CN215366293U - Ironing and embroidering integrated machine - Google Patents

Abstract

The application relates to an ironing and embroidering all-in-one machine, which comprises a rack, and a workbench, an embroidering mechanism, an ironing mechanism and a driving mechanism which are arranged on the rack, wherein the embroidering mechanism and the ironing mechanism are the same in quantity and are at least provided with one, the embroidering mechanism and the ironing mechanism are alternately arranged along the length direction of the rack at intervals, and the driving mechanism is respectively connected with the embroidering mechanism and the ironing mechanism and is used for driving the embroidering mechanism and the ironing mechanism to work. This application embroidery processing can directly utilize the piece mechanism that scalds to scald the piece processing after accomplishing, has reduced and has embroidered the back and take off the surface fabric from the embroidery machine, installs the trouble on scalding the piece machine again, has reduced the trouble of middle reinstallation surface fabric, can utilize immediately after the embroidery mechanism processing is accomplished to scald the piece with the piece mechanism that scalds, has reduced the time of stopping down, has promoted holistic machining efficiency greatly.

Description

Ironing and embroidering integrated machine

Technical Field

The application relates to the field of fabric embroidery and ironing processing, in particular to an ironing and embroidering all-in-one machine.

Background

Embroidery and ironing are common fabric post-processing technologies, and the fabric with exquisite patterns and rich colors can be obtained through embroidery and ironing.

Chinese patent publication No. CN112109429A discloses a sheet ironing machine, which comprises a frame and a working platform mounted on the frame, wherein the frame is provided with: at least one head driving mechanism, at least one piece ironing mechanism and at least one wafer support. The ultrasonic head is adopted to carry out the sheet ironing operation, namely, the cloth and the ironing sheet are placed between the ultrasonic head and the punch, then the punch is controlled to carry out stamping, the ironing sheet is attached to the ironing sheet and pressed on a stamping plane of the ultrasonic head, the ironing sheet is welded on the cloth by the operation of the ultrasonic head in the process, so that the subsequent transfer printing process can be saved, the production efficiency is improved,

in actual production, embroidery needs to be processed by an embroidery machine, and the hot plate needs to be processed by a hot plate machine. When embroidering, the fabric is placed on an embroidering table of an embroidering machine, the edge of the fabric is fixed, the fabric is tensioned, and then the fabric is embroidered through an embroidering machine head to form an embroidery pattern; when the piece is ironed, the fabric needs to be placed on the piece ironing machine, the edge of the fabric is fixed, the fabric is tensioned, and then the piece is ironed. The embroidery and the piece ironing work are carried out on different devices, the fixed tensioning work of the fabric is repeated, the workload is large, and the efficiency is low.

SUMMERY OF THE UTILITY MODEL

In order to improve the processing efficiency of fabric embroidery and ironing, the application provides an ironing and embroidering all-in-one machine.

The application provides a pair of ironing and embroidering all-in-one machine adopts following technical scheme:

the embroidery integrated machine comprises a rack, and a workbench, an embroidery mechanism, a piece ironing mechanism and a driving mechanism which are arranged on the rack, wherein the embroidery mechanism and the piece ironing mechanism are the same in quantity and at least one piece ironing mechanism is arranged, the embroidery mechanism and the piece ironing mechanism are alternately arranged at intervals along the length direction of the rack, and the driving mechanism is respectively connected with the embroidery mechanism and the piece ironing mechanism and used for driving the embroidery mechanism and the piece ironing mechanism to work.

Through adopting above-mentioned technical scheme, will scald piece mechanism and embroidery mechanism and install together, can directly utilize to scald piece mechanism and scald piece processing after embroidery processing is accomplished, take off the surface fabric from the embroidery machine after having reduced the embroidery, install the trouble on scalding the piece machine again, the trouble of installing the surface fabric again in the middle of having reduced, can utilize immediately after embroidery mechanism processing is accomplished to scald the piece by scalding piece mechanism, the time of having reduced the outage, the holistic machining efficiency has been promoted greatly, in addition, can also save a large amount of workshop spaces.

Optionally, the ironing mechanism and the embroidering mechanism are both located on the same side of the frame.

By adopting the technical scheme, the embroidery and the switching of the piece ironing work can be conveniently carried out, the fabric only needs to be moved during the switching, the piece ironing mechanism only needs to be moved below the embroidery pattern of the fabric for processing the piece ironing on the embroidery pattern, the moving amount of the workbench is reduced, and the embroidery pattern ironing machine is more energy-saving and efficient.

