CN116968423A - High-precision heat transfer printing device for aluminum material processing - Google Patents

Abstract

The invention discloses a high-precision heat transfer printing device for aluminum material processing, and belongs to the technical field of heat transfer printing. The invention comprises a conveyor belt, a film rolling assembly, a film printing assembly, a moving assembly, a clamping assembly, a limiting assembly and an adjusting assembly; the conveying belt is fixedly arranged on the upper side of the conveying belt base and used for conveying the aluminum material to be processed; the film winding assembly comprises an unreeling shaft and a reeling shaft; the moving assembly is arranged on the upper side of the conveyor belt and used for moving the film printing assembly; the clamping assembly comprises a clamping supporting plate, a clamping motor and a clamping telescopic rod; the limiting assembly is arranged at the rear side of the printing film assembly and comprises a left limiting assembly and a right limiting assembly; the adjusting component is arranged at the front side of the printing film component and comprises a left adjusting component and a right adjusting component; the placement position of the aluminum material can be automatically adjusted; preventing the aluminum material from slightly moving during thermal transfer; and the pattern required by the aluminum material is thermally transferred with high precision, so that the deviation of the pattern during thermal transfer is prevented.

Description

High-precision heat transfer printing device for aluminum material processing

Technical Field

The invention belongs to the technical field of thermal transfer printing, and particularly relates to a high-precision thermal transfer printing device for aluminum material processing.

Background

Thermal transfer printing is an emerging printing technique that prints a color pattern to be printed on a thermal transfer film in advance, then attaches the thermal transfer film to a final print substrate, and heats the thermal transfer film to transfer the color on the transfer film to the print substrate.

Often need manual regulation to aluminum product position when the aluminum product carries out thermal transfer processing, lack the subassembly of automatically regulated aluminum product position of putting, the manual work is put and is led to the fact the pattern of aluminum product thermal transfer to print the position mistake easily, can't accomplish high accuracy processing. In addition, when the aluminum material is subjected to thermal transfer printing, a clamping assembly for the aluminum material is lacking, and the aluminum material is easy to slightly move during processing, so that the thermal transfer printing pattern is printed incompletely or misprinted. The existing heat transfer printing equipment is often used for processing certain specific types of aluminum materials, has low working efficiency and cannot adapt to heat transfer printing processing of various aluminum materials with different shapes.

Disclosure of Invention

The invention aims to solve the technical problem of providing a high-precision heat transfer printing device for aluminum material processing, which is provided with an adjusting component and can automatically adjust the placement position of aluminum materials; the clamping assembly and the limiting assembly are arranged, so that the aluminum material is prevented from slightly moving during thermal transfer printing; can realize the required pattern of high accuracy heat transfer printing aluminum product, prevent that the pattern from taking place the deviation when heat transfer printing to can adapt to the heat transfer printing processing of multiple different shapes aluminum product.

The utility model provides an aluminum product processing is with high accuracy heat transfer device, includes conveyer belt, book membrane module, seal membrane module, removes subassembly, clamping assembly, spacing subassembly and adjusting part.

The conveyer belt is fixed to be set up in conveyer belt base upside for the conveying waits to process the aluminum product.

The film winding assembly comprises a unreeling shaft and a reeling shaft. The unreeling shaft is arranged at the left side of the conveyor belt. The winding shaft is arranged on the right side of the conveyor belt.

The moving assembly is arranged on the upper side of the conveyor belt and used for moving the printing film assembly.

The film printing component is fixedly connected with the moving component, so that the moving component drives the film printing component to move.

The clamping assembly comprises a clamping supporting plate, a clamping motor and a clamping telescopic rod. The clamping components are symmetrically arranged on two sides of the conveyor belt. The clamping support plate is fixedly connected with the upper side of the conveyor belt. The clamping motor is fixedly arranged on the upper side of the clamping supporting plate, the output end of the clamping motor is fixedly connected with the clamping telescopic rod, and the output end of the clamping motor faces to one side of the aluminum material to be processed.

The spacing subassembly sets up in seal membrane assembly rear side, and spacing subassembly includes left spacing subassembly and right spacing subassembly. The left limiting component and the right limiting component are symmetrically arranged on two sides of the conveyor belt. The left limiting component comprises a left guide rail, a left sliding block and a left limiting rod. The left guide rail is arranged at the left side of the conveyor belt. The left slider is in sliding connection with the left guide rail. The left limiting rod is rotationally connected with the left sliding block, and the left limiting rod can rotate around the joint of the left limiting rod and the left sliding block within the range of 0-90 degrees to serve as a rotation center.

