Coin Handling Device with a Lubrication system
REFERENCE TO RELATED APPLICATIONS
This application is a continuation-in-part of United States patent application Serial No. 08/325,778 filed October 17, 1994, which is a continuation-in-part of U.S. patent application Serial No. 08/177,908, now U.S. Patent No. 5,370,575. HELD OF THE INVENTION The present invention relates generally to coin handling devices for handling coins of mixed denominations. More particularly, the present invention relates to an improved lubrication distribution system for use with coin handling devices of the type which use a coin-driving member having a resilient surface for moving coins along a metal coin-guiding surface of a stationary coin-guiding member. BACKGROUND OF THE INVENTION
In coin handling devices of the foregoing type, the coin-guiding member presses coins into the resilient surface of the coin-driving member to maintain positive control over the coins while the coin-driving member moves the coins relative to the stationary coin-guiding member. Such positive control permits the coin handling device to accurately and quickly handle and/or sort coin mixtures which include coin denominations of substantially similar diameters. In addition, the positive control over the coins permits the coin handling device to be quickly stopped by braking of the movement of the coin-driving member when a preselected number of coins of a selected denomination have been ejected from the device. Positive control also permits the coin handling device to be relatively compact yet operate at high speed.
A disadvantage of obtaining positive control of coins by pressing the coins into engagement with the coin-guiding member is that coins composed of such materials as stainless steel, titanium, nickel, and aluminum tend to gall (transfer metal to) the surface of the coin-guiding member due to the friction caused by relative movement between the coins and the coin-guiding member. More specifically, as the coins move over the coin-guiding surface of the coin-guiding member, metal particles from the coins rub off onto the coin-guiding surface. The friction caused by relative movement between the coins and the coin-guiding surface
generates heat which, in turn, welds the metal particles from the coins onto the stationary coin-guiding surface. The galled surface of the coin-guiding member can result in mishandling of coins. SUMMARY OF THE INVENTION Accordingly, an object of the present invention is to provide a coin handling device which minimizes mishandling by preventing coins from galling the surface of the stationary coin-guiding member.
In accordance with the foregoing object, the present invention provides a coin handling device for handling a plurality of coins. In one particular embodiment, the coin handling device comprises a coin-driving member having a resilient surface and a stationary coin-guiding member having a coin-guiding surface opposing the resilient surface of the coin-driving member. The coin-guiding surface is positioned generally parallel to the resilient surface and spaced slightly therefrom. The resilient surface of the coin-driving member is constructed and arranged to move the coins along the coin-guiding surface of the coin-guiding member.
To reduce friction between the coins and the coin-guiding surface of the coin- guiding member, the present invention provides a lubrication distribution system for use with the coin handling device. The lubrication distribution system includes at least one cavity formed in the coin-guiding surface of the coin-guiding member. A reservoir stores a lubrication fluid, and supply tubing conveys the lubrication fluid from the reservoir to the cavity. A control system regulates the flow of the lubrication fluid to the cavity via the supply tubing such that the lubrication fluid intermittently flows to the cavity while the resilient surface of the coin-driving member is moving the coins along the coin-guiding surface of the coin-guiding member. As the coins pass adjacent the cavity containing the lubrication fluid, minute amounts of the lubrication fluid are dragged onto the passing coins. A portion of this dragged lubrication fluid is then transferred from the coins to the coin- guiding surface of the coin-guiding member. The end result is a significant reduction in the coefficient of friction between the coins and the coin-guiding member, which in turn minimizes galling of the coin-guiding member.
Brief Description Of The Drawings
Other objects and advantages of the invention will become apparent upon reading the following detailed description and upon reference to the drawings in which: FIG. 1 is perspective view of a disc-type coin sorter with a top portion thereof broken away to show internal structure;
FIG. 2 is an enlarged section taken generally along line 2-2 in FIG. 1;
FIG. 3 is an enlarged section taken generally along line 3-3 in FIG. 2, showing the coins in full elevation; FIG. 4 is an enlarged section taken generally along line 4-4 in FIG. 2, showing in full elevation a nickel registered with an ejection recess;
FIG. 5 is perspective view of a disc-to-disc type coin sorter;
FIG. 6 is a top plan view of the arrangement in FIG. 5;
FIG. 7 is an enlarged section taken generally along line 7-7 in FIG. 6; FIG. 8 is an enlarged section taken generally along line 8-8 in FIG. 6;
FIG. 9 is perspective view of a rail-type coin sorter with portions thereof broken away to show the internal structure;
FIG. 10 is an enlarged plan view of the coin-queuing portion of the coin sorter of FIG. 9, taken from the top surface of the rotating pad looking upwardly, with various coins superimposed thereon;
FIG. 11 is an enlarged section taken generally along line 11-11 in FIG. 10, showing the coins in full elevation;
FIG. 12 is an enlarged section taken generally along line 12-12 in FIG. 10, showing the coins in full elevation; FIG. 13 is an enlarged section taken generally along line 13-13 in FIG. 10, showing the coins in full elevation;
FIG. 14 is an enlarged section taken generally along line 14-14 in FIG. 10, showing the coins in full elevation;
FIG. 15 is an enlarged section taken generally along line 15-15 in FIG. 10, showing the coins in full elevation;
FIG. 16 is a top plan view of the coin sorter of FIG. 9;
FIG. 17 is an enlarged top plan view of the sorting rail of the device shown in FIG. 16, with various coins superimposed thereon;
FIG. 18 is a side elevation of the mechanism shown in FIG. 17, with the addition of a drive belt; FIG. 19 is an enlarged section of a portion of the drive belt of the rail-type coin sorter in FIG. 9, showing the coins in full elevation;
FIG. 20 is an enlarged top plan view of an alternative sorting rail for use in the rail-type device of FIG. 9;
FIG. 21 is a bottom plan view of a modified sorting head for use in the disc- type coin sorter of FIG. 1;
FIG. 22 is a top plan view of a modified disc-to-disc type coin sorter;
FIG. 23 is an enlarged top plan view of a modified sorting rail for use in the rail-type device of FIG. 9;
FIG. 24 is an enlarged top plan view of another modified sorting rail for use in the rail-type device of FIG. 9;
FIG. 25 is a bottom plan view of another modified sorting head for use in the disc-type coin sorter of FIG. 1;
FIG. 26 is an enlarged section taken generally along line 26-26 in FIG. 25;
FIG. 27 is a general mechanical and electrical schematic of the pertinent elements of a lubrication distribution system embodying the present invention;
FIG. 28 is a flow chart illustrating the sequence of operations used to actuate the pump at predetermined time intervals;
FIG. 29 is a general electrical and mechanical schematic for a modified lubrication distribution system that uses gravity to supply lubrication fluid to a porous discharge insert mounted in a coin-guiding member of the coin handling device;
FIG. 30 is a similar cross-section as shown in FIG. 26 except that the porous discharge inserts have been substituted with small holes; and
FIG. 31 is a similar cross- section as shown in FIG. 26 except that the porous discharge inserts have been substituted with small holes fitted with capillary tubes. While the invention is susceptible to various modifications and alternative forms, specific embodiments thereof have been shown by way of example in the drawings and will be described in detail. However, it should be understood there is
no intention to limit this invention to the particular forms disclosed. On the contrary, this intention is to cover all modifications, equivalents, and alternatives falling within the spirit and scope of the invention as defined by the appended claims. DESCRIPTION OF THE PREFERRED EMBODIMENTS Turning now to the drawings, FIGS. 1-26, 30, and 31 illustrate four types of coin handling devices, including a disc-type coin sorter (FIGS. 1-4, 21, 25, 26, 30, and 31), a disc-to-disc type coin sorter (FIGS. 5-8 and 22), a rail-type coin sorter with exit channels (FIGS. 9-19 and 23), and a modified rail-type coin sorter with exit apertures (FIGS. 20 and 24). Each of these types of coin handling devices uses a coin-driving member having a resilient surface for moving coins along a metal coin- guiding surface of a stationary coin-guiding member. In the disc-type coin sorter, the coin-driving member is a rotating disc and the coin-guiding member is a stationary sorting head. In the disc-to-disc type coin sorter, the coin-driving members include a pair of rotating discs and the coin-guiding members include a stationary queuing head and a stationary sorting disc. In the rail-type coin sorter, the coin-driving member is a drive belt and the coin-guiding member is a stationary sorting rail.
The present invention provides a lubrication distribution system (FIGS. 27-29) for controllably supplying lubrication fluid to the coin-guiding surface of the coin- driving member so as to reduce friction between the coins and the coin-guiding surface of the coin-guiding member. This lubrication distribution system may be used by itself or in combination with the various lubricating techniques depicted in FIGS. 1-24 and disclosed in United States patent application Serial No. 08/325,778, entitled "Coin Handling Device" and filed October 17, 1994. As described below in connection with FIGS. 1-24, these lubricating techniques may take the form of lubricant-filled cavities, self-lubricating inserts, or a gall-resistant coating applied to the coin-guiding surface.
With respect to the following detailed description, the term "stationary plate" is defined to encompass the stationary sorting head of the disc-type coin sorter, the queuing head and sorting disc of the disc-to-disc type coin sorter, and the sorting rail of the rail-type coin sorter. Furthermore, the term "sorting plate" is defined to encompass the stationary sorting head of the disc-type coin sorter, the sorting disc of the disc-to-disc type coin sorter, and the sorting rail of the rail-type coin sorter.
