CN210821356U - Full-automatic heat transfer printing equipment - Google Patents

Abstract

A full-automatic thermal transfer printing device comprises a material taking mechanism, a limiting mechanism, a material discharging mechanism, a printing mechanism and a discharging mechanism; the material taking mechanism is used for placing the printing stock in the limiting mechanism; the limiting mechanism comprises a rotary table, a first fixing piece connected with the rotary table, a first rotating shaft connected with the first fixing piece and a first positioning piece connected with the first rotating shaft; the shape of the first positioning piece is correspondingly matched with a printing stock; the discharging mechanism is used for placing the flower film; the printing mechanism comprises a roller and a heating element connected with the roller; the roller heated by the heating element is abutted against the patterned film and the first positioning element so that the pattern on the patterned film is transferred to a printing stock; the blanking mechanism is used for taking down the printing stock which is transferred on the first positioning piece. This full-automatic heat transfer apparatus places the stock in first locating piece through feeding agencies, and gyro wheel butt floral pattern and first locating piece after the heating, simultaneously, first pivot drive first locating piece and rotate, make the pattern rendition of floral pattern to stock, and unloading mechanism takes off the stock again, realizes full automatic processing.

Description

Full-automatic heat transfer printing equipment

Technical Field

The utility model relates to a rendition equipment technical field especially relates to a simple structure's full-automatic heat transfer apparatus.

Background

The transfer printing is a printing method for transferring the pictures and texts on the intermediate carrier film to a printing stock by adopting corresponding pressure; according to the different pressures, the transfer printing is divided into: thermal transfer, water transfer, air transfer, screen transfer, and the like. The heat transfer printing technology is to print the exquisite pattern on the heat-resistant film paper, and then print the pattern of the ink layer on the surface of the product by heating and pressurizing. The heat transfer printing technology is approved by customers by the characteristics of bright printing patterns, rich colors, environment-friendly production environment, durability, wear resistance and the like, improves the grade of products, has clear layers and bright luster, and is widely applied to various plastic products, building materials, wood, glass, ceramics, stainless steel, leather and other products.

Traditional heat transfer machine needs manual coordination operation, and manual operation causes scraping of product easily to spend or the position is inaccurate, leads to decorative pattern to appear misplacing or warping, and the imaging quality is not good and imaging speed is slow, waste time and energy, and is comparatively troublesome.

SUMMERY OF THE UTILITY MODEL

In view of the above, it is necessary to provide a fully automatic thermal transfer printing apparatus with simple structure, high efficiency and stability.

A full-automatic thermal transfer printing device comprises a material taking mechanism, a limiting mechanism, a material discharging mechanism, a printing mechanism and a discharging mechanism; the material taking mechanism is used for placing the printing stock on the limiting mechanism; the limiting mechanism comprises a rotary table, a first fixing piece connected with the rotary table, a first rotating shaft connected with the first fixing piece, and a first positioning piece connected with the first rotating shaft; the shape of the first positioning piece is correspondingly matched with the printing stock; the discharging mechanism is used for placing the flower film; the printing mechanism comprises a roller and a heating element connected with the roller; the roller heated by the heating element is abutted against the flower film and the first positioning element so that the pattern on the flower film is transferred to a printing stock; the blanking mechanism is used for taking down the printing stock which is transferred on the first positioning piece.

The utility model discloses a full-automatic heat transfer apparatus places the stock in first locating piece through feeding agencies, and gyro wheel butt flower mould and first locating piece after the heating, simultaneously, first pivot drive is equipped with the first locating piece rotation of stock to make the pattern rendition on the flower membrane to the stock, the stock of transfer-printing will be accomplished again to unloading mechanism takes off, realizes full automatic processing. The full-automatic heat transfer printing equipment has high automation degree, improves the production efficiency and improves the quality.

