CN217373843U - Combined heat transfer machine - Google Patents

Abstract

The utility model discloses a combined thermal transfer machine, which comprises a frame, wherein an upper die mechanism and a lower die mechanism are arranged on the frame, the upper die mechanism and the lower die mechanism are movably connected with the frame, a transmission mechanism is arranged in the frame and is connected with the lower die mechanism, the transmission mechanism is used for driving the lower die mechanism to move, a power structure is fixedly arranged on the upper die mechanism and comprises a contact state and a disconnection state, the power structure is in transmission connection with the transmission mechanism when in the contact state so as to enable the power structure to drive the transmission mechanism to start, the power structure is separated from the transmission mechanism when in the disconnection state, the transmission mechanism is not controlled by the power mechanism, the upper die mechanism drives the lower die mechanism to synchronously move through the transmission mechanism, the utility model has reasonable structure, and after the thermal transfer is finished, the upper die mechanism and the lower die mechanism are separated, the upper die mechanism can drive the transmission mechanism to start, the lower die mechanism is pushed out to one side by the transmission mechanism, and articles on the lower die mechanism are conveniently taken and placed.

Description

Combined heat transfer machine

Technical Field

The utility model relates to a heat-transfer seal field, in particular to combined heat-transfer seal machine.

Background

The thermal transfer printing is a special process for printing any pictures such as portrait, landscape and the like on common paper or high-precision printing paper by using thermal transfer ink, heating the pictures to a certain temperature within a few minutes by using corresponding thermal transfer printing equipment for thermal transfer printing, and transferring the image colors on the paper to materials such as porcelain cups, porcelain plates, clothes, metals and the like vividly. The thermal transfer printer can mold color patterns at one time without color register, and has the advantages of simple operation, delicate printing work, low production cost, small product loss, strong adhesive force and the like, so the thermal transfer printer is widely applied to the field of product printing.

In the existing thermal transfer printing equipment, the upper die mechanism and the lower die mechanism of the device are fixed in position, the opening degree of the upper die mechanism and the lower die mechanism is also determined, and the upper die mechanism and the lower die mechanism cannot be separated by a larger distance, so that some articles with larger height cannot be placed well, and cannot be observed and taken out well after printing. In view of the above problems, a solution is proposed as follows.

SUMMERY OF THE UTILITY MODEL

The utility model aims at providing a combined heat-transfer machine has and can enlarge the interval between upper die mechanism and the lower die mechanism to reach the advantage that makes things convenient for article to get and put.

The above technical object of the present invention can be achieved by the following technical solutions:

the utility model provides a combined heat-transfer machine, includes the frame, be equipped with upper die mechanism and lower die mechanism in the frame, upper die mechanism and lower die mechanism all with frame swing joint, be equipped with drive mechanism in the frame, drive mechanism is connected with lower die mechanism, drive mechanism is used for driving lower die mechanism and removes, the last power structure that has set firmly of upper die mechanism, power structure includes contact state and off-state, during the contact state, power structure is connected with the drive mechanism transmission to make power structure drive mechanism start, during the off-state, power structure and drive mechanism separate, drive mechanism does not receive power unit control, upper die mechanism drives lower die mechanism synchronous activity through drive mechanism.

Preferably, the upper die mechanism comprises a head lifting arm, the power structure is located at the lower end of the head lifting arm and is fixedly connected with the head lifting arm, the power structure comprises a pawl, the lower end of the head lifting arm is arc-shaped, a rotating shaft is arranged at the lower end of the head lifting arm, the rotating shaft transversely penetrates through the side wall of the head lifting arm and is rotatably connected with the head lifting arm, and two ends of the rotating shaft are respectively inserted into the rack and are fixedly connected with the rack.

Preferably, the upper die mechanism further comprises an upper die pressing plate, the upper die pressing plate is connected with the upper end of the head lifting arm, the upper die pressing plate comprises a pressing state and a hovering state, the upper end of the head lifting arm drives the upper die pressing plate to move downwards so that the pawl is not in transmission fit with the transmission mechanism, and the head lifting arm drives the upper die pressing plate to move upwards so that the pawl drives the transmission mechanism to start in the hovering state.

