CN218702051U - Thermoprint pushes down mechanism and system card equipment - Google Patents

Abstract

The utility model discloses a thermoprint pushes down mechanism and card making equipment. The hot stamping pressing mechanism comprises a driving cam assembly and a pressing assembly; the pressing component comprises a pressing cap, a fixing plate, a reset elastic piece, a hot stamping block component and a pressing rod; the pressing cap is arranged below the driving cam component; the driving cam assembly intermittently presses the cap down; the fixing plate and the pressing cap are arranged at intervals up and down; the reset elastic element is connected between the pressing cap and the fixing plate; the hot stamping block assembly is arranged below the pressing cap; one end of the pressure rod is fixedly connected with the pressure cap, and the other end of the pressure rod is fixedly connected with the hot stamping block assembly. The technical proposal of the utility model drives the pressing component to press down or rise through the cam driving component, the transmission structure is simpler, and the cost is lower; the elastic part that resets is located and is pushed down between the cap and the fixed plate of subassembly, then can guarantee to push down the subassembly and can realize the effect that rises or push down steadily.

Description

Thermoprint pushes down mechanism and system card equipment

Technical Field

The utility model relates to a thermoprint equipment technical field, in particular to thermoprint pushes down mechanism and uses this thermoprint to push down system card equipment of mechanism.

Background

Smart cards are increasingly issued, most smart cards have raised characters, and in order to make the card surface beautiful and difficult to copy, gold stamping or silver stamping processes are generally performed on the raised characters of the smart cards. At present, hot stamping equipment for gold stamping or silver stamping carries out hot stamping through a pressing mechanism, but the driving of the pressing mechanism and a transmission assembly have higher cost or are more complex.

SUMMERY OF THE UTILITY MODEL

The utility model aims at providing a thermoprint pushes down mechanism aims at improving the complicated problem of thermoprint pushing down mechanism transmission.

In order to realize the aim, the hot stamping pressing mechanism provided by the utility model comprises a driving cam component and a pressing component; the pressing component comprises a pressing cap, a fixing plate, a reset elastic piece, a hot stamping block component and a pressing rod; the pressing cap is arranged below the driving cam assembly; the drive cam assembly intermittently depresses the press cap; the fixing plate and the pressing cap are arranged at intervals up and down; the reset elastic piece is connected between the pressing cap and the fixing plate; the hot stamping block assembly is arranged below the pressing cap; one end of the pressing rod is fixedly connected with the pressing cap, and the other end of the pressing rod is fixedly connected with the hot stamping block assembly.

Optionally, the drive cam assembly comprises a drive member, a rotating shaft and a cam; the rotating shaft is in transmission connection with the driving piece, and the driving piece drives the rotating shaft to rotate; the cam is connected to the rotating shaft and rotates along with the rotating shaft; the pressing cap is arranged below the cam, and the cam intermittently presses down the pressing cap.

Optionally, the cam comprises a link and a pinch roller; one end of the connecting rod is connected with the rotating shaft, the other end of the connecting rod extends outwards along the radial direction of the rotating shaft and is connected with the pressing wheel, the pressing cap is arranged below the pressing wheel, and the pressing wheel intermittently presses down the pressing cap.

Optionally, the fixing plate is located between the pressing cap and the hot stamping block assembly, and the pressing rod penetrates through the fixing plate.

Optionally, the pressing assembly further comprises a guide sleeve, the guide sleeve penetrates through the fixing plate, and the pressing rod penetrates through the guide sleeve.

Optionally, the return elastic member is a return spring, and the return spring is sleeved outside the pressing rod; and/or one end of the reset spring is propped against the pressing cap, and the other end of the reset spring is connected with the guide sleeve; and/or, the guide sleeve comprises a sleeving part and an installation part, the sleeving part penetrates through the fixing plate, and the pressing rod penetrates through the sleeving part; the installation part is connected to the sleeving part and fixedly connected with the fixing plate.

Optionally, the hot stamping block assembly comprises a partition plate, a hot stamping plate and a buffering elastic piece, wherein the partition plate is arranged below the pressing cap and is fixedly connected with the other end of the pressing rod; the hot stamping plate is arranged below the partition plate; the buffer elastic piece is abutted between the partition plate and the hot stamping plate.

The utility model also provides a card making equipment, including the embossed character code printing module, first thermoprint module and second thermoprint module, the embossed character code printing module has seted up the business turn over bayonet socket, the embossed character code printing module includes relative first region and second region, the business turn over bayonet socket is located between the first region and the second region, the direction of first region to the second region is perpendicular with the direction of getting in and out the card by the business turn over bayonet socket; the first hot stamping module is arranged in front of the embossed character coding module and corresponds to the first area or one side of the first area, which is far away from the second area; the second hot stamping module is arranged in front of the embossed character coding module and corresponds to the second area or one side of the second area far away from the first area; at least one of the first hot stamping module and the second hot stamping module is provided with the hot stamping pressing mechanism.

Optionally, the card manufacturing equipment further comprises a card transmission mechanism, and the card transmission mechanism is arranged between the first hot stamping module and the second hot stamping module and can slide between the first hot stamping module and the second hot stamping module.

Optionally, the card transmission mechanism includes a card clamping assembly, a guide rod and a limiting member, the card clamping assembly includes a frame and a clamping portion, the frame is provided with a through hole, and the clamping portion is connected to the frame and used for clamping a card; the guide rod is arranged between the first hot stamping module and the second hot stamping module and penetrates through the through hole; the rack slides along the guide rod so as to convey the clamping assembly to the in-out bayonet; the limiting piece is connected to the end portion of the guide rod.

