration: 2041-04-01
Also published as: CN113203381A

Abstract

The invention provides a device and a method for testing the inner diameter of an automobile inductor, and the device comprises a device main body, wherein a clamp and an inclined plate are swung at the upper end of the device main body, a transmission assembly capable of rotating in two directions and a limiting assembly capable of limiting automatically are arranged on the inner side of the device main body, the transmission assembly comprises a support, a folding plate, a push rod, a disc, an axis, a connecting rod, a convex strip and a sliding block 304, when the inclined plate is lifted upwards, the push rod rotates clockwise on one side of the disc, so that the push rod drives the disc to rotate integrally, the disc rotates around the axis, the connecting rod pushes horizontally when the axis rotates, the testing device can drive the disc to rotate integrally by utilizing the upward extrusion pressure of the inductor, meanwhile, the push rod pushes horizontally, the push rod can drive the sliding block to slide horizontally on the inner side of a sleeve, the sliding block is extruded to one side of a sliding frame, and the sliding frame is folded and contracted through a first bearing and is extruded to two sides of a rotating frame.

Description

Automobile inductor inner diameter inspection and test device and method thereof

Technical Field

The invention relates to the field of automobile inductors, in particular to an automobile inductor inner diameter inspection testing device and method.

Background

With the development of science and technology and the improvement of electronic element processing and forming technology, the automobile inductance element needs to be inspected and tested for the inner diameter, the traditional testing device needs to be manually measured, and the situation of inconvenient measurement is easy to occur due to the fact that the automobile inductance element is small in size and different in specifications of different inductance elements;

aiming at the technical problems of the automobile inductor, a PCB inductor automatic intelligent comprehensive test production line and an inductor online test method are found through retrieval, the PCB inductor automatic intelligent comprehensive test production line and the inductor online test method have the patent number of CN202010725532.7, and the PCB inductor automatic intelligent comprehensive test production line and the inductor online test method are provided for realizing simultaneous feeding detection of a plurality of groups of PCB inductors, and a special material arranging and clamping device is adopted for ensuring that the PCB inductors are in a preset orientation, so that the PCB inductor detection production efficiency is greatly improved;

because the automobile needs to use various different inductance elements, the inductance elements are different in model and specification, and the inductance testing method cannot limit the inductance according to the size of the inductance, so that the inductance elements are easy to shift in the inductance testing process, the situations of inaccurate testing and deviation of results are easy to occur, and the limitation cannot be quickly carried out according to the size of the inductance elements.

Disclosure of Invention

The invention aims to provide a device and a method for testing the inner diameter of an automobile inductor.

In order to achieve the purpose, the invention provides the following technical scheme:

the automobile inductance inner diameter inspection testing device comprises a device body, wherein a clamp and an inclined plate are arranged at the upper end of the device body in a swinging mode, and a transmission assembly capable of rotating in a two-way mode and an automatic limiting assembly are arranged on the inner side of the device body.

As a further scheme of the invention: the transmission assembly comprises a support, a folding plate, a push rod, a disc, an axis, a connecting rod, a convex strip and a sliding block.

As a further scheme of the invention: the outside activity of connecting rod is run through there is the sleeve, telescopic inside is folded and is had the carriage, and the middle rotation of carriage has first bearing, and the upper end swing of carriage has revolving rack and weight.

As a further scheme of the invention: the folding plates are arranged in a wave-shaped folding mode, the folding plates are arranged on two sides of one end of the inclined plate, the distance between the push rod and the axis is 3-5cm, the raised strips are arranged in a transverse T shape, and the connecting rods are movably nested with the axis.

As a further scheme of the invention: when the inclined plate is lifted upwards, the push rod rotates clockwise on one side of the disc, the rotation angle is smaller than 180 degrees, the disc synchronously rotates, and meanwhile the connecting rod, the convex strip and the sliding block horizontally slide.

As a further scheme of the invention: the sliding frame is arranged in an X shape, the sliding frame slides on the side face of the sliding block, the inner portion of the sleeve is arranged in a hollow shape, the rotating frame is arranged in an inverted V shape, the weight of the weight is 100-200g, when the sliding block slides, the sliding frame integrally shrinks in a horizontal sliding mode, and meanwhile the rotating frame shrinks in a folding mode, and the rotating frame returns fast due to the weight of the weight.

