CN117232831A - Automatic chain performance detection equipment - Google Patents

Abstract

The invention relates to the technical field of chain detection, and discloses automatic chain performance detection equipment which comprises a bottom plate, support assemblies, detection mechanisms and limit guide assemblies, wherein the bottom plate is placed at a mounting position for fixing, the support assemblies are symmetrically arranged at the front and back of the upper end face of the bottom plate, a plurality of groups of detection mechanisms are arranged between the support assemblies, the limit guide assemblies are arranged below the detection mechanisms, and are arranged on the bottom plate.

Description

Automatic chain performance detection equipment

Technical Field

The invention relates to the technical field of chain detection, in particular to automatic detection equipment for chain performance.

Background

The chain is generally a metal chain ring or ring, is used for mechanical transmission and traction and is used for mechanical uploading, and can be divided into a short-pitch precise roller chain, a bending plate roller chain for heavy-duty transmission, a chain for cement machinery and a plate chain; the high-strength chain is mainly composed of chain plates, chain pins, sleeves and the like.

After the chain production is accomplished, in order to guarantee the quality of use, need test the chain to whether the circumstances of becoming flexible and unstability can appear in the observation chain after the atress, and when testing the chain, usually carry out the sequential test of piece by piece, single project to the chain, thereby will reduce the effect of test, test structure can only test to the chain of appointed size moreover, when meetting different size chains, only can test to need change the part, thereby lacks adaptability.

Disclosure of Invention

The technical problems to be solved are as follows: the automatic detection equipment for the chain performance can solve the problems pointed out in the background technology.

The technical scheme is as follows: in order to achieve the above purpose, the invention adopts the following technical scheme that the automatic chain performance detection equipment comprises a bottom plate, support assemblies, detection mechanisms and limit guide assemblies, wherein the bottom plate is placed at a mounting position for fixing, the support assemblies are symmetrically arranged on the front and back of the upper end face of the bottom plate, a plurality of groups of detection mechanisms are arranged between the support assemblies, the limit guide assemblies are arranged below the detection mechanisms, and the limit guide assemblies are arranged on the bottom plate.

The support assembly comprises a transverse -shaped frame, wherein the transverse -shaped frame is of a -shaped structure with a downward opening, the lower end face of the transverse -shaped frame is arranged on a bottom plate, longitudinal -shaped frames are uniformly arranged on the bottom face of the upper portion of the transverse -shaped frame from left to right, the longitudinal -shaped frame is of a -shaped structure with an upward opening, threaded rods are rotatably arranged at corresponding positions of the upper end faces of the transverse -shaped frames and the longitudinal -shaped frames, the threaded rods are connected through a linkage assembly, the lower ends of the threaded rods penetrate through the transverse -shaped frames and are rotatably connected with the bottoms of the longitudinal -shaped frames, lifting sliding blocks are slidably arranged in the longitudinal -shaped frames, the middle parts of the lifting sliding blocks are arranged on the threaded rods in a threaded fit mode, support columns are arranged on the lower end faces of the longitudinal -shaped frames, and the lower ends of the support columns are arranged on the bottom plate.

The detection mechanism comprises a return frame, the left side and the right side of the front end face and the rear end face of the return frame are connected with corresponding lifting sliding blocks, square blocks are arranged in the return frame, the left side and the right side of each square block are connected through a plurality of connecting shafts, the outer wall of each connecting shaft is rotatably arranged on the side wall of the return frame in a penetrating mode, a converting motor is installed on the left end face of the leftmost return frame through a motor base, the output end of the converting motor is connected with the leftmost connecting shaft, the right end face of the rightmost connecting shaft is rotatably connected with the return frame, and a reciprocating extrusion component is arranged on each square block.

Further, the linkage assembly comprises a driving belt, the driving belt is used for connecting and driving a plurality of threaded rods, the upper end face of the right part of the transverse -shaped frame is provided with a transition rod in a rotating mode, the transition rod is connected with the threaded rod on the rightmost side through a first connecting belt, the transition rods on the front side and the rear side are connected through a second connecting belt, belt grooves are formed in the corresponding positions of the outer wall of the upper part of the threaded rod and the belt, the upper end of one transition rod is connected with an output shaft of a rotating motor, and the rotating motor is installed on the transverse -shaped frame through a motor base.