Optionally, the card driving mechanism further comprises a first driving assembly, and the first driving assembly is connected with the frame to drive the frame to slide along the guide rod.

Optionally, the first driving assembly includes a first motor, a driving wheel, a driven wheel and a conveyor belt, and the driving wheel is connected to the first motor; the driven wheel and the driving wheel are arranged at intervals, and the direction from the driven wheel to the driving wheel is consistent with the extending direction of the guide rod; one end of the conveying belt is connected with the driving wheel, and the other end of the conveying belt is connected with the driven wheel; the frame is arranged on the conveyor belt.

Optionally, the clamping assembly further comprises a second driving assembly, and the second driving assembly is arranged on the frame and drives the clamping portion to move along a direction perpendicular to the extending direction of the guide rod.

Optionally, the second driving assembly comprises a second motor, a screw rod and a clamping part; the screw rod is connected with the second motor and is arranged perpendicular to the guide rod; the clamping part comprises a mounting seat arranged on the rack, the mounting seat is provided with a threaded hole, and the screw rod penetrates through the threaded hole and is in threaded fit with the threaded hole.

The technical scheme of the utility model is that the pressing cap is driven by the cam driving component to intermittently press downwards, the hot stamping block component is arranged below the pressing cap, one end of the pressing rod is fixedly connected with the pressing cap, and the other end of the pressing rod is fixedly connected with the hot stamping block component, so that the pressing cap is driven by the pressing rod to press downwards in the pressing process, and further the hot stamping effect on the product is realized; and the pressing cap is driven to press down through the cam driving assembly, so that the whole transmission mechanism is simpler, and a link mechanism, a gear rack mechanism and the like with more complicated structures and costs are avoided. In addition, the fixed plate and the pressing cap are arranged at intervals up and down, and the reset elastic part is connected between the pressing cap and the fixed plate, so that when the pressing cap moves downwards under the action of the cam driving assembly, the pressing cap drives the reset elastic part to deform; and when the cam driving assembly stops pressing the cap down, the elastic part that resets resumes to original state to the drive is pressed the cap and is also resumed to original state, thereby guarantees to press the cap and can realize better effect that resets, guarantees to press the cap and can steadily press down and rise with intermittent type nature.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings needed to be used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the structures shown in the drawings without creative efforts.

FIG. 1 is a schematic structural diagram of an embodiment of the interior of the hot stamping apparatus of the present invention;

FIG. 2 is a top view of the interior of the hot stamping apparatus of the present invention;

FIG. 3 isbase:Sub>A cross-sectional view A-A of FIG. 2;

FIG. 4 is an enlarged view of a portion of FIG. 2 at B;

fig. 5 is a schematic diagram of the position structures of the embossed character code printing module, the first hot stamping module and the second hot stamping module in the card manufacturing device of the present invention;

FIG. 6 is a schematic view of the position structure of the embossed-lettered code printing module and the card transmission mechanism in the card manufacturing device of the present invention;

FIG. 7 is an enlarged view of a portion of FIG. 6 at C;

fig. 8 is a schematic structural view of a card clamping assembly in the card manufacturing device of the present invention.

The reference numbers illustrate:

the objects, features and advantages of the present invention will be further described with reference to the accompanying drawings.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative efforts belong to the protection scope of the present invention.

It should be noted that, if directional indications (such as upper, lower, left, right, front and rear \8230;) are involved in the embodiments of the present invention, the directional indications are only used to explain the relative positional relationship between the components in a specific posture (as shown in the attached drawings), the motion situation, etc., and if the specific posture is changed, the directional indications are changed accordingly.

In addition, if there is a description relating to "first", "second", etc. in the embodiments of the present invention, the description of "first", "second", etc. is for descriptive purposes only and is not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include at least one such feature. In addition, the technical solutions in the embodiments may be combined with each other, but it must be based on the realization of those skilled in the art, and when the technical solutions are contradictory or cannot be realized, the combination of the technical solutions should not be considered to exist, and is not within the protection scope of the present invention.

The utility model provides a thermoprint pushes down mechanism.

In the embodiment of the present invention, please refer to fig. 1 to 4 in combination, the stamping pressing mechanism includes a cam driving assembly 100 and a pressing assembly 200; the pressing assembly 200 comprises a pressing cap 210, a fixing plate 220, a reset elastic element 240, a hot stamping block assembly 260 and a pressing rod 250; the pressing cap 210 is arranged below the cam driving assembly 100; the cam drive assembly 100 intermittently depresses the cap 210; the fixing plate 220 and the pressing cap 210 are arranged at intervals up and down; the restoring elastic member 240 is connected between the pressing cap 210 and the fixing plate 220; the hot stamping block assembly 260 is arranged below the pressing cap 210; one end of the pressing rod 250 is fixedly connected with the pressing cap 210, and the other end is fixedly connected with the hot stamping block assembly 260.

The pressing cap 210 is disposed under the cam driving assembly 100, and the cam driving assembly 100 intermittently presses the pressing cap 210, so that the pressing cap 210 intermittently performs a descending motion. The cam driving assembly 100 may include a driving member 110 and an eccentric wheel in transmission connection with the driving member 110, and a pressing cap 210 is disposed below the eccentric wheel; or the cam driving assembly 100 may also include a driving member 110 and a non-circular wheel in transmission connection with the driving member 110, and the pressing cap 210 is disposed below the non-circular wheel; or the cam driving assembly 100 may further include a driving member 110, a connecting rod 130 and a roller, one end of the connecting rod 130 is drivingly connected to the driving member 110, the other end is connected to the roller, and the pressing cap 210 is located below the roller. Therefore, through the arrangement of the cam driving component 100, the transmission structure of the hot stamping pressing mechanism is simpler, and the cost is lower; without the need to drive the pressing cap 210 to be pressed down or lifted by a complicated air cylinder or hydraulic cylinder device, which is costly and complicated in structure.

