CN116930464B - Hot air non-woven fabric detection device - Google Patents

Abstract

The utility model discloses a hot air non-woven fabric detection device, which relates to the technical field of non-woven fabric detection and comprises a bottom plate, a detection frame, a driving frame, a total support, a driving assembly, a tiling assembly and a detection assembly, wherein the driving assembly is arranged to progressively convey non-woven fabrics into the detection assembly during non-woven fabric detection so as to realize uniform detection of the non-woven fabrics; by arranging the tiling assembly, the non-woven fabric can be uniformly stuck on the circular arc surface, so that the problem of inaccurate detection caused by movement of the non-woven fabric during friction detection is solved; through setting up detection component, can carry out frictional property to the non-woven fabrics and detect to non-woven fabrics tear resistance can detect for it is diversified to non-woven fabrics detection mode, promotes detection efficiency.

Description

Hot air non-woven fabric detection device

Technical Field

The utility model relates to the technical field of non-woven fabric detection, in particular to a hot air non-woven fabric detection device.

Background

The hot air non-woven fabric is a non-woven fabric material, and a hot air method is adopted in the preparation process; the non-woven fabric is a textile formed by taking fibers as raw materials and adopting processes of mixing, laminating, reinforcing and the like, and compared with the traditional textile, the non-woven fabric does not need spinning and weaving steps; the hot air non-woven fabric has many advantages such as high strength, light weight, good air permeability, good hygroscopicity, abrasion resistance and the like, and the production process of the hot air non-woven fabric is environment-friendly because water and chemical solvents are not needed in the preparation process.

The Chinese patent with publication number of CN218847998U discloses an online detection device for defects of hot air non-woven fabrics, which is used for online detection of the defects of the hot air non-woven fabrics and consists of a main body supporting frame, a non-woven fabric conveying auxiliary belt, an auxiliary belt power shaft, non-woven fabric leveling equipment, non-woven fabric placing equipment and laser scanning equipment; the main body supporting frame is internally provided with a non-woven fabric conveying auxiliary belt, the auxiliary belt is connected with the main body supporting frame through a rotating shaft, and an auxiliary belt power shaft is fixed at one end of the non-woven fabric conveying auxiliary belt through a bolt and extends outwards through the main body supporting frame; the non-woven fabric leveling equipment is arranged at the outer sides of the two ends of the main body supporting frame through bolts and is used for keeping the non-woven fabric flat; the non-woven fabric placing equipment is arranged on the surfaces of the two ends of the non-woven fabric conveying auxiliary belt through bolts, so that the non-woven fabric is ensured to be placed correctly; the laser scanning device is positioned at the outer side of the middle part of the main body supporting frame and is used for scanning the non-woven fabrics and detecting defects.

The defects of the prior art scheme are that: the device can only detect the flaw of non-woven fabrics, can't detect the wear resistance and the anti performance of tearing of non-woven fabrics, and its detection mode is single, and the testing result is comparatively unilateral, and the device during operation, non-woven fabrics can the off tracking, leads to the testing result inaccurate.

Disclosure of Invention

Aiming at the technical problems, the utility model adopts the following technical scheme: the hot air non-woven fabric detection device comprises a bottom plate, a detection frame, a driving frame, a main support, a driving assembly, a tiling assembly and a detection assembly, wherein the bottom plate and the driving frame are fixedly arranged on the main support, the driving assembly is rotationally arranged on the driving frame, the tiling assembly is fixedly arranged on the bottom plate, the detection frame is fixedly arranged on a tiling arc plate, and the detection assembly is slidably arranged in the detection frame; the driving assembly comprises a first driving cam rotationally arranged on the driving frame, the first driving cam is fixedly arranged on an output shaft of the driving motor, one side of the first driving cam is fixedly provided with a first driving large gear, one side of the first driving large gear is fixedly provided with a first driving bevel gear, the first driving large gear is meshed with a driving small gear rotationally arranged on the driving frame, the other side of the driving small gear is fixedly provided with a second driving cam and a third driving cam, the first driving bevel gear is rotationally provided with a driving rod, one end of the driving rod is rotationally provided with a second driving bevel gear, the other end of the driving rod is in sliding fit with the third driving cam, the driving rod is rotationally provided with a third driving bevel gear, and one side of the third driving bevel gear is fixedly provided with a fourth driving bevel gear; the second driving bevel gear is meshed with the first driving bevel gear and the third driving bevel gear; the second driving cam is in sliding fit with a driving rope which is arranged on the driving frame in a sliding mode.