The adjusting assembly is arranged on the front side of the printing film assembly, and comprises a left adjusting assembly and a right adjusting assembly which are arranged on two sides of the conveying belt in bilateral symmetry. The left adjusting assembly comprises a left adjusting plate, a left adjusting guide rail and a left adjusting block. The left adjusting guide rail is arranged at the left side of the conveyor belt. The left adjusting block is in sliding connection with the left adjusting guide rail. The left adjusting plate is rotationally connected with the left adjusting block, and the left adjusting plate can rotate around the joint of the left adjusting plate and the left adjusting block within the range of 0-90 degrees to form a rotation center.

As a further improvement of the present invention, a thermal transfer film is provided between the unwind shaft and the wind-up shaft. The unreeling shaft is used for unreeling the thermal transfer film. The winding shaft is used for winding the thermal transfer film.

As a further improvement of the invention, the moving component comprises a thermal transfer printing bracket, an adjusting sliding block, an adjusting screw rod, an adjusting guide rod, an adjusting supporting plate and an adjusting motor. The thermal transfer support is fixedly arranged on the upper side of the conveyor belt, and the lower end of the thermal transfer support is respectively connected with the left side and the right side of the conveyor belt. The adjusting support plates are symmetrically arranged below two ends of the top wall of the thermal transfer printing support, the adjusting slide blocks are arranged between the adjusting support plates, and the adjusting slide blocks are in sliding connection with the adjusting screw rods and the adjusting guide rods. The adjusting guide rod is arranged between the adjusting support plates and above the adjusting screw rod. The adjusting motor is arranged on one side, far away from the adjusting screw rod, of the adjusting support plate, and the output end of the adjusting motor penetrates through the adjusting support plate to be connected with the adjusting screw rod.

As a further improvement of the present invention, the film printing assembly includes a hydraulic rod, a support plate, a transfer heating shell, a thermal transfer roller, and a high temperature heating layer. The hydraulic rod is arranged below the top wall of the thermal transfer printing bracket, and the upper end of the hydraulic rod is fixedly connected with the lower end of the adjusting slide block. The upper side of the supporting plate is fixedly connected with the lower end of the hydraulic rod. The transfer printing heating shell is arranged below the center of the supporting plate, and the cross section of the transfer printing heating shell is arranged in an arc shape with an opening at the lower end. The heat transfer roller is arranged in the transfer printing heating shell, and the high-temperature heating layer is arranged on the inner side wall of the transfer printing heating shell and above the heat transfer printing roller.

As a further improvement of the invention, the film printing assembly further comprises a leveling shaft. The leveling rotating shafts are symmetrically arranged on the lower side of the supporting plate and on two sides of the thermal transfer printing roller.

As a further improvement of the invention, four ends of the clamping supporting plate of the clamping assembly are provided with positioning holes for fixedly connecting the clamping supporting plate and the conveyor belt.

As a further improvement of the invention, the right limiting component in the limiting component comprises a right guide rail, a right sliding block and a right limiting rod. The right guide rail is arranged on the right side of the conveyor belt. The right slider is in sliding connection with the right guide rail. The right limiting rod is rotationally connected with the right sliding block, and the right limiting rod can rotate around the joint of the right limiting rod and the right sliding block within the range of 0-90 degrees as a rotation center.

As a further improvement of the invention, when the left limiting rod and the right limiting rod of the limiting assembly close to the transfer printing assembly are at the initial positions, the left limiting rod is clung to the inner side of the left guide rail, and the right limiting rod is clung to the inner side of the right guide rail.

As a further improvement of the present invention, the right adjusting assembly of the adjusting assemblies includes a right adjusting plate, a right adjusting rail, and a right adjusting block. The right adjusting guide rail is arranged on the right side of the conveyor belt. The right adjusting block is in sliding connection with the right adjusting guide rail. The right adjusting plate is rotationally connected with the right adjusting block, and the right adjusting plate can rotate around the joint of the right adjusting plate and the right adjusting block within the range of 0-90 degrees as a rotation center.

