TW201720980A - Ribbon loom transmission device increasing the ribbon throughput and prolonging service life of the heald frame and accessories - Google Patents

Abstract

The ribbon loom transmission device of the invention comprises a base set; a worm gearing box transmission set, which is disposed at the outer edge of the base set; and a cam set and a blade rocker arm set, which are installed inside the base set. The worm of the worm gearing box transmission set engages with the worm wheel of the cam set in order to drive the cam sheet against the blade rocker arm set to further drive a heald frame. The worm, formed in eight threads, meshes the worm wheel and thereby has the camshaft keeping pace with the raising speed of the main shaft, and increases interweaving cycles of the ribbon loom heald frame, thus increasing the ribbon throughput of the invention. Further, the cam sheet, having a four-phase exterior curve, hence makes it possible to have the jerk of the cam sheet operation lessened and thus has the cam sheet wear alleviated. Furthermore, because of the ease on the cam sheet vibration, the service life of the heald frame and accessories are prolonged.

Description

Ribbon machine drive

The present invention relates to a webbing machine, and more particularly to a webbing machine capable of increasing the warp knitting capacity of a heald frame group and extending the life of the driving cam and the heald frame assembly.

The ribbon weaving machine is a traditional textile machine which forms a warp and weft interwoven tape by interweaving warp and weft. It can be commonly used in, for example, a zipper or a narrow high speed webbing machine. The zipper nylon material and the needle sewing cloth on both sides are woven into a strip shape.

The prior art webbing machine, such as Taiwan's new patent certificate number 051775, and the Taiwan invention patent number No. I323750, the completion of the upper and lower displacement movements of the heald frame group is driven by the cam piece to drive the rocker arm, and the plurality of rocker arms are respectively Drive the plurality of heald frames to move up and down, the heald frames are provided with healds, and the warp yarns are worn on the healds. The healds are driven up and down with the heald frames to drive the warp ups and downs, and the cams are driven. It is achieved by connecting the main shaft of the webbing machine to the camshaft. The connection between the main shaft and the camshaft is in the form of a worm and a worm gear. At the same time, the back and forth transport of the weft is guided by the rotation of the main shaft. Therefore, the heald frame The warp yarns driven by the lifting and lowering movements are intertwined with the weft yarns to achieve the weaving action of the cloth strips.

However, the prior art webbing machine has a four-toothed worm type, so that it corresponds to a 32-tooth worm wheel, which constitutes a ratio of 1:8. When the main shaft is 1000 RPM, the camshaft is 125 RPM, and if the capacity is to be increased, When the spindle is raised to 2000 RPM, the speed of the camshaft is only 250 RPM, so the warp and weft interlacing can not be effectively improved. Moreover, the prior art adopts an eight-phase cam piece, that is, a cam is formed every 45 degrees. Although the movement of the lifting and lowering of the heald frame can perform eight times of interlacing in the process of one revolution of the main shaft, it is also known that the lifting and lowering of the cam piece is frequent and rapid, thus forming a relatively large cam piece hopping degree. The vibration caused by the rotation of the cam piece is also large, which not only causes the cam piece to wear, but also makes the heald piece set in the heald frame group easy to wear and break, and at the same time, in the case of the increase of the spindle rotation speed, the cam is inevitably unable to be lifted. The shaft speed and productivity will make the cam piece more wearable and the healds will break earlier. In addition, if the prior art wants to adjust the height of each heald frame lift, It is necessary to prepare a variety of different lengths of the cutter rocker arm to drive the heald frame group to move up and down at different heights. However, this is for the operator to adjust the heald frame in the face of different webbing thickness requirements. The amount of opening in the group is quite inconvenient.

The object of the present invention is to improve the prior art, the productivity cannot be increased due to the low rotation speed of the camshaft, and the eight-phase cam piece causes high jump and easy wear, and must be prepared with different size types of the rocker arm. Inconvenience, etc., by the implementation of the technical means of the present invention, the camshaft speed can be increased with the spindle speed to increase the productivity, and the cam piece can slow down the jerk and reduce the wear, thereby prolonging the life of the heald frame assembly, and The rocker arm can be flexibly adjusted with a single size, making the part simple.

In order to achieve the above-mentioned creative purpose, the technical means adopted by the present invention is to design a webbing machine transmission device, which has a base set, a worm gear box transmission group, a cam set, a closed knife rocker arm set and a heald frame set. The base set has a machine table, a motor and a closing knife binding plate, the motor is fixed at one side of the machine table, the closing knife binding plate is mounted on the machine table; the worm gear box transmission group is connected to the motor And having a box body, a main shaft and a worm; the box body has a mounting groove, a protruding portion and a mounting hole, the mounting groove is laterally formed on a side of the box body, and the protruding portion is annular a protruding protrusion is formed in the inside of the mounting groove, the mounting hole is formed on the other side of the box, and communicates with the protruding portion and the mounting groove; the main shaft is pivotally disposed in the box parallel to the length direction of the box body The main shaft is inserted into the mounting slot and connected to the motor; the worm is fixedly sleeved on the main shaft and disposed inside the mounting groove of the casing, the worm is formed by an eight-toothed port; the cam set is inserted through the mounting Hole to connect to the worm gearbox drive set And mounted on the inside of the machine, which has a cam shaft, a rotating disc, a worm wheel and a plurality of cam plates; one end of the cam shaft is pivoted on the protruding portion of the box body, and the other end is pivotally mounted on the machine The rotating disk is fixed at an end of the cam shaft in the casing, and is connected to one end surface of the worm wheel, the worm gear has thirty-two teeth to engage the worm; the plurality of cam plates are slab cam pieces, the plural The cam piece is spaced apart from the other end of the cam shaft and disposed inside the machine frame, and the plurality of cam pieces are four-phase outer shape curves; the closed tool rocker arm group is respectively connected to the cam group and the comprehensive a frame group, and having a plurality of pivoting seats and a plurality of closing blade rocker members, wherein the plurality of pivoting seats can adjust the position of the closing knife binding plate mounted on the base set, and located inside the machine table, the plurality of cutting tools The rocker members are respectively pivotally disposed on the plurality of pivoting seats, and one end portion is respectively abutted by the plurality of cam plates; the heald frame group is fixed to the top of the machine table, and has two mounting plates and a plurality of heald frames; The installation boards are spaced apart from each other and correspond to each other. And a plurality of spaced apart grooves, the groove is formed in the mounting plate along the length direction of the mounting plate; the plurality of heald frames are spaced apart from each other and can be moved up and down Between the mounting plates, the plurality of extending portions are symmetrically formed at two side edges of the heald frame piece, and one end of the plurality of heald frame pieces are respectively connected to the plurality of closed blade rocker members The other end portion of the mounting portion passes through the receiving groove of the mounting plate.