Turning first to the disc-type coin sorter of FIG. 1, a hopper 10 receives coins of mixed denominations and feeds them through central openings in a housing 11 and a coin-guiding member in the form of an annular sorting head or guide plate 12 inside or underneath the housing. As the coins pass through these openings, they are deposited on the top surface of a coin-driving member in the form of a rotatable disc 13. This disc 13 is mounted for rotation on a stub shaft (not shown) and driven by an electric motor 14 mounted to a base plate 15. The disc 13 comprises a resilient pad 16 bonded to the top surface of a solid metal disc 17.
The top surface of the resilient pad 16 is preferably spaced from the lower surface of the sorting head 12 by a gap of about 0.005 inches (0.13 mm). The gap is set around the circumference of the sorting head 12 by a three point mounting arrangement including a pair of rear pivots 18, 19 loaded by respective torsion springs 20 which tend to elevate the forward portion of the sorting head. During normal operation, however, the forward portion of the sorting head 12 is held in position by a latch 22 which is pivotally mounted to the frame 15 by a bolt 23. The latch 22 engages a pin 24 secured to the sorting head. For gaining access to the opposing surfaces of the resilient pad 16 and the sorting head, the latch is pivoted to disengage the pin 24, and the forward portion of the sorting head is raised to an upward position (not shown) by the torsion springs 20. As the disc 13 is rotated, the coins 25 deposited on the top surface thereof tend to slide outwardly over the surface of the pad due to centrifugal force. The coins 25, for example, are initially displaced from the center of the disc 13 by a cone 26, and therefore are subjected to sufficient centrifugal force to overcome their static friction with the upper surface of the disc. As the coins move outwardly, those coins which are lying flat on the pad enter the gap between the pad surface and the guide plate 12 because the underside of the inner periphery of this plate is spaced above the pad 16 by a distance which is about the same as the thickness of the thickest coin. As further described below, the coins are sorted into their respective denominations, and the coins for each denomination issue from a respective exit slot, such as the slots 27, 28, 29, 30, 31 and 32 (see FIGS. 1 and 2) for dimes, pennies, nickels, quarters, dollars, and half-dollars, respectively. In general, the coins for any given currency are sorted by the variation in diameter for the various denominations.
Preferably most of the aligning, referencing, sorting, and ejecting operations are performed when the coins are pressed into engagement with the lower surface of the sorting head 12. In other words, the distance between the lower surfaces of the sorting head 12 with the passages conveying the coins and the upper surface of the rotating disc 13 is less than the thickness of the coins being conveyed. As mentioned above, such positive control permits the coin sorter to be quickly stopped by braking the rotation of the disc 13 when a preselected number of coins of a selected denomination have been ejected from the sorter. Positive control also permits the sorter to be relatively compact yet operate at high speed. The positive control, for example, permits the single file stream of coins to be relatively dense, and ensures that each coin in this stream can be directed to a respective exit slot.
Turning now to FIG. 2, there is shown a bottom view of the preferred sorting head 12 including various channels and other means especially designed for high¬ speed sorting with positive control of the coins, yet avoiding the galling problem. It should be kept in mind that the circulation of the coins, which is clockwise in FIG.
1, appears counterclockwise in FIG. 2 because FIG. 2 is a bottom view. The various means operating upon the circulating coins include an entrance region 40, means 41 for stripping "shingled" coins, means 42 for selecting thick coins, first means 44 for recirculating coins, first referencing means 45 including means 46 for recirculating coins, second referencing means 47, and the exit means 27, 28, 29, 30, 31 and 32 for six different coin denominations, such as dimes, pennies, nickels, quarters, dollars and half-dollars. The lowermost surface of the sorting head 12 is indicated by the reference numeral 50.
Considering first the entrance region 40, the outwardly moving coins initially enter under a semi-annular region underneath a planar surface 61 formed in the underside of the guide plate or sorting head 12. Coin Cl, superimposed on the bottom plan view of the guide plate in FIG. 2 is an example of a coin which has entered the entrance region 40.
Free radial movement of the coins within the entrance region 40 is terminated when they engage a wall 62, though the coins continue to move circumferentially along the wall 62 by the rotational movement of the pad 16, as indicated by the central arrow in the counterclockwise direction in FIG. 2. To prevent the entrance
region 40 from becoming blocked by shingled coins, the planar region 61 is provided with an inclined surface 41 forming a wall or step 63 for engaging the upper most coin in a shingled pair. In FIG. 2, for example, an upper coin C2 is shingled over a lower coin C3. As further shown in FIG. 3, movement of the upper coin C2 is limited by the wall 63 so that the upper coin C2 is forced off of the lower coin C3 as the lower coin is moved by the rotating disc 13.
Returning to FIG. 2, the circulating coins in the entrance region 40, such as the coin Cl, are next directed to the means 42 for selecting thick coins. This means 42 includes a surface 64 recessed into the sorting head 12 at a depth of 0.070 inches (1.78 mm) from the lowermost surface 50 of the sorting head. Therefore, a step or wall 65 is formed between the surface 61 of the entrance region 40 and the surface 64. The distance between the surface 64 and the upper surface of the disc 13 is therefore about 0.075 inches so that relatively thick coins between the surface 64 and the disc 13 are held by pad pressure. To initially engage such thick coins, an initial portion of the surface 64 is formed with a ramp 66 located adjacent to the wall 62. Therefore, as the disc 13 rotates, thick coins in the entrance region that are next to the wall 62 are engaged by the ramp 66 and thereafter their radial position is fixed by pressure between the disc and the surface 64. Thick coins which fail to initially engage the ramp 66, however, engage the wall 65 and are therefore recirculated back within the central region of the sorting head. This is illustrated, for example, in FIG. 4 for the coin C4. This initial selecting and positioning of the thick coins prevents misaligned thick coins from hindering the flow of coins to the first referencing means 45.
Returning now to FIG. 2, the ramp 66 in the means 42 for selecting the thick coins can also engage a pair or stack of thin coins. Such a stack or pair of thin coins will be carried under pad pressure between the surface 64 and the rotating disc 13. In the same manner as a thick coin, such a pair of stacked coins will have its radial position fixed and will be carried toward the first referencing means 45. The first means 45 for referencing the coins obtains a single-file stream of coins directed against the outer wall 62 and leading up to a ramp 73.
Coins are introduced into the referencing means 45 by the thinner coins moving radially outward via centrifugal force, or by the thicker coin(s) C52a
following concentricity via pad pressure. The stacked coins C58a and C50a are separated at the inner wall 82 such that the lower coin C58a is carried against surface 72a. The progression of the lower coin C58a is depicted by its positions at C58b, C58c, C58d, and C58e. More specifically, the lower coin C58 becomes engaged between the rotating disc 13 and the surface 72 in order to carry the lower coin to the first recirculating means 44, where it is recirculated by the wall 75 at positions C58d and C58e. At the beginning of the wall 82, a ramp 90 is used to recycle coins not fully between the outer and inner walls 62 and 82 and under the sorting head 12. As shown in FIG. 2, no other means is needed to provide a proper introduction of the coins into the referencing means 45.
The referencing means 45 is further recessed over a region 91 of sufficient length to allow the coins C54 of the widest denomination to move to the outer wall 62 by centrifugal force. This allows coins C54 of the widest denomination to move freely into the referencing means 45 toward its outer wall 62 without being pressed between the resilient pad 16 and the sorting head 12 at the ramp 90. The inner wall 82 is preferably constructed to follow the contour of the recess ceiling. The region 91 of the referencing recess 45 is raised into the head 12 by ramps 93 and 94, and the consistent contour at the inner wall 82 is provided by a ramp 95.
The first referencing means 45 is sufficiently deep to allow coins C50 having a lesser thickness to be guided along the outer wall 62 by centrifugal force, but sufficiently shallow to permit coins C52, C54 having a greater thickness to be pressed between the pad 16 and the sorting head 12, so that they are guided along the inner wall 82 as they move through the referencing means 45. The referencing recess 45 includes a section 96 which bends such that coins C52, which are sufficiently thick to be guided by the inner wall 82 but have a width which is less - than the width of the referencing recess 45, are carried away from the inner wall 82 from a maximum radial location 83 on the inner wall toward the ramp 73.
This configuration in the sorting head 12 allows the coins of all denominations to converge at a narrow ramped finger 73a on the ramp 73, with coins C54 having the largest width being carried between the inner and outer walls via the surface 96 to the ramped finger 73a so as to bring the outer edges of all coins to a generally common radial location. By directing the coins C50 radially inward along the latter
portion of the outer wall 62, the probability of coins being offset from the outer wall 62 by adjacent coins and being led onto the ramped finger 73a is significantly reduced. Any coins C50 which are slightly offset from the outer wall 62 while being led onto the ramp finger 73a may be accommodated by moving the edge 51 of exit slot 27 radially inward, enough to increase the width of the slot 27 to capture offset coins C50 but to prevent the capture of coins of the larger denominations. For sorting Dutch coins, the width of the ramp finger 73a may be about 0.140 inch. At the terminal end of the ramp 73, the coins become firmly pressed into the pad 16 and are carried forward to the second referencing means 47. A coin such as the coin C50c will be carried forward to the second referencing means 47 so long as a portion of the coin is engaged by the narrow ramped finger 73a on the ramp 73. If a coin is not sufficiently close to the wall 62 so as to be engaged by this ramped finger 73a, then the coin strikes a wall 74 defined by the second recirculating means 46, and that coin is recirculated back to the entrance region 40.