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

1. through setting up conveyer belt, seal membrane module and book membrane module, the aluminum product is placed and is removed on the conveyer belt, realizes the automatic thermal transfer processing of aluminum product, saves the cost of labor, improves production efficiency.

2. Through setting up clamping assembly and spacing subassembly, realize pressing from both sides tightly the aluminum product when the aluminum product is processed, prevent that the aluminum product from taking place slightly to remove when heat transfer processing, can realize the required pattern of high accuracy heat transfer aluminum product, prevent that the pattern from taking place the deviation when heat transfer to can adapt to the heat transfer processing of multiple different shapes's aluminum product.

3. By arranging the adjusting component, the placement position of the aluminum material can be automatically adjusted, the position offset generated by manually placing the aluminum material is reduced, the accuracy of pattern thermal transfer is improved, and high-precision thermal transfer is realized; in addition, the adjusting component can also play a limiting role in aluminum processing.

4. Through setting up the flattening pivot, can realize that level with the thermal transfer membrane pressfitting on the aluminum product surface, make thermal transfer pattern laminate more on the aluminum product surface.

Drawings

FIG. 1 is a schematic diagram of the structure of a film rolling assembly, a film printing assembly and a moving assembly of the present invention;

FIG. 2 is a schematic view of a clamping assembly of the present invention clamping an aluminum material;

FIG. 3 is a schematic diagram illustrating the operation of the thermal transfer of the present invention;

FIG. 4 is a schematic view of the structure of the adjustment assembly and spacing assembly of the present invention;

FIG. 5 is a schematic view of the clamping assembly of the present invention;

FIG. 6 is a schematic view of the separator of the present invention;

FIG. 7 is a schematic diagram of the operation of the separator of the present invention;

FIG. 8 is a schematic view of the separator of the present invention in an initial position;

FIG. 9 is a schematic diagram of the operation of the adjustment assembly of the present invention;

fig. 10 is a schematic view of the operation of the present invention when the adjusting member is limited to aluminum.

The reference numerals in the figures illustrate:

the transfer printing device comprises a conveying belt 1, a thermal transfer printing support 2, a unreeling shaft 3, a reeling shaft 4, a hydraulic rod 5, a supporting plate 6, a transfer printing heating cover 7, a thermal transfer printing roller 8, a high-temperature heating layer 9, a leveling rotating shaft 10, an adjusting slide block 11, an adjusting screw rod 12, an adjusting guide rod 13, an adjusting supporting plate 14, an adjusting motor 15, a clamping supporting plate 16, a clamping motor 17, a clamping telescopic rod 18, a left guide rail 19, a left sliding block 20, a left limiting rod 21, a right guide rail 22, a right sliding block 23, a right limiting rod 24, a separator 25, a right adjusting plate 26, a right adjusting guide rail 27, a right adjusting block 28, a left adjusting plate 29, a left adjusting guide rail 30 and a left adjusting block 31.

Detailed Description

First embodiment: referring to fig. 1-10, a high-precision heat transfer device for aluminum processing comprises a conveyor belt 1, a film winding assembly, a film printing assembly, a moving assembly, a clamping assembly, a limiting assembly and an adjusting assembly.

The conveyer belt 1 is fixed to be set up in conveyer belt base upside for the conveying is waited to process the aluminum product, wait to process the aluminum product and is transported to the book membrane module department in proper order from left to right.

The film winding assembly comprises a unreeling shaft 3 and a reeling shaft 4. The unreeling shaft 3 is provided on the left side of the conveyor belt 1. The take-up reel 4 is arranged on the right side of the conveyor belt 1. A thermal transfer film is arranged between the unreeling shaft 3 and the reeling shaft 4, the thermal transfer film is flattened by the unreeling shaft 3 and the reeling shaft 4, and the flattening surface is parallel to the surface of the aluminum material to be processed. The unreeling shaft 3 is used for unreeling the thermal transfer film. The take-up reel 4 is used for taking up the thermal transfer film.