In one embodiment, the limiting mechanism further comprises a first connecting plate and a first adjusting piece, wherein the first connecting plate is connected with the rotary disc, and the first adjusting piece is connected with the first connecting plate and the rotary disc; one end of the first connecting plate is connected with the first fixing piece, and the other end of the first connecting plate is connected with the rotary disc through the first adjusting piece.

In one embodiment, the device further comprises a control mechanism; the control mechanism comprises a positioning sensor; the positioning sensor is matched with the first rotating shaft to adjust the position of the printing stock on the first positioning piece.

In one embodiment, the control mechanism further comprises a print sensor; the print sensor is used to control the operation of the printing mechanism.

In one embodiment, the control mechanism further comprises an alarm sensor; the alarm sensor is matched with the blanking mechanism to control the operation of the turntable.

In one embodiment, the printing mechanism comprises a shield connected to the heating element and a printing power element connected to the shield; the printing power part is used for driving the roller to be close to or far away from the first positioning part.

In one embodiment, the printing mechanism further comprises a sliding plate connected with the protective cover, a first rotating plate connected with the sliding plate, a second rotating plate connected with the first rotating plate, and a mounting plate connected with the second rotating plate; the sliding plate is used for adjusting the horizontal position of the protective cover; the first rotating plate is matched with the second rotating plate to adjust the angle of the protective cover; the printing power part is connected with the mounting plate.

In one embodiment, the discharging mechanism comprises a material placing part and a material receiving part; one end of the flower film is connected with the material placing part, and the other end of the flower film is connected with the material receiving part.

In one embodiment, the material taking mechanism comprises a material taking bracket, a longitudinal sliding plate connected with the material taking bracket, a horizontal sliding plate connected with the longitudinal sliding plate and a material taking piece connected with the horizontal sliding plate; the longitudinal sliding plate is arranged on the material taking bracket in a sliding manner, and the horizontal sliding plate is arranged on the longitudinal sliding plate in a sliding manner; the material taking part is used for placing the printing stock on the first positioning part.

In one embodiment, the blanking mechanism comprises a blanking bracket, a horizontal moving member connected with the blanking bracket, and a blanking member connected with the horizontal moving member; the horizontal moving piece is arranged on the blanking bracket in a sliding manner; the blanking piece is used for taking down the printing stock which is transferred on the first positioning piece.

Drawings

Fig. 1 is an assembly structure diagram of a full-automatic thermal transfer printing apparatus according to an embodiment of the present invention;

FIG. 2 is a schematic view of the full-automatic thermal transfer printing apparatus shown in FIG. 1 at another angle;

FIG. 3 is a schematic structural diagram of a limiting mechanism, a control mechanism and a printing stock in the full-automatic thermal transfer printing device shown in FIG. 1;

fig. 4 is a schematic structural diagram of a discharging mechanism, a printing mechanism and a flower film in the full-automatic thermal transfer printing equipment shown in fig. 2.

Reference is made to the accompanying drawings in which:

a full-automatic thermal transfer apparatus 100;

the device comprises a material taking mechanism 10, a material taking bracket 11, a longitudinal sliding plate 12, a horizontal sliding plate 13, a material taking part 14, a material taking conveying belt 15, a limiting mechanism 20, a rotary disc 21, a first fixing part 22, a first rotating shaft 23, a first positioning part 24, a first connecting plate 25, a first adjusting part 26, a first bottom plate 27, a supporting frame 28 and a mounting plate 29;

the feeding mechanism 30, the feeding member 31, the receiving member 32, the fixing frame 33, the first supporting member 34, the second supporting member 35, the first fixing member 36, the first pulley 37, the first supporting wheel 38, the printing mechanism 40, the roller 41, the protective cover 42, the printing power member 43, the sliding plate 44, the first rotating plate 45, the second rotating plate 46, the mounting plate 47, the blanking mechanism 50, the blanking bracket 51, the horizontal rotating member 52, the blanking member 53 and the blanking moving member conveying belt 54;

control mechanism 60, positioning sensor 61, printing sensor 62, alarm sensor 63, printing material 80, flower film 90.

