KR20010024574A - Coin acceptor - Google Patents

Abstract

A coin acceptor is a given monetary unit with a range of two metal coins with different metallic areas (21, 22), for example a new British £ 2.00 coin (8), each having its own characteristic characteristics. It is configured to detect coins of. This receiver has a coin detector (4) with sensing coil units (C3a, b) having a coil face (30) through which the coin (8) passes and substantially guides the outer area (22) of the coin selectively. Form a bond. The area of the coil face 30 is less than 72 mm ² .

Description

Coin acceptor

Coin acceptors are well known for identifying coins of different denominations, an example of which is described in Applicant's British Patent Application Publication No. 2,169,429. The coin acceptor passes coins along the peripheral edge surface so that the coils pass through a sensing section where the coils perform a series of induction tests on the major surfaces of the coin to generate coin parameter signals indicative of the material and metal content of the coin being inspected. A coin rundown path is provided. Coin parameter signals are digitized to provide digital coin parameter data, and the digitized data is compared with the coin data stored by the microprocessor to determine whether to accept the examined coin. If the coin is acceptable, the microprocessor operates the accept gate to direct the coin to the accept path. Otherwise, the receiving gate does not work and the coin is directed to the reject path.

Stored coin data represents the permissible values of coin parameter data. Theoretically stored data can be represented again as a single digital value, but in practice, the coin parameter data differs from coin to coin because of differences in the coins themselves, and thus usually corresponds to windows of allowable values of coin parameter data. Save window data. The width of the windows is a compromise between many factors. In order to achieve a satisfactory identification between real and fake coins, the window widths should be made as narrow as possible. However, if the windows are too narrow, there is a risk that real coins will be rejected as a result of minor differences between the characteristics of real coins.

For example, there is a growing popularity to cast coins to have regions of more material than one metal or metal alloy, and some monetary coins have a central region of the first alloy and a second other. It is made in a form surrounded by at least one annular region of the alloy (hereinafter referred to as "bimet" coin). Different regions exhibit different inductive characteristics with respect to the sense coils of the receiver. Inductive sensing devices deliver eddy currents to a wide range of coins over different areas of the coin. This allows the conductive and transmissive properties of the different metal regions of the coin to be sensed as a result of mixing, blurring the judgment provided by such sensing coils. As an example, the new British Bimetale £ 2.00 coin can make a similar judgment for some non-bimeth coins in the case of conventional sensing devices.

Another feature of bimetal coins is that the coupling between the first and second regions has variable electrical properties. Electrical connections vary with production, aging, impact and liquid contamination.

These factors make the receiving window for coin receivers using conventional inductive sensors wider than desired for bimethic coins, and these wide windows allow other coins and objects to be unacceptably accepted as real coins. This greatly reduces the guarantee and performance of the coin verification process.

The use of a coil beneath a coin rundown path with a face looking upwards at the surrounding corners has been proposed in EP-A-0, 780, 810. In practice, however, this configuration is sensitive to the position of the coin with respect to its width. Coins can move left and right in the coin rundown path, changing the inductive coupling with the underlying coil to fake when moving along the rundown path, leading to unreliable results.

The present invention relates to a coin receiver, and more particularly to a receiver for coins with regions of different electrical inductive properties, for example coins of two metals.

In order that the invention may be more fully understood, embodiments of the invention will now be described by way of example with reference to the accompanying drawings, in which:

1 is a schematic front view of a coin container according to the present invention;

FIG. 2 schematically shows the electrical circuits of the receiver shown in FIG. 1,

3 is a schematic partial cross-sectional view of the receiver taken along line A-A 'of FIG. 1;

4 is an explanatory view corresponding to FIG. 3 for explaining the flow coupling between the coils C3a, b through the outer annulus of the coin being examined;

5 shows the end of coil C3a facing the coin under test,

FIG. 6 is a schematic diagram corresponding to FIG. 1 of another embodiment of a coin container in accordance with the invention.

