CN210025634U - Automatic weave boiling hot rattan machine - Google Patents

Abstract

The utility model discloses an automatic weave boiling hot rattan machine, include: a weaving device for weaving rattans into rattan sheets; and a rattan ironing device for forming a convex knot at the edge of the rattan sheet, wherein the rattan ironing device comprises: the frame comprises an upper die frame, a lower die frame and a first cylinder which is arranged on the lower die frame and used for supporting the upper die frame to move up and down; the transverse rattan scalding mechanism is arranged on one side of the frame and comprises transverse hot slices and a second cylinder which is arranged on the lower die frame and used for supporting the transverse hot slices to move up and down; and the longitudinal rattan scalding mechanism is arranged on two opposite sides of the frame and comprises longitudinal hot slices and a third cylinder which is arranged on the lower die frame and used for supporting the longitudinal hot slices to move up and down. An object of the utility model is to provide a compile rattan and scald integrative structure of rattan, rational in infrastructure, the operation links up to the rattan piece of production is convenient for install and fixed automatic weaving scalds the rattan machine.

Description

Automatic weave boiling hot rattan machine

Technical Field

The utility model relates to a field is woven to the rattan, especially relates to an automatic weave boiling hot rattan machine.

Background

At present, in order to increase the weaving speed and reduce the labor force of the existing rattan product, a machine plane weaving technology is introduced, the rattan product woven on the plane is installed and fixed to further form the rattan product, and the direction of effort is always in the industry. The utility model discloses a "rattan automatic braider" that publication number CN207256450 discloses, this utility model is at first prepared the rattan in vertical rattan feeding mechanism and the horizontal rattan feeding mechanism through the manual work, pass vertical rattan weaving mechanism and horizontal rattan weaving mechanism and place, through weaving control system after that, control vertical rattan weaving mechanism and horizontal rattan weaving mechanism's motion realizes that crisscross pattern is woven violently and vertically, weave into the rattan form after the rethread receipts weaving mechanism carries out the automatic rolling to the automated production that the rattan was woven. However, the utility model has no knot forming device, the formed rattan sheet structure is unstable, and the rattan sheet is not easy to install and fix. If the woven rattan slices are placed into the next production line to be processed and embossed, time and labor are consumed, and the production cost is high.

SUMMERY OF THE UTILITY MODEL

In order to overcome the defects of the prior art, the utility model aims to provide a rattan weaving and rattan ironing integrated structure, which has reasonable structure and coherent operation, and the rattan sheet produced is convenient to install and fix and is automatically woven and ironed.

The purpose of the utility model is realized by adopting the following technical scheme:

the utility model provides an automatic weave boiling hot rattan machine, include: a weaving device for weaving rattans into rattan sheets; and a rattan ironing device for forming a convex knot at the edge of the rattan sheet, wherein the rattan ironing device comprises: the frame comprises an upper die frame, a lower die frame and a first cylinder which is arranged on the lower die frame and used for supporting the upper die frame to move up and down; the transverse rattan scalding mechanism is arranged on one side of the frame and comprises a transverse hot slice and a second air cylinder which is arranged on the lower die carrier and used for supporting the transverse hot slice to move up and down; and the longitudinal rattan ironing mechanism is arranged on two opposite sides of the frame and comprises longitudinal hot slices and a third cylinder which is arranged on the lower die frame and used for supporting the longitudinal hot slices to move up and down. Weaving rattans into rattan sheets by a weaving device, starting a first cylinder to drive an upper die frame to ascend, and forming accommodating spaces of the rattan sheets between the upper die frame and a lower die frame; and then placing the rattan sheet in an accommodating space of the rattan scalding device, opening the second cylinder and the third cylinder, placing the transverse hot cut sheet at one side edge of the rattan sheet, placing the longitudinal hot cut sheet at two side edges of the rattan sheet, heating the edge of the rattan sheet, and further forming a convex knot at the edge of the rattan sheet, wherein the rattan sheet with the convex knot is convenient to install and fix when the rattan chair is manufactured.

