CN112921520A - Processing equipment of biological shoe-pad - Google Patents

Abstract

The invention discloses a processing device of a biological insole, which comprises a hanging bracket, a fixing frame and a workpiece, wherein an active mechanism is arranged at the bottom of the hanging bracket, passive mechanisms are arranged on two sides of the active mechanism, each passive mechanism comprises a first driving mechanism and a second driving mechanism, and the first driving mechanism and the second driving mechanism are respectively positioned on two sides of the active mechanism. According to the invention, the driving mechanism is arranged, so that the driving mechanism not only can drive the first driving mechanism and the second driving mechanism on two sides to drive, but also can drive the sewing mechanism on the moving mechanism to move up and down to complete sewing operation, and the moving mechanism moves up and down to drive the loofahs at the tops of the fifth gears to move upwards to enter a processing station through the linkage rod, and meanwhile, the bidirectional screw of the moving mechanism is matched with the fourth gear to drive the loofahs at the tops of the fifth gears to rotate in the process of rising, so that the loofahs are peeled and deseeded more uniformly, and the effect is better.

Description

Processing equipment of biological shoe-pad

Technical Field

The invention relates to the technical field of insole processing, in particular to processing equipment of a biological insole.

Background

The vegetable sponge, also known as the shell of luffa, is a net-like body obtained by ripening and natural air-drying of vegetable luffa, and is rich in elasticity. According to the records of Li Shizhen Ben Cao gang mu, the loofah sponge has the efficacies of dispelling wind and dredging collaterals, promoting blood circulation and reducing phlegm, removing heat and benefiting intestines, and cooling blood and removing toxicity, and has important health-care function; the loofah sponge insole has obvious curative effect on corn, heel pain and the like by utilizing natural important components contained in loofah sponge. The foot pad is comfortable and auxiliary to wear, soft, dirty-resistant and wear-resistant, is easy to eliminate fatigue, has not been paid due attention to foot health care for a long time, and is unknown, and the burden of feet is the heaviest in human body parts. In common words: the diseases are all born from feet, and the old is old from feet.

However, the existing multi-step process of processing the loofah into the insole is separately carried out, and the manual work is semi-automatic, so that the work efficiency is low and the cost is high.

Disclosure of Invention

In order to overcome the above defects of the prior art, the embodiments of the present invention provide a processing apparatus for biological insoles, and the problems to be solved by the present invention are: the existing multi-step process for processing the loofah into the insole is separately carried out, and the insole is manual and semi-automatic, low in working efficiency and high in cost.

In order to achieve the purpose, the invention provides the following technical scheme: a processing device for biological insoles comprises a hanger, a fixing frame and a workpiece, wherein an active mechanism is installed at the bottom of the hanger, passive mechanisms are installed on two sides of the active mechanism, each passive mechanism comprises a first driving mechanism and a second driving mechanism, the first driving mechanism and the second driving mechanism are respectively located on two sides of the active mechanism, the first driving mechanism comprises a first mounting shaft, the top end of the first mounting shaft is installed at the bottom of the hanger through a bearing, the bottom end of the first mounting shaft is fixedly connected with a first toothed shaft, the bottom end of the first toothed shaft is fixedly provided with a first rolling roller, the top end of the first mounting shaft is fixedly provided with a first gear, the second driving mechanism comprises a second mounting shaft, the top end of the second mounting shaft is installed at the bottom of the hanger through a bearing, the bottom end of the second mounting shaft is fixedly connected with a second toothed shaft, and the bottom end of the second toothed shaft is fixedly, the second rolling roller is positioned on one side of the first rolling roller, the bottom end of one side of the first gear shaft is meshed with a first extruding mechanism, the bottom end of one side, away from the first extruding mechanism, of the second gear shaft is meshed with a second extruding mechanism, one side of the driving mechanism is slidably provided with a moving mechanism, and the moving mechanism is positioned on one side between the first gear shaft and the second gear shaft;

the driving mechanism comprises a motor, the motor is fixed at the bottom of the hanger, a bidirectional screw is mounted at the output end of the motor, a third gear is mounted at the top end of the bidirectional screw and is respectively meshed and connected with a first gear and a second gear, a telescopic cylinder is fixedly connected to the bottom end of the bidirectional screw, a telescopic rod is inserted into the bottom of an inner cavity of the telescopic cylinder in a sliding mode, and a fourth gear is fixedly connected to the bottom end of the telescopic rod;

