CN213534174U

CN213534174U - Multi-station high-speed heat transfer printing machine

Info

Publication number: CN213534174U
Application number: CN202021661740.7U
Authority: CN
Inventors: 杨卫力
Original assignee: Taizhou Caizhiyuan New Material Technology Co ltd
Current assignee: Zhejiang Caizhiyuan New Material Technology Co.,Ltd.
Priority date: 2020-08-11
Filing date: 2020-08-11
Publication date: 2021-06-25
Anticipated expiration: 2030-08-11

Abstract

The utility model discloses a multi-station high-speed thermal transfer printer, which comprises an installation wall; a workbench is arranged below the front side of the mounting wall, and a feeding mechanism of a product to be transferred is arranged on the workbench; the middle part of the mounting wall is provided with a connecting seat, the connecting seat is forwards provided with a multi-station rotating disc which can be butted with the feeding mechanism, the disc surface of the multi-station rotating disc is provided with at least three clamping inserted rods which are distributed at equal intervals along the circumferential direction, the multi-station rotating disc is driven by a power source behind the connecting wall to intermittently rotate, and the rotating angle of the multi-station rotating disc at each time is 360 degrees/the total number of the clamping inserted rods; and a transfer printing mechanism is arranged above the multi-station rotating disc on the connecting wall. The multi-station high-speed heat transfer machine designed by the invention adopts the intermittently rotating multi-station turntable, can simultaneously carry out the operations of feeding, transfer printing and discharging, can improve the heat transfer efficiency of products by times, has good economic benefit and can meet the requirement of mass production.

Description

Multi-station high-speed heat transfer printing machine

Technical Field

The invention relates to a thermal transfer printing machine, in particular to a multi-station high-speed thermal transfer printing machine.

Background

The heat transfer printing is a mature printing process, which prints color patterns on a heat-resistant base material film in advance, then transfers the patterns on the base material film to the surface of a product in a hot stamping way by matching with a special transfer printing machine, and the printed patterns have the characteristics of rich layers, bright colors, great variation and small color difference, can well meet the requirements of designers, and are suitable for the requirements of modern mass production.

Here, the structure of the conventional thermal transfer printer is generally a single-station structure, and in the process of processing, only the operations of feeding, transfer printing and discharging can be performed in sequence, so that the processing efficiency is very low, and the requirement of mass production is difficult to meet.

Disclosure of Invention

Aiming at the problems, the invention designs the multi-station high-speed heat transfer machine, which adopts the intermittently rotating multi-station turntable, can simultaneously carry out the operations of feeding, transfer printing and discharging, can improve the heat transfer efficiency of products by times, has good economic benefit and can meet the requirement of mass production.

In order to achieve the purpose, the invention adopts the following technical scheme:

the utility model provides a high-speed heat transfer machine of multistation which characterized in that: comprises a mounting wall; a workbench is arranged below the front side of the mounting wall, and a feeding mechanism of a product to be transferred is arranged on the workbench; the middle part of the mounting wall is provided with a connecting seat, the connecting seat is forwards provided with a multi-station rotating disc which can be butted with the feeding mechanism, the disc surface of the multi-station rotating disc is provided with at least three clamping inserted rods which are distributed at equal intervals along the circumferential direction, the multi-station rotating disc is driven by a power source behind the connecting wall to intermittently rotate, and the rotating angle of the multi-station rotating disc at each time is 360 degrees/the total number of the clamping inserted rods; and a transfer printing mechanism is arranged above the multi-station rotating disc on the connecting wall.

More specifically, the connecting seat is mounted on a height adjusting device, the height adjusting device comprises a rectangular outer fixing frame, and the bottom of the outer fixing frame is positioned on the mounting wall through a positioning seat; an inner movable frame is arranged in the inner frame of the outer fixed frame in a matching way, the top of the inner movable frame is fixedly connected with a connecting seat of the multi-station rotating disc, and a section of movable gap is reserved between a combined body formed by the inner movable frame and the connecting seat and the upper side and the lower side of the inner frame of the outer fixed frame; the bottom of the inner movable frame is provided with an adjusting screw rod, the adjusting screw rod downwards penetrates through the outer fixed frame and the positioning seat and then is connected with a driving wheel, the positioning seat is provided with an adjusting motor, an output shaft of the adjusting motor is provided with a driving wheel, and the driving wheel is connected with the driving wheel through a belt or a chain.

