Banknote processing

Abstract

Banknote processing equipment is disclosed, which comprises a chamber having an open end for insertion of a bag into the chamber and an extractor adapted to establish a lower ambient pressure between the chamber and the bag to that within the bag to cause the bag to expand into an open configuration during a banknote filling operation, whereby the banknote processing equipment can deposit banknotes in the bag.

Claims

1. A method for depositing one or more banknotes into a bag, the method comprising: receiving the bag in a chamber, the chamber having an open end disposed opposite a base end; expanding the bag into an open configuration during a filling operation by reducing an air pressure within the chamber around the bag; clamping a free end of the bag against the chamber during the filling operation by rotating one or more flaps into a first position; receiving the one or more banknotes into the bag through the free end of the bag during the filling operation; releasing the free end of the bag from the chamber following the filling operation by rotating the one or more flaps from the first position into a second position; and sealing the bag in a sealing operation after release of the free end of the bag from the chamber; wherein the one or more flaps are automatically rotated into the second position in connection with a movement of one or more sealing arms, the one or more sealing arms configured to engage the bag in connection with the sealing operation.

2. The method of claim 1, wherein the sealing operation includes closing the free end of the bag through welding.

3. The method of claim 1, wherein the bag is expanded using an extractor.

4. The method of claim 3, further comprising: controlling an operation speed of the extractor.

5. The method of claim 1, wherein the chamber forms part of at least one of a deposit safe, a cash dispenser, a note sorter, or a note counter.

6. The method of claim 1, wherein the one or more banknotes are received into the bag under gravity.

7. The method of claim 1, wherein the open configuration of the bag includes a rectangular cross section and a flat base.

Description

(1) Embodiment of the invention will now be described with reference to the accompanying drawings, in which:

(2) FIGS. 1 to 3 show plan, perspective and cross-sectional views of a first embodiment of the invention; and

(3) FIGS. 4 to 6 show plan, cross-sectional and side views of a second embodiment of the invention.

(4) In the device shown in FIGS. 1 to 3, a chamber 1 is made from two sheet metal U-shaped parts 2a, 2b joined together along their longitudinal edges. The top edges of the chamber 1 are folded over to form flanges 3a-3d.

(5) Six side rails 4a-4f are mounted to the chamber 1. The six side rails 4a-4f are affixed to the chamber 1 by way of tabs on the side rails 4a-4f that are passed through corresponding apertures in the chamber 1 and twisted to prevent them passing back through the apertures. The tabs on each of side rails 4c, 4f pass through apertures in both of the U-shaped parts 2a, 2b and thereby hold the two U-shaped parts 2a, 2b together.

(6) Towards a lower end of the chamber three support rods 5a-5c pass through the chamber 1. An extractor fan 6 is mounted to the underside of the chamber 1.

(7) To use the device, a bag 7 (see FIG. 3) is inserted through the open end of the chamber 1, that is the end of the chamber 1 adjacent the flanges 3a-3d. The free end (i.e. not the closed end) of the bag 7 is stretched over the flanges 3a-3d to hold it in place and the closed end of the bag 7 is allowed to rest on the support rods 5a-5c.

(8) The extractor fan 6 is then started, drawing air through the chamber 1 from the open end adjacent the flanges 3a-3d to the opposed, base end where the extractor fan 6 is mounted and out through the fan 6 in the direction of the arrows shown in FIG. 3. This reduces the air pressure within the chamber 1 around the bag 7.

(9) As a result of the reduction in pressure within the chamber 1 the bag 7 expands outwardly (as indicated by the arrows shown in FIG. 3) towards the side walls of the chamber 1. Thus, the bag 7 adopts an open configuration in which banknotes can be deposited simply by releasing them above the free end of the bag 7 such that they fall under gravity to rest on the closed end of the bag 7. The support rods 5a-5c provide support to prevent the bag 7 being drawn into the extractor fan 6 and for the banknotes deposited in the bag 7.

(10) Once the bag is in the open configuration, the speed of extractor fan 6 may be reduced. This is achieved by a speed controller (not shown) which controls the speed of extractor fan 6 in response to a speed control signal. The speed control signal may be issued by a master controller in an item of banknote processing equipment (for example, banknote sorting or counting equipment) to which the device shown in FIGS. 1 to 3 is fitted. The speed of the extractor fan 6 may be reduced to a dead stop. This speed-reduction feature reduces the noise of operation and power consumption of the device.

(11) The side rails 4a-4f prevent the bag 7 from conforming entirely to the <shape of the interior of the chamber 1 when it expands into the open configuration. Instead, the bag expands against the side rails 4a-4f and the side walls of the chamber 1 between the side rails 4a-4f. This results in air channels of approximately triangular cross-section being formed between the bag 7, the side walls of the chamber 1 and the side rails 4a-f. Thus, the passage of air through the chamber 1 and extractor fan 6 is maintained even when the bag 7 is in the open configuration, which prevents the extractor fan 6 being overworked and potentially overheating.

