TITLE: DRIVE MECHANISM FOR STACKER LINKAGE

FIELD OF THE INVENTION The present invention relates to cassettes for banknote acceptors or payment validators which receive a paper substrate for validation and acceptance. In particular, the invention relates to an improved drive mechanism for moving of a stack or mechanism to displace a paper substrate from a receiving slot into a storage area.

BACKGROUND OF THE INVENTION There are a host of banknote or payment validators which receive a paper substrate and advance the paper substrate through a validation section and if acceptable, move the substrate to a banknote cassette. The banknote cassette includes a stacker mechanism to displace the received banknote into a storage area where the received paper payments are retained in a stacked configuration.

Many of the known banknote or payment cassettes use a scissor type linkage for moving a stacker plate through receiving guides to displace a banknote received in a guide arrangement and move the paper substrate into the storage area to one side of the guide arrangement. An example of the scissor type stacking mechanism is shown in our United States Patent 6,241,240. In this patent, a rotary cam is used to control movement of the stacking mechanism and also control movement of the guides to provide a more efficient stripping of the banknote from the guides. Other arrangements merely use the scissor type stacking arrangement to move through the stationary guides.

Various arrangements have been proposed for efficient movement of the stacker plate through the

guides and into the storage arrangement. These mechanisms require power particularly when the storage arrangement has received a number of banknotes approaching the capacity of the cassette. Typically the storage area includes a pressure plate having a spring bias for biasing the plate towards the guides . The stacker plate when forced through the guides, overcomes the spring bias and moves the stack of banknotes, and on the return stroke of the stacker mechanism, the spring bias returns the stack to a stop position against the guides. Thus, the stacker mechanism must overcome the spring bias, in combination with the inertia and resistance of the stack of banknotes. The power requirements increase as the cassette approaches its capacity. Furthermore, it can be appreciated that the power variation during the stroke of the stacker plate also varies. The initial power of the stacker plate to move from an initial position to one side of the guides and through the guides is only opposed by any resistance offered by the single banknote being stripped from the guides. Once the stacker plate contacts the stack of previously stored banknotes or paper substrates, then additional power is required.

The prior art has used a number of different arrangements such as a gear train for driving of the stacker plate or a rotary cam arrangement as shown in our earlier patent or a push actuator projecting from the rear surface of the cassette. It is desirable to operate the stacker plate with a relatively low power drive to reduce the cost of the banknote acceptor and the cassette. It is also desirable to have a space efficient, relatively narrow drive to maximize the storage compartment. Typically, a banknote validator will have several banknote cassettes to allow withdrawal of a full cassette and insertion of an empty cassette. Therefore, it is desirable to have a cassette that can be manufactured in a cost effective manner.

The present invention provides an improved drive linkage associated with the scissor type mechanism for stacking of a paper substrate received in the guides.

SUMMARY OF THE INVENTION

A cassette for receiving and storing a substrate payment such as a banknote or coupon comprises a housing having a slot opening for longitudinally receiving a substrate payment with the slot opening including within the housing two opposed guides positioned on opposite sides of the housing to receive and support the substrate payment as it passes through the slot into the housing. A displaceable stacker plate is provided in an initial position located to one side of the two guides. The cassette includes storage arrangement to a side of the guides opposite the stacker plate. The storage arrangement receives therein substrate payments displaced from the guide members by the stacker plate to form a stack of substrate payment in the storage arrangement. The drive arrangement for controlled movement of the stacker plate includes a scissor type linkage having a pair of arms connected at an intermediate pivot. The scissor type linkage is connected to the stacker plate and the housing for moving the stacker plate from the initial position through the guides to a substrate payment stripping position within the storage arrangement. The drive arrangement further includes a drive linkage with two bar members pivotally connected to each other. A free end of one of the bar members is pivotally connected to the housing and a free end of the other bar member is pivotally connected to the scissor type linkage. The drive linkage in the initial position of the stacker plate has the bar members forming a substantially overlapped orientation and movable to an extended position forcing the stacker plate to the banknote stripping position.

According to an aspect of the invention the bar member connected to the scissor type linkage is pivotally connected to the intermediate pivot of the pair of arms .

According to a further aspect of the invention the drive linkage includes a bar link member connected to the pivot of the two bar members with a free end of the link member connected to a rotary crank arm.

