CN114571845B

CN114571845B - Thermal transfer printing device for green and environment-friendly printing

Info

Publication number: CN114571845B
Application number: CN202210203079.2A
Authority: CN
Inventors: 吴菊菊
Original assignee: Shenzhen Yongyixin Packing Technology Co ltd
Current assignee: Shenzhen Yongyixin Packing Technology Co ltd
Priority date: 2022-03-02
Filing date: 2022-03-02
Publication date: 2023-12-29
Anticipated expiration: 2042-03-02
Also published as: CN114571845A

Abstract

The invention discloses a thermal transfer printing method for green and environment-friendly printing, which belongs to the technical field of thermal transfer printing and comprises a thermal transfer printing component, wherein an replacing component is arranged on the thermal transfer printing component, a driving component is further arranged between the replacing component and the thermal transfer printing component, a material conveying component is further arranged at the position, corresponding to the replacing component, of the front side of the thermal transfer printing component, and a material conveying component is further arranged between the material conveying component and the thermal transfer printing component. According to the invention, through the designed heat transfer printing component and replacement component, the stability of the rotary platform of the heat transfer printing ironing mechanism in the descending process can be ensured, the heat transfer printing ironing mechanism is utilized to print plastic barrels or other products on the second inner sleeve barrel, the continuity of the heat transfer printing ironing mechanism in the running process is effectively improved, the processing efficiency of heat transfer printing is accelerated, the production efficiency is greatly improved, and the product quality is also increased along with the heat transfer printing; these all are favorable to reducing manufacturing cost, promote enterprise competitiveness.

Description

Thermal transfer printing device for green and environment-friendly printing

Technical Field

The invention relates to the technical field of thermal transfer printing, in particular to a thermal transfer printing device for green and environment-friendly printing.

Background

Thermal transfer printing is an emerging printing process, which has been introduced abroad for a period of no more than 10 years. The process printing mode is divided into two parts of transfer printing film printing and transfer printing processing, the transfer printing film printing adopts dot printing (the resolution ratio reaches 300 dpi), patterns are printed on the surface of the film in advance, the printed patterns are rich in layering, bright in color, changeable in all manner, small in color difference and good in reproducibility, the required effect of a designer can be achieved, and the process printing technology is suitable for mass production.

The invention patent in the technical field of partial heat transfer printing is disclosed in the prior art, wherein the invention patent with the application number of CN111688340A discloses a heat transfer printing device for printing the surface of a plastic barrel, the technical problem solved by the patent is that at present, most of the heat transfer printing device is used for printing patterns on a heat transfer printing film on the plastic barrel, firstly, people are required to sleeve the plastic barrel at a designated position on the heat transfer printing device, then, the heat transfer printing film is manually sleeved on the plastic barrel, and the patterns are started to be printed on the circumference of the surface of the plastic barrel, so that the operation is troublesome, in the printing process, people are required to press the heat transfer printing film by hands to avoid wrinkling, the time is long, the labor is wasted, and the problem is solved by the mutual cooperation of structures such as a designed first spring, a driving assembly, an electric heating roller, a second clamping rod and the like.

In the prior art, when printing the plastic drum, the plastic drum to be printed is usually sheathed on the supporting roller shaft manually, then the designed content on the thermal transfer film is printed on the plastic drum by utilizing the thermal transfer ironing mechanism, and the plastic drum is manually installed, so that the working strength is high, the installation accuracy is low, and the malposition phenomenon of the printed content is easy to occur.

Based on the above, the invention designs a thermal transfer device for green and environment-friendly printing to solve the above problems.

Disclosure of Invention

The present invention is directed to a thermal transfer device for green printing, which solves the above-mentioned drawbacks of the prior art.

In order to achieve the above purpose, the present invention provides the following technical solutions: the heat transfer printing device for green environment-friendly printing comprises a heat transfer printing component, wherein an replacing component is arranged on the heat transfer printing component, a driving component is further arranged between the replacing component and the heat transfer printing component, a material conveying component is further arranged at the position, corresponding to the replacing component, of the front side of the heat transfer printing component, a material feeding component is further arranged between the material conveying component and the heat transfer printing component, and a material discharging component is further arranged between the heat transfer printing component and the replacing component;

the heat transfer printing assembly comprises a workbench, an adjustable carrying platform is arranged at the top of the workbench, and a passing connection port is formed in the top of the adjustable carrying platform;

the utility model provides a change subassembly includes rotary platform, rotary platform's top is through shock pad fixedly connected with biax motor, a first inboard section of thick bamboo and a second inboard section of thick bamboo of cup jointing of fixedly connected with on two output shafts of biax motor respectively, rotary platform's bottom fixedly connected with upper strata switching axle, upper strata switching axle's surface is rotated through the bearing and is connected at rotary platform's top, switching device and elastic support device's one end fixed connection are passed through to upper strata switching axle's bottom, elastic support device's the other end is rotated and is connected in the interface of turning offered at lower floor switching axle top, still be provided with backstop device on lower floor switching axle's the surface to drive assembly sets up and is used for providing driving force for the change subassembly between heat transfer ironing machine and the lower floor switching axle.