Preferably, the power mechanism comprises a linkage shaft, a ratchet wheel and a gear, the ratchet wheel and the gear are both located on the linkage shaft and are fixedly connected with the linkage shaft, the ratchet wheel is matched with the pawl, the pawl drives the gear to synchronously rotate through the linkage rod, a one-way bearing is fixedly arranged on the inner edge of the gear, the one-way bearing is fixedly connected with the linkage shaft, the gear is in transmission connection with the lower die mechanism, and the gear is used for driving the lower die mechanism to move.

Preferably, the lower die mechanism comprises a transmission rack, a sliding groove is formed in the rack, the transmission rack is located in the sliding groove and is connected with the sliding groove in a sliding mode, the transmission rack is meshed with a gear, and the gear is used for driving the transmission rack to move along the sliding groove.

Preferably, the lower die mechanism further comprises a lower die support plate, a support plate groove is formed in the rack, the lower die support plate is located in the support plate groove and is in sliding fit with the support plate groove, one end of the transmission rack is fixedly connected with the lower die support plate, and the transmission rack is used for driving the lower die support plate to move.

Preferably, the side wall of the lower die support plate is provided with a guide groove. The side wall of the support plate groove is fixedly provided with a guide rail, the guide groove is in sliding fit with the guide rail, and the guide rail is used for limiting the position of the lower die support plate so that the lower die support plate can slide stably.

The beneficial effects of the utility model are that: after the thermal transfer printing is completed, the upper die pressing plate is moved to a hovering state from a pressing state, in the process, the head raising arm drives the ratchet wheel to rotate through the pawl, the ratchet wheel drives the gear to rotate through the linkage shaft, and the gear can drive the rack to move, so that the rack drives the lower die supporting plate to move towards the outer side of the supporting plate groove, the distance between the lower die supporting plate and the upper die pressing plate is increased, and articles can be conveniently observed, picked and placed.

Drawings

FIG. 1 is a schematic structural diagram of an embodiment;

fig. 2 is a sectional view of the embodiment.

Reference numerals: 1. a frame; 2. an upper die pressing plate; 3. a lower die support plate; 4. a head raising arm; 5. a pawl; 6. a rotating shaft; 7. a linkage shaft; 8. a ratchet wheel; 9. a gear; 10. a transmission rack.

Detailed Description

The following is only the preferred embodiment of the present invention, the protection scope is not limited to this embodiment, and all technical solutions belonging to the idea of the present invention should belong to the protection scope of the present invention. In which like parts are designated by like reference numerals. It should be noted that as used in the following description, the terms "front," "back," "left," "right," "upper" and "lower" refer to directions in the drawings, and the terms "bottom" and "top," "inner" and "outer" refer to directions toward and away from, respectively, the geometric center of a particular component.

As shown in fig. 1 and 2, a combined type thermal transfer printer includes a frame 1. The frame 1 is provided with an upper die mechanism and a lower die mechanism, an article needing thermal transfer printing is placed on the lower die mechanism, and then the upper die mechanism and the lower die mechanism are folded, so that the thermal transfer printing of the article can be completed.

The upper die mechanism is fixedly provided with a power structure, the frame 1 is internally provided with a transmission mechanism, the power structure is matched with the transmission mechanism, when the upper die mechanism is separated from the lower die mechanism upwards, the power structure can drive the transmission structure to be started, and after the transmission structure is started, the lower die mechanism can be pushed out to one side, so that articles on the lower die mechanism can be conveniently taken and placed.

The lower die mechanism further comprises a lower die supporting plate 3, the article is placed on the lower die supporting plate 3, the upper die mechanism comprises a head lifting arm 4 and an upper die pressing plate 2, the upper die pressing plate 2 is connected with the upper end of the head lifting arm 4, the upper die pressing plate 2 comprises a pressing state and a hovering state, and in the pressing state, the upper end of the head lifting arm 4 drives the upper die pressing plate 2 to move downwards, so that the upper die pressing plate 2 is close to the lower die supporting plate 3, and heat transfer printing of the article is completed. When the article is suspended, the upper die pressing plate 2 is separated from the lower die support plate 3, and the article can be taken out. In the process of converting from a hovering state to a pressing state, the head-up arm 4 cannot drive the transmission mechanism to start through the power structure, and actions between the upper die pressing plate 2 and the lower die supporting plate 3 are independent. In the process of changing the pressing state into the hovering state, the head raising arm 4 can drive the transmission mechanism to start through the power structure, so that the transmission mechanism drives the lower die pressing plate to move, the lower die pressing plate moves to the outer side of the rack 1, and articles are conveniently taken and placed.

