CN107063156B - Rotating structure of detection base in shaft detection equipment - Google Patents

Abstract

The invention provides a rotating structure of a detection base in shaft detection equipment, and belongs to the technical field of measurement. The automatic shaft detection device solves the technical problem that the existing shaft detection device does not have corresponding automatic equipment and the like. Axle check out test set includes the measuring table and fixes a plurality of on the measuring table and detects the base, it includes the bearing frame to detect the base, the bearing frame internal rotation is connected with upper bearing and lower bearing, the inner circle of upper bearing is pegged graft and is had a core, this rotating-structure includes driving motor and the pulley axle of pegging graft in the inner circle of lower bearing, it steps down clearance one to have between core and the pulley axle, bearing frame and fixedly connected with driven pulley are worn out to the lower extreme of pulley axle, driven pulley has step down clearance two with the lower terminal surface of bearing frame, driving motor fixes on the measuring table, be fixed with driving pulley in driving motor's the pivot, belt through the tensioning between driving pulley and a plurality of driven pulley is connected. The invention has the advantage of realizing synchronous detection of a plurality of detection bases.

Description

Rotating structure of detection base in shaft detection equipment

Technical Field

The invention belongs to the technical field of measurement, and relates to a rotating structure of a detection base in shaft detection equipment.

Background

In the field of high-precision equipment, the size requirement of parts in the equipment is high, so that the parts are detected after being manufactured so as to remove defective products with sizes which do not meet the requirement. The existing shaft is provided with two sections with different diameters, a step is formed between the two sections with different diameters, an inner hole is formed in the end of one section with the smaller diameter of the shaft, and the lengths of the two sections of the shaft and the diameter and the depth of the inner hole need to be detected before assembly. At present, no special equipment is used for automatically detecting the shaft with the structure, the detection of the shaft is mainly carried out manually by adopting a special instrument detection mode, the method is low in efficiency, and errors are easy to occur in manual detection.

Disclosure of Invention

The invention aims to provide a rotating structure of a detection base in shaft detection equipment aiming at the problems in the prior art, and the technical problem to be solved by the invention is to realize synchronous detection of a plurality of detection bases.

The purpose of the invention can be realized by the following technical scheme:

the utility model provides a rotating-structure of detection base among axle check out test set, axle check out test set include the measuring table and fix a plurality of on the measuring table and be used for the detection base of location axle, and a plurality of detection base sets up side by side, it includes the bearing frame fixed with the measuring table to detect the base, the bearing frame internal rotation is connected with upper bearing and lower bearing, the inner circle of upper bearing is pegged graft and is had the axle core, its characterized in that, this rotating-structure includes driving motor and the pulley axle of pegging graft in the inner circle of lower bearing, it gives way clearance one to have between axle core and the pulley axle, the pulley axle is fixed a position and the pulley axle can be relative axle core along axial displacement with the axle core in circumference, bearing frame and fixedly connected with driven pulley are worn out to the lower extreme of pulley axle, driven pulley has the clearance of giving way two with the lower terminal surface of bearing frame, driving motor fixes on the measuring table, be fixed with the driving pulley in driving motor's the pivot, be connected through the belt of tensioning between driving pulley and a plurality of driven pulley.

The lower end of the shaft penetrates through the shaft core and the step surface of the shaft is abutted against the shaft core for positioning during detection, the shaft core and the belt pulley shaft are rotatably connected into the bearing seat through the upper bearing and the lower bearing respectively, the shaft core and the belt pulley shaft are mutually independent of a connecting structure between the shaft core and the bearing seat, the shaft core and the belt pulley shaft are only positioned in the circumferential direction, the belt can float up and down when driving the driven pulley to rotate, the driven pulley can drive the belt pulley shaft to float up and down, the shifting gap I enables a space which floats up and down to be formed between the belt pulley shaft and the shaft core, the shifting gap II enables a space which floats up and down to be formed between the driven pulley and the bearing seat, and the shaft core is not connected with the belt pulley shaft in the axial direction, so that the vertical floating of the driven pulley and the belt pulley shaft cannot cause the vibration or the movement of the shaft core or the bearing seat, the shaft to be detected positioned on the shaft core cannot be influenced, and the precision and the accuracy of shaft detection can be ensured; a plurality of driven pulley is driven through a belt and rotates, can realize a plurality of detection base synchronous detection, and compact structure and detection efficiency are higher.

In the above rotation structure of the detection base in the shaft detection apparatus, the driven pulley has an annular guide convex ring protruding upward, and the guide convex ring penetrates into the bearing housing. When the driven pulley appears the condition of floating from top to bottom, can guarantee through the direction bulge loop that driven pulley only can float from top to bottom, consequently the pulley shaft also only can float from top to bottom, and the fluctuation of pulley shaft can not lead to the removal of axle core for the axle of pegging graft on the axle core can not receive the influence, avoids causing the interference to the measurement.

In the above rotation structure of the detection base in the shaft detection device, the lower end face of the shaft core is provided with at least two insertion holes, the upper end face of the pulley shaft is provided with the raised insertion rods in one-to-one correspondence with the insertion holes, the yielding gap I is formed between the lower end face of the shaft core and the upper end face of the pulley shaft, and the insertion rods can be inserted into the corresponding insertion holes and can axially move relative to the insertion holes. The shaft core and the belt pulley shaft synchronously rotate through the matching of the insertion rod and the insertion hole; the inserted link can be along axial displacement in the jack, and the axle core can not receive the influence when the belt pulley axle appears floating from top to bottom, consequently can not influence the axle of pegging graft on the axle core, guarantees that the axle detects and can not receive the interference, guarantees to detect precision and accuracy.