More specifically, an up-down angle adjusting device of a multi-station rotating disc is arranged on the front side of the inner frame of the inner movable frame, the up-down angle adjusting device comprises a transverse worm and a vertical worm which are meshed and connected with each other through a worm gear pair, one end of the transverse worm extends out of the inner movable frame and is connected with an adjusting hand wheel, and the top end of the vertical worm penetrates through the inner movable frame and the outer fixed frame upwards and is propped against the bottom of the connecting seat.

More specifically, the feeding mechanism comprises a vibration disc and a reciprocating feeding mechanism; the bottom of the vibration plate is provided with a high-frequency vibration source which is fixed on a fixed bracket; the vibrating disc is internally provided with a disc edge track which spirally rises along the edge, the outlet of the disc edge track is connected with a linear conveying track with the width corresponding to the height of a product to be processed, and the outlet of the linear conveying track is connected with the reciprocating feeding mechanism through a blanking block with a blanking groove.

More specifically, the reciprocating feeding mechanism comprises a guide block, the guide block is positioned on the workbench through a vertical frame, a linear guide chute is arranged on the guide block, the position of the linear guide chute is coaxially and correspondingly arranged with a clamping inserted bar on the multi-station rotating disc, only one product to be processed can be accommodated in the linear guide chute, and the blanking chute of the blanking block feeds one product to be processed into the linear guide chute at each time; and a push rod is arranged behind the linear guide chute and driven by a feeding cylinder to reciprocate back and forth, and the forward movement of the push rod pushes the product to be processed to move forward and insert the product into the clamping inserted rod.

More specifically, the reciprocating feeding mechanism further comprises a photoelectric detection probe, the photoelectric detection probe is fixed beside the material guide block, a detection head of the photoelectric detection probe is arranged right opposite to the middle of the linear material guide groove, and the photoelectric detection probe triggers a signal to start the feeding cylinder to work when detecting a product to be processed in the linear material guide groove.

More specifically, the vertical frame comprises an upper vertical frame and a lower vertical frame, wherein the upper vertical frame is provided with a plurality of connecting holes, the lower vertical frame is provided with a plurality of vertically-arranged strip holes, and the connecting holes are connected with the corresponding strip holes through screws.

More specifically, the transfer mechanism comprises a transfer device and a printing film conveying device which are vertically arranged; the transfer printing device comprises a horizontal connecting plate fixedly connected with the connecting wall, a transfer printing air cylinder is arranged on the horizontal connecting plate, an air cylinder rod of the transfer printing air cylinder downwards penetrates through the horizontal connecting plate to be connected with the main rack, a transfer printing machine head is arranged below the main rack, and the tail end of the transfer printing machine head is connected with a power motor on the main rack through a transmission mechanism; the transfer machine head is positioned right above a clamping inserted bar on the multi-station rotating disc.

More specifically, the printed film conveying device comprises a film placing bracket, a film feeding rubber roller assembly, a film collecting embossing roller assembly and a film collecting bracket, wherein the film placing bracket is used for positioning a rolled printed film; one end of the film placing support is positioned on the connecting wall, and the other end of the film placing support is provided with a film placing positioning roller which is sleeved with the rolled printing film; the film feeding rubber roller assembly consists of a plurality of rubber rollers and is divided into a front rubber roller, two middle rubber rollers and a rear rubber roller, wherein the two middle rubber rollers are respectively positioned on two sides of the transfer printing machine head and are arranged side by side at intervals horizontally; the printing film is sent to the film collecting embossing roller assembly after passing through the upper part of the front rubber roller, the lower parts of the two middle rubber rollers and the upper part of the rear rubber roller in sequence after coming out of the film releasing bracket; the film collecting embossing roller assembly comprises a connecting frame positioned on the connecting wall, and two film collecting embossing rollers are arranged in the connecting frame in a cutting mode; the printing film sent by the film-feeding rubber roller assembly passes through the two film-collecting embossing rollers and then is sent to the film-collecting bracket; one end of the film collecting support is connected with a film collecting motor on the connecting wall, and the other end of the film collecting support is provided with a film collecting positioning roller connected with the roll printing film sleeve.

More specifically, a working cursor is arranged between two adjacent patterns on the printing film, a working cursor detection head is arranged on the lower side between the film placing support and the film feeding rubber roller assembly, and the working cursor detection head sends a signal to stop the film collecting motor once detecting the next working cursor in the process of driving the printing film to feed materials by the film collecting motor.