The webbing drive device, wherein the plurality of cam pieces of the cam set are a first cam piece, a second cam piece, a third cam piece, a fourth cam piece, a fifth cam piece, a first a sixth cam piece, a seventh cam piece, an eighth cam piece, a ninth cam piece and a tenth cam piece, wherein the cam pieces respectively form a through hole, and are respectively recessed on the inner wall surface of the perforation to form a hole The first cam piece has a first coupling groove, a first lifting section, a first descending section, a first descending section, and a first coupling groove, and a first lifting section, a first retarding section, the first engaging groove is formed on the inner wall surface of the perforation, and the outer peripheral surface of the first cam piece corresponds to the first joint groove, and is formed clockwise every ninety degrees. The first lifting section, the first descending section, the first descending section and the first retarding section; the second cam piece has a second coupling groove, a second descending section, and a second lifting a segment, a third ascending segment and a second descending segment, wherein the second coupling groove is formed in the perforation a peripheral wall surface of the second cam piece corresponding to the second joint groove, and the second descending section, the second retarding section and the third top are sequentially formed every 90 degrees clockwise The third cam piece has a third coupling groove, a second third lifting section and two third descending sections, and the third coupling groove is formed on the inner wall of the perforation. The outer peripheral edge of the third cam piece corresponds to the third joint groove, and every third 90 degrees clockwise, one of the third top lift segments, one of the third sharp drop segments, and the other third top is sequentially formed. The fourth cam piece has a fourth coupling groove, a second fourth descending section and two fourth rising sections, and the fourth coupling groove is formed on the inner wall of the perforation. The outer peripheral surface of the fourth cam piece corresponds to the fourth joint groove, and every fourth 90 degrees clockwise, one of the fourth sharp drop sections, one of the fourth top lift sections, and the other fourth is sequentially formed. a fifth descending section and another fourth rising section; the fifth cam piece has a fifth coupling groove, two fifth lifting sections and two fifth lifting sections, The fifth joint groove is formed on the inner wall surface of the perforation, and the outer peripheral surface of the fifth cam piece corresponds to the fifth joint groove, and a fifth slow rise section is sequentially formed every 90 degrees clockwise. a fifth lifting section, another fifth lifting section and another fifth lifting section; the sixth cam piece has a sixth coupling groove, a second sixth lifting section and a second sixth descending section, a sixth coupling groove is formed on the inner wall surface of the perforation, and a peripheral surface of the outer edge of the sixth cam piece corresponds to the sixth coupling groove, and a sixth rising portion is sequentially formed every 90 degrees clockwise. a sixth descending section, another sixth jacking section and another sixth descending section; the seventh cam piece has a seventh coupling groove, a second seventh lifting section, and a seventh descending section a seventh lifting section, the seventh coupling groove is formed on the inner wall surface of the perforation, and the outer peripheral edge of the seventh cam piece corresponds to the seventh coupling groove, and is formed clockwise every ninety degrees. a seventh rising section, another seventh rising section, the seventh descending section and the seventh lifting section; the eighth cam piece has a The eighth coupling groove, the second eighth lifting section, an eighth descending section and an eighth lifting section, the eighth coupling groove is formed on the inner wall surface of the perforation, and the outer peripheral edge of the eighth cam piece corresponds to At the eighth joint groove, one eighth top lift section, the eighth slow descending section, the eighth slow rise section and another eighth top lift section are sequentially formed every 90 degrees clockwise; The ninth cam piece has a ninth coupling groove, a ninth descending section, a ninth lifting section and two ninth lifting sections, and the ninth coupling groove is formed on the inner wall of the perforation, the ninth cam piece The outer peripheral surface corresponds to the ninth joint groove, and every ninety degrees of clockwise, the ninth descending section, the ninth slow rising section, one of the ninth rising section and the other a tenth rising section; the tenth cam piece has a tenth coupling groove, a tenth lifting section, two tenth rising section and a tenth descending section, and the tenth coupling groove is formed on the inner wall of the perforation The peripheral surface of the outer edge of the tenth cam piece corresponds to the tenth joint groove, and the tenth stepwise section is formed in the clockwise direction every ninety degrees. Ten liters segment, the other segments and the tenth jacking tenth ramp down period.

The webbing machine transmission device, wherein the closing knife binding plate of the base set has a plurality of blind holes arranged at intervals, the blind hole recesses being formed on a side of the ply facing the inside of the machine; the closing rocker arm group has a pivoting seat having at least one positioning post and an engaging bearing, the positioning post protrudingly formed at one end of the pivoting seat, the positioning post being threaded on the cutting knife a blind hole of the plate, and the end of the pivoting seat forming the positioning post is fixed to the closing knife binding plate, the engaging bearing is mounted at the other end of the pivoting seat; the ten-way blade rocker arm is respectively pivotally connected to The ten pivoting seats and each having an engaging post and an abutting bearing, the engaging post protrudingly formed on one side of the closing blade rocker member, the abutting bearing being mounted on the closing blade rocker arm receiving cam An end portion of the top end of the sheet is mounted on the joint bearing, and the abutting bearing of the ten-way knife rocker member abuts against the ten cam piece; the heald frame group has ten heald frame pieces The frame sheets are each connected to the ten-way knife rocker member.

The webbing machine transmission device further includes a fastening portion, the buckle portion is recessed at the other end of the blade rocker arm member, and a through hole is formed; the heald frame group Further, the fixing base is disposed at an end of the heald frame group away from the machine base; the heald frame of the heald frame group further has a pull rod, a fixing block, a joint portion and a plurality of springs; the one end portion of the pull rod Fixed at one end of the heald frame, the fixing block is fixed on the pull rod, and the other end of the pull rod passes through the through hole of the fastening portion, the fixing block abuts against the inside of the fastening portion; the joint portion is formed At the other end of the heald frame, one end of the spring is fixed to the joint portion, and the other end portion is fixed to the fixing seat.

The belt machine transmission device, wherein the machine table further has an assembly hole formed through a side of the machine table and communicating with the inside of the machine table; the cam group is disposed through the assembly hole for mounting The inside of the machine, and further comprising a sleeve, a plurality of spacers and two positioning blocks; the sleeve is sleeved on the outer wall surface of the cam shaft, and the plurality of cam pieces and the plurality of spacers are fixedly mounted on the Each of the spacers is disposed between each of the two cam plates; the two positioning blocks are fixedly sleeved on the outer wall surface of the cam shaft, and each of the top portions abuts against the opposite ends of the sleeve.

The splicing machine transmission device, wherein the cam shaft further has a bearing set, an assembled bearing, a convex ring portion and a spacer ring; the bearing is assembled on an outer wall surface of one end of the cam shaft, and is accommodated in The inside of the convex portion of the casing; the spacer ring is sleeved on the outer wall surface of the cam shaft, and one end portion abuts against the bearing group; the assembled bearing is mounted on the outer wall surface of the cam shaft, and is accommodated The other end of the spacer ring abuts against the assembled bearing inside the mounting hole of the casing; the convex ring portion is formed in an annular shape on the outer wall surface of the cam shaft and abuts against the assembled bearing.

The belt conveyor transmission device, wherein the motor further has a transmission belt, the transmission belt sleeve is disposed at an output end of the motor; the worm gear box transmission group further has a transmission wheel, the transmission wheel is fixedly mounted on the main shaft At one end, the transmission belt is sleeved on the transmission wheel.