In the above rotation structure of the detection base in the shaft detection device, the circumferential surface of the lower end of the shaft core is provided with a first protruding ring, the insertion hole is formed in the lower end surface of the first protruding ring, the circumferential surface of the upper end of the belt pulley shaft is provided with a second protruding ring, and the insertion rod is arranged on the upper end surface of the second protruding ring. The structure can ensure the connection strength and stability of the shaft core and the belt pulley shaft.

In the above rotating structure of the detection base in the shaft detection device, the bearing seat includes an upper bearing seat and a lower bearing seat, the upper bearing seat is fixed with the measuring table through a bolt, the lower bearing seat is fixed on the lower bottom surface of the lower bearing seat, an upper abutting convex edge is arranged at the position, close to the lower end, of an inner hole of the upper bearing seat, an outer ring of the upper bearing abuts against the upper abutting convex edge, a lower abutting convex edge is arranged at the position, close to the lower end, of the inner hole of the lower bearing seat, and an outer ring of the lower bearing abuts against the lower abutting convex edge. The installation of convenient upper bearing and lower bearing through this structure, upper bearing passes through the bolster bearing housing and supports alone simultaneously, and the lower bearing passes through the lower bearing housing and supports alone, consequently the removal of lower bearing can not influence the upper bearing when driven pulley appears fluctuating, guarantees the axle core rotational stability to guarantee the accuracy that the axle detected.

In the above rotating structure of the detection base in the shaft detection device, the shaft core is provided with an upper through hole, the pulley shaft is provided with a lower through hole, the diameter of the lower through hole is larger than that of the upper through hole, the upper through hole of the shaft core is communicated with the lower through hole of the pulley shaft, and the middle part of the driven pulley is provided with a yielding through hole communicated with the lower through hole. The upper through hole of the shaft core is matched with the smaller section of the diameter of the shaft to be detected, and the yielding through hole of the driven belt pulley and the lower through hole of the belt pulley shaft are used for a pneumatic measuring head or a pneumatic distance probe to penetrate through.

In the above rotating structure of the detection base in the shaft detection device, the lower end of the abdicating through hole of the driven pulley is provided with a positioning convex edge, the pulley shaft is inserted into the abdicating through hole and abuts against the positioning convex edge, and the pulley shaft is fixed with the positioning convex edge through a bolt. This structure makes between belt pulley shaft and the driven pulley fixed firm, and guarantees the axis of belt pulley shaft and driven pulley's axis collineation for the condition that the belt pulley shaft can not appear rocking when rotating guarantees that the axle core rotates steadily, guarantees the accuracy that the axle detected.

In the rotating structure of the detection base in the shaft detection equipment, an end cover is fixed on the upper end face of the bearing seat, a yielding hole is formed in the middle of the end cover, a reference panel is fixed on the upper end face of the shaft core, a reference convex surface is arranged on the upper plate face of the reference panel, a reference convex ring is arranged on the lower plate face of the reference panel, the reference convex ring penetrates through the yielding hole and is attached to the upper end face of the shaft core, and the lower plate face of the reference panel is attached to the end cover. The fixed position of the reference panel and the shaft core is ensured through the structure, so that the fixed position of the reference panel is accurate, the stepped surface of the shaft can be attached to the reference convex surface when the shaft penetrates into the shaft core, the positioning position of the shaft is accurate, and the detection accuracy can be ensured.

In the above-mentioned rotating-structure of detecting the base in axle check out test set, it has threely to detect the base, driven pulley has threely and sets up side by side, the belt pastes with the outside that is located the driven pulley of both sides and keeps away from the measuring table and pastes with the inboard that is close to the measuring table of the driven pulley that is located the centre and pastes. The tensioning of belt pulley can be guaranteed to this structure, and the driven pulley who is located the centre can play the effect of take-up pulley, consequently need not to increase the tensioning that the take-up pulley also can guarantee the belt for the structure is simpler.

In the above rotating structure of the detection base in the shaft detection device, the measuring table is fixed with a rotating fixed support, the driving motor is fixed on the rotating fixed support, the measuring table is provided with a strip-shaped through hole, and the belt passes through the through hole. This structure enables a more compact structure.

Compared with the prior art, the rotating structure of the detection base in the shaft detection equipment has the advantages that the synchronous detection of a plurality of detection bases can be realized, the structure is compact, and the detection efficiency is high.

Fig. 1 is a schematic perspective view of the present detection apparatus.

FIG. 2 is a schematic perspective view of the present test device with the housing removed.

FIG. 3 is a schematic perspective view of the inspection apparatus with the housing removed and the automatic discharging device removed.

Fig. 4 is a schematic perspective view of the automatic feeding device.

Fig. 5 is a schematic sectional structure view of the automatic feeding device.

Fig. 6 is a schematic perspective view of the station transfer device, the length detection device, the inner hole detection device and the rotating structure during assembly.

Fig. 7 is a schematic perspective view of the station transfer device.

