Card de-bowing mechanism

Abstract

A substrate de-bowing mechanism, system and method are described. The mechanism can include a substrate support, one or more stationary contact members, and one or more dynamic or movable contact members that are adapted to contact the substrate and bend the substrate in a desired direction to reduce or eliminate bowing of the substrate. The mechanism is controlled by a CPU or other controller that can adjust the de-bow parameters of the de-bowing mechanism based on input settings that can be dynamic and/or static settings. The mechanism can be used to de-bow a variety of substrates including plastic cards, passports, and passport pages.

Claims

1. A substrate processing system, comprising: a substrate transport mechanism that transports a substrate through the substrate processing system in a substrate transport direction along a substrate travel path; a lamination mechanism disposed along the substrate travel path, the lamination mechanism is configured to apply a laminate to the substrate; a substrate de-bowing mechanism disposed along the substrate travel path, the substrate de-bowing mechanism has an axial footprint, measured between a pair of movable card contact members at a first home position and that are used to de-bow the substrate, the pair of movable card contact members are disposed on a first side of the substrate travel path when at the first home position and are rotatably movable to a second home position on a second side of the substrate travel path; and the substrate de-bowing mechanism further includes a stationary card contact member disposed on the second side of the substrate travel path midway along the axial footprint, the stationary card contact member is not movable toward or away from the substrate travel path.

2. The substrate processing system of claim 1, wherein the substrate is a plastic card having a nominal length of 3.370 inches, and the axial footprint is less than about 80 percent of the nominal length.

3. The substrate processing system of claim 1, wherein the system is a desktop card processing machine or a central card issuance system.

4. The substrate processing system of claim 3, wherein the system is a desktop card processing machine.

5. The substrate processing system of claim 1, wherein the system further includes a print mechanism, and the substrate de-bowing mechanism is downstream of the lamination mechanism.

Description

DRAWINGS

(1) FIGS. 1A and 1B illustrate an example of a substrate processing system in the form of a desktop card processing machine.

(2) FIGS. 2A, 2B and 2C are a top view, a perspective view showing convex bowing, and a perspective view showing concave bowing, respectively, of a plastic card substrate.

(3) FIG. 2D is a perspective view of a plastic card substrate with two dimensional bowing.

(4) FIG. 3 is a perspective view of one embodiment of a substrate de-bowing mechanism described herein.

(5) FIG. 4 is a perspective view of the de-bowing mechanism of FIG. 3 de-bowing a card downward.

(6) FIG. 5 is another perspective of the de-bowing mechanism of FIG. 3 that is de-bowing a card upward.

(7) FIG. 6 is a perspective view of another embodiment of a substrate de-bowing mechanism described herein.

(8) FIG. 7 is a perspective view of still another embodiment of a substrate de-bowing mechanism described herein.

(9) FIG. 8 is a perspective view of still another embodiment of a substrate de-bowing mechanism described herein.

(10) FIG. 9 is a perspective view of still another embodiment of a substrate de-bowing mechanism described herein.

(11) FIG. 10 is a perspective view of still another embodiment of a substrate de-bowing mechanism described herein.

(12) FIG. 11 is a top view of the de-bowing mechanism and a plastic card substrate demonstrating the axial footprint of the de-bowing mechanism.

(13) FIG. 12 illustrates an embodiment of a de-bowing mechanism without a card transport mechanism.

(14) FIG. 13 illustrates an embodiment of a de-bowing mechanism that includes a single rotating substrate contact member.

DETAILED DESCRIPTION

(15) Substrate de-bowing mechanisms as described in further detail below can include a substrate support, one or more stationary contact members, and one or more dynamic or movable contact members that are adapted to contact the substrate and bend the substrate in a desired direction to reduce or eliminate bowing of the substrate.

(16) As used herein, the term stationary as in stationary contact member or the like, or fixed as in fixed contact member or the like, means that the contact member does not move in order to cause de-bowing. However, the stationary or fixed contact member could rotate about its own axis or otherwise move in a manner that is incidental to the bending of the substrate.

(17) In an embodiment, the de-bowing mechanism can further include a substrate transport mechanism that facilitates movement of a substrate into and out of the substrate support.