Furthermore, the weaving device comprises a rack, a longitudinal rattan feeding structure arranged on the rack, a transverse rattan feeding mechanism, a longitudinal rattan weaving mechanism arranged on the rack, a transverse rattan weaving mechanism arranged on the rack, a folding mechanism arranged on the rack and a film covering mechanism, wherein the longitudinal rattan feeding structure is provided with a plurality of longitudinal rattan fixing devices; the transverse rattan feeding mechanism comprises a mounting frame, a rattan feeding component, a motor connected with the rattan feeding component and a guide component positioned on the mounting frame; the longitudinal rattan weaving mechanism comprises a plurality of telescopic sheets with through holes and a telescopic mechanism which drives the telescopic sheets to do front and back telescopic motion, and a plurality of longitudinal rattans passing through the longitudinal rattan fixing device penetrate through the through holes and then enter the transverse rattan weaving mechanism; the transverse rattan weaving mechanism comprises an upper pressing plate and a lower supporting plate, a transverse guide shuttle hole is defined by the upper pressing plate and the lower supporting plate, and the transverse guide shuttle hole is aligned with the transverse rattan feeding mechanism; the collecting and knitting mechanism comprises a driving device and a roller shaft connected with the driving device; the longitudinal rattan and the transverse rattan which passes through the transverse guiding shuttle-passing hole are woven together and are collected through the roll shaft of the collecting and weaving mechanism after being coated with films by the film coating mechanism.

Further, the guide assembly includes a base and a guide member connected to the base, the guide member having a guide hole receiving the transverse rattan; the rattan conveying component comprises a driving wheel connected with the motor and a bearing positioned on the base; the guide parts are positioned on two sides of a connecting line of the bearing and the driving wheel; the transverse rattan penetrates through the guide hole and a gap between the bearing and the driving wheel to enter the transverse rattan weaving mechanism.

Further, horizontal rattan feeding mechanism still including installing adjusting part on the mounting bracket, adjusting part is including establishing first guide rail on the mounting bracket, with first guide rail sliding connection's first slider, establish first pole on the mounting bracket, with the bearing is connected and with the second pole that first slider is fixed, first pole with be equipped with first elastic element between the second pole.

Further, vertical rattan fixing device includes the casing, establishes last gyro wheel and lower gyro wheel in the casing and establish casing top and be used for adjusting go up the adjusting nut that the gyro wheel reciprocated, wherein, the side of casing is equipped with waist shape hole, the pivot of going up the gyro wheel is located waist shape is downthehole.

Further, the driving device comprises a forward cylinder, a forward connecting rod connected with the forward cylinder, a pawl connected with the forward connecting rod, a forward gear connected with the roller shaft and abutted against the pawl, and a limiting assembly accommodating the forward connecting rod, wherein the pawl is abutted against the forward gear and drives the forward gear to rotate.

Further, the longitudinal rattan ironing mechanism further comprises an aligning part connected with the longitudinal hot section and the third cylinder. And opening the third cylinder to drive the aligning part to ascend and align the accommodating space formed between the upper die frame and the lower die frame, so that the rattan sheets are protected from being exposed outside the equipment when being put into the accommodating space.

Further, the transverse rattan scalding mechanism is arranged on one side of an inlet of the rattan scalding device. When the vine piece is getting into the rattan scalding device, the front end of vine piece forms the bulge under horizontal hot sliced effect, and the vine piece continues to move forward, and when the accommodation space was arranged in completely to the vine piece, horizontal hot sliced back end to the vine piece heated, and then formed the bulge.

Further, the transverse rattan weaving mechanism further comprises a wedge-shaped structure, a second guide rail which is connected with the lower supporting plate in an abutting mode and a second sliding block which is connected with the second guide rail in a sliding mode and connected with the upper pressing plate.

Furthermore, the transverse rattan weaving mechanism further comprises a second elastic element used for driving the lower supporting plate to move back and forth, one end of the second elastic element is connected with the lower supporting plate, and the other end of the second elastic element is connected with the rack.

Compared with the prior art, the beneficial effects of the utility model reside in that:

the utility model weaves the rattan into rattan sheets through the weaving device, then opens the first cylinder to drive the upper die frame to rise, and forms the containing space of the rattan sheets between the upper die frame and the lower die frame; opening a third cylinder to drive the aligning part to ascend and align with an accommodating space formed between the upper die frame and the lower die frame, so that the rattan sheets are protected from being exposed outside the equipment when being placed into the accommodating space; when the holding space is arranged in completely to the rattan piece, open the second cylinder, shift in one side edge of rattan piece on the horizontal hot section, close the third cylinder and drive alignment portion and vertical hot section and move down, vertical hot section is located the both sides edge of rattan piece, heats the edge of rattan piece, and then forms the bulge at the edge of rattan piece, adopts to compile rattan and scald rattan integrative, once only forms the bulge, and is convenient simple, labour saving and time saving.