The webbing drive device, wherein the base set further has a base, the bottom end of the machine base is fixed to the base; the machine base further has a flower plate axial fixed cover, the flower plate axial fixed The cover is mounted on the other side of the machine, and corresponding to the assembly hole, the other end of the cam shaft is pivotally disposed on the plate axial fixed cover.

The webbing mechanism of the webbing device further includes two cover plates, two auxiliary plates and a guide hole seat; the two cover plates are correspondingly disposed at two sides of the heald frame group to cover the a spring; the two auxiliary plates are disposed at two sides of the heald frame group, and each of the plurality of longitudinal grooves is formed at a plurality of intervals; the guide hole seat is fixed to the top end of the machine table, and the plurality of guide holes are formed through the interval The plurality of guide rods of the plurality of heald frame sheets are respectively disposed with the plurality of guide holes; the opposite ends of the joint portion of the heald frame sheets extend outwardly and are disposed through the longitudinal grooves of the two auxiliary plates.

The webbing device transmission device, wherein the heald frame group further has two guiding plates; the two guiding plates are disposed at two sides of the heald frame group, and each corresponding to the two mounting plates, and has a plurality of intervals The guiding groove is formed through the guiding plate in parallel with the longitudinal direction of the guiding plate, and the extending portion of the heald frame piece passes through the guiding groove.

The invention has the advantages that the worm gear formed by the eight-tooth port of the worm gear transmission group engages the worm wheel of the cam group, so that the rotation speed of the cam shaft can be activated in accordance with the increase of the spindle rotation speed, so that the blade rocker arm of the blade rocker arm group is actuated. And the number of lifting movements of the heald frame of the heald frame group can be increased, so that the number of interlacing actions of the webbing machine is increased, thereby increasing the productivity of the webbing machine, and because the cam piece has a four-phase profile, the cam piece is The hop of the operation process can be slowed down, thereby reducing the wear of the cam piece, and further improving the service life of the heald piece provided on the heald frame piece by improving the jitter formed by the cam piece, and further, because the pivot seat The adjustable can be fixed on the closing knife binding plate, and the closing blade rocking arm member can rotate relative to the pivoting seat, so that the range of the swinging rocker arm member swinging is adjusted, thereby adjusting the degree of lifting movement of the heald frame piece, and further, because of the pivot The socket can be adjusted and fixed on the blade combination plate, and the blade rocker member can be rotated relative to the pivoting seat, so that the range of the blade rocker member swing can be changed. The degree of lifting and lowering of the heald frame is adjusted. Therefore, the blade rocker member of the present invention can be in a single size form, and the cam piece can be matched under the premise of simplifying the parts, and the thickness of the webbing and the requirements of the heald opening are required. Adjustments have been made to improve the inconvenience of the prior art that it is necessary to prepare a plurality of lengths of the blade rocker.

The technical means adopted by the present invention for achieving the intended purpose of creation are further explained below in conjunction with the drawings and preferred embodiments of the present invention.

Referring to FIG. 1 , FIG. 2 and FIG. 5 , the webbing device transmission device of the present invention has a base set 10 , a worm gear box transmission set 20 , a cam set 30 , a closed knife rocker arm set 40 and a The heald frame group 50 is configured to cooperate with a weft feeding device group 60 and a weft yarn breaking control seat group 70, and the weft feeding device group 60 and the weft yarn breaking control seat group 70 are used for conveying. The weft yarn is further matched with the warp brown sheet passing through the heald frame group 50 to complete the interlacing action of the webbing machine.

Referring to FIG. 1 , FIG. 2 and FIG. 5 , the base set 10 has a machine table 11 , a motor 12 , a knife binding plate 13 and a base 100 .

The machine base 11 has an assembly hole 110 and a flower plate axial fixed cover 111. The assembly hole 110 is formed on one side of the machine table 11 and communicates with the inside of the machine table 11. The plate axial fixed cover The 111 is mounted on the other side of the machine table 11 and corresponds to the assembly hole 110.

The motor 12 is fixed to a side of the machine table 11 and has a transmission belt 121 which is sleeved at the output end of the motor 12.

The knife-bonding plate 13 is mounted on the machine table 11, and has a blind hole (not shown) and a positioning hole 131 disposed at a plurality of intervals.

The plurality of blind holes (not shown) are formed on the side of the blade bonding plate 13 facing the inside of the machine table 11, and are disposed at intervals of a row. Specifically, the operator can process the blade according to requirements. The blind holes are arranged in a lateral direction, such as: arranged in a straight line, or partially blind holes are staggered from other blind holes and not in the same course.

The plurality of positioning holes 131 are formed through the blade joining plate 13 .

The bottom end of the machine table 11 is fixed to the base 100.

Referring to FIGS. 2 to 4 , the worm gear transmission set 20 is coupled to the motor 12 and has a casing 21 , a transmission wheel 22 , a main shaft 23 , and a worm 24 .

The housing 21 has a mounting groove 210, a protruding portion 211 and a mounting hole 212. The mounting groove 210 is laterally formed on a side surface of the housing 21. The protruding portion 211 is formed in an annular shape. The mounting hole 212 is formed on the other side of the casing 21 and communicates with the protruding portion 211 and the mounting groove 210.

The transmission wheel 22 is disposed at an outer wall surface of one end of the casing 21, and the transmission belt 121 is sleeved on the transmission wheel 22.

The main shaft 23 is pivotally disposed inside the casing 21 in parallel with the longitudinal direction of the casing 21. The main shaft 23 passes through the mounting groove 210. The transmission wheel 22 is fixedly mounted at one end of the main shaft 23. The main shaft 23 Connected to the motor 12, specifically, the transmission wheel 22 is sleeved through the transmission belt 121 to form a connection between the main shaft 23 and the motor 12.

The worm 24 is fixedly sleeved on the outer wall surface of the main shaft 23, and is disposed inside the mounting groove 210 of the casing 21. Specifically, the worm 24 is formed by eight teeth.

Referring to FIG. 3 to FIG. 5 , one end of the cam assembly 30 is inserted through the mounting hole 212 of the box 21 to be connected to the worm gear box transmission group 20 , and the other end is inserted through the assembly hole 110 to be mounted on the machine. The inside of the table 11 has a cam shaft 31, a rotating disk 32, a worm wheel 33, a bushing 34, a plurality of cam plates 35, a plurality of spacers 36 and two positioning blocks 37.

One end of the camshaft 31 is pivotally disposed on the protruding portion 211 of the casing 21, and the other end is pivotally mounted on the hub axial fixed cover 111 of the machine table 11, and has a bearing set 311 and an assembled bearing 312. a convex ring portion 313 and a spacer ring 310.

The bearing set 311 is mounted on the outer wall surface of one end of the cam shaft 31 and is fixedly mounted inside the protruding portion 211 of the casing 21.

The assembled bearing 312 is mounted on the outer wall surface of the camshaft 31 and is fixedly mounted inside the mounting hole 212 of the casing 21.

The convex ring portion 313 is formed in an annular shape and formed on the outer wall surface of the cam shaft 31 and abuts against the assembled bearing 312.

