CN211106499U - Correction assembly and instant certificate making machine - Google Patents

Abstract

The utility model provides a correction component for card (certificate) making, which comprises a base, wherein the base is provided with a first bearing surface and a second bearing surface which are adjacently arranged and have height difference; an X-direction positioning piece capable of moving relative to the first supporting surface is movably arranged on one side of the first supporting surface; an X-direction floating push plate capable of moving relative to the X-direction positioning piece is arranged at the position opposite to the X-direction positioning piece; and a Y-direction fixed baffle is arranged on the other side of the first supporting surface and adjacent to the X-direction positioning piece, and a Y-direction floating push plate capable of moving relative to the Y-direction fixed baffle is arranged at the position opposite to the Y-direction fixed baffle. The utility model also provides an instant certificate making machine, including the organism, install plastic envelope subassembly and the print module on the organism and can with plastic envelope subassembly and print module complex above-mentioned correction subassembly. The utility model discloses system card machine can once accomplish printing system card, can guarantee card base and print the membrane coincidence completely through revising the subassembly, has effectively guaranteed system card quality.

Description

Correction assembly and instant certificate making machine

Technical Field

The utility model belongs to the technical field of system card equipment, concretely relates to just, system card equipment of revising subassembly and having this revision subassembly of design on system card machine immediately.

Background

With the continuous progress of society, more and more affairs in daily life of human need to use the certificate that has recorded personal information, for example record personal information's card or certificate (such as ID card, pass, student's card, etc.), take a period of time to accomplish from handling to taking the certificate. Moreover, when these cards or certificates are lost, a certain working day is required for reissuing the official certificates. However, since such cards or certificates are closely related to the life of the card (certificate) holder, such as identification cards, they are often used when the user takes a train, a high-speed rail, an airplane, etc., and when the user loses the card or certificate, the user is probably not at the place where the card (certificate) holder is located, which causes much inconvenience.

At present, the manufacture of the existing card or certificate needs to be completed by mutually pressing a card base and a printing film recorded with certain information, and the card base and the printing film are both formed by feeding the card base and the printing film into a pressing component through a pushing mechanism and then performing heat sealing and pressing. However, since the card base and the printing film are small-sized and light-weight members, the peripheries of the card base and the printing film are not completely aligned when the card base and the printing film are pushed to the pressing position, thereby affecting the quality of the manufactured card.

Therefore, it is necessary to solve the above-mentioned drawbacks.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to overcome above-mentioned prior art not enough, at first provide a correction subassembly that is used for making the card machine immediately, the periphery is identical completely when can guaranteeing card base and printing membrane pressfitting.

The utility model provides a correction assembly for making cards or certificates, which comprises a base, wherein the base is provided with a first bearing surface and a second bearing surface, and the first bearing surface and the second bearing surface are adjacently arranged and have a height difference; an X-direction positioning piece capable of moving relative to the first supporting surface is movably arranged at one side end of the first supporting surface; an X-direction floating push plate which can move relative to the X-direction positioning piece is arranged at the position opposite to the X-direction positioning piece; the other side of the first supporting surface is located at the position adjacent to the X-direction positioning piece, a Y-direction fixed baffle is arranged, and a Y-direction floating push plate capable of moving relative to the Y-direction fixed baffle is arranged at the position opposite to the Y-direction fixed baffle.

As the utility model discloses optional project organization, still be equipped with rotating assembly on the base, X direction setting element is a fixed stop, with the rotating assembly rigid coupling makes X direction setting element passes through rotating assembly's drive stretches out when revising suddenly in on the first bearing surface, before revising or after revising lie in under the first bearing surface.

As the utility model discloses optional project organization, still be equipped with the removal subassembly on the base, the X direction setting element is pin or baffle, with the removal subassembly rigid coupling makes the X direction setting element passes through the drive of removal subassembly stretches out when revising suddenly in on the bearing surface, before the revision or after revising lie in under the bearing surface.