For the purpose of overcoming this problem, the present invention provides a method for detecting coins of a given monetary value of money, each having a major surface with inner and outer regions exhibiting unique induction characteristics, wherein only substantially the outer region is selectively selected. It is configured to form an inductive coupling, and provides a method comprising passing the coin through a coin sensing unit having a sensing coil unit having a surface facing the main surface of the coin.

Thus, the inductive coupling can optionally be formed between the coil unit and the outer region of the coin, and the coin certainty indicates whether the inductive coupling has predetermined characteristics corresponding to the unique characteristics for the outer region for the real coin. Tested by judgment.

According to the invention, if the sensing coil unit has an area of less than 72 mm ² towards the coin to be identified, selective identification can actually be obtained for many coins with regions of different induction characteristics.

An additional sensing device for detecting the characteristics of the coin is used in the method according to the invention. The additional sensing device includes an additional sensing coil unit to allow an inductive coupling between the coin and the further sensing device. The induction characteristic of only the inner region of the coin is selectively detected using an additional sense coil unit.

Alternatively or additionally, the method comprises the step of detecting the induced characteristics of all said regions of the coin using an additional sense coil unit.

The method according to the invention is used to identify bimethic coins such as British coin # 2.00.

The present invention provides a method for detecting coins of a given monetary value with regions representing respective unique induction characteristics, each method comprising: first and second configured to selectively form inductive coupling with one of the regions; Passing the coin through the coin sensing unit with second sensing coil units, selectively detecting substantially one of the inductive properties of the regions using the first coil unit, and using the second coil unit Selectively detecting substantially different inductive characteristics of said regions.

The present invention also provides a coin acceptor for detecting coins of a given monetary unit amount having a major surface having an inner region and an outer region exhibiting unique induction characteristics, the coin acceptor comprising: a coin path; And a sensing coil unit having a surface facing a main surface of the coin moving along the coin path, the sensing coil unit configured to selectively form an inductive coupling with an outer region of the regions of the coin.

The area defined by the coil windings is generally circular or rectangular in cross section.

The coin receiver has a coin rundown path between the side walls, and the sensing coil unit is installed on one of the side walls. The sense coil unit has two coil assemblies on opposite sides of the coin rundown path even though a single coil is used.

The coin receiver has an additional one or more sense coil units, optionally in inductive coupling with the other of the regions of the coin. The sense coil units are arranged in an array.

The coin acceptor shown in FIGS. 1 to 5 includes a multi-coin acceptor capable of identifying coins of many other monetary amounts, including bimethic coins, eg, a set of British coins containing the new Bimet £ 2.00 coin. .

The physical structure of the coin receiver is schematically shown in FIG. The coin container has a body (1) having a coin rundown path (2) where coins to be examined pass from the entrance (3) through the coin detector (4) along the edge and then fall towards the gate (5). The inspection is carried out for each coin passing through the sensing section 4. If the result of the test indicates that a real coin is present, the gate 5 is opened to allow the coin to enter the receiving path 6, otherwise the gate remains closed and the coin is rejected. Will go out. The coin path for the coin 8 through the receiver is schematically shown by the dashed line 9.

The coin detector 4 has three sense coil units C1, C2a, b, C3a, b shown in dashed lines, which sense coil units are energized to generate a coin and an inductive coupling. Further, the fourth coil unit C4 is provided in the receiving path 6 downstream of the gate 5 in order to detect whether the coin which has been determined to be acceptable has actually passed through the receiving path 6.

The coils are of different geometries and are driven at different frequencies by the drive and interface circuit 10 shown in FIG. 2. Eddy currents are induced by the coil arrangements on the coin under test. The other inductive couplings between the three coils and the coin characterize the coin substantially uniquely. The drive and interface circuit 10 generates three corresponding coin parameter data signals x1, x2, x3 as a function of different inductive couplings between the coin and coil units C1, C2, C3. The corresponding signal x4 is generated to the coil unit C4. Coin parameter data signals x1, x2, x3 and x4 can be formed in many other known ways. One method is detailed in Applicant's British Patent Application Publication Nos. 2, 169, 429, where coils are provided in individual resonant circuits maintained at a natural resonant frequency as the coin passes through the coil. This frequency deviates temporarily as a result of a momentary change in the impedance of the coil caused by inductive coupling with the coin. This change in impedance creates a shift in both amplitude and frequency. This is monitored and digitized to provide the coin parameter signal x for each coil, as described in the applicant's above specification. By maintaining the drive frequency for the coil at its natural resonant frequency while the coin passes through the coil, the amplification shift is emphasized to help identify between the coins. However, the coin parameter signal x can be formed in other ways, for example, by monitoring the frequency shift generated when the coin passes through the coil, as described in British Patent Application Publication Nos. 1,452,740. See.