The spacer ring 310 is sleeved on the outer wall surface of the camshaft 31, and one end portion abuts against the bearing set 311, and the other end portion abuts against the assembled bearing 312.

The rotating disk 32 is fixed to an end portion of the cam shaft 31 in the casing 21, and is fixed to one end surface of the worm wheel 33. Specifically, the worm wheel 33 has thirty-two teeth to engage the worm 24.

The sleeve 34 is fixedly sleeved on the outer wall surface of the cam shaft 31.

The plurality of cam pieces 35 are flat-plate cam pieces, and the plurality of cam pieces 35 are fixedly spaced apart from the other end of the cam shaft 31, and are disposed inside the machine table 11. The plurality of cam pieces 35 are all four-phase type. The plurality of cam plates 35 and the plurality of spacers 36 are fixedly disposed on the outer wall surface of the sleeve 34, and the spacers 36 are disposed between each of the two cam plates 35.

The two positioning blocks 37 are fixedly sleeved on the outer wall surface of the cam shaft 31 and respectively abut against the opposite ends of the sleeve 34.

In the specific implementation of the present invention, the plurality of cam pieces 35 are a first cam piece 351, a second cam piece 352, a third cam piece 353, a fourth cam piece 354, and a fifth cam piece 355. a sixth cam piece 356, a seventh cam piece 357, an eighth cam piece 358, a ninth cam piece 359 and a tenth cam piece 350. As shown in FIG. 4, the cam pieces each penetrate through a through hole. The sleeve is sleeved on the cam shaft 31 and the sleeve 34, and is recessed on the inner wall surface of the perforation to form a coupling groove, so as to be fixed to the sleeve 34 by assembling a joint key.

Referring to FIG. 6 , the first cam piece 351 has a first coupling groove 3510 , a first lifting section 3511 , a first descending section 3512 , a first descending section 3513 , and a first lifting section . 3514, the first joint groove 3510 is recessed on the inner wall surface of the perforation, and the outer peripheral surface of the first cam piece 351 corresponds to the first joint groove 3510, and the first step is formed every 90 degrees clockwise. a lifting section 3511, the first descending section 3512, the first descending section 3513, and the first retarding section 3514.

Referring to FIG. 7 , the second cam piece 352 has a second coupling groove 3520 , a second descending section 3521 , a second lifting section 3522 , a third lifting section 3523 and a second descending section . 3524, the second coupling groove 3520 is concavely formed on the inner wall surface of the perforation, and the outer peripheral surface of the second cam piece 352 corresponds to the second coupling groove 3520, and the second portion is formed clockwise every ninety degrees. The second descending section 3521, the second rising section 3522, the third rising section 3523 and the second descending section 3524.

As shown in FIG. 8 , the third cam piece 353 has a third coupling groove 3530 , two third lifting sections 3531 and two third descending sections 3532 . The third coupling groove 3530 is recessed on the inner wall of the perforation. The peripheral surface of the outer edge of the third cam piece 353 corresponds to the third coupling groove 3530, and every third 90 degrees of clockwise, one of the third rising sections 3531 and one of the third descending sections 3532 are sequentially formed. The other third rising section 3531 and the other third falling section 3532.

As shown in FIG. 9 , the fourth cam piece 354 has a fourth coupling groove 3540, two fourth descending sections 3541 and two fourth rising sections 3542. The fourth coupling groove 3540 is recessed on the inner wall of the perforation. The peripheral surface of the outer edge of the fourth cam piece 354 corresponds to the fourth coupling groove 3540, and every fourth 90 degrees of clockwise, one of the fourth descending sections 3541 and one of the fourth rising sections 3542 are sequentially formed. Another fourth rappelling section 3541 and another fourth hoisting section 3542.

As shown in FIG. 10, the fifth cam piece 355 has a fifth coupling groove 3550, two fifth lifting sections 3551 and two fifth lifting sections 3552. The fifth coupling groove 3550 is recessed on the inner wall of the perforation. The peripheral surface of the outer edge of the fifth cam piece 355 corresponds to the fifth coupling groove 3550, and every fifth 90 degrees of clockwise, one of the fifth lifting section 3551 and one of the fifth lifting section 3552 is sequentially formed. And another fifth lifting section 3551 and another fifth lifting section 3552.

Referring to FIG. 11, the sixth cam piece 356 has a sixth coupling groove 3560, a second sixth lifting section 3561, and a second sixth descending section 3562. The sixth coupling groove 3560 is recessed on the inner wall of the perforation. The peripheral surface of the outer edge of the sixth cam piece 356 corresponds to the sixth coupling groove 3560, and every sixth 90 degrees of clockwise, one of the sixth rising sections 3561 and one of the sixth descending sections 3562 are sequentially formed. Another sixth rising section 3561 and another sixth descending section 3562.

Referring to FIG. 12, the seventh cam piece 357 has a seventh coupling groove 3570, a second seventh lifting section 3571, a seventh descending section 3572, and a seventh lifting section 3573. The seventh coupling groove 3570 recess is formed on the inner wall surface of the perforation, and the outer peripheral surface of the seventh cam piece 357 corresponds to the seventh joint groove 3570, and a seventh top lift section 3571 is sequentially formed every 90 degrees clockwise. The other seventh rising section 3571, the seventh descending section 3572 and the seventh lifting section 3573.

Referring to FIG. 13 , the eighth cam piece 358 has an eighth coupling groove 3580 , a second eighth lifting section 3581 , an eighth descending section 3582 and an eighth lifting section 3583 . The eighth coupling groove The 3580 recess is formed on the inner wall surface of the perforation, and the outer peripheral surface of the eighth cam piece 358 corresponds to the eighth joint groove 3580, and the eighth top lift section 3581 is sequentially formed every 90 degrees clockwise. The eighth descending section 3582, the eighth retarding section 3583 and another eighth jacking section 3581.

Referring to FIG. 14 , the ninth cam piece 359 has a ninth coupling groove 3590 , a ninth descending section 3591 , a ninth lifting section 3592 and two ninth lifting sections 3593 . 3590 recess is formed on the inner wall surface of the perforation, the outer peripheral surface of the ninth cam piece 359 corresponds to the ninth coupling groove 3590, and the ninth descending segment 3591 is sequentially formed every 90 degrees clockwise. The ninth lifting section 3592, one of the ninth rising section 3593 and the other ninth rising section 3593.

Referring to FIG. 15 , the tenth cam piece 350 has a tenth coupling groove 3500 , a tenth lifting section 3501 , a second tenth lifting section 3502 , and a tenth descending section 3503 . 3500 recesses are formed on the inner wall surface of the perforations, and the outer peripheral surface of the tenth cam piece 350 corresponds to the tenth coupling groove 3500, and the tenth retarding section 3501 is sequentially formed every 90 degrees clockwise. A tenth rising section 3502, another tenth rising section 3502, and the tenth descending section 3503.

Referring to FIG. 5 , FIG. 16 and FIG. 17 , the blade rocker arm group 40 is respectively connected to the cam group 30 and the heald frame group 50 , and has a plurality of pivoting seats 41 and a plurality of blade bending arm members 42 .