(18) In an embodiment, the dynamic contact member(s) can be an end contact member(s) adapted to contact a portion(s) of the substrate at or near the end(s) of the substrate.

(19) In an embodiment, the dynamic contact members are rotatable about respective rotation axes, which allows the dynamic contact members to be set in different home positions (i.e. above or below the substrate travel path) in order to facilitate contact with either a first surface or a second surface of the substrate. This allows the same mechanism to de-bow substrates that have either a concave bowing or convex bowing. The rotational aspect of the dynamic contact members can also reduce the footprint of the de-bowing mechanism so that the footprint has a length that is less than the length of the substrate.

(20) The de-bowing mechanism can be controlled by either an independent controller or by part of a system controller. The motion profile and other aspects of the de-bowing mechanism can be pre-programmed, modified based on dynamic and/or static settings, or modified based on data provided by detection means that detect the direction and/or amount of bowing of a substrate.

(21) With reference initially to FIGS. 1A and 1B, a substrate processing system 10 that incorporates a substrate de-bowing mechanism 12 is illustrated. The system 10 can be any system that handles substrates 14 that are bowed or become bowed during processing in the system 10. The substrate 14 can be any substrate that is or becomes bowed in the system 10 and for which one wishes to eliminate or reduce the bow.

(22) To facilitate the explanation, the system 10 will be described as a personalized document processing system, in particular a desktop card processing machine, and the substrate 14 will be described as a personalized document such as a plastic card including but not limited to financial (e.g. credit and debit) cards, drivers' licenses, national identification cards, gift cards, loyalty cards, employee badges, and other plastic cards which bear personalized data unique to the card holder and/or which bear other card or document information, as well as to passports or passport pages. Therefore, the de-bowing mechanism 12 will also be described as being a personalized document de-bowing mechanism. However, it is to be realized that the system and substrate are not limited to personalized documents or to desktop card processing machines.

(23) In FIGS. 1A and 1B, the desktop card processing machine includes an input 16 that can hold a plurality of plastic cards 14 to be processed and that mechanically feeds the cards one-by-one into the machine for processing. In the illustrated example, the cards are initially fed into a printer 18 that prints on the cards. After printing, the cards are mechanically transported to a lamination mechanism 20 which applies a laminate(s) to one or both surfaces of the cards. The cards are then transported to the de-bowing mechanism 12 which removes or reduces any bowing that occurs in the card resulting from the lamination process. In some embodiments, the cards, after the de-bowing process, satisfy ISO 7810 Section 8.1.11, which is hereby incorporated by reference herein in its entirety.

(24) After de-bowing, the card can be fed into one or more further processing mechanisms, for example an indenting mechanism 22 which performs indenting on the cards and the cards are then discharged into an output 24. Alternatively, the cards can be transported directly from the de-bowing mechanism into an output.

(25) FIGS. 2A-C illustrate an example of the plastic card 14. In this example, the card 14 is generally rectangular in construction with a first or upper surface 26 and a second or lower surface 28. The terms upper and lower as used herein are relative to the orientation of the card depicted in FIGS. 2A-C. In the examples described herein, it will be assumed that the cards 14 travel through the desktop card processing machine in the flat or planar orientation illustrated in FIG. 2A with the first surface 26 facing upward and the second surface 28 facing downward, and in a direction of the longitudinal axis of the card between a leading edge 30 and a trailing edge 32. In one embodiment, the card can have nominal ID-1 card dimensions of 2.1253.370 inches. The cards can be made of plastic material(s) or made of any material(s) susceptible to bowing. However, the cards can have other card shapes, sizes and materials.

(26) As a result of the processing that occurs on the card 14, particularly the lamination process, the card 14 can become bowed. The bowing can occur in an upward direction (e.g. convex bowing) as indicated in FIG. 2B or the bowing can occur in a downward direction (e.g. concave bowing) as indicated FIG. 2C, depending upon factors such as which surface 26, 28 has been laminated.