Fig. 8 is a rear view and a partial enlarged view of the translating cylinder and translating slide block when assembled.

Fig. 9 is a schematic perspective view of the translational air cylinder assembled with the translational sliding seat.

FIG. 10 is a schematic cross-sectional view of the detection base.

In the figure, 1, a workbench; 11. a measuring table; 111. a slide rail; 112. a transverse moving pushing cylinder; 113. through the hole; 12. a feed reversing sleeve; 121. a discharge reversing sleeve; 2. mounting a bracket; 21. a lifting cylinder; 211. lifting convex strips; 212. a lifting slide seat; 213. a first connecting block part; 214. installing a flat plate; 215. a reinforcing plate; 22. a translation cylinder; 221. translating the convex strip; 222. a clip; 223. a limiting block; 224. positioning the through groove; 225. positioning the inclined plane; 226. a translational sliding seat; 227. a translation chute; 228. positioning and chamfering; 229. a second connecting block part; 229a, a bayonet; 23. mounting a plate; 24. a clamping jaw; 241. a finger cylinder; 242. a chuck; 243. a groove is embedded; 3. an upper distance sensor; 31. a lower distance sensor; 4. an air tightness measuring instrument; 41. a lifting frame; 411. detecting a lifting cylinder; 412. detecting a lifting slide seat; 413. a measuring head mounting plate; 414. a fixed seat; 42. a pneumatic measuring head; 43. positioning the air cylinder; 44. positioning the head; 5. detecting a base; 51. a shaft core; 511. an upper through hole; 512. a first convex ring; 52. a bearing seat; 521. an upper bearing seat; 522. the upper part is abutted against the convex edge; 523. a lower bearing seat; 524. the lower support is against the convex edge; 53. an upper bearing; 54. a lower bearing; 55. a pulley shaft; 551. a convex ring II; 552. a plug rod; 553. yielding gaps are one; 554. a driven pulley; 555. a yielding through hole; 556. positioning the convex edge; 557. a guide convex ring; 558. a yielding gap II; 559. a lower through hole; 56. an end cap; 57. a reference panel; 571. a reference convex surface; 572. a reference convex ring; 58. rotating the fixed bracket; 59. a drive motor; 591. a drive pulley; 592. a belt; 6. a hopper; 6a, a feed opening; 61. a side plate; 611. a tailgate; 612. a sloping plate; 613. a protection plate; 62. a push-pull plate; 621. a feeding through groove; 622. guiding chamfering; 63. a material pushing bracket; 632. a first slide rail; 64. a blanking sliding block; 641. fixing the sheet metal part; 642. a fixed part; 65. a material ejection block; 66. a second slide rail; 67. a feeding pushing cylinder; 7. a magazine; 71. a discharging support; 72. a discharge guide rail; 73. a slide base; 74. a discharging lifting cylinder; 75. and (4) clamping arms.

Detailed Description

The following are specific embodiments of the present invention and are further described with reference to the drawings, but the present invention is not limited to these embodiments.

As shown in fig. 1 to 10, the shaft detection apparatus includes a housing, a workbench 1 fixed in the housing and a measuring table 11 disposed on the workbench 1, three detection bases 5 disposed side by side are disposed on the measuring table 11, a shaft core 51 for positioning a shaft is rotatably connected to the detection bases 5, the shaft core 51 is vertically disposed, the shaft core 51 of the three detection bases 5 can rotate synchronously through a rotating structure, a feeding reversing sleeve 12 and a discharging reversing sleeve 121 are rotatably disposed at two ends of the three detection bases 5 on the measuring table 11, the feeding reversing sleeve 12 and the discharging reversing sleeve 121 can rotate to a horizontal state or a vertical state, a station transfer device capable of transferring a shaft from the feeding reversing sleeve 12 in the vertical state to the discharging reversing sleeve 121 in the vertical state after sequentially passing through the three detection bases 5 is disposed on the workbench 1, a hopper 6 for storing the shaft is fixed on one side of the workbench 1 close to the feeding reversing sleeve 12, an upper shaft automatic feeding device capable of automatically and sequentially inserting the shaft in the feeding reversing sleeve 12 in the horizontal state is disposed on the workbench 1, and a detection device capable of detecting a length of detecting the discharging shaft on the workbench 1 and detecting the two detection bases 5 corresponding to the discharging sleeve 121.

Specifically, as shown in fig. 1 to 3 and fig. 6 and 7, the station transfer device includes a mounting bracket 2, a lifting cylinder 21, a translation cylinder 22, a clamping jaw 24, and two parallel slide rails 111 fixed in the middle of the workbench 1, where the two slide rails 111 are arranged in parallel and at an interval, the measurement platform 11 is slidably connected to the slide rails 111, a traverse pushing cylinder 112 is fixed on the workbench 1, an expansion rod of the traverse pushing cylinder 112 is parallel to the slide rails 111, the expansion rod of the traverse pushing cylinder 112 is fixed to the measurement platform 11, the measurement platform 11 is pushed by the traverse pushing cylinder 112 to slide back and forth along the slide rails 111, the mounting bracket 2 is fixed on the workbench 1, the lifting cylinder 21 is vertically fixed downward on the mounting bracket 2, the translation cylinder 22 is fixed on the expansion rod of the lifting cylinder 21, the expansion rod of the translation cylinder 22 is perpendicular to the slide rails 111, the clamping jaw 24 corresponds to the detection base 5 one-to one, the mounting plate 23 is fixed on the expansion rod of the translation cylinder 22, and the clamping jaw 24 is fixed side by side on the mounting plate 23 and located above the detection base 5.