More specifically, the main frame is provided with a plurality of guide posts upward, and the guide posts are movably connected with the guide holes and the guide sleeves on the horizontal connecting plate.

More specifically, the main frame comprises a lifting plate, the upper part of the lifting plate is connected with a cylinder rod of a transfer printing cylinder, the lower part of the lifting plate is connected with a fixed block, the bottom of the fixed block is provided with a slide rail for installing a longitudinal sliding plate, a screw rod is arranged between the fixed block and the longitudinal sliding plate, the outer end of the screw rod is provided with a rotating wheel, and the rotating wheel drives the screw rod to rotate so that the longitudinal sliding plate can move back and forth relative to the fixed; a protective cover and a transfer printing machine head are sequentially arranged below the longitudinal sliding plate; and a connecting arm is arranged at the rear side of the longitudinal sliding plate, the power motor is installed on the connecting arm, and an output shaft of the power motor is connected with the transfer printing machine head through a transmission mechanism.

The multi-station rotating disc designed by the invention is provided with at least three clamping plugs, in the processing process, each clamping plug can simultaneously carry out loading, printing film transfer printing and product blanking on a product to be processed, and each station is intermittently rotated along with each time of the multi-station rotating disc so as to sequentially alternate, and by analogy, the transfer printing processing of the product can be continuously and efficiently realized.

Compared with the existing single-station processing equipment, the design of the invention can improve the heat transfer printing processing efficiency of the product by times, has good economic benefit and can meet the requirement of mass production.

Drawings

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

FIG. 2 is a schematic perspective view of another embodiment of the present invention;

FIG. 3 is a schematic perspective view of the multifunctional rotary disk of the present invention;

FIG. 4 is a schematic perspective view of the multifunctional rotary disk according to the present invention;

FIG. 5 is a schematic perspective view of the feeding mechanism of the present invention;

FIG. 6 is a schematic perspective view of the feeding mechanism of the present invention from another perspective;

FIG. 7 is a schematic perspective view of a transfer device according to the present invention;

FIG. 8 is a schematic perspective view of another perspective view of a transfer device according to the present invention.

Detailed Description

As shown in fig. 1-8, a multi-station high-speed thermal transfer printer comprises a mounting wall 1, a workbench 11 is arranged below the front side of the mounting wall 1, and a feeding mechanism 2 for a product to be transferred is arranged on the workbench 11; the middle part of the mounting wall 1 is provided with a connecting seat 31, and the connecting seat 31 is provided with a multi-station rotating disc 3 which can be butted with the feeding mechanism 2 forwards.

The plate surface of the multi-station rotating plate 3 is provided with at least three clamping insertion rods 32. In the machining, since three stations of loading, transferring and blanking are involved at the same time at the same machining time, the number of the clamping insert rods 32 is at least three, and only the structure of providing four clamping insert rods 32 is described in the figure, and more clamping insert rods can be set as required in practice.

The clamping insert rods 32 are circumferentially distributed at equal intervals. The multi-station rotating disc 3 is driven by a power source 33 behind the connecting wall to intermittently rotate, the rotating angle of the multi-station rotating disc 3 is 360 degrees/the total number of the clamping inserted rods, and the total number of the clamping inserted rods 32 is four, so that the rotating angle is 90 degrees.

Here, in order to meet the processing requirements of products with different specifications, the height adjustment of the multi-station rotating disc 3 is actually involved, and for this purpose, the connecting seat 31 for fixing the multi-station rotating disc 3 is installed on a height adjusting device.

The height adjusting device comprises a rectangular outer fixing frame 41, and the bottom of the outer fixing frame 41 is positioned on the mounting wall 1 through a positioning seat 42. An inner movable frame 43 is fittingly installed in the inner frame of the outer fixed frame 41, the top of the inner movable frame 43 is fixedly connected with the connecting seat 31 of the multi-station rotating disc 3, and a section of movable gap 4a is reserved between the combined body formed by the inner movable frame 43 and the connecting seat 31 and the upper side and the lower side of the inner frame of the outer fixed frame 41. An adjusting screw rod 44 is arranged at the bottom of the inner movable frame 43, the adjusting screw rod 44 penetrates through the outer fixed frame 41 and the positioning seat 42 downwards and then is connected with a transmission wheel 45, an adjusting motor 46 is arranged on the positioning seat 42, a driving wheel 47 is arranged on an output shaft of the adjusting motor 46, and the driving wheel 47 is connected with the transmission wheel 45 through a belt 48 or a chain.