The fixing plate 220 of the pressing cap 210 and the pressing cap 210 are arranged at an interval from top to bottom, and the elastic restoring element 240 is connected between the pressing cap 210 and the fixing plate 220, so that when the cam driving assembly 100 presses the pressing cap 210 downwards, the pressing cap 210 drives the elastic restoring element 240 to generate elastic deformation; when the cam driving assembly 100 stops pressing the pressing cap 210, the elastic restoring member 240 restores to the initial state and drives the pressing cap 210 to also restore to the initial state (i.e., the pressing cap 210 is lifted from the pressed position to the initial position). Specifically, the fixing plate 220 may be disposed below the pressing cap 210, and when the pressing cap 210 moves downward under the driving action of the cam driving assembly 100, it drives the return elastic member 240 to compress; when the cam driving assembly 100 stops pressing the pressing cap 210, the elastic restoring member 240 returns to its initial state, that is, the elastic restoring member 240 extends reversely from the compressed state, so as to drive the pressing cap 210 to move upward to the initial state of the pressing cap 210. Alternatively, the fixing plate 220 may be disposed above the pressing cap 210, and when the pressing cap 210 moves downward under the driving action of the cam driving assembly 100, it drives the elastic restoring member 240 to stretch; when the cam driving assembly 100 stops pressing the pressing cap 210, the restoring elastic member 240 returns to its original state, that is, the restoring elastic member 240 retracts in the opposite direction from the stretched state, and further drives the pressing cap 210 to move upward to the original state of the pressing cap 210. So configured, it can be ensured that when the cam driving assembly 100 intermittently presses down the pressing cap 210, the pressing cap 210 can intermittently achieve the descending and ascending effects. In addition, the return elastic member 240 may be a spring, a spring plate, or another elastic member with a telescopic function. It should be noted that the fixing plate 220 in the technical solution of the present invention refers to a fixed plate, and may be a part of the frame or the fixing plate 220 fixedly connected to the frame. Additionally, the utility model discloses "upper" among the technical scheme, down "direction all is established with this thermoprint pushing down the normal operating condition of mechanism as the benchmark, and the direction that faces towards ground is the direction to" down "under this state promptly, and the direction that deviates from ground is the direction to" up ".

Thermoprint block subassembly 260 locates the below of pressing cap 210, and the one end fixed connection of depression bar 250 presses cap 210, and other end fixed connection thermoprint block subassembly 260 makes pressure cap 210 descend the in-process, and it drives thermoprint block subassembly 260 through depression bar 250 and descends together, and then realizes the thermoprint effect to the product. When the pressing cap 210 rises, the pressing rod 250 drives the hot stamping block assembly 260 to rise together, so that the effect of stopping hot stamping on the product is achieved. Specifically, when the fixing plate 220 is disposed below the pressing cap 210, the hot stamping block assembly 260 may be disposed above the fixing plate 220 or below the fixing plate 220. When the stamping block assembly 260 is arranged below the fixing plate 220, the pressing rod 250 can pass through the fixing plate 220; or the pressing rod 250 may be disposed outside the sidewall of the fixing plate 220, and one end of the pressing rod 250 is disposed above the fixing plate 220 and the other end is disposed below the fixing plate 220.

The technical scheme of the utility model is that the pressing cap 210 is driven by the cam driving component 100 to intermittently press downwards, the thermoprint block component 260 is arranged below the pressing cap 210, one end of the pressing rod 250 is fixedly connected with the pressing cap 210, and the other end of the pressing rod 250 is fixedly connected with the thermoprint block component 260, so that the pressing cap 210 drives the thermoprint block component 260 to press downwards through the pressing rod 250 in the pressing process, and the thermoprint effect on the product is further realized; and the cam driving component 100 drives the pressing cap 210 to press down, so that the whole transmission mechanism is simple. In addition, the fixing plate 220 and the pressing cap 210 are arranged at an interval up and down, and the reset elastic member 240 is connected between the pressing cap 210 and the fixing plate 220, so that when the pressing cap 210 moves downwards under the action of the cam driving assembly 100, the reset elastic member 240 is driven to deform; when the cam driving assembly 100 stops pressing down the pressing cap 210, the reset elastic member 240 returns to the original state and drives the pressing cap 210 to return to the original state, so that the pressing cap 210 can be ensured to realize a good reset effect, and the pressing cap 210 can be ensured to be stably pressed down and raised intermittently.

Referring to fig. 2 and fig. 3, in the present embodiment, the cam driving assembly 100 includes a driving member 110, a rotating shaft 120 and a cam assembly; the rotating shaft 120 is in transmission connection with the driving element 110, and the driving element 110 drives the rotating shaft 120 to rotate; the cam assembly is connected to the shaft 120 and rotates with the shaft 120; a press cap 210 is provided below the cam assembly, which intermittently depresses the press cap 210.

The driving member 110 drives the rotating shaft 120 to rotate, the rotating shaft 120 drives the cam assembly to rotate, and during the rotation of the rotating shaft 120, two portions of the cam assembly located at two opposite sides of the axis of the rotating shaft 120 are asymmetric, so that the cam assembly has a state of abutting against the pressing cap 210 and a state of leaving from the pressing cap 210. When the cam assembly abuts against the pressing cap 210, the pressing cap 210 moves downwards under the action of the cam assembly as the pressing cap 210 is positioned below the cam assembly; when the cam assembly leaves the press cap 210, the cam assembly no longer drives the press cap 210 to move downwards, so that the effect of intermittently pressing the press cap 210 downwards by the cam assembly can be achieved.