A lifting slide base 212 is arranged between the lifting cylinder 21 and the translation cylinder 22, a lifting convex strip 211 which is vertically arranged is arranged on the outer wall of a cylinder body of the lifting cylinder 21, a lifting sliding groove is formed in the lifting slide base 212, the lifting slide base 212 is attached to the outer wall of the cylinder body of the lifting cylinder 21, the lifting convex strip 211 is clamped into the lifting sliding groove and can slide relative to the lifting sliding groove, the translation cylinder 22 is fixed at the lower end of the lifting slide base 212, a first vertically convex connecting block part 213 is arranged on the lifting slide base 212, and a telescopic rod of the lifting cylinder 21 is fixed with the first connecting block part 213. The lifting air cylinder 21 drives the lifting slide seat 212 to move up and down, so that the translation air cylinder 22 moves up and down, and the clamping jaw 24 moves up and down.

The lower end of the lifting slide base 212 is fixed with a mounting flat plate 214, an L-shaped reinforcing plate 215 is fixed on the mounting flat plate 214, one side of the reinforcing plate 215 is attached and fixed with the lifting slide base 212, the other side of the reinforcing plate 215 is attached and fixed with the mounting flat plate 214, and the translation cylinder 22 is fixed on the lower side of the mounting flat plate 214.

Be equipped with translation sliding seat 226 between translation cylinder 22 and the mounting panel 23, the telescopic link and the translation sliding seat 226 of translation cylinder 22 are connected, it has translation spout 227 to open on the mounting panel 23, translation sand grip 221 has on the cylinder body bottom surface of translation cylinder 22, translation sand grip 221 blocks into in the translation spout 227 and can slide relative translation spout 227, the cylinder body side of translation cylinder 22 is fixed with stopper 223, stopper 223 opens towards one side of translation sliding seat 226 has location logical groove 224, the side card of translation sliding seat 226 is blocked into location logical groove 224, the below at translation sliding seat 226 is fixed to mounting panel 23. The upper and lower edges of the side surface of the translational sliding seat 226 are both provided with positioning chamfers 228, and the groove walls of both sides of the positioning through groove 224 are both positioning inclined surfaces 225 capable of abutting against the positioning chamfers 228. One end of the translational sliding seat 226 is provided with a second connecting block portion 229 which is vertically protruded, the second connecting block portion 229 is provided with a bayonet 229a, the bayonet 229a is U-shaped, the inner wall of the bayonet 229a is protruded to form a limiting strip matched with the shape of the bayonet 229a, the end of the telescopic rod of the translational air cylinder 22 is fixed with two clamping pieces 222, and the limiting strip is clamped between the two clamping pieces 222.

The clamping jaw 24 comprises a finger cylinder 241 and two clamping heads 242, the two clamping heads 242 are respectively fixed on the cylinder arm of the finger cylinder 241, and the opposite side surfaces of the two clamping heads 242 are provided with embedded grooves 243.

As shown in fig. 1 to 3 and 6, the length detection device includes an upper distance sensor 3 and a lower distance sensor 31, the lower distance sensor 31 is fixed on the measuring table 11, and a shaft core 51 corresponding to the detection base 5 is located right above the lower distance sensor 31, and the upper distance sensor 3 is fixed on the worktable 1 and can move right below the upper distance sensor 3 corresponding to the shaft core 51 of the detection base 5. The upper distance sensor 3 and the lower distance sensor 31 are respectively contacted with the upper end surface and the lower end surface of the shaft, and the positions among the upper distance sensor 3, the lower distance sensor 31 and the shaft core 51 are determined, so that the length of a section with a larger shaft diameter can be detected by the upper distance sensor 3, and the length of a section with a smaller shaft diameter can be detected by the lower distance sensor 31; during detection, the rotating structure drives the shaft core 51 to rotate, so that the shaft can also rotate, the upper distance sensor 3 can be respectively contacted with different positions of the upper end surface of the shaft, the lower distance sensor 31 can be respectively contacted with different positions of the lower end surface of the shaft, and the lengths of a section with a larger shaft diameter and a section with a smaller shaft diameter can be accurately obtained through measurement of a plurality of positions; preferably, the upper distance sensor 3 and the lower distance sensor 31 in the present application are sensors of type GT2-a50, which are existing products.