The first recirculating means 44, the second recirculating means 46 and the second referencing means 47 are defined at successive positions in the sorting head 12. It should be apparent that the first recirculating means 44, as well as the second recirculating means 46, recirculate the coins under positive control of pad pressure. The second referencing means 47 also uses positive control of the coins to align the outer most edge of the coins with a gaging wall 77. For this purpose, the second referencing means 47 includes a surface 76, for example, at 0.110 inches (1.27 mm) from the bottom surface of the sorting head 12, and a ramp 78 which engages the inner edge portions of the coins, such as the coin C50d. As best shown in FIG. 2, the initial portion of the gaging wall 77 is along a spiral path with respect to the center of the sorting head 12 and the sorting disc 13, so that as the coins are positively driven in the circumferential direction by the rotating disc 13, the outer edges of the coins engage the gaging wall 77 and are forced slightly radially inward to a precise gaging radius, as shown for the coin C16 in FIG. 3. FIG. 3 further shows a coin C17 having been ejected from the second recirculating means 46.
Referring back to FIG. 2, the second referencing means 47 terminates with a slight ramp 80 causing the coins to be firmly pressed into the pad 16 on the rotating disc with their outer most edges aligned with the gaging radius provided by the gaging wall 77. At the terminal end of the ramp 80 the coins are gripped between the guide plate 12 and the resilient pad 16 with the maximum compressive force.
This ensures that the coins are held securely in the new radial position determined by the wall 77 of the second referencing means 47.
The sorting head 12 further includes sorting means comprising a series of ejection recesses 27, 28, 29, 30, 31 and 32 spaced circumferentially around the outer periphery of the plate, with the innermost edges of successive slots located progressively farther away from the common radial location of the outer edges of all the coins for receiving and ejecting coins in order of increasing diameter. The width of each ejection recess is slightly larger than the diameter of the coin to be received and ejected by that particular recess, and the surface of the guide plate adjacent the radially outer edge of each ejection recess presses the outer portions of the coins received by that recess into the resilient pad so that the inner edges of those coins are tilted upwardly into the recess. The ejection recesses extend outwardly to the periphery of the guide plate so that the inner edges of these recesses guide the tilted coins outwardly and eventually eject those coins from between the guide plate 12 and the resilient pad 16.
The innermost edges of the ejection recesses are positioned so that the inner edge of a coin of only one particular denomination can enter each recess; the coins of all other remaining denominations extend inwardly beyond the innermost edge of that particular recess so that the inner edges of those coins cannot enter the recess. For example, the first ejection recess 27 is intended to discharge only dimes, and thus the innermost edge 51 of this recess is located at a radius that is spaced inwardly from the radius of the gaging wall 77 by a distance that is only slightly greater than the diameter of a dime. Consequently, only dimes can enter the recess 27. Because the outer edges of all denominations of coins are located at the same radial position when they leave the second referencing means 47, the inner edges of the pennies, nickels, quarters, dollars and half dollars all extend inwardly beyond the innermost edge of the recess 27, thereby preventing these coins from entering that
particular recess.
At recess 28, the inner edges of only pennies are located close enough to the periphery of the sorting head 12 to enter the recess. The inner edges of all the larger coins extend inwardly beyond the innermost edge 52 of the recess 28 so that they remain gripped between the guide plate and the resilient pad. Consequently, all the coins except the pennies continue to be rotated past the recess 28.
Similarly, only nickels enter the ejection recess 29, only the quarters enter the recess 30, only the dollars enter the recess 31, and only the half dollars enter the recess 32. Because each coin is gripped between the sorting head 12 and the resilient pad
16 throughout its movement through the ejection recess, the coins are under positive control at all times. Thus, any coin can be stopped at any point along the length of its ejection recess, even when the coin is already partially projecting beyond the outer periphery of the guide plate. Consequently, no matter when the rotating disc is stopped (e.g. , in response to the counting of a preselected number of coins of a particular denomination), those coins which are already within the-various ejection recesses can be retained within the sorting head until the disc is re-started for the next counting operation.
In order to prevent coins from galling the sorting head 12 in regions where the coins are pressed by the sorting head 12 into the resilient pad 16, the sorting head 12 is provided with gall-resistant means. In an embodiment shown in FIG. 2, selected regions of the sorting head 12 are machined to form a multiplicity of small cavities, dimples, or depressions 99 filled with a solid lubricant. The cavities 99 may be filled with the lubricant by rubbing a solid stick of the lubricant back and forth across the dimpled surfaces so as to fill the cavities 99 with lubricant and, at the same time, coat the surfaces surrounding the cavities 99. The selected regions are generally those regions where the coins are pressed into the pad. With respect to the center of the sorting head 12, the cavities 99 are strategically positioned at radial locations targeting the inner and outer edges of the various coins moving beneath the sorting head 12. It has been found that these inner and outer coin edges precipitate galling more than other portions of the coins. If desired, a uniform or random distribution of a larger number of cavities 99 may be employed in lieu of the strategic
positioning of the cavities 99. Although the cavities 99 are illustrated in FIGS. 3 and 4 as having a conical shape, it should be apparent that the cavities 99 may be configured in a variety of other shapes, including but not limiting to cylindrical and rectangular configurations. As coins slide over the dimpled surfaces of the sorting head, minute amounts of the lubricant are dragged from the cavities onto the passing coins. A portion of this lubricant is then transferred from the coins to the solid surfaces of the sorting head that engage the coins. The end result is a significant reduction in the coefficient of friction between the coins and the sorting head, which in turn minimizes galling of the sorting head. The lubricant is replenished from time to time, preferably at intervals measured by the number of coins processed by the sorter. One way to replenish the lubricant is to simply rub a solid stick of the lubricant back and forth across the dimpled surfaces.
The lubricant should remain solid over the operating temperature range of the sorting head, which can be heated well above room temperature when processing large batches of coins. The lubricant should also be soft enough that it can be removed from the cavities by passing coins, small quantities at a time. In the preferred embodiment, the lubricant is "Door-Easy" lubricant (the DE-25 formula) produced by American Grease Stick Co. of Muskegon, Michigan, and having a flash point of approximately 300 °F.
In an alternative embodiment illustrated in FIG. 21, the lubricant-filled cavities 99 are substituted with self-lubricating plugs or inserts 99'. With respect to the center of the sorting head 12, these inserts 99' are elongated in the radial direction and are positioned to target the inner and outer edges of the various coins moving beneath the sorting head 12. The elongated inserts 99' are press-fit into shallow cavities machined into the lower surface of the sorting head 12. The cavities have a depth of approximately 1/16 inch. The inserts 99' should provide gall- resistant, corrosion-resistant, low- wear and low-friction surfaces. Furthermore, the inserts 99' should deliver consistent performance over the operating temperature range of the sorting head. As previously stated, the temperature at the bearing surface (coin-contacting surface) of the inserts 99' can be somewhat higher than room temperature due to the frictional heat generated by the coins moving beneath the
sorting head. Moreover, the inserts 99' should exhibit excellent overall dimensional stability combined with a high degree of toughness.
The inserts 99' are preferably composed of VESPEL® polyimide resin (the SP-22 formula) commercially available from Du Pont Engineering Polymers of Newark, Delaware. The SP-22 polyimide is a graphite-filled, sintered polyimide resin composed 40 percent by weight of graphite. The graphite in the resin provides the inserts 99' with low wear and friction. In particular, a machined insert composed of SP-22 polyimide has a coefficient of friction of approximately 0.1 at a pressure velocity of 3.5 MPa m/s, a wear rate of approximately 4.2 m/s x 10" , and a hardness of approximately 5-25 on the Rockwell "E" scale. The inserts 99' may be machined with conventional metalworking equipment applying techniques used in machining brass. Alternatively, the inserts 99' may be manufactured by conventional direct-forming techniques such as molding.
As coins slide over the inserts 99' of the sorting head, minute amounts of graphite rub off the self-lubricating inserts 99' onto the passing coins. A portion of this graphite is then transferred from the coins to the solid surfaces of the sorting head that engage the coins. Thus, the moving coins distribute the graphite across the sorting head. The end result is a significant reduction in the coefficient of friction between the coins and the sorting head, which in turn minimizes galling of the sorting head. It has been found that four inserts 99', positioned as shown in FIG. 21, can sufficiently coat the lower surface of the sorting head 12 to minimize galling. FIG. 21 illustrates two radially-overlapping inserts 99' located in the referencing means 45 just upstream from the ramp 73. A third insert 99' is located just upstream from the ejection recess 28, and a fourth insert 99' is located just upstream from the ejection recess 29. If extensive and long-term use of the coin sorter wears down one or moie of the inserts 99', the worn inserts are easily removed from the sorting head and replaced with new inserts.