Optionally, it includes the ultrasonic head, is provided with the punching press aircraft nose and the wafer support of drift to scald piece mechanism, the ultrasonic head sets up in the frame and is located the workstation below, the punching press aircraft nose sets up in the frame and is located the top of workstation, the punching press hole has been seted up on the workstation, thereby actuating mechanism is connected with the drift of punching press aircraft nose and is driven the drift and carry out punching press work.

Through adopting above-mentioned technical scheme, on placing the wafer support with the wafer dish that the rolling has the material area, then pull out the material area and send into the punching press aircraft nose, the punching press is carried out to the first drift of punching press under the actuating mechanism drive, scalds the piece in this in-process material area and is driven to push down and place the surface fabric on work platform on, and ultrasonic head and drift realize being connected between them with the surface fabric and scalding the piece pressfitting this moment.

Optionally, a plurality of first wafer disks distributed along the length direction of the rack are arranged on the wafer support, the wafer support is arranged on the rack in a sliding manner along the length direction of the rack, and a color changing driving part for driving the wafer support to move is arranged between the wafer support and the rack.

Through adopting above-mentioned technical scheme, during the use, utilize and trade the look driving piece and drive the removal of wafer support, when the wafer support removed, first wafer dish removed for the punching press aircraft nose to switch the material area that corresponds with the punching press aircraft nose, can realize the trade look and the function of reloading of scalding the piece.

Optionally, the frame is provided with a rolling mechanism, the rolling mechanism comprises a material collecting frame slidably mounted on the frame, a wafer sliding plate fixed on the frame, a rolling driving member and a roll changing driving member, the material receiving frame is arranged on the rack in a sliding manner along the length direction of the rack, the reel changing driving piece is arranged on the rack and connected with the material receiving frame for driving the material receiving frame and the wafer support to synchronously slide, the material receiving frame is rotatably provided with second wafer disks which are the same as the first wafer disks in number and are distributed along the length direction of the machine frame, the wafer sliding plate is arranged on the frame and is positioned below the second wafer disc, the wafer sliding plate is provided with a material selecting groove for only one second wafer disc to enter, two ends of the material selecting groove are provided with guide inclined planes, the rolling driving part is arranged on the rack and is used for driving the second wafer disc positioned in the material selecting groove to rotate.

By adopting the technical scheme, the waste material belt after stamping and ironing the piece needs to be recycled, so that the influence of the waste material belt on the ironing and embroidering work is reduced, and the waste material belt is wound by the winding mechanism; when the waste material is wound, the end part of the waste material belt is connected to a second wafer disc on the material receiving frame, the second wafer disc corresponds to the first wafer disc one by one, the roll changing driving piece drives the material receiving frame to synchronously slide with the wafer support, so that when the first wafer disc scalds the wafer, the second wafer disc corresponding to the first wafer disc is positioned in the material selecting groove, the winding driving piece can drive the second wafer disc of the material selecting groove to rotate, other second wafer discs do not rotate, and the waste material belt is wound when the second wafer disc rotates, so that the waste material is collected and wound; when the color is changed, the roll changing driving part drives the material receiving frame and the wafer support to synchronously slide, the front second wafer disc moves out of the material selecting groove through the guide inclined plane, and the new second wafer disc moves into the material selecting groove to realize the collection and the winding of waste materials.

Optionally, the winding driving part includes a winding motor and a driving roller, the material receiving frame is provided with placing grooves, the number of the placing grooves is the same as that of the second wafer discs, the placing grooves are used for placing the second wafer discs, the placing grooves penetrate through the material receiving frame, the driving roller is rotatably mounted on the material receiving frame and located below the placing grooves, and the winding motor is arranged on the material receiving frame and connected with the supporting driving roller; when the second wafer disk is abutted against the wafer sliding plate, the second wafer disk is separated from the driving roller; when the second wafer disk is positioned in the material selecting groove, the second wafer disk is abutted against the driving roller.

By adopting the technical scheme, the driving roller is driven to rotate by the winding motor, when the second wafer disc is positioned in the material selecting groove, the second wafer disc is abutted against the driving roller, and the driving roller drives the second wafer disc to rotate for winding; the other second wafer discs are positioned outside the material selecting groove and are separated from the driving roller, so that the other second wafer discs do not rotate and are not wound; the function that only the second wafer disc in the material selecting groove is driven by the rolling driving part is achieved through the matching of the rolling motor and the driving roller, and the device is simple in structure, convenient to use and good in effect.

Optionally, the winding mechanism further comprises a connecting plate, the connecting plate slides along the length direction of the rack and is arranged on the rack, the material collecting frame is arranged on the connecting plate, and the reel changing driving piece is sequentially connected with the connecting plate along the length direction of the rack so as to drive the material collecting frame and the wafer support to synchronously slide.