As shown in fig. 1 to 3 and 6, the inner hole detection device includes a detection air pump and an air tightness measuring instrument 4, a lifting frame 41 is arranged on the workbench 1, two pneumatic measuring heads 42 which are vertically and upwards arranged are fixed on the lifting frame 41, the lifting frame 41 can drive the two pneumatic measuring heads 42 to move up and down, the two pneumatic measuring heads 42 can be respectively located under two shaft cores 51 corresponding to the two detection bases 5, the detection air pump is connected with the air tightness measuring instrument 4 through an air pipe, and the air tightness measuring instrument 4 is respectively connected with the two pneumatic measuring heads 42 through the air pipe. The pneumatic side head is lifted by the lifting frame 41 and penetrates into the inner hole of the shaft, meanwhile, the air pump is detected to be inflated, and airflow enters the inner hole through the pneumatic measuring head 42 after passing through the air tightness measuring instrument 4; because the pneumatic gauge head 42 does not necessarily lie in the axis of axle when penetrating the hole of axle, consequently through the axis of rotation when detecting between the inner wall that makes the axle hole and the pneumatic side head dynamic change, airtight measuring apparatu 4 can detect the pressure change of following the pneumatic gauge head 42 outflow gas to compare with the value of prestoring on sending data to the computer, if the data is in the scope of prestoring the value then the hole size of axle satisfies the requirement, if the data is outside the scope of prestoring the value then the hole size of axle is unqualified, carry out twice detection through the hole of two sets of detection bases 5 axles, guarantee the precision of detecting.

As shown in fig. 1, 2 and 6, the lifting frame 41 includes a detection lifting cylinder 411, a detection lifting slide seat 412 and a measuring head mounting plate 413, the detection lifting cylinder 411 is fixed on the measuring table 11, a telescopic rod of the detection lifting cylinder 411 is fixed with the detection lifting slide seat 412, a detection lifting guide strip vertically arranged is arranged on a cylinder body of the detection lifting cylinder 411, a detection lifting through groove is formed in the detection lifting slide seat 412, the detection lifting guide strip is clamped into the detection lifting through groove and can relatively detect the lifting through groove to slide, and the measuring head mounting plate 413 is fixed on the detection lifting slide seat 412. Detect lift cylinder 411 and be two pole cylinders, two telescopic links that detect lift cylinder 411 are fixed with detection lift slide 412, and two pole cylinders can make and detect lift slide 412 and reciprocate more stably. Detect and be fixed with fixing base 414 on the cylinder body of lift cylinder 411, be fixed with the sensor on the fixing base 414, the probe of sensor can support with fixing base 414 and lean on. The sensor can be triggered when the fixed base 414 is returned.

As shown in fig. 1, 2 and 6, the mounting bracket 2 is fixed with positioning cylinders 43 corresponding to the two detection bases 5 for detecting the shaft inner holes one by one, the telescopic rods of the positioning cylinders 43 are vertically arranged downwards and located right above the corresponding shaft cores 51, the telescopic rods of the positioning cylinders 43 are fixed with positioning heads 44, and the lower ends of the positioning heads 44 are provided with convex balls. When in detection, the ball of the positioning head 44 is abutted against the upper end of the shaft through the positioning air cylinder 43, so that the shaft is fixedly abutted against the shaft core 51.

As shown in fig. 1 to 3, 6 and 10, the rotating structure includes a driving motor 59 and a belt 592, the detection base 5 includes a bearing seat 52 fixed to the measuring table 11, and an upper bearing 53 and a lower bearing 54 rotatably connected in the bearing seat 52, the shaft core 51 is inserted and positioned in an inner ring of the upper bearing 53, a pulley shaft 55 is inserted and positioned in an inner ring of the lower bearing 54, a relief gap 553 is provided between the shaft core 51 and the pulley shaft 55, the pulley shaft 55 and the shaft core 51 are positioned in a circumferential direction and the pulley shaft 55 can move axially relative to the shaft core 51, a lower end of the pulley shaft 55 penetrates through the bearing seat 52 and is fixedly connected with a driven pulley 554, the driven pulley 554 has an annular guide convex ring 557 protruding upward, the guide convex ring 557 penetrates through the bearing seat 52, the driven pulley 554 and a lower end face of the bearing seat 52 have a relief gap 558, the driving motor 59 is fixed on the measuring table 11, a rotating shaft of the driving motor 59 is fixed with a driving pulley 591, and the three driven pulleys 554 are connected by the tensioned belt 592. The shaft core 51 and the pulley shaft 55 are rotatably connected in the bearing seat 52 through an upper bearing 53 and a lower bearing 54 respectively, the connecting structures between the shaft core 51 and the pulley shaft 55 and the bearing seat 52 are mutually independent, the shaft core 51 and the pulley shaft 55 are only positioned in the circumferential direction, the belt 592 can float up and down when driving the driven pulley 554 to rotate, the driven pulley 554 can drive the pulley shaft 55 to float up and down, a space which floats up and down is formed between the pulley shaft 55 and the shaft core 51 due to the clearance one 553, a space which floats up and down is formed between the driven pulley 554 and the bearing seat 52 due to the clearance two 558, and the shaft core 51 is not connected with the pulley shaft 55 in the axial direction, so that the up and down floating of the driven pulley 592 and the pulley shaft 55 cannot cause the vibration or the movement of the shaft core 51 or the bearing seat 52, and a shaft to be detected positioned on the shaft core 51 cannot be influenced, and the precision and the accuracy of shaft detection can be ensured; the belt 592 drives the driven pulleys 554 to rotate, synchronous detection of the detection bases 5 can be achieved, the structure is compact, and detection efficiency is high.