Drawings

Fig. 1 is a perspective view of the automatic rattan plaiting and scalding machine of the present invention;

fig. 2 is a side view of the automatic rattan plaiting and scalding machine of the present invention;

fig. 3 is a perspective view of the rattan scalding device of the present invention;

fig. 4 is a schematic structural view of the longitudinal rattan fixing device of the present invention;

fig. 5 is a schematic structural view of the transverse rattan feeding structure of the present invention;

fig. 6 is a schematic structural view of the transverse rattan weaving mechanism of the present invention;

in the figure: 100. a knitting device; 101. a frame; 110. a longitudinal rattan feeding structure; 111. a longitudinal rattan fixing device; 112. a housing; 113. adjusting the nut; 114. a waist-shaped hole; 120. a transverse rattan feeding mechanism; 121. a mounting frame; 122. a vine feeding component; 1221. a driving wheel; 1222. a bearing; 123. a motor; 124. a guide assembly; 1241. a base; 1242. a guide member; 1243. a guide hole; 125. an adjustment assembly; 1251. a first guide rail; 1252. a first slider; 1253. a first lever; 1254. a second lever; 1255. a first elastic element; 130. a longitudinal rattan weaving mechanism; 131. a through hole; 132. a stretchable sheet; 133. a telescoping mechanism; 140. a transverse rattan weaving mechanism; 141. an upper pressure plate; 142. a lower supporting plate; 143. a transverse guide shuttle hole; 144. a cylinder; 145 wedge-shaped structures; 146. a second guide rail; 147. a second slider; 148. a second elastic element; 150. a collecting and knitting mechanism; 151. a drive device; 1511. a forward cylinder; 1512. an advancing link; 1513. a pawl; 1514. a forward gear; 1515. a limiting component; 1516. a first accommodating groove; 1517. a second accommodating groove; 152. a roll shaft; 160. a film covering mechanism; 200. a rattan scalding device; 210. a frame; 211. feeding a mold frame; 212. a lower die frame; 213. a first cylinder; 220. a transverse rattan scalding mechanism; 221. transversely thermally slicing; 222. a second cylinder; 230. a longitudinal rattan scalding mechanism; 231. longitudinally hot slicing; 232. a third cylinder; 233. an alignment portion.

Detailed Description

The present invention will be further described with reference to the accompanying drawings and the detailed description, and it should be noted that the embodiments or technical features described below can be arbitrarily combined to form a new embodiment without conflict.

The utility model provides an automatic weave boiling hot rattan machine, refer to fig. 1, fig. 2 and fig. 3, this automatic weave boiling hot rattan machine including be used for weaving into the rattan weaving device 100 of rattan piece and be used for the boiling hot rattan device 200 of knot at the edge formation of rattan piece. The rattan scalding device 200 comprises a frame 210, a transverse rattan scalding mechanism 220 arranged on one side of the frame 210, and longitudinal rattan scalding mechanisms 230 arranged on two opposite sides of the frame 210. The frame 210 includes an upper mold frame 211, a lower mold frame 212, and a first cylinder 213 disposed on the lower mold frame 212 for supporting the upper mold frame 211 to move up and down, and the first cylinder 213 drives the upper mold frame 211 to ascend so that an accommodating space for accommodating the rattan sheets is formed between the upper mold frame 211 and the lower mold frame 212.

Referring to fig. 3, the transverse rattan scalding mechanism 220 includes a transverse hot section 221 and a second cylinder 222 disposed on the lower mold frame 212 and used for supporting the transverse hot section 221 to move up and down, and the second cylinder 222 drives the transverse hot section 221 to move up and down to heat the rattan to form a knot. Further, the transverse rattan scalding mechanism 220 is disposed at an inlet side of the rattan scalding device 200. When the vine slices enter the vine scalding device 200, the front ends of the vine slices form convex knots under the action of the transverse hot cutting pieces 221, the vine slices move forwards continuously, and when the vine slices are completely placed in the containing space, the transverse hot cutting pieces 221 heat the rear ends of the vine slices, so that the convex knots are formed.