Specifically, referring to fig. 2 and 3 in combination, the cam assembly includes a connecting rod 130 and a pressing wheel 140; one end of the connecting rod 130 is connected to the rotating shaft 120, the other end of the connecting rod extends outwards along the radial direction of the rotating shaft 120 and is connected to the pressing wheel 140, the pressing cap 210 is arranged below the pressing wheel 140, and the pressing wheel 140 intermittently presses the pressing cap 210 downwards.

One end of the connecting rod 130 is connected with the rotating shaft 120, and the other end of the connecting rod 130 extends outwards along the radial direction of the rotating shaft 120 and is connected with the pressing wheel 140, so that the pressing wheel 140 and the connecting rod 130 rotate around the rotating shaft 120 together, and the distance from the pressing wheel 140 to the rotating shaft 120 is greater than the distance from the end of the connecting rod 130, which is not connected with the pressing wheel 140, to the rotating shaft 120. Therefore, when the pressing wheel 140 rotates to a side of the rotating shaft 120 close to the pressing cap 210, and the distance between the pressing wheel 140 and the rotating shaft 120 is large, and the space between the rotating shaft 120 and the pressing cap 210 is not enough to accommodate the pressing wheel 140, the pressing wheel 140 can press the pressing cap 210 downward, so that the effect of driving the pressing cap 210 to press downward is achieved. When the pressing wheel 140 rotates to a side of the rotating shaft 120 far away from the pressing cap 210, the pressing wheel 140 does not press the pressing cap 210 downward because the pressing wheel 140 is not affected by the size of the space between the rotating shaft 120 and the pressing cap 210, and thus the pressing cap 210 is not controlled by the pressing wheel 140. In summary, the pressing wheel 140 can intermittently press down the pressing cap 210. In addition, in the embodiment, the connecting rod 130 is connected to the pressing wheel 140, the pressing wheel 140 may be circular or not, and the connecting rod 130 is more simple and saves material compared to a scheme in which an eccentric wheel is directly sleeved on the rotating shaft 120, so that the rotating shaft 120 has a better driving effect on the pressing wheel 140.

Of course, in other embodiments, the connecting rod 130 and the pressing wheel 140 can be replaced by an elliptical or other non-circular wheel, which is sleeved outside the rotating shaft 120.

The utility model provides an embodiment, please combine and refer to fig. 1 to fig. 3, fixed plate 220 is located between pressure cap 210 and the thermoprint block subassembly 260, and the depression bar 250 wears to establish fixed plate 220.

So set up, then can make whole thermoprint push down mechanism structure compacter, and depression bar 250 wears to establish fixed plate 220, then this fixed plate 220 can all play the guide effect to the downward and ascending motion of depression bar 250 to guarantee that thermoprint push down mechanism can realize stable effect of pushing down.

Further, referring to fig. 2 and 3, the pressing assembly 200 further includes a guide sleeve 230, the guide sleeve 230 penetrates through the fixing plate 220, and the pressing rod 250 penetrates through the guide sleeve 230.

The guide sleeve 230 penetrates through the fixing plate 220, the pressing rod 250 penetrates through the guide sleeve 230, a good guiding effect is further achieved on the upward and downward movement of the pressing rod 250, and the stable pressing effect of the hot stamping pressing mechanism is further improved.

Referring to fig. 1 to fig. 3, based on the above scheme that the pressing rod 250 penetrates through the fixing plate 220, in the present embodiment, the elastic return element 240 is a return spring, and the return spring is sleeved outside the pressing rod 250.

Outside the depression bar 250 was located through the reset spring cover, then made reset spring can follow the extending direction compression and the extension of depression bar 250 better, and then reset spring can drive and press cap 210 to rise and push down along the extending direction of depression bar 250 to realize that thermoprint pushes down the mechanism and has good guide effect and good stability pushing down the in-process.

As shown in fig. 3, based on the solution that the guide sleeve 230 penetrates through the fixing plate 220, in this embodiment, one end of the elastic restoring element 240 may also abut against the pressing cap 210, and the other end thereof is connected to the guide sleeve 230.

With such an arrangement, the pressing cap 210 can be driven to ascend to the initial position under the action of the reset elastic element 240. Specifically, the return spring 240 may be connected to an outer sidewall of the guide sleeve 230, or the return spring 240 may be connected to an end surface of the guide sleeve 230, or the return spring 240 may be further connected to an inner sidewall of the guide sleeve 230.

As shown in fig. 3, the present invention further provides an embodiment: the reset elastic member 240 is a reset spring, and the reset spring is sleeved outside the pressing rod 250; the elastic restoring element 240 may also have one end abutting against the pressing cap 210 and the other end connected to the guide sleeve 230.

So set up, on the one hand can make thermoprint push down the overall structure of mechanism comparatively compact, on the other hand still guarantees that elastic component 240, depression bar 250 and pressure cap 210 reset all have good guide effect at rising and push down the in-process. Specifically, the guide sleeve 230 has a good guiding effect on the ascending and descending directions of the pressing rod 250, and the pressing rod 250 has a good guiding effect on the compressing and stretching directions of the restoring elastic member 240. Further, when the other end of the elastic restoring member 240 extends into the guide sleeve 230, the guide sleeve 230 has a good guiding effect on the stretching and compressing directions of the elastic restoring member 240 and the ascending and descending directions of the pressing rod 250 by the guide sleeve 230.