Further, the reciprocating extrusion and pulling assembly comprises a bidirectional cylinder, the bidirectional cylinder is fixedly arranged inside the square block, the front side and the rear side of the square block are respectively provided with a transverse reciprocating part and a longitudinal reciprocating part, the telescopic ends of the bidirectional cylinder are respectively connected with the transverse reciprocating part and the longitudinal reciprocating part, and the transverse reciprocating part and the longitudinal reciprocating part are arranged in a longitudinal and transverse staggered mode and have the same structure.

Further, horizontal reciprocating part includes the mounting panel, mounting panel fixed mounting has offered the kidney slot at square block rear end face bilateral symmetry on the mounting panel, and the axle that slides is all installed through sliding connection mode in the kidney slot, and the curb plate is all installed to the axle other end that slides, and rectangular channel has all been seted up to the opposite face of curb plate, and the bull stick is all installed through round pin axle front and back symmetry in the rectangular channel, and the other end of bull stick is all installed on the hollow block through the round pin axle, and the hollow block is installed at the flexible end of two-way cylinder, and the flexible outer wall of two-way cylinder wears to establish with the mounting panel slip and sets up.

Further, the longitudinal reciprocating part and the transverse reciprocating part are identical in structure and are arranged in a front-back crisscross mode, and the end faces, far away from the sliding shaft, of the side plates of the longitudinal reciprocating part and the transverse reciprocating part are respectively provided with a longitudinal clamping part and a transverse clamping part which are symmetrically arranged.

Further, horizontal clamping part is including transferring the board, has transferred to set up rectangular channel on the board that moves, and the displacement screw rod is installed in the rectangular channel rotation, and hollow piece one end is kept away from to the displacement screw rod extends to transferring the board outside, and slidable mounting has the cardboard in the rectangular channel, and the cardboard is installed on the displacement screw rod through the screw thread fit mode, and the cardboard is fork structure and both sides thickness from front to back taper.

Further, the longitudinal clamping part comprises a spacing plate, a long groove is formed in the spacing plate, a bidirectional screw rod is rotatably installed in the long groove, one end, far away from the hollow block, of the bidirectional screw rod extends to the outer side of the spacing plate, supporting push rods are symmetrically arranged on the bidirectional screw rod, fixed ends of the supporting push rods are slidably arranged in the long groove, and arc-shaped grooves are formed in one side, far away from the hollow block, of the outer wall of the supporting push rods.

Further, the limiting guide assembly comprises a wheel frame, the wheel frame is installed on the bottom plate in a front-back symmetrical mode, and a chain wheel is installed on the outer wall of the middle of the wheel frame in a running fit mode.

The beneficial effects are as follows:

1. the support assembly and the detection mechanism are matched to test a plurality of chains with different sizes, the height of the chains can be synchronously lifted and moved, the adaptability of the limiting clamping positions is adjusted, the chains are continuously tested transversely and longitudinally in sequence through synchronous rotation and conversion, and the testing efficiency and the adaptability are improved.

2. The linkage assembly drives the plurality of detection mechanisms to synchronously lift, the height of the test position is synchronously moved, the plurality of square blocks are driven to synchronously rotate through the plurality of connecting shafts by the rotation of the conversion motor to carry out position conversion, so that the plurality of chains can be synchronously detected in a transverse and longitudinal reciprocating manner, and the working efficiency is improved.

3. The clamping plate can be moved to a position matched with the chain plate by rotating the displacement screw according to the width dimension of the chain, and the clamping plate is downwards moved to be clamped on the chain plate for position determination, so that a transverse test is performed; according to different pitch sizes of the chains, the distance between the pushing rods is adjusted by rotating the bidirectional screw rod, so that the pushing rods can smoothly enter gaps between the chain sleeves, longitudinal testing is performed, and adaptability is greatly improved.