As the utility model discloses optional project organization, in on the base, be equipped with the second motor, remove seat and X direction guide rail, the bottom of removing the seat set up in on the X direction guide rail and with X direction guide rail cooperation, the upper end of removing the seat is connected the unsteady push pedal of X direction, be connected with on the second motor output shaft can with remove the seat cooperation, follow in order to drive this removal seat X direction guide rail removes, and then drives the second driving piece that the unsteady push pedal of X direction removed.

As an optional design structure of the utility model, the second driving member is a screw rod, and the movable seat is correspondingly provided with a spiral groove which can be matched with the screw rod; or the second driving piece is a gear, and a rack structure which can be matched with the gear is correspondingly arranged on the movable seat.

As the utility model discloses optional project organization, in on the base, be equipped with the third motor, be connected with the eccentric wheel on the third motor output shaft, the unsteady push pedal of Y direction with the eccentric wheel cooperation just passes through the rotation of eccentric wheel drives this unsteady push pedal of Y direction and is reciprocating motion.

As an optional design structure of the utility model, the base is provided with a push rod seat, and a push rod passes through the push rod seat; the Y-direction floating push plate comprises a front push plate used for correcting the card base and the printing film and a rear push plate used for being matched with the eccentric wheel, and two ends of the push rod are respectively connected with the front push plate and the rear push plate, so that the push rod seat is arranged between the front push plate and the rear push plate.

Furthermore, an elastic part is sleeved on the push rod and is positioned between the rear push plate and the push rod seat.

As an optional design structure of the present invention, a first position sensor is disposed on the first supporting surface, and a second position sensor is disposed on the second supporting surface; the base is further provided with a controller and a plurality of proximity switches, wherein the controller can control the X-direction positioning piece, the X-direction floating push plate and the Y-direction floating push plate to act.

The utility model also provides an instant certificate making machine, including organism, controller and install in plastic envelope subassembly and printing element on the organism, still be provided with the aforesaid on the organism correction subassembly, printing element borders on the Y direction fixed stop who corrects the subassembly, the plastic envelope subassembly borders on the X direction setting element of correction subassembly, the correction subassembly pass through the controller with the instant certificate making process is accomplished in the cooperation of plastic envelope subassembly and printing element.

The utility model discloses a revise the subassembly, when being used for the preparation of card (card), through set up the unsteady push pedal of X direction setting element, mobilizable X direction, Y direction fixed stop and Y direction push pedal on the base, can make card base and print the membrane coincide after align, coincide completely before the pressfitting all around, moreover, the utility model discloses revise the subassembly and make card base and print the membrane at X direction and Y direction one side fixed location, the opposite side adopts unsteady propelling movement correction mode, can make the card base and print the thrust that receives when the membrane coincide is revised less, can avoid card base and print the membrane damage.

The instant certificate making machine with the correction assembly can complete printing and certificate making at one time, can be handled on site, can take certificates instantly, is convenient and fast, and simultaneously reliably ensures the quality and effect of certificates (cards) made by instant certificate making.

Drawings

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

FIG. 1 is a schematic diagram of a structure of a correction assembly according to an embodiment of the present invention before correction;

FIG. 2 is a diagram illustrating a state of the embodiment of FIG. 1 in a modification;

FIG. 3 is a top view of FIG. 2;

FIG. 4 is a schematic diagram of another embodiment of the correction assembly according to the present invention before correction;

FIG. 5 is a side view of FIG. 4;

FIG. 6 is a diagram illustrating a state of the embodiment of FIG. 4 in a modification;

FIG. 7 is a front view of the instant certificate making machine according to the embodiment of the present invention;

fig. 8 is a top view of the instant certificate making machine according to the present invention.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more clearly understood, the present invention is further described in detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.

It will be understood that when an element is referred to as being "secured to" or "disposed on" another element, it can be directly on the other element or intervening elements may also be present. When an element is referred to as being "connected to" another element, it can be directly connected to the other element or intervening elements may also be present.

It should be further noted that the terms "X direction", "Y direction", "up", "down", "upper end", "lower end", "one side", "the other side", "one end" or "the other end" in the embodiments of the present invention are only relative terms or are referred to the normal using state of the product, or are referred to the position shown in the drawings, and are only for convenience of describing the present invention and simplifying the description, but do not indicate or imply that the device or element referred to must have a specific orientation, be constructed in a specific orientation, and be operated, and thus should not be considered as limiting.