As a further scheme of the invention, the two sides of the top of the workbench are respectively and fixedly connected with a heat transfer film release mechanism and a heat transfer film winding mechanism, and the heat transfer ironing mechanism is arranged above the heat transfer film winding mechanism and the heat transfer film release mechanism.

As a further scheme of the invention, the switching device comprises an inner joint shaft, the top of the inner joint shaft is fixedly connected with the bottom end of the upper switching shaft, the surface of the inner joint shaft is sleeved with an outer joint shaft sleeve, the inner side wall of the outer joint shaft sleeve is provided with a switching groove, the position of the surface of the inner joint shaft corresponding to the switching groove is also clamped with the switching groove, and the same switching bead is embedded between the two opposite switching grooves.

As a further scheme of the invention, the elastic supporting device comprises an inner telescopic shaft, the top end of the inner telescopic shaft is fixedly connected to the bottom of an outer joint shaft sleeve, the surface of the inner telescopic shaft is sleeved with the outer joint shaft sleeve, the bottom of the inner side of the outer joint shaft sleeve is fixedly connected with one end, close to the inner telescopic shaft, of the inner telescopic shaft through an inner spring, and the bottom end of the outer joint shaft sleeve is rotatably connected in a switching groove formed in the top end of a lower switching shaft through a pin shaft.

As a further scheme of the invention, the backstop device comprises a backstop sleeve, the top of the backstop sleeve is clamped at the top of the inner side of the workbench, a plurality of outer arc bodies which are arranged in an annular array are arranged on the inner side of the backstop sleeve, one surface of each outer arc body, which is far away from the lower layer switching shaft, is fixedly connected with the inner side wall of the backstop sleeve through a backstop spring, the same inner arc body is embedded between two adjacent outer arc bodies, and the inner arc bodies are fixedly connected with the surface of the lower layer switching shaft.

As a further scheme of the invention, the driving assembly comprises a linkage gear, the bottom end of the lower layer switching shaft is rotationally connected to the bottom of the inner side of the workbench through a bearing, a unidirectional driving toothed plate is meshed on the surface of the linkage gear, a wedge-shaped seat is fixedly connected to the side end face of the unidirectional driving toothed plate, rolling balls are connected to the inclined face of the wedge-shaped seat in a rolling way, the rolling balls are connected in a ball groove formed in the bottom end of the driving shaft in a rolling way, a sliding connecting sleeve is sleeved on the surface of the driving shaft and is clamped at the top of the workbench, the top end of the driving shaft is fixedly connected to the bottom of the thermal transfer ironing mechanism, a first sliding connecting groove is formed in the bottom of the wedge-shaped seat, a first sliding connecting seat is connected in a sliding way in the first sliding connecting groove, and the top of the first sliding connecting seat is fixedly connected with the bottom of the inner side of the workbench through a first supporting spring and the end face of the inner side of the first sliding connecting groove.

As a further scheme of the invention, the unidirectional driving toothed plate is formed by combining and connecting a spring hinge, a toothed plate and teeth, and the teeth are hinged with the toothed plate through the spring hinge.

As a further scheme of the invention, the material conveying component comprises a rack, the rack is arranged at the front side of the workbench, a transmission belt is arranged on the rack, an arc-shaped groove is formed in the position, corresponding to the first inner side sleeve barrel and the second inner side sleeve barrel, of the top of the rack, an arc-shaped clamping sleeve is connected in a sliding manner in the arc-shaped groove, a second sliding connecting groove is formed in the bottom of the arc-shaped clamping sleeve, a second sliding connecting seat is connected in the second sliding connecting groove in a sliding manner, and the bottom of the second sliding connecting seat is fixedly connected to the bottom of the inner side of the arc-shaped groove.

As a further scheme of the invention, the feeding component comprises a driving seat, the driving seat is fixedly connected to the front end face of the thermal transfer ironing mechanism, an inclined shaft is rotatably connected in a rotating interface formed in the front end face of the driving seat through a pin shaft, one end of the inclined shaft, which is far away from the driving seat, is rotatably connected in the rotating interface formed in the front end face of the upper pushing plate through a pin shaft, the bottom of the upper pushing plate is fixedly connected with a third sliding connecting seat, the third sliding connecting seat is slidably connected in a third sliding connecting groove formed in the top of the lower pushing plate, and one surface, close to the third sliding connecting seat, of the inner side wall of the third sliding connecting groove is fixedly connected with one surface, close to the third sliding connecting seat, of the third sliding connecting seat through a third supporting spring.

As a further scheme of the invention, the blanking assembly comprises a blanking shaft, the top end of the blanking shaft is rotationally connected to the end face of the rear side of the thermal transfer ironing mechanism through a spring pin shaft, the other end of the blanking shaft is rotationally connected to the top of a blanking arc-shaped piece through a spring pin shaft, and the blanking arc-shaped piece is arranged above the first inner sleeve barrel or the second inner sleeve barrel.