As shown in fig. 10, at least two insertion holes are formed in the lower end surface of the shaft core 51, the upper end surface of the pulley shaft 55 is provided with protruding insertion rods 552 corresponding to the insertion holes one by one, an abdicating gap 553 is formed between the lower end surface of the shaft core 51 and the upper end surface of the pulley shaft 55, the insertion rods 552 can be inserted into the corresponding insertion holes, and the insertion rods 552 can move axially relative to the insertion holes. The shaft core 51 and the pulley shaft 55 rotate synchronously through the matching of the plug rod 552 and the plug hole. The lower end peripheral surface of the shaft core 51 is provided with a convex first convex ring 512, the insertion hole is arranged on the lower end surface of the convex first convex ring 512, the upper end peripheral surface of the belt pulley shaft 55 is provided with a convex second convex ring 551, and the insertion rod 552 is arranged on the upper end surface of the convex second convex ring 551.

The bearing seat 52 comprises an upper bearing seat 521 and a lower bearing seat 523, the upper bearing seat 521 is fixed with the measuring table 11 through bolts, the lower bearing seat 523 is fixed on the lower bottom surface of the lower bearing seat 523, an upper abutting convex edge 522 is arranged at the position, close to the lower end, of an inner hole of the upper bearing seat 521, an outer ring of the upper bearing 53 abuts against the upper abutting convex edge 522, a lower abutting convex edge 524 is arranged at the position, close to the lower end, of the inner hole of the lower bearing seat 523, and an outer ring of the lower bearing 54 abuts against the lower abutting convex edge 524.

The shaft core 51 is provided with an upper through hole 511, the pulley shaft 55 is provided with a lower through hole 559, the diameter of the lower through hole 559 is larger than that of the upper through hole 511, the upper through hole 511 of the shaft core 51 is communicated with the lower through hole 559 of the pulley shaft 55, and the middle part of the driven pulley 554 is provided with a position-avoiding through hole 555 communicated with the lower through hole 559.

The lower end of the abdicating through hole 555 of the driven pulley 554 is provided with a positioning convex edge 556, the pulley shaft 55 is inserted into the abdicating through hole 555 and is abutted against the positioning convex edge 556, and the pulley shaft 55 is fixed with the positioning convex edge 556 through a bolt.

An end cover 56 is fixed on the upper end face of the bearing seat 52, an abdicating hole is formed in the middle of the end cover 56, a reference panel 57 is fixed on the upper end face of the shaft core 51, a reference convex surface 571 is formed on the upper plate surface of the reference panel 57, a reference convex ring 572 is formed on the lower plate surface of the reference panel 57, the reference convex ring 572 passes through the abdicating hole to be attached and fixed to the upper end face of the shaft core 51, and the lower plate surface of the reference panel 57 is attached to the end cover 56. The inspection base 5 has three, the driven pulleys 554 have three and are arranged side by side, and the belt 592 abuts against the outside of the driven pulleys 554 located on both sides away from the measuring table 11 and abuts against the inside of the driven pulleys 554 located in the middle near the measuring table 11.

The rotation fixing bracket 58 is fixed on the measuring table 11, the driving motor 59 is fixed on the rotation fixing bracket 58, a strip-shaped through hole 113 is formed on the measuring table 11, and the belt 592 passes through the through hole 113.

As shown in fig. 1 to 5, the automatic feeding device includes a push-pull plate 62, a downward elongated feed opening 6a is provided on the hopper 6, the push-pull plate 62 is located between the workbench 1 and the hopper 6, and the push-pull plate 62 can move back and forth along the front-back direction, a feeding through groove 621 capable of accommodating only one shaft is provided in the middle of the push-pull plate 62, an upper notch of the feeding through groove 621 can be aligned with the feed opening 6a, a pushing support 63 is further fixed on the workbench 1, the pushing support 63 is located at the rear portion of the hopper 6, a material ejecting block 65 capable of sliding and sliding from one end of the feeding through groove 621 to the other end is provided on the pushing support 63, and the other end of the feeding through groove 621 can be aligned with the feeding reversing sleeve 12 in a horizontal state. A shaft to be detected is placed in the hopper 6, the push-pull plate 62 is pushed to move forwards until the feeding through groove 621 of the push-pull plate 62 is aligned with the discharging opening 6a, at the moment, the shaft in the hopper 6 at the discharging opening 6a falls into the feeding through groove 621, the push-pull plate 62 is retracted, the push-pull plate 62 moves backwards to draw out the shaft in the feeding through groove 621, at the moment, the upper plate surface of the push-pull plate 62 is aligned with the discharging opening 6a, the shaft is prevented from falling out of the hopper 6, when the push-pull plate 62 moves to enable the ejector block 65 to be aligned with the feeding through groove 621, the push-pull plate stops moving, at the moment, the feeding through groove 621 is aligned with the feeding reversing sleeve 12, the ejector block 65 slides and pushes the shaft in the feeding through groove 621 to move towards the feeding reversing sleeve 12 until the shaft is inserted into the feeding reversing sleeve 12, and the automatic feeding of the shaft is realized in a reciprocating manner; the push-pull plate 62 with the feeding through groove 621 moves back and forth to ensure that only one shaft is drawn out at each time, and the shaft is pushed to the feeding reversing sleeve 12 through the material pushing block 65, so that the structure is simple, and continuous feeding of the shaft can be ensured.