Furthermore, the terms "first," "second," "third," "fourth," and the like are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicit to a number of indicated technical features. Thus, features defined as "first", "second", "third", "fourth" may explicitly or implicitly include one or more of the features. In the description of the present invention, "a plurality" means two or more unless specifically limited otherwise.

As a specific embodiment of the correction assembly 1 of the present invention, referring to fig. 1-6, the correction assembly 1 is mainly used for the alignment correction before the mutual pressing of the card base and the printing film during the card (certificate) making, and includes a base 100, the base 100 is the basic component of the correction assembly 1 and can be used as a carrier, so that each element constituting the correction assembly 1 is installed on the base 100, and meanwhile, the installation of the correction assembly 1 on the card (certificate) making machine is facilitated. The base 100 has a first supporting surface 101, and the first supporting surface 101 is horizontally arranged and used for placing a printing film before correction, and the printing film printed with information by a printer can be sent to the first supporting surface 101 by a pushing mechanism. In the adjacent position of the first bearing surface 101, there is a second bearing surface 102, and the second bearing surface 102 is also horizontally arranged for placing the card base. After the printed film with the information is fed onto the first supporting surface 101, the card base is pushed onto the first supporting surface 101 and falls to cover the printed film, so as to prepare for subsequent pressing. The second supporting surface 102 is higher than the first supporting surface 101, and has a certain height difference, which is generally the thickness of the card base, so that the card base can smoothly cover the printing film when being pushed to the first supporting surface 101. A clearance groove is arranged between the second supporting surface 102 and the first supporting surface 101, so that the falling of the card base is facilitated. As shown in fig. 1 to 6, an X direction and a Y direction are defined by using a first supporting surface 101 and a second supporting surface 102 as references, an X-direction positioning member 103 is disposed at one side end of the first supporting surface 101, and the X-direction positioning member 103 is movably disposed to move up and down with respect to the first supporting surface 101. The X-direction positioning element 103 is provided with a blocking surface perpendicular to the first supporting surface 101, the X-direction positioning element 103 protrudes above the first supporting surface 101 during correction and is used for positioning the card base and the printing film at one side in the X direction, and the X-direction positioning element 103 before or after correction is positioned below the first supporting surface 101, so that the corrected card base and the printing film can be conveniently sent out. An X-direction floating push plate 106 is disposed in parallel at a position opposite to the X-direction positioning member 103, the X-direction floating push plate 106 protrudes above the second supporting surface 102 and can move along the X-direction relative to the X-direction positioning member 103 to push the substrate on the second supporting surface 102, so that the substrate covers the printing film on the first supporting surface 101 and cooperates with the X-direction positioning member 103 after the substrate covers the printing film, so that the substrate and the printing film can be corrected in the X-direction. Meanwhile, a Y-direction fixing baffle 109 is disposed at the other side end of the first supporting surface 101 and adjacent to the X-direction positioning element 103, and the Y-direction fixing baffle 109 also has a blocking surface perpendicular to the first supporting surface 101. A Y-direction floating push plate 110 is provided in parallel on the first support surface 101 at a position opposite to the Y-direction fixing shutter 109, the Y-direction floating push plate 110 being movable in the Y-direction for cooperating with the Y-direction fixing shutter 109 to allow the correction of the card base and the print film in the Y-direction. Thus, through the X-direction positioning piece 103 and the Y-direction fixed baffle 109 which are movably arranged on the first supporting surface 101, and simultaneously, the X-direction floating push plate 106 and the Y-direction floating push plate 110 are respectively arranged in parallel at the positions corresponding to the X-direction positioning piece 103 and the Y-direction fixed baffle 109, the card base and the printing film which are superposed on the first supporting surface 101 can be reliably aligned before lamination under the moving and pushing of the X-direction floating push plate 106 and the Y-direction floating push plate 110, and the four peripheries of the card base and the printing film are completely aligned and completely superposed, so that the card base and the printing film can be reliably aligned after being covered on the printing film, and the micro-dislocation phenomenon caused by possible movement during lamination can be avoided, thereby effectively ensuring the uniformity and complete superposition of the peripheries of the products during card certification and improving the quality of the certified products. Further, because the card base is little, the quality is light with printing the membrane size, the utility model discloses revise the subassembly and make the card base and print the membrane at X direction and Y direction one side fixed position, the opposite side adopts the propelling movement correction mode that floats, and the thrust that receives when can making the card base and printing the membrane coincide and revising is very little, can avoid the card base and print the membrane damage.