Drawings

Fig. 1 is a top view of the present invention.

Fig. 2 is an enlarged view of fig. 1 according to the present invention.

Fig. 3 is a cross-sectional view taken along line B-B of fig. 1 in accordance with the present invention.

Fig. 4 is a cross-sectional view taken along line C-C of fig. 1 in accordance with the present invention.

Fig. 5 is a D enlarged view of fig. 3 according to the present invention.

Fig. 6 is an enlarged cross-sectional view of fig. 3 according to the present invention.

Fig. 7 is a schematic structural view of the wheel frame of the present invention.

In the figure: 1. a bottom plate; 2. a bracket assembly; 21. a transverse -shaped rack; 22. a longitudinal -shaped rack; 23. a threaded rod; 24. a linkage assembly; 241. a drive belt; 242. a transition rod; 243. a first connecting belt; 244. a second connecting belt; 245. a rotating motor; 25. a lifting slide block; 26. a support column; 3. a detection mechanism; 31. a mold frame; 32. square blocks; 33. a connecting shaft lever; 34. converting a motor; 35. a reciprocating squeeze-and-pull assembly; 351. a bidirectional cylinder; 352. a transverse reciprocating part; 3521. a mounting plate; 3522. a slip shaft; 3523. a side plate; 3524. a rotating rod; 3525. a hollow block; 353. a longitudinal reciprocation part; 354. a longitudinal clamping portion; 3541. a spacing plate; 3542. a bidirectional screw; 3543. a push rod; 355. a lateral clamping portion; 3551. a transfer plate; 3552. a displacement screw; 3553. a clamping plate; 4. a limit guide assembly; 41. a wheel carrier; 42. a sprocket.

Detailed Description

The following description of the embodiments of the present invention 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 invention, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

Referring to fig. 1, the present invention provides a technical solution: the utility model provides a chain performance automated inspection equipment, includes bottom plate 1, bracket component 2, detection mechanism 3 and spacing direction subassembly 4, bottom plate 1 is placed and is fixed at the mounted position, and bracket component 2 is installed to the symmetry around the bottom plate 1 upper end, is provided with multiunit detection mechanism 3 between the bracket component 2, and detection mechanism 3's below all is provided with spacing direction subassembly 4, and spacing direction subassembly 4 is installed on bottom plate 1.

Referring to fig. 3, in this embodiment, the limit guide assembly 4 includes a wheel frame 41, the wheel frame 41 is symmetrically mounted on the bottom plate 1, and a sprocket 42 is mounted on the outer wall of the middle of the wheel frame 41 in a manner of running fit; during operation, the rear side of the transverse -shaped frame 21 is provided with an existing chain unreeling structure, the front side of the transverse -shaped frame 21 is provided with an existing chain reeling structure, so that intermittent unreeling and reeling are carried out on a chain, the chain is limited and prevented from shifting when moving through the matched rotation of the two corresponding chain wheels 42 arranged front and back, and the chain wheels 42 can ensure the horizontal straightening and stability of the chain when stopping unreeling.

Referring to fig. 1 and 4, in this embodiment, the bracket assembly 2 includes a transverse -shaped frame 21, the transverse -shaped frame 21 has a -shaped structure with a downward opening, the lower end surface of the transverse -shaped frame 21 is mounted on the bottom plate 1, the upper bottom surface of the transverse -shaped frame 21 is uniformly provided with a longitudinal -shaped frame 22 from left to right, the longitudinal -shaped frame 22 has a -shaped structure with an upward opening, the upper end surface of the transverse -shaped frame 21 and the corresponding position of the longitudinal -shaped frame 22 are rotatably mounted with a threaded rod 23, the threaded rods 23 are connected through a linkage assembly 24, the lower end of the threaded rod 23 passes through the transverse -shaped frame 21 and is rotatably connected with the bottom of the longitudinal -shaped frame 22, lifting sliders 25 are slidably mounted in the longitudinal -shaped frame 22, the middle parts of the lifting sliders 25 are mounted on the threaded rods 23, the lower end surfaces of the longitudinal -shaped frames 22 are mounted with support columns 26, and the lower ends of the support columns 26 are mounted on the bottom plate 1.