Through adopting above-mentioned technical scheme, the roll change driving piece drives the connecting plate and slides in frame length direction, and the work of colour drive piece is traded in the cooperation, makes the roll change driving piece and the work of trading the colour drive piece synchronous, can make when the scald piece trades the colour, receives the material frame and can synchronous motion, with the second wafer dish immigration that corresponds selecting material trench position, realizes the switching of rolling work.

Optionally, trade the look driving piece including trading the look axle and trading the look cylinder, trade the look cylinder and set up in the one end of frame horizontally, trade the setting of look axle level and connect gradually the wafer support, trade the piston rod of look cylinder and trade the look hub connection, trade a roll driving piece including trading a roll cylinder and trading the spool, trade the spool and trade the parallel and connection plate in proper order of look axle, trade a roll cylinder and set up in the frame and be used for driving to trade the spool and remove along frame length direction, trade a roll cylinder and trade look cylinder synchronous telescope.

By adopting the technical scheme, when the stamping machine is used, the piston rod of the color changing cylinder stretches and retracts to drive the color changing shaft to move, so that the material belt corresponding to the punch head of the stamping machine head is changed, and color changing or material changing of the material belt is realized; when changing color or changing material, the roll changing cylinder and the color changing cylinder synchronously act to ensure that the roll changing shaft moves, the corresponding second wafer disk is synchronously changed to enter the material selecting groove, and the color changing driving part and the roll changing driving part have simple structures and good control effect.

Optionally, the material receiving frame is provided with a material receiving assembly for conveying the material belt to the second wafer disc, the material receiving assembly comprises a material receiving roller mounted on the connecting plate, a material receiving driving member for driving the material receiving roller to rotate, a pressing wheel for abutting against the material receiving roller, and a pressing cylinder fixedly mounted on the frame, and the pressing wheel is arranged on a piston rod of the pressing cylinder.

Through adopting above-mentioned technical scheme, it stimulates the material area to set up the receipts material subassembly, and the piston rod that compresses tightly the cylinder through control stretches out for the pinch roller is with the material area pressure on receiving the material roller, receives the material roller this moment and rotates under receiving the material driving piece drive, makes to receive the material roller and can drive the material area and carry, thereby compensaties the problem that the drive roller conflict mode drives second wafer dish pivoted pulling force is not enough, reduces and appears unable completion receipts material or receive the not good problem of material effect.

Optionally, the head pitch of the embroidery mechanism is the same as the head pitch of the ironing mechanism.

By adopting the technical scheme, a plurality of same patterns can be processed simultaneously, and the distances among the patterns are the same, so that continuous embroidering and piece ironing of the fabric are facilitated.

In summary, the present application includes at least one of the following beneficial technical effects:

1. the embroidery mechanism and the piece ironing mechanism are alternately arranged on the same frame at intervals to form an embroidery and piece ironing integrated machine, when the embroidery and piece ironing integrated machine is used, the embroidery and the piece ironing are not required to be respectively carried out on two machines, the work of fixing and taking down the fabric for many times is reduced, the downtime is reduced, the efficiency is improved, and the space is also saved;

2. when the sheet is scalded, the material belts with different colors or materials can be replaced according to the needs, and when the sheet is replaced, the piston rod of the color changing cylinder drives the color changing shaft to move, so that the material belt corresponding to the punch is changed, and the switching is realized;

3. when the material area switches, drive through the cylinder of changing a roll and change the spool and remove to the second wafer dish immigration that corresponds with the material area that is using trades the material trench position, makes this second wafer dish and drive roller contact, rotates under the drive of drive roller, carries out the rolling in waste material area.

Drawings

FIG. 1 is a schematic structural diagram of an integrated machine for ironing and embroidering according to an embodiment of the present application.

FIG. 2 is a schematic structural diagram of the back of an integrated machine for ironing and embroidering according to an embodiment of the present application.

Fig. 3 is an enlarged view of a in fig. 1.

FIG. 4 is a schematic structural diagram of a piece ironing mechanism of a piece ironing and embroidering all-in-one machine according to an embodiment of the present application.

FIG. 5 is a sectional view of an ironing mechanism of an ironing and embroidering all-in-one machine according to an embodiment of the present application.

Fig. 6 is an enlarged view at B in fig. 5.

FIG. 7 is a front view of a winding mechanism of the integrated machine for ironing and embroidering according to the embodiment of the present application.

FIG. 8 is a schematic structural diagram of a winding mechanism of an integrated machine for ironing and embroidering according to an embodiment of the present application.