Further, as shown in fig. 3, the guide sleeve 230 includes a sleeve portion 231 and an installation portion 232, the sleeve portion 231 penetrates through the fixing plate 220, and the pressing rod 250 penetrates through the sleeve portion 231; the mounting portion 232 is connected to the engaging portion 231 and is fixedly connected to the fixing plate 220.

The engaging portion 231 penetrates the fixing plate 220, and the pressing rod 250 penetrates the engaging portion 231, so that the engaging portion 231 has a good guiding effect at least in the ascending and descending directions of the pressing rod 250. In addition, the mounting portion 232 is connected to the sleeve portion 231 and is fixedly connected to the fixing plate 220, so that the guide sleeve 230 and the fixing plate 220 can be ensured to have a good fixing connection effect. Specifically, the mounting portion 232 may be a connection lug protruding from an outer side wall of the sleeve portion 231, or the mounting portion 232 may be a connection plate protruding from an end surface of the sleeve portion 231 to an outer side. The mounting portion 232 and the fixing plate 220 may be fixedly connected by means of a screw, welding, or caulking.

Referring to fig. 1 to fig. 3, in the present embodiment, the stamping block assembly 260 includes a partition 261, a stamping plate 262 and a buffering elastic member 263, wherein the partition 261 is disposed below the pressing cap 210 and is fixedly connected to the other end of the pressing rod 250; the hot stamping plate 262 is arranged below the partition 261; the buffering elastic element 263 is pressed between the partition 261 and the stamping plate 262.

The stamping plate 262 is used for stamping the product. The partition plate 261 is located below the pressing cap 210 and connected to the other end of the pressing rod 250, the hot stamping plate 262 is arranged below the partition plate 261, and the partition plate 261 has an effect of isolating the hot stamping plate 262 from the pressing rod 250 and has a protection effect on the hot stamping plate 262. In addition, since the cam driving assembly 100 has a sudden impact force when pressing down the pressing cap 210, in the embodiment, the buffering elastic member 263 abuts between the partition 261 and the hot stamping plate 262, so that in the pressing down process of the pressing rod 250, the partition 261 has a direct downward pressure on the buffering elastic member 263, and a large downward pressing impact force on the hot stamping plate 262 due to direct rigid contact between the partition 261 and the hot stamping plate 262 is avoided, thereby preventing the hot stamping plate 262 from having a large impact force on the product.

Specifically, the buffering elastic member 263 may be a spring, a leaf spring, or other elastic material (e.g., rubber or silicone). In order to realize the hot stamping effect, a heating wire 265 may be disposed in the hot stamping plate 262, and the heating wire 265 performs heat transfer on the hot stamping plate 262 after heating, so that the heated hot stamping plate 262 stamps gold paper or silver paper disposed below the heated hot stamping plate onto a product.

In order to further improve the effect that the stamping plate 262 has a large impact force on the product, a buffer pad 266 can be connected to the lower end of the stamping plate 262, and the buffer pad 266 can be a rubber pad or a silicone pad.

Further, referring to fig. 1 to fig. 3, the stamping block assembly 260 further includes an adjusting screw 264, one end of the adjusting screw 264 is connected to the partition 261, and the other end is connected to the stamping plate 262.

When the pressure plate is not pressed down, the adjusting screw 264 can adjust the distance between the partition 261 and the stamping plate 262; and then cooperate with the buffering elastic member 263, can also play the effect of adjusting the pressing distance, and can avoid the position deviation from damaging the product when the hot-stamping plate 262 has impact force on the product.

Further, referring to fig. 1 to fig. 3, based on the scheme that the stamping block assembly 260 further includes an adjusting screw 264, the buffering elastic member 263 is a buffering spring, and the buffering spring is sleeved outside the adjusting screw 264.

So set up, can make buffer spring along adjusting screw 264's length direction compression and tensile, and then further guarantee that thermoprint board 262 moves along adjusting screw 264's length direction, avoid appearing great positional deviation.

The utility model also provides a card making device, as shown in fig. 5, the card making device comprises a concave-convex character code printing module 30, a first hot stamping module 10 and a second hot stamping module 20; the embossed character coding module 30 is provided with an in-out bayonet 33, the embossed character coding module 30 comprises a first area 31 and a second area 32 which are opposite, the in-out bayonet 33 is positioned between the first area 31 and the second area 32, and the direction from the first area 31 to the second area 32 is vertical to the direction of the card in and out from the in-out bayonet 33; the first hot stamping module 10 is arranged in front of the embossed character coding module 30, and the first hot stamping module 10 is arranged corresponding to the first area 31 or one side of the first area 31 far away from the second area 32; the second hot stamping module 20 is arranged in front of the embossed character coding module 30, and the second hot stamping module 20 is arranged corresponding to the second area 32 or is arranged corresponding to one side of the second area 32 far away from the first area 31; at least one of the first and second stamping modules 10 and 20 is provided with a stamping pressing mechanism.