(27) Two-dimensional bowing can also occur on the card 14. For example, with reference to FIG. 2D, the card 14 is shown as being convexly bowed generally between the leading edge 30 and the trailing edge 32. The card 14 is also convexly bowed at location 29 between side edges of the card 14.

(28) In addition, the cards 14 travel into, through and from the de-bowing mechanism 12 in a substrate transport direction X-X from the leading edge 30 to the trailing edge 32 along a substrate travel path which is generally a plane defined by the card. In an embodiment, the transport direction X-X is one-way so that the cards travel in a single direction. In another embodiment, the transport direction X-X is two-way so that the cards can travel in a forward and reverse direction in the de-bowing mechanism 12, as well as optionally in other processing mechanisms of the system 10.

(29) Turning now to FIG. 3, one embodiment of the de-bowing mechanism 12 will now be described. The mechanism 12 includes a substrate support 40 that is configured to support a card during a de-bowing operation. The support 40 has the transport direction X-X therethrough and a substrate travel path such that in the orientation illustrated in FIG. 3, the card is oriented generally horizontally with the first surface 26 facing upward and the second surface 28 facing downward.

(30) The support 40 can have any configuration that is suitable for supporting the card during de-bowing. For example, the support 40 can comprise a generally rectangular plate 42 having a front or substrate input end 44 and a rear or substrate output end 46. A pair of flanges 48a, 48b extend upwardly from sides of the plate 42 and extend substantially from the front end 44 to the rear end 46. Bars 50a, 50b extend between the flanges 48a, 48b to help stiffen the plate 42.

(31) A drive roller 52 is rotatably mounted on the plate 42. An idler roller 54 is also mounted on the plate 42 opposite of and facing the roller 52. A nip 56 is defined between the roller 52, 54 for receiving the card therebetween. Therefore, the substrate travel path extends through the nip 56. The rollers 52, 54 are fixed relative to one another such that the rollers 52, 54 are not movable toward each other. In other embodiments, the drive roller 52 does not necessarily need to be positioned opposite the idle roller 54.

(32) The drive roller 52 is in driving engagement with a drive motor (not shown) for driving the roller 52. The roller 52 is used to drive the card into and from the mechanism 12. The drive motor can be any type of motor known in the art that is suitable for driving the roller 52, and the drive motor can drive the roller in one direction or the motor can be reversible to drive the roller in both directions. However, other card transport mechanisms could be used, for example a transport mechanism that moves the card by contacting the edges of the card as described in U.S. patent application Ser. No. 13/773,753, filed on Feb. 22, 2013, which is incorporated herein by reference in its entirety.

(33) The idler roller 54 is rotatably mounted on a shaft 58 that extends between the flanges 48a, 48b. The idler roller 54 rolls along the surface of the card opposite the surface engaged by the drive roller 52.

(34) In the illustrated example, the drive roller 52 forms a first intermediate, stationary substrate contact member and the idler roller 54 forms a second intermediate, stationary substrate contact member. When a card is received in the nip 56, the drive roller 52 contacts the first side surface 26 of the card and the idler roller 54 contacts the second side surface 28 of the card. However, other designs are possible, including designs where a single intermediate substrate contact member is utilized.

(35) The mechanism 12 also includes a first end substrate contact member 60 and a second end substrate contact member 62 mounted on the substrate support 40. The substrate contact members 60, 62 are designed to engage one of the surfaces 26, 28 of the card to bend the card about either the drive roller 52 (i.e. when bending the card downwardly) or the idler roller 54 (i.e. when bending the card upwardly).

(36) Taking the transport direction X-X as the axial direction, the first end substrate contact member 60 is disposed on a first axial side of the first and second intermediate substrate contact members 52, 54 and the second end substrate contact member 62 is disposed on a second axial side of the first and second intermediate substrate contact members 52, 54. In other words, the rollers 53, 54 are located between the first and second end substrate contact members 60, 62. The first and second end substrate contact members 60, 62 are each rotatable about respective rotation axes 64, 66 that are perpendicular to the substrate transport direction X-X and that are located axially between the first and second end substrate contact members 60, 62.