The moving component is arranged on the upper side of the conveyor belt 1 and is used for moving the printing film component. The moving assembly comprises a thermal transfer printing bracket 2, an adjusting slide block 11, an adjusting screw rod 12, an adjusting guide rod 13, an adjusting support plate 14 and an adjusting motor 15. The thermal transfer support 2 is fixedly arranged on the upper side of the conveyor belt 1, and the lower end of the thermal transfer support is respectively connected with the left side and the right side of the conveyor belt 1. The adjusting support plates 14 are symmetrically arranged below the two ends of the top wall of the thermal transfer printing support 2, and the upper ends of the adjusting support plates 14 are fixedly connected with the lower sides of the two ends of the top wall of the thermal transfer printing support 2. The adjusting slide block 11 is arranged between the adjusting support plates 14, the adjusting slide block 11 is in sliding connection with the adjusting screw rod 12 and the adjusting guide rod 13, and the adjusting slide block 11 can move linearly between the adjusting screw rod 12 and the adjusting guide rod 13. The adjusting guide rod 13 is arranged between the adjusting support plates 14 and above the adjusting screw rod 12. The regulating motor 15 is arranged on one side of the regulating support plate 14 far away from the regulating screw rod 12, and the output end of the regulating motor 15 penetrates through the regulating support plate 14 and is connected with the regulating screw rod 12.

The film printing component is fixedly connected with the moving component, so that the moving component drives the film printing component to move. The printing film component comprises a hydraulic rod 5, a supporting plate 6, a transfer printing heating shell 7, a thermal transfer printing roller 8 and a high-temperature heating layer 9. The hydraulic rod 5 is arranged below the top wall of the thermal transfer printing bracket 2, and the upper end of the hydraulic rod 5 is fixedly connected with the lower end of the adjusting slide block 11. The upper side of the supporting plate 6 is fixedly connected with the lower end of the hydraulic rod 5. The transfer printing heating shell 7 is arranged below the center of the supporting plate 6, the upper side of the transfer printing heating shell 7 is fixedly connected with the lower side of the supporting plate 6, and the cross section of the transfer printing heating shell 7 is in an arc shape with an opening at the lower end. The thermal transfer roller 8 is arranged in the transfer heating shell 7, and the high-temperature heating layer 9 is arranged on the inner side wall of the transfer heating shell 7 and above the thermal transfer roller 8. The film printing assembly further includes a leveling shaft 10. The leveling rotating shafts 10 are symmetrically arranged on the lower side of the supporting plate 6 and on two sides of the thermal transfer printing roller 8, and the leveling rotating shafts 10 are used for leveling the patterns after thermal transfer printing.

The clamping assembly comprises a clamping support plate 16, a clamping motor 17 and a clamping telescopic rod 18. The clamping components are symmetrically arranged on two sides of the conveyor belt 1, are positioned in front of the limiting device and are positioned on the lower sides of the film printing component and the moving component. The clamping support plate 16 is fixedly connected with the upper side of the conveyor belt 1. The clamping motor 17 is fixedly arranged on the upper side of the clamping supporting plate 16, the output end of the clamping motor 17 is fixedly connected with the clamping telescopic rod 18, and the output end of the clamping motor 17 faces to one side of the aluminum material to be processed. The clamping telescopic rods 18 on the two sides move in opposite directions, and one end of each rod is abutted against the surface of the aluminum material to be processed so as to clamp the aluminum material to be processed. Four ends of a clamping supporting plate 16 of the clamping assembly are provided with positioning holes for fixedly connecting the clamping supporting plate 16 and the conveyor belt 1.

The limiting assembly comprises a left limiting assembly and a right limiting assembly. The left limiting component and the right limiting component are symmetrically arranged on two sides of the conveyor belt 1. The left limit assembly comprises a left guide rail 19, a left slider 20 and a left limit rod 21. The left guide rail 19 is provided on the left side of the conveyor belt 1. The left slider 20 is slidably connected to the left rail 19. The left limiting rod 21 is rotationally connected with the left sliding block 20, and the left limiting rod 21 can rotate around the connection position of the left limiting rod and the left sliding block 20 within the range of 0-90 degrees as a rotation center.

The right limiting assembly of the limiting assemblies comprises a right guide rail 22, a right sliding block 23 and a right limiting rod 24. The right guide rail 22 is provided on the right side of the conveyor belt 1. The right slider 23 is slidably connected to the right rail 22. The right limiting rod 24 is rotationally connected with the right sliding block 23, and the right limiting rod 24 can rotate around the connection position of the right limiting rod and the right sliding block 23 within the range of 0-90 degrees as a rotation center.

When the left and right stopper rods 21, 24 are in the initial positions, the left stopper rod 21 is closely attached to the inner side of the left guide rail 19, and the right stopper rod 24 is closely attached to the inner side of the right guide rail 22.