The specific structure of the hot stamping pressing mechanism refers to the above embodiments, and as the card manufacturing equipment adopts all technical schemes of all the above embodiments, all beneficial effects brought by the technical schemes of the above embodiments are at least achieved, which is not repeated herein. The embossed-lettered coding module 30 is used for printing embossed characters or embossed characters on the card. The embossing process is typically performed on the card for aesthetic reasons and to prevent counterfeiting. Specifically, the hot stamping process may be a gold stamping process or a silver stamping process. The utility model discloses technical scheme provides an embodiment: one of the first stamping module 10 and the second stamping module 20 may be a gold stamping module, and the other may be a silver stamping module. For example, the first stamping module 10 may be a stamping module, and the second stamping module 20 may be a silver stamping module; or the first stamping module 10 may be a silver stamping module and the second stamping module 20 may be a gold stamping module. Through setting up one of them of first thermoprint module 10 and second thermoprint module 20 into gilt module, another one of them sets up to the gilt module, then the utility model discloses card making equipment among the technical scheme both can satisfy gilt technology, can satisfy the gilt technology again. Of course, in other embodiments, the first stamping module 10 and the second stamping module 20 may perform the same stamping process, for example, if both the first stamping module 10 and the second stamping module 20 are stamping modules, both the first stamping module 10 and the second stamping module 20 can perform the stamping process, so that when one of the stamping modules fails, the other stamping module can perform the stamping process, thereby avoiding delaying the work cycle. Or, the first hot stamping module 10 and the second hot stamping module 20 are both silver stamping modules, and the first hot stamping module 10 and the second hot stamping module 20 can both perform silver stamping processes, so that when one silver stamping module fails, the other silver stamping module can perform the silver stamping process, thereby avoiding delaying the work cycle. The concave-convex character coding module 30 is provided with an in-out bayonet 33, so that the card can enter the concave-convex character coding module 30 through the in-out bayonet 33 to code; or the card can be sent out through the in-out bayonet 33 and then sent into the first stamping module 10 or the second stamping module 20 for the stamping process. In particular, the access bayonet 33 may be rectangular, circular or other shape.

The utility model discloses among the technical scheme, through all locating the place ahead that the embossed letter printed the code module 30 with first thermoprint module 10 and second thermoprint module 20, then the embossed letter printed the code module 30 and see the back out the card through business turn over bayonet 33, the card can directly be sent to first thermoprint module 10 or second thermoprint module 20 to avoid the card to just can reach first thermoprint module 10 or second thermoprint module 20 department through tortuous complicated route. Furthermore, the first hot stamping module 10 is arranged corresponding to the first area 31 or arranged corresponding to one side of the first area 31, which is far away from the second area 32, and the second hot stamping module 20 is arranged corresponding to the second area 32 or arranged corresponding to one side of the second area 32, which is far away from the first area 31, so that the cards sent by the in-and-out bayonet 33 move in the direction away from the second area 32 to reach the first hot stamping module 10, and the cards sent by the in-and-out bayonet 33 move in the direction away from the first area 31 to reach the second hot stamping module 20. So set up, can simplify the route of card to first thermoprint module 10, still can simplify the route of card to second thermoprint module 20, and then can reduce the occupation space of whole system card equipment, and can improve card conveying efficiency, and then realize improving production efficiency's effect. It should be noted that, the utility model discloses the place ahead of code module 30 is beaten to unsmooth word among the technical scheme indicates to be located the direction of the one side that the card place was behind the code module 30 sending out the card to unsmooth word, also passes in and out bayonet 33's play card direction. In addition, since the in-out bayonet 33 is located between the first area 31 and the second area 32, and the direction from the first area 31 to the second area 32 is perpendicular to the in-out bayonet 33, when the first stamping module 10 and the second stamping module 20 are respectively disposed corresponding to the first area 31 and the second area 32, both the first stamping module 10 and the second stamping module 20 are disposed in front of the side of the in-out bayonet 33.

Further, referring to fig. 5 and fig. 6 in combination, in order to facilitate the transportation of the cards between the embossed-embossed character code printing module 30 and the first hot stamping module 10 and between the embossed-embossed character code printing module 30 and the second hot stamping module 20, the card manufacturing apparatus further includes a card transmission mechanism 40, and the card transmission mechanism 40 is disposed between the first hot stamping module 10 and the second hot stamping module 20 and can slide between the first hot stamping module 10 and the second hot stamping module 20.

Through locating card drive mechanism 40 between first thermoprint module 10 and second thermoprint module 20, then can be when card drive mechanism 40 freely conveys the card, not have the influence to the thermoprint technology of first thermoprint module 10 and second thermoprint module 20, and through a card drive mechanism 40, then can both convey the card to first thermoprint module 10, can transmit the card to second thermoprint module 20 again. In addition, the arrangement also enables the installation of each module of the card making equipment to be more compact, and reduces the occupied space of the card making equipment.

Further, referring to fig. 6 and fig. 7, the card driving mechanism 40 includes a clamping assembly 410, a guide rod 420 and a limiting member 430; the card clamping assembly 410 comprises a frame 411 and a clamping part 412, wherein the frame 411 is provided with a through hole 411a, and the clamping part 412 is connected to the frame 411 and used for clamping a card; the guide rod 420 is inserted through the through hole 411a; the frame 411 slides along the guide rod 420 and can convey the card clamping assembly 410 to the in-out bayonet 33; the stopper 430 is connected to an end of the guide rod 420.

Through the arrangement of the guide rod 420, the guide rod 420 penetrates through the through hole 411a of the frame 411 of the clamping assembly 410, and the frame 411 is provided with the clamping portion 412, so that the frame 411 of the clamping assembly 410 can drive the clamping portion 412 to slide on the guide rod 420 at the same time, and further the transmission effect of the clamping assembly 410 is realized. Further, when the frame 411 moves along the guide rod 420, the card clamping assembly 410 can be conveyed to the position of the in-out bayonet 33, so that the effect of conveying the card to the in-out bayonet 33 is achieved, or the effect of conveying the card to the card clamping assembly 410 by the embossed-in code printing module 30 from the in-out bayonet 33 is achieved. By connecting the limiting plate to the end of the guide rod 420, the limiting plate has a limiting effect on the clip assembly 410, and the clip assembly 410 is prevented from being separated from the guide rod 420.

