JP2001522109A - Coin acceptor - Google Patents

Abstract

(57) [Summary] The coin acceptor is a bimetallic coin having different metal areas (21, 22), such as a new British 2.00 pound coin, each of which has a specific par value with an area exhibiting a unique inducing property. It is configured to detect coins. The acceptor has a coin detecting unit, and the coin detecting unit includes a sensor coil unit (C3a, b) having a coil surface (30) through which the coin (8) passes, and is selectively provided only in a substantially outer region (22) of the coin. To form an inductive bond. The area of the coil face (30) is smaller than 72 mm ² .

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001] The present invention relates to coin acceptors, and more particularly, to acceptors for coins having different electrical guiding properties, for example, bimetallic coins.

BACKGROUND Coin acceptors that identify coins of different denominations are well known and an example is described in our GB-A-2169429. The acceptor has a coin descending path, and the coin rolls along the path and passes through the detector, where the coil performs a series of induction tests on the main surface of the coin, and the material and metal content of the test coin. Is generated. The coin parameter signal is digitized to provide digital coin parameter data, which is compared by the microprocessor with the stored coin data to determine whether the test coin is acceptable. If it is determined that the coin is acceptable, the microprocessor opens the receiving gate and the coin is guided to the receiving passage. Otherwise, the receiving gate will not operate and the coin will be directed to the reject passage.

[0003] The stored coin data represents an acceptable value of the coin parameter data. The stored data can theoretically be represented by a single digital value, but in practice, the coin parameter data varies from coin to coin due to differences in the coin itself, and as a result, the acceptance of coin parameter data It is common to store window data corresponding to a window of possible values. The width of the window is a compromise between factors. The window width should be as narrow as possible to satisfactorily distinguish between true coins and fake coins. However, if the window is too narrow, there is a risk that a true coin will be rejected as a result of monitoring the differences between the characteristics of the true coin.

[0004] Cast coins, for example of two or more metals or metal alloys, with regions of different materials are widespread, and a certain denomination of the coin is a certain region of the first alloy and a second heterogeneous region surrounding it. And at least one annular region of the alloy (hereinafter referred to as bimet coin). The different regions exhibit different inductive properties for the acceptor sensor coil. The inductive sensor detects eddy currents over the coin area including different areas of the coin. As a result, the conductivity and magnetic permeability characteristics of the dissimilar metal region of the test coin are detected as a mixture thereof,
The detection value obtained by the sensor coil becomes ambiguous. For example, a typical sensor reads a new British bimet 2 pound coin in the same way as a non-bimet coin.

Another feature of the bimet coin is that the junction between the first and second regions has variable electrical properties. Its electrical connections vary with product, age, shock and liquid contamination.

[0006] These factors cause the receiving window for the coin acceptor using the conventional inductive sensor to be made wider than required by the bimet coin, and the wide window allows other coins and objects to be formed. It is incorrectly accepted as a true coin, which significantly reduces the security and ability of the coin verification process.

[0007] EP-A-0780810 proposes to use a coil lying on a coin descending passage with a face facing upward on the periphery of the bimet coin. However, in practice, this arrangement is sensitive to the position of the coin relative to the width of the coin path. Since the coin can move laterally from side to side of the descending passage, when the coin moves along the descending passage, the inductive coupling of the coin with the lying coil changes in a pseudo manner,
Leads to unreliable results.

SUMMARY OF THE INVENTION In view of overcoming this problem, the present invention is a method for detecting coins of a predetermined denomination with a main surface comprising inner and outer regions each exhibiting unique inductive properties, A method comprising passing a coin through a coin detector having a sensor coil unit having a surface facing the main surface of the coin and selectively forming an inductive coupling with only the outer region substantially. Is what you do. Thus, an inductive coupling can be selectively formed between the coil unit and the outer region of the coin to determine whether the inductive coupling has predetermined characteristics corresponding to the unique characteristics of the outer region of a true coin. By doing so, the validity of the coin can be tested.