The material pushing support 63 comprises a portal frame and a first sliding rail 632 fixed on the portal frame, the first sliding rail 632 is parallel to the feeding through groove 621, the first sliding rail 632 is connected with a blanking sliding block 64 in a sliding mode, a driving source capable of pushing the blanking sliding block 64 to slide back and forth is arranged on the portal frame, and the material pushing block 65 is fixed with the blanking sliding block 64. The driving source can be a motor or an air cylinder, the first sliding rail 632 slides back and forth to drive the ejector block 65 to move back and forth, when the push-pull plate 62 moves back, a shaft is arranged in the feeding through groove 621, the ejector block 65 is located at one end of the feeding through groove 621, the ejector block 65 moves towards the other end of the feeding through groove 621, the ejector block 65 can abut against one end of the shaft and push the shaft to move in the process, and finally the shaft is pushed into the feeding reversing sleeve 12.

The blanking sliding block 64 is fixed with a fixed sheet metal part 641, the lower end of the fixed sheet metal part 641 is provided with a fixed part 642, the ejector block 65 is cylindrical, one end of the ejector block 65 is provided with a positioning step, the fixed part 642 is embedded into the positioning step of the ejector block 65 and fixed with the ejector block 65 through bolts, and the other end of the ejector block 65 is an ejector end face. The ejector block 65 is made of brass or plastic. The hardness of brass and plastic is low, so that damage to the shaft during material ejection is avoided; brass is not easy to wear and has long service life, which is the preferred scheme.

The hopper 6 comprises two side plates 61 arranged in parallel, a rear baffle 611 and an inclined plate 612 which are fixed between the two side plates 61, the lower ends of the two side plates 61 are fixed with the workbench 1, the rear baffle 611 is arranged vertically, a gap is arranged between the lower end of the rear baffle 611 and the workbench 1, the inclined plate 612 inclines along the vertical direction, a gap is arranged between the lower end of the inclined plate 612 and the workbench 1, and the lower end of the inclined plate 612 and the lower end of the rear baffle 611 form the feed opening 6a. The inner side surfaces of the two side plates 61 are fixed with protection plates 613, and the protection plates 613 are made of plastics.

The width of the feeding opening 6a is at least twice as large as that of the feeding through groove 621. The dead condition of card between feed opening 6a between the axle and the axle has been avoided, has guaranteed that feed opening 6a and material loading lead to groove 621 and have a axle to get into in the logical groove 621 of material loading certainly when aligning. The distance between the upper end surface of the push-pull plate 62 and the baffle plate and the inclined plate 612 is smaller than the width of the feeding through groove 621. The shaft can be prevented from entering the space between the push-pull plate 62 and the baffle and sloping plate 612 when the push-pull plate 62 moves back and forth, ensuring that only one shaft can be pulled out of the push-pull plate 62 each time. The upper edges of the push-pull plate 62 on both sides of the loading through slot 621 are provided with guide chamfers 622. Two sliding rails II 66 are fixed on the workbench 1 along the front-back direction, the push-pull plate 62 is connected to the sliding rails II 66 in a sliding mode, and a feeding pushing cylinder 67 capable of pushing the push-pull plate 62 to move back and forth is fixed on the workbench 1.

As shown in fig. 2, the automatic discharging device includes a clamping arm 75 fixed on the workbench 1, a discharging support 71 is fixed on the workbench 1, a discharging guide rail 72 horizontally arranged is fixed on the discharging support 71, the magazine 7 is located under the discharging guide rail 72, and both ends of the discharging guide rail 72 are located outside the magazine 7, a sliding seat 73 is slidably connected on the discharging guide rail 72, a discharging lifting cylinder 74 is vertically fixed on the sliding seat 73, a telescopic rod of the discharging lifting cylinder 74 is arranged downward, and the clamping arm 75 is fixed on the telescopic rod of the discharging lifting cylinder 74. Shaft detection equipment has ejection of compact switching-over sleeve 121, and the axle that ejection of compact switching-over sleeve 121 will detect the completion rotates to horizontal position, presss from both sides the axle through arm lock 75 this moment, and ejection of compact switching-over sleeve 121 retreats and makes the axle withdraw from in the ejection of compact switching-over sleeve 121, and the arm lock 75 that rethread slide 73 will accompany the axle removes to magazine 7 top to make arm lock 75 descend through ejection of compact lift cylinder 74 and place the axle in magazine 7, how reciprocal realization automatic discharging.

During detection, a plurality of shafts to be detected are placed in the hopper 6, the shafts are pulled out from the hopper 6 one by one through the push-pull plate 62, the pulled shafts are pushed to the feeding reversing sleeve 12 through the ejector block 65, at the moment, the feeding reversing sleeve 12 is aligned with the feeding through groove 621 of the push-pull plate 62, the shafts are inserted into the feeding reversing sleeve 12, the feeding reversing sleeve 12 is rotated to a vertical position through the motor, the shafts are vertically arranged, the measuring table 11 transversely moves towards one side of the hopper 7 through the transverse moving pushing cylinder 112, the shafts vertically arranged on the feeding reversing sleeve 12 move to be right below the clamping jaws 24 close to the hopper 6, the clamping jaws 24 clamp the shafts and pull the shafts out of the feeding reversing sleeve 12, the measuring table 11 is moved back to an initial position, at the moment, the shafts on the clamping jaws 24 close to the hopper 6 are positioned right above the detection base 5 close to the hopper 6, the clamping jaws 24 are axially inserted into the detection base 5, and at the same time, the lifting frame 41 extends the pneumatic measuring head 42 into the inner hole of the shaft for detection, the clamping jaw 24 extracts the shaft from the detection base 5 after the detection is finished, the shaft is inserted into the second detection base 5 for pneumatic detection through the back and forth movement of the measuring table 11, the shaft is inserted into the third detection base 5 through the matching of the clamping jaw 24 and the measuring table 11 after the size of the inner hole is detected twice, the length of the shaft is detected through the upper distance sensor 3 and the lower distance sensor 31, the shaft rotates along with the detection base 5 in the detection process, the shaft is inserted into the discharging reversing sleeve 121 through the matching of the clamping jaw 24 and the measuring table 11 after the detection is finished, the discharging reversing sleeve 121 rotates to enable the shaft to be horizontal, then the shaft is clamped through the clamping arm 75, the shaft is extracted from the discharging reversing sleeve 121 through the retraction of the measuring table 11, the clamping arm 75 puts the shaft into the material box 7 for recovery, completing the detection of the shaft; the detection process is carried out in a flow line mode, and therefore shafts are arranged in the three detection bases 5 when detection is carried out at each time, and therefore detection efficiency is high.