Referring to fig. 1-3, in an embodiment of the correction assembly 1 of the present invention, the X-direction positioning element 103 can be movably disposed through a rotating element, the rotating element is fixed on the base 100 and connected to the X-direction positioning element 103, the X-direction positioning element 103 can be a bar-shaped baffle 103A having a long end and a short end, the bar-shaped baffle 103A is located above 101 of the first supporting surface before the printing film is fed into 101 of the first supporting surface, and is used for positioning the printing film and the card base at one end of the X-direction; before or after the correction, the card base and the print film are sent to the next process even if the highest point of the strip-shaped baffle plate 103A is lower than 101 of the first supporting surface. In this embodiment, the rotating assembly includes a rotating member 114 and a first motor 124, the rotating member 114 is connected to the output shaft of the first motor, and is also connected to the bar-shaped baffle 103A. Before the printing film is sent to the first supporting surface 101, the first motor is started to rotate, the rotating piece 114 can be driven to rotate by 90 degrees under the control of the controller, the rotating piece 114 simultaneously drives the strip-shaped baffle plate 103A to rotate, so that the long end of the strip-shaped baffle plate 103A is vertically arranged above the first supporting surface 101 during correction and protrudes above the first supporting surface 101, and the printing film is positioned at one end of the card base and the printing film in the X direction when the printing film is arranged on the first supporting surface 101 and the card base and the printing film are corrected; after correction, the rotating member 114 is driven to rotate in the reverse direction by 90 degrees under the control of the controller, and the rotating member 114 simultaneously drives the strip-shaped baffle plate 103A to rotate in the reverse direction, at this time, the short end of the strip-shaped baffle plate 103A is on the upper side and lower than the first supporting surface 101. This allows the corrected card substrate and printed film to pass over the first support surface 101 and be fed to a subsequent laminating process. It can be understood that, in the structure of the embodiment, the X-direction positioning element 103 is completed by combining the strip-shaped baffle 103A and the rotating assembly, and the structure of the X-direction positioning element 103 is not limited to the structure of the strip-shaped baffle 103A shown in fig. 1-3, and may also be a sector member or other structures; the rotation assembly is not limited to the transmission mode of the rotation motor and the rotation member 114, and it is within the protection scope of the present application as long as the rotation combination mode can be realized to enable the X-direction positioning member 103 to be movably located above or below the first supporting surface 101 as required, and further description is omitted here.

Referring to fig. 4-6, in another embodiment of the correction assembly 1 of the present invention, the X-direction positioning element 103 may also be movably disposed through a moving assembly, the moving assembly is fixed on the base 100 and connected to the X-direction positioning element 103, the X-direction positioning element 103 may be a stop lever or a baffle, the embodiment is specifically illustrated as two parallel stop levers 103B, the highest point of the two stop levers 103B is located on the first supporting surface 101 during correction, and the two stop levers are used for positioning the card base and the printing film at one end in the X-direction; the highest point before or after the correction is completed is located below the first supporting surface 101, so that the corrected card base and the printing film are sent out to the next pressing procedure. In this embodiment, the moving assembly includes a first motor 124, a lifting seat 121 and a first driving member 123, the stop lever 103B is vertically fixed on the lifting seat 121, the first driving member 123 may be a gear, and is connected to the first motor 124 and can be driven by the first motor 124 to rotate, a rack is vertically processed on the lifting seat 121 and can be engaged with the gear, when the first motor 124 rotates, the gear is driven to rotate, when the rack arranged on the lifting seat 121 is engaged with the gear, the rack can move up and down relative to the first supporting surface 101, and further the two stop levers 103B are driven to move up and down, so that the highest point of the two stop levers 103B is located above the first supporting surface 101 during correction, and the highest point is located below the first supporting surface 101 before or after correction. Further, in this embodiment, the base 100 is further provided with a guide seat 122, the guide seat 122 is provided with two through holes, and the two blocking rods 103B are inserted into the two through holes and can move in the two through holes, that is, the guide seat 122 can guide the up-and-down movement of the two blocking rods 103B. It is understood that in the structure of the present embodiment, the X-direction positioning member 103 is completed by combining the two blocking levers 103B and the moving assembly, and the structure of the two blocking levers 103B is not limited to the structure shown in fig. 4 to 6, and may be a baffle member or the like; the moving assembly is not limited to the engagement manner of the gear in the first driving element 123 and the rack in the lifting seat 121, and may also be a transmission manner such as a lead screw, a worm gear, an air cylinder, etc., and it is a protection scope of the present application as long as the moving combination manner can be implemented to enable the X-direction positioning element 103 to be movably located above or below the first supporting surface 101 as required, and is not described herein again.