Further, the first driving cam is in sliding fit with a driving connecting rod movably arranged on the driving frame, a reset spring is arranged between the driving connecting rod and the driving frame, the other end of the driving connecting rod is rotatably provided with a second driving connecting rod, the other end of the driving connecting rod is rotatably provided with a third driving connecting rod, the third driving connecting rod is rotatably arranged on a second driving roller gear, the third driving connecting rod is movably provided with a second driving pawl, the second driving pawl is movably matched with the second driving roller gear, the first driving pawl is movably arranged on the driving frame, the first driving pawl is movably matched with the second driving roller gear, the second driving roller gear is rotatably arranged on the driving frame, the second driving roller gear is meshed with the first driving roller gear rotatably arranged on the driving frame, the second driving roller gear is fixedly provided with the first driving roller, and the first driving roller gear is fixedly provided with the second driving roller.

Further, the tiling assembly comprises a tiling arc plate fixedly arranged on the bottom plate, a tiling gear II and a tiling gear I are rotationally arranged on the tiling arc plate, the tiling gear I is meshed with the tiling gear II, the tiling gear I is connected with the tiling rack through a tiling belt, the tiling rack is rotationally arranged on the detection frame, a tiling rotating rod I is fixedly arranged on the tiling gear II, a tiling rotating rod II is fixedly arranged on the tiling gear I, a tiling roller I is movably arranged in the tiling rotating rod I, and a tiling roller II is movably arranged in the tiling rotating rod II; a flat reset spring is arranged between the flat rotating rod II and the flat arc plate.

Further, the first tiling roller and the second tiling roller slide in the arc-shaped groove on the first tiling arc-shaped plate, and a driving rope is fixedly arranged at the other end of the second tiling rotating rod and is in sliding fit with the circular ring fixedly arranged on the first tiling arc-shaped plate.

Further, detect the subassembly including sliding the detection dead lever that sets up in detecting the frame, detect dead lever and tiling ratch meshing, detect fixed the being provided with on the dead lever and detect the stationary blade, detect fixed gear is fixed to be provided with in dead lever one end, detect the dead lever outside rotation and be provided with the detection ring gear, detect the fixed gear and a plurality of detection gear meshing that rotate the setting on detecting the ring gear.

Further, the detection rotating column is fixedly arranged on the detection gear, the detection fixing plate is fixedly arranged at the other end of the detection rotating column, the detection movable disc is rotatably arranged on the detection fixing plate, and the detection friction head is fixedly arranged on the detection movable disc.

Further, detect the ring gear and rotate and be provided with the detection movable rod, detect movable rod and detect stationary blade sliding fit, detect the movable rod and rotate and be provided with detection connecting rod one, detect connecting rod one other end rotation and set up on detection connecting rod two, detect connecting rod two slip setting and detect the ring gear, detect connecting rod two with rotate the detection plectrum sliding fit that sets up on detecting the ring gear, detect connecting rod two and detect and be provided with the detection spring between the impact head.

Further, the detection impact head is arranged on the detection connecting rod II in a sliding mode, the detection impact head is in sliding fit with the detection shifting plate, the detection toothed ring is meshed with the meshing gear, the detection bevel gear is fixedly arranged on the meshing gear, and the detection bevel gear is meshed with the driving bevel gear IV.

Compared with the prior art, the utility model has the beneficial effects that: (1) According to the utility model, the driving assembly is arranged, so that the non-woven fabric can be progressively conveyed into the detection assembly during non-woven fabric detection, and uniform detection of the non-woven fabric is realized; (2) By arranging the tiling assembly, the non-woven fabric can be uniformly stuck on the circular arc surface, so that the problem of inaccurate detection caused by movement of the non-woven fabric during friction detection is solved; (3) Through setting up detection component, can carry out frictional property to the non-woven fabrics and detect to non-woven fabrics tear resistance can detect for it is diversified to non-woven fabrics detection mode, promotes detection efficiency.

Drawings

FIG. 1 is a schematic view of a part of the structure of the present utility model.

Fig. 2 is a schematic diagram of the whole structure of the utility model in front view.

FIG. 3 is a schematic side view of the overall structure of the present utility model.

Fig. 4 is a schematic diagram of a partial structure of a driving assembly according to the present utility model.

Fig. 5 is a schematic diagram showing a partial structure of a driving assembly according to the present utility model.

Fig. 6 is a schematic diagram of a part of the driving assembly according to the third embodiment of the present utility model.