Detailed Description

In order to facilitate understanding of the present invention, the present invention will be described more fully below. The invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. The terminology used in the description of the invention herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention.

Referring to fig. 1 to 4, a full-automatic thermal transfer printing apparatus 100 according to an embodiment of the present invention includes a material taking mechanism 10, a limiting mechanism 20, a material discharging mechanism 30, a printing mechanism 40, and a material discharging mechanism 50; the material taking mechanism 10 is used for placing the printing stock 80 on the limiting mechanism 20; the limiting mechanism 20 comprises a rotary disc 21, a first fixing piece 22 connected with the rotary disc 21, a first rotating shaft 23 connected with the first fixing piece 22, and a first positioning piece 24 connected with the first rotating shaft 23; the shape of the first positioning member 24 is correspondingly matched with the printing stock 80; the discharging mechanism 30 is used for placing the flower film 90; the printing mechanism 40 includes a roller 41 and a heating member (not shown) connected to the roller 41; the roller 41 heated by the heating member abuts the patterned film 90 and the first positioning member 24 to transfer the pattern on the patterned film 90 to the printing material 80; the blanking mechanism 50 is used to remove the substrate 80 that has been transferred to the first positioning member 24. This full-automatic heat transfer equipment 100 places stock 80 in first locating piece 24 through extracting mechanism 10, and the gyro wheel 41 butt flower mould 90 and first locating piece 24 after the heating, simultaneously, first pivot 21 drives the first locating piece 24 that is equipped with stock 80 and rotates to make the pattern on the flower film 90 rendition to the stock 80 on, unloading mechanism 50 takes off the stock 80 who accomplishes the rendition again, realizes full automatic processing.

As shown in fig. 1 and fig. 2, in the present embodiment, the material taking mechanism 10 includes a material taking bracket 11, a longitudinal sliding plate 12 connected to the material taking bracket 11, a horizontal sliding plate 13 connected to the longitudinal sliding plate 12, and a material taking member 14 connected to the horizontal sliding plate 13; the longitudinal sliding plate 12 is arranged on the material taking bracket 11 in a sliding manner, and the horizontal sliding plate 13 is arranged on the longitudinal sliding plate 12 in a sliding manner; the take-off member 14 is used to place the substrate 80 on the first positioning member 24. Optionally, the material taking part 14 adsorbs the printing material 80 through air negative pressure; the substrate 80 is a plastic drum. In order to realize automatic production, the material taking mechanism 10 further comprises a material taking conveyor belt 15 and a material taking sensor (not shown) connected to one end of the material taking conveyor belt 15; the material taking conveyer belt 15 is used for conveying printing stocks 80 to be close to the material taking bracket 11 so as to take materials from the material taking parts 14; the material taking sensor is used for controlling the operation of the material taking conveyer belt 15; optionally, the substrate 80 is placed upright on the take-off conveyor 15. During operation, the printing material 80 is close to the material taking support 11 through the material taking conveying belt 15 for conveying, after the material taking sensor senses the printing material 80, the material taking conveying belt 15 stops, meanwhile, the material taking part 14 is driven to move through the longitudinal sliding plate 12 and the horizontal sliding plate 13, and the printing material 80 on the material taking conveying belt 15 is transferred to the first positioning part 24 through the material taking part 14.

