CN220053194U - Novel slipper vamp rotation heat transfer printing machine - Google Patents

Abstract

The utility model discloses a novel slipper vamp rotation heat transfer machine, which structurally comprises an air cylinder, a mounting frame, a lifting frame and a roller mechanism, wherein the air cylinder is fixedly arranged at the top of the mounting frame, the lifting frame is arranged at the lower end of the mounting frame, a first motor and a second motor are started to run to drive a roller to rotate for a whole circle, the second motor drives a bracket to roll for a half circle, the roller and the bracket rotate reversely, the pattern on the surface of a film at the lower end of the roller can be transferred to an arc vamp of a slipper smoothly, the film is conducted in a gap between a rotating roller and a clamping roller, and when in heat transfer, a pushing block is driven to approach the rotating roller by starting of a small air cylinder to change the distance between the rotating roller and the clamping roller so as to clamp the film, thereby avoiding the phenomenon that the film is pulled back in the heat transfer process, and the pattern which is not transferred on the film is wrinkled.

Description

Novel slipper vamp rotation heat transfer printing machine

Technical Field

The utility model relates to the field of slipper preparation, in particular to a novel slipper vamp rotary heat transfer machine.

Background

The thermal transfer printing is an emerging printing process, the printing mode of the process is divided into two parts of transfer printing film printing and transfer printing processing by foreign transfer printing, the transfer printing film printing adopts dot printing, patterns are printed on the surface of a film in advance, the pattern of the slipper vamp can be increased through a thermal transfer printer, but when the patterns are thermally transferred to the slipper vamp through the thermal transfer printer, the slipper vamp has a certain arc radian, the patterns on the surface of the film are required to be rolled after being transferred, the film is difficult to be in contact stretching during rolling, the stretching tightness of the film is low, the patterns which are not transferred on the film are easy to wrinkle, and the patterns on the surface of the film are difficult to be transferred to the slipper vamp through a thermal transfer plate on the thermal transfer printer in a flat mode.

Disclosure of Invention

Aiming at the problems, the utility model provides a novel slipper vamp rotation heat transfer machine.

In order to achieve the above object, the present utility model is realized by the following technical scheme: the utility model provides a novel slippers vamp rotates heat transfer machine, its structure includes brace table, electric cabinet, unreel roller, conduction roller, transfer mechanism, clamping mechanism, wind-up roll, the electric cabinet is installed at the brace table top to brace table front end left side is equipped with unreels roller and conduction roller, transfer mechanism installs at brace table front end middle part to transfer mechanism is connected with the electric cabinet electricity, clamping mechanism installs on brace table front end right side, the wind-up roll is established in brace table upper right end to the wind-up roll is located the clamping mechanism top.

As a further improvement of the utility model, the three conducting rollers are arranged, the film with the whole belt pattern is placed on the unreeling roller, and the head end of the film is wound on the reeling roller.

As a further improvement of the utility model, the transfer mechanism comprises an air cylinder, a mounting frame, a lifting frame and a roller mechanism, wherein the air cylinder is fixedly arranged at the top of the mounting frame, the lifting frame is arranged at the lower end of the mounting frame, the top of the lifting frame is mechanically connected with the output end of the air cylinder, and the roller mechanism is arranged at the lower end of the inside of the lifting frame.

As a further improvement of the utility model, the roller mechanism comprises a first motor, a roller, a second motor and a bracket, wherein the output end of the first motor rotates synchronously with the roller, the output end of the second motor rotates synchronously with the bracket, the roller is arranged at the lower end inside the lifting frame, and the roller is positioned right above the bracket.

As a further improvement of the utility model, the roller is a heating roller, the bracket is of a semi-cylindrical structure, the upper end surface of the bracket of the semi-cylindrical structure is of an arc-shaped structure, the bracket is exactly matched with the arc shape of the slipper, the slipper can be placed and clamped, the roller is driven to rotate for a whole circle by the first motor, and the bracket is driven to roll for a half circle by the second motor.

As a further improvement of the utility model, the clamping mechanism comprises a motor, a rotating roller, a supporting plate, a clamping roller, a push block and a small air cylinder, wherein the output end of the motor rotates synchronously with the axis of the rotating roller, the rotating roller is arranged on the inner side of the supporting plate, the clamping roller is positioned on the right side of the rotating roller, the push block is arranged at the rear end of the clamping roller, the push block is slidably arranged on the right side of the front end of the supporting table, the small air cylinder is in transmission connection with the push block, the small air cylinder is arranged on the right side of the supporting plate, the rotating roller and the clamping roller are both positioned below the winding roller, the distance between the rotating roller and the clamping roller is changed by pushing the push block through the small air cylinder, and the film is conducted in the gap between the rotating roller and the clamping roller.