In use, the adjusting motor 46 drives the screw rod 44 to rotate, so as to drive the combination body formed by the inner movable frame 43 and the connecting seat 31 to move up or down relative to the inner frame of the fixed outer frame 41, and the up-and-down movement of the connecting seat 31 can synchronously drive the height adjustment of the multi-station rotating disc 3, so as to meet the processing requirements of products with different specifications.

In addition, in order to meet the requirement of fine adjustment of the up-down angle of the multi-station rotating disc 3, an up-down angle adjusting device of the multi-station rotating disc 3 is arranged on the front side of the inner frame of the inner movable frame 43, and comprises a transverse worm 51 and a vertical worm 52 which are meshed and connected with each other through a worm gear pair 5a, one end of the transverse worm 51 extends out of the inner movable frame 43 to be connected with an adjusting hand wheel 53, and the top end of the vertical worm 52 upwards penetrates through the inner movable frame 43 and the outer fixed frame 41 to be supported at the bottom of the connecting seat 31.

In use, the adjusting hand wheel 53 drives the transverse worm 51 to rotate, the vertical worm 52 is driven to rotate through the meshing transmission of the turbine pair 5a, the rotation of the vertical worm 52 can realize the lifting or descending of the front end of the connecting seat 31, the up-and-down angle adjustment of the multi-station rotating disc 3 is realized, the levelness of the central line of each clamping inserted rod 32 on the multi-station rotating disc 3 is ensured, and the smooth butt joint with the feeding mechanism 2 is realized.

The feeding mechanism 2 comprises a vibration disc 21 and a reciprocating feeding mechanism 22.

Wherein, the bottom of the vibration plate 21 is provided with a high-frequency vibration source 211, and the high-frequency vibration source 211 is fixed on a fixed bracket 212. The vibrating disk 21 is provided with a disk edge track 213 which spirally rises along the edge, the outlet of the disk edge track 213 is connected with a linear conveying track 214 with the width corresponding to the height of the product 6 to be processed, and the outlet of the linear conveying track 214 is connected with the reciprocating feeding mechanism 22 through a blanking block 7 with a lower blanking groove 71. In operation, the products 6 to be processed are gradually raised along the disk edge rail 213 by the high frequency vibration of the vibration source 211, until the products 6 to be processed come out from the outlet of the disk edge rail 213 with their mouths facing forward, and then sequentially enter the linear conveying rail 214 to be arranged and pressed forward.

The reciprocating feeding mechanism 22 comprises a material guiding block 221, the material guiding block 221 is positioned on the workbench 11 through a vertical frame 222, a linear material guiding slot 2211 is arranged on the material guiding block 221, the position of the linear material guiding slot 2211 is coaxially and correspondingly arranged with the rightmost clamping insertion rod 32 on the multi-station rotating disc 3, only one product 6 to be processed can be accommodated in the linear material guiding slot 2211, and one product 6 to be processed is fed into the linear material guiding slot 2211 by the material feeding slot 71 of the material feeding block 7 at a time. A push rod 223 is arranged behind the linear material guide 2211, the push rod 223 is driven by a material loading cylinder 224 to reciprocate back and forth, and the forward movement of the push rod 223 pushes the product 6 to be processed to move forward and insert the product into the clamping inserted bar 32.

Here, to realize automatic feeding, the reciprocating feeding mechanism 22 further includes a photoelectric detection probe 225, the photoelectric detection probe 225 is fixed beside the material guide block 221, a detection head of the photoelectric detection probe 225 is disposed opposite to the middle portion of the linear material guide slot 2211, when the photoelectric detection probe 225 detects a product 6 to be processed in the linear material guide slot 2211, a trigger signal is triggered to start the feeding cylinder 224 to operate so as to perform a feeding operation on the product 6 to be processed, and after the feeding operation is completed, the feeding cylinder 224 drives the push rod 223 to reset, so as to prepare for the next feeding.