the moving mechanism comprises a sliding seat, one side of the sliding seat is fixedly connected with a sliding sleeve, a bidirectional screw penetrates through the sliding sleeve, the bottom end of one side of the sliding seat is provided with a sewing mechanism, one side of the top of the sliding seat is provided with a cutting mechanism, the cutting mechanism comprises a mounting frame, the mounting frame is fixed on one side of the top of the sliding seat, one side of the mounting frame is provided with a first cutting roller, one side of the first cutting roller is provided with a second cutting roller, the sewing mechanism is positioned at the bottom of the first cutting roller, blades are respectively arranged on the surfaces of the first cutting roller and the second cutting roller, two ends of the first cutting roller are fixedly connected with a fifth installation shaft, the fifth installation shaft is arranged near one end of the second tooth shaft and is provided with a third inclined gear, the third inclined gear is meshed with the second tooth shaft, two ends of the second cutting roller are fixedly connected with a sixth installation, the mechanism comprises a first mounting shaft, a second mounting shaft, a first gear shaft, a second gear shaft, a linkage rod, a fixing plate, a telescopic rod, a first grinding roller, a second grinding roller, a third gear, a fourth gear, a fork, a third gear, a fourth gear, a fifth gear, a third gear, a fourth gear, a fifth gear, a third gear, a fourth gear, a fifth gear, a fourth gear;

an extrusion mechanism includes the squeeze roll No. one, No. three installation axles are pegged graft at a squeeze roll both ends, No. three installation axles are close to a pinion one end and install a bevel gear, and a bevel gear is connected with a pinion meshing No. one, No. two extrusion mechanisms include No. two squeeze rolls, and No. two squeeze rolls are located squeeze roll one side, No. two squeeze roll both ends are pegged graft and are had No. four installation axles, No. four installation axles are close to No. two pinion one ends and install No. two bevel gears, and No. two bevel gears are connected with No. two pinion meshing.

Preferably, the shaking mechanism comprises a shaking box, a first crown gear is movably mounted at the top of an inner cavity of the shaking box, the bottom end of a penetrating shaft is fixedly connected with the first crown gear, a second crown gear is meshed and connected with the bottom of the first crown gear, and the second crown gear is fixed in the inner cavity of the shaking box.

Preferably, the mount is located actuating mechanism and No. two actuating mechanism both sides, installation axle, No. two installation axles, No. three installation axles and No. four installation axle both ends are all fixed in mount one side through the bearing.

Preferably, one side of the fixing frame is respectively provided with a first clamping mechanism and a second clamping mechanism, the first clamping mechanism and the second clamping mechanism are respectively positioned at the bottoms of the two ends of the second cutting roller and the first cutting roller, the first clamping mechanism and the second clamping mechanism both comprise connecting frames, the connecting frames are fixed at one side of the fixing frame, the first clamping mechanism and the second clamping mechanism are identical in structure, one end of each connecting frame is fixedly connected with a first fixing rod, one end of each first fixing rod is fixedly connected with a sleeve, a spring is arranged in the inner cavity of the sleeve, a second fixing rod is movably inserted at one end of the inner cavity of the sleeve, one end of each second fixing rod is fixedly connected with the spring, one side of the first fixing rod is provided with a first clamping roller, one side of the second fixing rod is provided with a second clamping roller, and the second clamping roller is positioned at one side of the first, a centre gripping gyro wheel and No. two centre gripping gyro wheels are located No. two cutting rolls and a cutting roll both ends bottom respectively, and a centre gripping gyro wheel and No. two centre gripping gyro wheels are located the work piece both ends, a centre gripping gyro wheel and No. two centre gripping gyro wheels are located an squeeze roll and No. two squeeze roll tops.

Preferably, the surface of the first rolling roller and the surface of the second rolling roller are both fixedly provided with a convex block.

Preferably, the two sides of the inner cavity of the telescopic cylinder are both provided with limiting sliding grooves, the two sides of the top end of the telescopic rod are both fixedly connected with limiting sliding blocks, and the limiting sliding blocks are slidably located in the inner cavities of the limiting sliding grooves.

Preferably, the bottom of the mounting frame is fixedly provided with a lining plate, the lining plate is positioned at one end of the sewing mechanism, and the lining plate is positioned at the bottom of the second cutting roller.

Preferably, the equal fixedly connected with leading truck in slide top both sides, the lantern ring is connected with to leading truck one end fixedly, and the lantern ring is run through in the activity respectively to installation axle and No. two installations axle.

The invention has the technical effects and advantages that:

1. according to the invention, the driving mechanism is arranged, so that the driving mechanism not only can drive the first driving mechanism and the second driving mechanism on two sides to drive, but also can drive the sewing mechanism on the moving mechanism to move up and down to complete sewing operation, and the moving mechanism moves up and down to drive the loofahs at the tops of the fifth gears to move upwards to enter a processing station through the linkage rod, and meanwhile, the bidirectional screw of the moving mechanism is matched with the fourth gear to drive the loofahs at the tops of the fifth gears to rotate in the ascending process, so that the loofahs are peeled and deseeded more uniformly, and the effect is better;

2. the first driving mechanism and the second driving mechanism are arranged to drive the first rolling roller and the second rolling roller at the bottom to rotate at high speed to peel and remove seeds of the passed towel gourd, and the first driving mechanism and the second driving mechanism are matched with each other to drive the first extruding mechanism and the second extruding mechanism to complete the function of extruding the towel gourd into slices; the cutting mechanism which can conveniently drive the up-and-down movement is driven; the towel gourd seeds and the towel gourd peels can fall off more smoothly due to the arrangement of the shaking mechanism; whole equipment structure is simple, and degree of automation is high, and is multiple functional, solves the transmission multiple operation and separately carries out inefficiency, and a driving source is shared to a plurality of mechanisms moreover, and is with low costs, and the power consumption is low, makes things convenient for later stage maintenance and repair.