The linkage assembly 24 comprises a transmission belt 241, the transmission belt 241 connects and transmits a plurality of threaded rods 23, the upper end face of the right part of the transverse -shaped frame 21 is provided with a transition rod 242 in a rotating way, the transition rod 242 is connected with the threaded rod 23 on the rightmost side through a first connecting belt 243, the transition rods 242 on the front side and the rear side are connected through a second connecting belt 244, belt grooves are formed in the corresponding positions of the outer walls of the upper parts of the threaded rods 23 and the belts, the upper end of one transition rod 242 is connected with the output shaft of a rotating motor 245, and the rotating motor 245 is arranged on the transverse -shaped frame 21 through a motor seat; during operation, the rotating motor 245 is started, and the rotating motor 245 is matched with the transmission belt 241 through the transition rod 242, the second connecting belt 244, the first connecting belt 243 and the transmission belt 242 to drive all the threaded rods 23 to synchronously rotate, so that the lifting sliding blocks downwards move in the longitudinal -shaped frame 22 to drive the detection mechanism 3 to move to the working position, and synchronous detection of multiple groups of chains can be realized.

Referring to fig. 1, 2, 3 and 5, in this embodiment, the detection mechanism 3 includes a mold-returning frame 31, the front end surface and the left and right sides of the rear end surface of the mold-returning frame 31 are both connected with corresponding lifting sliders 25, square blocks 32 are disposed in the mold-returning frame 31, the left and right sides of the square blocks 32 are all connected through a plurality of connecting shafts 33, the outer walls of the connecting shafts 33 are all rotatably arranged on the side walls of the mold-returning frame 31, a conversion motor 34 is mounted on the left end surface of the mold-returning frame 31 at the leftmost side through a motor base, the output end of the conversion motor 34 is connected with the leftmost connecting shaft 33, the right end surface of the rightmost connecting shaft 33 is rotatably connected with the mold-returning frame 31, and a reciprocating extruding and pulling assembly 35 is disposed on the square blocks 32; during operation, the conversion motor 34 rotates to drive the square blocks 32 to synchronously rotate through the connecting shafts 33 to perform position conversion, so that the transverse and longitudinal reciprocating movement detection can be synchronously performed on the chains, the detection efficiency is improved, and the detection effect is also improved.

The reciprocating extruding and pulling assembly 35 comprises a bidirectional air cylinder 351, the bidirectional air cylinder 351 is fixedly arranged in the square block 32, a transverse reciprocating part 352 and a longitudinal reciprocating part 353 are arranged on the front side and the rear side of the square block 32, the telescopic ends of the bidirectional air cylinder 351 are respectively connected with the transverse reciprocating part 352 and the longitudinal reciprocating part 353, and the transverse reciprocating part 352 and the longitudinal reciprocating part 353 are arranged in a longitudinally-longitudinally staggered mode and have the same structure; the transverse reciprocating part 352 comprises a mounting plate 3521, the mounting plate 3521 is fixedly mounted on the rear end face of the square block 32, kidney-shaped grooves are symmetrically formed in the mounting plate 3521 in a left-right symmetry manner, sliding shafts 3522 are mounted in the kidney-shaped grooves in a sliding connection manner, side plates 3523 are mounted at the other ends of the sliding shafts 3522, rectangular grooves are formed in opposite faces of the side plates 3523, rotating rods 3524 are symmetrically mounted in the rectangular grooves front and back through pin shafts, the other ends of the rotating rods 3524 are mounted on hollow blocks 3525 through pin shafts, the hollow blocks 3525 are mounted at telescopic ends of the bidirectional air cylinders 351, and the outer walls of the telescopic shafts of the bidirectional air cylinders 351 are arranged in a sliding penetrating manner with the mounting plate 3521; the longitudinal reciprocation part 353 and the transverse reciprocation part 352 have the same structure and are arranged in a front-back crisscross manner, and the longitudinal reciprocation part 353 and the end surface of the side plate 3523 of the transverse reciprocation part 352, which is far away from the sliding shaft 3522, are respectively provided with a longitudinal clamping part 354 and a transverse clamping part 355 which are symmetrically arranged; when the sliding shaft 3522 is in operation, the bidirectional cylinder 351 is started to drive the hollow block 3525 to move along with the hollow block, so that the rotating rod 3524 rotates in position, and the sliding shaft 3522 is driven to slide back and forth in the kidney-shaped groove, so that the two side plates 3523 synchronously move back and forth in opposite directions.