Description of reference numerals: 1. a frame; 11. a girder; 12. a work table; 121. punching a hole; 2. an embroidering mechanism; 3. a sheet ironing mechanism; 31. an ultrasonic head; 32. punching a machine head; 321. a punch; 322. a guide seat; 323. punching a bottom plate; 3231. a through hole; 3232. punching a die hole; 324. a guide hole; 325. color changing ball rows; 326. the material is provided with a hole; 327. a drive shaft; 328. a tool cap; 329. a return spring; 33. a wafer support; 34. a housing; 35. mounting a plate; 36. a color changing ball guide rail; 4. a drive mechanism; 41. a sheet ironing driving member; 42. an embroidery drive member; 421. an embroidery motor; 422. a drive shaft; 5. a winding mechanism; 51. a material receiving frame; 511. a substrate; 512. positioning a plate; 513. a partition plate; 514. a through groove; 515. a placement groove; 52. a wafer slide; 521. a material selecting groove; 522. a guide ramp; 53. rolling a driving piece; 531. a winding motor; 532. a drive roller; 54. a reel change drive; 541. a reel changing cylinder; 542. changing the reel; 55. a fixing plate; 56. changing the roll ball guide rail; 57. a connecting plate; 571. a through hole; 58. a color changing bracket; 6. a first wafer tray; 7. a color-changing driving member; 71. a color changing axis; 72. a color changing cylinder; 8. a second wafer tray; 9. a material receiving assembly; 91. a material receiving roller; 911. embossing rollers; 92. a material receiving driving member; 93. a pinch roller; 94. a pressing cylinder; 95. a material receiving seat; 96. a sheet passing plate; 97. and (4) a sheet passing hole.

Detailed Description

The present application is described in further detail below with reference to figures 1-8.

The embodiment of the application discloses an integrated machine for ironing and embroidering, and with reference to fig. 1 and 2, the integrated machine for ironing and embroidering comprises a rack 1, a workbench 12, an embroidering mechanism 2, an ironing mechanism 3, a driving mechanism 4 and a winding mechanism 5.

The frame 1 is provided with a girder 11, and the girder 11 is horizontally arranged along the length direction of the frame 1. The workbench 12 is installed on the frame 1 in a sliding mode and located below the girder 11, and can move left and right on the frame 1 along with embroidery and ironing pieces, so that the positions of the embroidery and the ironing pieces are changed, and a gap is reserved between the girder 11 and the workbench 12.

The piece ironing mechanisms 3 and the embroidery mechanisms 2 are located on the same side of the frame 1 and are all provided with five pieces, and the piece ironing mechanisms 3 and the embroidery mechanisms 2 are distributed along the length direction of the crossbeam 11 and are alternately arranged at intervals. The head distance of the ironing mechanism 3 is the same as that of the embroidery mechanism 2, namely the distance between the adjacent ironing mechanisms 3 is equal to that between the adjacent embroidery mechanisms 2.

The embroidery mechanism 2 and the iron plate mechanism 3 are driven by a driving mechanism 4 to perform embroidery and iron plate work.

The driving mechanism 4 includes an iron sheet driving member 41 and an embroidery driving member 42.

As shown in fig. 3, the embroidery driving member 42 includes an embroidery motor 421 and a driving shaft 422, the embroidery motor 421 is mounted on the girder 11, the driving shaft 422 is rotatably mounted on the girder 11, one end of the driving shaft 422 is connected to an output shaft of the embroidery motor 421, and the other end of the driving shaft 422 extends along the length direction of the girder 11 and is sequentially connected to the shuttle box of the embroidery mechanism 2, so as to drive the embroidery mechanism 2 to perform embroidery processing.

As shown in fig. 2 and 3, the ironing sheet mechanism 3 includes an ultrasonic head 31, a press head 32 provided with a punch 321, and a wafer holder 33, a housing 34 is fixedly mounted on the girder 11, and an ironing sheet driving member 41 is mounted in the housing 34.

As shown in fig. 3 and 4, a mounting plate 35 is fixedly mounted on a side surface of the housing 34 facing away from the girder 11, two horizontal color changing ball guide rails 36 are fixedly mounted on an outer surface of the mounting plate 35 facing away from the girder 11, and the two color changing ball guide rails 36 are vertically distributed.

The two color changing ball guide rails 36 are matched with the color changing ball rows 325 in a sliding manner, four material belt holes 326 which are distributed along the length direction of the rack 1 and are used for a material feeding belt to penetrate are formed in the color changing ball rows 325, and the side surfaces of the two color changing ball rows 325, which are back to the mounting plate 35, are fixedly mounted with the punching machine head 32.