When the sensor coil unit has a test coin facing surface having an area smaller than 72 mm ² , it is possible to actually perform selective identification for many coins having regions with different guiding characteristics. The present invention has been found.

[0010] Yet another sensor for detecting the characteristics of the coin may be used in the method according to the invention. The other sensor further includes another sensor coil unit,
An inductive coupling may be formed between the other sensor coil unit and the coin.
The inductive properties of only the substantially inner area of the coin may be selectively detected using the other sensor coil unit.

[0011] Alternatively or additionally, the method of the present invention may have another sensor coil unit detect the inductive properties of the entire area of the coin. The method of the invention may be used to verify bimet coins, such as the UK 2.00 pound coin.

[0012] The present invention is also a method of detecting coins of a predetermined denomination provided with regions exhibiting respective unique guiding characteristics, wherein each of the first and second coins has a configuration for selectively forming an inductive coupling with one of the regions. And passing a coin through a coin detection unit having a second center coil unit, selectively detecting substantially only one induction characteristic of the area using the first coil unit, and using the second coil unit. A method comprising selectively detecting substantially only one other inductive property of the region.

[0013] The present invention is also a coin acceptor for detecting a coin of a predetermined denomination having a main surface composed of an inner and an outer region each exhibiting a unique guiding characteristic, comprising: a coin passage; A sensor coil unit having a surface facing the main surface of the moving coin, wherein the coil unit is configured to selectively form an inductive coupling with a region outside the region of the coin. To provide. The area formed by the coil windings can be generally circular or square in cross section.

The acceptor may include a coin descending passage between the side walls, and the sensor coil unit may be provided on one of the side walls. The acceptor may include one or more sensor coil units configured to selectively form an inductive coupling with another region of the coin. The sensor coil units may be arranged in a line.

DETAILED DESCRIPTION The acceptor shown in FIGS. 1-5 comprises a multi-coin acceptor capable of verifying a plurality of different face value coins, including bimet coins, such as British coins, including the new bimet 2 pound coin. You. FIG. 1 schematically shows the physical layout of the coin acceptor. The acceptor has a main body 1 having a coin descending passage 2.
Along the path, the test coin rolls from the insertion slot 3 through the coin detection unit 4, and eventually falls to the gate 5. The test of each coin is performed when the coin passes the detection unit 4. If the result of the test indicates the presence of a true coin, the gate 5 will open and the coin can proceed to the receiving passage 6, otherwise the gate will remain closed and the coin will go to the reject passage 7 Be diverted. A coin path through which the coin 8 passes through the acceptor is schematically indicated by a broken line 9.

The coin detecting unit 4 includes three coin sensor coil units C1, C2a, b and C3a, b, each of which is outlined by a broken line, and is fed with power to form an inductive bond with the coin. The fourth coil unit C4 is connected to the receiving passage 6 downstream of the gate 5.
It is detected whether or not the coin provided in the receiving passage 6 has actually entered the receiving passage 6. The coils have different geometries and are powered at different frequencies by the drive interface circuit 10 shown in FIG. An eddy current is generated in the test coin by the coil unit. Due to the different inductive couplings between the three coils and the coin, the coin is substantially characterized in each case. The drive interface circuit 10 generates corresponding coin parameter data signals X1, X2, X3 as a function of the different inductive couplings between the coin and the coil units C1, C2, C3. The corresponding signal X4 is generated by the coil unit C4. The coin parameter data signals X1, X2, X3, X4 can be generated by a plurality of different known methods.

One method is described in detail in GB-A-2169429, where the coil is provided in a separate resonant circuit, which is maintained at the natural resonant frequency as the coin passes through the coil. This frequency deviates from a temporary reference as a result of instantaneous changes in coil impedance caused by inductive coupling with the coin. This change in impedance causes deviations in both amplitude and frequency. As mentioned in our previous specification, the amplitude of the peak is monitored and digitized to provide a coin parameter signal X for each coil. Maintaining the drive frequency to the coil at the natural resonance frequency while moving from coil to coil emphasizes amplitude changes and helps distinguish between the coils. However, the coin parameter signal X, with reference to GB1452740, can be formed in other ways, for example by monitoring the frequency change generated as the coin passes through the coil.