Referring to fig. 1-4 and 6, in the embodiment of the correction assembly 1 of the present invention, two through grooves 120 are formed on the first supporting surface 101 and the second supporting surface 102 along the X direction; a second motor 104, a movable seat 105 and an X-direction guide rail 108 are arranged on the base 100, and the X-direction guide rail 108 is fixed on the base 100 and is positioned at a corresponding position below the second supporting surface 102; the bottom end of the moving seat 105 is arranged on the X-direction guide rail 108 and is matched with the X-direction guide rail 108, the upper end of the moving seat 105 is connected with the two X-direction floating push plates 106, and the two X-direction floating push plates 106 are vertically arranged in the two through grooves 120 and protrude above the first supporting surface 101 and the second supporting surface 102; the second motor 104 is located at a side end of the base 100, an output shaft of the second motor 104 is connected with a second driving member 107, the second driving member 107 is capable of cooperating with the movable base 105, and under the driving of the second motor 104, the movable base 105 is driven to move along the X-direction guide rail 108 by the rotation of the second driving member 107, so as to drive the X-direction floating push plate 106 to move along the X-direction guide rail 108 in the two through grooves 120. Therefore, through the cooperation among the second motor 104, the second driving member 107, the movable base 105 and the X-direction guide rail 108, the X-direction floating push plate 106 fixed at the upper end of the movable base 105 can be displaced in the X-direction under the control of the controller, and after the card base placed on the second supporting surface 102 is pushed to the first supporting surface 1-01 to be covered on the printing film, the overlapped card base and printing film are further corrected. In the structural design of the above embodiment, the first supporting surface 101 and the second supporting surface 102 are provided with two through grooves, which is beneficial to the arrangement of the floating push plate 106 in the X direction and the guiding of the movement, and is also beneficial to the layout between the floating push plate 106 in the X direction and the moving seat 105, so that the overall structural space is reduced, meanwhile, two-point positioning can be performed on the other side end of the superposed card base and the other side end of the printing film, and the card base and the printing film are prevented from inclining when being pushed.

The utility model discloses in the optional embodiment of correction subassembly 1, second driving piece 107 can be like the lead screw shown in fig. 1, fig. 2, remove and correspond on the seat 105 and be equipped with the helicla flute, when the lead screw was inserted and is located on removing the seat 105, can cooperate with the helicla flute on removing the seat 105, it is rotatory through second motor 104, drive the lead screw rotatory and remove the seat 105 on the helicla flute mesh and make and remove seat 105 and remove along X direction guide rail 108 to drive the unsteady push pedal 106 of X direction and remove in two logical grooves 120. It is understood that the second driving member 107 can also be a gear, and the moving seat 105 is correspondingly provided with a rack structure, and is engaged with the gear, and the second motor 104 rotates to drive the gear to rotate and engage with the rack structure on the moving seat 105, so as to move the moving seat 105 along the X-direction guide rail 108, so as to drive the X-direction floating push plate 106 to move in the two through grooves. Of course, the second driving member 107 can also be other members, such as elements like an air cylinder, as long as it can be matched with the structure correspondingly arranged on the movable seat 105 to drive the movable seat 105 to move, which all belong to the protection scope of the present invention, and are not described herein again.