The plurality of pivoting seats 41 can be adjusted to the position of the blade assembly plate 13 of the base set 10 and disposed inside the machine table 11. The pivoting seat 41 has at least one positioning post 411 and an engaging bearing 412. .

The positioning post 411 is formed at one end of the pivoting seat 41. The positioning post 411 is mounted on the blind hole of the blade bonding plate 13. The engaging bearing 412 is mounted on the other end of the pivoting seat 41. Specifically, the pivoting seat 41 forms a positioning hole 131 corresponding to the end of the positioning post 411 corresponding to the knife binding plate 13 , and the operator can connect the pivoting seat 41 through the positioning hole 131 with a screw fastener, so that the pivoting seat 41 The pivoting seat 41 is fixed to the blade bonding plate 13 .

The plurality of pivoting rocker members 42 are respectively pivotally disposed on the plurality of pivoting seats 41, and one end portion is respectively abutted by the plurality of cam plates 35. The blade bending arm member 42 has an engaging post 421 and an abutting bearing 422. And a fastening portion 423.

The engaging post 421 is formed on one side of the blade rocker member 42; the engaging post 421 is mounted on the engaging bearing 412 of the pivoting seat 41.

The abutting bearing 422 is mounted on one end of the blade rocker arm member 42 , and the abutting bearing 422 abuts against the cam plate 35 .

The fastening portion 423 is recessed at the other end of the blade rocker member 42 and is formed with a through hole.

Specifically, the blade rocker arm assembly 40 of the present invention has a ten pivoting seat 41 and a ten-way rocker arm member 42 respectively pivotally connected to the ten pivoting seats 41, and respectively corresponding to Abutting the first cam piece 351, the second cam piece 352, the third cam piece 353, the fourth cam piece 354, the fifth cam piece 355, the sixth cam piece 356, and the seventh cam piece 357 The eighth cam piece 358, the ninth cam piece 359, and the tenth cam piece 350.

Referring to FIG. 1 , FIG. 16 and FIG. 17 , the heald frame group 50 is fixed to the top end of the machine table 11 and has two mounting plates 51 , a plurality of heald frame plates 52 , two guiding plates 53 , and a fixing seat 54 . Two cover plates 55, two auxiliary plates 56 and a guide hole holder 500.

The two mounting plates 51 are spaced apart from each other and correspondingly disposed on the machine table 11 and have a plurality of spaced apart receiving grooves 511 formed in the mounting plate 51 along the length direction of the mounting plate 51. 51.

The plurality of heald frames 52 are spaced apart from each other and are movable up and down between the two mounting plates 51. The heald frame 52 has a plurality of extending portions 521, a pull rod 522, a fixing block 523, a joint portion 524, and The plurality of springs 525; in particular, the heald frame group 50 is opposite to the blade rocker member 42 and the cam plate 35, and has a heald frame 52, one end of which is connected to the blade rocker The fastening portion 423 of the member 42.

The plurality of extending portions 521 are formed symmetrically at the two side edges of the heald frame 52. The extending portion 521 extends through the receiving groove 511 of the mounting plate 51.

One end of the pull rod 522 is fixed to one end of the heald frame 52, and the fixing block 523 is fixed to the pull rod 522. The other end of the pull rod 522 passes through the through hole of the fastening portion 423, and the fixing block 523 abuts The inside of the fastening portion 423.

The joint portion 524 is formed at the other end of the heald frame sheet 52, and the joint portion 524 extends outwardly relative to the two end portions.

One end of the spring 525 is fixed to the joint portion 524.

The two guide plates 53 are disposed at the two sides of the heald frame group 50, and have a plurality of spaced apart guiding grooves 531, the guiding groove 531 is formed parallel to the length of the guiding plate 53 and formed in the guiding plate 53; The two guide plates 53 respectively correspond to the two mounting plates 51 , and the extending portion 521 of the heald frame 52 passes through the guiding grooves 531 .

The fixing seat 54 is disposed at an end of the heald frame group 50 away from the machine table 11; the other end of the spring 525 is fixed to the fixing base 54.

The two cover plates 55 are correspondingly disposed at two sides of the heald frame group 50 to cover the spring 525.

The two auxiliary plates 56 are disposed at two sides of the heald frame group 50, and each of them forms a plurality of longitudinal grooves. The two ends of the joint portion 524 are disposed through the longitudinal grooves of the two auxiliary plates 56.

The guide hole holder 500 is fixed to the top end of the machine table 11, and the plurality of guide holes 5000 are formed through the gaps. Specifically, the guide hole holder 500 correspondingly has ten guide holes 5000, and the tie rods 522 of the heald frame piece 52 are worn. The guide hole 5000 is provided.

Referring to FIG. 5, FIG. 16, and FIG. 17, when the plurality of cam pieces 35 are respectively actuated to abut the abutting bearing 422 against the end of the blade rocker arm member 42, the blade rocker member 42 is actuated. The one end of the pivoting arm member 42 is pivoted downwardly relative to the latching portion 423 of the other end of the pivoting seat 41. The securing portion 523 is engaged by the latching portion 423, and the connecting rod 522 is connected through the connecting rod 522. So that the heald frame 52 is displaced downward against the elastic force of the spring 525. If the cam piece 35 continues to rotate until the lifting section leaves the blade rocker arm member 42, the heald frame piece 52 is replaced by the spring 525. The elastic force returns to the original position.

The groove 511 of the mounting plate 51 and the guiding groove 531 of the guiding plate 53 guide the upper and lower displacement of the heald frame 52 to ensure the stability of the heald frame 52 during the lifting and lowering process.

Referring to FIG. 18 and FIG. 20, since the fourth cam piece 354 of the present invention has a four-phase design, the fourth cam piece 354 is completed every 90 degrees during the implementation of one rotation of the fourth cam piece 354. The action of the cam piece lifting and lowering, in contrast, the cam piece of the prior art in FIG. 20 (on the next one) is an eight-phase cam piece, that is, the action of lifting and lowering the cam piece every 45 degrees, thereby knowing the lifting action of the cam piece Frequent and rapid, thus forming a relatively large cam piece jerk, the vibration caused by the rotation of the cam piece is also large, not only the wear of the cam piece, but also the heald piece set on the heald frame piece 52 is easy to break; The total lift distance H is the difference between the maximum distance from the center of the cam piece to the circumference and the minimum distance from the center of the cam piece to the periphery, that is, the end of the blade rocker arm member 42 is raised from the lowest position to the highest position at the end of the bearing 422. the distance.

Referring to FIG. 19 and FIG. 21, the first cam piece 351 of the present invention can maintain the blade rocker arm member 42 in the high position during the rotation process from 0 degrees to 180 degrees. When the cam piece 351 is turned to 270 degrees, the closed blade rocker arm member 42 reaches the low position, and the first cam piece 351 is used as a phase of the lifting action every 90 degrees. Otherwise, the prior art of FIG. 21 The cam piece (three times up and down) is the phase of a lifting action every 45 degrees, which also causes the cam piece to have a large jump and a large jitter.