The power structure is located the lower extreme of raising the head arm 4, and with raising the head arm 4 fixed connection, and the power structure includes pawl 5, and the lower extreme of raising the head arm 4 is the arc, and the lower extreme of raising the head arm 4 is equipped with axis of rotation 6, and axis of rotation 6 transversely runs through the lateral wall of raising the head arm 4, and rotates with raising the head arm 4 and be connected, and the both ends of axis of rotation 6 are inserted respectively and are established on frame 1, and with frame 1 fixed connection. The power structure comprises a contact state and a disconnection state, wherein in the contact state, the power structure is in transmission connection with the transmission mechanism so that the power structure drives the transmission mechanism to start, and in the disconnection state, the power structure is separated from the transmission mechanism, and the transmission mechanism is not controlled by the power mechanism. When the upper die pressing plate 2 is switched between the two states, the head raising arm 4 can be driven to rotate around the rotating shaft 6, the lower end of the head raising arm 4 can drive the pawl 5 to move, when the pawl 5 moves in the forward direction, the transmission structure can be driven to start, and when the pawl 5 moves in the reverse direction, the transmission structure cannot be driven to start.

The power mechanism comprises a linkage shaft 7, a ratchet wheel 8 and a gear 9, the ratchet wheel 8 and the gear 9 are both positioned on the linkage shaft 7 and fixedly connected with the linkage shaft 7, the ratchet wheel 8 is matched with the pawl 5, the pawl 5 drives the gear 9 to synchronously rotate through the linkage rod, the gear 9 is in transmission connection with the lower die mechanism, and the gear 9 is used for driving the lower die mechanism to move. The inner edge of the gear 9 is fixedly provided with a one-way bearing which is fixedly connected with the linkage shaft 7. When the pawl 5 moves forward, the ratchet wheel 8 is driven to rotate forward, and the ratchet wheel 8 drives the gear 9 to rotate forward through the linkage shaft 7. When the linkage shaft 7 rotates reversely, the gear 9 cannot be driven to rotate.

The lower die mechanism comprises a transmission rack 10, a sliding groove is formed in the rack 1, the transmission rack 10 is located in the sliding groove and is in sliding connection with the sliding groove, and the transmission rack 10 is meshed with the gear 9. The rack 1 is provided with a support plate groove, the lower die support plate 3 is positioned in the support plate groove and is in sliding fit with the support plate groove, one end of the transmission rack 10 is fixedly connected with the lower die support plate 3, and the transmission rack 10 is used for driving the lower die support plate 3 to move. When the linkage shaft 7 drives the gear 9 to rotate in the forward direction, the gear 9 can drive the transmission rack 10 to move, so that the transmission rack 10 drives the lower die supporting plate 3 to move, and the lower die supporting plate 3 is moved out of the outer side.

The side wall of the lower die support plate 3 is provided with a guide groove. The side wall of the support plate groove is fixedly provided with a guide rail, the guide groove is in sliding fit with the guide rail, and the guide rail is used for limiting the position of the lower mold support plate 3 so that the lower mold support plate 3 can slide stably.

The working principle is as follows: when the lifting mechanism is used, the upper die pressing plate 2 is pressed downwards, the upper die pressing plate 2 drives the head raising arm 4 to move, the head raising arm 4 drives the pawl 5 to move reversely, and the pawl 5 cannot drive the ratchet 8 to rotate; when the upper die pressing plate 2 is lifted upwards, the upper die pressing plate 2 can drive the head lifting arm 4 to move, the head lifting arm 4 drives the pawl 5 to move in the forward direction, the pawl 5 can drive the ratchet 8 to rotate in the forward direction, so that the ratchet 8 drives the gear 9 to rotate in the forward direction through the universal driving shaft 7, the gear 9 can drive the transmission rack 10 to move at the moment, the transmission rack 10 can drive the lower die supporting plate 3 to move, the lower die supporting plate 3 is moved out of the supporting plate groove, and the object on the lower die supporting plate 3 can be conveniently taken and placed.