Referring to fig. 3, the first fixing member 22, the first rotating shaft 23 and the first positioning member 24 are matched with each other in a one-to-one correspondence manner, and the shape of the first positioning member 24 is matched with the object 80. Alternatively, the first locator 24 is transverse and the first locator 24 is tapered. The limiting mechanism 20 further comprises a first connecting plate 25 connected with the turntable 21 and a first adjusting piece 26 connected with the first connecting plate 25 and the turntable 21; one end of the first connecting plate 25 is connected with the first fixing member 22, and the other end is connected with the rotary table 21 through the first adjusting member 26; the top surface of the first positioning member 24 is ensured to be a horizontal surface by adjusting the angle of the first connecting plate 25 with the turntable 21, which facilitates printing. Optionally, the limiting mechanism 20 further comprises a first bottom plate 27 connected to the rotating disc 21, and the first connecting plate 25 is connected to the first bottom plate 27 so as to adjust the horizontal position of the first connecting plate 25. The limiting mechanism 20 further comprises a turntable power member (not shown) and a first rotating shaft driving member (not shown); the turntable power part is used for driving the turntable 21 to rotate; the first shaft driver is used for driving the first shaft 23 to rotate. Optionally, the turntable power member is a motor, one end of the turntable power member is connected with a divider, and the divider is connected with the turntable 21; the first rotating shaft driving part is a servo motor. Further, the limiting mechanism 20 further comprises a supporting frame 28 and a mounting plate 29 fixedly connected with the supporting frame 28; the turntable power part is arranged below the supporting frame 28, the turntable 21 is connected above the supporting frame 28, and the mounting plate 29 is arranged above the turntable 21. In order to improve the processing efficiency, the limiting mechanism 20 further includes a second fixing element (not shown), a second rotating shaft (not shown), a second positioning element (not shown), a third fixing element (not shown), a third rotating shaft (not shown), a third positioning element (not shown), a fourth fixing element (not shown), a fourth rotating shaft (not shown), and a fourth positioning element (not shown); the first fixing element 22, the second fixing element, the third fixing element and the fourth fixing element have the same structure, the first rotating shaft 23, the second rotating shaft, the third rotating shaft and the fourth rotating shaft have the same structure, and the first positioning element 24, the second positioning element, the third positioning element and the fourth positioning element have the same structure, which will not be described in detail below. In other embodiments, the limiting mechanism 20 at least includes a first fixing member 22, a first rotating shaft 23, a first positioning member 24, a first connecting plate 25, a first adjusting member 26 and a first bottom plate 27; the first positioning member 24 has a cylindrical shape.

Referring to fig. 4, the discharging mechanism 30 includes a material placing member 31 and a material receiving member 32; one end of the flower film 90 is connected with the material placing part 31, and the other end is connected with the material receiving part 32. Optionally, the material placing member 31 and the material receiving member 32 rotate at the same speed, and both the material placing member 31 and the material receiving member 32 are guide wheels. The discharging mechanism 30 further includes a fixing frame 33, a first supporting member 34, a second supporting member 35, a discharging power member (not shown), and a collecting power member (not shown); the fixed frame 33 is connected with the supporting frame 28, one end of the first supporting piece 34 is connected with one end of the fixed frame 33, and the other end is connected with the material placing piece 31; one end of the second supporting member 35 is connected with one end of the fixed frame 33 far away from the material receiving member 32, and the other end is connected with the material receiving member 32; the first supporting piece 34 and the second supporting piece 35 are both slidably arranged on the fixed frame 33, the first supporting piece 34 is used for adjusting the height of the material placing piece 31, and the second supporting piece 35 is used for adjusting the height of the material receiving piece 32, so that the flower film 90 is positioned above the first positioning piece 24; the discharging power piece is used for driving the material placing piece 31 to rotate so as to discharge materials, and the material receiving power piece is used for driving the material receiving piece 32 to rotate so as to recover the processed flower films. In order to firmly fix the material receiving member 32 and the material holding member 31, the discharging mechanism 30 further includes a third supporting member (not shown) and a fourth supporting member (not shown); the third supporting member is disposed symmetrically to the first supporting member 34, and the fourth supporting member is disposed symmetrically to the second supporting member 35. In order to adjust the pre-tightening force of the flower film 90 and ensure the transfer effect, the discharging mechanism 30 further includes a first fixing member 36, a first pulley 37 connected to the first fixing member 36, a first supporting wheel 38 connected to the first fixing member 36, a second fixing member (not shown), a second pulley (not shown) connected to the second fixing member, and a second supporting wheel (not shown) connected to the second fixing member; the flower film 90 slides from the material placing member 31 to the upper side of the first positioning member 24 through the first pulley 37 and the first supporting wheel 38, and is recovered by the material receiving member 32 through the second supporting wheel and the second pulley. Alternatively, the first fixing member 36 and the second fixing member, the first pulley 37 and the second pulley, and the first supporting wheel 38 and the second supporting wheel have the same structure. Further, there are a plurality of first fixing members and a plurality of second fixing members, a plurality of first pulleys 37 and a plurality of second pulleys, and a plurality of first supporting wheels 38 and a plurality of second supporting wheels.