Compared with the prior art, the utility model has the following beneficial effects:

1. according to the utility model, the slippers are clamped and placed on the bracket, then the lifting frame is driven to descend by the electric cabinet starting cylinder, at the moment, the rollers on the lifting frame vertically move downwards, the film and the slipper vamp on the bracket are just extruded, meanwhile, the first motor and the second motor are started to operate, the rollers are driven to rotate in a whole circle, the second motor drives the bracket to roll for half a circle, and the rollers and the bracket rotate in the opposite direction, so that the patterns on the film surface at the lower end of the rollers can be transferred to the arc vamp of the slippers smoothly.

2. According to the utility model, the film is conducted in the gap between the rotating roller and the clamping roller, and the small air cylinder is started to push the pushing block to drive the clamping roller to approach the rotating roller during thermal transfer, so that the distance between the rotating roller and the clamping roller is changed to clamp the film, and the phenomenon that the film is pulled back in the thermal transfer process to cause the non-transferred pattern on the film to be wrinkled is avoided.

Drawings

Fig. 1 is a schematic diagram of a novel slipper vamp rotary heat transfer machine.

Fig. 2 is a schematic structural view of the transfer mechanism of the present utility model.

FIG. 3 is a schematic view of a roller mechanism according to the present utility model.

Fig. 4 is a schematic top view of the clamping mechanism of the present utility model.

In the figure: the device comprises a supporting table-1, an electric cabinet-2, an unreeling roller-3, a transmission roller-4, a transfer printing mechanism-5, a clamping mechanism-6, a winding roller-7, an air cylinder-51, a mounting frame-52, a lifting frame-53, a roller mechanism-54, a first motor-54 a, a roller-54 b, a second motor-54 c, a bracket-54 d, a motor-61, a rotating roller-62, a supporting plate-63, a clamping roller-64, a pushing block-65 and a small air cylinder-66.

Detailed Description

The utility model is further described in connection with the following detailed description, in order to make the technical means, the creation characteristics, the achievement of the purpose and the effect of the utility model easy to understand.

Examples

As shown in fig. 1-4, the utility model provides a novel slipper vamp rotary thermal transfer printer, which structurally comprises a supporting table 1, an electric cabinet 2, an unreeling roller 3, a conducting roller 4, a transfer printing mechanism 5, a clamping mechanism 6 and a winding roller 7, wherein the electric cabinet 2 is arranged at the top of the supporting table 1, the unreeling roller 3 and the conducting roller 4 are arranged on the left side of the front end of the supporting table 1, the transfer printing mechanism 5 is arranged in the middle of the front end of the supporting table 1, the transfer printing mechanism 5 is electrically connected with the electric cabinet 2, the clamping mechanism 6 is arranged on the right side of the front end of the supporting table 1, the winding roller 7 is arranged at the upper right end of the supporting table 1, and the winding roller 7 is positioned above the clamping mechanism 6.

Wherein, the conduction roller 4 is equipped with three, and the film that whole area tape has the pattern is placed on unreeling roller 3, and the head end of film then twines on wind-up roll 7, and the transmission in-process is taut with the film through three conduction roller 4, improves the tensile degree of film conduction.

The transfer mechanism 5 comprises an air cylinder 51, a mounting frame 52, a lifting frame 53 and a roller mechanism 54, wherein the air cylinder 51 is fixedly mounted at the top of the mounting frame 52, the lifting frame 53 is mounted at the lower end of the mounting frame 52, the top of the lifting frame 53 is mechanically connected with the output end of the air cylinder 51, and the roller mechanism 54 is mounted at the lower end inside the lifting frame 53.

The roller mechanism 54 comprises a first motor 54a, a roller 54b, a second motor 54c and a bracket 54d, wherein the output end of the first motor 54a rotates synchronously with the roller 54b, the output end of the second motor 54c rotates synchronously with the bracket 54d, the roller 54b is arranged at the lower end inside the lifting frame 53, and the roller 54b is positioned right above the bracket 54 d.

The roller 54b is a heating roller, the bracket 54d is of a semi-cylindrical structure, the upper end face of the bracket 54d of the semi-cylindrical structure is of an arc-shaped structure, the bracket is exactly matched with the arc shape of a slipper, the slipper can be placed and clamped, the roller 54b is driven to rotate in a whole circle through the first motor 54a, the bracket 54d is driven to rotate in a half circle through the second motor 54c, the roller 54b and the bracket 54d are rotated in the opposite direction, and the pattern on the film surface at the lower end of the roller 54b can be transferred onto the arc-shaped slipper vamp of the slipper in a flat mode.

The clamping mechanism 6 comprises a motor 61, a rotating roller 62, a supporting plate 63, a clamping roller 64, a push block 65 and a small air cylinder 66, the output end of the motor 61 rotates synchronously with the axis of the rotating roller 62, the rotating roller 62 is arranged on the inner side of the supporting plate 63, the clamping roller 64 is positioned on the right side of the rotating roller 62, the push block 65 is arranged at the rear end of the clamping roller 64, the push block 65 is slidably arranged on the right side of the front end of the supporting table 1, the small air cylinder 66 is in transmission connection with the push block 65, the small air cylinder 66 is arranged on the right side of the supporting plate 63, the rotating roller 62 and the clamping roller 64 are both positioned below the winding roller 7, the distance between the rotating roller 62 and the clamping roller 64 is changed by pushing the push block 65 through the small air cylinder 66, and the film is conducted in the gap between the rotating roller 62 and the clamping roller 64, so that the film is prevented from being pulled back in the process of thermal transfer, and the untransferred pattern on the film is prevented from being wrinkled.