To determine the authenticity of the coin, three parameter signals X 1, X 2, X 3 generated by the test coin are provided to a microcontroller 11, which is coupled to a memory comprising an EEPROM 12. The microcontroller 11 compares the coin parameter signal withdrawn from the test coin with the corresponding stored value held in the EEPROM 12. The stored values are stored in a window having upper and lower limits. Thus, if each coin parameter signal X1, X2, X3 falls within the corresponding window associated with a true coin of a particular denomination, the coin is indicated as acceptable, otherwise it is rejected. . If acceptable, a signal is provided on line 13 to drive circuit 14, which activates gate 5 shown in FIG. If not,
The gate 5 does not open and the coin proceeds to the reject passage 7.

The microcontroller converts the coin parameter data signals X1, X2, X3 into
Comparing with different sets of operating window data suitable for coins of different denominations, the coin acceptor can accept or reject one or more coins of a particular currency set. When the coin is received, the movement of the coin along the receiving passage 6 is detected by the coil unit C4, and the unit 10 stores the corresponding data X
4 is passed to the microprocessor 11, and the microprocessor 11 sequentially outputs an output indicating the currency amount of the received coin to the line 15.

The configuration of the sensor coil will be described in more detail below. Referring again to FIG. 1, the acceptor has a coin door 16 which is hinged to the acceptor body 1 by a shaft 17 in a conventional manner. The coin descending passage 2
As shown in detail in FIG. 3, it is provided between the inner wall 18 of the door 16 and the wall 19 of the identification main body 1. The coin descending passage 2 has an inclined lip 20 on the door 16, and the coin rolls down the coin descending passage to form the sensor coil units C1, C2, C3.
Pass through. In FIG. 3, the coin 8 is shown on the lip 20 of the descending passage 2. As is known in the art, the door 16 is spring-biased to a closed position as shown in FIGS. 1 and 3. Can be removed and dropped into the reject passage 7.

Referring again to FIG. 1, the coil unit C 1 includes a coil provided inside the wall 19 of the housing 1, and includes a single coil wound on a circular bobbin (not shown). Has an area larger than the area of the main surface of the various denomination coins verified by the acceptor. Usually, the coil unit C1 has an outer diameter of 14 mm and thus an area of 154 mm ² . When the coin 8 passes through the coil unit C1, the inductive coupling between the coil and the coin alternates momentarily to generate the coin parameter signal X1 as described above. The relatively large area of coil C1 produces a signal that averages substantially the entire inductive characteristic of the main surface of the test coin.

The coil unit C2 includes a pair of coils C2a and C2b electrically connected in series, and the coils C2a and C2b are respectively wound on mutually equal rectangular bobbins (not shown). One of the coil units C2a is installed inside the wall 19 of the acceptor housing 1, and the other coil unit C2b is installed on the wall 18 of the door 16 and faces the coil C2a. Therefore, when the coin 8 passes between the coils C2a and C2b, the inductive coupling between the coils is interrupted, thereby generating the coin parameter signal X2 as described above. Since the area of the coils C2a and C2b is larger than the area of various denomination coins that can be verified by the acceptor, a signal is generated that averages almost the entire induction characteristics of the main surface of the test coin. For example, the surface area of each coil C2a, b is 315 mm ² and the outer diameter is 20 mm.

As shown in FIG. 1, the test coin 8 is a bimet coin, in this example a new 2.00 pound coin. The coin 8 has opposing main surfaces 8a, 8a 'and a cylindrical outer peripheral surface 8b. The coin comprises a first inner central copper-nickel core region 21 and an outer circular region or ring 22 surrounding region 21, which is here called bronze, 76% Cu, 4% Ni, This is an alloy composed of 20% Zn. These two regions show different inductive properties for the detection coil unit, but they are averaged out by the coil units C1 and C2a, b. Further, as described above, since the joints of the regions 21 and 22 have different electrical characteristics depending on the coin, the characteristics affect the values of the signals X1 and X2 generated by the coil units C1 and C2. As a result, the coil units C1 and C2a, b do not necessarily output a coin parameter signal that successfully identifies 2.00 pound coins and other denominations or fraudulent coins. However, this problem is caused by the coil units C3a,
Overcome by having b.