In one embodiment, the printing mechanism 40 includes a shield 42 coupled to the heating element and a printing power element 43 coupled to the shield 42; the printing power member 43 is used to drive the roller 41 toward or away from the first positioning member 24. The heating element is arranged in the protective cover 42, and the printing power element 43 is arranged on the fixed frame 33; optionally, the roller 41 is a silicone wheel; the heating element adopts electric heating; the printing power member 43 is an air cylinder. In operation, when the printing material 80 is transferred to the lower part of the roller 41, the heating element heats the roller 41, the printing power element 43 drives the roller 41 to abut against the patterned film 90 to enable the patterned film 90 to abut against the printing material 80, and the first rotating shaft 23 drives the printing material 80 to rotate, so that the pattern on the patterned film 90 is transferred to the printing material 80. In order to adjust the position of the roller 41, the printing mechanism 40 further includes a sliding plate 44 connected to the shield 42, a first rotating plate 45 connected to the sliding plate 44, a second rotating plate 46 connected to the first rotating plate 45, and an installation plate 47 connected to the second rotating plate 46; the sliding plate 44 is used for adjusting the horizontal position of the protective cover 42 relative to the fixed frame 33; the first rotating plate 45 cooperates with the second rotating plate 46 to adjust the angle of the shield 42; the printing power member 43 is connected with the mounting plate 47, and the printing power member 43 is used for driving the mounting plate 47 to move up and down. In one embodiment, the blanking mechanism 50 includes a blanking bracket 51, a horizontal moving member 52 connected to the blanking bracket 51, and a blanking member 53 connected to the horizontal moving member 52; the horizontal moving piece 52 is arranged on the blanking bracket 51 in a sliding manner; the blanking member 53 is used to remove the substrate 80 that has been transferred to the first positioning member 24. Optionally, the blanking member 53 sucks the printing material 80 by air negative pressure. In order to realize automatic production, the blanking mechanism 50 further includes a blanking conveyer belt 54 and a blanking sensor (not shown) connected to one end of the blanking conveyer belt 54; the blanking conveyer belt 54 is used for conveying printing stocks 80 away from the blanking bracket 51; the blanking sensor is used for controlling the operation of the blanking conveyer belt 54; optionally, the blanking member 53 transfers the printing material 80, which has completed the transfer on the first positioning member 24, to the blanking conveyor belt 54; the substrate 80 is placed on the blanking conveyor belt 54 vertically to avoid scratching the pattern on the substrate 80. In operation, the horizontal moving member 52 drives the discharging member 53 to move, so that the discharging member 14 transfers the printing material 80 on the first positioning member 24 to the discharging conveyer belt 54, after the discharging sensor senses the printing material 80, the discharging conveyer belt 54 starts to operate, and the printing material 80 is conveyed away from the discharging support 51 through the discharging conveyer belt 54.