As a further scheme of the invention: the limiting assembly comprises a rotating disk, a clamping block, a swinging frame, a clamping ring, a baffle plate, a lever frame, a groove, a limiting frame and a movable plate.

As a further scheme of the invention: the clamping blocks are arranged in a T shape, 10-12 clamping blocks are arranged, one ends of the clamping blocks are all arranged in an inclined manner at an angle of 15-45 degrees, the convex strips slide horizontally, the clamping rings are made of rubber and arranged in a circular manner, when the convex strips are extruded to one side of the clamping blocks, the rotating disc rotates anticlockwise, the single rotation angle is 30-36 degrees, and the swinging frame swings in an inclined manner.

As a further scheme of the invention: the limiting frame penetrates through and extends to the lower end of the support, the baffle and the limiting frame are sequentially arranged at the upper end and the lower end of the lever frame, the interval between the baffle and the swing frame is 1-3cm, when the swing frame swings obliquely, the clamping ring is embedded into the inner side of the groove, and meanwhile, the baffle drives the limiting frame to swing obliquely through the lever frame.

As a further scheme of the invention: an automobile inductor inner diameter inspection testing device comprises the following testing method:

s1: the inductor is manually placed at the lower end of the inclined plate, the clamp drives the inclined plate to limit the inductor element, and the inductor is extruded to the lower end of the inclined plate due to the inclined arrangement of the inclined plate, so that one end of the inclined plate is lifted upwards;

s2: when the inclined plate is lifted upwards, the push rod rotates clockwise on one side of the disc, so that the push rod drives the disc to rotate integrally, the disc rotates by taking the axis as a center, and the connecting rod pushes horizontally when the axis rotates, so that the testing device can utilize the upward extrusion pressure of the inductor to drive the disc to rotate integrally, and meanwhile, the push rod pushes horizontally;

s3: the push rod can drive the sliding block to horizontally slide on the inner side of the sleeve, the sliding block is extruded to one side of the sliding frame, the sliding frame is folded and contracted through the first bearing, meanwhile, the sliding frame is extruded to two sides of the rotating frame, the rotating frame can return quickly due to the gravity of the weight, and the sliding frame can be extruded to one side of the sliding block when returning, so that the sliding block can drive the connecting rod to horizontally slide in a reciprocating manner;

s4: when the convex strips slide horizontally, the convex strips are extruded to one side of the clamping block, one end of the clamping block is obliquely arranged, so that the convex strips can drive the rotating disc to rotate anticlockwise through the clamping block, the rotating disc can rotate anticlockwise, the swinging frame can tilt upwards, meanwhile, the clamping ring is embedded into the inner side of the groove, the swinging frame is simultaneously extruded to one side of the baffle, the baffle can drive the limiting frame to swing at an inclined angle through the lever frame, and the outer side of the inductor can be limited through the limiting frame;

s5: when the inductance volume is less, rock the inductance from top to bottom through manual, and then the sand grip can be one side of continuous extrusion fixture block for the rotary disk can reach many times of rotations, because the many times of rotation of rotary disk, the rotary disk can drive the rotation angle of spacing frame through the swing span and progressively slope, makes this kind of testing arrangement can be spacing fast to the inductance element according to the inductance element size, makes things convenient for follow-up test inspection.

Advantageous effects

1. When the inclined plate is lifted upwards, the push rod rotates clockwise on one side of the disc, so that the push rod drives the disc to rotate integrally, the disc rotates by taking the axis as a center, the connecting rod pushes horizontally when the axis rotates, the testing device can drive the disc to rotate integrally by utilizing the upward extrusion pressure of the inductor, meanwhile, the push rod pushes horizontally, the push rod can drive the sliding block to slide horizontally on the inner side of the sleeve, the sliding block is extruded to one side of the sliding frame, the sliding frame is folded and contracted through the first bearing, and meanwhile, the sliding frame is extruded to two sides of the rotating frame, the rotating frame can return quickly due to the gravity of the weight, and the sliding frame can be extruded to one side of the sliding block when returning, so that the sliding block can drive the connecting rod to slide horizontally and repeatedly;