The longitudinal rattan scalding mechanism 230 includes a longitudinal hot-cut piece 231 and a third cylinder 232 disposed on the lower mold frame and supporting the longitudinal hot-cut piece 231 to move up and down. Further, the longitudinal rattan ironing mechanism 230 further includes an aligning part 233 connected to the longitudinal hot-cut piece 231 and the third cylinder 232. Opening the third cylinder 232 to drive the aligning part 233 to rise to align with the accommodating space formed between the upper mold frame 211 and the lower mold frame 212, so that the rattan sheets are protected from being exposed outside the device when being put into the accommodating space. When the vine chips are completely placed in the receiving space between the upper mold frame 211 and the lower mold frame 212, the third cylinder 232 is turned off, the aligning part 233 and the longitudinal hot-cut chips 231 move down, and the longitudinal hot-cut chips 231 are located at both sides of the vine chips. Turning on the power supply device of the longitudinal hot slice 231, the hot slice starts to generate heat, the hot slice generates heat to form a high temperature of 1500 ℃, the vine slices start to shrink (shrink for about 2min) to form a convex knot, turning off the power supply device after the vine slices shrink, and the hot slice starts to cool.

The utility model weaves the rattan into rattan sheets through the weaving device, and then opens the first cylinder 213 to drive the upper die frame 211 to rise, and a holding space for the rattan sheets is formed between the upper die frame 211 and the lower die frame 212; opening the third cylinder 232 to drive the aligning part 233 to ascend and align with the accommodating space formed between the upper die frame 211 and the lower die frame 212, so that the rattan sheets are protected from being exposed outside the equipment when being put into the accommodating space; when the rattan sheet is completely placed in the accommodating space, the first cylinder 213 is closed, the upper mold frame 211 descends, and the rattan sheet is compressed; the second cylinder 222 is opened, the transverse hot cut piece 221 moves upwards to be located at one side edge of the rattan piece, the third cylinder 232 is closed to drive the alignment part 233 and the longitudinal hot cut piece 231 to move downwards, and the longitudinal hot cut piece 231 is located at two side edges of the rattan piece. Turning on power supply devices of the longitudinal hot slices 231 and the transverse hot slices 221, starting heating of the hot slices, heating of the hot slices to form a high temperature of 1500 ℃, heating the edges of the vine slices, starting contraction of the vine slices after heating (contraction for about 2min) to form convex knots at the edges of the vine slices, turning off the power supply devices after the vine slices are contracted, and starting cooling of the hot slices. And (3) opening a fan to cool for about 1min, then opening the first cylinder 213 to drive the upper die carrier 211 to ascend, closing the second cylinder 222, descending the transverse hot cut piece 221, and taking out the processed rattan piece. The rattan weaving and rattan ironing are integrated, so that the protruding knots are formed at one time, and the rattan ironing machine is convenient and simple.

According to the embodiment of the present invention, referring to fig. 1 and 2, weaving device 100 includes a frame 101, a vertical rattan feeding structure 110 arranged in the frame, a horizontal rattan feeding mechanism 120, a vertical rattan weaving mechanism 130 arranged in the frame, a horizontal rattan weaving mechanism 140 arranged in the frame, a folding weaving mechanism 150 arranged in the frame, and a film coating mechanism 160, it should be understood that vertical rattan feeding structure 110, the vertical rattan weaving mechanism 130, the horizontal rattan weaving mechanism 140, and the folding weaving mechanism 150 are arranged from top to bottom along the frame, and the horizontal rattan feeding mechanism 120 is located at the side of the horizontal rattan weaving mechanism 140.

Referring to fig. 4, the longitudinal rattan feeding structure 110 has a plurality of longitudinal rattan fixing devices 111, and each longitudinal rattan fixing device 111 includes a housing 112, an upper roller and a lower roller disposed in the housing 112, and an adjusting nut 113 disposed above the housing 112 and used for adjusting the upper roller to move up and down, wherein a waist-shaped hole 114 is disposed on a side surface of the housing 112, and a rotating shaft of the upper roller is disposed in the waist-shaped hole 114. The gap is reserved between the upper roller and the lower roller, the longitudinal rattan penetrates through the gap between the upper roller and the lower roller to enter the longitudinal rattan weaving mechanism, the upper roller is enabled to move up and down along the waist-shaped hole 114 through the adjusting nut 113, the distance between the upper roller and the lower roller is adjusted, and then the tightness of the longitudinal rattan is adjusted.