Referring to fig. 2, in this embodiment, the transverse clamping portion 355 includes a shifting plate 3551, a rectangular groove is formed in the shifting plate 3551, a displacement screw 3552 is rotatably mounted in the rectangular groove, one end of the displacement screw 3552, which is far away from the hollow block 3525, extends to the outer side of the shifting plate 3551, a clamping plate 3553 is slidably mounted in the rectangular groove, the clamping plate 3553 is mounted on the displacement screw 3552 in a threaded fit manner, the clamping plate 3553 is in a fork-shaped structure, and the thicknesses of two sides of the clamping plate 3553 are gradually thinned from front to back.

Referring to fig. 6, in this embodiment, the longitudinal clamping portion 354 includes a spacing plate 3541, a long groove is formed in the spacing plate 3541, a bi-directional screw 3542 is rotatably mounted in the long groove, one end of the bi-directional screw 3542, which is far away from the hollow block 3525, extends to the outer side of the spacing plate 3541, a pushing rod 3543 is symmetrically disposed on the bi-directional screw 3542, a fixed end of the pushing rod 3543 is slidably disposed in the long groove, an arc-shaped groove is formed on one side, which is far away from the hollow block 3525, of the outer wall of the pushing rod 3543, during operation, according to different pitch sizes of the chain, the distance between the pushing rods 3543 can be smoothly adjusted by rotating the bi-directional screw 3542, and during the longitudinal reciprocating pushing test, the arc-shaped groove of the pushing rod 3543 cooperates with the outer wall of the chain sleeve to push the adjacent sleeves to two sides.

When the chain unreeling device works, the existing chain unreeling structure and the existing chain reeling structure are used for intermittently unreeling and reeling the chain, the two chain wheels 42 are arranged to rotate in a matched mode with the chain, limiting and deviation preventing of the chain in moving are achieved, and when unreeling is stopped, the chain wheels 42 can ensure horizontal straightening and stability of the chain; when a lateral test of the chain is required: the conversion motor 34 rotates forward by 90 degrees to enable the transverse reciprocating part 352 and the transverse clamping part 355 to rotate to the lower side, the rotary displacement screw 3552 moves the clamping plate 3553 to a position matched with the chain plate according to the width dimension of the chain, then the rotary motor 245 synchronously rotates all threaded rods 23 through the transition rod 242, the second connecting belt 244, the first connecting belt 243 and the transmission belt 241 matched with the belt, a plurality of lifting sliding blocks move downwards in the longitudinal -shaped frame 22 to drive the transverse reciprocating part 352 and the transverse clamping part 355 on the return frame 31 to the working position, the clamping plate 3553 moves downwards to clamp the outside of the chain plate to perform position determination, then the bidirectional cylinder 351 starts to drive the hollow block 3525 to move along with the clamping plate 3524 to perform position rotation to drive the sliding shaft 3522 to slide back and forth in the waist-shaped groove, so that the two side plates 3523 synchronously move back and forth, the clamping plate 3553 pulls two sides, the strength and the stability in the width direction of the chain are tested, and the transverse reciprocating part 352 and the transverse clamping part 355 move upwards and the rotation restore to the original positions after the test is completed.