Specific use and action of the embodiment:

according to the utility model, a film with patterns is placed on an unreeling roller 3, the first end of the film is wound on a winding roller 7, the film is tensioned in the transmission process through three transmission rollers 4, the stretching degree of film transmission is improved, when the vamp is subjected to thermal transfer printing, slippers are clamped and placed on a bracket 54d, then a cylinder 51 is started by an electric cabinet 2 to drive a lifting frame 53 to descend, at the moment, a roller 54b on the lifting frame 53 vertically moves downwards, the film is just extruded with slipper vamp on the bracket 54d, meanwhile, a first motor 54a and a second motor 54c are started to operate, the roller 54b is driven to rotate completely, the second motor 54c is driven to rotate a half circle, the roller 54b and the bracket 54d are reversely rotated, the patterns on the lower end of the film on the roller 54b can be smoothly transferred onto the arc vamp of the slipper, and simultaneously, the film is transmitted in a gap between a rotating roller 62 and a clamping roller 64, and when the thermal transfer printing is performed, a small cylinder 66 is started to drive a rotating roller 64 to move the rotating roller 62 and the slipper vamp to be close to the rotating roller 62, and the gap between the slipper 64 is not required to be changed, and the film is prevented from being transferred back in the thermal transfer printing process.

The technical features of the above-described embodiments may be arbitrarily combined, and all possible combinations of the technical features in the above-described embodiments are not described for brevity of description, however, as long as there is no contradiction between the combinations of the technical features, they should be considered as the scope of the description.

The present embodiments are, therefore, to be considered in all respects as illustrative and not restrictive, the scope of the utility model being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Claims (6)

1. Novel slippers vamp rotates heat transfer machine, its structure includes brace table (1), electric cabinet (2), unreel roller (3), conduction roller (4), transfer mechanism (5), clamping mechanism (6), wind-up roll (7), its characterized in that:

electric cabinet (2) are installed at supporting bench (1) top to supporting bench (1) front end left side is equipped with unreel roller (3) and deflector roll (4), transfer mechanism (5) are installed at supporting bench (1) front end middle part to transfer mechanism (5) are connected with electric cabinet (2) electricity, clamping mechanism (6) are installed on supporting bench (1) front end right side, wind-up roll (7) are established at supporting bench (1) upper right end to wind-up roll (7) are located clamping mechanism (6) top.

2. The novel slipper upper rotating heat transfer machine of claim 1, wherein: the three conducting rollers (4) are arranged, the film with the patterns is placed on the unreeling roller (3) in a whole belt mode, and the head end of the film is wound on the winding roller (7).

3. The novel slipper upper rotating heat transfer machine of claim 1, wherein: transfer mechanism (5) are including cylinder (51), mounting bracket (52), crane (53), roller mechanism (54), cylinder (51) fixed mounting is at mounting bracket (52) top to crane (53) are installed to mounting bracket (52) lower extreme, crane (53) top and cylinder (51) output mechanical connection, roller mechanism (54) are installed to inside lower extreme of crane (53).

4. A novel slipper upper rotational heat transfer machine according to claim 3, characterized in that: the roller mechanism (54) comprises a first motor (54 a), a roller (54 b), a second motor (54 c) and a bracket (54 d), wherein the output end of the first motor (54 a) and the roller (54 b) synchronously rotate, the output end of the second motor (54 c) and the bracket (54 d) synchronously rotate, the roller (54 b) is arranged at the lower end inside the lifting frame (53), and the roller (54 b) is positioned right above the bracket (54 d).

5. The novel slipper upper rotating heat transfer machine of claim 4, wherein: the roller (54 b) is a heating roller, the bracket (54 d) is of a semi-cylindrical structure, and the upper end face of the bracket (54 d) of the semi-cylindrical structure is of an arc-shaped structure and is exactly matched with the arc shape of the slipper.

6. The novel slipper upper rotating heat transfer machine of claim 1, wherein: the clamping mechanism (6) comprises a motor (61), a rotating roller (62), a supporting plate (63), a clamping roller (64), a pushing block (65) and a small air cylinder (66), wherein the output end of the motor (61) rotates synchronously with the axis of the rotating roller (62), the rotating roller (62) is arranged on the inner side of the supporting plate (63), the clamping roller (64) is positioned on the right side of the rotating roller (62), the pushing block (65) is arranged at the rear end of the clamping roller (64), the pushing block (65) is slidably mounted on the right side of the front end of the supporting table (1), the small air cylinder (66) is in transmission connection with the pushing block (65), the small air cylinder (66) is arranged on the right side of the supporting plate (63), and the rotating roller (62) and the clamping roller (64) are both positioned below the winding roller (7).