Referring to FIG. 3, the coil units C 3 a and C 3 b include a pair of coil assemblies C 3 a and C 3 b provided inside the wall 19 of the acceptor body 1 and on the wall 18 of the door 16.
Is provided. The coil assemblies C3a, C3b are configured to selectively form inductive coupling to the bronze ring 22 and not to form significant inductive coupling to the copper-nickel region 21 in the center of the coin.

Each of the coil assemblies C3a, b includes a substantially cylindrical bobbin 23 made of a plastic material, on which the coil 24 is wound. Bobbin 23
Are pressed into a so-called half-pot core 25 made of a sintered ferrite material. The core 25 includes a central cylindrical yoke 26 having a through hole to reduce the amount of ferrite material used, and a peripheral coaxial cylindrical support flange 27.

Instead of using a bobbin, the winding of the coil 24 is wound around a winding form (not shown), the insulator is heated and melted, and when cooled, formed into a self-supporting coil, which is fitted into the half pot core 25. You may make it match.

The support flange 27 of the half pot core 25 is fitted into a corresponding recess of the wall,
The flange 27 of the assembly C3a fits into the cylindrical recess 28 of the wall 19 and the flange 27 of the assembly C3b fits into the corresponding recess 29 of the wall 18. The outer diameter d1 of the coil of the coil 24 is 7.3 mm. The inner diameter d2 of the coil 24 including the bobbin 23 is 2.78 mm, and the diameter of the through hole of the yoke 26 is 2 mm. The surfaces 30 of the coil assemblies C3a, b are in this example separated from one another by 6.24 mm. The coil 24 has an axial length of 2.78 mm. The outer diameter d3 of the half pot core 25 is 9 mm, and therefore, the end surface of each coil unit, that is, the area A of the end facing the test coin is 63.62 mm ² in this example. The windings 24 of the assemblies C3a, b are electrically connected in series. As can be seen in FIG. 3, the coil assembly C3a, b comprises a coil 24 mounted on a common axis B on both sides of the test coin 8. Therefore, the common axis B is the main surface 8a of the test coin passing between the coils.
And the main surface 30 of the coil 24 faces the main surfaces 8a, 8a 'of the coin.

As is known in the art of solenoid coil design, the magnetic field of a substantially cylindrical coil is concentrated along the axis of the coil, so for each of the coil assemblies C3a, b, the magnetic field is primarily Concentrating in the ferrite yoke 26 of the half pot core 25, the magnetic flux around the coil is mainly guided into the loop around the coil by the surrounding ferrite flange 27 except in the area of the surface 30, and the magnetic flux is And returns to the yoke 26. Therefore, the sensitivity of the assembly C3a, b to the passing coin is mostly limited to the area of the coin passing between the yokes 26. As shown in FIG. 3, the assemblies C3a, b are installed close to the coin descending passage 2, and the coil diameter d3 is set so that the inductive coupling between the coin and the coil is substantially equal to the second outer area 22 of the coin 8. Only the first inner region 21 is sized so as not to cause large coupling. This is shown more clearly in FIG. 4, which schematically illustrates the relative dimensions and configuration of the coil assembly C3a, b and the coin 8 as the coin passes through the gap between the coils. . As seen in FIG. 3, half pot core 2
5 extends below the coin lower passage 20 so that the core 26 is aligned with the outer ring 22 of the coin 8. Accordingly, the coin parameter signal X3 generated when the coin 8 passes through the coil unit C3 is mainly determined by the characteristics of the bronze region of the 2.00 pound coin, and the characteristics of the joint between the copper-nickel region 21 and the regions 21 and 22. It is not. Thus, coin parameter signal X3, along with signals X1 and X2, provide a series of coin parameter signals that substantially identify each of the British coins, including the 2.00 pound coin.