When the chain needs to be longitudinally tested, the conversion motor 34 rotates reversely to rotate 90 degrees, so that the longitudinal reciprocating part 353 and the longitudinal clamping part 354 rotate to the lower side, the bidirectional screw 3542 rotates to adjust the distance between the pushing rods 3543 according to different pitch sizes of the chain, the pushing rods 3543 can smoothly enter a gap between the chain sleeves, then the motor 245 rotates to enable the longitudinal reciprocating part 353 and the longitudinal clamping part 354 on the return frame 31 to move downwards to a working position, the pushing rods 3543 move downwards and are inserted into the gap between the adjacent chain sleeves, the bidirectional cylinder 351 is used for starting to drive the hollow block 3525 to move along with the hollow block 3525, the rotating rod 3524 is used for position rotation, the sliding shaft 3522 is driven to reciprocate in the kidney-shaped groove, the pushing rods 3543 synchronously reciprocate in the two groups, and the outer walls of the corresponding chain sleeves are synchronously pushed against the outer sides of the corresponding chain sleeves when synchronously moving backwards, so that the strength and stability of the length direction of the chain are tested.

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. Without further limitation. The term "comprising" an element defined by the term "comprising" does not exclude the presence of other identical elements in a process, method, article or apparatus that comprises the element.

Although embodiments of the present invention 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 invention, the scope of which is defined in the appended claims and their equivalents.

Claims (8)

1. The utility model provides a chain performance automated inspection equipment, includes bottom plate (1), bracket component (2), detection mechanism (3) and spacing direction subassembly (4), its characterized in that: the base plate (1) is placed at the installation position for fixing, support assemblies (2) are symmetrically installed on the front and back of the upper end face of the base plate (1), a plurality of groups of detection mechanisms (3) are arranged between the support assemblies (2), limit guide assemblies (4) are arranged below the detection mechanisms (3), and the limit guide assemblies (4) are installed on the base plate (1);

the support assembly (2) comprises a transverse -shaped frame (21), the transverse -shaped frame (21) is of a -shaped structure with a downward opening, the lower end face of the transverse -shaped frame (21) is arranged on the bottom plate (1), longitudinal -shaped frames (22) are uniformly arranged on the bottom face of the upper part of the transverse -shaped frame (21) from left to right, the longitudinal -shaped frames (22) are of -shaped structures with an upward opening, threaded rods (23) are rotatably arranged at the corresponding positions of the upper end face of the transverse -shaped frame (21) and the longitudinal -shaped frames (22), the threaded rods (23) are connected through a linkage assembly (24), the lower ends of the threaded rods (23) penetrate through the transverse -shaped frame (21) and are rotatably connected with the bottom of the longitudinal -shaped frames (22), lifting sliding blocks (25) are slidably arranged in the longitudinal -shaped frames (22), the middle parts of the lifting sliding blocks (25) are arranged on the threaded rods (23), support columns (26) are rotatably arranged on the lower end faces of the longitudinal -shaped frames (22), and the lower ends of the support columns (26) are arranged on the bottom plate (1).

Detection mechanism (3) are including returning type frame (31), the left and right sides of preceding terminal surface and the rear end face of returning type frame (31) all are connected with corresponding lift slider (25), all be provided with square piece (32) in returning type frame (31), a plurality of square pieces (32) left and right sides all are connected through a plurality of connecting axostylus axostyle (33), connect axostylus axostyle (33) outer wall all rotate and wear to establish on returning type frame (31) lateral wall, changeover motor (34) are installed through the motor cabinet to the left side returning type frame (31) left end face, the output of changeover motor (34) is connected with left side connecting axostylus axostyle (33), right side connecting axostylus axostyle (33) right-hand member face and returning type frame (31) rotate and are connected, be provided with reciprocal crowded drawing subassembly (35) on square piece (32).