Compared with the prior art, the invention has the beneficial effects that:

1. the invention, through the designed heat transfer assembly and the replacement assembly, after the heat transfer film on the heat transfer film releasing mechanism is windingly connected on the heat transfer film winding mechanism, the heat transfer film winding mechanism is controlled to operate, and then the heat transfer film on the heat transfer film releasing mechanism can be driven to flow towards the direction of the heat transfer film winding mechanism, in the process, the heat transfer ironing mechanism is also required to be synchronously controlled to approach towards the direction of the first inner sleeve until the heat transfer film is hot-pressed on the outer cylinder wall of the plastic cylinder sleeved on the surface of the first inner sleeve, thereby the content designed on the heat transfer film can be printed on the plastic cylinder or other products positioned on the first inner sleeve, after the primary printing is completed, the heat transfer ironing mechanism is controlled to perform the ascending motion, the driving shaft is driven by the heat transfer ironing mechanism to drive the rolling beads to move towards the direction far away from the wedge-shaped seat, under the action of the reset spring, the wedge-shaped seat can drive the unidirectional driving plate to move towards the direction far away from the linkage gear, the wedge-shaped driving plate can be converted into the ascending motion by utilizing the effect between the gear and the unidirectional driving toothed plate, the bidirectional driving plate, the electric motor can rotate to rotate at the inner side of the first inner sleeve, the upper sleeve is driven by the two-shaped rotating shafts, the upper sleeve is driven by the spindle sleeve, the upper spindle is driven by the spindle, the spindle is driven by the spindle, and the spindle rotates to rotate, and the spindle is driven by the spindle, and the spindle, rotates and the spindle, the special property of the wedge-shaped seat inclined surface structure is utilized when the heat transfer printing ironing mechanism drives the driving shaft and the rolling beads on the driving shaft to approach to the wedge-shaped seat, so that the unidirectional driving toothed plate can be pushed to approach to the direction of the linkage gear by the wedge-shaped seat; these all are favorable to reducing manufacturing cost, promote enterprise competitiveness.

2. According to the invention, through the designed replacement component, the adjustable carrying platform has the front-back and up-down adjusting functions, and the replacement component is internally provided with the upper layer switching shaft and the lower layer switching shaft, and the switching device and the elastic supporting device are used as connecting media between the upper layer switching shaft and the lower layer switching shaft, so that the upper layer switching shaft and the lower layer switching shaft can have a certain telescopic function on the basis of having an angle adjusting function, and further can adapt to the adjusting process of the adjustable carrying platform, and the adjustable carrying platform has high flexibility and strong adaptability.

3. According to the invention, through the designed material conveying component and material conveying component, the conveying belt can convey plastic barrels or other products into the arc-shaped clamping sleeve, after the plastic barrels or other products are conveyed into the arc-shaped clamping sleeve, the thermal transfer ironing mechanism is in a descending state, the driving seat applies backward thrust to the upper pushing plate by using the inclined shaft, and as the third sliding connecting seat, the third supporting spring and the third sliding connecting seat are used as connecting media between the upper pushing plate and the lower pushing plate, the upper pushing plate pushes the plastic barrels in the arc-shaped clamping sleeve to approach in the direction of the first inner sleeve or the second inner sleeve through the lower pushing plate when the upper pushing plate is acted by the thrust, and then the upper pushing plate is used for approaching in the direction of the first inner sleeve or the second inner sleeve, so that a new plastic barrel is sleeved on the first inner sleeve or the second inner sleeve, the pushing distance is fixed, the relative stability of the position between the plastic barrels and the thermal transfer ironing mechanism is effectively ensured, the content on the thermal transfer film can be printed on the surface of the plastic barrel more accurately, the thermal transfer mechanism is not required to be scalded, and the thermal transfer mechanism is not required to be lowered, and the thermal transfer mechanism is not required to be affected simultaneously.

4. According to the invention, through the designed blanking assembly, the thermal transfer ironing mechanism drives the blanking arc piece to approach to the direction of the first inner sleeve barrel or the second inner sleeve barrel which is moved to the rear side through the blanking shaft in the descending process, so that the plastic barrel on the first inner sleeve barrel or the second inner sleeve barrel which is moved to the rear side can be detached by utilizing the blanking arc piece, and the working efficiency is further improved.

Drawings

FIG. 1 is a schematic diagram of the overall structure of the present invention;

FIG. 2 is a schematic diagram of an alternate assembly according to the present invention;

FIG. 3 is a schematic view of a medial joint shaft according to the present invention;

FIG. 4 is a schematic cross-sectional view of the elastic support device of the present invention;

FIG. 5 is a schematic diagram of a driving assembly according to the present invention;

FIG. 6 is a schematic top view of a non-return device according to the present invention;

FIG. 7 is a schematic diagram of an adjustable loading platform according to the present invention;

FIG. 8 is a schematic view of a split structure of a feeding assembly according to the present invention;

FIG. 9 is a schematic view of an arc ferrule of the present invention;

fig. 10 is a schematic structural diagram of a blanking assembly in the present invention.