2. when the raised lines slide horizontally, the raised lines are extruded to one side of the clamping block, one end of the clamping block is arranged in an inclined mode, the raised lines can drive the rotating disc to rotate anticlockwise through the clamping block, the rotating disc can rotate anticlockwise, the swinging frame can tilt upwards, meanwhile, the clamping ring is embedded into the inner side of the groove, the swinging frame is extruded to one side of the baffle, the baffle can drive the limiting frame to swing in an inclined angle mode through the lever frame, the outer side of the inductor can be limited through the limiting frame, when the size of the inductor is small, the inductor can swing up and down manually, the raised lines can continuously extrude one side of the clamping block, the rotating disc can rotate for multiple times, and due to the fact that the rotating disc rotates for multiple times, the rotating disc can drive the rotating angle of the limiting frame to gradually incline through the swinging frame, the testing device can rapidly limit the inductor according to the size of the inductor, and subsequent testing and inspection are convenient.

Drawings

Fig. 1 is a plan view of the overall structure of the present invention.

Fig. 2 is a cross-sectional view of a stent structure of the present invention.

Fig. 3 is an enlarged view of the structure at a in fig. 2 according to the present invention.

FIG. 4 is a schematic diagram of a rotating disk assembly of the present invention.

FIG. 5 is an enlarged view of the structure at B of FIG. 2 according to the present invention.

FIG. 6 is a schematic view of a rubber ring structure according to the present invention.

In FIGS. 1-6: 1-device body, 101-clamp, 102-inclined plate, 2-bracket, 201-folding plate, 202-push rod, 3-disc, 301-axle center, 302-connecting rod, 303-raised strip, 304-sliding block, 4-sleeve, 401-sliding frame, 402-first bearing, 403-rotating frame, 404-weight, 5-rotating disc, 501-clamping block, 502-swinging frame, 503-clamping ring, 6-baffle plate, 601-lever frame, 602-groove, 603-limiting frame and 604-moving plate.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Unless otherwise defined, technical or scientific terms used herein shall have the ordinary meaning as understood by one of ordinary skill in the art to which this disclosure belongs. The use of the word "comprising" or "comprises", and the like, in this disclosure is intended to mean that the elements or items listed before that word, include the elements or items listed after that word, and their equivalents, without excluding other elements or items. The terms "connected" or "coupled" and the like are not restricted to physical or mechanical connections, but may also include electrical connections, whether direct or indirect. "upper", "lower", "left", "right", and the like are used only to indicate relative positional relationships, and when the absolute position of the object being described is changed, the relative positional relationships may also be changed accordingly.

Referring to fig. 1-6, in an embodiment of the present invention,

example 1: a car inductance inner diameter inspection testing device and a method thereof comprise a device main body 1, wherein the upper end of the device main body 1 swings with a clamp 101 and an inclined plate 102, and the inner side of the device main body 1 is provided with a transmission assembly capable of rotating in two directions and a limiting assembly capable of limiting automatically;

wherein: the inductor is manually placed at the lower end of the inclined plate 102, the clamp 101 drives the inclined plate 102 to limit the inductor element, the inclined plate 102 is obliquely arranged, and the inductor is extruded to the lower end of the inclined plate 102, so that one end of the inclined plate 102 is lifted upwards, the inclined plate 102 drives the transmission assembly to rotate in a bidirectional mode when lifted, the transmission assembly can drive the limiting assembly to automatically limit the inductor element, and the inductor element can be limited by the testing device according to the specification of the inductor element;

the transmission assembly comprises a bracket 2, a folding plate 201, a push rod 202, a disc 3, an axle center 301, a connecting rod 302, a convex strip 303 and a slide block 304;

a sleeve 4 movably penetrates through the outer side of the connecting rod 302, a sliding frame 401 is folded inside the sleeve 4, a first bearing 402 rotates in the middle of the sliding frame 401, and a rotating frame 403 and a weight 404 swing at the upper end of the sliding frame 401;