The eight-tooth port of the worm 24 of the present invention corresponds to the 32 teeth of the worm wheel 33, forming a ratio of 1:4. It can be seen that when the rotational speed of the spindle 23 is raised from 1000 RPM to 2000 RPM, the rotational speed of the camshaft 31 will be 250RPM is raised to 500RPM. Since the main shaft 23 rotates once, and the heald frame 52 is driven by the cam piece 35 and the closing blade rocker member 42 to complete a lifting operation, the interlacing action can be completed. The rotation speed of the camshaft 31 can be increased in accordance with the rotation speed of the main shaft 23, that is, the number of movements of the heald frame 52 can be increased, so that the heald frame 52 can be more operated in a unit time, thereby improving The production capacity of the ribbon machine.

In contrast, the prior art worm is a four-toothed worm gear of 32 teeth, which constitutes a ratio of 1:8. When the spindle is 1000 RPM, the camshaft is 125 RPM, and the number of revolutions of the camshaft is lower than 250 RPM of the present invention. Its production capacity is much lower than the present invention. Even if the spindle is raised to 2000RPM, the speed of its camshaft is still only 250RPM. At the same time, because the prior art adopts the eight-phase cam plate, the cam will be intensified when the camshaft speed is increased. The phenomenon of sharp jump and jitter makes the cam piece more wearable and the heald piece breaks earlier.

That is, in the implementation of the present invention, each time the cam piece 35 completes one rotation, the cam piece 35 is a four-phase profile, so that the heald frame 52 can be lifted four times. The execution of the interlacing of the warp and weft yarns is achieved four times, and the operator can adjust the state of the high and low positions of each of the cam sheets 35 according to the thickness of the webbing to be manufactured, thereby adjusting the height of each heald frame 52. The amount of opening, on the other hand, the eight-phase cam piece of the prior art can perform eight interleaving operations when completing each rotation, but can only adjust the high and low positions of each cam piece consistently. Thus, the operator individually adjusts the amount of opening of each heald frame.

In the present invention, the worm gear 24 formed by the eight-tooth mouth of the worm gear transmission group 20 engages the worm wheel 33 of the cam assembly 30, so that the rotation speed of the camshaft 31 can be actuated in accordance with the increase of the rotation speed of the spindle 23, so that the The number of lifting movements of the blade rocker arm member 42 of the knife rocker arm group 40 and the heald frame piece 52 of the heald frame group 50 can be increased, thereby increasing the number of times of the interlacing operation of the webbing machine, thereby increasing the productivity of the webbing machine, and Since the cam piece 35 has a four-phase profile, the cam sheet 35 can be slowed down during operation, thereby reducing the wear of the cam piece 35, and further improving the jitter formed by the cam piece 35. Further extending the service life of the heald piece disposed on the heald frame 52, and further, because the pivoting seat 41 is adjustably fixed to the blade joining plate 13, and the blade rocker member 42 can Rotating relative to the pivoting seat 41, the range in which the blade rocker member 42 swings can be changed, thereby adjusting the degree of lifting displacement of the heald frame 52. Therefore, the blade rocker member 42 can be provided in a single size form. Flexible adjustment, and Of parts, it must be prepared to improve the prior art rocker member inconvenience cutters of various length.

The above is only a preferred embodiment of the present invention, and is not intended to limit the scope of the present invention. Although the present invention has been disclosed in the above preferred embodiments, it is not intended to limit the invention, and A person skilled in the art can make some modifications or modifications to equivalent embodiments by using the above-disclosed technical contents without departing from the technical scope of the present invention. The present invention is not limited to any simple modifications, equivalent changes and modifications of the above embodiments.

10‧‧‧Base Group
11‧‧‧ machine
110‧‧‧Assembled holes
111‧‧‧Flower plate axial fixed cover
12‧‧‧ motor
121‧‧‧Drive belt
13‧‧‧Knife combined board
131‧‧‧Positioning holes
100‧‧‧Base
20‧‧‧ Worm Gearbox
21‧‧‧ cabinet
211‧‧‧Protruding
212‧‧‧Mounting holes
210‧‧‧Installation slot
22‧‧‧Drive wheel
23‧‧‧ Spindle
24‧‧‧ worm
30‧‧‧Cam Group
31‧‧‧Camshaft
311‧‧‧ bearing set
312‧‧‧Assembled bearings
313‧‧‧ convex ring
310‧‧‧ spacer ring
32‧‧‧ rotating disk
33‧‧‧ worm gear
34‧‧‧ bushings
35‧‧‧Cam film
351‧‧‧First cam piece
3510‧‧‧First joint slot
3511‧‧‧First ascent
3512‧‧‧First slowdown
3513‧‧‧1st down segment
3514‧‧‧First slow-up section
352‧‧‧Second cam piece
3520‧‧‧Second joint slot
3521‧‧‧second falling section
3522‧‧‧second slow rise section
3523‧‧‧second lifting section
3524‧‧‧second slowdown
353‧‧‧ Third cam piece
3530‧‧‧3rd joint slot
3531‧‧‧3rd lift
3532‧‧‧ Third emergency section
354‧‧‧4th cam piece
3540‧‧‧4th joint slot
3541‧‧‧The fourth sudden drop
3542‧‧‧Four lift
355‧‧‧ fifth cam piece
3550‧‧‧5th joint slot
3551‧‧‧The fifth slow-up section
3552‧‧‧5th lift
356‧‧‧6th cam piece
3560‧‧‧6th joint slot
3561‧‧‧6th lift
3562‧‧‧6th descent section
357‧‧‧ seventh cam piece
3570‧‧‧ seventh joint slot
3571‧‧‧ seventh rising section
3572‧‧‧ seventh slowdown
3573‧‧‧ seventh slow rise section
358‧‧‧8th cam piece
3580‧‧‧8th joint slot
3581‧‧‧8th ascending section
3582‧‧‧ Eighth descending section
3583‧‧‧8th levee
359‧‧‧Ninth cam piece
3590‧‧‧ninth joint slot
3591‧‧‧The ninth descent section
3592‧‧‧Ninth volley
3593‧‧‧The ninth rising section
350‧‧‧10th cam piece
3500‧‧‧10th joint slot
3501‧‧‧10th stagflation section
3502‧‧‧10th ascent
3503‧‧‧10th descent section
36‧‧‧ Spacer
37‧‧‧ Positioning block
40‧‧‧Knife rocker arm set
41‧‧‧ pivoting seat
411‧‧‧Positioning column
412‧‧‧ joint bearing
42‧‧‧Knife rocker arm
421‧‧‧ Engagement column
422‧‧‧Resist bearings
423‧‧‧Detention Department
50‧‧‧heald frame group
51‧‧‧Installation board
511‧‧‧容沟
52‧‧‧heald frame
521‧‧‧Extension
522‧‧‧ lever
523‧‧‧Fixed block
524‧‧‧ joints
525‧‧ ‧ spring
53‧‧‧ Guide
531‧‧‧Guide ditch
54‧‧‧ fixed seat
55‧‧‧ Cover
56‧‧‧Auxiliary board
500‧‧‧guide hole seat
5000‧‧‧Guide
60‧‧‧Spinning device group
70‧‧‧Weft yarn breakage control set
H‧‧‧ total lift
R‧‧‧The distance from the center of the cam piece to the circumference θ‧‧‧Cam lens rotation angle