In yet another embodiment illustrated in FIGS. 25-31, a lubrication distribution system (FIGS. 27 and 29) controllably conveys lubrication fluid to one or more disc-shaped porous discharge inserts 302 mounted in the sorting head 12. Each porous discharge insert 302 is made of a material containing pores which permit lubrication fluid to pass between its opposing flat surfaces. A preferred material is
stainless steel containing pores which are uniformly distributed throughout the material, with an average hydraulic diameter of 100 microns. Such porous inserts 302 are commercially available from Mott Metallurgical Corporation of Farmington, Connecticut. The preferred pore size for any given application is somewhat dependent upon the viscosity of the lubrication fluid. The pore size and lubrication fluid are selected such that surface tension prevents the lubrication fluid from dripping off the inserts 302 onto the rotating pad 16. A preferred lubrication fluid is Capella Oil WF manufactured by Texaco Refining and Marketing Inc. of Houston, Texas. As best shown in FIGS. 25 and 26, the porous discharge inserts 302 are positioned to target at least the inner and outer edges of coins moving through the referencing channel 45. The illustrated inserts 302 cover virtually the entire width of the referencing channel 45. One of the inserts 302 is immediately adjacent the inner wall 82 of the referencing channel 45, while the other of the inserts 302 is immediately adjacent the outer wall 62 of the channel 45. As best shown in FIG. 26, each porous discharge insert 302 is press-fit into a shallow cylindrical cavity 304 machined into the lower surface of the sorting head 12. The shallow cavity 304 extends approximately 0.125 inches deep from the surface of the referencing channel 45. The shallow cylindrical cavity 304 has a diameter of approximately 0.625 inches.
Lubrication fluid is controllably supplied to the porous discharge inserts 302 in FIG. 26 via the upper surface, i.e., noncoin-guiding surface, of the sorting head 12. With respect to each insert 302, a narrow hole 306 is formed in the upper portion of the sorting head 12. The hole 306 extends approximately 0.250 inches deep from the upper surface of the sorting head 12, and has a diameter of approximately 0.313 inches. The narrow hole 306 is tapped to permit a hose fitting (see FIGS. 27 and 29) to be threadably inserted into the hole 306. In addition to the narrow tapped hole 306, a pooling cavity 308 is formed in the central portion of the sorting head 12 between the narrow hole 306 and the shallow cavity 304. The pooling cavity 308 has a depth of approximately 0.125 inches and a diameter of approximately 0.562 inches. As discussed below, in the lubrication distribution systems illustrated in FIGS. 27 and 29, the flow of lubrication fluid to the porous
discharge inserts 302 is modulated such that the pooling cavities 308 are intermittently filled with the lubrication fluid.
FIG. 27 shows one preferred embodiment of a lubrication distribution system 300 provided by this invention in which an electric pump motor 310 drives a pump 312 thereby supplying lubrication fluid 314 from a reservoir 316 to the porous inserts 302. The reservoir 316 can simply be the container in which the lubrication fluid 314 is shipped and stored. A preferred pump is a 12-volt DC diaphragm pump which produces a pressure of about 7 psi within the pooling cavities 308. Like FIGS. 25 and 26, the porous inserts 302 are mounted in the sorting head 12 to directly lubricate coins as they traverse the referencing channel 45. A microprocessor 318 enables a pump switch circuit 320 to activate the electric pump motor 310 in response to coin proximity sensors 321 (see FIG. 25) in the exit channels 27-32 counting a predetermined number "C" of coins.
The coin proximity sensors 321 are mounted in the upper surfaces of the respective exit channels 27-32 along the outboard edges thereof. The effective fields of the sensors 321 are all located just outboard of the radius at which the outer edges of all coin denominations are gaged before they reach the exit channels 27-32, so that each sensor 321 detects only the coins which enter its exit channel and does not detect the coins which bypass that exit channel. The coin proximity sensor 321 associated with a particular exit channel generates an electrical pulse each time a coin passes through that exit channel. The electrical pulses from the six sensors 321 yield actual counts of dimes, pennies, nickels, quarters, dollars, and half dollars passing through the respective exit channels 27-32. The total sum of the actual counts of these coin denominations is accumulated in a coin counter 322 coupled to the sensors 321. Thus, the coin counter 322 maintains a running sum of the total number of coins which have been processed by the coin sorter. As discussed below, the coin counter 322 is reset to zero each time the stored coin count reaches the predetermined number "C" of coins.
The microprocessor 318 uses an internal timing mechanism 324 to control the time intervals for supplying the lubrication fluid 314 to the porous inserts 302. Specifically, in response to the coin count in the coin counter 322 reaching the predetermined number "C" of coins, the microprocessor 318 sends a positive signal
to the pump switch circuit 320 which drives the electric pump motor 310. The electric pump motor 310 then actuates the pump 312 and the lubrication fluid 314 is slowly forced from the reservoir 316 to the pooling cavities 308 located above the respective porous inserts 302. The lubrication fluid 314 is carried from the reservoir 316 to the pooling cavities 308 through interconnect tubing 326. The pump 312 remains actuated for the time period of "T" microseconds. The time period of "T" microseconds is preferably chosen to be the approximate length of time required to substantially fill the pooling cavities 308 with the lubrication fluid 314. After the time period of "T" microseconds, the microprocessor 318 sends a control signal to the pump switch circuit 320 to deactivate the pump motor 310, thereby turning off the pump 312. The size of the pores in the porous inserts 302 is chosen such that gravity G alone causes the lubrication fluid 314 within the pooling cavities 308 to pass through the porous inserts 302 beneath those cavities 308.
To convey the lubrication fluid 314 to both of the pooling cavities 308, the interconnect tubing 326 splits into two branches 326a, 326b at a T-shaped connector 328. The T-shaped connector 328 equally divides the lubrication fluid 314 entering the connector 328 among the two branches 326a, 326b. To attach the tubing 326 to the sorting head 12, downstream ends of the two branches 326a, 326b are provided with respective threaded male fittings 330. The male fittings 330 are threadably engaged within the narrow tapped holes 306 (FIG. 26).
FIG. 28 is a flow chart illustrating the sequence of operations used to actuate the electrically-driven pump 312 at predetermined time intervals. As previously stated, the microprocessor circuitry 318 includes the coin counter 322 and the timer 324. The coin counter 322 is initially cleared to zero (step 332), the count-down timer 324 is initially loaded with a value of "T" microseconds (step 334), and the electric pump 312 is initially "off" (step 336). As coins are processed with the coin sorter, the coin counter 322 maintains a running sum of the total number of coins detected by the coin sensors 321 in the exit channels 27-32. In response to the coin count in the coin counter 322 reaching the predetermined number "C" of processed coins, the microprocessor 318 clears the counter 322 to zero (steps 338 and 340). Furthermore, the microprocessor 318 actuates the pump 312 by sending a positive
signal to the pump switch circuit 320 which drives the electric pump motor 310 (step 342).
In response to the microprocessor 318 turning "on" the pump 312, the timer 324 counts down to zero from "T" microseconds (steps 344 and 346). The value of "T" is preferably selected to be the amount of time required to substantially fill the pooling cavities 308 with the lubrication fluid 314. In one embodiment, the value of "T" is less than 10 microseconds. After "T" microseconds have lapsed, the microprocessor 318 turns "off" the pump 312 (step 336) and resets the timer 324 to "T" microseconds. The pump 312 remains 'roff" until the predetermined number "C" of coins have once again passed through the exit channels 27-32 of the coin sorter. In one embodiment, this predetermined number "C" of coins is selected to be the number of coins required to substantially deplete the lubrication fluid in the pooling cavities 308 from the time that these cavities are filled with the fluid.
To summarize, the coin counter 322 repeatedly drives the electric pump 312 through the on/off cycles in FIG. 28. In response to the coin counter 322 counting the predetermined number "C" of coins sorted by the coin sorter, the microprocessor 318 turns "on" the pump 312 for a period of "T" microseconds measured by the timer 324. After "T" microseconds, the microprocessor 318 turns "off" the pump 312. The pump 312 remains "off" until the coin counter 322 has once again counted the predetermined number "C" of coins passing through the exit channels 27-32. The on/off cycle of the electric pump 312 is repeated each time the coin counter 322 counts the predetermined number "C" of coins.
FIG. 29 illustrates a modified lubrication distribution system 300' which relies upon gravity G to convey a lubrication fluid 314 into the pooling cavities 308 above the porous discharge inserts 302 through interconnect tubing 352 connected to a reservoir 316. An electrically switched control valve 356, disposed within the tubing 352, permits or prohibits flow of the fluid 314 into the pooling cavities 308. The reservoir 316 is fitted with a special cap 358 that includes means for direct attachment to the interconnect tubing 352. The lubrication distribution system in FIG. 29 employs a microprocessor- based control system similar to that used in the lubrication distribution system in FIG. 27. Specifically, in response to the coin count in the coin counter 322 reaching
the predetermined number "C" of coins, the microprocessor 318 sends a positive signal to the valve switch circuit 360. In response to the positive signal, the valve switch circuit 360 opens the control valve 356 for the predetermined time period of "T" microseconds as measured by the timer 324. The time period of "T" microseconds is sufficiently long to substantially fill the pooling cavities 308 when the reservoir 316 is nearly empty and has little back pressure to force the fluid 314 into the pooling cavities 308. If it is determined that the length of the time period is too long such that when the reservoir 316 is full, the large back pressure forces the fluid 314 through the porous inserts 302 after the pooling cavities 308 are filled but before the control valve 356 closes, then a pressure sensor can be placed in the cap 358 which the microprocessor 318 would monitor. The microprocessor 318 then adjusts the time interval over which the control valve 356 remains open based on the pressure at the cap 358, thereby providing the exact amount of the fluid 314 into the pooling cavities 308 under all conditions. This pressure sensor could serve a dual role in that the microprocessor 318 could send a signal to a user interface panel indicating when the fluid reservoir 316 is low or empty.