Fig. 7 is a schematic view of a part of a tiling assembly according to the present utility model.

Fig. 8 is a schematic diagram of a part of a tiling assembly according to the present utility model.

Fig. 9 is a schematic diagram of a portion of a tiling assembly according to the present utility model.

Fig. 10 is a schematic diagram showing a partial structure of a tile assembly according to the present utility model.

FIG. 11 is a schematic diagram of a part of a detecting component according to the present utility model.

FIG. 12 is a schematic diagram showing a partial structure of a detecting component according to the present utility model.

Fig. 13 is a schematic diagram of a partial structure of a detecting component according to the present utility model.

Fig. 14 is a schematic diagram showing a partial structure of a detecting component according to the present utility model.

Fig. 15 is a schematic diagram showing a partial structure of a detecting component according to the present utility model.

FIG. 16 is a schematic diagram showing a partial structure of a detecting unit according to the present utility model.

Reference numerals: 1-a drive assembly; 2-tiling the assembly; 3-a detection assembly; 4-a bottom plate; 5-a detection frame; 6-driving a frame; 7-total support; 101-driving a motor; 102-driving a cam I; 103-driving a large gear; 104-a drive pinion; 105-driving a cam II; 106-driving a cam III; 107-driving rod; 108-driving a bevel gear I; 109-driving a bevel gear II; 110-driving a bevel gear III; 111-driving bevel gears IV; 112-driving rope; 113-a drive link; 114-driving a second connecting rod; 115-drive link three; 116-drive roller gear one; 117-drive roller gear two; 118-drive pawl one; 119-driving roller one; 120-driving the second roller; 121-driving a pawl II; 201-tiling a toothed bar; 202-tiling the belt; 203-tiling a first gear; 204-tiling a second gear; 205-tiling a reset spring; 206-tiling the first rotating rod; 207-tiling the second rotating rod; 208-tiling the first roller; 209-tiling the second roller; 210-tiling an arc plate; 211-a circular ring; 301-detecting a fixed rod; 302-detecting a movable disk; 303-detecting the fixed plate; 304-detecting a rotating column; 305-detecting a gear; 306-detect the movable bar; 307-detecting the first connecting rod; 308-detecting a second connecting rod; 309-detecting a plectrum; 310-detecting a spring; 311-detecting an impact head; 312-detecting the stator; 313-detecting a fixed gear; 314-detecting the friction head; 315-detecting a toothed ring; 316-detecting a bevel gear; 317-meshing gears.

Description of the embodiments

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

As shown in fig. 1 to 16, a hot air non-woven fabric detection device comprises a bottom plate 4, a detection frame 5, a driving frame 6, a total support 7, a driving assembly 1, a tiling assembly 2 and a detection assembly 3, wherein the bottom plate 4 and the driving frame 6 are fixedly arranged on the total support 7, the driving assembly 1 is rotatably arranged on the driving frame 6, the tiling assembly 2 is fixedly arranged on the bottom plate 4, the detection frame 5 is fixedly arranged on a tiling arc plate 210, and the detection assembly 3 is slidably arranged in the detection frame 5; the driving assembly 1 comprises a first driving cam 102 rotationally arranged on the driving frame 6, the first driving cam 102 is fixedly arranged on an output shaft of the driving motor 101, a first driving large gear 103 is fixedly arranged on one side of the first driving cam 102, a first driving bevel gear 108 is fixedly arranged on one side of the first driving large gear 103, the first driving large gear 103 is meshed with a driving small gear 104 rotationally arranged on the driving frame 6, a second driving cam 105 and a third driving cam 106 are fixedly arranged on the other side of the driving small gear 104, a driving rod 107 is rotationally arranged on the first driving bevel gear 108, a second driving bevel gear 109 is rotationally arranged at one end of the driving rod 107, the other end of the driving rod 107 is in sliding fit with the third driving cam 106, a third driving bevel gear 110 is rotationally arranged on the driving rod 107, and a fourth driving bevel gear 111 is fixedly arranged on one side of the third driving bevel gear 110; the second drive bevel gear 109 is meshed with the first drive bevel gear 108 and the third drive bevel gear 110; the second driving cam 105 is slidably engaged with the driving rope 112 slidably provided on the driving frame 6.