Drawings

FIG. 1 is a schematic view of the overall structure of the present invention;

FIG. 2 is a schematic side view of the present invention;

FIG. 3 is a schematic top view of the present invention;

FIG. 4 is a schematic perspective view of the moving mechanism of the present invention;

FIG. 5 is a schematic top view of the moving mechanism of the present invention;

FIG. 6 is a schematic top view of the cutting mechanism of the present invention;

FIG. 7 is a schematic top view of the first rolling mechanism and the second rolling mechanism of the present invention;

FIG. 8 is a schematic top view of the first and second clamping mechanisms of the present invention;

FIG. 9 is a schematic structural diagram of a shaking mechanism according to the present invention;

FIG. 10 is a schematic diagram of a structure of a jitter box of the present invention;

fig. 11 is a schematic structural view of the telescopic cylinder of the present invention.

The reference signs are: 1. a hanger; 2. a passive mechanism; 21. a first driving mechanism; 211. a first pinion; 212. mounting a shaft I; 213. a first gear; 214. a first rolling roller; 2141. a protruding block; 22. a second driving mechanism; 221. a second pinion; 222. mounting a shaft II; 223. a second gear; 224. a second rolling roller; 3. a first extrusion mechanism; 31. a first bevel gear; 32. a squeeze roll; 33. mounting a shaft III; 4. a second extrusion mechanism; 41. a second bevel gear; 42. a second squeeze roll; 43. mounting a shaft in No. four; 5. an active mechanism; 51. a bidirectional screw; 52. a third gear; 53. a telescopic cylinder; 531. a limiting chute; 54. a telescopic rod; 541. a limiting slide block; 55. a fourth gear; 56. a fifth gear; 561. penetrating the shaft; 562. a fork; 57. a shaking mechanism; 571. a shaking box; 5711. a first crown gear; 5712. a second crown gear; 58. a motor; 6. a moving mechanism; 61. a slide base; 62. a sewing mechanism; 63. a guide frame; 64. a collar; 65. a cutting mechanism; 651. a mounting frame; 652. a first cutting roller; 653. a second cutting roller; 654. mounting a shaft in fifth; 655. mounting a shaft No. six; 656. a liner plate; 657. a blade; 658. a third bevel gear; 659. a fourth bevel gear; 66. a linkage rod; 67. a fixing plate; 68. a sliding sleeve; 7. a first clamping mechanism; 71. a first fixing rod; 72. a sleeve; 73. a second fixing rod; 74. a spring; 75. a first clamping roller; 76. a second clamping roller; 77. a connecting frame; 8. a second clamping mechanism; 9. a fixed mount; 10. and (5) a workpiece.

Detailed Description

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

The processing equipment of the biological insole comprises a hanging bracket 1, a fixing frame 9 and a workpiece 10, wherein the bottom of the hanging bracket 1 is provided with an active mechanism 5, two sides of the active mechanism 5 are provided with passive mechanisms 2, the passive mechanisms 2 comprise a first driving mechanism 21 and a second driving mechanism 22, the first driving mechanism 21 and the second driving mechanism 22 are respectively positioned at two sides of the active mechanism 5, the first driving mechanism 21 comprises a first mounting shaft 212, the top end of the first mounting shaft 212 is arranged at the bottom of the hanging bracket 1 through a bearing, the bottom end of the first mounting shaft 212 is fixedly connected with a first toothed shaft 211, the bottom of the first toothed shaft 211 is fixedly provided with a first rolling roller 214, the top end of the first mounting shaft 212 is fixedly provided with a first gear 213, the second driving mechanism 22 comprises a second mounting shaft 222, the top end of the second mounting shaft 222 is arranged at the bottom of the hanging bracket 1 through a bearing, the bottom end of the second mounting shaft 222, no. two fluted shafts 221 bottom fixed mounting have rolling roller 224 No. two, and rolling roller 224 No. two is located rolling roller 214 one side No. one, No. one extrusion mechanism 3 is installed in meshing of a fluted shaft 211 one side bottom, No. two fluted shafts 221 keep away from extrusion mechanism 3 one side bottom meshing and install No. two extrusion mechanism 4, 5 one side slidable mounting of driving mechanism has moving mechanism 6, and moving mechanism 6 is located one side between a fluted shaft 211 and No. two fluted shafts 221.