Further, referring to fig. 6 to 8, the card driving mechanism 40 further includes a first driving component, and the first driving component is connected to the frame 411 to drive the frame 411 to slide along the guide rod 420.

Through setting up the first drive assembly who is connected with frame 411, this first drive assembly can drive frame 411 and slide along guide arm 420, then can realize that frame 411 is automatic along the gliding effect of guide arm 420, avoids sliding along guide arm 420 through manual drive frame 411, and then avoids sliding along guide arm 420 through the whole card subassembly 410 of pressing from both sides of manual drive to realize the effect of using manpower sparingly.

Specifically, the first driving assembly may include an air cylinder or a hydraulic cylinder, a piston rod of the air cylinder or the hydraulic cylinder is connected to the frame 411, and an extending direction of the piston rod is consistent with an extending direction of the guide rod 420, so as to achieve an effect that the air cylinder pushes the frame 411 to slide along the guide rod 420. Or the first driving assembly may include a motor, a gear and a rack, for example, the gear is connected to a motor shaft of the motor, the rack is connected to the frame 411 and aligned with the extending direction of the guide rod 420, and the gear is engaged with the rack; when the motor is started, the motor drives the gear to rotate, so that the rack engaged with the gear moves along the extending direction of the guide rod 420, thereby achieving the effect that the rack drives the rack 411 to move along the extending direction of the guide rod 420. It can be understood that when the rack bar drives the rack 411 to slide along the guide rod 420, the sliding direction of the rack bar is related to the rotation direction of the motor shaft of the motor, for example, when the motor shaft of the motor rotates forward, the rack bar drives the rack 411 to move toward one end close to the guide rod 420; when the motor shaft of the motor rotates reversely, the rack bar drives the frame 411 to move toward the other end close to the guide rod 420.

Referring to fig. 6 and fig. 7, the present embodiment further provides a scheme that the first driving assembly drives the frame 411 to slide along the extending direction of the guide rod 420: the first driving assembly comprises a first motor 441, a driving wheel 442, a driven wheel 443 and a transmission belt 444, wherein the driving wheel 442 is connected with the first motor 441; the driven wheels 443 are arranged at intervals with the driving wheel 442, and the direction from the driven wheels 443 to the driving wheel 442 is consistent with the extending direction of the guide rods 420; one end of the conveyor belt 444 is connected with the driving wheel 442, and the other end is connected with the driven wheel 443; the rack 411 is provided to the conveyor 444.

When the first motor 441 is activated, the first motor 441 drives the driving wheel 442 to rotate, and the driving wheel 442 drives the conveyor 444 to move. Since the direction from the driven wheel 443 to the driving wheel 442 is the same as the extending direction of the guide rod 420, and one end of the transmission belt 444 is connected to the driving wheel 442, and the other end is connected to the driven wheel 443, the transmission belt 444 is driven to move along the direction of the guide rod 420 when the driving wheel 442 moves, and thus the transmission belt 444 drives the rack 411 to move along the direction of the guide rod 420 is achieved. In this embodiment, the first driving assembly includes the first motor 441, the driving wheel 442, the driven wheel 443, and the conveyor belt 444, so that the manufacturing requirements on the driving wheel 442, the driven wheel 443, and the conveyor belt 444 of the first driving assembly are not high, and the cost of the first driving assembly is low.

Referring to fig. 6 and 8, in order to ensure that the clamping portion 412 of the card clamping assembly 410 can be adjusted in multiple directions to meet the requirement of the docking with the in-and-out bayonet 33 of the embossed code printing module 30, in this embodiment, the card clamping assembly 410 further includes a second driving assembly 450, and the second driving assembly 450 is disposed on the frame 411 and drives the clamping portion 412 to move along the extending direction of the vertical guide rod 420.

Through setting up second drive assembly 450, and second drive assembly 450 drive clamping part 412 moves along the extending direction of perpendicular guide arm 420, makes clamping part 412 of double-layered card subassembly 410 can be based on the effect of the extending direction motion of above-mentioned along guide arm 420, can also realize the effect of the extending direction motion of perpendicular to guide arm 420, and then can further realize the effect with business turn over bayonet 33 butt joint.

Specifically, when the second driving assembly 450 is disposed on the frame 411, the second driving assembly 450 can achieve the effect of driving the clamping portion to move along the extending direction of the vertical guide rod 420 by referring to the transmission structure of the first driving assembly, which is not described herein again.

As shown in fig. 8, in addition to the solution of driving the frame 411 by referring to the first driving assembly, the present embodiment also provides a solution of driving the movement of the clamping portion 412 by the second driving assembly 450: the second driving assembly 450 includes a second motor 451, a screw rod 452 and a clamping part 412; the screw rod 452 is connected with the second motor 451, and the screw rod 452 is arranged perpendicular to the guide rod 420; the clamping portion 412 includes an installation seat 453 provided on the frame 411, the installation seat 453 has a screw hole 1211, the screw rod 452 is inserted through the screw hole 1211 and is screw-engaged with the screw hole 1211, and the installation seat 453 is provided with the clamping portion 412.

The screw rod 452 is connected with the second motor 451, and then the second motor 451 can drive the screw rod 452 to rotate after being started. Since the mounting seat 453 of the clamping portion 412 is provided with the screw hole 1211 through which the screw passes, when the screw 452 rotates, the mounting seat 453 provided with the clamping portion 412 moves in the extending direction of the screw 452 through the screw hole 1211 engaged with the screw 452. By arranging the screw 452 perpendicular to the guide bar 420, an effect is achieved that the clamping portion 412 moves in a direction perpendicular to the extension direction of the guide bar 420.