Referring to fig. 1-6, in the embodiment of the correction assembly 1 of the present invention, a third motor 113 is further disposed on the base 100, the third motor 113 is vertically disposed and fixed by a motor base 112, an output shaft of the third motor is connected with an eccentric wheel 111, and the eccentric wheel 111 can vertically rotate around an axis line thereof. The base 100 is further provided with a push rod seat 116, the push rod seat 116 is fixed on the base 100 and is provided with two through holes, and the two push rods 117 pass through the two through holes of the push rod seat 116 and can move in the through holes. In order to improve the wear resistance, a copper sleeve may be provided between the through hole and the push rod 117. Referring to fig. 1-6 again, in the illustrated embodiment of the present invention, the Y-direction floating push plate 110 is formed by combining a front push plate 1101 and a rear push plate 1102 at intervals, wherein the front push plate 1101 is located at the side end of the first supporting surface 101 and is arranged opposite to the Y-direction fixing baffle 109 for pushing the card base and the printing film to realize the Y-direction correction function; the rear push plate 1102 is located on the motor base 112 and used for being matched with the eccentric wheel 111. The two ends of the push rod 117, which penetrate through the push rod seat 116, are respectively connected with the front push plate 1101 and the rear push plate 1102, so that the push rod seat 116 is arranged between the front push plate 1101 and the rear push plate 1102, and the front push plate 1101 and the rear push plate 1102 are arranged on the push rod seat 116 in a floating manner through the push rod 117. When the third motor 113 is started, the eccentric wheel 111 is driven to rotate, and then the rear push plate 1102 is driven to horizontally move along the Y direction, because the push rod 117 is connected with the front push plate 1101 and the rear push plate 1102, the push rod 117 can be driven by the rear push plate 1102 to horizontally move in the through hole of the push rod seat 116, and further the front push plate 1101 is driven to horizontally move together, that is, the movement of the rear push plate 1102 can drive the front push plate 1101 to horizontally move along the Y direction, so that the Y-direction floating push plate 110 is driven by the rotation of the eccentric wheel 111 to horizontally reciprocate relative to the Y-direction fixed baffle 109 in the Y direction, so as to form floating positioning of the overlapped card base and the overlapped printing film at one end in the Y direction, and then the card base and the overlapped printing film arranged on the first supporting surface 101 can be corrected. The push rod seat 116 is provided to support the push rod 117, and to guide the movement of the Y-direction floating push plate 110, so as to avoid the shift during pushing.

Further, an elastic member 115 is sleeved on the two push rods 117, the elastic member 115 may be a compression spring and is located between the push rod seat 116 and the rear push plate 1102, and the front push plate 1101 may be kept fixed in the corrected position under the action of the compression spring. After the correction is completed, the Y-direction floating push plate 110 can be automatically reset under the action of the elastic member 115.

With further reference to fig. 3, in an embodiment of the correction assembly 1 of the present invention, a first position sensor 119 is disposed on the first supporting surface 101, and a second position sensor 118 is disposed on the second supporting surface 102. The first position sensor 119 and the second position sensor 118 are used for respectively sensing whether the printing film and the card base placed on the first supporting surface 101 and the second supporting surface 102 are in place or not, and providing signals for a controller arranged on the certification machine to control the actions of each mechanism of the correction assembly 1. In the illustrated embodiment, the second position sensor 118 may be two as shown in fig. 1-3, or one as shown in fig. 4 and 6. The base 100 is also provided with a controller and a plurality of proximity switches (not shown) for controlling the movement and displacement of the X-direction positioner 103, the X-direction floating push plate 106, and the Y-direction floating push plate 110. In addition, each motor is provided with a trigger switch, and the controller controls each motor to start and stop to drive the driving piece to move and realize accurate positioning of each position.