While the control valve 356 is open, the lubrication fluid 314 is carried from the reservoir 316 to the pooling cavities 308 through the interconnect tubing 352. The control valve 356 remains open for the time period of "T" microseconds. After the time period of "T" microseconds, the microprocessor 318 sends a control signal to the valve switch circuit 360 to close the control valve 356. The open/close cycles of the control valve 356 are directly analogous to the on/off cycles of the electrically- driven pump 312 in FIG. 27. Therefore, each time the coin count in the coin counter 322 reaches the predetermined number "C", the control valve 356 is opened for a time period of "T" microseconds as measured by the timer 324. During this time period of "T" microseconds, the interconnect tubing 352 supplies the volume of lubrication fluid 314 necessary to substantially fill the pooling cavities 308 above the porous inserts 302. The porous discharge inserts 302 in FIGS. 26, 27, and 29 sufficiently inhibit the flow of lubrication fluid to the lower coin-guiding surface of the referencing channel 45 such that the lubrication fluid does not drip onto the rotating pad 16. The
surface tension generated by the pores in each insert 302 maintains the lubrication fluid within that insert 302 until a coin drags a minute portion of that fluid from the lower surface of the insert 302. Instead of using the porous discharge inserts 302 to inhibit the flow of the lubrication fluid to the lower coin-guiding surface of the referencing channel 45, the sorting head 12 may alternatively be provided with either narrow holes 362 (FIG. 30) or holes fitted with capillary tubes 364 (FIG. 31).
FIG. 30 illustrates three holes 362 passing completely through the sorting head 12. The lower ends of the holes 362 open into the referencing channel 45. At least the upper portions of the holes 362 are tapped to permit threadable engagement to the hose fittings 330 of the lubrication distribution system in FIG. 27 or FIG. 29. The holes 362 are sufficiently narrow in diameter such that the surface tension at the lower ends of the holes 362 prevents the lubrication fluid from dripping onto the rotating pad 16. In one embodiment, these holes 362 have a diameter of approximately 0.18 inches. The number of holes 362 machined in the sorting head 12 may, of course, be varied depending upon the desired amount of coverage.
The lubrication distribution systems 300, 300' in respective FIGS. 27 and 29 supply lubrication fluid to the holes 362 in FIG. 30 is a manner similar to the manner in which these systems supply the lubrication fluid to the porous discharge inserts 302 in FIG. 26. For example, with respect to the lubrication distribution system 300 in FIG. 27, in response to the coin count in the coin counters 322 reaching the predetermined number "C" of coins, the microprocessor 318 turns "on" the pump 312 for a time period of "T" microseconds. This time period, which is measured by the timer 324, is selected such that the pumped lubrication fluid 314 substantially fills the holes 362. Similarly, with respect to the lubrication distribution system 300' in FIG. 29, the microprocessor 318 opens the control valve 356 for a time period of
"T" microseconds in response to the coin count in the coin counters 322 reaching the predetermined number "C".
The modified sorting head in FIG. 31 is similar to the sorting head in FIG. 30 except that the holes are slightly reduced in diameter and are fitted with stainless steel capillary tubes 364. The capillary tubes 364 are secured in their respective holes by a compression fit. The lower ends of the capillary tubes 364 are flush with the lower coin-guiding surface of the sorting head 12. The upper ends of the capillary tubes
364 protrude upward from the upper surface of the sorting head 12 to facilitate attachment to hose fittings of the lubrication distribution system. The inner diameter of the capillary tubes 364 is chosen in accordance with the viscosity of the lubrication fluid such that the capillary tubes 364 adequately restrict the flow of the lubrication fluid supplied thereto and the surface tension at the lower ends of the capillary tubes 364 can be strictly controlled to prevent the lubrication fluid from dripping onto the rotating pad 16. In one embodiment, the capillary tubes 364 have an inner diameter of approximately 0.063 inches.
The lubricant-filled cavities 99 (FIGS. 1-4), the elongated self-lubricating inserts 99' (FIG. 21), the lubricant-supplied porous discharge inserts 302 (FIGS. 25- 29), the lubricant-supplied narrow holes 362 (FIG. 30), and the holes fitted with the lubricant-supplied capillary tubes 364 (FIG. 31) are described above in connection with a coin sorter of the type which uses a resilient disc rotating beneath a stationary coin-manipulating head. These lubrication techniques, however, may also be employed with other types of coin handling devices, including disc-to-disc type coin sorters and rail-type coin sorters.
For example, FIG. 5 illustrates a disc-to-disc type coin sorter including a queuing device 110 having a hopper which receives coins of mixed denominations. The hopper feeds the coins through a central feed aperture in a coin-guiding member in the form of an annular queuing head or guide plate 112. As the coins pass through the feed aperture, they are deposited on the top surface of a coin-driving member in the form of a rotatable disc 114. This disc 114 is mounted for rotation on a stub shaft (not shown) driven by an electric motor (not shown). The disc 114 comprises a resilient pad 118, preferably made of a resilient rubber or polymeric material, bonded to the top surface of a solid metal plate 120.
As the disc 114 is rotated (in the counterclockwise direction as viewed in FIG. 6), the coins deposited on the top surface thereof tend to slide outwardly over the surface of the pad 118 due to centrifugal force. As the coins move outwardly, those coins which are lying flat on the pad 118 enter the gap between the pad surface and the queuing head 112 because the underside of the inner periphery of this head 112 is spaced above the pad 118 by a distance which is approximately the same as the thickness of the thickest coin.
As can be seen most clearly in FIG. 6, the outwardly moving coins initially enter an annular recess 124 formed in the underside of the queuing head 112 and extending around a major portion of the inner periphery of the queuing head 112. To permit radial movement of coins entering the recess 124, the recess 124 has an upper surface spaced from the top surface of the pad 118 by a distance which is greater than the thickness of the thickest coin. An upstream outer wall 126 of the recess 124 extends downwardly to the lowermost surface 128 of the queuing head 112, which is preferably spaced from the top surface of the pad 118 by a distance (e.g. , 0.010 inch) which is significantly less (e.g. , 0.010 inch) than the thickness of the thinnest coin. Consequently, the initial radial movement of the coins is terminated when they engage the upstream outer wall 126 of the recess 124, though the coins continue to move circumferentially along the wall 126 by the rotational movement of the pad 118.
A ramp 127 is formed at the downstream end of the outer wall 126. Coins which are engaged to the wall 126 prior to reaching the ramp 127 are moved by the rotating pad 118 into a channel 129. For example, the coin T at approximately the 12 o'clock position in FIG. 6 will be moved by the rotating pad 118 into the channel 129. However, those coins which are still positioned radially inward from the outer wall 126 prior to reaching the ramp 127 engage a recirculation wall 131, which prevents the coins from entering the channel 129. Instead, the coins are moved along the recirculation wall 131 until they reach a ramp 132 formed at the upstream end of a land 130.
The only portion of the central opening of the queuing head 112 which does not open directly into the recess 124 is that sector of the periphery which is occupied by the land 130. The land 130 has a lower surface which is co-planar with or at a slightly higher elevation than the lowermost surface 128 of the queuing head 112. Coins initially deposited on the top surface of the pad 118 via its central feed aperture do not enter the peripheral sector of the queuing head 112 located beneath the land 130 because the spacing between the land 130 and the pad 118 is slightly less than the thickness of the thinnest coin.
When a coin has only partially entered the recess 124 (i.e., does not engage the ramp 127) and moves along the recirculation wall 131, the coin is recirculated.
More specifically, an outer portion of the coin engages the ramp 132 on the leading edge of the land 130. For example, a 25 cent coin at approximately the 9 o'clock position in FIG. 6 is illustrated as having engaged the ramp 132. The ramp 132 presses the outer portion of the coin downwardly into the resilient pad 118 and causes the coin to move downstream in a concentric path beneath the inner edge of the land 130 (i.e. , inner periphery of the queuing head 112) with the outer portion of the coin extending beneath the land 130. After reaching the downstream end of the land 130, the coin reenters the recess 124 so that the coin can be moved by the rotating pad 118 through the recess 124 and into the channel 129. To prevent the coins from galling the surface of the land 130 of the queuing head 112 as the outer portion of the coin moves therebeneath, the land 130 is preferably provided with lubricant-filled cavities 146 akin to the cavities 99 in FIG. 2. Like the cavities 99 in FIG. 2, the cavities may have virtually any geometric configuration, including, but not limited to, cylindrical, polygonal, or other closed shape. If desired, the periphery of the closed shape may include both straight lines and curved lines.