The above only is the preferred embodiment of the present invention, not limiting the scope of the present invention, all the equivalent structure changes made by the contents of the specification and the drawings under the inventive concept of the present invention, or the direct/indirect application in other related technical fields are included in the patent protection scope of the present invention.

Claims (14)

1. The utility model provides a thermoprint pushes down mechanism which characterized in that includes:

a cam drive assembly; and

a hold down assembly, the hold down assembly comprising:

the pressing cap is arranged below the cam driving assembly; the cam driving assembly intermittently presses down the press cap;

the fixing plate and the pressing cap are arranged at intervals up and down;

the resetting elastic piece is connected between the pressing cap and the fixing plate;

the hot stamping block assembly is arranged below the pressing cap; and

and one end of the pressing rod is fixedly connected with the pressing cap, and the other end of the pressing rod is fixedly connected with the hot stamping block assembly.

2. The stamp hold-down mechanism of claim 1, wherein the cam drive assembly comprises:

a drive member;

the rotating shaft is in transmission connection with the driving piece, and the driving piece drives the rotating shaft to rotate;

the cam assembly is connected to the rotating shaft and rotates along with the rotating shaft; the pressing cap is arranged below the cam, and the cam assembly intermittently presses down the pressing cap.

3. The stamp hold down mechanism of claim 2, wherein the cam assembly comprises:

one end of the connecting rod is connected to the rotating shaft, and the other end of the connecting rod extends outwards along the radial direction of the rotating shaft; and

the pressing wheel is connected to the other end of the connecting rod, the pressing cap is arranged below the pressing wheel, and the pressing wheel intermittently presses down the pressing cap.

4. The stamping pressing mechanism as claimed in claim 1, wherein the fixing plate is located between the pressing cap and the stamping block assembly, and the pressing rod penetrates through the fixing plate.

5. The stamping and pressing mechanism of claim 4, wherein the pressing assembly further comprises a guide sleeve, the guide sleeve penetrates through the fixing plate, and the pressing rod penetrates through the guide sleeve.

6. The hot stamping pressing mechanism according to claim 5, wherein the return elastic member is a return spring, and the return spring is sleeved outside the pressing rod;

and/or one end of the reset elastic piece is abutted against the pressing cap, and the other end of the reset elastic piece is connected with the guide sleeve;

and/or, the guide sleeve comprises a sleeving part and an installation part, the sleeving part penetrates through the fixing plate, and the pressing rod penetrates through the sleeving part; the installation part is connected to the sleeving part and fixedly connected with the fixing plate.

7. The stamping hold-down mechanism as recited in any one of claims 1 to 6, wherein the stamping block assembly comprises:

the partition plate is arranged below the pressing cap and is fixedly connected with the other end of the pressing rod;

the hot stamping plate is arranged below the partition plate; and

the buffer elastic piece is abutted between the partition plate and the hot stamping plate.

8. A card manufacturing apparatus, comprising:

the concave-convex character coding module is provided with an inlet and outlet bayonet and comprises a first area and a second area which are opposite, the inlet and outlet bayonet is positioned between the first area and the second area, and the direction from the first area to the second area is vertical to the direction of the card inlet and outlet from the inlet and outlet bayonet;

the first thermoprinting module is arranged in front of the embossed character code printing module and corresponds to the first area or one side of the first area, which is far away from the second area; and

the second hot stamping module is arranged in front of the embossed character code printing module and corresponds to the second area or one side of the second area, which is far away from the first area; at least one of the first stamping module and the second stamping module is provided with a stamping pressing mechanism as claimed in any one of claims 1 to 7.

9. The card manufacturing apparatus of claim 8, further comprising a card transmission mechanism disposed between the first stamping module and the second stamping module and slidable between the first stamping module and the second stamping module.

10. The card-making apparatus of claim 9, wherein said card-driving mechanism comprises:

the clamping component comprises a rack and a clamping part, the rack is provided with a through hole, and the clamping part is connected to the rack and used for clamping a card;

the guide rod is arranged between the first hot stamping module and the second hot stamping module and penetrates through the through hole; the rack slides along the guide rod so as to convey the clamping assembly to the in-out bayonet; and

and the limiting part is connected to the end part of the guide rod.

11. The card-handling device of claim 10, wherein the card-moving mechanism further comprises a first drive assembly coupled to the frame for driving the frame to slide along the guide.

12. The card-making apparatus of claim 11, wherein the first drive assembly comprises:

a first motor;

the driving wheel is connected with the first motor;

the driven wheel and the driving wheel are arranged at intervals, and the direction from the driven wheel to the driving wheel is consistent with the extending direction of the guide rod; and

one end of the conveying belt is connected with the driving wheel, and the other end of the conveying belt is connected with the driven wheel; the frame is arranged on the conveyor belt.

13. The card-making apparatus according to any one of claims 10 to 12, wherein the card-clamping assembly further comprises a second driving assembly provided to the housing and driving the clamping portion to move in a direction perpendicular to an extending direction of the guide bar.

14. The card-making apparatus of claim 13, wherein the second drive assembly comprises:

a second motor;

the screw rod is connected with the second motor and is arranged perpendicular to the guide rod; and

the clamping part comprises a mounting seat arranged on the rack, the mounting seat is provided with a threaded hole, and the screw rod penetrates through the threaded hole and is in threaded fit with the threaded hole.

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