In order to determine the credibility of the coin, the three parameter signals x1, x2, x3 generated by the coin to be examined are supplied to the microcontroller 11 coupled to the memory in the form of an EEPROM 12. The microcontroller 11 compares the coin parameter signals derived from the coin under test with the corresponding stored values held in the EEPROM 12. Stored values are stored in a window format with upper and lower limits. Thus, if the individual coin parameter signals x1, x2, x3 are in corresponding windows relating to the true coin of a particular monetary amount, the coin is marked acceptable, otherwise it is rejected. If acceptable, a signal is provided to the drive circuit 14 via line 13, which drives the gate 5 shown in FIG. 1 to allow coins to pass through the receiving path 6. Activate If not, the gate 5 does not open and the coin passes through the reject path 7.

The microcontroller applies a plurality of coin parameter data signals x1, x2 and x3 to coins of different monetary amounts so that the coin acceptor can accept or reject more than one coin of a particular currency set. Are compared with the other sets of working window data. If the coin is accepted, the passage of the coin along the receiving path 6 is detected by the coil unit C4, and the coil drive and interface circuit 10 sends the corresponding data x4 to the microcontroller 11. Passing, the microcontroller provides an output that indicates the amount of money that belongs to the coin received via line 15.

The construction of the sensor coils will now be described in more detail.

Referring to FIG. 1, the receiver has a coin entrance 16 hinged to the shaft 17 on the receiver body 1 in a conventional manner. As shown in more detail in FIG. 3, a coin rundown path 2 is provided between the inner wall 18 of the doorway 16 and the wall 19 of the receiver body 1. The rundown path 2 includes a lip 20 inclined to the entrance 16, and the coin rolls down to the lower side of the sloping lip and passes through the sensing coil units C1, C2 and C3. In FIG. 3, the coin 8 is shown on the lip 20 of the rundown path 2. As is known in the art, the doorway 16 is biased with a spring in the closed position shown in Figs. 1 and 3, but if the coin is caught to disengage the caught coin and allow it to fall into the reject passage 7 It is possible to hingeally move outward from the body 1.

Referring again to FIG. 1, the coil unit C1 comprises a coil installed inside the wall 19 of the body 1 and covers the area of the main surface of the coins of different monetary amounts that can be identified by the receiver. In comparison, it comprises a single coil wound around a relatively large area of the circular bobbin not shown. Typically coil unit C1 has an outer diameter of 14 mm and an area of 154 mm ² . When the coin 18 passes through the coil unit C1, the inductive coupling between the coil and the coin changes instantaneously, producing the coin parameter signal x1 as described above. The relatively large area of coil C1 causes the signal to be the average of the induction properties of substantially all major surfaces of the coin examined.

The coil unit C2 includes a pair of coils C2a and C2b electrically connected in series. These coils are respectively wound on the same rectangular bobbins. One of the coil units C2a is installed inside the wall 19 of the receiver body 1, and the other coil unit C2b is installed on the wall 18 opposite the coil C2a of the doorway 16. . Thus, when the coin 8 passes between the coils C2a and C2b, the inductive coupling between the coils is disturbed, generating the coin parameter signal x2 in the manner previously described. The area of the coils C2a and C2b is relatively large compared to the area of the coins of other monetary amounts that can be identified by the coin acceptor, so that the signal is the average of the induction characteristics of substantially all major surfaces of the coin being inspected. Makes it happen. As an example, the surface area of each coil C2a, b is 20 mm, giving an area of 315 mm ² .