Coins which engage the ramp 127 enter the channel 129, defined by the inner wall 131 and an outer wall 133. The outer wall 133 has a constant radius with respect to the center of the disc 114. Since the distance between the upper surface of the channel 129 and the top surface of the rotating pad 118 is only slightly less than the thickness of the thinnest coin, the coins move downstream in a concentric path through the channel 129. To prevent galling of the surface of the channel 129 as the coins move downstream therethrough, the channel 129 is provided with the lubricant- filled cavities 146. While moving downstream, the coins maintain contact with the outer wall 133. At the downstream end of the channel 129, the coins move into a spiral channel 134 via a ramp 141. The distance between the upper surface of the spiral channel 134 and the top surface of the pad 118 is slightly greater than the thickness of the thickest coin, thereby causing the coins to maintain contact with an outer spiral wall 137 of the channel 134 while moving downstream through the channel 134. The spiral channel 134 guides the coins to an exit channel 136. At the downstream end of the outer spiral wall 137, i.e., at the point where the spiral wall 137 reaches its maximum radius, the coins engage a ramp 139 which presses the
coins downwardly into the resilient surface of the rotating pad 118. The outer edges of coins which are against the outer wall 137 have a common radial position and are ready for passage into the exit channel 136. Coins whose radially outer edges are not engaged by the ramp 139 engage a wall 138 of a recycling channel 140 which guides such coins back into the entry recess 124 for recirculation.
The spiral channel 134 strips apart most stacked or shingled coins entering the channel 134 from the channel 129. While a pair of stacked or shingled coins are moving through the channel 129, the combined thickness of the stacked or shingled coins is usually great enough to cause the lower coin in that pair to be pressed into the resilient pad 118. As a result, that pair of coins will be rotated concentrically with the disc through the channel 129 and into the channel 134. Because the inner wall 135 of the channel 134 spirals outwardly, the upper coin will eventually engage the upper vertical portion of the inner wall 135, and the lower coin will pass beneath the wall 135 and beneath the land 130. This lower coin will then be rotated concentrically with the disc beneath the land 130 and recirculated back to the entry recess 124 of the queuing head 112. If, however, the combined thickness of the stacked or shingled coins is not great enough to cause the lower coin in the pair to be pressed into the pad 118 (e.g., two very thin foreign coins), the coins are stripped apart in the exit channel 136 as described below. The exit channel 136 causes all coins which enter the channel 136, regardless of different thicknesses and/or diameters, to exit the channel 136 with a common edge (the inner edges of all coins) aligned at the same radial position so that the opposite (outer) edges of the coins can be used for sorting in the circular sorting device 122. The upper surface of the channel 136 is recessed slightly from the lowermost surface 128 of the queuing head 112 so that the inner wall 142 of the channel 136 forms a coin-guiding wall. This upper surface, however, is close enough to the pad surface to press coins of all denominations into the resilient pad 118. While the rotating pad 118 moves the coins through the exit channel 136, the lubricant-filled cavities 146 prevent the coins from galling the surface of the exit channel 136.
As coins are advanced through the exit channel 136, they follow a path that is concentric with the center of rotation of the disc 114 in FIG. 5 because the coins of
all denominations are continuously pressed firmly into the resilient disc surface. Because the coins are securely captured by this pressing engagement, there is no need for an outer wall to contain coins within the exit channel 136. The inner edges of coins of all denominations eventually engage the inner wall 142, which then guides the coins outwardly to the periphery of the disc. As can be seen in FIG. 6, a downstream section of the inner wall 142 of the exit channel 136 forms the final gaging wall for the inner edges of the coins as the coins exit the queuing head 112.
The exit channel 136 strips apart stacked or shingled coins which are not stripped apart by the spiral channel 134. The combined thickness of any pair of stacked or shingled coins is great enough to cause the lower coin in that pair to be pressed into the resilient pad 118. Consequently, that pair of coins will be rotated concentrically with the disc. Because the inner wall 142 of the exit channel 136 spirals outwardly, the upper coin will eventually engage the upper vertical portion of the inner wall 142, and the lower coin will pass beneath the wall 142. This lower coin will be passed into a recirculating channel 144, which functions like the entry recess 124 to guide the coin downstream into the channel 129.
In the preferred embodiment, the queuing device 110 is used to feed the circular sorting device 122 (see FIG. 5). Thus, in FIG. 6 the coins are sorted by passing the coins over a series of apertures formed around the periphery of a coin- guiding member in the form of a stationary sorting plate or disc 150. The apertures 152a- 152h are of progressively increasing radial width so that the small coins are removed before the larger coins. The outboard edges of all the apertures 152a-152h are spaced slightly away from a cylindrical wall 154 extending around the outer periphery of the disc 150 for guiding the outer edges of the coins as the coins are advanced over successive apertures. The disc surface between the wall 154 and the outer edges of the apertures 152a-152h provides a continuous support for the outer portions of the coins. The inner portions of the coins are also supported by the disc 150 until each coin reaches its aperture, at which point the inner edge of the coin tilts downwardly and the coin drops through its aperture. Before reaching the aperture 152a, the coins are radially moved slightly inward by the wall 154 to insure accurate positioning of the coins after they are transferred from the queuing device 110 to the circular sorting device 122.
To advance the coins along the series of apertures 152a-152h, the upper surfaces of the coins are engaged by a resilient rubber pad 156 attached to the lower surface of a coin-driving member in the form of a rotating disc 158 (FIGS. 7 and 8). As viewed in FIG. 6, the disc 158 is rotated clockwise. Alternatively, the pad 156 in FIGS. 7 and 8 may be substituted with a resilient rubber ring attached to the outer periphery of the lower surface of the rotating disc 158. The lower surface of the rubber pad 156 is spaced sufficiently close to the upper surface of the disc 150 that the rubber pad 156 presses coins of all denominations, regardless of coin thickness, firmly down against the surface of the disc 150 while advancing the coins concentrically around the peripheral margin of the disc 150. Consequently, when a coin is positioned over the particular aperture 152 through which that coin is to be discharged, the resilient rubber pad 156 presses the coin down through the aperture (FIG. 8).
To prevent the coins from galling the upper surface of the metal disc 150 as the rotating pad 156 advances the coins around the peripheral margin of the disc 150, the disc 150 is provided with lubricant-filled cavities or holes 162 in the peripheral region of the disc 150. As coins slide over these cavities 162, minute amounts of the lubricant are dragged from the cavities 162 onto the passing coins. A portion of this lubricant is then transferred from the coins to the solid surfaces of the stationary sorting disc 150 that engage the coins. The end result is a significant reduction in the coefficient of friction between the coins and the disc 150, which in turn minimizes galling of the disc 150.
As can be seen in FIG. 6, an arc-shaped section of the stationary disc 150 is cut away at a location adjacent the queuing device 110 to permit a smooth transition between the exit channel 136 and sorting device 122. Because of this cut-away
"section, coins which are advanced along the exit channel 136 formed by the queuing head 112 are actually engaged by the rubber pad 156 before the coins completely leave the disc 114. As each coin approaches the periphery of the disc 114, the outer portion of the coin begins to project beyond the disc periphery. This projection starts earlier for large-diameter coins than for small-diameter coins. As can be seen in FIG. 7, the portion of a coin that projects beyond the disc 114 eventually overlaps the support surface formed by the stationary sorting disc 150. When a coin overlaps
the disc 150, the coin also intercepts the path of the rubber pad 156. The outer portion of the coin is engaged by the rubber pad 156 (FIG. 7).
Each coin is positioned partly within the queuing device 110 and partly within the sorting device 122 for a brief interval before the coin is actually transferred from the queuing device 110 to the sorting device 122. As can be seen in FIG. 6, the coin-guiding inner wall 142 of the exit channel 136 in the queuing head 112 begins to follow an extension of the inner surface 154a of the wall 154 at the exit end of the queuing head 112, so that the inboard edges of the coins on the disc 114 (which become the outboard edges of the coins when they are transferred to the disc 150) are smoothly guided by the inner wall 142 of the exit channel 136 and then the inner surface 154a of the wall 154 as the coins are transferred from the disc 114 to the disc 150.
As previously stated, the exit channel 136 has such a depth that the coins of all denominations are pressed firmly down into the resilient pad 118. The coins remain so pressed until they leave the queuing device 110. This firm pressing of the coins into the pad 118 ensures that the coins remain captured during the transfer process, i.e., ensuring that the coins do not fly off the disc 114 by centrifugal force before they are transferred completely to the stationary disc 150 of the sorting device 122. To facilitate the transfer of coins from the disc 114 to the disc 150, the outer edge portion of the top surface of the disc 150 is tapered at 160 (see FIG. 7). Thus, even though the coins are pressed into the pad 118, the coins do not catch on the edge of the disc 150 during the coin transfer.
In an alternative embodiment illustrated in FIG. 22, the lubricant-filled cavities 146 and 162 are substituted with elongated self-lubricating plugs or inserts ~ 146' and 162' akin to the inserts 99' in FIG. 21. These inserts 146' and 162' are press-fit into shallow cavities machined into the surface of the respective stationary queuing head 112 and the stationary disc 150. As depicted in FIG. 22, the queuing head 112 preferably contains two radially-overlapping inserts 146' just upstream from the channel 129 and two radially-overlapping inserts 146' just upstream from the exit channel 136. The stationary disc 150 preferably contains two radially-overlapping inserts 162' just upstream from the exit aperture 152a. Each radially-overlapping
pair of graphite-loaded inserts targets the inner and outer edges of the various coins moving over the inserts.