As shown in fig. 4 and 5, a guide seat 322 and a die base plate 323 are mounted at the bottom of the press head 32, the guide seat 322 has a downward opening and is shaped like a [ ", the die base plate 323 is mounted at the bottom of the guide seat 322, four guide holes 324 are formed in the guide seat 322 and distributed along the length direction of the girder 11, a transmission shaft 327 is slidably connected in each guide hole 324, the top end of the transmission shaft 327 extends out of the guide seat 322 and is mounted with a tool cap 328, and the bottom end extends out of the guide seat 322 and is connected with the punch 321. The transmission shaft 327 is sleeved with a return spring 329, the top end of the return spring 329 is abutted against the tool cap 328, the other end of the return spring is abutted against the guide seat 322, the upper end of the punch 321 is provided with a chuck 3211, and the diameter of the chuck 3211 is larger than the aperture of the guide hole 324.

As shown in fig. 5 and 6, a through hole 3231 through which the material strap passes is formed in the die base plate 323, the through hole 3231 is horizontally arranged and perpendicular to the girder 11, a vertical die hole 3232 is formed in the die base plate 323, and the die hole 3232 is communicated with the through hole 3231 and used for allowing the punch 321 to enter the through hole 3231 to punch the material strap. The shape of the die hole 3232 may be designed into a circular shape, a triangular shape, a quadrangular shape, a star shape, a quincunx shape, etc., of different sizes according to the needs of the pattern of the hot stamping sheet.

As shown in fig. 1 and 3, five punching holes 121 are formed in the table 12, and the ultrasonic head 31 is mounted on the frame 1 such that the ultrasonic head 31 is located directly below the die base plate 323 and below the table 12.

As shown in fig. 3 and 4, the wafer support 33 is fixed on the top of the punch head 32, four first wafer disks 6 distributed along the length direction of the girder 11 are rotatably mounted on the wafer support 33, and a tape is wound around the first wafer disks 6.

The four first wafer disks 6 can be wound with the same material belt, and after the first material belt is used up, the second material belt is used for ironing the wafer; the material belt with different colors or materials can be wound, and the material belt with different colors or materials can be replaced in the iron sheet to iron the sheet.

In this embodiment, the winding of different color tapes is described.

The tape on the first wafer disk 6 is unwound from the first wafer disk 6, and then passes through the tape holes 326 of the two color changing ball rows 325, and then passes through the through hole 3231.

As shown in fig. 4 and 5, the ironing sheet driving member 41 has a driving rod in a vertical direction, and the driving rod is driven to move up and down under the control of the ironing sheet driving member 41, the driving rod is located right above one of the transmission shafts 327, and when the driving rod moves down, the driving rod collides with the tool cap 328 on the transmission shaft 327, so that the tool cap 328 and the transmission shaft 327 move down, thereby the punch 321 presses the material tape and the fabric onto the ultrasonic head 31, the punch 321 punches the ironing sheet down, and the ultrasonic head 31 presses the ironing sheet and the fabric.

As shown in fig. 3, the girder 11 is provided with the color changing driving member 7, the color changing driving member 7 includes a color changing shaft 71 and a color changing cylinder 72, the color changing cylinder 72 is installed on the girder 11, a piston rod of the color changing cylinder is parallel to the girder 11, one end of the color changing shaft 71 is fixed on the piston rod of the color changing cylinder 72, and the other end of the color changing shaft extends along the length direction of the girder 11 and is sequentially fixedly connected with the driving heads of the five ironing plate mechanisms 3. When the piston rod of the color-changing cylinder 72 extends, the wafer support 33 can be driven to move along the length direction of the girder 11, so that the transmission shaft 327 and the material belt corresponding to the driving rod are replaced, and the material belt switching during the sheet ironing is realized.

As shown in fig. 2 and 7, the take-up mechanism 5 includes a take-up frame 51, a wafer slide plate 52, a take-up drive 53, and a reel change drive 54.

The reel change drive 54 includes a reel change cylinder 541 and a reel change shaft 542.

As shown in fig. 7 and 8, the take-up driver 53 includes a take-up motor 531 and a drive roller 532.

As shown in fig. 7 and 8, a fixing plate 55 is mounted on a side surface of the girder 11 opposite to the housing 34, two reel changing ball rails 56 which are parallel to and vertically distributed on the girder 11 are fixed on the fixing plate 55, and the two reel changing ball rails 56 are slidably connected with a same connecting plate 57.

The material receiving frame 51 comprises a base plate 511, a positioning plate 512 and partition plates 513, wherein the base plate 511 is fixed on a connecting plate 57, the positioning plate 512 is fixed on the upper surface of the base plate 511 and extends towards one side of the base plate 511, a through groove 514 is formed in the surface of the positioning plate 512, the partition plates 513 are fixed on the positioning plate 512 and located in the through groove 514, five partition plates 513 are arranged, a placing groove 515 is formed between every two five partition plates 513, and the five partition plates 513 together form four placing grooves 515.

