CN115320234A

CN115320234A - Silica gel cup sleeve heat transfer device

Info

Publication number: CN115320234A
Application number: CN202111557502.0A
Authority: CN
Inventors: 陈毅
Original assignee: Individual
Current assignee: Guangdong Yuxiang Silicon Plastic Co ltd
Priority date: 2021-12-19
Filing date: 2021-12-19
Publication date: 2022-11-11
Anticipated expiration: 2041-12-19
Also published as: CN115320234B

Abstract

The invention relates to a thermal transfer printing device, in particular to a thermal transfer printing device for a silica gel cup sleeve. The technical problem is as follows: the silicone glass sleeve heat transfer printing device can reduce risks, automatically and uniformly support a silicone glass sleeve and automatically perform heat transfer printing. The utility model provides a silica gel glass holder heat-transfer seal device, includes base, work board, railing, motor, the big straight-teeth gear of scarce tooth, first straight-teeth gear, first drive wheel, first axis of rotation, secondary drive wheel, second axis of rotation etc. and fixed mounting has the work board on the base, and the railing is installed at the interval on the work board, and the motor is installed to the upper left side of work board, connects a big straight-teeth gear of scarce tooth on the output shaft of motor. The invention replaces manpower with machinery, can improve the working efficiency and the product quality, and simultaneously reduces the working risk; the glass holder placing mechanism can place and open the silica gel glass holder.

Description

Silica gel cup sleeve heat transfer device

Technical Field

The invention relates to a thermal transfer printing device, in particular to a thermal transfer printing device for a silica gel cup sleeve.

Background

At present, the thermal transfer printing of the silica gel cup sleeve needs manual operation, the cup sleeve is firstly unfolded and then sleeved on a fixed frame, then two hands compress a thermal transfer printing film, then a thermal transfer printing machine is started, the thermal transfer printing machine is pressed downwards, the upper surface of the cup sleeve is pressed for one time through the thermal transfer printing film, a pattern on the thermal transfer printing film is thermally transferred to the silica gel cup sleeve, and then the silica gel cup sleeve is manually taken out. Manual operation still has some shortcomings, and is slower when strutting the silica gel glass holder and putting on the cover toward the mount, needs slowly to push inwards, needs the manual work to compress tightly the heat-transfer die in the heat-transfer seal, and heat-transfer seal in-process workman's both hands are nearer from the machine, and misoperation will lead to burn scald etc..

To above problem, need design one kind and can reduce the risk, prop open the silica gel glass holder automatically, compress tightly automatically and carry out the silica gel glass holder heat-transfer seal device of heat-transfer seal.

Disclosure of Invention

Relatively slow when strutting the cover on the mount in order to overcome silica gel glass holder, need slowly push away inwards, need the manual work to compress tightly the heat-transfer die in the heat-transfer seal, the in-process workman's of heat-transfer seal both hands are nearer from the machine, misoperation will lead to the shortcoming of burn scald, technical problem: the silicone glass sleeve heat transfer printing device can reduce risks, automatically open the silicone glass sleeve, automatically compress and perform heat transfer printing.

A silica gel cup sleeve heat transfer device comprises a base, a working plate, a railing, an annular track, a motor, a large straight gear with missing teeth, a first straight gear, a first transmission wheel, a first rotation shaft, a second transmission wheel, a second rotation shaft, a transmission belt, a third transmission wheel, a fourth transmission wheel, a printing film recovery wheel, a heat transfer film, a printing film placing wheel, a first shaft sleeve, a second shaft sleeve, a resistance connecting shaft, a cup sleeve placing mechanism and a pattern heat transfer mechanism, wherein the working plate is fixedly arranged on the base, the railing is arranged on the working plate at intervals, the annular track is arranged on the inner side of the railing on the working plate, the motor is arranged on the upper left side of the working plate, the output shaft of the motor is connected with the large straight gear with missing teeth, the first rotation shaft and the second rotation shaft are arranged on the left side of the working plate, the first rotation shaft is fixedly connected with the first transmission wheel, the front end of the first transmission wheel is provided with a first straight gear which can be meshed with the large missing-tooth straight gear, a second transmission wheel is arranged on a second rotating shaft, the front half part of the second rotating shaft is provided with a printing film recovery wheel, a first shaft sleeve is arranged between the printing film recovery wheel and the second transmission wheel on the second rotating shaft, the right side of the working plate is rotatably connected with a third transmission wheel and a fourth transmission wheel, the first transmission wheel, the second transmission wheel, the third transmission wheel and the fourth transmission wheel are sleeved with transmission belts, the middle part of the front surface of the working plate is rotatably connected with a resistance connecting shaft, the resistance connecting shaft is sleeved with a second shaft sleeve, the front end of the resistance connecting shaft is fixedly connected to the printing film placing wheel, the heat transfer films are sleeved on the printing film placing wheel, and the cup sleeve placing mechanisms are uniformly distributed on the transmission belts and used for placing and propping open the cup sleeves, the pattern heat transfer printing mechanism is arranged on the working plate and is used for thermally transferring the pattern to the opened cup sleeve.