(12) The device forms part of an item of banknote processing equipment, such as a banknote deposit safe, a cash dispenser, a banknote sorter or banknote counter. In some cases, more than one device may be fitted to the same piece of equipment. It is then possible to use a single fan coupled to each device to reduce the pressure in each chamber simultaneously or, with a suitable system of baffles, selectively in each chamber.

(13) FIGS. 4 and 5 show plan and side cross-sectional views of a second embodiment of the invention. Generally, the structure of the second embodiment is the same as that of the first embodiment described above with reference to FIGS. 1 to 3. However, there are some important additions as will become apparent.

(14) A chamber 10 has an open end for receiving bags and an extractor fan 11 mounted on the underside of the chamber 10. The extractor fan 11 is able to draw air through the open end, through the chamber 10 and out through the base end (opposite to the open end) as shown by the arrows. Three support rods 12a-12c pass through the chamber 10 near its base end. The arrangement so far is identical to that of the first embodiment, the extractor fan 11 and support rods 12a-12c performing the same functions as the equivalent extractor fan 6 and support rods 5a-5c of the first embodiment. These functions have already been described above. However, the second embodiment also comprises a sealing mechanism and a clamping arrangement.

(15) The clamping arrangement comprises a pair of flaps 13a, 13b, each disposed on a long edge of the open end of the chamber 10. The flaps 13a, 13b are rotatable around respective hinges 14a, 14b running along the long edges of the chamber 10. They are able to move between the positions indicated as A and C (in dashed lines), and can be held at the interim position indicated as B (also in dashed lines) by detents.

(16) When the flaps 13a, 13b are in position C, an operator is able to load a bag 15 into chamber 10. In position A, the flaps 13a, 13b clamp the bag 15 to the chamber 10 by engaging the inner surfaces of bag 15 and applying a clamping force to the bag 15 pushing it against the side walls of the chamber. This not only holds the bag 15 in the correct configuration to allow deposition of banknotes in the bag 15, it also provides a well-defined opening into the bag 15 so that banknotes do not collide with the open end of the bag 15 as they are deposited.

(17) As best seen in FIG. 4, the flaps 13a, 13b have chamfered corners 16a-16d on their leading edges. This prevents the corners catching on the bag 15 as the flaps 13a, 13b are moved into position A to engage the bag 15. An alternative design for the flaps 13a, 13b could have curved leading edges.

(18) The flaps 13a, 13b occupy effectively the full width of the chamber to force the bag 15 open as much as possible along its entire width, thereby providing as wide an opening as possible. They are designed to have a width that is slightly less than the width of the bag 15 when open. Typically, the width of the flaps 13a, 13b will be around 3 mm to 5 mm less than the width of the bag 15 when open.

(19) The sealing mechanism comprises a pair of sealing arms 17a, 17b mounted to the chamber 10 on pivots 18a, 18b. Each sealing arm 17a, 17b is provided with a stub axle 19a, 19b to enable a force to be applied to the sealing arms 17a, 17b to draw them together and pull them apart. At the top of each sealing arm 17a, 17b is a sealing element 20a, 20b. The sealing elements 20a, 20b apply heat to the bag 15 when the sealing arms 17a, 17b are drawn together so that the sealing elements 20a, 20b engage the bag 15. This welds the sides of the bag 15 together, thereby closing the open free end.

(20) The operation of this embodiment is similar to the first embodiment. The flaps 13a, 13b are moved manually to position C by an operator. The bag 15 is then inserted through the open end of the chamber 10. The extractor fan 11 is then started, drawing air through the chamber 10 from the open end to the base end where the extractor fan 11 is mounted and out through the fan 11 in the direction of the arrows shown in FIG. 5. This reduces the air pressure within the chamber 10 around the bag 15.

(21) As a result of the reduction in pressure within the chamber 10, the bag 15 expands rapidly outwardly towards the side walls of the chamber 10. The bag 15 conforms approximately to the internal volume of the chamber 10, the side walls of which constrain further expansion of the bag 15. Thus, the bag 15 adopts the open configuration shown in FIG. 5. Even with a normal non-gusseted bag, the chamber 10 can cause it to open into a well-formed shape with a rectangular cross-section and a flat bottom suitable for receiving banknotes.

(22) The flaps are then manually rotated to position C to clamp the free end of the bag 15 to the chamber 10 and to present a neatly-formed opening of the appropriate size to receive banknotes.

(23) Banknotes can then be deposited simply by releasing them above the clamped free end of the bag 15 such that they fall under gravity to rest on the closed end of the bag 15. The support rods 12a-12c provide support to prevent the bag 15 being drawn into the extractor fan 11 and for the banknotes deposited in the bag 15.