In the drawings, the list of components represented by the various numbers is as follows:

1. a thermal transfer assembly; 101. a work table; 102. a thermal transfer film release mechanism; 103. a thermal transfer film winding mechanism; 104. a thermal transfer ironing mechanism; 105. an adjustable carrying platform; 106. passing through the connecting port; 2. An replacement component; 201. a rotary platform; 202. a biaxial motor; 203. a first inner sleeve; 204. a second inner sleeve; 205. an upper layer switching shaft; 206. a switching device; 2061. a medial joint axis; 2062. an outer joint sleeve; 2063. a transfer groove; 2064. a transfer bead; 207. an elastic supporting device; 2071. an inner telescopic shaft; 2072. an outer telescopic sleeve; 2073. an inner spring; 208. a lower layer transfer shaft; 209. a backstop device; 2091. a non-return sleeve; 2092. an outer arc body; 2093. a backstop spring; 2094. an inner arc body; 3. a drive assembly; 301. a unidirectional driving toothed plate; 302. a linkage gear; 303. a wedge-shaped seat; 304. rolling the beads; 305. a drive shaft; 306. a first sliding connection groove; 307. a first sliding connection seat; 308. a first support spring; 4. a material conveying component; 401. a frame; 402. a transmission belt; 403. arc-shaped cutting ferrule; 404. a second sliding connection groove; 405. the second sliding connecting seat; 406. a second support spring; 5. a feeding assembly; 501. A driving seat; 502. a shaft is obliquely arranged; 503. an upper pushing plate; 504. a lower pushing plate; 505. a third sliding connection seat; 506. a third sliding connection groove; 507. a third support spring; 6. a blanking assembly; 601. a blanking shaft; 602. and blanking the arc-shaped piece.

Description of the embodiments

Referring to fig. 1-10, the present invention provides a technical solution: the utility model provides a heat transfer device for green printing, includes heat transfer component (1), be provided with on heat transfer component (1) and replace subassembly (2) to still be provided with drive assembly (3) between replacement subassembly (2) and heat transfer component (1), heat transfer component (1) front side corresponds the position department of replacing subassembly (2) still is provided with material conveying subassembly (4), still be provided with feeding subassembly (5) between material conveying subassembly (4) and heat transfer component (1), still be provided with unloading subassembly (6) between heat transfer component (1) and the replacement subassembly (2);

the heat transfer printing assembly (1) comprises a workbench (101), an adjustable carrying platform (105) is arranged at the top of the workbench (101), and a passing connection port (106) is formed in the top of the adjustable carrying platform (105);

the replacement component (2) comprises a rotary platform (201), the top of the rotary platform (201) is fixedly connected with a double-shaft motor (202) through a shock pad, two output shafts of the double-shaft motor (202) are respectively fixedly connected with a first inner sleeve joint cylinder (203) and a second inner sleeve joint cylinder (204), the bottom of the rotary platform (201) is fixedly connected with an upper layer switching shaft (205), the surface of the upper layer switching shaft (205) is rotationally connected to the top of the rotary platform (201) through a bearing, the bottom end of the upper layer switching shaft (205) is fixedly connected with one end of an elastic supporting device (207) through a switching device (206), the other end of the elastic supporting device (207) is rotationally connected to a switching interface formed in the top of a lower layer switching shaft (208), a backstop device (209) is further arranged on the surface of the lower layer switching shaft (208), and a driving component (3) is arranged between a thermal transfer ironing mechanism (104) and the lower layer switching shaft (208) and is used for providing driving force for the replacement component (2).

Specifically, as shown in fig. 2-7, two sides of the top of the workbench (101) are fixedly connected with a thermal transfer film release mechanism (102) and a thermal transfer film winding mechanism (103) respectively, the thermal transfer ironing mechanism (104) is arranged above the thermal transfer film winding mechanism (103) and the thermal transfer film release mechanism (102), the switching device (206) comprises an inner telescopic shaft (2061), the top of the inner telescopic shaft (2061) is fixedly connected with the bottom end of the upper switching shaft (205), the surface of the inner telescopic shaft (2061) is sleeved with an outer side joint shaft sleeve (2062), the inner side wall of the outer side joint shaft sleeve (2062) is provided with a switching groove (2063), the position of the surface of the inner side joint shaft (2061) corresponding to the switching groove (2063) is also provided with a switching bead (2064) in a clamped manner, the elastic supporting device (207) comprises an inner side telescopic shaft (2071), the top end of the inner side telescopic shaft (2061) is fixedly connected with the bottom of the upper switching shaft (205) at the bottom of the outer side joint shaft sleeve (2062), the inner side joint shaft (2062) is fixedly connected with one end of the inner side joint shaft (2072) by the bottom of the inner side joint shaft (2062), the bottom end of the outer joint shaft sleeve (2062) is rotationally connected in a switching groove (2063) formed in the top end of the lower layer switching shaft (208) through a pin shaft.