Referring to fig. 7 and 8, the present invention further provides an instant certificate making machine, which includes a machine body 3 and a controller (not shown), wherein the machine body 3 is provided with a plastic package assembly 2 and a printing assembly 4, and the correction assembly 1 is provided, the printing assembly 4 is arranged beside the correction assembly 1 along the Y direction, and is adjacent to the Y direction fixing baffle 109 of the correction assembly 1, so that a printing film printed with information by the printing assembly 4 can be sent to the first supporting surface 101; the plastic package assembly 2 is arranged beside the correction assembly 1 along the X direction, is adjacent to the X-direction positioning part 103 of the correction assembly 1, is positioned on the first supporting surface 101, and is directly fed into the plastic package assembly 2 to complete the pressing process through the X-direction floating push plate 106 after the card base and the printing film which are overlapped and corrected are positioned on the first supporting surface 101. The correction assembly 1, the plastic package assembly 2 and the printing assembly 4 are matched through a controller to complete the whole certificate making process.

The utility model provides an instant system card machine can make printing, system card once accomplish, can handle on the spot, takes the card immediately, and very convenient and fast especially has brought the convenience for those people that need to use the certificate urgently (like handling of interim ID card etc.). And simultaneously, because the utility model discloses the design has the correction subassembly on the instant system card machine, card base and printing membrane coincidence completely when can guaranteeing instant system card machine system card, have effectively guaranteed system card quality and effect.

It should be noted that the correction assembly provided by the present application can be used not only in an instant certificate making machine, but also in other certificate making devices or terminals, and is within the scope of the present application as long as the correction between the card base and the printing film can be completed.

The utility model discloses make certificate machine embodiment working process immediately:

when the power is turned on, the controller sends out a signal to make the rotating assembly or the moving assembly located at the side end of the first supporting surface 101 move, so as to drive the X-direction positioning element 103 to rotate or move, so that the X-direction positioning element 103 rotates or moves upwards and protrudes above the first supporting surface 101, and the two X-direction floating push plates 106 move to the rear end position (initial state) of the second supporting surface 102.

The blank print film is placed in the printer with the card substrate on the second support surface 102 at position I. After the controller confirms the printing information, a printing signal is sent out, the printer is started, the personal information is printed on the printing film, and after the printing of the printing film is finished, the personal information automatically falls on the first supporting surface 101. After the card base is in place, the first position sensor 119 sends a signal for sensing the card base and a signal for detecting that the printing film is in place by the first position sensor 119 to the controller.

After the controller receives the signal, the second motor 104 is started, the moving seat 105 is driven to move along the guide rail 108 in the X direction through the screw 107, the two X-direction floating push plates 106 are driven to move in the two through grooves 120 in the X direction, the card base arranged on the second supporting surface 102 is pushed into the first supporting surface 101 from the second supporting surface 102 and covers the printing film, after the two are overlapped, the second motor 104 rotates reversely, and the X-direction floating push plates 106 stop after retreating for a certain distance. Then, the controller sends a signal again to start the third motor 113 to drive the eccentric wheel 111 to rotate, and the rotation of the eccentric wheel 111 pushes the rear push plate 1102 to move forward, so that the push rod 117 drives the front push plate 1101 to move forward at the same time. With the rotation of the eccentric wheel 111, the front push plate 1101 is continuously moved in a reciprocating manner, so that the Y-direction floating push plate 110 corrects the overlapped card base and the printed film in the Y direction.

After the Y-direction correction is completed, the third motor 113 stops rotating, and the front push plate 1101 is kept stationary at the correction position by the elastic member 115. At this time, the second motor 104 is restarted, the screw 107 continues to rotate, and the X-direction floating push plate 106 is driven to repeatedly push in the X direction, so as to correct the stacked card base and the printed film in the X direction.

After the correction in the X direction and the Y direction is completed, the controller controls the rotating assembly or the moving assembly to drive the X-direction positioning member 103 to rotate or move in the opposite direction, so that the X-direction positioning member 103 moves or rotates downward. When the X-direction positioning element 103 moves downward or rotates to a predetermined position, the first motor 124 stops, and the rotating or moving element returns to the original position. At this time, the second motor 104 drives the screw 107 to continue rotating, and drives the two X-direction floating push plates 106 to continue moving forward, so as to push the corrected card base and the print film into the plastic package assembly 4. During the movement of the floating push plate 106 in the X direction, the floating push plate 110 in the Y direction is kept stationary by the elastic member 115 to guide the movement of the floating push plate 106 in the X direction. After the card base and the printing film are sent into the plastic package assembly 2, the card base and the printing film are pressed and sent out in a hot pressing mode, the certificate making process is completed, and the next working cycle is started.