According to a further aspect of the invention the crank arm and link member form a generally perpendicular angle therebetween when the stacker plate is in the extended position.

In yet a further aspect of the invention the crank arm cooperates with the link member and the scissor linkage to provide a mechanical advantage for a worm drive used to rotate said crank arm and moves said stacker plate through the guides to the substrate payment stripping position.

In yet a further aspect of the invention, the two bar members of the drive linkage are of different lengths with the bar member attached to the housing being greater in length than the bar member attached to the scissor type linkage.

According to a further aspect of the invention, the drive linkage in the initial position of the stacker plate has said two bar members forming an acute angle therebetween at the pivot of said arms and movable to the extended position forming an obtuse angle between the two bar members when the stacker plate is in the substrate payment stripping position.

BRIEF DESCRIPTION OF THE DRAWINGS

Preferred embodiments of the invention are shown in the drawings, wherein:

Figure 1 is a sectional view through a banknote cassette showing the stacking mechanism to one side of a storage area;

Figure 2 is a sectional end view of the banknote cassette; and

Figure 3 is a side view showing the scissor type linkage and drive linkage.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

As shown in Figures 1 and 2, a currency cassette comprises a housing or casing 1 with an access door 2 and lock arrangement 3 at one end of the cassette. The cassette includes a storage chamber 4 and an intake chamber 5 provided with the opposed guide members 6. A double scissor type linkage 7 is positioned within the intake chamber 5 and controls the position of the stacker plate 100.

A drive linkage 102 comprises bar members 9a and 9b with link 9b pivotally secured to the casing and link 9a pivotally secured to the central pivot shaft 8 of the scissor type linkage. Bar members 9a and 9b are pivotally secured to one another at 104.

A connecting link 11 is attached to the pivot location 104 of links 9a and 9b with a free end 105 of the connecting link 11 pivotally attached to a crank arm 106. Crank arm 106 is driven by a gear 12b which is in mesh with the spiral worm gear 12a. The spiral worm gear 12a is driven by a power gear 13. The power gear 13 cooperates with a drive of the banknote acceptor for selective powering of the stacking mechanism. The power for moving the stacker mechanism is provided by a drive

motor that is part of the banknote acceptor as opposed to a motor in the cassette.

The plastic guides 14 can be separately molded guides or can include a common connection base. Each of the guides has opposed walls 15a and 15b which define a payment substrate receiving slot 108 therebetween. As shown in Figure 1, the guide arrangement 14 includes a base portion 110 for providing a stop surface for a payment substrate such as a banknote or paper substrate.

Feed rollers 16 on a common axis 17 cooperate with pressure rollers 18 for receiving a banknote and feeding of a banknote into the guide arrangement 14. Once a banknote has been received within the banknote cassette, the stacking mechanism 120 will strip the banknote from the guide arrangement 14 and add the substrate to the stack of banknotes 18 provided within the storage chamber 4.

Within the storage chamber 4, a pressure plate 19 is engaged by a spring bias 20 to maintain the stack of banknotes against the rear surface of the guide arrangement 14. Other arrangements for maintaining the stack of banknotes can be provided.

Figure 1 shows an initial position of the scissor type linkage and drive linkage whereas Figure 3 shows a substrate payment stripping position of the scissor type linkage caused by the drive linkage being moved the extended position.

In Figure 1 the drive linkage is in a substantially folded orientation and in Figure 3, the drive linkage has moved to the open orientation.

As shown in Figure 2, the stacker plate 25 is controlled by two opposed scissor linkages 7. The

scissor linkages are connected by a common shaft 8. A single drive linkage defined by the bar members 9a and 9b is provided between the two scissor type linkages and is connected to the common shaft 8. A link member 11 is connected to the pivot securement 28 between the bar members 9a and 9b. The opposite end of the link member 11 is pivotally connected to the crank arm 106 and the crank arm is driven by the worm drive 12a in mesh with the gear 12b which is directly connected to the bank arm 106. The drive linkage and link member 11 uses the space between the scissor linkages and does not interfere with movement of the scissor linkages.