The embodiment is specifically as follows: after the heat transfer film on the heat transfer film release mechanism (102) is wound and connected on the heat transfer film winding mechanism (103), the heat transfer film winding mechanism (103) is controlled to operate, so that the heat transfer film on the heat transfer film release mechanism (102) can be driven to flow towards the heat transfer film winding mechanism (103), in the process, the heat transfer ironing mechanism (104) is also required to be synchronously controlled to approach towards the first inner sleeve barrel (203) until the heat transfer film is hot-pressed on the outer barrel wall of the plastic barrel sleeved on the surface of the first inner sleeve barrel (203), so that the designed content on the heat transfer film can be printed on the plastic barrel or other products positioned on the first inner sleeve barrel (203), after primary printing is finished, the heat transfer ironing mechanism (104) is controlled to perform lifting action, the plastic barrel or other products on the second inner sleeve barrel (204) are printed by the heat transfer ironing mechanism (104), the continuity in the operation process of the heat transfer ironing mechanism (104) is effectively improved, the production efficiency of heat transfer printing is accelerated, and the processing quality is greatly improved; these all are favorable to reducing manufacturing cost, promote enterprise competitiveness.

Specifically, as shown in fig. 2, 3 and 6, the backstop device (209) comprises a backstop sleeve (2091), the top of the backstop sleeve (2091) is clamped at the top of the inner side of the workbench (101), a plurality of outer arc bodies (2092) arranged in an annular array are arranged at the inner side of the backstop sleeve (2091), one surface of the outer arc bodies (2092) far away from the lower layer switching shaft (208) is fixedly connected with the inner side wall of the backstop sleeve (2091) through a backstop spring (2093), the same inner arc body (2094) is embedded between two adjacent outer arc bodies (2092), the inner arc bodies (2094) are fixedly connected to the surface of the lower layer switching shaft (208), the driving assembly (3) comprises a linkage gear (302), the bottom end of the lower layer switching shaft (208) is rotatably connected to the bottom of the inner side of the workbench (101) through a bearing, the surface of the linkage gear (302) is meshed with a unidirectional driving toothed plate (301), the upper end surface of the unidirectional driving toothed plate (301) is fixedly connected with the inner side wall of the backstop sleeve (2092), the inner arc body (2094) is fixedly connected with the surface of the lower layer switching shaft (208), the inner arc body (208) is connected with the rolling balls (208) in rolling balls (303) in the rolling seat (303) in rolling seat, rolling balls (303) are connected on the rolling balls (303) in rolling seat (303), and top fixed connection of drive shaft (305) scalds the bottom of pressing mechanism (104) at the heat transfer printing, first sliding connection groove (306) have been seted up to the bottom of wedge seat (303), sliding connection has first sliding connection seat (307) in first sliding connection groove (306), the top of first sliding connection seat (307) is with the bottom fixed connection of workstation (101) inboard, the side end face of first sliding connection seat (307) is through first supporting spring (308) and the terminal surface fixed connection of first sliding connection groove (306) inboard, unidirectional drive pinion rack (301) are by spring hinge, pinion rack and tooth composite connection, the tooth is articulated with the pinion rack through the spring hinge.

The embodiment is specifically as follows: under the action of the reset elastic force of the first supporting spring (308), the wedge-shaped seat (303) drives the unidirectional driving toothed plate (301) to move away from the linkage gear (302), the linear force on the wedge-shaped seat (303) can be converted into torsion force and acts on the lower layer transfer shaft (208) by utilizing the linkage effect between the linkage gear (302) and the unidirectional driving toothed plate (301), the lower layer transfer shaft (208) drives the inner side joint shaft (2061) on the inner side of the outer side joint shaft sleeve (2062) through the elastic supporting device (207), the inner side joint shaft (2061) also drives the biaxial motor (202) fixedly connected with the top of the rotary platform (201) to rotate on the horizontal plane through the upper layer transfer shaft (205), the position between the first inner side sleeve (203) and the second inner side sleeve (204) is driven by the two output shafts of the linkage gear (202), the upper layer transfer shaft (305) is driven by the upper layer transfer shaft (305) to the heat transfer roller (305) to the position closest to the wedge-shaped seat (303) when the inner side joint shaft (2062) is moved up to the inner side joint shaft (2061) through the elastic supporting device (207), utilize the particularity of wedge seat (303) inclined plane structure, and then just can promote unidirectional drive pinion rack (301) to be close to the direction of linkage gear (302) through wedge seat (303), owing to be the link medium between the two with the spring hinge between pinion rack and the tooth on unidirectional drive pinion rack (301), have unidirectional drive function, and still be provided with inboard arc body (2094), outside arc body (2092) and backstop spring (2091) between lower floor's switching axle (208), make lower floor's switching axle (208) received torsion less under the circumstances still be in still static state, thereby just can guarantee the stability of heat transfer ironing mechanism (104) in-process rotation platform (201) down.