Optionally, the glass holder placement machine constructs including the fixed plate, the slide, the fixed block, first semicolumn, the second semicolumn, spring and distraction mechanism, even cover has the fixed block on the driving belt, fixed block fixed mounting is on the fixed plate, the slide is still installed to the fixed plate rear side, fixed mounting has a first semicolumn on the fixed plate leading flank, two slides have been seted up on the fixed plate, sliding connection has the second semicolumn in the slide on the fixed plate, be fixed with the spring on being close to first semicolumn one side inner wall in the slide on the fixed plate, the spring other end is connected on the second semicolumn in the slide, distraction mechanism installs on fixed plate and slide.

Optionally, the opening mechanism comprises a U-shaped plate, a cross rotating rod and a special-shaped supporting column, the U-shaped plate is installed below the right side of the second driving wheel on the workbench, the sliding plate is connected with the special-shaped supporting column in a rotating mode, the shaft of the special-shaped supporting column penetrates through the fixing plate to be connected to the sliding plate, the cross rotating rod is fixedly connected with the gap between the fixing plate and the sliding plate in the shaft of the special-shaped supporting column, the cross rotating rod can rotate a quarter circle when passing through the U-shaped plate, and the first half cylinder and the second half cylinder are opened.

Optionally, the pattern heat-transfer printing mechanism is including placing the piece, the second straight-tooth gear, the fourth axis of rotation, the dwang, the head rod, the second connecting rod, the mounting bracket, fifth axis of rotation and heat-seal piece, the piece is placed in the installation of the second drive wheel right side of workstation left side below, the preceding top of placing the piece of workstation is rotated and is connected with the fourth axis of rotation, fixedly connected with second straight-tooth gear in the fourth axis of rotation, fourth axis of rotation foremost fixedly connected with dwang, the dwang opposite side articulates there is a head rod, the head rod other end articulates there is a second connecting rod, the second connecting rod other end is fixed on the mounting bracket, the mounting bracket both sides are rotated respectively and are connected with a fifth axis of rotation, still install the heat-seal piece on the mounting bracket, the heat-seal piece is prior art, through the heat-transfer printing technique with the pattern on the heat-transfer printing film on the silica gel cup cover.

Optionally, the cup holder further comprises a third rotating shaft, and the third rotating shaft is mounted at a position where the cup holder is sleeved on each of the first half cylinder and the second half cylinder.

Optionally, the base is fixed with the L-shaped fixing frame on the left side, the vertical wall of the L-shaped fixing frame is connected with the two sliding rods in a sliding mode, the tension springs are installed on the inner sides of the two sliding rods on the L-shaped fixing frame, the other ends of the sliding rods and the tension springs are installed on the L-shaped base plate, the moving rod is further installed on the L-shaped base plate, the L-shaped fixing rod is fixedly connected to the mounting frame, and the pushing inclined block is installed on the other side of the L-shaped fixing rod.

Optionally, the automatic discharging device further comprises a discharging slope, and the middle part of the rightmost side of the workbench is provided with the discharging slope.

The beneficial effects are that: the invention replaces manpower with machinery, can improve the working efficiency and the product quality, and simultaneously reduces the working risk; the cup sleeve placing mechanism can place and open the silica gel cup sleeve, so that the time for manually opening the cup sleeve is reduced; during thermal transfer printing, the cup sleeve can be uniformly spread, the probability of pattern shrinkage after the cup sleeve is loosened is reduced, and the product quality is improved; during heat transfer printing, the two fifth rotating shafts are used for replacing the hands of workers to press the heat transfer printing film tightly, so that the risk of injury of the workers is eliminated; during thermal transfer printing, an L-shaped backing plate is padded inside the silica gel cup sleeve, so that the printing surface of the cup sleeve can be flattened, and patterns can be conveniently printed; the cup sleeve with the heat transfer printing completed does not need to be manually taken out, and the cup sleeve placing mechanism can be automatically ejected out of the slope when the cup sleeve passes through the discharging slope, so that the cup sleeve placing mechanism is very convenient.