Referring to the attached drawings 1-11 of the specification, the driving mechanism 5 of the processing equipment of the biological insole of the embodiment comprises a motor 58, the motor 58 is fixed at the bottom of the hanger 1, a bidirectional screw 51 is installed at the output end of the motor 58, a third gear 52 is installed at the top end of the bidirectional screw 51, the third gear 52 is respectively meshed with a first gear 213 and a second gear 223, a telescopic cylinder 53 is fixedly connected at the bottom end of the bidirectional screw 51, a telescopic rod 54 is inserted at the bottom of the inner cavity of the telescopic cylinder 53 in a sliding manner, and a fourth gear 55 is fixedly connected at the bottom end of the telescopic rod 54;

the moving mechanism 6 comprises a sliding seat 61, a sliding sleeve 68 is fixedly connected to one side of the sliding seat 61, a bidirectional screw 51 penetrates through the sliding sleeve 68, a sewing mechanism 62 is installed at the bottom end of one side of the sliding seat 61, a cutting mechanism 65 is installed at one side of the top of the sliding seat 61, the cutting mechanism 65 comprises a mounting frame 651, the mounting frame 651 is fixed to one side of the top of the sliding seat 61, a first cutting roller 652 is installed at one side of the mounting frame 651, a second cutting roller 653 is installed at one side of the first cutting roller 652, the sewing mechanism 62 is located at the bottom of the first cutting roller 652, blades 657 are installed on the surfaces of the first cutting roller 652 and the second cutting roller 653, a fifth mounting shaft 654 is fixedly connected to two ends of the first cutting roller 652, a third bevel gear 658 is installed at one end of the fifth mounting shaft 654 close to the second gear shaft 221, a sixth mounting shaft 655 is fixedly connected to two ends of the second cutting roller 653, and both the fifth mounting shaft 654, a fourth bevel gear 659 is mounted at one end, close to the first toothed shaft 211, of the sixth mounting shaft 655, the fourth bevel gear 659 is meshed with the first toothed shaft 211, a linkage rod 66 is fixedly connected to one side of a sliding sleeve 68, the linkage rod 66 is located at one side of a bidirectional screw 51, a fixing plate 67 is fixedly connected to one side of the bottom of the linkage rod 66, the bottom end of a telescopic rod 54 is fixed above the fixing plate 67, a shaking mechanism 57 is mounted at one end of the fixing plate 67, a fifth gear 56 is mounted at the top of the shaking mechanism 57, the fifth gear 56 is meshed with a fourth gear 55, a through shaft 561 is movably inserted into an inner cavity of the fifth gear 56, a fork 562 is fixedly connected to the top of the through shaft 561, the fork 562 is located at the bottom between the first rolling roller 214 and the second rolling roller 224, and the shaking mechanism 57 is;

no. 3 extrusion device includes squeeze roll 32, No. three installation axles 33 have been pegged graft at squeeze roll 32 both ends, No. three installation axles 33 are close to a pinion 211 one end and install a bevel gear 31, and a bevel gear 31 is connected with a pinion 211 meshing, No. two extrusion device 4 includes No. two squeeze rolls 42, and No. two squeeze rolls 42 are located a squeeze roll 32 one side, No. two squeeze rolls 42 both ends are pegged graft and are had No. four installation axles 43, No. two bevel gears 41 are installed near No. two pinion 221 one end to No. four installation axles 43, and No. two bevel gears 41 are connected with No. two pinion 221 meshing.