Specifically, as shown in fig. 8 and 9, the material conveying component (4) comprises a frame (401), the frame (401) is arranged at the front side of the workbench (101), a transmission belt (402) is arranged on the frame (401), an arc groove is formed at the position, corresponding to the first inner sleeve (203) and the second inner sleeve (204), of the top of the frame (401), an arc clamping sleeve (403) is connected in a sliding manner in the arc groove, a second sliding connecting groove (404) is formed at the bottom of the arc clamping sleeve (403), a second sliding connecting seat (405) is connected in a sliding manner in the second sliding connecting groove (404), the bottom of the second sliding connecting seat (405) is fixedly connected at the bottom of the inner side of the arc groove, the material conveying component (5) comprises a driving seat (501), the driving seat (501) is fixedly connected on the front end face of the thermal transfer ironing mechanism (104), an inclined shaft (502) is connected in a rotating manner through a pin shaft in a rotating manner in a switching interface formed on the front end face of the driving seat (501), the inclined shaft (502) is pushed by a pin shaft (502) to push a third sliding plate (503) to be connected with the bottom of the driving seat (503) at one end of the driving plate (503), the third sliding connecting seat (505) is slidably connected in a third sliding connecting groove (506) formed in the top of the lower pushing plate (504), and one surface, close to the third sliding connecting seat (505), of the inner side wall of the third sliding connecting groove (506) is fixedly connected through a third supporting spring (507).

The embodiment is specifically as follows: the upper pushing plate (503) and the lower pushing plate (504) are further connected by a third sliding connecting seat (505), a third supporting spring (507) and a third sliding connecting seat (505) as connecting media between the upper pushing plate and the lower pushing plate, so that the upper pushing plate (503) can push the plastic barrel in the arc-shaped cutting sleeve (403) to approach the direction of the first inner sleeve barrel (203) or the second inner sleeve barrel (204) through the lower pushing plate (504) when being acted by pushing force, then the upper pushing plate (503) is utilized to approach the direction of the first inner sleeve barrel (203) or the second inner sleeve barrel (204), a new plastic barrel can be sleeved on the first inner sleeve barrel (203) or the second inner sleeve barrel (204), the pushing distance is fixed, the relative stability of the position between the plastic barrel and the thermal transfer ironing mechanism (104) is effectively ensured, the content on the thermal transfer film can be printed on the surface of the plastic barrel more accurately, the manual feeding is not only needed, the working strength of workers is reduced, and meanwhile, the thermal transfer mechanism (104) can be prevented from being scalded.

Specifically, as shown in fig. 10, the blanking assembly (6) comprises a blanking shaft (601), the top end of the blanking shaft (601) is rotationally connected to the rear end face of the thermal transfer ironing mechanism (104) through a spring pin, the other end of the blanking shaft (601) is rotationally connected to the top of a blanking arc piece (602) through a spring pin, and the blanking arc piece (602) is arranged above the first inner sleeve barrel (203) or the second inner sleeve barrel (204).

The embodiment is specifically as follows: in the downlink process, the thermal transfer ironing mechanism (104) drives the blanking arc piece (602) to approach to the direction of the first inner sleeve barrel (203) or the second inner sleeve barrel (204) which move to the rear side through the blanking shaft (601), so that the plastic barrel on the first inner sleeve barrel (203) or the second inner sleeve barrel (204) which move to the rear side can be detached by using the blanking arc piece (602), and the working efficiency is further improved.