Also, the stand 222 for positioning the guide block 221 is composed of an upper stand 222a and a lower stand 222b in consideration of the adjustment of the vertical height position. The upper vertical frame 222a is provided with a plurality of connection holes (not shown), and the lower vertical frame 222b is provided with an equal number of vertically arranged elongated holes 2222, which are connected with the corresponding elongated holes 2222 by screws 2221. When the height needs to be adjusted, the screws 2221 are loosened, then the long holes 2222 are slid to the needed height, and then the locking is tightened again.

The connecting wall 1 is provided with a transfer mechanism above the multi-station rotating disc 3, and the transfer mechanism comprises a transfer device 8 and a printing film conveying device 9 which are vertically arranged.

The transfer device 8 comprises a horizontal connecting plate 81 fixedly connected with the connecting wall 1, a transfer cylinder 82 is arranged on the horizontal connecting plate 81, a cylinder rod of the transfer cylinder 82 downwards penetrates through the horizontal connecting plate 81 to be connected with a main frame 83, a transfer machine head 84 is arranged below the main frame 83, and the tail end of the transfer machine head 84 is connected with a power motor 86 on the main frame 83 through a transmission mechanism 85.

The transfer machine head 84 is positioned right above one clamping inserted rod 32 on the multi-station rotating disc 3. In the process, the printing film 10 is tightly attached to the side wall of the product 6 to be processed on the clamping insertion rod 32, and the transfer printing head 84 can be driven by the transfer printing cylinder 82 to descend so as to transfer the pattern on the printing film 10 to the side wall of the product 6 to be processed.

In order to ensure the accuracy of the up-and-down movement of the transfer head 84, the main frame 83 is provided with a plurality of guide posts 83a upward, and the guide posts 83a are movably connected with guide holes and guide sleeves 811 on the horizontal connecting plate 81. In operation, the guide posts 83a can play a good role in guiding, so as to prevent the transfer head 84 from shifting during the descending process to affect the transfer quality.

In addition, in consideration of the requirement of adjusting the front and back of the transfer head 84 in actual processing, the main frame 83 includes a lifting plate 831, the upper portion of the lifting plate 831 is connected with a cylinder rod and a guide post 83a of the transfer cylinder 82, the lower portion of the lifting plate 831 is connected with a fixed block 832, the bottom of the fixed block 832 is provided with a slide rail 8321, a longitudinal sliding plate 833 is mounted on the slide rail 8321, a lead screw 834 is arranged between the fixed block 832 and the longitudinal sliding plate 833, the outer end of the lead screw 834 is provided with a rotating wheel 835, and the rotating wheel 835 drives the lead screw 834 to rotate so that the longitudinal sliding plate. The longitudinal sliding plate 833 is provided with a shield 836 and a transfer head 84 in this order thereunder. A connecting arm 837 is arranged at the rear side of the longitudinal sliding plate 833, the power motor 86 is mounted on the connecting arm 837, and an output shaft of the power motor 86 is connected with the transfer printing machine head 84 through a transmission mechanism 85. In use, the screw 834 is driven by the runner 835 to rotate for adjustment, so that the longitudinal sliding plate 833, the shield 836 and the transfer printing head 84 can be adjusted back and forth.

The printing film conveying device 9 comprises a film placing support 91, a film feeding rubber roller assembly 92, a film collecting embossing roller assembly 93 and a film collecting support 94, wherein the film placing support 91 is used for positioning the rolled printing film 10.

One end of the film placing support 91 is positioned on the connecting wall 1, and the other end of the film placing support 91 is provided with a film placing positioning roller 911 which is sleeved with the rolled printing film 10.

The film feeding rubber roller assembly 92 consists of a plurality of rubber rollers and is divided into a front rubber roller 921, two middle rubber rollers 922 and a rear rubber roller 923, wherein the two middle rubber rollers 922 are respectively positioned at two sides of the transfer printing machine head 84 and are arranged side by side at intervals horizontally; stamp membrane 10 is from putting membrane support 91 and coming back according to the preface through preceding rubber roll 921 top, two middle rubber roll 922 below, back rubber roll 923 top and then send to receive membrane embossing roller assembly 93.

The film collecting and embossing roller assembly 93 comprises a connecting frame 931 positioned on the connecting wall 1, and two film collecting and embossing rollers 932 are arranged in the connecting frame 931 in a cutting mode; the printing film 10 sent by the film feeding rubber roller assembly 92 passes through the two film collecting embossing rollers 932 and is sent to the film collecting bracket 94.