The full-automatic thermal transfer printing equipment 100 is sequentially provided with a feeding station, a positioning station, a printing station and a discharging station; the feeding station corresponds to the material taking mechanism 10, the positioning station is arranged on one side of the feeding station, the printing station corresponds to the printing mechanism 40, and the discharging station corresponds to the discharging mechanism 50. In order to improve the transfer quality, the full-automatic thermal transfer apparatus 100 further includes a control mechanism 60; the control mechanism 60 includes a positioning sensor 61; the registration sensor 61 cooperates with the first shaft 23 to adjust the position of the substrate 80 on the first registration member 24. Optionally, the positioning sensor 61 is connected to the mounting plate 29, and the positioning sensor 61 corresponds to the positioning station; further, the positioning sensor 61 is an electronic optical fiber sensor, and a handle hole is formed in the side surface of the printing stock 80; in operation, the positioning sensor 61 cooperates with the first shaft 23 to position the handle aperture of the substrate 80. For automated operation, the control mechanism 60 further includes a print sensor 62; the printing sensor 62 is used for controlling the operation of the printing mechanism 40, the printing sensor 62 is connected to the mounting plate 29, and the printing sensor 62 corresponds to the feeding station; when the print sensor 62 identifies that the substrate 80 is not present on the first positioning member 24, the printing mechanism 40 will not operate when the first positioning member 24 is transferred to the printing station. The control mechanism 60 further includes an alarm sensor 63; the alarm sensor 63 is matched with the blanking mechanism 50 to control the operation of the turntable 21; the alarm sensor 63 is connected to the mounting plate 29, and the alarm sensor 63 corresponds to the blanking station; when the alarm sensor 63 recognizes that the blanking is abnormal, the turntable 21 stops to remind the user of processing.

When the full-automatic thermal transfer printing equipment 100 is used, a printing stock 80 is conveyed to one side of the fixed frame 33 through the material taking conveying belt 15, the material taking part 14 takes materials and puts the materials into the first positioning part 24 of the feeding station, the first positioning part 24 provided with the printing stock 80 moves to the positioning station along with the rotary table 21, and the positioning sensor 61 is matched with the first rotary shaft 23 to position and adjust the lifting handle hole of the printing stock 80; after the positioning is finished, the first positioning member 24 moves to a printing station along with the turntable 21, the printing power member 43 pushes the roller 41 heated by the heating member to abut against the patterned film 90 and the first positioning member 24, and meanwhile, the first rotating shaft 23 drives the printing stock 80 to rotate, so that the pattern on the patterned film 90 is transferred to the printing stock 80; after the transfer is completed, the first positioning member 24 moves to a blanking station along with the turntable 21, and the blanking member 53 transfers the printing stock 80 to the blanking conveyer belt 54 to be conveyed to other stations, so that the automatic transfer is completed. In this embodiment, when the first positioning element 24 is located at the feeding station, the second positioning element is located at the positioning station, the third positioning element is located at the printing station, and the fourth positioning element is located at the discharging station; along with the rotation of carousel 21, first setting element 24, second setting element, third setting element and fourth setting element switch over the position in proper order, realize getting material, location, printing simultaneously and unloading, accomplish the back simultaneously, carousel 21 fast rotation switches over the station, raises the efficiency. The full-automatic thermal transfer printing equipment 100 saves labor cost and realizes unmanned production; the printing stock 80 is directly connected with the material taking conveyer belt 15 from the production line, so that the time is saved, and the yield is improved; compared with the screen printing process, the thermal transfer printing process is environment-friendly and has less harm to the body of a user.

The utility model discloses a full-automatic heat transfer equipment 100 places stock 80 in first locating piece 24 through extracting mechanism 10, and gyro wheel 41 butt floral pattern 90 and first locating piece 24 after the heating, simultaneously, first pivot 21 drives the first locating piece 24 that is equipped with stock 80 and rotates to make pattern rendition on the floral pattern 90 to the stock 80 on, the stock 80 that unloading mechanism 50 will accomplish the rendition again takes off, realizes full automatic processing. The full-automatic heat transfer printing equipment 100 has high automation degree, improves the production efficiency and improves the quality.

The technical features of the embodiments described above may be arbitrarily combined, and for the sake of brevity, all possible combinations of the technical features in the embodiments described above are not described, but should be considered as being within the scope of the present specification as long as there is no contradiction between the combinations of the technical features.