the folding plates 201 are arranged in a wave-shaped folding manner, the folding plates 201 are arranged on two sides of one end of the inclined plate 102, the distance between the push rod 202 and the axis 301 is 3-5cm, the raised strips 303 are arranged in a transverse T shape, the connecting rods 302 are movably nested with the axis 301, when the inclined plate 102 is lifted upwards, the push rod 202 rotates clockwise on one side of the disc 3, the rotating angle is less than 180 degrees, the disc 3 rotates synchronously, and meanwhile, the connecting rods 302, the raised strips 303 and the sliding blocks 304 slide horizontally;

the sliding frame 401 is arranged in an X shape, the sliding frame 401 slides on the side face of the sliding block 304, the inner part of the sleeve 4 is arranged in a hollow shape, the rotating frame 403 is arranged in an inverted V shape, the weight of the weight 404 is 100-200g, when the sliding block 304 slides, the sliding frame 401 integrally slides and contracts horizontally, meanwhile, the rotating frame 403 is folded and contracted, and the rotating frame 403 returns rapidly due to the weight of the weight 404;

wherein: when the inclined plate 102 is lifted upwards, the push rod 202 rotates clockwise on one side of the disc 3, so that the push rod 202 drives the disc 3 to rotate integrally, the disc 3 rotates around the axis 301, the connecting rod 302 pushes horizontally when the axis 301 rotates, so that the testing device can drive the disc 3 to rotate integrally by utilizing the upward extrusion pressure of the inductor, meanwhile, the push rod 202 pushes horizontally, the push rod 202 can drive the sliding block 304 to slide horizontally on the inner side of the sleeve 4, the sliding block 304 is extruded to one side of the sliding frame 401, the sliding frame 401 is folded and contracted through the first bearing 402, and the sliding frame 401 is extruded to two sides of the rotating frame 403 at the same time, due to the gravity of the weight 404, the rotating frame 403 can return quickly, and the sliding frame 401 can be extruded to one side of the sliding block 304 when returning, so that the sliding block 304 can drive the connecting rod 302 to slide horizontally and reciprocally;

the limiting assembly comprises a rotating disc 5, a clamping block 501, a swinging frame 502, a clamping ring 503, a baffle 6, a lever frame 601, a groove 602, a limiting frame 603 and a movable plate 604;

the fixture blocks 501 are arranged in a T shape, 10-12 fixture blocks 501 are arranged, one ends of the fixture blocks 501 are all arranged in an inclined manner at an angle of 15-45 degrees, the convex strips 303 horizontally slide, the clamping rings 503 are made of rubber, the clamping rings 503 are arranged in a circular ring shape, when the convex strips 303 are extruded to one side of the fixture blocks 501, the rotating disc 5 rotates anticlockwise, the single rotation angle is 30-36 degrees, the swing frame 502 swings in an inclined manner, the limiting frame 603 penetrates through and extends to the lower end of the support 2, the baffle 6 and the limiting frame 603 are sequentially arranged at the upper end and the lower end of the lever frame 601, the interval between the baffle 6 and the swing frame 502 is 1-3cm, when the swing frame 502 swings in an inclined manner, the clamping rings 503 are embedded into the inner sides of the grooves 602, and meanwhile, the baffle 6 drives the limiting frame 603 to swing in an inclined manner through the lever frame 601;

wherein: when sand grip 303 is the horizontal slip, sand grip 303 extrudees to one side of fixture block 501, because the one end of fixture block 501 is the slope setting, make sand grip 303 can drive rotary disk 5 through fixture block 501 and be anticlockwise rotation, because rotary disk 5 can anticlockwise rotation, swing span 502 can upwards the perk, snap ring 503 imbeds in the inboard of recess 602 simultaneously, and swing span 502 extrudees to one side of baffle 6 simultaneously, baffle 6 can drive spacing frame 603 through lever frame 601 and be the inclination swing, accessible spacing frame 603 is spacing to the inductance outside, the inductance volume is less, rock the inductance from top to bottom through manual, and then sand grip 303 can be one side of lasting extrusion fixture block 501, make rotary disk 5 can reach the multitime rotation, because the multitime of rotary disk 5 is rotatory, rotary disk 5 can drive the rotation angle of spacing frame 603 through swing span 502 and progressively slope, make this kind of testing arrangement can be fast spacing to the inductance element according to the inductance element size, make things convenient for follow-up test inspection.