Drawings

Fig. 1 is a schematic perspective view of the present invention.

Fig. 2 is a schematic perspective view of the work board of the present invention.

Fig. 3 is a schematic perspective view of the drive belt of the present invention.

Fig. 4 is a partial perspective view of the drive belt of the present invention.

Fig. 5 is a schematic perspective view of the printing film placing wheel of the present invention.

Fig. 6 is a schematic perspective view of the cup holder placing mechanism according to the present invention.

Fig. 7 is a schematic perspective view of a first semi-cylinder according to the present invention.

Fig. 8 is a schematic perspective view of a second semi-cylinder according to the present invention.

Fig. 9 is a schematic perspective view of the special-shaped support column of the present invention.

FIG. 10 is a schematic perspective view of a thermal pattern transfer mechanism according to the present invention.

Fig. 11 is a schematic perspective view of an L-shaped pad of the present invention.

Reference numbers in the drawings: 1. a base, 2, a working plate, 201, a discharging slope, 202, a railing, 203, a U-shaped plate, 204, an annular track, 3, a motor, 301, a large missing tooth spur gear, 302, a first straight gear, 303, a first driving wheel, 304, a first rotating shaft, 305, a second driving wheel, 306, a second rotating shaft, 307, a driving belt, 308, a third driving wheel, 309 and a fourth driving wheel, 4, a fixing plate, 401, a sliding plate, 402, a fixing block, 403, a first semi-cylinder, 404, a second semi-cylinder, 405, a spring, 406, a cross rotating rod, 407 and a special-shaped supporting column, 408, a third rotating shaft, 5, a printing film recycling wheel, 501, a heat transfer film, 502, a printing film placing wheel, 503, a first shaft sleeve, 504, a second shaft sleeve, 505, a resistance connecting shaft, 6, a placing block, 601, a second spur gear, 602, a fourth rotating shaft, 603, a rotating rod, 604, a first connecting rod, 605, a second connecting rod, 606, a mounting rack, 607, a fifth rotating shaft, 608, a heat printing block, 7, an L-shaped fixing rack, 701, an L-shaped backing plate, 702, a sliding rod, 703, a tension spring, 704, a moving rod, 705, an L-shaped fixing rod, 706 and a pushing inclined block.

Detailed Description

The invention is described in detail below with reference to the figures and the embodiments.

Example 1

A silica gel cup sleeve heat transfer device is disclosed, as shown in figures 1-10, comprising a base 1, a working plate 2, a railing 202, an annular track 204, a motor 3, a tooth-missing big spur gear 301, a first straight gear 302, a first driving wheel 303, a first rotating shaft 304, a second driving wheel 305, a second rotating shaft 306, a driving belt 307, a third driving wheel 308, a fourth driving wheel 309, a printing film recovery wheel 5, a heat transfer film 501, a printing film placing wheel 502, a first shaft sleeve 503, a second shaft sleeve 504, a resistance connecting shaft 505, a cup sleeve placing mechanism and a pattern heat transfer mechanism, wherein the working plate 2 is fixedly arranged on the base 1, the railings 202 are arranged on the working plate 2 at intervals, the railings 202 just surround the cup sleeve placing mechanism, the silica gel cup sleeve on the cup sleeve placing mechanism can be prevented from falling down, the annular track 204 is arranged on the inner side of the railing 202 on the working plate 2, the motor 3 is arranged on the left upper side of the working plate 2, an output shaft of the motor 3 is connected with a large missing tooth spur gear 301, half of the teeth of the large missing tooth spur gear 301 are omitted, the large missing tooth spur gear 301 can only be meshed with one of a first straight gear 302 and a second straight gear 601 at the same time, a first rotating shaft 304 and a second rotating shaft 306 are arranged on the left side of the working plate 2, a first transmission wheel 303 is fixedly connected onto the first rotating shaft 304, the first straight gear 302 is mounted at the front end of the first transmission wheel 303, the first straight gear 302 can be meshed with the large missing tooth spur gear 301, the large missing tooth spur gear 301 drives the first straight gear 302 to rotate in a rotating mode, when the large missing tooth spur gear 301 rotates to the missing tooth position, the first straight gear 302 stops rotating, the first transmission wheel 303 is in the same motion state as the first straight gear 302 and stops in the same rotation mode, the first transmission wheel 303 drives the transmission belt 307 to rotate when rotating, the transmission belt 307 rotates in the same intermittent mode as the first transmission wheel 303, the driving belt 307 drives the second driving wheel 305, the third driving wheel 308 and the fourth driving wheel 309 to rotate together, the second driving wheel 305 is mounted on the second rotating shaft 306, the second driving wheel 305 is driven by the driving belt 307 to rotate, the second rotating shaft 306 also rotates along with the second driving wheel 305, the printing film recovery wheel 5 is mounted on the front half portion of the second rotating shaft 306, a first sleeve 503 is mounted between the printing film recovery wheel 5 and the second driving wheel 305 on the second rotating shaft 306, the third driving wheel 308 and the fourth driving wheel 309 are rotatably connected to the right side of the working plate 2, the third driving wheel 308 and the fourth driving wheel 309 are in the same vertical line, the first driving wheel 303, the second driving wheel 305, the third driving wheel 308 and the fourth driving wheel 309 are sleeved with the driving belt 307, a resistance connecting shaft 505 is rotatably connected to the middle portion of the front surface of the working plate 2, the resistance 505 is mounted on the second sleeve 504, the front end of the resistance connecting shaft 505 is fixedly connected to the printing film placing wheel 502, the thermal transfer film placing wheel 502 is sleeved with the thermal transfer film placing wheel 502, the thermal transfer film placing wheel 502 is not rotated by the resistance connecting shaft 505, only when the fifth driving belt is pressed against the thermal transfer sleeve 505, and the thermal transfer cup holding mechanism is uniformly spread, and the cup holding pattern is uniformly spread by the cup holding mechanism 607.