In yet another alternative embodiment, the disc-to-disc type coin sorter in FIG. 5 is used in connection with one of the lubrication distribution systems 300, 300' in respective FIGS. 27 and 29. The stationary queuing head 112 and the stationary disc 150 are provided with either (1) porous discharge inserts akin to the inserts 302 in FIG. 26; (2) narrow holes akin to the holes 362 in FIG. 30; or (3) holes fitted with capillary tubes akin to the capillary tubes 364 in FIG. 31. The locations of these elements is similar to the locations of the self-lubricating plugs 146' and 162' in FIG. 22. Since the coin-guiding surface of the stationary disc 150 is the upper surface of that disc 150, the lubrication distribution system is provided with a conventional pressure control to counteract gravity and force the lubrication fluid through the porous discharge inserts, narrow holes, or capillary tubes to the upper coin-guiding surface of the stationary disc 150. This pressure control insures that the lubrication fluid is present at the coin-guiding surface. Furthermore, the interconnect tubing associated with the lubrication distribution system is divided into a number of branches corresponding to the number of employed porous discharge inserts, holes, or capillary tubes.
The embodiments described and illustrated in connection with FIGS. 1-8, 21, 22, 25, 26, 30, and 31 focus on coin handling devices of the type which use a resilient rotating disc and a stationary plate for handling coins of mixed denominations. The present invention, however, may also be employed with coin handling devices of the type which use a stationary sorting rail and a drive belt for moving coins along the sorting rail. One such coin handling device is illustrated in FIGS. 9-19.
Referring first to FIG. 9, a hollow cylinder 210 receives coins of mixed denominations and feeds them onto the top surface of a rotatable disc 211 mounted for rotation on the output shaft (not shown) of an electric motor 212. The disc 211 comprises a resilient pad 213, preferably made of a resilient rubber or polymeric material, bonded to the top surface of a solid metal plate 214.
As the disc 211 is rotated, the coins deposited on the top surface thereof tend to slide outwardly over the surface of the pad 213 due to centrifugal force. As the
coins move outwardly, they engage either the inside wall of the cylinder 210 or a queuing head 215 mounted over a peripheral portion of the disc 211 from about the 8 o'clock position to about the 1 o'clock position (see FIG. 10).
The queuing head 215 delivers a single layer of coins in a single file to a coin-guiding member in the form of a sorting rail 216 (FIG. 9). The sorting rail 216 sorts the coins by size. A coin-driving member in the form of a drive belt 217, driven by an electric motor 218, drives the coins along the sorting rail 216.
As the disc 211 is rotated (in the clockwise direction as viewed in FIG. 10), coins adjacent the cylinder 210 are carried into engagement with the entry end 220 of the queuing head 215. Coins can be rotated beneath the queuing head by entering a channel 221 having converging inner and outer walls 222 and 223. The inner wall 222 spirals outwardly (relative to the center of the disc 211) to about the 12 o'clock position, and then continues along a straight tangential line which crosses the periphery of the disc 211 at about the 1 o'clock position. The outer wall 223 has a constant radius from about 8 o'clock to about 9 o'clock, then spirals inwardly from 9 o'clock to about 11 o'clock to form a channel with converging walls in that region of the queuing head. Beyond the 11 o'clock position, the outer wall 223 parallels the inner wall 222, thereby forming a channel of constant width.
The lowermost surface 224 of the queuing head 215 is preferably spaced from the top surface of the pad 213 by only a few thousandths of an inch, so that coins cannot escape from the channel 221 by passing beneath the outer wall 222, and so that coins cannot enter the channel 221 from the inner periphery 225 of the head 215.
The lowermost surface 224 of the queuing head 215 forms a land 226 along the entire inner edge of the head. The upstream end of the land 226 forms a ramp 227 which presses any coin brought into engagement therewith downwardly into the resilient pad 213, which causes the engaged coin to be recirculated. More specifically, coins which are pressed down into the pad 213 by the ramp 227, such as the coin Cl in FIG. 10, are carried along a path of constant radius beneath the land 226, while the inner edge of the head 215 spirals outwardly from the center of the disc 211. Eventually, therefore, the coin is rotated clear of the inner edge of the head 215 and is then free to move outwardly against the cylinder 211 and to be recirculated to the entry end 220 of the head 215.
The channel 221 causes all coins which enter the channel, regardless of different thicknesses and/or diameters, to exit the channel with a common edge (the inner edges of all coins in FIGS. 9-16) aligned at the same position so that the opposite (outer) edges of the coins can be used for sorting. As can be seen in FIG. 10, the tangential portion of the inner wall 222 at the exit end of the queuing head 215 forms the final gaging wall for the inner edges of the coins as the coins exit the queuing head.
A major portion of the inwardly spiraling portion of the wall 223 is tapered, as at 223a, to enable the outer portions of the coins to pass under that wall as the channel 221 converges to a width that is smaller than the diameters of the respective coins. The region 228 immediately outboard of the wall 223 presses the portions of all coins extending outwardly beyond the wall 223 down into the resilient pad 213, thereby tilting the inner edges of the coins upwardly into firm engagement with the gaging wall 222 (FIGS. 11-15). At about the 12 o'clock position, as viewed in FIG. 10, the walls 222 and 223 both extend along lines which are tangents to the arcs defining the respective walls just before the 12 o'clock position. These tangential walls guide the coins off the disc 211 to the desired coin-receiving device such as a coin-sorting or coin-wrapping mechanism. To ensure stability of the coins as they leave the rotating disc 211, the depth of the channel between the walls 222 and 223 is reduced at 230 so that the tangential portion of that channel (beyond the 12 o'clock position) is shallower than the thickness of the thinnest coin. Consequently, the coins of all denominations are pressed firmly into the resilient pad 213 as the coins leave the disc.
The sorting rail 216 and the drive belt 217 are shown in more detail in FIGS. 16-19. The sorting rail 216 comprises an elongated plate which forms a series of coin exit channels 251, 252, 253, 254, 255 and 256 which function to discharge coins of different denominations at different locations along the length of the plate. The top surface of the sorting rail 216 receives and supports the coins as they are discharged from the disc 211. Because the coins are pressed into the resilient surface of the disc 211, the top surface of the sorting rail 216 is positioned below the lowest coin-engaging surface of the head 215, at the exit end thereof, by about the thickness of the thickest coin. If desired, the entry end of the sorting rail 216 may be tapered
slightly to facilitate the transfer of coins from the disc 211 to the sorting rail 216.
The coins are advanced along the sorting rail 216 by a drive belt 217 which presses the coins down against the sorting rail 216. As can be seen in FIG. 16, the exit end of the head 215 is cut out to allow the belt 217 to engage the upper surfaces of the coins even before they leave the disc 211. The aligned edges of the coins follow a gaging wall 258 which is a continuation of the wall 222 in the queuing head 215 and is interrupted only by the exit channels 251-256. The side walls of the exit channels 251-256 intersect the gaging wall 258 at oblique angles so that the driving force of the belt 217 on the upper surfaces of the coins drives the coins outwardly through their respective exit channels 251-256.
To prevent the coins from galling the surface of the sorting rail 216 as they are advanced along the rail 216 by the drive belt 217, the rail 216 is provided with lubricant-filled cavities 268 akin to the lubricant-filled cavities 99, 146, and 162 in FIGS. 2 and 6. As the coins pass over these cavities 268, the coins drag minute amounts of lubricant from the cavities 268 and distribute a portion of this lubricant across the surface of the sorting rail 216. The end result is a significant reduction in the coefficient of friction between the coins and the surface of the sorting rail 216. In an alternative embodiment of the sorting rail 216, the lubricant-filled cavities 268 are substituted with a radially-overlapping pair of self-lubricating inserts 268' (FIG. 23) akin to the inserts 99', 146', and 162' in FIGS. 21 and 22. In yet another alternative embodiment, the sorting rail 216 is used in connection with one of the lubrication distribution systems 300, 300' in respective FIGS. 27 and 29. The sorting rail 216 is provided with either (1) porous discharge inserts akin to the inserts 302 in FIG. 26; (2) narrow holes akin to the holes 362 in FIG. 30; or (3) holes fitted with capillary tubes akin to the capillary tubes 364 in FIG. 31. Since the coin- guiding surface of the sorting rail 216 is the upper surface of that rail 216, the lubrication distribution system is provided with a conventional pressure control to counteract gravity and force the lubrication fluid through the porous discharge inserts, narrow holes, or capillary tubes to the upper coin-guiding surface of the sorting rail 216.
The drive belt 217 has a resilient outer surface 259 (FIG. 19) which is positioned close enough to the top surface of the sorting rail 216 to press all the coins
firmly against the sorting rail 216. This capturing of the coins between the belt 217 and the sorting rail 216 holds the coins precisely in the same relative positions established by the queuing device, with the aligned edges of the coins riding along the gaging wall 258. Consequently, the positions of the opposite edges (the upper edges as viewed in FIG. 16) of the coins are uniquely determined by the respective diameters of the coins, so that each denomination of coin will be intercepted by a different exit channel. The resilient surface of the belt 217 ensures that each coin is pressed down into its respective exit channel, and that each coin is exited from the sorting rail 216 by the driving force of the belt 217 urging the coin against the longer (forward) side wall of its exit channel.
The inlet ends of successive exit channels 251-256 are located progressively farther away from the line of the gaging wall 258, thereby receiving and ejecting coins in order of increasing diameter. In the particular embodiment illustrated, the six channels 251-256 are positioned and dimensioned to successively eject the six United States coins in order of increasing size, namely, dimes (channel 251), pennies (channel 252), nickels (channel 253), quarters (channel 254), dollars (channel 255), and half dollars (channel 256). The inlet ends of the exit channels 251-256 are positioned so that only one particular denomination can enter each channel; the coins of all other denominations reaching a given exit channel extend laterally beyond the inlet end of that particular channel so that those coins cannot enter the channel and, therefore, continue on to the next exit channel.