The driving rollers 532 are rotatably mounted on the base plates 511, two driving rollers 532 are arranged on each base plate 511 and distributed along the width direction of the girder 11, the winding motor 531 is mounted on one side of each base plate 511, which is back to the partition 513, and an output shaft of the winding motor 531 is simultaneously connected with the two driving rollers 532 through a belt pulley, so that the driving rollers 532 are driven to rotate by the winding motor 531.

A color changing bracket 58 is fixed on the fixing plate 55, the joint of the color changing bracket 58 and the fixing plate 55 is located between the two roll changing ball guide rails 56, a through hole 571 which penetrates through the connecting plate 57 along the width direction of the girder 11 is formed in the surface of the connecting plate 57 facing the fixing plate 55, the through hole 571 is located between the two roll changing ball guide rails 56 and is used for the color changing bracket 58 to penetrate through the connecting plate 57, the wafer sliding plate 52 is fixed at one end of the color changing bracket 58 far away from the fixing plate 55 and located below the placing groove 515, the second wafer disk 8 is placed in the placing groove 515, and the bottom of the second wafer disk 8 is supported on the wafer sliding plate 52.

The upper surface of the wafer sliding plate 52 is provided with a material selecting groove 521, two ends of the material selecting groove 521 are provided with guide inclined planes 522, the size of the material selecting groove 521 can only be used for a second wafer disk 8 to enter, and the material selecting groove 521 and the driving rod of the ironing sheet driving part 41 are positioned at the same length position of the crossbeam 11, so that the second wafer disk 8 in the material selecting groove 521 and the first wafer disk 6 of the ironing sheet in the ironing sheet mechanism 3 correspond to each other in sequence and are aligned with each other.

Two driving rollers 532 on the same base plate 511 are located on both sides of the wafer slide plate 52 in the width direction of the girder 11 and are higher than the wafer slide plate 52. The second wafer disk 8 in the material selecting groove 521 is contacted with the driving roller 532 due to the fact that the bottom end of the second wafer disk 8 enters the material selecting groove 521, the second wafer disk 8 is supported by the driving roller 532, and therefore when the winding motor 531 drives the driving roller 532 to rotate, the second wafer disk 8 in the material selecting groove 521 is driven to rotate through friction, and material receiving is conducted. The second wafer disk 8 positioned in the sorting chute 521 is supported by the portion of the wafer slide plate 52 positioned outside the sorting chute 521 so as to be separated from the driving roller 532 and remain stationary.

The reel changing cylinder 541 and the reel changing shaft 542 are arranged in a whole, the reel changing cylinder 541 is installed on one side, opposite to the outer shell 34, of the girder 11, and a piston rod of the reel changing cylinder 541 is parallel to the girder 11. The reel changing shaft 542 has one end connected to a piston rod of the reel changing cylinder 541 and the other end extending in the longitudinal direction of the girder 11 and connected to the respective connecting plates 57 in turn.

The piston rod of the roll changing cylinder 541 stretches synchronously with the piston rod of the color changing cylinder 72, and when the piston rod of the color changing cylinder 72 stretches, the piston rod of the roll changing cylinder 541 stretches synchronously to drive the connecting plate 57 to slide on the roll changing ball guide rail 56, so that the second wafer disk 8 entering the material selecting groove 521 is switched, and the second wafer in the material selecting groove 521 corresponds to the first wafer disk 6 of the hot plate all the time.

As shown in fig. 7 and 8, the girder 11 is provided with a material receiving assembly 9, and the material receiving assembly 9 includes a material receiving roller 91, a material receiving driving member 92, a pressing roller 93 and a pressing cylinder 94. Be fixed with on the connecting plate 57 and receive material seat 95, receive material roller 91 and rotate and install on receiving material seat 95 and parallel with girder 11, receive material driving piece 92 including receiving the material motor, receive the material motor and install on receiving material seat 95 and the output shaft is connected with receiving material roller 91 and rotate in order to drive receiving material roller 91, receive and install four knurling wheels 911 along receiving material roller 91 length direction distribution on the material roller 91, knurling wheel 911 and first wafer dish 6, 8 one-to-one of second wafer dish. The pressing cylinder 94 is fixed on the fixing plate 55 and vertically arranged downwards, the pressing wheel 93 is rotatably mounted on a piston rod of the pressing cylinder 94, the pressing wheel 93 and the driving rod of the ironing sheet driving part 41 are located on the same length position of the girder 11, so that the pressing wheel corresponds to a material belt for ironing the sheet, and the material belt is tightly abutted to the embossing wheel 911.