When the device works, firstly, the silica gel cup sleeve is sleeved on the cup sleeve placing mechanism, then the heat transfer film 501 is sleeved in the printing film placing wheel 502, waste paper at the front section of the heat transfer film 501 is wound on the printing film recycling wheel 5, the motor 3 is started, the motor 3 drives the large missing-tooth spur gear 301 to rotate, the large missing-tooth spur gear 301 is firstly meshed with the first spur gear 302, the large missing-tooth spur gear 301 drives the first spur gear 302 to rotate, the first spur gear 302 drives the first rotating shaft 304 to rotate, the first driving wheel 303 on the first rotating shaft 304 also rotates along with the first straight gear, the driving belt 307 on the first driving wheel 303 also starts to rotate, the second driving wheel 305, the third driving wheel 308 and the fourth driving wheel 309 on the first belt start to rotate under the driving of the first driving wheel 303, when the gear-missing big spur gear 301 is meshed with the first spur gear 302 and then is rotated to a gear-missing position, the whole transmission belt 307 stops rotating, when the gear-missing big spur gear 301 rotates for one circle, the transmission belt 307 rotates for one end distance, the function of intermittent rotation is achieved, one cup holder placing mechanism can move to the position below the pattern heat transfer mechanism in each rotation, at the moment, a silica gel cup holder in the cup holder placing mechanism can be propped open, when the gear-missing big spur gear 301 is not meshed with the first spur gear 302, the gear-missing big spur gear 301 is meshed with the second spur gear 601 in the pattern heat transfer mechanism, the pattern heat transfer mechanism presses the heat transfer film 501, and the pattern on the heat transfer film 501 is subjected to heat transfer printing on the propped-open silica gel cup holder.

Example 2

On the basis of the embodiment 1, as shown in fig. 6 to 9, the cup holder placing mechanism includes a fixing plate 4, a sliding plate 401, a fixing block 402, a first semi-cylinder 403, a second semi-cylinder 404, a spring 405 and a spreading mechanism, the fixing block 402 is uniformly sleeved on a transmission belt 307, the fixing block 402 drives the cup holder placing mechanism to intermittently move along with the transmission belt 307, when the fixing block 402 rotates to the positions of the first transmission wheel 303, the second transmission wheel 305, the third transmission wheel 308 and the fourth transmission wheel 309, the fixing block 402 is not influenced by the first transmission wheel 303, the second transmission wheel 305, the third transmission wheel 308 and the fourth transmission wheel 309, the fixing block 402 is fixedly installed on the fixing plate 4, the sliding plate 401 is further installed at the lower portion of the rear side of the fixing plate 4, the sliding plate 401 slides on the circular track 204, fixed mounting has a first semicircle post 403 on the fixed plate 4 leading flank, first semicircle post 403 right side wall lower part is opened there is an arc wall, two slides have been seted up on the fixed plate 4, sliding connection has second semicircle post 404 in the slide on the fixed plate 4, an arc wall has also been opened on second semicircle post 404 left side wall upper portion, the arc wall size of seting up on first semicircle post 403 and the second semicircle post 404 is the same, the position is opposite, be fixed with spring 405 on being close to one side inner wall of first semicircle post 403 in the slide on the fixed plate 4, the second semicircle post 404 in the slide is connected to the spring 405 other end, spring 405 is used for pulling back the normal position with the second semicircle post 404 that loosens, distraction mechanism installs on fixed plate 4 and slide 401.