The specific embodiments described herein are merely illustrative of the spirit of the invention. Various modifications or additions may be made to the described embodiments or alternatives may be employed by those skilled in the art without departing from the spirit or ambit of the invention as defined in the appended claims.

Claims (8)

1. A rotating structure of a detection base in shaft detection equipment is characterized in that the rotating structure comprises a driving motor and a pulley shaft inserted in an inner ring of a lower bearing, a yielding gap I is formed between the shaft core and the pulley shaft, the pulley shaft and the shaft core are positioned in the circumferential direction and can move axially relative to the shaft core, the lower end of the pulley shaft penetrates through the bearing seat and is fixedly connected with a driven pulley, a yielding gap II is formed between the driven pulley and the lower end surface of the bearing seat, the driving motor is fixed on the measurement platform, a driving pulley is fixed on a rotating shaft of the driving motor, and the driving pulley is connected with a plurality of driven pulleys through tensioned belts; the lower end face of the shaft core is provided with at least two insertion holes, the upper end face of the belt pulley shaft is provided with protruding insertion rods which correspond to the insertion holes one by one, the yielding gap I is formed between the lower end face of the shaft core and the upper end face of the belt pulley shaft, the insertion rods can be inserted into the corresponding insertion holes, and the insertion rods can axially move relative to the insertion holes; the bearing frame includes bolster bearing housing and step, bolster bearing housing passes through the bolt and fixes with the measuring desk, the step is fixed on the lower bottom surface of step, bolster bearing housing's hole is close to lower extreme department and has to support to lean on protruding edge on, the outer lane of upper bearing supports with to support on to support and lean on protruding edge, the hole of step is close to lower extreme department and has to support under and lean on protruding edge, the outer lane of lower bearing supports with to support under and lean on protruding edge and support and lean on.

2. The rotation structure of a sensing base in a shaft sensing apparatus according to claim 1, wherein the driven pulley has a guide protrusion ring in a ring shape protruded upward, the guide protrusion ring penetrating into the bearing housing.

3. The rotation structure of the detection base in the shaft detection device according to claim 1, wherein the shaft core has a first protruding ring on a lower end peripheral surface thereof, the insertion hole is formed in a lower end surface of the first protruding ring, the belt pulley shaft has a second protruding ring on an upper end peripheral surface thereof, and the insertion rod is disposed on an upper end surface of the second protruding ring.

4. The rotation structure of a detection base in a shaft detection apparatus according to claim 1, wherein an upper through hole is formed in the shaft core, a lower through hole is formed in the pulley shaft, the diameter of the lower through hole is larger than that of the upper through hole, the upper through hole of the shaft core is communicated with the lower through hole of the pulley shaft, and a abdicating through hole communicated with the lower through hole is formed in the middle of the driven pulley.

5. The rotation structure of a detection base in an axis detection device according to claim 1, wherein a positioning convex edge is provided at a lower end of the abdicating through hole of the driven pulley, the pulley shaft is inserted into the abdicating through hole and abuts against the positioning convex edge, and the pulley shaft is fixed to the positioning convex edge by a bolt.

6. The rotating structure of the detecting base in the shaft detecting device according to claim 1, wherein an end cover is fixed on the upper end surface of the bearing seat, a yielding hole is formed in the middle of the end cover, a reference panel is fixed on the upper end surface of the shaft core, a reference convex surface is arranged on the upper plate surface of the reference panel, a reference convex ring is arranged on the lower plate surface of the reference panel, the reference convex ring passes through the yielding hole and is attached to and fixed with the upper end surface of the shaft core, and the lower plate surface of the reference panel is attached to the end cover.

7. The rotary structure of the detecting base in the shaft detecting device according to claim 1, wherein the detecting base has three, the driven pulleys have three and are arranged side by side, and the belt is abutted with the outer sides of the driven pulleys at both sides far from the measuring table and abutted with the inner sides of the driven pulleys at the middle near the measuring table.

8. The rotary structure of the detecting base in the shaft detecting device according to claim 1, wherein a rotary fixing bracket is fixed to the measuring table, the driving motor is fixed to the rotary fixing bracket, a through hole in a bar shape is formed in the measuring table, and the belt passes through the through hole.

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