The first driving cam 102 is in sliding fit with a driving connecting rod 113 movably arranged on the driving frame 6, a reset spring is arranged between the driving connecting rod 113 and the driving frame 6, the second end of the driving connecting rod 113 is rotatably provided with a second driving connecting rod 114, the other end of the driving connecting rod 114 is rotatably provided with a third driving connecting rod 115, the third driving connecting rod 115 is rotatably arranged on a second driving roller gear 117, a second driving pawl 121 is movably arranged on the third driving connecting rod 115, the second driving pawl 121 is movably matched with the second driving roller gear 117, a first driving pawl 118 is movably arranged on the driving frame 6, the first driving pawl 118 is movably matched with the second driving roller gear 117, the second driving roller gear 117 is rotatably arranged on the driving frame 6, the second driving roller gear 117 is meshed with a first driving roller gear 116 rotatably arranged on the driving frame 6, a first driving roller 119 is fixedly arranged on the second driving roller gear 117, and a second driving roller 120 is fixedly arranged on the first driving roller gear 116.

The flat assembly 2 comprises a flat arc plate 210 fixedly arranged on the bottom plate 4, a flat gear II 204 and a flat gear I203 are rotationally arranged on the flat arc plate 210, the flat gear I203 is meshed with the flat gear II 204, the flat gear I203 is connected with a flat toothed bar 201 through a flat belt 202, the flat toothed bar 201 is rotationally arranged on the detection frame 5, a flat rotating rod I206 is fixedly arranged on the flat gear II 204, a flat rotating rod II 207 is fixedly arranged on the flat gear I203, a flat roller I208 is movably arranged in the flat rotating rod I206, and a flat roller II 209 is movably arranged in the flat rotating rod II 207; a flat reset spring 205 is arranged between the flat rotating rod II 207 and the flat arc plate 210; the first laying roller 208 and the second laying roller 209 slide in the arc-shaped groove on the arc-shaped plate 210, the driving rope 112 is fixedly arranged at the other end of the second laying rotating rod 207, and the driving rope 112 is in sliding fit with the circular ring 211 fixedly arranged on the arc-shaped plate 210.

The detection assembly 3 comprises a detection fixing rod 301 which is arranged in the detection frame 5 in a sliding manner, the detection fixing rod 301 is meshed with the tiled toothed bar 201, a detection fixing piece 312 is fixedly arranged on the detection fixing rod 301, a detection fixing gear 313 is fixedly arranged at one end of the detection fixing rod 301, a detection toothed ring 315 is rotatably arranged on the outer side of the detection fixing rod 301, and the detection fixing gear 313 is meshed with a plurality of detection gears 305 which are rotatably arranged on the detection toothed ring 315. The detection gear 305 is fixedly provided with a detection rotation column 304, the other end of the detection rotation column 304 is fixedly provided with a detection fixing plate 303, the detection fixing plate 303 is rotatably provided with a detection movable disc 302, and the detection movable disc 302 is fixedly provided with a detection friction head 314.

The detection toothed ring 315 is rotatably provided with a detection movable rod 306, the detection movable rod 306 is in sliding fit with a detection fixing piece 312, the detection movable rod 306 is rotatably provided with a detection connecting rod I307, the other end of the detection connecting rod I307 is rotatably arranged on a detection connecting rod II 308, the detection connecting rod II 308 is slidably arranged on the detection toothed ring 315, the detection connecting rod II 308 is in sliding fit with a detection shifting piece 309 rotatably arranged on the detection toothed ring 315, and a detection spring 310 is arranged between the detection connecting rod II 308 and a detection impact head 311; the detection impact head 311 is slidably arranged on the second detection connecting rod 308, the detection impact head 311 is slidably matched with the detection pulling piece 309, the detection toothed ring 315 is meshed with the meshing gear 317, the meshing gear 317 is fixedly provided with the detection bevel gear 316, and the detection bevel gear 316 is meshed with the fourth drive bevel gear 111.

The utility model discloses a hot air non-woven fabric detection device, which has the following working principle: the non-woven fabric to be detected passes through the rollers at the right end on the main support 7, so that the non-woven fabric is arranged among the first tiling roller 208, the second tiling roller 209 and the arc surface at the bottom end of the detection support 5, and then passes through the space between the first driving roller 119 and the second driving roller 120.

The driving motor 101 is started, the driving motor 101 rotates to drive the first driving cam 102, the driving large gear 103 and the first driving bevel gear 108 to rotate, the driving large gear 103 rotates to drive the driving pinion 104, the driving pinion 104 rotates to drive the second driving cam 105 and the third driving cam 106, the third driving cam 106 rotates to drive the driving rod 107 to rotate, the driving rod 107 drives the second driving bevel gear 109, the second driving bevel gear 109 rotates to drive the third driving bevel gear 110 to rotate, and the third driving bevel gear 110 rotates to drive the fourth driving bevel gear 111 to rotate.