The above-mentioned embodiments only represent some embodiments of the present invention, and the description thereof is specific and detailed, but not to be construed as limiting the scope of the present invention. It should be noted that, for those skilled in the art, without departing from the spirit of the present invention, several variations and modifications can be made, which are within the scope of the present invention. Therefore, the protection scope of the present invention should be subject to the appended claims.

Claims (10)

1. A full-automatic thermal transfer printing device is characterized by comprising a material taking mechanism, a limiting mechanism, a material discharging mechanism, a printing mechanism and a discharging mechanism; the material taking mechanism is used for placing the printing stock on the limiting mechanism; the limiting mechanism comprises a rotary table, a first fixing piece connected with the rotary table, a first rotating shaft connected with the first fixing piece, and a first positioning piece connected with the first rotating shaft; the shape of the first positioning piece is correspondingly matched with the printing stock; the discharging mechanism is used for placing the flower film; the printing mechanism comprises a roller and a heating element connected with the roller; the roller heated by the heating element is abutted against the flower film to transfer the pattern on the flower film to a printing stock; the blanking mechanism is used for taking down the printing stock which is transferred on the first positioning piece.

2. The full-automatic thermal transfer printing apparatus according to claim 1, wherein the position limiting mechanism further comprises a first connecting plate connecting the turntable and a first adjusting member connecting the first connecting plate and the turntable; one end of the first connecting plate is connected with the first fixing piece, and the other end of the first connecting plate is connected with the rotary disc through the first adjusting piece.

3. The full-automatic thermal transfer apparatus according to claim 1, further comprising a control mechanism; the control mechanism comprises a positioning sensor; the positioning sensor is matched with the first rotating shaft to adjust the position of the printing stock on the first positioning piece.

4. The fully automatic thermal transfer apparatus of claim 3, wherein the control mechanism further comprises a print sensor; the print sensor is used to control the operation of the printing mechanism.

5. The full-automatic thermal transfer apparatus according to claim 3, wherein said control mechanism further comprises an alarm sensor; the alarm sensor is matched with the blanking mechanism to control the operation of the turntable.

6. The fully automatic thermal transfer apparatus of claim 1, wherein the printing mechanism comprises a shield coupled to the heating element and a printing power coupled to the shield; the printing power part is used for driving the roller to be close to or far away from the first positioning part.

7. The fully automatic thermal transfer apparatus of claim 6, wherein the printing mechanism further comprises a sliding plate coupled to the protective cover, a first rotating plate coupled to the sliding plate, a second rotating plate coupled to the first rotating plate, and a mounting plate coupled to the second rotating plate; the sliding plate is used for adjusting the horizontal position of the protective cover; the first rotating plate is matched with the second rotating plate to adjust the angle of the protective cover; the printing power part is connected with the mounting plate.

8. The full-automatic thermal transfer printing equipment according to claim 1, wherein the discharging mechanism comprises a material placing part and a material receiving part; one end of the flower film is connected with the material placing part, and the other end of the flower film is connected with the material receiving part.

9. The full-automatic thermal transfer printing equipment according to claim 1, wherein the material taking mechanism comprises a material taking bracket, a longitudinal sliding plate connected with the material taking bracket, a horizontal sliding plate connected with the longitudinal sliding plate, and a material taking piece connected with the horizontal sliding plate; the longitudinal sliding plate is arranged on the material taking bracket in a sliding manner, and the horizontal sliding plate is arranged on the longitudinal sliding plate in a sliding manner; the material taking part is used for placing the printing stock on the first positioning part.

10. The full-automatic thermal transfer printing equipment according to claim 1, wherein the blanking mechanism comprises a blanking support, a horizontal moving member connected with the blanking support, and a blanking member connected with the horizontal moving member; the horizontal moving piece is arranged on the blanking bracket in a sliding manner; the blanking piece is used for taking down the printing stock which is transferred on the first positioning piece.

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