One end of the film collecting support 94 is connected with a film collecting motor 941 on the connecting wall 1, and the other end of the film collecting support 94 is provided with a film collecting positioning roller 942 sleeved with the rolled printed film 10.

Here, considering the fixed length of the printed film 10 during actual processing to be carried, be provided with the work cursor between two adjacent patterns on the printed film 10, the downside between putting the membrane support 91 and sending membrane rubber roll subassembly 92 is provided with work cursor detection head 95 simultaneously, and work cursor detection head 95 is in receiving the work of membrane motor 941 and is driven printed film 10 pay-off in-process and send out the signal promptly and make and receive membrane motor 941 stop work in case of detecting next work cursor.

The multi-station rotating disc 3 designed by the invention is provided with at least three clamping plugs 32, in the processing process, each clamping plug 32 can simultaneously carry out loading, printing film transfer printing and product blanking on different products to be processed, and intermittently rotates along with each time of the multi-station rotating disc 3 so as to sequentially alternate each station, and by analogy, the transfer printing processing of the products can be continuously and efficiently realized.

Compared with the existing single-station processing equipment, the design of the invention can improve the heat transfer printing processing efficiency of the product by times, has good economic benefit and can meet the requirement of mass heat transfer printing production.

The above description is only a preferred embodiment of the present invention, and is not intended to limit the present invention in any way, and any simple modification, equivalent change or modification made to the above embodiments according to the technical principle of the present invention still falls within the scope of the technical solution of the present invention.

Claims

1. The utility model provides a high-speed heat transfer machine of multistation which characterized in that: comprises a mounting wall; a workbench is arranged below the front side of the mounting wall, and a feeding mechanism of a product to be transferred is arranged on the workbench; the middle part of the mounting wall is provided with a connecting seat, the connecting seat is forwards provided with a multi-station rotating disc which can be butted with the feeding mechanism, the disc surface of the multi-station rotating disc is provided with at least three clamping inserted rods which are distributed at equal intervals along the circumferential direction, the multi-station rotating disc is driven by a power source behind the connecting wall to intermittently rotate, and the rotating angle of the multi-station rotating disc at each time is 360 degrees/the total number of the clamping inserted rods; and a transfer printing mechanism is arranged above the multi-station rotating disc on the connecting wall.

2. A multi-station, high speed thermal transfer machine according to claim 1, wherein: the connecting seat is installed on a height adjusting device, the height adjusting device comprises a rectangular outer fixing frame, and the bottom of the outer fixing frame is positioned on the installation wall through the positioning seat; an inner movable frame is arranged in the inner frame of the outer fixed frame in a matching way, the top of the inner movable frame is fixedly connected with a connecting seat of the multi-station rotating disc, and a section of movable gap is reserved between a combined body formed by the inner movable frame and the connecting seat and the upper side and the lower side of the inner frame of the outer fixed frame; the bottom of the inner movable frame is provided with an adjusting screw rod, the adjusting screw rod downwards penetrates through the outer fixed frame and the positioning seat and then is connected with a driving wheel, the positioning seat is provided with an adjusting motor, an output shaft of the adjusting motor is provided with a driving wheel, and the driving wheel is connected with the driving wheel through a belt or a chain.

3. A multi-station, high speed thermal transfer machine according to claim 2, wherein: an upper and lower angle adjusting device of a multi-station rotating disc is arranged on the front side of the inner frame of the inner movable frame and comprises a transverse worm and a vertical worm which are meshed and connected with each other through a worm gear pair, one end of the transverse worm extends out of the inner movable frame and is connected with an adjusting hand wheel, and the top end of the vertical worm penetrates through the inner movable frame and the outer fixed frame upwards and is propped against the bottom of the connecting seat.

4. A multi-station high speed thermal transfer machine according to any one of claims 1 to 3 wherein: the feeding mechanism comprises a vibration disc and a reciprocating feeding mechanism; the bottom of the vibration plate is provided with a high-frequency vibration source which is fixed on a fixed bracket; the vibrating disc is internally provided with a disc edge track which spirally rises along the edge, the outlet of the disc edge track is connected with a linear conveying track with the width corresponding to the height of a product to be processed, and the outlet of the linear conveying track is connected with the reciprocating feeding mechanism through a blanking block with a blanking groove.