The first driving cam 102 rotates to drive the driving connecting rod 113 to swing, the driving connecting rod 113 swings to pull the second driving connecting rod 114, the second driving connecting rod 114 drives the third driving connecting rod 115, and then the second driving pawl 121 drives the second driving roller gear 117 to rotate, the second driving roller gear 117 rotates to drive the first driving roller gear 116 to rotate, the second driving roller gear 117 and the first driving roller gear 116 rotate to drive the first driving roller 119 and the second driving roller 120 to rotate, and the first driving roller 119 and the second driving roller 120 rotate to drive non-woven fabrics between the first driving roller 119 and the second driving roller 120 to move.

Simultaneously, the driving bevel gear IV 111 rotates to drive the detection bevel gear 316 to rotate, the detection bevel gear 316 rotates to drive the meshing gear 317 to rotate, the driving cam II 105 rotates to drive the driving rope 112 to slide, the driving rope 112 slides to drive the flat rotating rod II 207, the flat rotating rod II 207 drives the flat gear I203 to rotate, the flat gear I203 drives the flat gear II 204, the flat gear II 204 drives the flat rotating rod I206 to rotate, the flat gear I203 simultaneously drives the flat toothed bar 201 through the flat belt 202 during rotation, the flat toothed bar 201 rotates to drive the detection assembly 3 to move downwards, so that the detection friction head 314 and the detection impact head 311 are close to the non-woven fabrics, and simultaneously, the flat rotating rod II 207 and the flat rotating rod I206 rotate to drive the flat roller I208 and the flat roller II 209 to be arranged on the circular arc surfaces of the flat roller I208, the flat roller II 209 and the non-woven fabrics of the circular arc surfaces of the bottom end of the detection frame 5.

When the detection assembly 3 moves to drive the detection friction head 314 and the detection impact head 311 to be close to the non-woven fabric, the detection toothed ring 315 is meshed with the meshing gear 317, the meshing gear 317 rotates to drive the detection toothed ring 315 to rotate, the detection toothed ring 315 rotates to drive the detection gear 305 to be meshed with the detection fixed gear 313, the detection gear 305 rotates to drive the detection rotating column 304 and the detection fixed plate 303 to further drive the detection movable plate 302, and the detection movable plate 302 drives the detection friction head 314 to rub the non-woven fabric tightly attached to the arc surface of the detection frame 5, so that the friction resistance performance detection of the non-woven fabric is realized.

When the detection toothed ring 315 rotates, the detection movable rod 306 is driven to slide on the detection fixed rod 301, when the detection movable rod 306 and the detection fixed piece 312 touch, the detection movable rod 306 rotates to drive the detection first connecting rod 307, the detection first connecting rod 307 enables the detection second connecting rod 308 to move downwards, at the moment, the detection impact head 311 and the detection pulling piece 309 touch, when the detection second connecting rod 308 continues to move downwards, the detection spring 310 is compressed, the detection second connecting rod 308 touches the detection pulling piece 309, the detection pulling piece 309 releases the detection impact head 311, elastic potential energy of the detection spring 310 is released, and the detection impact head 311 is pushed out to hit the non-woven fabric, so that tear resistance of the non-woven fabric is measured.

Claims (1)

1. The utility model provides a hot-blast non-woven fabrics detection device, includes bottom plate (4), detects frame (5), drive frame (6), total support (7), its characterized in that: the device comprises a base plate (4), a driving frame (6), a driving assembly (1), a tiling assembly (2) and a detection assembly (3), wherein the base plate (4) and the driving frame (6) are fixedly arranged on a general support (7), the driving assembly (1) is rotationally arranged on the driving frame (6), the tiling assembly (2) is fixedly arranged on the base plate (4), the detection frame (5) is fixedly arranged on a tiling arc plate (210), and the detection assembly (3) is slidably arranged in the detection frame (5);