As shown in fig. 1 to 11, the implementation scenario specifically includes: in practical use, (I) the dried towel gourd with two cut ends is inserted into the fork 562 above the fifth gear 56, then the power supply is turned on, the motor 58 starts to work, so that the motor 58 drives the bidirectional screw 51 at the bottom to rotate, when the bidirectional screw 51 rotates, the third gear 52 drives the first gear 213 and the second gear 223 at two sides to rotate, so that the first gear 213 and the second gear 223 can drive the first driving mechanism 21 and the second driving mechanism 22 to rotate, meanwhile, as the bidirectional screw 51 rotates, the bidirectional screw 51 can drive the sliding seat 61 at one side to move upwards, and when the sliding seat 61 moves upwards, the linkage rod 66 at one side of the sliding sleeve 68 is driven to move upwards, so that the fixing plate 67 at one side of the bottom of the linkage rod 66 can drive the telescopic rod 54 and the shaking mechanism 57 and the fifth gear 56 to move upwards, when the telescopic rod 54 moves downwards, the telescopic rod 54 slides into the inner cavity of the telescopic cylinder 53, the four-gear 55 at the bottom end of the telescopic rod 54 and the five-gear 56 meshed at one side move upwards simultaneously, the bidirectional screw 51 rotates and drives the telescopic cylinder 53 to rotate, because the two sides of the inner cavity of the telescopic cylinder 53 are provided with the limiting chutes 531, and the two sides of the top end of the telescopic rod 54 are provided with the limiting sliders 541, the telescopic cylinder 53 rotates and drives the telescopic rod 54 to rotate, the telescopic rod 54 drives the four-gear 55 fixedly installed at the bottom to rotate, so that the four-gear 55 drives the five-gear 56 meshed at one side to rotate, the five-gear 56 rotates simultaneously in the process of rising, when the five-gear 56 rises, the dried loofah fixed on the top fork 562 is sent between the first rolling roller 214 and the second rolling roller 224, when the first rolling roller 214 and the second rolling roller 224 rotate, the dried loofah is rolled and collided through the convex blocks 2141, therefore, the relatively fragile skin on the surface of the dried luffa is squeezed, crushed and dropped, and the luffa seeds in the sun-dried luffa fall from the bottom incision in the rolling process, the penetrating shaft 561 in the inner cavity of the fifth gear 56 can drive the first crown gear 5711 at the bottom to rotate when rotating, the penetrating shaft 561 can move up and down in the inner cavity of the fifth gear 56 but cannot rotate, so that the fifth gear 56 can drive the penetrating shaft 561 and the luffa on the top fork 562 to rotate, and the first crown gear 5711 and the second crown gear 5712 at the bottom generate up-and-down bumping vibration when rotating, so that the luffa seeds are more easily dropped from the inner part of the luffa (the second crown gear 5712 is in a fixed state and does not rotate), (second) the luffa are peeled and deseeded by the first rolling roller 214 and the second rolling roller 224 and then enter between the first pressing roller 32 and the second pressing roller 42 at the top, and the first pressing roller 32 and the second pressing roller 42 are arranged between the first bevel gear 31, The second bevel gear 41 rolls under the matching of the first gear shaft 211 and the second gear shaft 221, so that the first extrusion roller 32 and the second extrusion roller 42 extrude the peeled and deseeded luffa, meanwhile, the towel gourd is conveyed upwards, extruded into a sheet shape and then enters between a first clamping mechanism 7 and a second clamping mechanism 8 at the top, therefore, the first clamping roller 75 and the second clamping roller 76 of the first clamping mechanism 7 and the second clamping mechanism 8 at two sides clamp the two side edges of the workpiece 10 (flattened towel gourd) which is pressed into the slices (in the state shown in figures 3 and 8), the first clamping roller 75 and the second clamping roller 76 are very thin, when the two clamping devices clamp the workpiece 10 (the squashed towel gourd), the workpiece is only clamped at the edge parts of the two sides, so that the interference of the sewing mechanism 62 with the first clamping roller 75 and the second clamping roller 76 when the movement of the moving mechanism 6 is influenced is avoided; (III), after the workpiece 10 is pressed flat and pushed to the position between the first clamping roller 75 and the second clamping roller 76 for clamping, the one side sliding seat 61 enables the one side sewing mechanism 62 to move for sewing the workpiece 10 clamped at one end when sliding upwards, the lining plate 656 at one side of the workpiece 10 supports the workpiece 10 during sewing, the lining plate 565 and the sewing mechanism 62 move simultaneously along with the sliding seat 61, and the subsequent towel gourd existing at the bottom part continues to be processed after sewing, so that the workpiece 10 at the bottom part pushes the workpiece 10 after sewing to enter between the first cutting roller 652 and the second cutting roller 653, and the edge of the workpiece 10 after sewing is cut when the first cutting roller 652 and the second cutting roller 653 rotate through the third bevel gear 658 and the fourth bevel gear 659 at one end respectively engaged with the second gear shaft 221 and the first gear shaft 211, the insole is cut into the shape of an insole, and the cut and processed insole is pushed out of a first cutting roller 652 and a second cutting roller 653 and then taken away by a manipulator; after the loofah on the fork 562 is rolled between the first rolling roller 214 and the second rolling roller 224, and the fork 562 is empty and retracted, the next group of loofah is inserted into the fork 562 for processing, and the operation is circulated in sequence; by arranging the driving mechanism 5, the driving mechanism can drive the first driving mechanism 21 and the second driving mechanism 22 on the two sides to drive the first driving mechanism and the second driving mechanism 22 on the two sides to drive the sewing mechanism 62 on the moving mechanism 6 to move up and down to complete sewing operation, and the moving mechanism 6 moves up and down to drive the loofahs on the top of the fifth gear 56 to move upwards to enter a processing station through the linkage rod 66, and meanwhile, the bidirectional screw 51 of the moving mechanism 6 is matched with the fourth gear 55 to drive the loofahs on the top of the fifth gear 56 to rotate in the ascending process, so that the loofahs are peeled and deseeded more uniformly, and the effect is better; the first driving mechanism 21 and the second driving mechanism 22 are arranged to drive the first rolling roller 214 and the second rolling roller 224 at the bottom to rotate at a high speed to peel and remove seeds of the passed towel gourd, and the first driving mechanism 21 and the second driving mechanism 22 are matched with each other to drive the first extruding mechanism 3 and the second extruding mechanism 4 to complete the function of extruding the towel gourd into slices; and the cutting mechanism 65 which conveniently drives the up-and-down movement is driven; the towel gourd seeds and the towel gourd peels can fall off more smoothly due to the arrangement of the shaking mechanism 57; whole equipment structure is simple, and degree of automation is high, and is multiple functional, solves the transmission multiple operation and separately carries out inefficiency, and a driving source is shared to a plurality of mechanisms moreover, and is with low costs, and the power consumption is low, makes things convenient for later stage maintenance and repair.