5. A multi-station, high speed thermal transfer machine according to claim 4, wherein: the reciprocating feeding mechanism comprises a guide block, the guide block is positioned on the workbench through a vertical frame, a linear guide groove is arranged on the guide block, the position of the linear guide groove is coaxially and correspondingly arranged with a clamping inserted bar on the multi-station rotating disc, only one product to be processed can be accommodated in the linear guide groove, and one product to be processed is fed into the linear guide groove by the blanking groove of the blanking block each time; and a push rod is arranged behind the linear guide chute and driven by a feeding cylinder to reciprocate back and forth, and the forward movement of the push rod pushes the product to be processed to move forward and insert the product into the clamping inserted rod.

6. A multi-station, high speed thermal transfer machine according to claim 5, wherein: the reciprocating feeding mechanism further comprises a photoelectric detection probe, the photoelectric detection probe is fixed beside the material guide block, a detection head of the photoelectric detection probe is arranged right opposite to the middle of the linear material guide groove, and the photoelectric detection probe triggers a signal to start the feeding cylinder to work when detecting a product to be processed in the linear material guide groove.

7. A multi-station high speed thermal transfer machine according to any one of claims 1 to 3 wherein: the transfer mechanism comprises a transfer device and a printing film conveying device which are vertically arranged; the transfer printing device comprises a horizontal connecting plate fixedly connected with the connecting wall, a transfer printing air cylinder is arranged on the horizontal connecting plate, an air cylinder rod of the transfer printing air cylinder downwards penetrates through the horizontal connecting plate to be connected with the main rack, a transfer printing machine head is arranged below the main rack, and the tail end of the transfer printing machine head is connected with a power motor on the main rack through a transmission mechanism; the transfer machine head is positioned right above a clamping inserted bar on the multi-station rotating disc.

8. A multi-station, high speed thermal transfer machine according to claim 7, wherein: the printing film conveying device comprises a film placing bracket, a film feeding rubber roller assembly, a film collecting embossing roller assembly and a film collecting bracket, wherein the film placing bracket, the film feeding rubber roller assembly, the film collecting embossing roller assembly and the film collecting bracket are used for positioning a roll of printing film; one end of the film placing support is positioned on the connecting wall, and the other end of the film placing support is provided with a film placing positioning roller which is sleeved with the rolled printing film; the film feeding rubber roller assembly consists of a plurality of rubber rollers and is divided into a front rubber roller, two middle rubber rollers and a rear rubber roller, wherein the two middle rubber rollers are respectively positioned on two sides of the transfer printing machine head and are arranged side by side at intervals horizontally; the printing film is sent to the film collecting embossing roller assembly after passing through the upper part of the front rubber roller, the lower parts of the two middle rubber rollers and the upper part of the rear rubber roller in sequence after coming out of the film releasing bracket; the film collecting embossing roller assembly comprises a connecting frame positioned on the connecting wall, and two film collecting embossing rollers are arranged in the connecting frame in a cutting mode; the printing film sent by the film-feeding rubber roller assembly passes through the two film-collecting embossing rollers and then is sent to the film-collecting bracket; one end of the film collecting support is connected with a film collecting motor on the connecting wall, and the other end of the film collecting support is provided with a film collecting positioning roller connected with the roll printing film sleeve.

9. A multi-station, high speed thermal transfer machine according to claim 8, wherein: a working cursor is arranged between every two adjacent patterns on the printing film, a working cursor detection head is arranged on the lower side between the film placing support and the film feeding rubber roller assembly, and the working cursor detection head sends a signal to stop the film collecting motor once detecting the next working cursor in the process of driving the printing film feeding by the film collecting motor to work.

10. A multi-station, high speed thermal transfer machine according to claim 7, wherein: the main frame comprises a lifting plate, the upper part of the lifting plate is connected with a cylinder rod of the transfer printing cylinder, the lower part of the lifting plate is connected with a fixed block, the bottom of the fixed block is provided with a slide rail for mounting a longitudinal sliding plate, a screw rod is arranged between the fixed block and the longitudinal sliding plate, the outer end of the screw rod is provided with a rotating wheel, and the rotating wheel drives the screw rod to rotate so that the longitudinal sliding plate can move back and forth relative to the fixed; a protective cover and a transfer printing machine head are sequentially arranged below the longitudinal sliding plate; and a connecting arm is arranged at the rear side of the longitudinal sliding plate, the power motor is installed on the connecting arm, and an output shaft of the power motor is connected with the transfer printing machine head through a transmission mechanism.