(24) Once the bag is in the open configuration, the speed of extractor fan 11 may be reduced. This is achieved by a speed controller (not shown) which controls the speed of extractor fan 11 in response to a speed control signal. The speed control signal may be issued by a master controller in an item of banknote processing equipment (for example, banknote sorting or counting equipment) to which the chamber 10 is fitted. The speed of the extractor fan 11 may be reduced to a dead, stop. This speed-reduction feature reduces the noise of operation and power consumption.

(25) Although not shown in this embodiment, the chamber could be fitted with side rails similar to the side rails 4a-4f already described above with reference to the first embodiment. These side rails have the same effect as already described, namely providing air channels of approximately triangular cross-section being formed between the bag 15, the side walls of the chamber 10 and the side rails. Thus, the passage of air through the chamber 10 and extractor fan 11 is maintained even when the bag 15 is in the open configuration, which prevents the extractor fan 11 being overworked and potentially overheating.

(26) When the desired quantity of banknotes has been deposited in bag 15 by the banknote processing equipment to which chamber 10 is fitted, the flaps 13a, 13b are moved to position B and the sealing arms 17a, 17b are moved so that the sealing elements 20a, 20b engage the bag 15. The sealing elements 20a, 20b are then energised to weld the open free end of the bag 15.

(27) The movement of the flaps 13a, 13b to position B occurs automatically as the sealing arms 17a, 17b are moved so that the sealing elements 20a, 20b engage the bag 15. This is carried out by a mechanism shown in FIG. 6. Movement of the sealing arms 17a, 17b is caused by operation of a motor 21, coupled via a pulley 22 and belt 23 to a main cam 24. There main cam 24 has a “racetrack” groove in which the stub axles 19a, 19b of the sealing arms 17a, 17b are located. Thus, as the motor 21 rotates the main cam 24 through ninety degrees from the position shown in FIG. 6, the sealing arms 17a, 17b are brought together by the groove 25 acting on the stub axles 19a, 19b. A further ninety degree rotation of the main cam 24 causes the sealing arms 17a, 17b to be pulled apart, again by the groove 25 acting on the stub axles 19a, 19b.

(28) A pair of secondary cams 26a, 26b is provided on the periphery of main cam 24. A roller 27 bears on the peripheral surface of main cam 24 and follows its profile. When the secondary cams 26a, 26b are underneath it (as shown in FIG. 6), the roller 27 lifts the T-shaped member 28 against springs 29a, 29b. The T-shaped member is coupled to bellcranks 30a, 30b, and in this position these are moved out of the way so that the flap-operating levers 31a, 31b can occupy the position indicated as A in FIG. 6 (in which the flaps 13a, 13b are also in their position A).

(29) However, when a sealing command is issued by a controller, the motor 21 is caused to rotate the main cam 24 through ninety degrees from the position it is shown to occupy in FIG. 6. This brings the sealing arms 17a, 17b together for the sealing operation as already described. It also allows the springs 29a, 29b to urge the T-shaped member 28 downwardly as the secondary cam 26a moves out of the way of roller 27. The T-shaped member thus pulls the bellcranks 30a, 30b inwardly so that rollers 32a, 32b (rotatably mounted on bellcranks 30a, 30b) push the flap-operating levers 31a, 31b (and hence flaps 13a, 13b) to position B. A pair of springs 33a, 33b and balls 34a, 34b form detents together with notches 35a, 35b in the flap-operating levers 31a, 31b. The balls 34a, 34b are urged into the notches 35a, 35b by springs 33a, 33b as the flap-operating levers 31a, 31b arrive at position B and hold them in that position.

(30) After the sealing operation, the motor 21 is caused to rotate the main cam 24 through another ninety degrees, which returns the sealing arms 17a, 17b, T-shaped member 28 and bellcranks 30a, 30b to their original positions as shown in FIG. 5. The flaps 13a, 13b will stay in position B due to the action of the above-mentioned detents on flap-operating levers 31a, 31b. This enables the operator to recover the bag straightforwardly, which is done by manually moving the flaps 13a, 13b to position C. The bag is then recovered and the system is ready to receive the next bag.

(31) Optionally, the extractor fan 11 may be run for a period of a few seconds, typically six seconds, during and/or after the sealing elements 20a, 20b are energised. This helps to cool the welded region of the bag and speed up the cycle time.

(32) The chamber 10 is mounted to or forms an integral part of banknote processing equipment, such as a banknote deposit safe, a cash dispenser, a banknote sorter or banknote counter. In some cases, more than one device may be fitted to the same piece of equipment. It is then possible to use a single fan coupled to each device to reduce the pressure in each chamber simultaneously or, with a suitable system of baffles, selectively in each chamber.