The readings from the coil assemblies C3a, b are, in fact, very stable, due to the coils selectively facing the area of the coin, compared to the irregularities of the coin surface. It was found that it was not affected. The foregoing example of the invention is not limited to detecting UK 2.00 pound coins from a UK coin group, but is generally applicable to the detection of Bimet coins, and may be found in other countries' coin groups. It will be appreciated that the method is applicable to detection of met coins and bimet chips. The coin data stored in the EEPROM 12 can store window data appropriate for the coins and chips involved. In general, it is possible to improve the identification of a coin by making the area A facing the coin of a coin unit such as the coils C3a, b smaller than 72 mm ² so that coin areas having individual guiding characteristics are detected. Have been found by the present invention.

Many modifications and changes may be made within the scope of the present invention. For example, in the embodiment of FIGS. 1 to 5, the coil unit C3 includes a pair of opposed coils C3a and b, but a single coil may be used. The coil C3 need not be circular. In fact, an effect is obtained from a coil wound in a square or square shape.

Further, various configurations of the coil units C 1 and C 2 can be used based on the test currency. Therefore, the coil units C1 and / or C2 may be installed in a portion different from the coin descending passage 2 in FIG. Further, at least one optical coin sensor (not shown) may be provided in the descending passage 2 in addition to or instead of one of the coil units C1 and C2.

In a variant, the coil assembly C3 is attached to the door 16 and the wall 19 of the housing 1.
A series of recesses 28, 29 for a and b may be provided and located at various locations to maximize the ability for various groups of coins. Further, an adjusting mechanism may be provided so that the position of the coil assemblies C3a, b can be adjusted.

It is not necessary to use the coil assemblies C3a, b only to detect the outer region 22 of the coin. FIG. 6 shows a modification in which the coil unit C2 is replaced by a coil unit C5 provided with coil assemblies C5a, b connected in series corresponding to the assemblies C3a, b. The coil unit C5 is configured to selectively detect an induction characteristic of the first inner region 21 of the bimet coin 8. When the coin descends while rolling along the path 2, the output X1 from the coil C1 causes the microprocessor 11 to reach the maximum value, and the inner area 21 of the coin passes when it passes between the coil assemblies C5a, b. And selectively monitor its binding. Since the area of the coil surface is sufficiently small, the region 21 can be selectively detected. The coin parameter signal X2 during the time window therefore represents the guiding properties of the region 21 and is hardly affected by the junction between the region 22 and the regions 21 and 22.

The coil assemblies C3a, b and C5a, b do not necessarily have to be connected in series as described above, but switch connections to perform different inductive tests as described in our EP-A-0599844. Is also good. Also, the coil assemblies C3a, b and / or C5a, b are not necessarily
It is not necessary to provide along the line, but it can be provided at another part in the acceptor. A plurality of coil assemblies can be provided in a row.

While the above embodiment describes the detection of a British two pound bimet coin, the acceptor can also be used to detect bimet coins of various currencies such as the euro. It will be appreciated that areas of the coin having particular characteristics may have different configurations.

For example, a coin may have more than one ring of different metal composition.
Further, the different regions do not necessarily have to be ring-shaped, but may have other shapes. They need not all be metal. A portion without coin material, for example, a hole may be provided.

Further, the regions may be various regions of a coin made of a uniform metal composition. For example, a U.S. 25 cent coin has a very wavy surface in its central region, but its edge regions are smooth. These different regions exhibit different inductive properties, but can be individually detected by the present invention.

In general, it is appreciated that if another coil assembly corresponding to the assembly C3a, b is provided at a position for detecting a preselected region of the test coin, its induction characteristics can be individually detected. Will be. As used herein, the term "coin" includes coins, chips and other coin-like objects.

[Brief description of the drawings]

FIG. 1 is a schematic front view of a coin acceptor according to the present invention.

FIG. 2 schematically shows an electric circuit of the acceptor shown in FIG.