The receiving seat 95 is fixed with a sheet passing plate 96, the sheet passing plate 96 is located on one side of the receiving roller 91, which is back to the connecting plate 57, four sheet passing holes 97 which are distributed along the axial direction of the receiving roller 91 are formed in the sheet passing plate 96, the sheet passing holes 97 correspond to the embossing rollers 911 one by one, the material belt passes through the through hole 3231 and then passes through the corresponding sheet passing holes 97 and then upwards winds in the corresponding second wafer disc 8.

The implementation principle of the ironing and embroidering all-in-one machine in the embodiment of the application is as follows:

when in use, the embroidery mechanism 2 performs embroidery processing on the fabric on the workbench 12 to obtain embroidery patterns. After the embroidering is completed, the table 12 is moved to move the embroidery pattern below the iron sheet mechanism 3.

The color changing cylinder 72 drives the color changing shaft 71 to move, a transmission rod corresponding to a material strip needing to be ironed is moved between the punching hole 121 and the driving rod, then the ironing sheet driving part 41 drives the driving rod to move downwards, the driving rod downwards props against the tool cap 328, the tool cap 328 and the transmission shaft 327 move downwards, the reset spring 329 contracts, so that the punch 321 presses the material strip and the fabric onto the ultrasonic head 31, the punch 321 punches the ironing sheet, and the ultrasonic head 31 presses the ironing sheet and the fabric.

Then the sheet-ironing driving member 41 drives the driving rod to rise and reset, the reset spring 329 recovers to drive the transmission shaft 327 to move upwards, the sheet-ironing work of one sheet is completed, then the workbench 12 drives the fabric to move, the above operation is repeated, and the sheet-ironing is carried out at a new target position.

When the sheet is scalded, the waste material belt after stamping enters the winding mechanism 5 to wind the waste material belt.

One of the four second wafer disks 8 is positioned in the sorting trough 521, and the bottom of the one second wafer disk is in contact with the driving roller 532; the remaining three are supported by the wafer sled 52 and disengaged from the drive roller 532.

The waste tape passes around the embossing wheel 911 and then through the corresponding through-sheet hole 97 and then is wound around the corresponding second wafer disk 8.

When the winding motor 531 rotates, the two driving rollers 532 are driven by the belt pulley to rotate, and the driving rollers 532 rotate to drive the second wafer disk 8 in the material selecting groove 521 to rotate, so that winding is performed.

During rolling, the waste material belt on the embossing wheel 911 corresponding to the rotating second wafer disc 8 is pressed on the embossing wheel 911 by the pressing wheel 93 controlled by the pressing cylinder 94, the material receiving roller 91 rotates under the driving of the material receiving motor to drive the waste material belt to be conveyed to the second wafer disc 8, and the waste material belt on the other embossing wheels 911 and the embossing wheel 911 slip.

The color changing shaft 71 is driven by the color changing cylinder 72 to move to change colors in the film ironing process, the color changing shaft 542 is driven by the roll changing cylinder 541 to move during color changing, different second wafer discs 8 can be replaced to enter the material selecting groove 521, and meanwhile the pressing wheel 93 and the material collecting roller 91 move relatively, so that waste materials corresponding to the second wafer discs 8 located in the material selecting groove 521 are pressed on the corresponding embossing wheels 911.

After the piece ironing is finished, the workbench 12 moves to drive the fabric to move, a new embroidery position is moved to the position below the embroidery mechanism 2 to perform new embroidery processing, and the embroidery, piece ironing and material receiving operations are repeated until the fabric finishes all embroidery and piece ironing processing.

Because the winding mechanism 5 is integrally arranged on the back of the girder 11, the upper part of the girder 11 is left for placing the embroidery thread roll required by the embroidery mechanism 2, and the overall layout is more reasonable.

The above embodiments are preferred embodiments of the present application, and the protection scope of the present application is not limited by the above embodiments, so: all equivalent changes made according to the structure, shape and principle of the present application shall be covered by the protection scope of the present application.

Claims (10)

1. The utility model provides a scald piece embroidery all-in-one which characterized in that: the embroidery machine comprises a rack (1), and a workbench (12), an embroidery mechanism (2), an ironing mechanism (3) and a driving mechanism (4) which are arranged on the rack (1), wherein the embroidery mechanism (2) and the ironing mechanism (3) are the same in quantity and at least one in quantity, the embroidery mechanism (2) and the ironing mechanism (3) are alternately arranged along the length direction of the rack (1) at intervals, and the driving mechanism (4) is respectively connected with the embroidery mechanism (2) and the ironing mechanism (3) and is used for driving the embroidery mechanism (2) and the ironing mechanism (3) to work.

2. An integrated machine for ironing and embroidering according to claim 1, wherein: the piece ironing mechanism (3) and the embroidery mechanism (2) are both positioned on the same side of the rack (1).