Working principle: after the heat transfer film on the heat transfer film release mechanism (102) is wound and connected on the heat transfer film winding mechanism (103), the heat transfer film winding mechanism (103) is controlled to operate, further, the heat transfer film on the heat transfer film release mechanism (102) can be driven to flow towards the heat transfer film winding mechanism (103), in the process, the heat transfer ironing mechanism (104) is also required to be synchronously controlled to approach towards the first inner sleeve barrel (203) until the heat transfer film is hot-pressed on the outer barrel wall of the plastic barrel sleeved on the surface of the first inner sleeve barrel (203), so that the designed content on the heat transfer film can be printed on the plastic barrel or other products positioned on the first inner sleeve barrel (203), after one-time printing is completed, the heat transfer ironing mechanism (104) is controlled to perform ascending action, a driving shaft (305) is driven to drive rolling beads (304) to move towards a direction far away from a wedge-shaped seat (303), under the reset elastic force of a first supporting spring (308), the wedge-shaped seat (303) can drive a gear plate (301) to move towards a linear linkage torque force between a gear (301) and a lower linkage plate (301) by utilizing the action of a linear torque force of the upper linkage plate (301), the lower layer changeover shaft (208) drives the inner side joint shaft (2061) at the inner side of the outer side joint shaft sleeve (2062) to rotate through the elastic supporting device (207), the double-shaft motor (202) fixedly connected with the top of the rotary platform (201) is driven by the upper layer changeover shaft (205) to rotate on the horizontal plane when the inner side joint shaft (2061) rotates, the positions of the first inner side sleeve (203) and the second inner side sleeve (204) are interchanged under the driving of the double-shaft motor (202), the thermal transfer ironing mechanism (104) rises to the highest position and then performs the descending motion, as the thermal transfer ironing mechanism (104) drives the driving shaft (305) and the rolling beads (304) on the driving shaft (305) to approach the direction of the wedge-shaped seat (303), the unidirectional driving toothed plate (301) can be pushed to approach the direction of the linkage gear (302) through the wedge-shaped seat (303), as the toothed plate on the unidirectional driving toothed plate (301) is driven by the springs between the teeth, the two toothed plates are connected with the inner side springs (208) to serve as hinges, and the lower arc-shaped body (2094) is still in an arc state of the lower arc-shaped body (2094) is still arranged between the lower arc-shaped body (2094) and the lower arc-shaped body (2090) is still in a state of the lower arc-shaped body (2090) is still in a state than the state, therefore, the stability of the rotary platform (201) of the thermal transfer ironing mechanism (104) in the descending process can be ensured, the thermal transfer ironing mechanism (104) is utilized to print plastic barrels or other products on the second inner side sleeve barrel (204), the continuity of the thermal transfer ironing mechanism (104) in the running process is effectively improved, the processing efficiency of thermal transfer printing is accelerated, the production efficiency is greatly improved, and the product quality is also increased along with the stability; the adjustable carrying platform (105) has the front-back and up-down adjusting functions, the switching device (206) and the elastic supporting device (207) are used as connecting media between the upper switching shaft (205) and the lower switching shaft (208) in the replacement component (2), so that the upper switching shaft (205) and the lower switching shaft (208) can have a certain telescopic function on the basis of the angle adjusting function, the adjustable carrying platform (105) can be adjusted, the flexibility is high, the adaptability is strong, the transmission belt (402) can transmit plastic barrels or other products into the arc-shaped cutting sleeve (403), the thermal transfer ironing mechanism (104) is in a descending state after the plastic barrels or other products are transmitted into the arc-shaped cutting sleeve (403), the driving seat (501) is used for pushing the upper pushing plate (503) backwards, the sliding plate (504) and the lower pushing plate (503) are connected with the third connecting seat (505) through the driving seat (501) by using the inclined shaft, therefore, the upper pushing plate (503) can push the plastic barrel in the arc clamping sleeve (403) to approach the first inner side sleeve barrel (203) or the second inner side sleeve barrel (204) through the lower pushing plate (504) when the upper pushing plate (503) is acted by the pushing force, then the upper pushing plate (503) is used for approaching the first inner side sleeve barrel (203) or the second inner side sleeve barrel (204), then a new plastic barrel can be sleeved on the first inner side sleeve barrel (203) or the second inner side sleeve barrel (204), the pushing distance is certain, the relative stability of the position between the plastic barrel and the thermal transfer printing mechanism (104) is effectively ensured, the content on the thermal transfer printing film can be printed on the surface of the plastic barrel more accurately, manual feeding is not needed, the working strength of workers is reduced, meanwhile, the accident that a thermal transfer printing ironing mechanism (104) causes scalding can be avoided, and in the descending process, a blanking piece (602) can be driven to move to the first inner side sleeve barrel (203) or the second inner side sleeve barrel (204) through the blanking shaft (601), and then the arc-shaped piece (602) can be further moved to the second inner side sleeve barrel (204) to the first inner side sleeve barrel (203) or the second inner side sleeve barrel (204), and the arc-shaped piece (204) can be further detached.

Claims

1. The utility model provides a heat transfer device for green printing, includes heat transfer component (1), be provided with on heat transfer component (1) and replace subassembly (2) to still be provided with drive assembly (3) between replacement subassembly (2) and heat transfer component (1), heat transfer component (1) front side corresponds the position department of replacing subassembly (2) and still is provided with material conveying subassembly (4), still be provided with feeding subassembly (5) between material conveying subassembly (4) and heat transfer component (1), still be provided with unloading subassembly (6) between heat transfer component (1) and the replacement subassembly (2), its characterized in that: the heat transfer printing assembly (1) comprises a workbench (101) and a heat transfer printing ironing mechanism (104), wherein an adjustable carrying platform (105) is arranged at the top of the workbench (101), and a passing connection port (106) is formed at the top of the adjustable carrying platform (105);

2. The thermal transfer device for green and environment-friendly printing according to claim 1, wherein: two sides of the top of the workbench (101) are fixedly connected with a thermal transfer film release mechanism (102) and a thermal transfer film winding mechanism (103) respectively, and the thermal transfer ironing mechanism (104) is arranged above the thermal transfer film winding mechanism (103) and the thermal transfer film release mechanism (102).

3. The thermal transfer device for green and environment-friendly printing according to claim 1, wherein: the switching device (206) comprises an inner joint shaft (2061), the top of the inner joint shaft (2061) is fixedly connected with the bottom end of the upper layer switching shaft (205), an outer joint shaft sleeve (2062) is sleeved on the surface of the inner joint shaft (2061), a switching groove (2063) is formed in the inner side wall of the outer joint shaft sleeve (2062), switching grooves (2063) are also clamped at the positions, corresponding to the switching grooves (2063), of the surface of the inner joint shaft (2061), and one switching bead (2064) is embedded between the two opposite switching grooves (2063).