As shown in Fig. 1, the coin 8 to be identified includes a bimeth coin, and in this example a new ￡ 2.00 coin. The coin 8 is discoid with opposing major surfaces 8a, 8a 'and a cylindrical, peripheral edge surface 8b. This coin consists of a first centered cupola core region 21 and a second outer circular region or ring of alloy referred to here, comprising bronze comprising 76% Cu, 4% Ni and 20% Zn. (22). These two regions exhibit different inductive characteristics for the sense coil units, and therefore these characteristics are averaged by the coil units C1 and C2a, b. Also, as previously described, the connection between the regions 21 and 22 has different electrical properties for each coin. It affects the values of the signals x1, x2 generated by the coil units C1, C2. As a result, the coil units C1 and C2a, b themselves do not necessarily provide coin parameter signals that satisfactorily identify between £ 2.00 coins and other monetary amounts and fakes. However, this problem is overcome by the provision of the coil units C3a, b according to the invention.

Referring to FIG. 3, the coil units C3a and b may include a pair of coil assemblies C3a and C3b installed in the wall 19 of the receiver body 1 and the wall 18 of the doorway 16. Include. The coil assemblies C3a and C3b selectively form inductive bonds with the bronze ring 22 of the bimetallic coin 8 being examined, i.e., insignificant inductive coupling with the central copper core region 21 of the coin. It is configured to have.

Each of the coil assemblies C3a, b generally comprises a cylindrical bobbin 23 of plastic material, on which a coil winding 24 is formed. The bobbin 23 is push fit into a half pot core 25 made of sintered ferrite material. The half-port core 25 has a cylindrical yoke 26 located in the center formed to have a through hole for reducing the amount of ferrite material used, and a cylindrical support flange 27 positioned at the periphery and concentrically shaped.

As another alternative to the use of bobbins, the coil winding 24 is wound around a bobbin, not shown, which is heated to melt its insulator, so that a self supporting coil is formed during cooling, and then half The press-fit is fitted to the port core 25.

The support flange 27 of the half-port core 25 is press fit to the corresponding recess of the wall, so that the flange 27 of the assembly C3a is press fit to the cylindrical recess 28 of the wall 19. The flange 27 of the assembly C3b is press fit to the corresponding recess 29 of the wall 18. The outer diameter d ₁ of the coil winding 24 is 7.3 mm. The inner diameter d ₂ of the coil 24 together with the bobbin 23 is 2.78 mm, and the hole diameter penetrating the yoke 26 is 2 mm. In this example, the faces 30 of the coil assemblies C3a and b are spaced apart by 6.24 mm. The coils 24 have an axial length of 2.78 mm. The outer diameter d ₃ of the half-port core 25 is 9 mm, so that the area A of the end face 30 of each coil unit, that is, the end face 30 of each coil unit facing the coin to be inspected is In this example, 63.62mm ² . The coil windings 24 of the assemblies C3a and b are electrically connected in series. As can be seen in FIG. 3, the coil assemblies C3a, b are arranged with coils 24 arranged on a common axis B on opposite sides of the coin 8 being inspected. Thus, the common axis B extends across the major surfaces 8a, 8a 'of the tested coin passing between the coils, and the major surface 30 of the coils 24 is the major surfaces of the coin. Avoid (8a, 8a ').