(37) In the illustrated example, the substrate contact members 60, 62 are generally similar in construction to one another, but they are rotatable in opposite directions to one another during a bending operation. In particular, each of the contact members 60, 62 includes a single contact member in the form of a rotatable roller 68 having a first end 70, a second end 72, and a length L between the first end and the second end. Each roller 68 is rotatable about its longitudinal axis Y-Y perpendicular to the card transport direction X-X.

(38) The first end 70 has a generally frustoconical shape that extends or downwardly tapers toward the second end 72. Likewise, the second end 72 has a frustoconical shape that extends or tapers downwardly toward the first end 70. A section 74 of constant dimension interconnects the small diameter ends of the frustoconical ends 70, 72. The length L of each roller 68 is equal to or greater than a height of the substrate to be de-bowed. For example, with reference to FIG. 2A, the height of the card substrate is defined as the straight-line distance between the side edges 31, 33.

(39) With continued reference to FIG. 3, the first ends 70 of the rollers 68 are each connected to drive gears 76, 78 that are rotatably mounted on the support 40 for rotation about the axes 64, 66. In addition, shafts 80, 82 are connected to the gears 66, 68 and are supported on the support 40. The shafts 80, 82 extend across the support and through the flange 48a where the ends of the shafts are connected to arms 84, 86 that are fixed to the second ends 72 of the rollers 68. As should be apparent, when the gears 76, 78 rotate, the rotation is transmitted to both ends of the rollers 68 to rotate the rollers 68 about the axes 64, 66.

(40) In the embodiment in FIG. 3, the gears 76, 78 are meshed with each other, and one of the gears, for example the gear 78, is engaged with a drive gear 90 which is driven by a gear 92 and a gear 94. The gear 88 is driven by a drive mechanism, such as a reversible electric motor (not shown). When the gear 88 is rotated, the gears 76, 78 are rotated in opposite directions so that the rollers 68 are moved either away from each other (i.e. in a downward direction) or mover toward each other (i.e. in an upward direction), depending upon the direction of rotation of the gear 94.

(41) In order to be able to bend the substrate upwardly or downwardly, the first and second end substrate contact members 60, 62 are rotatable between a first home position (shown in FIG. 11) where the first and second end substrate contact members are positioned on one side of the travel path (i.e. above the nip 56) to permit the first and second end substrate contact members to contact the first side surface 26 of the substrate, and a second home position (not shown) where the first and second end substrate contact members 60, 62 are positioned on an opposite side of the substrate travel path (i.e. below the nip 56) to permit the first and second end substrate contact members to contact the second side surface 28 of the substrate.

(42) Further, the construction of the mechanism 12 results in a reduced axial footprint (i.e. the axial size) of the mechanism 12. For example, with reference to FIG. 11, an axial distance D1 between the first and second end card contact members 60, 62 when the members 60, 62 are at the first home position is equal to or less than the length D2 of the substrate to be de-bowed. In one embodiment, the axial distance D1 or footprint can be less than approximately 80 percent of the length D2 of the substrate, for example a plastic card. In another embodiment, the axial distance D1 or footprint can be less than approximately 75 percent of the length D2 of the substrate. In another embodiment, the axial distance D1 or footprint can be less than approximately 65 percent of the length D2 of the substrate.

(43) With reference to FIG. 6, an embodiment of a de-bowing mechanism 12a is illustrated that is similar to the de-bowing mechanism 12 with like elements referenced using the same reference numerals. One way in that the embodiment in FIG. 6 differs is that instead of a single continuous contact member as used in FIG. 3, the de-bowing mechanism 12a includes a first end substrate contact member 60a and the second end substrate contact member 62a that each has first and second contact portions 70a, 72a that are not directly connected to one another. Each contact portion 70a has a first end fixed to the gear 76, 78, and a second free end 74a. Likewise, each contact portion 72a has a first end fixed to the arms 84, 86 and a second free end 74a. The first and second contact portions are frustoconical in shape and extend (i.e. taper) toward one another. In addition, the distance L from the first end of the first contact portion to the first end of the second contact portion is equal to or greater than a height of the substrate to be de-bowed.