The above-mentioned embodiments further explain in detail the technical problems, technical solutions and advantages solved by the present invention, and it should be understood that the above only is a specific embodiment of the present invention, and is not intended to limit the present invention, and any modifications, equivalent substitutions, improvements, etc. made within the spirit and principle of the present invention should be included in the scope of the present invention.

Claims (7)

1. The utility model provides a combined heat-transfer machine, includes frame (1), its characterized in that, be equipped with upper die mechanism and lower die mechanism on frame (1), upper die mechanism and lower die mechanism all with frame (1) swing joint, be equipped with drive mechanism in frame (1), drive mechanism is connected with lower die mechanism, drive mechanism is used for driving lower die mechanism and removes, the last power structure that has set firmly of upper die mechanism, power structure includes contact state and off-state, during the contact state, power structure is connected with the drive mechanism transmission to make power structure drive mechanism start, during the off-state, power structure and drive mechanism separation, drive mechanism is not controlled by power unit, upper die mechanism passes through drive mechanism and drives lower die mechanism synchronous activity.

2. The combined type thermal transfer printer according to claim 1, wherein the upper mold mechanism comprises a head-raising arm (4), the power structure is located at the lower end of the head-raising arm (4) and is fixedly connected with the head-raising arm (4), the power structure comprises a pawl (5), the lower end of the head-raising arm (4) is arc-shaped, the lower end of the head-raising arm (4) is provided with a rotating shaft (6), the rotating shaft (6) transversely penetrates through the side wall of the head-raising arm (4) and is rotatably connected with the head-raising arm (4), and two ends of the rotating shaft (6) are respectively inserted on the frame (1) and are fixedly connected with the frame (1).

3. The combined thermal transfer printer according to claim 2, wherein the upper mold mechanism further comprises an upper mold platen (2), the upper mold platen (2) is connected to an upper end of the raising arm (4), the upper mold platen (2) comprises a pressing state and a hovering state, the upper end of the raising arm (4) drives the upper mold platen (2) to move downwards in the pressing state, so that the pawl (5) is not in transmission fit with the transmission mechanism, and the raising arm (4) drives the upper mold platen (2) to move upwards in the hovering state, so that the pawl (5) drives the transmission mechanism to start.

4. The combined type heat transfer printing machine according to claim 3, wherein the power mechanism comprises a linkage shaft (7), a ratchet wheel (8) and a gear (9), the ratchet wheel (8) and the gear (9) are both located on the linkage shaft (7) and fixedly connected with the linkage shaft (7), the ratchet wheel (8) is matched with a pawl (5), the pawl (5) drives the gear (9) to synchronously rotate through the linkage rod, a one-way bearing is fixedly arranged on the inner edge of the gear (9), the one-way bearing is fixedly connected with the linkage shaft (7), the gear (9) is in transmission connection with a lower die mechanism, and the gear (9) is used for driving the lower die mechanism to move.

5. The combined type heat transfer printing machine according to claim 4, wherein the lower mold mechanism comprises a transmission rack (10), the frame (1) is provided with a sliding slot, the transmission rack (10) is located in the sliding slot and is slidably connected with the sliding slot, the transmission rack (10) is engaged with a gear (9), and the gear (9) is used for driving the transmission rack (10) to move along the sliding slot.

6. The combined type heat transfer printing machine according to claim 5, wherein the lower mold mechanism further comprises a lower mold support plate (3), a support plate groove is formed in the frame (1), the lower mold support plate (3) is located in the support plate groove and slidably engaged with the support plate groove, one end of the transmission rack (10) is fixedly connected with the lower mold support plate (3), and the transmission rack (10) is used for driving the lower mold support plate (3) to move.

7. A combined type heat transfer printer according to claim 6, wherein the side walls of said lower die plate (3) are provided with guide grooves, and the side walls of said plate grooves are provided with guide rails, said guide grooves are slidably engaged with the guide rails, said guide rails are used for limiting the position of the lower die plate (3) so as to make the lower die plate (3) slide smoothly.

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