Example 2: an automobile inductance inner diameter inspection testing device comprises the following steps:

s1: the inductor is manually placed at the lower end of the inclined plate 102, the fixture 101 drives the inclined plate 102 to limit the inductor element, and the inductor is extruded to the lower end of the inclined plate 102 due to the inclined arrangement of the inclined plate 102, so that one end of the inclined plate 102 is lifted upwards;

s2: when the inclined plate 102 is lifted upwards, the push rod 202 rotates clockwise on one side of the disc 3, so that the push rod 202 drives the disc 3 to rotate integrally, the disc 3 rotates around the axis 301, and the connecting rod 302 pushes horizontally when the axis 301 rotates, so that the testing device can utilize the pressure of upward extrusion of the inductor to drive the disc 3 to rotate integrally, and meanwhile, the push rod 202 pushes horizontally;

s3: the push rod 202 can drive the sliding block 304 to horizontally slide on the inner side of the sleeve 4, the sliding block 304 is extruded to one side of the sliding frame 401, the sliding frame 401 is folded and contracted through the first bearing 402, meanwhile, the sliding frame 401 is extruded to two sides of the rotating frame 403, due to the gravity of the weight 404, the rotating frame 403 can return quickly, and the sliding frame 401 can be extruded to one side of the sliding block 304 when returning, so that the sliding block 304 can drive the connecting rod 302 to horizontally slide in a reciprocating manner;

s4: when the raised line 303 slides horizontally, the raised line 303 is extruded to one side of the fixture block 501, because one end of the fixture block 501 is arranged obliquely, the raised line 303 can drive the rotating disc 5 to rotate anticlockwise through the fixture block 501, because the rotating disc 5 can rotate anticlockwise, the swing frame 502 can tilt upwards, meanwhile, the clamping ring 503 is embedded into the inner side of the groove 602, the swing frame 502 is extruded to one side of the baffle plate 6 at the same time, the baffle plate 6 can drive the limiting frame 603 to swing at an oblique angle through the lever frame 601, and the outer side of the inductor can be limited through the limiting frame 603;

s5: when the inductance volume is less, rock the inductance from top to bottom through manual, and then sand grip 303 can be one side of continuously extruding fixture block 501 for rotary disk 5 can reach many times of rotations, because rotary disk 5's many times of rotations, rotary disk 5 can drive the progressively slope of rotation angle of spacing 603 through swing span 502, makes this kind of testing arrangement can be spacing fast to the inductance element according to the inductance element size, makes things convenient for follow-up test inspection.

The above is only a preferred embodiment of the present invention, and it should be noted that, for those skilled in the art, it is possible to make several variations and modifications without departing from the concept of the present invention, and these should be considered as the protection scope of the present invention, which will not affect the effect of the implementation of the present invention and the utility of the patent.

Claims

1. The utility model provides an automobile inductance internal diameter inspection testing arrangement, includes device main part (1), the upper end swing of device main part (1) has anchor clamps (101) and swash plate (102), its characterized in that: the inner side of the device main body (1) is provided with a transmission assembly capable of rotating in two directions and a limiting assembly capable of limiting automatically;

the transmission assembly comprises a support (2), a folding plate (201), a push rod (202), a disc (3), an axle center (301), a connecting rod (302), a convex strip (303) and a sliding block (304);

a sleeve (4) movably penetrates through the outer side of the connecting rod (302), a sliding frame (401) is folded inside the sleeve (4), a first bearing (402) rotates in the middle of the sliding frame (401), and a rotating frame (403) and a weight (404) swing at the upper end of the sliding frame (401);

the folding plates (201) are arranged in a wave-shaped folding manner, the folding plates (201) are arranged on two sides of one end of the inclined plate (102), the distance between the push rod (202) and the axis (301) is 3-5cm, the raised lines (303) are arranged in a transverse T shape, and the connecting rods (302) are movably nested with the axis (301);

when the inclined plate (102) is lifted upwards, the push rod (202) rotates clockwise on one side of the disc (3), the rotating angle is smaller than 180 degrees, the disc (3) synchronously rotates, and meanwhile the connecting rod (302), the convex strip (303) and the sliding block (304) horizontally slide;

the limiting assembly comprises a rotating disc (5), a clamping block (501), a swinging frame (502), a clamping ring (503), a baffle (6), a lever frame (601), a groove (602), a limiting frame (603) and a movable plate (604);