(44) In addition, in the de-bowing mechanism 12a, the first and second contact portions 70a, 72a are not rotatable about their longitudinal axes. Instead, the portions 70a, 72 are non-rotatably fixed to their support structures (i.e. the gears and the arms). However, in one embodiment, the contact portions 70a, 72a could rotate about their longitudinal axes

(45) FIG. 7 illustrates an embodiment of a de-bowing mechanism 12b that uses separate drive mechanisms to drive the end contact members of FIG. 6 (or FIG. 3). In particular, the drive gears 76b, 78b are separate from each other, and each is in driving engagement with a gear 94a, 94b. Each gear 94a, 94b is driven by its own drive motor which permits separate control of the de-bowing performed by each end contact member. Therefore, each drive train can be separately driven and used to de-bow either the whole substrate or partial substrate.

(46) FIG. 8 illustrates an embodiment of a de-bowing mechanism 12c that uses a solenoid drive mechanism to drive the end contact members of FIG. 6 (or FIG. 3). In particular, the drive gears 76c, 78c are engaged with each other as in FIG. 3. In addition, a solenoid 100 is provided that has an output shaft 102 that is engaged in a suitable manner with one of the gears 76c, 78c, for example the gear 78c, to convert linear motion of the shaft 102 into rotational motion of the gears 76c, 78c. In the illustrated example, the gear 78c includes a tab 104 projecting therefrom that is engaged with the shaft 102 such that when the shaft extends linearly, the gear 78c is rotated which simultaneously rotates the gear 76c. In another embodiment, the solenoid 100 is engaged with the gear 76c, or separate solenoids are engaged with each gear 76c, 78c similar to the separate drive mechanisms in FIG. 7. A biasing spring is provided at any suitable location in the drive train to bias the arms and the gears 76c, 78c back to the home position.

(47) Means can also be provided for tracking the amount of rotational movement of the end substrate contact members to ensure a proper amount of de-bowing movement (i.e. depth of de-bowing). Any means for tracking movement to determine the depth of de-bowing, either of the mechanical parts or of the substrate itself, can be used. For example, the tracking means can be a photocell, a camera, a rotary encoder, or any other form of displacement sensor.

(48) For example, one embodiment of a rotational movement tracking means is illustrated in FIG. 9 in the form of a photocell mechanism 110 adjacent to the end of one of the arms, for example the arm 86, that detects the amount of movement of the arm. In the illustrated embodiment, the gears 76, 78 are connected to one another so that the arm 84 moves the same amount as the arm 86. Therefore, it is only necessary to track the movement of one of the arms 84, 86. However, if separate drive mechanisms are used as in FIG. 7, the movement of both of the arms can be separately tracked using separate photocell mechanisms or other mechanisms.

(49) Another embodiment of a rotational movement tracking means is illustrated in FIG. 10 in the form of a rotary encoder mechanism 120 connected to one of the arms, for example the arm 86. If separate drive mechanisms are used as in FIG. 7, a rotary encoder mechanism can be used on each arm.

(50) FIG. 4 illustrates another example of detecting depth of de-bowing by using a sensor 140, for example a photocell, a camera, or other form of displacement sensor, that is positioned to detect the amount of movement of the substrate itself.

(51) In one embodiment, the de-bowing can occur without any sensor feedback.

(52) FIG. 12 illustrates another example of a de-bowing mechanism 12d that does not include a card transport mechanism. In this embodiment, the rollers 52, 54 described above are removed. Instead, the substrate is introduced into and removed from the de-bowing mechanism 12d using transport mechanisms of the processing machine located upstream and downstream of the de-bowing mechanism 12d. Alternatively, in one embodiment, the substrate is manually introduced into and removed from the de-bowing mechanism 12d. During a de-bowing operation, the substrate can bend around a central portion 43 of the plate 42 which forms a stationary contact member during downward de-bowing, or around the bars 50a, 50b during an upward de-bowing. The construction of the de-bowing mechanism 12d is otherwise as described above.