FIG. 3 is a schematic partial cross-sectional view of the acceptor taken along line AA of FIG. 1;

FIG. 4 is a schematic view corresponding to FIG. 3, showing magnetic flux coupling between coils C3a and b via the outer ring of the test coin.

FIG. 5 shows an end of a coil C3a facing a test coin.

FIG. 6 is a view corresponding to FIG. 1 of another embodiment of the acceptor according to the present invention.

Claims (22)

[Claims] 1. A method for detecting coins of a predetermined denomination with a main surface comprising inner and outer regions each exhibiting a unique inductive characteristic, comprising a surface facing the main surface of the coin, A method comprising passing a coin through a coin detector having a sensor coil unit configured to selectively form inductive coupling with substantially only the outer region. 2. A method comprising: forming an inductive coupling between a coil unit and an outer region of a coin; and determining whether the inductive coupling has a predetermined characteristic corresponding to a characteristic characteristic of the outer region. Item 7. The method according to Item 1. 3. The sensor coil unit facing the test coin has a surface of 72
^3. The method according to claim 1, having an area smaller than mm2. 4. The coin characteristic is detected by using another sensor.
The method according to any one of the preceding claims. 5. The method of claim 4, wherein the additional sensor comprises another sensor coil unit and comprises forming an inductive coupling between the another sensor coil unit and the coin. 6. The method of claim 5, further comprising selectively detecting the inductive properties of substantially the inner area of the coin using another sensor coil unit. 7. The method according to claim 5, further comprising the step of detecting inductive properties of the entire area of the coin with another sensor coil unit. 8. A method for detecting coins of a predetermined denomination having regions each exhibiting a unique guiding characteristic, the first and second coins each having a configuration for selectively forming inductive coupling with one of the regions. A coin is passed through a coin detection unit provided with a center coil unit, the first coil unit is used to selectively detect the inductive characteristics of only one of the regions, and the second coil unit is used to substantially detect the induction characteristics of the other region. A method comprising selectively detecting only one inductive property. 9. The method according to claim 1, which is used for verifying a bimet coin.
The method according to any one of the preceding claims. 10. A method according to any one of claims 1 to 9 for use in validating UK 2.00 pound coins. 11. A coin acceptor for detecting coins of a predetermined face value having a main surface comprising an inner and an outer region each exhibiting a unique guiding characteristic, wherein the coin acceptor moves along the coin passage. A sensor coil unit having a surface facing the main surface of the coin, wherein the coil unit is configured to selectively form an inductive coupling with a region outside the region of the coin. 12. The sensor coil unit facing the test coin has a surface of 7
The coin acceptor according to claim 11, having an area smaller than ² mm2. 13. The coin acceptor according to claim 11, wherein the sensor coil unit is provided with a coil winding on a bobbin fitted in the yoke. 14. The coin acceptor according to claim 13, wherein the yoke is made of a sintered ferrite material. 15. The coin acceptor according to claim 11, wherein a region formed by the coil winding has a substantially circular cross section. 16. The coin acceptor according to claim 11, wherein a region formed by the coil winding has a substantially rectangular cross section. 17. The coin acceptor according to claim 11, wherein the passage has a coin descending passage between the side walls, and the sensor coil unit is installed on one of the side walls. 18. The coin acceptor according to claim 17, wherein the sensor coil unit includes two coil assemblies on both sides of the coin descending passage. 19. The coin acceptor according to claim 11, wherein the coil unit includes a coil having a long axis extending perpendicular to a main surface of the coin when the coin passes through the coil. 20. The coin acceptor according to any one of claims 11 to 18, further comprising another sensor coil unit configured to selectively form an inductive coupling with an inner region of the coin. 21. A coin acceptor according to any one of claims 11 to 19, comprising a series of sensor coil units configured to selectively form inductive coupling with each area of the coin. 22. The coin acceptor according to any one of claims 11 to 20, further comprising at least one sensor configured to collectively detect characteristics of an inner and outer area of the coin.