The shaking mechanism 57 comprises a shaking box 571, a first crown gear 5711 is movably mounted at the top of the inner cavity of the shaking box 571, the bottom end of the penetrating shaft 561 is fixedly connected with the first crown gear 5711, a second crown gear 5712 is meshed and connected at the bottom of the first crown gear 5711, and the second crown gear 5712 is fixed in the inner cavity of the shaking box 571.

The fixing frame 9 is located on two sides of the first driving mechanism 21 and the second driving mechanism 22, and two ends of the first mounting shaft 212, the second mounting shaft 222, the third mounting shaft 33 and the fourth mounting shaft 43 are fixed on one side of the fixing frame 9 through bearings.

One side of the fixed frame 9 is respectively provided with a first clamping mechanism 7 and a second clamping mechanism 8, the first clamping mechanism 7 and the second clamping mechanism 8 are respectively positioned at the bottoms of two ends of a second cutting roller 653 and a first cutting roller 652, the first clamping mechanism 7 and the second clamping mechanism 8 both comprise a connecting frame 77, the connecting frame 77 is fixed at one side of the fixed frame 9, the first clamping mechanism 7 and the second clamping mechanism 8 are identical in structure, one end of the connecting frame 77 is fixedly connected with a first fixing rod 71, one end of the first fixing rod 71 is fixedly connected with a sleeve 72, a spring 74 is arranged in an inner cavity of the sleeve 72, one end of the inner cavity of the sleeve 72 is movably inserted with a second fixing rod 73, one end of the second fixing rod 73 is fixedly connected with the spring 74, one side of the first fixing rod 71 is provided with a first clamping roller 75, one side of the second fixing rod 73 is provided with a second clamping roller 76, and the second clamping, the first clamping roller 75 and the second clamping roller 76 are respectively positioned at the bottoms of the two ends of the second cutting roller 653 and the first cutting roller 652, the first clamping roller 75 and the second clamping roller 76 are positioned at the two ends of the workpiece 10, and the first clamping roller 75 and the second clamping roller 76 are positioned at the tops of the first extrusion roller 32 and the second extrusion roller 42.

As shown in fig. 3 and 8, a spring 74 is arranged between the first fixing rod 71 and the second fixing rod 73 of the first clamping mechanism 7 and the second clamping mechanism 8, so that the distance between the first clamping roller 75 on one side of the first fixing rod 71 and the second clamping roller 76 on one side of the second fixing rod 73 can be elastically extended and contracted, and workpieces 10 with different thicknesses can be conveniently clamped by the different clamping rollers 75 and 76.

The protruding blocks 2141 are fixedly mounted on the surfaces of the first rolling roller 214 and the second rolling roller 224.

Spacing spout 531 has all been seted up to telescopic cylinder 53 inner chamber both sides, the equal fixedly connected with spacing slider 541 in telescopic rod 54 top both sides, and spacing slider 541 slides and is located spacing spout 531 inner chamber.

The bottom of the mounting frame 651 is fixedly provided with a lining plate 656, the lining plate 656 is positioned at one end of the sewing mechanism 62, and the lining plate 656 is positioned at the bottom of the second cutting roller 653.

The equal fixedly connected with leading truck 63 in slide 61 top both sides, leading truck 63 one end fixedly connected with lantern ring 64, and No. one installation axle 212 and No. two installation axles 222 activity respectively run through lantern ring 64.

As shown in fig. 4, the guide frame 63 is movably fixed outside the first mounting shaft 212 and the second mounting shaft 222 by the collar 64, so that the slide carriage 61 is more stable when moving.