2. The automatic chain performance detection device according to claim 1, wherein: the linkage assembly (24) comprises a driving belt (241), the driving belt (241) is used for connecting and driving a plurality of threaded rods (23), the upper end face of the right part of the transverse -shaped frame (21) is rotatably provided with a transition rod (242), the transition rod (242) is connected with the threaded rod (23) on the rightmost side through a first connecting belt (243), the transition rods (242) on the front side and the rear side are connected through a second connecting belt (244), belt grooves are formed in the corresponding positions of the outer walls of the upper part of the threaded rods (23) and the belts, the upper end of one transition rod (242) is connected with the output shaft of a rotating motor (245), and the rotating motor (245) is arranged on the transverse -shaped frame (21) through a motor seat.

3. The automatic chain performance detection device according to claim 1, wherein: the reciprocating extrusion-pulling assembly (35) comprises a bidirectional cylinder (351), the bidirectional cylinder (351) is fixedly arranged inside the square block (32), the front side and the rear side of the square block (32) are respectively provided with a transverse reciprocating part (352) and a longitudinal reciprocating part (353), the telescopic ends of the bidirectional cylinder (351) are respectively connected with the transverse reciprocating part (352) and the longitudinal reciprocating part (353), and the transverse reciprocating part (352) and the longitudinal reciprocating part (353) are arranged in a front-back crisscross mode and have the same structure.

4. A chain performance automatic test equipment as claimed in claim 3 wherein: transverse reciprocating part (352) is including mounting panel (3521), mounting panel (3521) fixed mounting is at square piece (32) rear end face, the kidney-shaped groove has been seted up to bilateral symmetry on mounting panel (3521), sliding shaft (3522) are all installed through sliding connection mode in the kidney-shaped groove, curb plate (3523) are all installed to the sliding shaft (3522) other end, rectangular channel has all been seted up to the opposite face of curb plate (3523), the bull stick (3524) are all installed through round pin axle fore-and-aft symmetry in the rectangular channel, the other end of bull stick (3524) is all installed on hollow piece (3525) through the round pin axle, the flexible end at bi-directional cylinder (351) is installed to hollow piece (3525), the flexible outer wall of bi-directional cylinder (351) is worn to establish with mounting panel (3521) slip.

5. A chain performance automatic test equipment as claimed in claim 3 wherein: the longitudinal reciprocating part (353) and the transverse reciprocating part (352) are identical in structure and are arranged in a front-back crisscross mode, and the longitudinal clamping parts (354) and the transverse clamping parts (355) which are symmetrically arranged are respectively arranged on the end faces, far away from the sliding shaft (3522), of the lateral plates (3523) of the longitudinal reciprocating part (353) and the transverse reciprocating part (352).

6. The automatic chain performance detection apparatus as set forth in claim 5, wherein: transverse clamping part (355) is including transferring board (3551), has seted up the rectangular channel on transferring board (3551), and displacement screw rod (3552) are installed in the rectangular channel rotation, and hollow piece (3525) one end is kept away from to displacement screw rod (3552) extends to transferring board (3551) outside, and slidable mounting has cardboard (3553) in the rectangular channel, and cardboard (3553) are installed on displacement screw rod (3552) through the screw-thread fit mode, and cardboard (3553) are fork structure and both sides thickness from front to back taper.

7. The automatic chain performance detection apparatus as set forth in claim 5, wherein: the vertical clamping part (354) comprises a spacing plate (3541), a long groove is formed in the spacing plate (3541), a bidirectional screw rod (3542) is rotationally installed in the long groove, one end, far away from the hollow block (3525), of the bidirectional screw rod (3542) extends to the outer side of the spacing plate (3541), supporting push rods (3543) are symmetrically arranged on the bidirectional screw rod (3542), fixed ends of the supporting push rods (3543) are slidably arranged in the long groove, and arc-shaped grooves are formed in one sides, far away from the hollow block (3525), of the outer walls of the supporting push rods (3543).

8. The automatic chain performance detection device according to claim 1, wherein: the limiting guide assembly (4) comprises a wheel frame (41), the wheel frame (41) is installed on the bottom plate (1) in a front-back symmetrical mode, and a chain wheel (42) is installed on the outer wall of the middle of the wheel frame (41) in a rotating fit mode.