Referring to fig. 1 and 2, the longitudinal rattan weaving mechanism 130 includes a plurality of telescopic pieces 132 having through holes 131, and a telescopic mechanism 133 driving the telescopic pieces 132 to perform a front-back telescopic motion, and a plurality of longitudinal rattans passing through the longitudinal rattan fixing device 111 pass through the through holes 131 and enter the transverse rattan weaving mechanism 140. The telescopic pieces 132 are divided into an upper group and a lower group, the through holes of the upper group and the lower group are staggered in front and back positions, the telescopic mechanisms respectively drive the telescopic pieces to perform telescopic motion so as to perform longitudinal rattan weaving, and it should be understood that the telescopic mechanism 133 is an air cylinder; the stretch panels 132 may also be arranged in multiple groups above one another to accommodate different types of weaving patterns.

Referring to fig. 5, the transverse rattan feeding mechanism 120 includes a mounting frame 121, a rattan feeding unit 122, a motor 123 connected to the rattan feeding unit 122, and a guide unit 124 provided on the mounting frame 121. Wherein the guide assembly 124 comprises a base 1241 and a guide 1242 connected to the base 1241, the guide 1242 having a guide hole 1243 for receiving a transverse rattan; the vine feeding assembly 122 comprises a driving wheel 1221 connected with the motor 123 and a bearing 1222 positioned on the base 1241, and the driving wheel 1221 rotates to drive the bearing 1222 to rotate; the guide 1242 is located at both sides of a line connecting the bearing 1222 and the driving wheel 1221, that is, the guide 1242 includes two portions distributed at both sides of the line connecting the bearing 1222 and the driving wheel 1221, and the guide 1242 at both sides has a curved surface engaged with the bearing 1222 and the driving wheel 1221; the transverse rattan passes through the guide hole 1243 of one side and the gap between the bearing 1222 and the driving wheel 1221, and then passes through the guide hole 1243 of the other side to enter the transverse rattan weaving mechanism 140.

It should be understood that the transverse rattan feeding mechanism 120 may include two sets of rattan feeding units, two motors, two guiding units, and two sets of guiding units arranged in parallel, so as to achieve a mixed weaving. Of course, the transverse rattan feeding mechanism can also comprise a plurality of groups of the above-mentioned devices to realize mixed weaving.

It should be understood that motor 123 rotates driving wheel 1221, and friction is generated between driving wheel 1221 and the transverse rattan to drive the transverse rattan forward, and friction is generated between the transverse rattan and bearing 1222 to drive bearing 1222 to rotate. The relative rotation between the bearing 1222 and the transverse rattan reduces the wear of the transverse rattan.

Further, referring to fig. 5, the transverse rattan feeding mechanism 120 further includes an adjusting assembly 125 mounted on the mounting frame 121, the adjusting assembly 125 includes a first guide rail 1251 provided on the mounting frame 121, a first slider 1252 slidably connected to the first guide rail 1251, a first rod 1253 provided on the mounting frame 121, a second rod 1254 connected to the bearing 1222 and fixed to the first slider 1252, and a first elastic member 1255 is provided between the first rod 1253 and the second rod 1254. That is, the bearing 1222 is connected to the second rod 1254, the second rod 1254 is fixed to the first slider 1252, and the distance between the first rod 1253 and the second rod 1254, and thus the distance between the bearing 1222 and the driver 1221, i.e. the clamping force of the bearing 1222 and the driver 1221 against the transverse rattan, is adjusted by the pre-load force of the first elastic element 1255.

Referring to fig. 2 and 6, the transverse rattan weaving mechanism 140 includes an upper press plate 141, a lower support plate 142, a transverse guide shuttle hole 143 defined between the upper press plate 141 and the lower support plate 142, the transverse guide shuttle hole 143 being aligned with a guide hole 1243 of the transverse rattan feeding mechanism 120, and a transverse rattan coming out of the guide hole 1243 into the transverse guide shuttle hole 143. It should be understood that the transverse rattan weaving mechanism 140 further includes an air cylinder 144 connected to the upper press plate 141 to drive the upper press plate 141 to move up and down; a rattan cutting device is further arranged between the upper pressing plate 141 and the transverse feeding mechanism 120, the longitudinal rattan weaving mechanism 130 staggers two adjacent longitudinal rattans back and forth through the through holes 131 which stagger back and forth, the transverse guiding shuttle holes 143 just face to the positions between the longitudinal rattans which stagger back and forth, the driving wheel 1221 drives the transverse rattans to shuttle in the transverse guiding shuttle holes 143, and when the transverse rattans reach the set length, the cutting device cuts off the transverse rattans.