In summary, the following steps: the dried loofah with two cut ends is inserted into the fork 562 above the fifth gear 56, then the power supply is turned on, so that the motor 58 starts to work, the motor 58 drives the bidirectional screw 51 at the bottom to rotate, the bidirectional screw 51 drives the first driving mechanism 21 and the second driving mechanism 22 to rotate under the cooperation of the third gear 52, the first gear 213 and the second gear 223, meanwhile, as the bidirectional screw 51 rotates, the bidirectional screw 51 can drive the sliding seat 61 at one side to move upwards, the sliding seat 61 drives the linkage rod 66 at one side of the sliding sleeve 68 to move upwards simultaneously when moving upwards, so that the linkage rod 66 drives the loofah on the fork 562 to move upwards, the bidirectional screw 51 drives the fifth gear 56 to rotate under the cooperation of the bidirectional screw 51, the dried loofah fixed on the top fork 562 is conveyed between the first rolling roller 214 and the second rolling roller 224 which rotate at the top when the fifth gear 56 rises, when the first rolling roller 214 and the second rolling roller 224 rotate, the sun-dried very fragile loofah is rolled and collided through the protruding block 2141, so that fragile skin on the surface of the sun-dried loofah is extruded and crushed to fall off, the loofah seeds inside in the rolling process fall off from a bottom cut, the loofah without skin and seeds enters the space between the first rolling roller 32 and the second rolling roller 42 to be extruded into a sheet shape, the loofah enters the space between the first clamping mechanism 7 and the second clamping mechanism 8 after being extruded, then the loofah is sewn through the sewing mechanism 62 on one side of the sliding seat 61, the loofah enters the space between the first cutting roller 652 and the second cutting roller 653 for cutting after being sewn, the mechanical arm is taken away after cutting, when the loofah on the fork 562 is rolled between the first rolling roller 214 and the second rolling roller 224, and the fork 562 is empty and retracted, the next group of loofah is inserted into the fork 562 for processing, and (5) circulating operation in turn.

And finally: the above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the invention, and any modifications, equivalents, improvements and the like that are within the spirit and principle of the present invention are intended to be included in the scope of the present invention.

Claims (8)

1. The utility model provides a processing equipment of biological shoe-pad, includes gallows (1), mount (9) and work piece (10), its characterized in that: the automatic transmission mechanism comprises a hanger (1), wherein an active mechanism (5) is installed at the bottom of the hanger (1), passive mechanisms (2) are installed on two sides of the active mechanism (5), each passive mechanism (2) comprises a first driving mechanism (21) and a second driving mechanism (22), the first driving mechanism (21) and the second driving mechanism (22) are respectively located on two sides of the active mechanism (5), each driving mechanism (21) comprises a first mounting shaft (212), the top end of the first mounting shaft (212) is installed at the bottom of the hanger (1) through a bearing, a first gear shaft (211) is fixedly connected to the bottom end of the first mounting shaft (212), a first rolling roller (214) is fixedly installed at the bottom of the first gear shaft (211), a first gear (213) is fixedly installed at the top end of the first mounting shaft (212), the second driving mechanism (22) comprises a second mounting shaft (222), and the top end of the second mounting shaft (222) is installed at the bottom of the hanger (1) through, the bottom end of the second mounting shaft (222) is fixedly connected with a second gear shaft (221), the bottom end of the second gear shaft (221) is fixedly provided with a second rolling roller (224), the second rolling roller (224) is positioned on one side of the first rolling roller (214), the bottom end of one side of the first gear shaft (211) is meshed with a first extruding mechanism (3), the bottom end of one side, far away from the first extruding mechanism (3), of the second gear shaft (221) is meshed with a second extruding mechanism (4), one side of the driving mechanism (5) is slidably provided with a moving mechanism (6), and the moving mechanism (6) is positioned on one side between the first gear shaft (211) and the second gear shaft (221);

the driving mechanism (5) comprises a motor (58), the motor (58) is fixed to the bottom of the hanger (1), a bidirectional screw (51) is installed at the output end of the motor (58), a third gear (52) is installed at the top end of the bidirectional screw (51), the third gear (52) is respectively meshed with the first gear (213) and the second gear (223) in a meshed mode, a telescopic cylinder (53) is fixedly connected to the bottom end of the bidirectional screw (51), a telescopic rod (54) is inserted into the bottom of an inner cavity of the telescopic cylinder (53) in a sliding mode, and a fourth gear (55) is fixedly connected to the bottom end of the telescopic rod (54);

moving mechanism (6) includes slide (61), slide (61) one side fixedly connected with sliding sleeve (68), and two-way screw rod (51) run through sliding sleeve (68), sewing mechanism (62) are installed to slide (61) one side bottom, slide (61) top one side is installed and is cut mechanism (65), it includes mounting bracket (651) to cut mechanism (65), and mounting bracket (651) are fixed in slide (61) top one side, No. one cutting roller (652) is installed to mounting bracket (651) one side, No. two cutting roller (653) are installed to No. one cutting roller (652) one side, and sewing mechanism (62) are located No. one cutting roller (652) bottom, blade (657) are all installed on No. one cutting roller (652) and No. two cutting roller (653) surfaces, No. five installation axle (654) of No. one cutting roller (652) both ends fixedly connected with, the No. five installation shaft (654) is close to one end of the No. two gear shaft (221) and is provided with a No. three bevel gear (658), the No. three bevel gear (658) is meshed with the No. two gear shaft (221) and is connected with the No. two cutting roller (653) through two installation shafts (655), the No. five installation shaft (654) and the No. six installation shaft (655) both penetrate through the installation frame (651), the No. six installation shaft (655) is close to one end of the No. one gear shaft (211) and is provided with a No. four bevel gear (659), the No. four bevel gear (659) is meshed with the No. one gear shaft (211), one side of the sliding sleeve (68) is fixedly connected with the linkage rod (66), the linkage rod (66) is positioned on one side of the two-way screw (51), one side of the bottom of the linkage rod (66) is fixedly connected with the fixing plate (67), the bottom end of the telescopic rod (54) is fixed above the fixing plate (, the top of the shaking mechanism (57) is provided with a fifth gear (56), the fifth gear (56) is meshed with a fourth gear (55), a through shaft (561) is movably inserted into an inner cavity of the fifth gear (56), the top of the through shaft (561) is fixedly connected with a fork (562), the fork (562) is positioned at the bottom between the first rolling roller (214) and the second rolling roller (224), and the bottom of the through shaft (561) is provided with the shaking mechanism (57);