The silica gel cup sleeve is sleeved on a first semi-cylinder 403 and a second semi-cylinder 404 in the cup sleeve placing mechanism, the fixing block 402 is sleeved on the transmission belt 307, when the transmission belt 307 rotates, the fixing block 402 drives the whole cup sleeve placing mechanism to move, the sliding plate 401 slides on the outer side of the transmission belt 307 on the working plate 2, when the cup sleeve placing mechanism rotates to the position below the pattern heat transfer mechanism along the transmission belt 307, the first semi-cylinder 403 and the second semi-cylinder 404 can be unfolded by the unfolding mechanism, the silica gel cup sleeve is unfolded, after the pattern heat transfer is completed, the first semi-cylinder 403 and the second semi-cylinder 404 are loosened by the unfolding mechanism, the second semi-cylinder 404 is pulled by the spring 405 to be folded with the first semi-cylinder, and the function of placing and unfolding the silica gel cup sleeve is realized by the cup sleeve placing mechanism 403.

As shown in fig. 9, the expanding mechanism includes a U-shaped plate 203, a cross rotating rod 406 and a special-shaped supporting column 407, a U-shaped plate 203 is installed at the right lower side of the second transmission wheel 305 on the workbench, the vertical wall of the U-shaped plate 203 can just contact the cross rotating rod 406, the sliding plate 401 is rotatably connected with the special-shaped supporting column 407, two ends of the special-shaped supporting column 407 are formed into two quarter cylinders, the U-shaped plate can just be placed into an arc-shaped groove formed in the first half cylinder 403 and the second half cylinder 404, a short shaft is further fixed at the middle position of the rear portion of the special-shaped supporting column 407, the short shaft of the special-shaped supporting column 407 penetrates through the fixing plate 4 and is connected to the sliding plate 401, the cross rotating rod 406 is fixedly connected to a gap between the fixing plate 4 and the sliding plate 401 on the shaft of the special-shaped supporting column 407, the cross rotating rod 406 can rotate a quarter circle when passing through the U-shaped plate 203, the special-shaped supporting column 407 rotates out from the arc-shaped grooves formed in the first half cylinder 403 and the second half cylinder 404 when the cross rotating rod 406 rotates, the first half cylinder 403 and the second half cylinder 406 open, after the silicone sleeve heat transfer is well transferred, the cup sleeve is placed on the cup sleeve 203, the cup sleeve placed on the cup placed on the first half cylinder 404, the second half cylinder 406 and the second half cylinder 406.

When the cup holder placing mechanism moves to the position of the U-shaped plate 203 on the working plate 2, the cross rotating rod 406 is in contact with the vertical plate of the U-shaped plate 203, a quarter turn is rotated, the special-shaped supporting column 407 initially stays in the grooves formed in the first semi-cylinder 403 and the second semi-cylinder 404, after the cross rotating rod 406 rotates a quarter turn, the special-shaped supporting column 407 rotates out of the grooves formed in the first semi-cylinder 403 and the second semi-cylinder 404, two planes of the special-shaped supporting column 407 are respectively aligned with the first semi-cylinder 403 and the second semi-cylinder 404, the first semi-cylinder 403 and the second semi-cylinder 404 are opened, the silica gel cup holder is also opened, when the cup holder placing mechanism leaves the U-shaped plate 203, the cross rotating rod 406 is in contact with the other vertical plate on the U-shaped plate 203 again, a quarter turn is performed again, the special-shaped supporting column 407 rotates into the grooves formed in the first semi-cylinder 403 and the second semi-cylinder 404, the spring 405 connected to the second semi-cylinder 404 is restored, the second semi-cylinder 404 is pulled to the first semi-cylinder 403, and the silica gel cup holder is loosened.