4. The thermal transfer device for green and environment-friendly printing according to claim 1, wherein: elastic supporting device (207) are including inboard telescopic shaft (2071), the top fixed connection of inboard telescopic shaft (2071) is in the bottom of outside joint axle sleeve (2062), outside joint axle sleeve (2062) has been cup jointed on the surface of inboard telescopic shaft (2071), the inboard bottom of outside joint axle sleeve (2062) is through the one end fixed connection that inboard spring (2073) is close with inboard telescopic shaft (2071), the bottom of outside joint axle sleeve (2062) is through the round pin axle rotation connection in adapter groove (2063) that lower floor adapter shaft (208) top was seted up.

5. The thermal transfer device for green and environment-friendly printing according to claim 1, wherein: the non-return device (209) is including non-return cover (2091), the top joint of non-return cover (2091) is at the inboard top of workstation (101), the inboard of non-return cover (2091) is provided with a plurality of outside arc bodies (2092) that are annular array setting, the one side that lower floor's switching axle (208) was kept away from to outside arc body (2092) is through non-return spring (2093) and non-return cover (2091) inside wall fixed connection, and inlays between two adjacent outside arc bodies (2092) and be equipped with same inboard arc body (2094), inboard arc body (2094) fixed connection is at the surface of lower floor's switching axle (208).

6. The thermal transfer device for green and environment-friendly printing according to claim 1, wherein: the driving assembly (3) comprises a linkage gear (302), the bottom of the lower layer switching shaft (208) is rotationally connected to the bottom of the inner side of the workbench (101) through a bearing, a unidirectional driving toothed plate (301) is meshed with the surface of the linkage gear (302), a wedge-shaped base (303) is fixedly connected to the side end face of the unidirectional driving toothed plate (301), rolling balls (304) are in rolling connection with the inclined face of the wedge-shaped base (303), the rolling balls (304) are in rolling connection with the ball grooves formed in the bottom of the driving shaft (305), a sliding connecting sleeve is sleeved on the surface of the driving shaft (305), the sliding connecting sleeve is clamped to the top of the workbench (101), the top of the driving shaft (305) is fixedly connected to the bottom of the heat transfer ironing mechanism (104), a first sliding connecting groove (306) is formed in the bottom of the wedge-shaped base (303), the top of the first sliding connecting base (307) is in sliding connection with the bottom of the inner side of the workbench (101), and the first sliding connecting base (307) is fixedly connected to the first side end face of the first sliding connecting base (307) through the first sliding connecting groove (308).

7. The thermal transfer device for green and environmental protection printing of claim 6, wherein: the unidirectional driving toothed plate (301) is formed by combining and connecting a spring hinge, a toothed plate and teeth, and the teeth are hinged with the toothed plate through the spring hinge.

8. The thermal transfer device for green and environment-friendly printing according to claim 1, wherein: the conveying assembly (4) comprises a frame (401), the frame (401) is arranged on the front side of the workbench (101), a transmission belt (402) is arranged on the frame (401), an arc-shaped groove is formed in the position of the top of the frame (401) corresponding to the first inner sleeve (203) and the second inner sleeve (204), an arc-shaped clamping sleeve (403) is connected in the arc-shaped groove in a sliding mode, a second sliding connecting groove (404) is formed in the bottom of the arc-shaped clamping sleeve (403), a second sliding connecting seat (405) is connected in the second sliding connecting groove (404) in a sliding mode, and the bottom of the second sliding connecting seat (405) is fixedly connected to the bottom of the inner side of the arc-shaped groove.

9. The thermal transfer device for green and environment-friendly printing according to claim 1, wherein: the feeding assembly (5) comprises a driving seat (501), the driving seat (501) is fixedly connected to the front side end face of the thermal transfer ironing mechanism (104), an inclined shaft (502) is rotatably connected to a rotating interface formed in the front side end face of the driving seat (501) through a pin shaft, one end of the inclined shaft (502), far away from the driving seat (501), is rotatably connected to the rotating interface formed in the front side end face of an upper pushing plate (503) through a pin shaft, a third sliding connecting seat (505) is fixedly connected to the bottom of the upper pushing plate (503), the third sliding connecting seat (505) is slidably connected to a third sliding connecting groove (506) formed in the top of a lower pushing plate (504), and one side, close to the third sliding connecting seat (505), of the inner side of the third sliding connecting groove (506) is fixedly connected to a third sliding connecting seat (505) through a third supporting spring (507).

10. The thermal transfer device for green and environment-friendly printing according to claim 1, wherein: the blanking assembly (6) comprises a blanking shaft (601), the top end of the blanking shaft (601) is rotationally connected to the rear end face of the heat transfer ironing mechanism (104) through a spring pin shaft, the other end of the blanking shaft (601) is rotationally connected to the top of a blanking arc piece (602) through a spring pin shaft, and the blanking arc piece (602) is arranged above a first inner sleeve barrel (203) or a second inner sleeve barrel (204).