(53) FIG. 13 illustrates another example of a de-bowing mechanism 12e that includes a single rotating substrate contact member, for example the contact member 60. In this embodiment, the substrate support is suitably configured to support the end of the substrate opposite the contact member 60 to counter the bending force of the contact member. Any means for retaining the opposite end of the substrate can be used. In the example illustrated in FIG. 13, the substrate support includes one or more retainers 150 that hold opposite corners of the substrate while the substrate is de-bowed by movement of the contact member 60.

(54) To aid in the de-bowing process, it may be useful to heat the substrate immediately prior to or during de-bowing so that the substrate has an elevated temperature during de-bowing. When heating of the substrate is desired, a means for heating the substrate can be provided. The heating means can take any form that is suitable for increasing the temperature of the substrate, and can be positioned at any location(s) for heating the substrate immediately prior to and/or during de-bowing. For example, in one embodiment, the drive roller 52 can be heated in order to transfer heat into the substrate. In another embodiment, the idler roller 54 is heated, or both of the rollers 52, 54 can be heated.

(55) In another embodiment, illustrated diagrammatically in FIG. 4, a heated air discharge 130 can be mounted on the mechanism 12 to blow heated air onto the substrate 14 while the substrate is in the mechanism 12 to increase the temperature of the substrate. The heated air can be provided by a suitable fan mechanism mounted elsewhere in the system. In an alternative embodiment, the air discharge 130 can be mounted immediately upstream of the mechanism 12 to increase the temperature of the substrate immediately prior to the substrate being input into the mechanism 12 to be de-bowed.

(56) In addition, it is sometimes useful to know both the direction of bowing (i.e. convex bow or concave bow) in the substrate as well as the amount of bowing. Knowing the amount of bowing allows one to adjust the de-bowing process to achieve the appropriate amount of de-bowing, and knowing the direction of bowing allows one to appropriately set the correct home positions of the end substrate contact members. Therefore, in an embodiment, a means for detecting bowing in the substrate can be provided. The means for detecting bowing can be located upstream of the de-bowing mechanism 12 to detect the direction and amount of bowing prior to the substrate entering the mechanism 12 and/or on the mechanism 12 to detect the direction and amount of bowing while the substrate is on the mechanism 12. If the means for detecting bowing is on the mechanism, it may be necessary to temporarily transport the substrate out of the mechanism once the direction of bowing is detected to permit change in the home position of the end substrate contact members.

(57) The means for detecting bowing can take any form suitable for detecting the direction and/or amount of bowing in the substrate. In one example, the means for detecting bowing comprises a camera that captures one or more images of the substrate. The image(s) is then processed automatically in image processing software or manually by visual inspection to determine the direction and/or amount of bowing in the substrate.

(58) The de-bow mechanism 12 can be controlled by either an independent controller or by a controller of the system 10. In one embodiment, the operation of the de-bowing mechanism 12 follows a pre-programed sequence. This mode of operation is useful when parameters such as the direction of bowing, the amount of bowing, and the type of substrate being de-bowed are generally constant from one substrate to the next.

(59) In another embodiment, the operation of the de-bowing mechanism 12 can be modified based on dynamic or static settings. The dynamic settings can be defined based on, among others, the following examples:

(60) 1. Defined/Calculated in the controller(s) based on, for example, logic, sensors, hardware, camera, or the like.

(61) 2. User Input that is defined as part of system setup, for example via a graphical user interface, a communication interface, system initializations, or the like.

(62) 3. Sent dynamically by an external interface as part of job (i.e. substrate) processing (single or batch substrate processing).

(63) 4. Defined by interfaces like RFID, ICODE, smart card chips, SD cards, encrypted storage devices or the like on supplies like a laminate supply, and/or on the substrate and/or on supply packaging.

(64) 5. Defined by a computed heuristic based on testing, experience, theory and the like.

(65) The settings can include the following exemplary settings, among others:

(66) 1. Motion profile(s) for the drive motor(s) for the end substrate contact members.

(67) 2. A PID/PID profile for the drive motor(s)

(68) 3. A PID/PID profile for the substrate heater (if used).

(69) 4. Delays, dwell, displacement, frequencies, and the like for the drive motor(s).

(70) 5. Substrate materials including substrate types and laminate types, for example all/any card types, all/any card laminates, and all/any passport materials.