As shown in fig. 10, the pattern thermal transfer printing mechanism includes a placement block 6, a second spur gear 601, a fourth rotation shaft 602, a rotation rod 603, a first connection rod 604, a second connection rod 605, a mounting rack 606, a fifth rotation shaft 607 and a thermal printing block 608, the placement block 6 is installed on the right side of a second transmission wheel 305 on the lower left of the workbench, the upper side of the placement block 6 on the workbench is rotatably connected with the fourth rotation shaft 602, the second spur gear 601 is fixedly connected to the fourth rotation shaft 602, the second spur gear 601 can be meshed with the large missing-tooth spur gear 301, when the second spur gear 601 rotates, the whole pattern thermal transfer printing mechanism is driven to reciprocate up and down, the rotation rod 603 is fixedly connected to the forefront end of the fourth rotation shaft 602, the rotation rod 603 rotates along with the fourth rotation shaft 602, the other side of the rotation rod 603 is hinged with the first connection rod 604, the other end of the first connection rod 604 is hinged to the second connection rod 604, the other end of the second connection rod 605 is fixed to the mounting rack 606, the mounting rack 606 is slidably connected to the placement block 6, two sides of the mounting rack 606 are respectively rotatably connected with the fifth rotation shaft 607, the thermal transfer printing block 608, the thermal printing block is also installed on the thermal printing block 606, the conventional silicone printing cup for applying a thermal printing technology to a pattern on the silicone printing cup.

After the cup holder placing mechanism expands the silicone cup holder, the silicone cup holder stays for a period of time due to the transmission belt 307 which rotates intermittently, at this time, the large toothless spur gear 301 is meshed with the second spur gear 601, the second spur gear 601 rotates to drive the fourth rotating shaft 602 to rotate, the rotating rod 603 fixed on the fourth rotating shaft 602 also rotates along with the rotating rod, the first connecting rod 604 hinged on the fixing rod 7 moves along with the rotating rod, the second connecting rod 605 reciprocates up and down due to the movement of the first connecting rod 604 and simultaneously drives the mounting rack 606 to move up and down, the two fifth rotating shafts 607 on the mounting rack 606 press the thermal transfer film 501 down, the film placing wheel 502 and the film recovery wheel 5 both rotate, a part of the thermal transfer film 501 is released, after the thermal transfer block 608 presses the thermal transfer film 501 against the silicone cup holder, various patterns on the thermal transfer film 501 are thermally transferred onto the silicone cup holder, after the patterns are thermally transferred, the whole device moves up, after the patterns are moved to the original position, the large toothless spur gear 301 stops being meshed with the second spur gear 601, and the pattern thermal transfer function of the silicone cup holder is achieved.

Example 3

On the basis of the embodiment 2, as shown in fig. 6 to 8, the silicone glass holder further includes a third rotating shaft 408, the third rotating shaft 408 is installed at a position on each of the first semicylinder 403 and the second semicylinder 404 where the silicone glass holder is sleeved, and when the silicone glass holder is unfolded by the cup holder placing mechanism, the silicone glass holder can slightly rotate by the third rotating shaft 408, so that the silicone glass holder is uniformly unfolded, and the quality of a finished product is improved.

After the opening mechanism opens the first semicylinder 403 and the second semicylinder 404, the silica gel cup sleeve is also opened, but in order to prevent the silica gel cup sleeve from opening unevenly, the third rotating shaft 408 is installed on the first semicylinder 403 and the second semicylinder 404, when the silica gel cup sleeve is opened, the third rotating shaft 408 enables the silica gel cup sleeve to rotate, the silica gel cup sleeve is opened evenly, and the figure of the thermal transfer printing is not deformed due to the uneven opening of the silica gel cup sleeve.

As shown in fig. 11, the device further comprises an L-shaped fixing frame 7, an L-shaped backing plate 701, a sliding rod 702, a tension spring 703, a moving rod 704, an L-shaped fixing rod 705 and a pushing inclined block 706, the L-shaped fixing frame 7 is fixed on the left side of the base, the vertical wall of the L-shaped fixing frame 7 faces upwards, two sliding rods 702 are slidably connected to the vertical wall of the L-shaped fixing frame 7, the sliding rods 702 penetrate through the L-shaped fixing frame 7, the tension spring 703 is installed on the inner sides of the two sliding rods 702 on the L-shaped fixing frame 7, the tension spring 703 is used for pulling the L-shaped backing plate 701 back to the original position, the other ends of the sliding rods 702 and the tension spring 703 are installed on the L-shaped backing plate 701, the sliding rods 702 can enable the L-shaped backing plate 701 to slide back and forth, the sliding rods 702 also play a role in supporting and fixing, the moving rod 704 is further installed on the L-shaped backing plate 701, the moving rod is a circular disc connected to the front end of a cylinder, the L-shaped fixing rod 705 is fixedly connected to the mounting frame 606, the vertical wall of the L-shaped fixing rod 705 faces downwards, the other side of the L-shaped fixing rod 705 is installed with a pushing inclined block 706, and pushes the inclined block 706 to push the inclined block 706 to move upwards and downwards along with the inclined plane 706 when the inclined block 706.