3. An integrated machine for ironing and embroidering according to claim 2, wherein: scald piece mechanism (3) including ultrasonic head (31), be provided with punching press aircraft nose (32) and wafer support (33) of drift (321), ultrasonic head (31) set up on frame (1) and are located workstation (12) below, punching press aircraft nose (32) set up on frame (1) and are located the top of workstation (12), punching press hole (121) have been seted up on workstation (12), thereby actuating mechanism (4) are connected with drift (321) of punching press aircraft nose (32) and are driven drift (321) and carry out punching press work.

4. An integrated machine for ironing and embroidering according to claim 3, wherein: the wafer support (33) is provided with a plurality of first wafer disks (6) distributed along the length direction of the rack (1), the wafer support (33) is arranged on the rack (1) in a sliding manner along the length direction of the rack (1), and a color changing driving piece (7) for driving the wafer support (33) to move is arranged between the wafer support (33) and the rack (1).

5. An integrated machine for ironing and embroidering according to claim 4, wherein: the automatic wafer-rolling machine is characterized in that a rolling mechanism (5) is arranged on the rack (1), the rolling mechanism (5) comprises a material receiving frame (51) which is installed on the rack (1) in a sliding manner, a wafer sliding plate (52) which is fixed on the rack (1), a rolling driving part (53) and a roll changing driving part (54), the material receiving frame (51) is arranged on the rack (1) in a sliding manner along the length direction of the rack (1), the roll changing driving part (54) is arranged on the rack (1) and connected with the material receiving frame (51) and used for driving the material receiving frame (51) and a wafer support (33) to synchronously slide, second wafer disks (8) which are the same in number as that of the first wafer disks (6) and are distributed along the length direction of the rack (1) are rotatably installed on the material receiving frame (51), a wafer sliding plate (52) is arranged on the rack (1) and located below the second wafer disks (8), a material selecting groove (521) for the second wafer disks (8) to enter is arranged on the wafer sliding plate (52), the two ends of the material selecting groove (521) are provided with guide inclined planes (522), and the winding driving part (53) is arranged on the rack (1) and used for driving the second wafer disc (8) in the material selecting groove (521) to rotate.

6. An integrated machine for ironing and embroidering according to claim 5, wherein: the winding driving part (53) comprises a winding motor (531) and a driving roller (532), the material receiving frame (51) is provided with placing grooves (515) which are the same as the second wafer disc (8) in number and used for placing the second wafer disc (8), the placing grooves (515) penetrate through the material receiving frame (51), the driving roller (532) is rotatably installed on the material receiving frame (51) and located below the placing grooves (515), and the winding motor (531) is arranged on the material receiving frame (51) and connected with the supporting driving roller (532); when the second wafer disk (8) abuts against the wafer sliding plate (52), the second wafer disk (8) is separated from the driving roller (532); when the second wafer disk (8) is positioned in the material selecting groove (521), the second wafer disk (8) is abutted against the driving roller (532).

7. An integrated machine for ironing and embroidering according to claim 5, wherein: winding mechanism (5) still include connecting plate (57), and connecting plate (57) slide along frame (1) length direction and set up in frame (1), receive work or material rest (51) and set up on connecting plate (57), roll change driving piece (54) connect gradually connecting plate (57) along frame (1) length direction to drive and receive work or material rest (51) and wafer support (33) synchronous slip.

8. An integrated machine for ironing and embroidering according to claim 7, wherein: trade look driving piece (7) including trading look axle (71) and trade look cylinder (72), trade look cylinder (72) horizontally set up in the one end of frame (1), trade look axle (71) level sets up and connects gradually wafer support (33), the piston rod that trades look cylinder (72) is connected with trade look axle (71), trade a roll driving piece (54) including trading a roll cylinder (541) and trade spool (542), trade spool (542) and trade look axle (71) parallel and connect gradually connecting plate (57), trade a roll cylinder (541) set up in frame (1) and be used for driving to trade spool (542) and remove along frame (1) length direction, trade a roll cylinder (541) and trade look cylinder (72) synchronous flexible.

9. An integrated machine for ironing and embroidering according to claim 7, wherein: receive and be provided with on work or material rest (51) and be used for sending the material area to receipts material subassembly (9) of second wafer dish (8), receive material subassembly (9) including installing receipts material roller (91) on connecting plate (57), be used for driving receipts material roller (91) pivoted receipts material driving piece (92), be used for supporting pinch roller (93) of tightly receiving material roller (91) and fixed mounting compress tightly cylinder (94) on frame (1), pinch roller (93) set up on the piston rod of compressing tightly cylinder (94).

10. An integrated machine for ironing and embroidering according to claim 1, wherein: the head distance of the embroidery mechanism (2) is the same as that of the ironing mechanism (3).

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