Further, referring to fig. 6, the transverse rattan weaving mechanism 140 further includes a wedge structure 145, a second guide rail 146 abutting against the wedge structure 145 and connected to the lower supporting plate 142, a second slider 147 slidably connected to the second guide rail 146 and connected to the upper press plate 141, and a second elastic member 148 for driving the lower supporting plate 142 to move forward and backward, one end of the second elastic member 148 is connected to the lower supporting plate 142, and the other end of the second elastic member 148 is connected to the frame 101. The air cylinder 144 drives the upper pressing plate 141 to move downwards, the upper pressing plate 141 presses the lower supporting plate 142 to move downwards, the lower supporting plate 142 presses the second guide rail 146 to move backwards under the action of the second elastic element 148, the wedge-shaped structure 145 is wide at the upper end and narrow at the lower end, the rear end of the second guide rail 146 slides backwards along the wedge-shaped structure 145 and drives the lower supporting plate 142 to move backwards, at the moment, the bottom of the transverse guide shuttle-passing hole 143 between the upper pressing plate 141 and the lower supporting plate 142 is opened, and the transverse rattans fall into the weaving area and are tightly woven with the longitudinal rattans.

Referring to fig. 1, the retracting mechanism 150 includes a driving device 151 and a roller 152 connected to the driving device 151, the driving device 151 includes an advancing cylinder 1511, an advancing link 1512 connected to the advancing cylinder 1511, a pawl 1513 connected to the advancing link 1512, an advancing gear 1514 abutting against the pawl 1513 and connected to the roller 152, and a limit component 1515 accommodating the advancing link 1512, and the pawl 1513 abuts against the advancing gear 1514 and drives the advancing gear 1514 to rotate. The forward cylinder 1511 drives the forward link 1512 to move forward, the forward link 1512 pulls the pawl 1513 to move backward, and the pawl 1513 pulls the forward gear 1514 to rotate while moving backward.

It should be understood that the driving device 151 includes a limiting assembly 1515 disposed on the frame, the limiting assembly 1515 includes a first receiving groove 1516 and a second receiving groove 1517; one end of the forward link 1512 connected with the forward cylinder 1511 is accommodated in the first accommodating groove 1516 and slides in the first accommodating groove 1516, one end of the forward link 1512 connected with the pawl 1513 is accommodated in the second accommodating groove 1517 and slides relative to the second accommodating groove 1517, when the forward link 1512 is driven by the forward cylinder 1511 to move forward, the forward link 1512 moves at one end side wall of the first accommodating groove 1516 and abuts against the other end side wall of the first accommodating groove 1516, the forward link 1512 slides obliquely downward in the second accommodating groove 1517 and pulls the pawl 1513 to move backward, thereby driving the forward gear 1514 to rotate. The advancing gear 1514 drives the roller shaft 152 to rotate, meanwhile, a film (such as a PE film) on the film covering mechanism 160 covers the rattan sheets, the film is pressed by the roller shaft to strengthen the combination with the rattan sheets, and finally, the rattan sheets which are covered with the film are collected by the collecting and weaving mechanism.

The above embodiments are only preferred embodiments of the present invention, and the protection scope of the present invention cannot be limited thereby, and any insubstantial changes and substitutions made by those skilled in the art based on the present invention are all within the protection scope of the present invention.

Claims (10)

1. An automatic weaving rattan ironing machine, characterized by comprising:

a weaving device for weaving rattans into rattan sheets; and

a rattan ironing device for forming a knot at an edge of the rattan sheet, wherein the rattan ironing device comprises:

the frame comprises an upper die frame, a lower die frame and a first cylinder which is arranged on the lower die frame and used for supporting the upper die frame to move up and down;

the transverse rattan scalding mechanism is arranged on one side of the frame and comprises a transverse hot slice and a second air cylinder which is arranged on the lower die carrier and used for supporting the transverse hot slice to move up and down; and

vertically scald rattan mechanism, vertically scald rattan mechanism and set up the relative both sides of frame, vertically scald rattan mechanism and include that it is in to indulge to scald the hot section and set up down on the die carrier and be used for supporting the third cylinder of vertical hot section up-and-down motion.