Figure 1 is a perspective view of the present invention. 2 is a partially separated perspective view of the worm gear box transmission group, the cam group and the base set of the present invention. Figure 3 is a cross-sectional elevational view of the worm gearbox drive set of the present invention. Figure 4 is a cross-sectional side view of the worm gearbox drive set and cam set of the present invention. Figure 5 is a partial perspective view of the cam set and the shut-off rocker arm set of the present invention. Figure 6 is a front plan view of the first cam piece of the present invention. Figure 7 is a front plan view of a second cam piece of the present invention. Figure 8 is a front plan view of a third cam piece of the present invention. Figure 9 is a front plan view of a fourth cam piece of the present invention. Figure 10 is a front plan view of a fifth cam piece of the present invention. Figure 11 is a front plan view of a sixth cam piece of the present invention. Figure 12 is a front plan view of a seventh cam piece of the present invention. Figure 13 is a front plan view of the eighth cam piece of the present invention. Figure 14 is a front plan view of a ninth cam piece of the present invention. Figure 15 is a front plan view of a tenth cam piece of the present invention. Figure 16 is a partially exploded perspective view of the heald frame of the present invention. Figure 17 is a partial perspective view of the blade rocker arm set and the heald frame set of the present invention. Figure 18 is a diagram showing the rotation angle of the cam piece of Figure 9 of the present invention - the distance from the center of the cam piece to the circumference. Figure 19 is a view showing the relationship between the rotation angle of the cam piece of Figure 6 and the distance from the center of the cam piece to the circumference of the present invention. Figure 20 is a diagram showing the relationship between the rotation angle of the cam piece of the prior art cam piece - the center-to-circumference distance of the cam piece. Figure 21 is a diagram showing the relationship between the rotation angle of the cam piece of another prior art cam piece - the center-to-circumference distance of the cam piece.

111‧‧‧Flower plate axial fixed cover

13‧‧‧Knife combined board

131‧‧‧Positioning holes

30‧‧‧Cam Group

31‧‧‧Camshaft

35‧‧‧Cam film

40‧‧‧Knife rocker arm set

41‧‧‧ pivoting seat

411‧‧‧Positioning column

42‧‧‧Knife rocker arm

50‧‧‧heald frame group

Claims (10)