the clamping blocks (501) are arranged in a T shape, 10-12 clamping blocks (501) are arranged, one ends of the clamping blocks (501) are all arranged in an inclined manner at an angle of 15-45 degrees, the protruding strips (303) horizontally slide, the clamping rings (503) are made of rubber, the clamping rings (503) are arranged in a circular ring shape, when the protruding strips (303) are extruded to one side of the clamping blocks (501), the rotating disc (5) rotates anticlockwise, the single rotation angle is 30-36 degrees, and the swinging frame (502) obliquely swings;

spacing (603) run through and extend to the lower extreme of support (2), and baffle (6) and spacing (603) set gradually in the upper and lower both ends of lever frame (601), and interval 1-3cm between baffle (6) and swing span (502), and during swing span (502) tilt swing, snap ring (503) are embedded in the inboard of recess (602), and baffle (6) drive spacing (603) through lever frame (601) simultaneously are the tilt swing.

2. The automobile inductance inner diameter inspection and test device according to claim 1, characterized in that: the sliding frame (401) is arranged in an X shape, the sliding frame (401) slides on the side face of the sliding block (304), the inner portion of the sleeve (4) is arranged in a hollow shape, the rotating frame (403) is arranged in an inverted V shape, the weight of the weight (404) is 100-200g, when the sliding block (304) slides, the sliding frame (401) is integrally contracted in a horizontal sliding mode, meanwhile, the rotating frame (403) is folded and contracted, and the weight (404) of the weight rotating frame (403) returns quickly.

3. A test method of an automobile inductance inner diameter inspection test device is characterized by comprising the following steps: the automobile inductance inside diameter inspection testing device according to any one of claims 1-2, wherein the testing method comprises the following steps:

s1: the inductor is manually placed at the lower end of the inclined plate (102), the clamp (101) drives the inclined plate (102) to limit the inductor element, and the inductor is extruded to the lower end of the inclined plate (102) due to the inclined arrangement of the inclined plate (102), so that one end of the inclined plate (102) is lifted upwards;

s2: when the inclined plate (102) is lifted upwards, the push rod (202) rotates clockwise on one side of the disc (3), so that the push rod (202) drives the disc (3) to rotate integrally, the disc (3) rotates by taking the axis (301) as a center, and the connecting rod (302) pushes horizontally when the axis (301) rotates, so that the test device can drive the disc (3) to rotate integrally by utilizing the upward extrusion pressure of the inductor, and meanwhile, the push rod (202) pushes horizontally;

s3: the push rod (202) can drive the sliding block (304) to horizontally slide on the inner side of the sleeve (4), the sliding block (304) is extruded to one side of the sliding frame (401), the sliding frame (401) is folded and contracted through the first bearing (402), meanwhile, the sliding frame (401) is extruded to two sides of the rotating frame (403), due to the gravity of the weight (404), the rotating frame (403) can return quickly, and the sliding frame (401) can be extruded to one side of the sliding block (304) when returning, so that the sliding block (304) can drive the connecting rod (302) to horizontally slide in a reciprocating manner;

s4: when the convex strip (303) slides horizontally, the convex strip (303) is extruded to one side of the clamping block (501), because one end of the clamping block (501) is arranged in an inclined manner, the convex strip (303) can drive the rotating disc (5) to rotate anticlockwise through the clamping block (501), because the rotating disc (5) can rotate anticlockwise, the swing frame (502) can tilt upwards, meanwhile, the clamping ring (503) is embedded into the inner side of the groove (602), the swing frame (502) is extruded to one side of the baffle (6) simultaneously, the baffle (6) can drive the limiting frame (603) to swing in an inclined angle through the lever frame (601), and the outer side of the inductor can be limited through the limiting frame (603);

s5: when the inductance volume is less, rock the inductance from top to bottom through manual, and then sand grip (303) can be one side of lasting extrusion fixture block (501) for rotary disk (5) can reach many times of rotations, because the multitime rotation of rotary disk (5), rotary disk (5) can drive the progressively slope of rotation angle of spacing (603) through swing span (502), make this kind of testing arrangement can be spacing fast to the inductance element according to the inductance element size, make things convenient for follow-up test inspection.