When the pattern heat transfer mechanism transfers a heat pattern to the silicone sleeve, nothing is supported on the lower portion of the sleeve, and the pattern may be incompletely pressed, so that an L-shaped pad 701 is added to assist heat transfer, when the pattern heat transfer mechanism is pressed downwards, the L-shaped fixing rod 705 fixed on the mounting frame 606 moves downwards along with the whole device, the pushing inclined block 706 fixed on the L-shaped fixing rod 705 also presses downwards, when the pushing inclined block 706 contacts with a disk at the front end of the moving rod 704, the pushing inclined block 706 presses the moving rod 704 to move backwards, the moving rod 704 pushes the L-shaped pad into the inner side of the silicone sleeve, the heat printing block 608 pushes the heat with the complete pattern onto the silicone sleeve, so that the function of the complete heat transfer pattern is realized, when the heat transfer is completed, the pushing inclined block 706 and the L-shaped fixing rod 705 return upwards along with the mounting frame 606, the tension spring 703 pulls the L-shaped pad 701 out of the silicone sleeve, and the sliding rod 702 connected to the L-shaped pad 701 also slides forwards to return.

As shown in fig. 2, the cup holder placing mechanism further comprises a discharging slope 201, the discharging slope 201 is installed in the middle of the rightmost side of the workbench, when the driving belt 307 drives the cup holder placing mechanism to rotate to the right side of the working plate 2, the silicone cup holder on the cup holder placing mechanism can be gradually pushed out of the cup holder placing mechanism along the slope through the discharging slope 201.

When the driving belt 307 drives the cup holder placing mechanism to rotate to the right side of the working plate 2, the cup holder placing mechanism can be gradually pushed out along the slope through the discharging slope 201, and the function of automatic discharging is realized.

While the disclosure has been described with respect to a limited number of embodiments, those skilled in the art, having benefit of this disclosure, will appreciate that various other embodiments can be devised which do not depart from the scope of the invention as disclosed herein. Accordingly, the scope of the invention should be limited only by the attached claims.

Claims

1. A silica gel cup sleeve heat transfer device is characterized by comprising a base (1), a working plate (2), a railing (202), an annular track (204), a motor (3), a large tooth-missing spur gear (301), a first straight gear (302), a first driving wheel (303), a first rotating shaft (304), a second driving wheel (305), a second rotating shaft (306), a driving belt (307), a third driving wheel (308), a fourth driving wheel (309), a printing film recovery wheel (5), a heat transfer film (501), a printing film placing wheel (502), a first shaft sleeve (503), a second shaft sleeve (504), a resistance connecting shaft (505), a cup sleeve placing mechanism and a pattern heat transfer mechanism, wherein the working plate (2) is fixedly installed on the base (1), the railings (202) are installed on the working plate (2) at intervals, the annular track (204) is installed on the inner side of the railing (202) on the working plate (2), the motor (3) is installed on the upper left side of the working plate (2), the output shaft of the motor (3) is connected with the large tooth-missing spur gear (301), the first rotating shaft (304) and the first driving wheel (303) are installed on the left side of the first rotating shaft (304), the first straight gear (302) can be meshed with the large missing-tooth straight gear (301), a second transmission wheel (305) is installed on a second rotating shaft (306), a printing film recovery wheel (5) is installed on the front half portion of the second rotating shaft (306), a first shaft sleeve (503) is installed between the printing film recovery wheel (5) and the second transmission wheel (305) on the second rotating shaft (306), a third transmission wheel (308) and a fourth transmission wheel (309) are rotatably connected to the right side of the working plate (2), a first transmission wheel (303), the second transmission wheel (305), a transmission belt (307) is sleeved on the third transmission wheel (308) and the fourth transmission wheel (309), a resistance connecting shaft (505) is rotatably connected to the position, which is deviated from the left, in the middle of the front surface of the working plate (2), a second shaft sleeve (504) is sleeved on the resistance connecting shaft (505), the front end of the resistance connecting shaft (505) is fixedly connected to the printing film placing wheel (502), a heat transfer film placing wheel (501) is sleeved on the printing film placing wheel (502), the cup sleeve placing mechanisms are uniformly distributed on the transmission belt (307), the cup placing mechanisms can be placed on the heat transfer printing patterns, and the cup transferring mechanisms can be installed on the heat transferring cup transferring mechanisms (2).