2. The automatic rattan weaving and ironing machine according to claim 1, wherein the weaving device includes a frame, a longitudinal rattan feeding mechanism provided on the frame, a lateral rattan feeding mechanism, a longitudinal rattan weaving mechanism provided on the frame, a lateral rattan weaving mechanism provided on the frame, a collecting mechanism provided on the frame, and a film covering mechanism, wherein,

the longitudinal rattan feeding structure is provided with a plurality of longitudinal rattan fixing devices;

the transverse rattan feeding mechanism comprises a mounting frame, a rattan feeding component, a motor connected with the rattan feeding component and a guide component positioned on the mounting frame;

the longitudinal rattan weaving mechanism comprises a plurality of telescopic sheets with through holes and a telescopic mechanism which drives the telescopic sheets to do front and back telescopic motion, and a plurality of longitudinal rattans passing through the longitudinal rattan fixing device penetrate through the through holes and then enter the transverse rattan weaving mechanism;

the transverse rattan weaving mechanism comprises an upper pressing plate and a lower supporting plate, a transverse guide shuttle hole is defined by the upper pressing plate and the lower supporting plate, and the transverse guide shuttle hole is aligned with the transverse rattan feeding mechanism;

the collecting and knitting mechanism comprises a driving device and a roller shaft connected with the driving device; the longitudinal rattan and the transverse rattan which passes through the transverse guiding shuttle-passing hole are woven together and are collected through the roll shaft of the collecting and weaving mechanism after being coated with films by the film coating mechanism.

3. The automatic rattan weaving and ironing machine according to claim 2, characterized in that the guide assembly comprises a base and a guide connected to the base, the guide having a guide hole for receiving the transverse rattan; the rattan conveying component comprises a driving wheel connected with the motor and a bearing positioned on the base; the guide parts are positioned on two sides of a connecting line of the bearing and the driving wheel; the transverse rattan penetrates through the guide hole and a gap between the bearing and the driving wheel to enter the transverse rattan weaving mechanism.

4. The automatic rattan ironing machine according to claim 3, characterized in that the transverse rattan feeding mechanism further comprises an adjusting assembly mounted on the mounting frame, the adjusting assembly comprising a first guide rail provided on the mounting frame, a first slider slidably connected to the first guide rail, a first rod provided on the mounting frame, a second rod connected to the bearing and fixed to the first slider, and a first elastic element provided between the first rod and the second rod.

5. The automatic rattan weaving and ironing machine according to claim 2, wherein the longitudinal rattan fixing device comprises a housing, an upper roller and a lower roller which are arranged in the housing, and an adjusting nut which is arranged above the housing and is used for adjusting the upper roller to move up and down, wherein a waist-shaped hole is formed in the side surface of the housing, and a rotating shaft of the upper roller is located in the waist-shaped hole.

6. The automatic rattan ironing machine according to claim 2, characterized in that the drive means comprises an advancing cylinder, an advancing link connected to the advancing cylinder, a pawl connected to the advancing link, an advancing gear abutting against the pawl and connected to the roller shaft, and a limit assembly accommodating the advancing link, the pawl abutting against the advancing gear and driving the advancing gear to rotate.

7. The automatic rattan ironing machine according to claim 1, wherein the longitudinal rattan ironing mechanism further includes an alignment portion connected to the longitudinal thermal section and the third cylinder.

8. The automatic rattan ironing machine according to claim 1, wherein the transverse rattan ironing mechanism is provided on the inlet side of the rattan ironing device.

9. The automatic rattan ironing machine according to claim 2, characterized in that the transverse rattan weaving mechanism further comprises a wedge structure, a second guide rail abutting against the wedge structure and connected with the lower supporting plate, and a second slider slidably connected with the second guide rail and connected with the upper press plate.

10. The automatic rattan weaving and ironing machine according to claim 9, wherein the transverse rattan weaving mechanism further includes a second elastic member for driving the lower support plate to move forward and backward, one end of the second elastic member is connected to the lower support plate, and the other end of the second elastic member is connected to the frame.

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