The adjusting assembly is arranged at the front side of the printing film assembly and comprises a left adjusting assembly and a right adjusting assembly which are symmetrically arranged at the two sides of the conveyor belt 1; the left adjustment assembly comprises a left adjustment plate 29, a left adjustment rail 30 and a left adjustment block 31; the left adjusting guide 30 is provided on the left side of the conveyor belt 1; the left adjusting block 31 is slidably connected with the left adjusting guide rail 30; the left adjusting plate 29 is rotatably connected with the left adjusting block 31, and the left adjusting plate 29 can rotate around the connection position of the left adjusting plate and the left adjusting block 31 within the range of 0-90 degrees as a rotation center.

The right adjusting assembly of the adjusting assemblies comprises a right adjusting plate 26, a right adjusting guide rail 27 and a right adjusting block 28; the right adjusting guide rail 27 is provided on the right side of the conveyor belt 1; the right adjusting block 28 is in sliding connection with the right adjusting guide rail 27; the right adjusting plate 26 is rotatably connected with the right adjusting block 28, and the right adjusting plate 26 can rotate around the connection part of the right adjusting plate and the right adjusting block 28 within the range of 0-90 degrees as a rotation center.

The right and left regulating plates 26 and 29 are of a trapezoidal structure with the short side direction facing the inlet of the aluminum material, and an opening is formed in the middle for the aluminum material to pass through. The position of the opening determines the position of the aluminum material during processing. The right adjusting plate 26 and the left adjusting plate 29 are controlled by a controller, and the controller drives the controller to rotate and move so as to adjust the size and the position of the opening. The aluminum product is placed on the conveyer belt 1 and firstly passes through the adjusting component, the required opening size and position are preset, the aluminum product and the inclined edge of the adjusting plate are in contact collision, the aluminum product is limited to enter the opening along the inclined edge, and the opening width is slightly larger than the width of the aluminum product, so that the aluminum product is determined on a correct processing route.

When the aluminum material is clamped by the clamping assembly, the right adjusting plate 26 and the left adjusting plate 29 automatically rotate to enable the longest side of the aluminum material to rotate to the side close to the aluminum material, and move to abut against the aluminum material to jointly act with the limiting assembly, so that the aluminum material is clamped in the front-back direction and does not move.

Working principle:

the aluminum material to be processed is placed on the conveyor belt 1, the right adjusting plate 26 and the left adjusting plate 29 of the adjusting assembly are controlled by a controller, and the controller drives the aluminum material to rotate and move, so that the size and the position of the opening are adjusted. The aluminum product is placed on the conveyer belt 1 and firstly passes through the adjusting component, the required opening size and position are preset, the aluminum product and the inclined edge of the adjusting plate are in contact collision, the aluminum product is limited to enter the opening along the inclined edge, and the opening width is slightly larger than the width of the aluminum product, so that the aluminum product is determined on a correct processing route. When the aluminum material is clamped by the clamping assembly, the right adjusting plate 26 and the left adjusting plate 29 automatically rotate to enable the longest side of the aluminum material to rotate to the side close to the aluminum material, and move to abut against the aluminum material to jointly act with the limiting assembly, so that the aluminum material is clamped in the front-back direction and does not move.

The conveyer belt 1 transports the aluminum product to be processed to the clamping assembly department, and conveyer belt 1 stops the motion, and the clamping telescopic link 18 that is located the aluminum product both sides of waiting to process moves in opposite directions, presss from both sides tight aluminum product to be processed, and left slider 20 and right slider 23 move to corresponding position along left guide rail 19 and right guide rail 22, and left gag lever post 21 and right gag lever post 24 are rotatory towards one side of the aluminum product of waiting to process, make the gag lever post and wait to process the mutual butt of aluminum product in front and back to spacing the aluminum product of waiting to process.

The moving assembly drives the adjusting slide block 11 to move the film printing assembly to the position right above the aluminum material to be processed, the high-temperature heating layer 9 in the transfer printing heating shell 7 heats the heat transfer printing roller 8, the hydraulic rod 5 stretches downwards to push the heat transfer printing roller 8 below the supporting plate 6 to move, the heat transfer printing roller 8 is close to the heat transfer printing film between the unwinding shaft 3 and the winding shaft 4 after heating, the heat transfer printing film is pressed on the aluminum material to be processed, and therefore patterns on the heat transfer printing film are printed on the surface of the aluminum material. After the pressing is completed, the adjustment slider 11 is reciprocally moved left and right to make the leveling shaft 10 level the pattern surface. The anti-rolling shaft 3 and the winding shaft 4 roll to move the thermal transfer film to a new pattern part.