A belt conveyor transmission device, comprising a base set, a worm gear box drive set, a cam set, a closed knife rocker arm set and a heald frame set; the base set has a machine table, a motor and a knife a motor is fixed to a side of the machine, the knife binding plate is mounted on the machine; the worm gear transmission is connected to the motor, and has a box body, a main shaft and a worm; the box body The mounting groove has a mounting groove, a protruding portion and a mounting hole, and the mounting groove is formed laterally on a side of the housing. The protruding portion is formed in an annular shape and is formed inside the mounting groove. The mounting hole is formed in the mounting hole. The other side of the box body, and communicates with the protruding portion and the mounting groove; the main shaft is pivotally disposed inside the box body parallel to the longitudinal direction of the box body, the main shaft passes through the mounting groove and is connected to the motor; The worm is fixedly sleeved on the main shaft and disposed inside the mounting groove of the box body, and the worm is formed by an eight-toothed port; the cam set is inserted through the mounting hole to be connected to the worm gear box transmission group, and is mounted on the machine Inside the table, it has a camshaft, a rotation a worm wheel and a plurality of cam plates; one end of the cam shaft is pivoted on the protruding portion of the box body, and the other end portion is pivotally mounted on the machine table; the rotating disk is fixed at an end portion of the cam shaft in the box body, and Connecting to one end surface of the worm wheel, the worm gear has thirty-two teeth to engage the worm; the plurality of cam sheets are slab cam pieces, and the plurality of cam pieces are spaced apart from each other at the other end of the cam shaft, and are disposed on Inside the machine, the plurality of cam segments are four-phase outer curve; the blade rocker arm group is respectively connected to the cam group and the heald frame group, and has a plurality of pivoting seats and a plurality of closing blade rocker members, The plurality of pivoting seats can be adjusted to the position of the blade assembly plate of the base set, and are located inside the machine table, and the plurality of blade rocker arms are respectively pivoted on the plurality of pivoting seats, and one end portion is respectively The plurality of cam plates are abutted; the heald frame group is fixed to the top of the machine frame, and has two mounting plates and a plurality of heald frame plates; the two mounting plates are spaced apart from each other and correspondingly disposed on the machine table, and have a plurality of Interval setting The groove is formed in the mounting plate along the longitudinal direction of the mounting plate; the plurality of heald frames are spaced apart from each other and can be moved up and down between the two mounting plates, and have a plurality of extending portions, the plurality of extending portions a symmetrical protrusion is formed at two side edges of the heald frame piece, and one end of the plurality of heald frame pieces is respectively connected to the other end of the plurality of off blade rocker members, and the extension portion passes through the mounting plate ditch. The webbing device of claim 1, wherein the plurality of cam pieces of the cam group are a first cam piece, a second cam piece, a third cam piece, a fourth cam piece, and a fifth cam. a sheet, a sixth cam piece, a seventh cam piece, an eighth cam piece, a ninth cam piece and a tenth cam piece, wherein the cam pieces respectively form a perforation and are on the inner wall of the perforation Each of the recesses forms a coupling groove for assembling a binding key to be fixedly sleeved on the cam shaft; the first cam piece has a first coupling groove, a first lifting section, a first descending section, and a first a descending section and a first retarding section, the first engaging groove is recessed on the inner wall surface of the perforation, and the outer peripheral edge of the first cam piece corresponds to the first joint groove, and every ninety degrees clockwise Forming the first lifting section, the first descending section, the first descending section and the first retarding section; the second cam piece has a second coupling groove, a second descending section, and a a second retarding section, a third jacking section and a second descending section, the second joint groove recessed Forming on the inner wall surface of the perforation, the peripheral surface of the outer edge of the second cam piece corresponds to the second joint groove, and the second descending section and the second descending section are sequentially formed every 90 degrees clockwise. The third lifting section and the second descending section; the third cam piece has a third coupling groove, two third lifting sections and two third descending sections, and the third coupling groove is formed in the through hole a peripheral wall surface, the outer peripheral surface of the third cam piece corresponds to the third joint groove, and clockwise every ninety degrees, sequentially forming one of the third rising sections, one of the third descending sections, and the other a third lifting section and another third sharpening section; the fourth cam piece has a fourth coupling groove, two fourth descending sections and two fourth rising sections, and the fourth coupling groove is formed in the perforation The inner edge wall surface, the outer peripheral surface of the fourth cam piece corresponds to the fourth joint groove, and every fourth 90 degrees clockwise, one of the fourth sharp drop sections, one of the fourth top lift sections, Another fourth descending section and another fourth rising section; the fifth cam piece has a fifth coupling groove, a second fifth lifting section and two second In the jacking section, the fifth joint groove is formed on the inner wall surface of the perforation, and the outer peripheral surface of the fifth cam piece corresponds to the fifth joint groove, and clockwise every ninety degrees, sequentially forming one of the first a fifth lifting section, a fifth rising section, another fifth lifting section and another fifth lifting section; the sixth cam piece has a sixth coupling groove, a second sixth lifting section and two second a sixth descending section, the sixth joint groove is formed on the inner wall surface of the perforation, and the outer peripheral surface of the sixth cam piece corresponds to the sixth joint groove, and one of them is formed clockwise every ninety degrees. a sixth lifting section, a sixth descending section, another sixth lifting section and another sixth descending section; the seventh cam piece has a seventh coupling groove, a second seventh lifting section, and a a seventh descending section and a seventh descending section, wherein the seventh joint groove is formed on the inner wall surface of the perforation, and the outer peripheral edge of the seventh cam piece corresponds to the seventh joint groove, clockwise every ninety degrees a range of sequentially forming one of a seventh jacking section, another seventh jacking section, the seventh descending section, and the seventh slowing section; The eight cam piece has an eighth coupling groove, a second eighth lifting section, an eighth descending section and an eighth lifting section, and the eighth coupling groove is formed on the inner wall surface of the perforation, and the eighth cam piece is The outer peripheral surface of the outer edge corresponds to the eighth joint groove, and every eighty degrees of clockwise, one of the eighth top lift sections, the eighth descending section, the eighth slow rise section and the other eighth is sequentially formed. The ninth cam piece has a ninth coupling groove, a ninth descending section, a ninth retarding section and two ninth rising sections, and the ninth coupling groove is formed on the inner wall of the perforation. The outer peripheral surface of the ninth cam piece corresponds to the ninth joint groove, and the ninth descending section, the ninth retarded section, and one of the ninth rises are sequentially formed every 90 degrees clockwise. And the ninth lifting section; the tenth cam piece has a tenth coupling groove, a tenth lifting section, two tenth rising section and a tenth descending section, and the tenth coupling groove is formed by depression On the inner wall surface of the perforation, the outer peripheral surface of the tenth cam piece corresponds to the tenth joint groove, and the clockwise direction is formed every ninety degrees. Ramp section, wherein lifting a tenth segment, and other segments of the tenth jacking tenth ramp down period. The webbing machine transmission device of claim 2, wherein the closing knife-bonding plate of the base set has a plurality of blind holes disposed at intervals, the blind hole recesses being formed on a side of the cutter-bonding plate facing the inside of the machine; The pivoting arm set has ten pivoting seats and ten closing rocker arms; the pivoting seat has at least one positioning post and an engaging bearing, and the positioning post is protruded and formed at one end of the pivoting seat, the positioning post And the end of the pivoting seat forming the positioning post is fixed to the closing knife binding plate, and the engaging bearing is mounted on the other end of the pivoting seat; The rocking arm members are respectively pivotally connected to the ten pivoting seats, and each has an engaging post and an abutting bearing, and the engaging post is protrudedly formed on one side of the closing blade rocker member, and the abutting bearing is mounted on the The blade rocker arm member is received by the top end of the cam piece, and the engaging column is mounted on the joint bearing, and the abutting bearing of the ten-way blade rocker arm member abuts against the ten cam piece; the heald frame group has ten The heald frame piece is respectively connected to the ten-way knife rocker arm piece. The webbing device of any one of claims 1 to 3, wherein the blade rocker member further has a fastening portion, the buckle portion being recessed at the other end of the blade rocker member, and Forming a through hole; the heald frame group further has a fixing seat disposed at an end of the heald frame group away from the machine base; the heald frame piece of the heald frame group further has a tie rod, a fixing block and a joint And a plurality of springs; the one end of the rod is fixed to one end of the heald frame, the fixing block is fixed to the rod, and the other end of the rod passes through the through hole of the fastening portion, and the fixing block abuts The inside of the fastening portion is formed at the other end of the heald frame piece, the one end of the spring is fixed to the joint portion, and the other end portion is fixed to the fixing seat. The webbing drive device of claim 4, wherein the machine further has an assembly hole formed through a side of the machine and communicating with the inside of the machine; the cam assembly is configured to pass the assembly The hole is mounted on the inside of the machine, and further has a sleeve, a plurality of spacers and two positioning blocks; the sleeve is sleeved on the outer wall surface of the cam shaft, and the plurality of cam pieces and the plurality of spacers are fixed The spacers are disposed on the outer wall surface of the sleeve, and each of the spacers is disposed between each of the two cam plates; the two positioning blocks are fixedly sleeved on the outer wall surface of the cam shaft, and each of the top portions abuts against the opposite side of the sleeve Two ends. The webbing mechanism of claim 5, wherein the camshaft further has a bearing set, an assembled bearing, a convex ring portion and a spacer ring; the bearing assembly is disposed on an outer wall surface of one end of the cam shaft. And the spacer ring is sleeved on the outer wall surface of the camshaft, and one end portion abuts against the bearing set; the assembled bearing is mounted on the outer wall surface of the camshaft And being disposed inside the mounting hole of the box body, the other end portion of the spacer ring abutting against the assembled bearing; the convex ring portion is formed in an annular shape and formed on the outer wall surface of the cam shaft, and is abutted against The assembled bearing. The webbing machine transmission device of claim 6, wherein the motor further has a transmission belt sleeved at an output end of the motor; the worm gear box transmission group further has a transmission wheel, the transmission wheel is fixedly mounted At one end of the spindle, the drive belt is sleeved on the drive wheel. The webbing mechanism of claim 7, wherein the base set further has a base, the bottom end of the machine is fixed to the base; the machine further has a flower plate axial fixed cover, the flower The plate axial fixing cover is mounted on the other side of the machine table, and corresponding to the assembly hole, the other end of the cam shaft is pivotally disposed on the flower plate axial fixed cover. The webbing mechanism of claim 8, wherein the heald frame group further has two cover plates, two auxiliary plates and a guide hole seat; the two cover plates are correspondingly disposed at two sides of the heald frame group, The second auxiliary plate is disposed at two sides of the heald frame group, and each of the plurality of longitudinal grooves is formed at a plurality of intervals; the guide hole seat is fixed to the top of the machine table, and the interval is penetrated A plurality of guide holes are formed, and the plurality of guide rods of the plurality of heald frame sheets are respectively disposed through the plurality of guide holes; the opposite ends of the joint portion of the heald frame sheets extend outwardly and are disposed through the longitudinal grooves of the two auxiliary plates. The webbing mechanism of any one of claims 1 to 3, wherein the heald frame group further has two guide plates; the two guide plates are disposed at two sides of the heald frame group, and each corresponding to the The second mounting plate has a plurality of spaced guiding grooves, and the guiding groove is formed through the guiding plate in parallel with the longitudinal direction of the guiding plate, and the extending portion of the heald frame passes through the guiding groove.