As is well known in the solenoid coil design technique, the magnetic field of a generally cylindrical coil is concentrated along the coil axis, so in each case of the coil assemblies C3a, b the magnetic field is mainly the ferrite of the half-port core 25. The magnetic flux around the coil is concentrated by the yoke 26, and the magnetic flux around the coil is coiled by the peripheral ferrite flange 27 except for the region of the face 30 through which the magnetic material passes through the peripheral material against the yoke 26. It mainly leads to the surrounding loop. Thus, the sensitivity of assemblies C3a, b to passing coins is in most cases limited to the area of coins passing between yokes 26. As shown in Fig. 3, the assemblies C3a, b are located close to the coin rundown path 2, and the coils have a significant coupling between the coin and the inductive coupling between the coils and the first inner region 21. It does not occur and has a dimension d ₃ such that it is substantially limited only to the second outer region 22 of the coin 8. This can be seen more clearly in FIG. 4, which schematically shows the relative dimensions and shape of the coil assemblies C3a, b when the coin 8 passes through the gap between the coils. As can be seen in FIG. 3, the half-port cores 25 extend below the coin rundown path 20 so that the yokes 26 are aligned with the outer ring 22 of the coin 8. do. The coin parameter signal x3 is generated when the coin 8 passes through the coil device C3 and is thus mainly determined by the properties of the bronze region 22 of the ￡ 2.00 coin, and the regions 21, 22) There is no confirmation by the connection between or features of the cuproic core area 21. Thus, the coin parameter signal x3, in combination with the signals xl and x2, provides a set of coin parameter signals that uniquely characterize each of the coins in the British coin set, including £ 2.00 coins.

Judgments from coil assemblies C3a, b were found to be very stable by coils that selectively faced areas of coin that are relatively free of surface irregularities in practical matters.

The described example of the invention is not limited to detecting the £ 2.00 coin of the British coin set, but is generally applicable to the detection of bimet coins and bimetal coins present in the coin set of other countries. Coin data stored in EEPROM 12 may store appropriate window data for related coins or tokens. According to the present invention, improved identification is achieved by making the area A of the coil unit facing the coin, such as coils C3a and b, smaller than 72 mm ² , which allows the coin area to have individual inductive properties to be sensed. It was found possible.

Many variations and modifications are within the scope of the invention. For example, although the coil unit C3 includes a pair of opposing coils C3a, b in the embodiment of FIGS. 1-5, a single coil may be used.

The very or each coil C3 need not be circular. In fact, advantages can be obtained from coils that are square or rectangular wound.

In addition, the coil units C1 and C2 of other shapes may be used depending on the currency to be confirmed. Thus, the coil units C1 or C2, or both, can be located at different positions relative to the coin rundown path 2 as compared to FIG. Moreover, at least one optical coin detector (not shown) may be provided in the rundown path 2 in addition to the coil units C1, 2 or as a substitute for one of these units.

In a variant, the door assembly 16 and the wall 19 of the body 1 allow the coil assemblies C3a, b to be installed in different positions in order to maximize the performance for different sets of calls. A series of recesses 28, 29 for the teeth C3a, b are provided. Alternatively, an incremental adjustment mechanism is provided to allow adjustment of the positions of the coil assemblies C3a, b.

The coil assemblies C3a, b need not only be used to detect the outer area 22 of the coin. 6 shows a variant in which the coil unit C2 is replaced by a coil unit C5 connected in series with the coil assemblies C5a, b corresponding to the assemblies C3a, b. The coil unit C5 is configured to selectively detect the induction characteristics of the first inner region 21 of the bimetal coin 8. When the coin rolls down the path 2, the output xl from the coil C1 is applied to the coil assemblies allowing the inner region 21 of the coin to selectively monitor its engagement with the inner region 21 ( Allow microcontroller 11 to reach its maximum value while passing between C5a, b). The coil surfaces are small enough to allow selective sensing of the area 21. Thus, the coin parameter signal x2 during the time window represents the induction characteristics of the area 21 and is substantially unaffected by the area 22 or the connection between it and the area 21. Do not.

Coil assemblies C3a, b and C5a, b do not necessarily have to be coupled in series as previously described, and to perform other induction tests as described in EP 0, 599, 844. You can change the connections.

In addition, the coil assemblies C3a, b and / or C5a, b need not necessarily be disposed along the lip 20 and may be disposed at other locations within the receiver. The plurality of coil assemblies may be arranged in an array.

In the above embodiments, the detection of British £ 2.00 bimet coin has been described, but the receiver can also be used to detect bimeth coins of other currencies such as Euro. It will be appreciated that areas of the coin with unique characteristics may be formed differently. For example, a coin has more than one ring of different metallic composition. Also, the other areas need not necessarily be rings, but may be other shapes. All of them do not need to be metal. They will not contain coins, such as holes.