no. one extrusion mechanism (3) is including a squeeze roll (32), No. three installation axles (33) are pegged graft at squeeze roll (32) both ends, No. three installation axles (33) are close to a pinion (211) one end and install bevel gear (31) No. one, and bevel gear (31) and pinion (211) meshing connection No. one, No. two extrusion mechanism (4) are including No. two squeeze rolls (42), and No. two squeeze rolls (42) are located a squeeze roll (32) one side, No. two squeeze rolls (42) both ends are pegged graft and are had No. four installation axles (43), No. four installation axles (43) are close to No. two pinion (221) one end and install No. two bevel gear (41), and No. two bevel gear (41) and No. two pinion (221) meshing connection.

2. The processing equipment of a biological insole as claimed in claim 1, wherein: the shaking mechanism (57) comprises a shaking box (571), a first crown gear (5711) is movably mounted at the top of an inner cavity of the shaking box (571), the bottom end of a penetrating shaft (561) is fixedly connected with the first crown gear (5711), a second crown gear (5712) is meshed and connected with the bottom of the first crown gear (5711), and the second crown gear (5712) is fixed in the inner cavity of the shaking box (571).

3. The processing equipment of a biological insole as claimed in claim 1, wherein: mount (9) are located actuating mechanism (21) and No. two actuating mechanism (22) both sides, installation axle (212), No. two installation axle (222), No. three installation axle (33) and No. four installation axle (43) both ends all are fixed in mount (9) one side through the bearing.

4. The processing equipment of a biological insole as claimed in claim 1, wherein: the cutting device is characterized in that a first clamping mechanism (7) and a second clamping mechanism (8) are respectively installed on one side of the fixed frame (9), the first clamping mechanism (7) and the second clamping mechanism (8) are respectively located at the bottoms of two ends of a second cutting roller (653) and a first cutting roller (652), the first clamping mechanism (7) and the second clamping mechanism (8) respectively comprise a connecting frame (77), the connecting frame (77) is fixed on one side of the fixed frame (9), the first clamping mechanism (7) and the second clamping mechanism (8) are identical in structure, one end of the connecting frame (77) is fixedly connected with a first fixing rod (71), one end of the first fixing rod (71) is fixedly connected with a sleeve (72), a spring (74) is installed in the inner cavity of the sleeve (72), a second fixing rod (73) is movably inserted into one end of the inner cavity of the sleeve (72), and one end of the second fixing rod (73) is fixedly connected with the spring (74), no. one centre gripping gyro wheel (75) is installed to dead lever (71) one side, No. two centre gripping gyro wheels (76) are installed to No. two dead lever (73) one sides, and No. two centre gripping gyro wheels (76) are located a centre gripping gyro wheel (75) one side, a centre gripping gyro wheel (75) and No. two centre gripping gyro wheels (76) are located No. two cutting roller (653) and a cutting roller (652) both ends bottom respectively, and a centre gripping gyro wheel (75) and No. two centre gripping gyro wheels (76) are located work piece (10) both ends, a centre gripping gyro wheel (75) and No. two centre gripping gyro wheels (76) are located an squeeze roll (32) and No. two squeeze roll (42) tops.

5. The processing equipment of a biological insole as claimed in claim 1, wherein: and the surfaces of the first rolling roller (214) and the second rolling roller (224) are fixedly provided with protruding blocks (2141).

6. The processing equipment of a biological insole as claimed in claim 1, wherein: spacing spout (531) have all been seted up to telescopic cylinder (53) inner chamber both sides, equal fixedly connected with spacing slider (541) in telescopic link (54) top both sides, and spacing slider (541) slide to be located spacing spout (531) inner chamber.

7. The processing equipment of a biological insole as claimed in claim 1, wherein: the bottom of the mounting frame (651) is fixedly provided with a lining plate (656), the lining plate (656) is positioned at one end of the sewing mechanism (62), and the lining plate (656) is positioned at the bottom of the second cutting roller (653).

8. The processing equipment of a biological insole as claimed in claim 1, wherein: equal fixedly connected with leading truck (63) in slide (61) top both sides, leading truck (63) one end fixedly connected with lantern ring (64), and No. one installation axle (212) and No. two installation axles (222) activity respectively run through lantern ring (64).

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