the driving assembly (1) comprises a first driving cam (102) which is rotatably arranged on a driving frame (6), the first driving cam (102) is fixedly arranged on an output shaft of a driving motor (101), a driving large gear (103) is fixedly arranged on one side of the first driving cam (102), a driving bevel gear I (108) is fixedly arranged on one side of the driving large gear (103), the driving large gear (103) is meshed with a driving small gear (104) which is rotatably arranged on the driving frame (6), a second driving cam (105) and a third driving cam (106) are fixedly arranged on the other side of the driving small gear (104), a driving rod (107) is rotatably arranged on the first driving bevel gear (108), a second driving bevel gear (109) is rotatably arranged at one end of the driving rod (107), the other end of the driving rod (107) is in sliding fit with the third driving cam (106), a third driving bevel gear (110) is rotatably arranged on the driving rod (107), and a fourth driving bevel gear (111) is fixedly arranged on one side of the driving bevel gear III (110); the second driving bevel gear (109) is meshed with the first driving bevel gear (108) and the third driving bevel gear (110); the second driving cam (105) is in sliding fit with a driving rope (112) which is arranged on the driving frame (6) in a sliding manner;

the driving cam I (102) is in sliding fit with a driving connecting rod (113) movably arranged on the driving frame (6), a reset spring is arranged between the driving connecting rod (113) and the driving frame (6), the driving connecting rod II (114) is rotatably arranged at the other end of the driving connecting rod (113), the driving connecting rod III (115) is rotatably arranged at the other end of the driving connecting rod II (114), the driving connecting rod III (115) is rotatably arranged on the driving roller gear II (117), the driving connecting rod III (115) is movably provided with a driving pawl II (121), the driving pawl II (121) is in movable fit with the driving roller gear II (117), the driving pawl I (118) is movably arranged on the driving frame (6), the driving roller gear II (117) is rotatably arranged on the driving frame (6), the driving roller gear II (117) is meshed with the driving roller gear I (116) rotatably arranged on the driving frame (6), and the driving roller I (119) is fixedly arranged on the driving roller gear II (116);

the flat assembly (2) comprises a flat arc plate (210) fixedly arranged on a bottom plate (4), a flat gear II (204) and a flat gear I (203) are rotatably arranged on the flat arc plate (210), the flat gear I (203) is meshed with the flat gear II (204), the flat gear I (203) is connected with a flat toothed bar (201) through a flat belt (202), the flat toothed bar (201) is rotatably arranged on a detection frame (5), a flat rotating rod I (206) is fixedly arranged on the flat gear II (204), a flat rotating rod II (207) is fixedly arranged on the flat gear I (203), a flat roller I (208) is movably arranged in the flat rotating rod I (206), and a flat roller II (209) is movably arranged in the flat rotating rod II (207); a flat reset spring (205) is arranged between the flat rotating rod II (207) and the flat arc plate (210);

the first tiling roller (208) and the second tiling roller (209) slide in an arc-shaped groove on the tiling arc-shaped plate (210), a driving rope (112) is fixedly arranged at the other end of the second tiling rotating rod (207), and the driving rope (112) is in sliding fit with a circular ring (211) fixedly arranged on the tiling arc-shaped plate (210);

the detection assembly (3) comprises a detection fixing rod (301) which is arranged in the detection frame (5) in a sliding manner, the detection fixing rod (301) is meshed with the flat toothed bar (201), a detection fixing piece (312) is fixedly arranged on the detection fixing rod (301), a detection fixing gear (313) is fixedly arranged at one end of the detection fixing rod (301), a detection toothed ring (315) is rotatably arranged on the outer side of the detection fixing rod (301), and the detection fixing gear (313) is meshed with a plurality of detection gears (305) which are rotatably arranged on the detection toothed ring (315);

detection rotation column (304) is fixedly arranged on detection gear (305), detection fixing plate (303) is fixedly arranged at the other end of detection rotation column (304), detection movable plate (302) is rotatably arranged on detection fixing plate (303), and detection movable plate (302) is fixedly arranged on detection movable plate (302)

The detection toothed ring (315) is rotatably provided with a detection movable rod (306), the detection movable rod (306) is in sliding fit with a detection fixed plate (312), the detection movable rod (306) is rotatably provided with a detection connecting rod I (307), the other end of the detection connecting rod I (307) is rotatably arranged on a detection connecting rod II (308), the detection connecting rod II (308) is slidably arranged on the detection toothed ring (315), the detection connecting rod II (308) is in sliding fit with a detection pulling piece (309) rotatably arranged on the detection toothed ring (315), and a detection spring (310) is arranged between the detection connecting rod II (308) and a detection impact head (311);

the detection impact head (311) is arranged on the detection connecting rod II (308) in a sliding mode, the detection impact head (311) is in sliding fit with the detection shifting piece (309), the detection toothed ring (315) is meshed with the meshing gear (317), the meshing gear (317) is fixedly provided with the detection bevel gear (316), and the detection bevel gear (316) is meshed with the driving bevel gear IV (111).