For example, the first exit channel 251 is intended to discharge only dimes, and thus the inlet end 251a of this channel is spaced away from the gaging wall 258 by a distance that is only slightly greater than the diameter of a dime. Consequently, only dimes can enter the channel 251. Because one edge of all denominations of coins engages the gaging wall 258, all denominations other than the dime extend beyond the inlet end 251a of the channel 251, thereby preventing all coins except the dimes from entering that particular channel.
Of the coins that reach channel 252, only the pennies are of small enough diameter to enter that exit channel. All other denominations extend beyond the inlet end of the channel 252 so that they remain gripped between the sorting rail and the resilient belt. Consequently, such coins are rotated past the channel 252 and continue
on to the next exit channel.
Similarly, only nickels can enter the channel 253, only quarters can enter the channel 254, only dollars can enter the channel 255, and only half dollars can enter the channel 256. In the particular embodiment of the sorting rail 216 shown in FIGS. 16-19, the exit channels 251-256 are narrower at the entry ends than at the exit ends. The change in channel width occurs at the gaging wall 258. The narrowing of the channels at their entry ends provides a wider coin-support area between each pair of adjacent exit channels, which helps prevent undesired tilting of coins as they pass over successive exit channels. Undesired tilting of coins can result in missorting.
As can be seen in FIG. 18, the bottom wall of each of the exit channels 251- 256 is tapered across the width of the channel, so that the maximum depth is along the longer, forward side wall of the channel. This tapering of the bottom wall causes the coins to tilt as they are being exited through the channels 251-256, thereby ensuring engagement of each coin with the forward side wall of its respective channel. This further ensures that each coin will remain in the desired exit channel, avoiding missorting.
As shown in FIG. 19, the drive belt 217 preferably has a laminated construction. The inside surface of the belt is made of a layer 217a of relatively hard material, forming a toothed surface for positive engagement with both a driven pulley 260a and an idler pulley 260b depicted in FIG. 18. The thick central layer 217b of the belt is made of a relatively soft, resilient material, such as a closed-cell foam polymer. The outer surface of the belt which engages the coins is formed by a thin layer 217c of a tough flexible polymer which can conform to the shapes of the coins (see FIG. 19) and yet withstand the abrasive effect of coins sliding across the belt as they are exited through the channels 251-256.
The sorting rail 216 in FIG. 17 contains the exit channels 251-256 for discharging coins of different denominations. In an alternative embodiment shown in FIG. 20, the exit channels 251-256 of the sorting rail 216 are substituted with exit apertures 251'-256'. Since the exit apertures 251 '-256' sort and discharge coins in similar fashion to the apertures 152a-152h in FIG. 6, the operation of the apertures 251 '-256' is not described in detail herein. It suffices to state that the coins are
sorted by passing the coins over the series of apertures 251 '-256' formed adjacent to the gaging wall 258'. The apertures 251 '-256' are of progressively increasing lateral width so that the small coins are removed before the larger coins. The lower edges of all the apertures 251 '-256' (as viewed in FIG. 20) are spaced slightly away from the gaging wall 258' for guiding the lower edges of the coins as the coins are advanced over successive apertures. The rail surface between the gaging wall 258' and the lower edges of the apertures 251 '-256' provides a continuous support for the lower portions of the coins. The lower portions of the coins are also supported by the rail 216' until each coin reaches its aperture, at which point the lower edge of the coin tilts downwardly and the coin drops through its aperture.
To prevent the coins from galling the surface of the sorting rail 216', the sorting rail 216' may either be provided with lubricant-filled cavities 270 (FIG. 20) or self-lubricating inserts 270' (FIG. 24). Also, the sorting rail 216' may be employed with one of the lubrication distribution systems 300, 300' in respective FIGS. 27 and 29.
As described above, the coin handling devices in FIGS. 1-26, 30, and 31 employ a variety of lubrication techniques to reduce the coefficient of friction between the coins and the surface of a stationary coin-guiding member of the coin handling device as the coins are moved along the surface by a movable coin-driving member. The coin-driving member has a resilient surface for engaging the coins and driving the engaged coins along the surface of the stationary member. As stated above, the stationary coin-guiding member varies in accordance with the type of coin handling device manipulating the coins. For example, the disc-type coin sorter in FIGS. 1-4, 21, 25, 26, 30, and 31 includes the stationary sorting head 12, and the coin-driving member for moving coins along the surface of this sorting head 12 is the rotating disc 13. The disc-to-disc type coin sorter in FIGS. 5-8 and 22 includes the stationary queuing head 112, and the coin-driving member for moving coins along the surface of this queuing head 112 is the rotating disc 114. The disc-to-disc type coin sorter in FIGS. 5-8 and 22 further includes the stationary sorting disc 150, and the coin-driving member for moving coins along the surface of this sorting disc 150 is the rotating disc 158 with resilient pad 156. The rail-type coin sorter in FIGS. 9-19 and 23 includes the stationary sorting rail 216, and the coin-driving member for
moving coins along the surface of the sorting rail 216 is the drive belt 217. Finally, the modified rail-type coin sorter in FIGS. 20 and 24 includes the stationary sorting rail 216', and the coin-driving member for moving coins along the surface of the sorting rail 216' is the drive belt 217. In each of the coin handling devices of FIGS. 1-20, the lubricant-filled cavities are preferably disposed in one or more regions where the stationary coin- guiding member presses the coins into the resilient surface of the coin-driving member. Moreover, the lubricant-filled cavities are strategically positioned in the coin-guiding member at locations targeting the inner and outer edges of the various coins moving along the surface of the stationary coin-guiding member. In the alternative coin handling devices of FIGS. 21-26, 30, and 31 , the self-lubricating inserts (FIGS. 21-24), the porous discharge inserts (FIGS. 25-26), the lubricant- supplied narrow holes (FIG. 30), and the lubricant-supplied capillary tubes (FIG. 31) are preferably disposed at one or more locations just upstream from high pressure regions. At each location one or more of these elements are positioned to target the inner and outer edges of the various coins moving along the surface of the stationary coin-guiding member. The lubrication techniques described herein effectively reduce the friction between the coins and the stationary coin-guiding member as the resilient surface of the coin-driving member moves the coins along the coin-guiding member. This reduced friction, in turn, minimizes galling of the coin-guiding member.
In an alternative embodiment, a gall-resistant coating is applied to the coin- guiding surface of the coin-guiding member. In particular, the gall-resistant coating is applied to the lower surface of the stationary sorting head 12 of the disc-type coin sorter in FIGS. 1-4, 21, 25, 26, 30, and 31. Similarly, the coating is applied to the lower surface of the stationary queuing head 112 and to the upper surface of the stationary sorting disc 150 of the disc-to-disc type coin sorter in FIGS. 5-8 and 22. Finally, the coating is applied to the upper surface of the sorting rails 216 and 216' of the rail-type coin sorters in FIGS. 9-20, 23, and 24. The gall-resistant coating may be employed in place of or in addition to the other lubrication techniques described herein.
In one embodiment, the gall-resistant coating is a solid film lubricant which lubricates effectively over the operating temperature range of the coin handling
devices. The solid film lubricant should have superior chip resistance and wear life and should have a low coefficient of friction. A "solid film lubricant" is defined herein as a thin film of resin which binds solid lubricating particles to a surface. In connection with the coin handling devices in FIGS. 1-26, 30, and 31, the lubricating particles are bound to the surfaces of the coin-guiding members. These lubricating particles then prevent surface-to-surface contact between the coins and the coin- guiding members and thus reduce friction and wear between these surfaces.
In the preferred embodiment, the solid film lubricant is EVERLUBE® 6111 solid film lubricant produced by E/M Corporation of West Lafayette, Indiana. The EVERLUBE® 6111 lubricant has a pencil hardness of 4H (ASTM D-3363) and a coefficient of friction of 0.06. This solid film lubricant uses an epoxy binder to bind polytetrafluoroethane (PTFE) and molybdenum disulfide lubricants to the surface of the coin-guiding members of the various coin handling devices in FIGS. 1-24. The solid film lubricant may be applied to the coin-guiding members by spraying, dipping, brushing, spray /tumbling, or dip/tumbling. The lubricant achieves optimum wear properties when applied to a total thickness between 0.0002 and 0.0005 inches. In another embodiment, the gall-resistant coating is formed on the surface of the coin-guiding members by subjecting the coin-guiding members to NITROTEC™ surface treatments performed by Ipsen Commercial Heat Treating of Rockford, Illinois. The coin-guiding members are gaseous nitrocarburized, polished, and then oxidized to yield a surface with a low coefficient of friction and long wear life. The NITROTEC™ process is described in detail in European Patent No. 0 077 627 A2 entitled "Corrosion Resistant Steel Components and Method of Manufacture", published April 27, 1983, and incorporated herein by reference. While the present invention has been described with reference to one or more particular embodiments, those skilled in the art will recognize that many changes may be made thereto without departing from the spirit and scope of the present invention. For example, the various lubrication techniques described above may be used in combination with each other, especially in situations where the galling problem is particularly prevalent. Each of these embodiments and obvious variations thereof is contemplated as falling within the spirit and scope of the claimed invention, which is set forth in the following claims.