The clamping assembly, the limiting device and the limiting assembly are reset, the conveyor belt 1 continues to work, the processed aluminum material is transported forward, and the next aluminum material to be processed is transported.

Specific embodiment II: please refer to fig. 1-10, which illustrate a high-precision heat transfer device for aluminum processing, and the embodiment is the same as the first embodiment in that the details are omitted, except that: the clamping assembly further comprises a separator 25; the separator 25 is a long strip-shaped conical rod, and the tail end of the separator 25 is connected with the output end of the clamping motor 17, so that the separator 25 can rotate around the connection part of the separator and the clamping motor 17 as a rotation center. The separator 25 is positioned between the surface of the aluminum material to be processed and the hot stamping film, and the initial position of the separator 25 is that the separator 25 rotates to the side close to the inner side of the conveyor belt 1. When the hot stamping process is completed, the separator 25 rotates left and right, passing between the aluminum surface and the hot stamping film. The heat transfer device may cause uneven heating, so that when the transfer film is stamped, the transfer pattern is not completely transferred due to different melting states of the transfer pattern, and adhesion occurs between the transfer film and the aluminum material. After the separator 25 has completed its work, it returns to its original position. The separator 25 passes between the aluminum material and the heat-seal film, and can effectively prevent the transfer film from sticking to the aluminum material.

Claims (9)

1. A high-precision heat transfer printing device for aluminum product processing is characterized in that: comprises a conveyor belt (1), a film rolling assembly, a film printing assembly, a moving assembly, a clamping assembly, a limiting assembly and an adjusting assembly;

the conveying belt (1) is fixedly arranged on the upper side of the conveying belt base and is used for conveying the aluminum material to be processed;

the film winding assembly comprises a unreeling shaft (3) and a reeling shaft (4); the unreeling shaft (3) is arranged at the left side of the conveyor belt (1); the winding shaft (4) is arranged on the right side of the conveyor belt (1);

the moving component is arranged on the upper side of the conveyor belt (1) and is used for moving the film printing component;

the film printing component is fixedly connected with the moving component, so that the moving component drives the film printing component to move;

the clamping assembly comprises a clamping supporting plate (16), a clamping motor (17) and a clamping telescopic rod (18); the clamping components are symmetrically arranged at two sides of the conveyor belt (1); the clamping support plate (16) is fixedly connected with the upper side of the conveyor belt (1); the clamping motor (17) is fixedly arranged on the upper side of the clamping supporting plate (16), the output end of the clamping motor (17) is fixedly connected with the clamping telescopic rod (18), and the output end of the clamping motor (17) faces to one side of the aluminum material to be processed;

the limiting assembly is arranged at the rear side of the printing film assembly and comprises a left limiting assembly and a right limiting assembly; the left limiting assembly and the right limiting assembly are symmetrically arranged at two sides of the conveyor belt (1) left and right; the left limiting assembly comprises a left guide rail (19), a left sliding block (20) and a left limiting rod (21); the left guide rail (19) is arranged at the left side of the conveyor belt (1); the left sliding block (20) is in sliding connection with the left guide rail (19); the left limiting rod (21) is rotationally connected with the left sliding block (20), and the left limiting rod (21) can rotate around the joint of the left limiting rod and the left sliding block (20) within the range of 0-90 degrees as a rotation center;

the adjusting assembly is arranged at the front side of the printing film assembly and comprises a left adjusting assembly and a right adjusting assembly which are symmetrically arranged at the two sides of the conveyor belt (1); the left adjusting assembly comprises a left adjusting plate (29), a left adjusting guide rail (30) and a left adjusting block (31); the left adjusting guide rail (30) is arranged at the left side of the conveyor belt (1); the left adjusting block (31) is in sliding connection with the left adjusting guide rail (30); the left adjusting plate (29) is rotationally connected with the left adjusting block (31), and the left adjusting plate (29) can rotate around the joint of the left adjusting plate and the left adjusting block (31) within the range of 0-90 degrees as a rotation center.