Moreover, the areas are other areas of the coin made of a uniform metal composition, for example the US 25 cent coin, which has a very undulating surface in its central area, but smoother in its border area. These different areas exhibit different inductive properties. It can be detected individually according to the invention.

In general, additional coil assemblies corresponding to assemblies C3a, b may be provided at locations that detect substantially preselected areas of the coin being examined to detect their inductive properties substantially only.

As used herein, the term “coin” includes coins, tokens, and related items similar to other coins.

Claims (22)

A method for detecting coins of a given monetary unit amount, each having a major surface with inner and outer regions exhibiting unique induction characteristics, And substantially passing only the coin through a coin detector having a sense coil unit with a surface facing the main surface of the coin, wherein only the outer region is selectively formed to form an inductive coupling. The method of claim 1, further comprising: inductive coupling between the coil unit and the outer region of the coin; And Determining whether the inductive coupling has predetermined characteristics corresponding to the unique characteristics for the outer region. The method according to claim 1 or 2, wherein the surface of the sensing coil unit facing the coin to be identified has an area of less than 72 mm ² . 4. A method according to any one of claims 1 to 3, comprising detecting the characteristics of the coin using an additional sensing device. The apparatus of claim 4, wherein the additional sensing device includes an additional sensing coil unit. Forming an inductive bond between the additional sense coil unit and the coin. 6. A method according to claim 5, further comprising the step of selectively detecting the induction characteristics of only the inner region of the coin using an additional sense coil unit. 6. The method of claim 5, comprising detecting induced characteristics of all said regions of the coin using an additional sense coil unit. A method for detecting coins of a given monetary unit amount with regions representing respective unique induction characteristics, Passing the coin through a coin detector having first and second sense coil units each configured to selectively form an inductive coupling with one of the regions; Selectively detecting substantially one of the inductive characteristics of the regions using a first coil unit; And Selectively detecting substantially different inductive characteristics of said regions using a second coil unit. The method of any one of claims 1 to 8 used to identify bimeth coins. 10. The method according to any one of claims 1 to 9, which is used to identify British £ 2.00 coins. In a coin acceptor for detecting coins of a given monetary unit amount, each having a major surface having an inner region and an outer region exhibiting unique induction characteristics, Coin path; And A sensing coil unit having a face toward a main surface of a coin moving along the coin path, the sensing coil unit comprising a sensing coil unit configured to selectively form an inductive coupling with an outer region of the regions of the coin. 12. The coin acceptor of claim 11, wherein the face of the sense coil unit facing the coin to be identified has an area of less than 72 mm ² . The coin storage device according to claim 11 or 12, wherein the sensing coil unit has a coil winding on a bobbin fixed to the yoke. 14. The coin acceptor of claim 13, wherein the yoke comprises a sintered ferrite material. The coin container according to any one of claims 11 to 14, wherein a region defined by the coil winding is generally circular in cross section. The coin storage device according to any one of claims 11 to 14, wherein a region defined by the coil winding is generally rectangular in cross section. The coin storage device according to any one of claims 11 to 16, wherein the coin path includes a coin run down path between the side walls, and the sensing coil unit is installed on one of the side walls. 18. The coin acceptor of claim 17, wherein the sense coil unit comprises two coil assemblies on opposite sides of the coin rundown path. 18. The coin acceptor of any one of claims 11 to 17, wherein the sense coil unit has a longitudinal axis coil extending transverse to the major surface of the coin passing through the coil. 19. The coin acceptor of any one of claims 11 to 18, further comprising one of said sense coil units configured to selectively form an inductive coupling with said inner region of the coin. 20. A coin storage device according to any one of claims 11 to 19, having an arrangement of said sense coil units configured to selectively form inductive coupling with respective regions of the coin. 21. The coin acceptor of any one of claims 11 to 20, having at least one additional sensing device configured to jointly detect properties of the inner and outer regions of the coin.