As shown in Figure 1, the crank arm 106 rotates from a position generally aligned with the link member 11 to the extended position of Figure 3 where the link member 11 and the crank arm 106 forms an angle closer to perpendicular. During initial movement of the scissor type linkage 7, the amount of power required is relatively low as there is essentially no opposition to movement of the scissor type linkage other than initial resistance to movement by the scissor type linkage itself. The link member 11 pulls on the pivot connection 104 to cause the drive linkage to go from the substantially overlapped condition of Figure 1 to the extended position of Figure 3. The angular relationship of the crank arm, the link member 11, and the drive linkage in the initial position is not favourable from a power consideration, however, little initial power 13 is required.

The links 9a and 9b provide a mechanical advantage in moving the scissor type linkages when movement of these linkages is being opposed by the stack of banknotes and the spring bias 20. Thus, the mechanical advantage of the drive linkage in combination with the mechanical advantage of the crank arm and the link member 11 provide more power at the appropriate position of the scissor

type linkage when the drive linkage is moving to the extended position. Once the drive linkage has caused the scissor type linkage to move to the extended position of Figure 3 , any banknote provided in the banknote receiving slot 108 has been fully stripped and any stack of banknotes has been moved away from the guide members such that the stripped banknote has cleared the walls 15a of the guide members. The worm drive can then be reversed in direction to return the scissor type linkage to the initial position of Figure 1. As can be appreciated, the worm drive provides an accurate mechanism for providing accurate control of the drive linkage.

The double type scissor type linkage comprises a base plate 24 attached to the cassette housing 1. A pusher plate 25 is connected to the base plate 24 in parallel relation by the pair of scissor type linkages 7. These scissor type linkages move the pusher plate 25 toward or away from the base plate 24 in parallel relation thereto. Each scissor type linkage 7 comprises two slide levers 23a and 23b pivotally connected by a common shaft 8. One end of the guide levers 23a is pivotally connected to the base plate 24 by pivot connection 125 supported without longitudinal movement but for hinged movement of the link lever 23a. The other end of the link lever 23a is pivotally connected to the pusher plate 25 for rotation and longitudinal movement by shaft 120 received within an elongated slot 122 of a flange 27 attached to the pusher plate 25.

The other link lever 23b is connected to the base plate 24 for rotation and longitudinal movement by a shaft 124 received within an elongate slot 26 of the base plate 24 attached to the cassette wall. The other end of link 23b is pivotally connected to the pusher plate 25 by a pivot connection 126 supported without longitudinal movement but for hinged movement. The two scissor

linkages are connected by shaft 120, shaft 124 and shaft 8.

The two bar element drive linkage comprises the two bar members 9a and 9b attached by the common pivot location 28. The free end of bar member 9a is pivotally connected to the middle pivot shaft 8 of the scissor type linkages. An opposite end of member 9b is pivotally connected to the base plate 24 by shaft 29. Pivot 28 is linked with a crank arm 10 by the connecting link member 11. Rotation of the crank arm causes the connecting link member to move in a parallel like manner to the base plate 24. The motion of the pivot 28 causes reciprocal motion of the pusher plate 25 as indicated. The crank 10 as rotated by the worm gear transmission comprises the worm gear 12a and the gear 12b.

As shown in Figure 3, the crank arm 106, year 12b, the scissor linkages 7, the drive linkage 9a and 9b, and the link member 11 are all commonly supported on the base plate 24. The base plate is connected to the container wall.

The guide arrangement 14 with the stop wall 21a comprises a lengthwise central window with a width about one third of the widest note to be received. Each pressure roller 18 is pressed against the drive roller 16 by a suitable spring arrangement.

The particular drive linkage preferably has a two bar linkage where the ratio of the length of one bar to the length of the other bar is 1.5 to 1.7. The longer length bar is pivotally connected to the cassette housing to provide the desired mechanical amplification.

This type of structure has been described with respect to a note validator or other banknote or currency handling device that requires stacking of a substrate to

one side of a receiving guide arrangement. These devices are useful in banks, postal facilities, super markets, casinos, or transportation facilities. This particular drive arrangement can also be used for receiving other substrates such as cards, films, paper sheets, or printed substrates.

Although various preferred embodiments of the present invention have been described herein in detail, it will be appreciated by those skilled in the art, that variations may be made thereto without departing from the spirit of the invention or the scope of the appended claims.