2. The thermal transfer printing device for the silica gel cup sleeves according to claim 1, wherein the cup sleeve placing mechanism comprises a fixing plate (4), a sliding plate (401), a fixing block (402), a first semi-cylinder (403), a second semi-cylinder (404), a spring (405) and a supporting mechanism, the fixing block (402) is uniformly sleeved on a transmission belt (307), the fixing block (402) is fixedly installed on the fixing plate (4), the sliding plate (401) is further installed on the rear side of the fixing plate (4), the first semi-cylinder (403) is fixedly installed on the front side face of the fixing plate (4), two slideways are formed in the fixing plate (4), the second semi-cylinder (404) is connected to the slideways in the fixing plate (4) in a sliding mode, the spring (405) is fixed to the inner wall, close to the first semi-cylinder (403), of the slideways in the fixing plate (4), the other end of the spring (405) is connected to the second semi-cylinder (404) in the slideways, and the supporting mechanism is installed on the fixing plate (4) and the sliding plate (401).

3. The thermal transfer printing device for the silica gel cup sleeves according to claim 2, wherein the opening mechanism comprises a U-shaped plate (203), a cross rotating rod (406) and special-shaped supporting columns (407), the U-shaped plate (203) is installed on the lower right of the second transmission wheel (305) on the workbench, the special-shaped supporting columns (407) are connected to the sliding plate (401) in a rotating mode, shafts of the special-shaped supporting columns (407) penetrate through the fixing plate (4) to be connected to the sliding plate (401), the cross rotating rod (406) is fixedly connected to a gap between the fixing plate (4) and the sliding plate (401) on the shaft of the special-shaped supporting columns (407), the cross rotating rod (406) can rotate a quarter of a circle when passing through a vertical wall of one end of the U-shaped plate (203), the first semicylinder (403) and the second semicylinder (404) are opened, the cross rotating rod (406) rotates a quarter of a circle when passing through a vertical wall of the other side of the U-shaped plate (203), and the first semicylinder (403) and the second semicylinder (404) are closed.

4. The silicone cup sleeve heat transfer printing device according to claim 3, wherein the pattern heat transfer printing mechanism comprises a placement block (6), a second spur gear (601), a fourth rotating shaft (602), a rotating rod (603), a first connecting rod (604), a second connecting rod (605), a mounting frame (606), a fifth rotating shaft (607) and a heat printing block (608), the placement block (6) is installed on the right side of the second driving wheel (305) below the left side of the workbench, the fourth rotating shaft (602) is rotatably connected above the placement block (6) in front of the workbench, the second spur gear (601) is fixedly connected to the fourth rotating shaft (602), the rotating rod (603) is fixedly connected to the foremost end of the fourth rotating shaft (602), the first connecting rod (604) is hinged to the other side of the rotating rod (603), the second connecting rod (605) is hinged to the other end of the first connecting rod (604), the other end of the second connecting rod (605) is fixed to the mounting frame (606), the fifth rotating shaft (607) is rotatably connected to both sides of the mounting frame (606), the heat printing block (608) is further installed on the heat transfer printing block (606), and the existing silicone cup sleeve is a pattern which is printed by the existing heat transfer printing technology.

5. The thermal transfer printing device for the silica gel cup sleeves as claimed in claim 4, further comprising a third rotating shaft (408), wherein the third rotating shaft (408) is installed at the position where the cup sleeve is sleeved on each of the first semi-cylinder (403) and the second semi-cylinder (404).

6. The thermal transfer printing device for the silicone cup sleeves according to claim 5, further comprising an L-shaped fixing frame (7), an L-shaped backing plate (701), sliding rods (702), tension springs (703), moving rods (704), L-shaped fixing rods (705) and a pushing inclined block (706), wherein the L-shaped fixing frame (7) is fixed on the left side of the base, the two sliding rods (702) are slidably connected to the vertical wall of the L-shaped fixing frame (7), the tension springs (703) are installed on the inner sides of the two sliding rods (702) on the L-shaped fixing frame (7), the other ends of the sliding rods (702) and the tension springs (703) are installed on the L-shaped backing plate (701), the moving rods (704) are further installed on the L-shaped backing plate (701), one L-shaped fixing rod (705) is fixedly connected to the mounting frame (606), and one pushing inclined block (706) is installed on the other side of the L-shaped fixing rod (705).

7. The thermal transfer printing device for the silica gel cup sleeve according to claim 6, further comprising a discharging slope (201), wherein a discharging slope (201) is installed in the middle of the rightmost side of the workbench.