The above description is only exemplary of the present invention and should not be construed as limiting the present invention, and any modification, equivalent replacement or improvement made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (10)

1. A correction assembly for use in the manufacture of cards or certificates, comprising a base, wherein the base is provided with a first support surface and a second support surface, the first support surface and the second support surface being arranged in abutment and having a height difference; an X-direction positioning piece capable of moving relative to the first supporting surface is movably arranged at one side end of the first supporting surface; an X-direction floating push plate which can move relative to the X-direction positioning piece is arranged at the position opposite to the X-direction positioning piece; the other side of the first supporting surface is located at the position adjacent to the X-direction positioning piece, a Y-direction fixed baffle is arranged, and a Y-direction floating push plate capable of moving relative to the Y-direction fixed baffle is arranged at the position opposite to the Y-direction fixed baffle.

2. The corrector assembly of claim 1, wherein the base further comprises a rotating assembly, and the X-directional positioning member is a fixed stop plate fixedly connected to the rotating assembly, so that the X-directional positioning member is driven by the rotating assembly to protrude above the first supporting surface during correction, and to be located below the first supporting surface before or after correction.

3. The correcting assembly of claim 1, wherein the base is further provided with a moving assembly, and the X-direction positioning element is a stop lever or a baffle plate fixedly connected to the moving assembly, so that the X-direction positioning element is driven by the moving assembly to protrude above the supporting surface during correction, and to be located below the supporting surface before or after correction.

4. The correction assembly as claimed in claim 1, wherein a second motor, a movable base and an X-direction guide rail are disposed on the base, a bottom end of the movable base is disposed on the X-direction guide rail and is engaged with the X-direction guide rail, an upper end of the movable base is connected to the X-direction floating push plate, and a second driving member is connected to an output shaft of the second motor and is engaged with the movable base to drive the movable base to move along the X-direction guide rail and further drive the X-direction floating push plate to move.

5. The corrector assembly of claim 4, wherein said second driving member is a screw rod, and said movable base is correspondingly provided with a spiral groove capable of cooperating with said screw rod; or the second driving piece is a gear, and a rack structure which can be matched with the gear is correspondingly arranged on the movable seat.

6. The corrector assembly of any one of claims 1 to 5, wherein a third motor is provided on the base, an eccentric is connected to an output shaft of the third motor, and the Y-direction floating push plate is engaged with the eccentric and is driven to reciprocate by rotation of the eccentric.

7. The corrector assembly of claim 6, wherein the base is provided with a push rod seat, and a push rod passes through the push rod seat; the Y-direction floating push plate comprises a front push plate used for correcting the card base and the printing film and a rear push plate used for being matched with the eccentric wheel, and two ends of the push rod are respectively connected with the front push plate and the rear push plate, so that the push rod seat is arranged between the front push plate and the rear push plate.

8. The corrector assembly of claim 7, wherein an elastic member is further sleeved on the push rod, the elastic member being positioned between the rear push plate and the push rod seat.

9. The corrector assembly of claim 1, wherein a first position sensor is provided on said first support surface and a second position sensor is provided on said second support surface; the base is further provided with a controller and a plurality of proximity switches, wherein the controller can control the X-direction positioning piece, the X-direction floating push plate and the Y-direction floating push plate to act.

10. An instant certificate making machine, which comprises a machine body, a controller, a plastic package assembly and a printing assembly, wherein the plastic package assembly and the printing assembly are installed on the machine body, the machine body is further provided with a correction assembly according to any one of claims 1 to 9, the printing assembly is adjacent to a Y-direction fixed baffle of the correction assembly, the plastic package assembly is adjacent to an X-direction positioning piece of the correction assembly, and the correction assembly is matched with the plastic package assembly and the printing assembly through the controller to complete an instant certificate making process.

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