2. The high-precision heat transfer device for aluminum processing according to claim 1, wherein: a thermal transfer film is arranged between the unreeling shaft (3) and the reeling shaft (4); the unreeling shaft (3) is used for unreeling the thermal transfer film; the winding shaft (4) is used for winding the thermal transfer film.

3. The high-precision heat transfer device for aluminum processing according to claim 1, wherein: the moving assembly comprises a thermal transfer printing bracket (2), an adjusting sliding block (11), an adjusting screw rod (12), an adjusting guide rod (13), an adjusting supporting plate (14) and an adjusting motor (15); the thermal transfer support (2) is fixedly arranged on the upper side of the conveyor belt (1), and the lower end of the thermal transfer support is respectively connected with the left side and the right side of the conveyor belt (1); the adjusting support plates (14) are symmetrically arranged below the two ends of the top wall of the thermal transfer printing support (2), the adjusting slide blocks (11) are arranged between the adjusting support plates (14), and the adjusting slide blocks (11) are in sliding connection with the adjusting screw rods (12) and the adjusting guide rods (13); the adjusting guide rod (13) is arranged between the adjusting support plates (14) and above the adjusting screw rod (12); the adjusting motor (15) is arranged on one side, far away from the adjusting screw rod (12), of the adjusting supporting plate (14), and the output end of the adjusting motor (15) penetrates through the adjusting supporting plate (14) to be connected with the adjusting screw rod (12).

4. The high-precision heat transfer device for aluminum processing according to claim 1, wherein: the printing film component comprises a hydraulic rod (5), a supporting plate (6), a transfer printing heating shell (7), a thermal transfer printing roller (8) and a high-temperature heating layer (9); the hydraulic rod (5) is arranged below the top wall of the thermal transfer printing bracket (2), and the upper end of the hydraulic rod (5) is fixedly connected with the lower end of the adjusting slide block (11); the upper side of the supporting plate (6) is fixedly connected with the lower end of the hydraulic rod (5); the transfer printing heating shell (7) is arranged below the center of the supporting plate (6), and the cross section of the transfer printing heating shell (7) is in an arc shape with an opening at the lower end; the heat transfer roller (8) is arranged in the transfer printing heating shell (7), and the high-temperature heating layer (9) is arranged on the inner side wall of the transfer printing heating shell (7) and above the heat transfer roller (8).

5. The high-precision heat transfer device for aluminum processing as recited in claim 4, wherein: the film printing assembly also comprises a leveling rotating shaft (10); the leveling rotating shafts (10) are symmetrically arranged at the lower side of the supporting plate (6) and at the two sides of the thermal transfer roller (8).

6. The high-precision heat transfer device for aluminum processing according to claim 1, wherein: four ends of a clamping supporting plate (16) of the clamping assembly are provided with positioning holes for fixedly connecting the clamping supporting plate (16) and the conveyor belt (1).

7. The high-precision heat transfer device for aluminum processing according to claim 1, wherein: the right limiting assembly in the limiting assemblies comprises a right guide rail (22), a right sliding block (23) and a right limiting rod (24); the right guide rail (22) is arranged on the right side of the conveyor belt (1); the right sliding block (23) is in sliding connection with the right guide rail (22); the right limiting rod (24) is rotationally connected with the right sliding block (23), and the right limiting rod (24) can rotate around the connection position of the right limiting rod and the right sliding block (23) within the range of 0-90 degrees as a rotation center.

8. The high-precision heat transfer device for aluminum processing according to claim 1, wherein: when a left limiting rod (21) and a right limiting rod (24) of a limiting assembly close to the transfer printing assembly are at initial positions, the left limiting rod (21) is clung to the inner side of the left guide rail (19), and the right limiting rod (24) is clung to the inner side of the right guide rail (22).

9. The high-precision heat transfer device for aluminum processing according to claim 1, wherein: the right adjusting assembly in the adjusting assembly comprises a right adjusting plate (26), a right adjusting guide rail (27) and a right adjusting block (28); the right adjusting guide rail (27) is arranged on the right side of the conveyor belt (1); the right adjusting block (28) is in sliding connection with the right adjusting guide rail (27); the right adjusting plate (26) is rotationally connected with the right adjusting block (28), and the right adjusting plate (26) can rotate around the connecting position of the right adjusting plate and the right adjusting block (28) within the range of 0-90 degrees as a rotation center.