(71) 6. Ambient atmospheric conditions such as temperature, altitude, pressure, humidity, and the like.

(72) 7. Single sided lamination or dual sided lamination.

(73) 8. Number of de-bow cycles, including partial and/or full cycles and any combinations of de-bow cycles.

(74) In one embodiment, the variable or dynamic settings can include the following exemplary settings, among others. In one embodiment, some or all of the variable settings can be automatically read via RFID from a supply or supply packaging and used to automatically adjust the operation, and/or some or all are input by a user.

(75) Exemplary Variable Settings Front Side Laminate type or presence (Patch, Topcoat, or the like) Front Side Laminate application temperature Back Side Laminate type or presence (Patch, Topcoat, or the like) Back Side Laminate application temperature Card or substrate Type (PVC, Polycarbonate, Passport booklet, or the like) User Setting (More de-bow vs. Less de-bow) Frontside lamination pressure Rearside lamination pressure Frontside lamination speed Rearside lamination speed Card temperature (if measured by a sensor) Initial card bow (if measured by a sensor) Lamination order (for example, front side of card first vs. back side first) Heated roller type (aluminum roller; rubber coated roller; and the like) Heated roller wattage Partial patch/topcoat; full patch/topcoat on front and/or back

(76) In one embodiment, the static settings can include the following exemplary static settings, among others.

(77) Exemplary Static Settings Motor profile/acceleration curve Displacement: how far the card is de-bowed which impacts the number of motor steps Dwell time: how long the card is de-bowed before the mechanism lets go Single impact or multi-impact. De-bowing direction: does the card need to be de-bowed up or down

(78) In another embodiment, the temperature of the substrate can be measured prior to de-bowing and the setting dictating the amount of de-bowing is determined based on the detected substrate temperature.

(79) In one exemplary operation of the mechanism 12, a method of de-bowing a substrate includes inserting the substrate to be de-bowed into the nip 56 between the first intermediate substrate contact member 52 and the second intermediate substrate contact member 54 so that the first intermediate substrate contact member contacts the first side surface 26 of the substrate and the second intermediate substrate contact member contacts the second side surface 28 of the substrate approximate a center of the substrate. The first end substrate contact member 60 and the second end substrate contact member 62 are then engaged with the first or second side surface of the substrate adjacent to the ends of the substrate depending upon when the substrate is to be de-bowed upwardly or downwardly. The first end substrate contact member and the second end substrate contact member are then rotated in opposite directions to cause the substrate to bend about either the first or second intermediate substrate contact member depending upon the direction of de-bowing.

(80) In a specific exemplary operation of the mechanism 12, a substrate enters the mechanism. The motor(s) accelerates using a setting profile (discussed above) and drives the arms to a de-bow depth (discussed above). The depth can be measured by the photocell 110, the encoder 120, or by detecting deflection of the card itself. The motor(s) holds its position for a de-bow dwell time (discussed above), after which the motor(s) drives the arms back to their home position and the substrate exits.

(81) Prior to inserting the substrate into the mechanism, the first end substrate contact member 60 and the second end substrate contact member 62 are brought to the appropriate home position depending upon the direction of de-bowing needed. For example, in the case of concave bowing 14b (see FIG. 2), the substrate needs to be de-bowed downwardly. Therefore, in this situation, the end substrate contact members 60, 62 are initially brought to the first home position so to bend the substrate downward about the drive roller 52 as shown in FIG. 4. In the case of convex bowing 14a (see FIG. 2), the substrate needs to be de-bowed upwardly. Therefore, in this situation, the end substrate contact members 60, 62 are initially brought to the second home position so to bend the substrate upward about the idler roller 54 as shown in FIG. 5

(82) The direction of bowing and/or the amount of bowing can also be detected, such as prior to inserting the substrate into the mechanism and/or during the de-bowing process to determine if the bow has been removed and if not to implement another de-bowing cycle. Also, to aid in de-bowing the substrate, the substrate can be heated prior to de-bowing

(83) The embodiments disclosed in this application are to be considered in all respects as illustrative and not limitative. The scope of the claimed invention is indicated by any appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are intended to be embraced therein.