JP2006268484A - Coin discriminating device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a coin discriminating device which can determine contamination correctly even when the surface of coin transportation passage is contaminated while contamination of both faces of the coin can be detected. <P>SOLUTION: This device is provided with a first and a second module for detecting contamination and unifying as constitutional elements at least an irradiation means which irradiates the coin surfaces with light, a first light receiving means which receives positive reflection light of the light from the coin surfaces, and a second light receiving means which receives scattered reflection light of the light from the coin surfaces. Each of the means of the first module for detecting contamination and each of the means of the second module for detecting contamination are arranged so that mutual optical axes are orthogonal to coin passage surface. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a coin discriminating apparatus for identifying the denomination, authenticity, etc. of a coin in a coin processing machine, and in particular, it can detect fouling on both upper and lower surfaces of a coin and accurately determine fouling even if the coin passage surface is dirty. The present invention relates to a coin discriminating apparatus that can be used.

  As a conventional coin discriminating apparatus having a function of discriminating damaged coins, for example, there is one disclosed in Patent Document 1. In the coin processing machine described in Patent Document 1, the amount of reflected light received from the coin surface (the lower surface of the coin) detected by the contamination detection sensor and the determination of the contamination for each denomination are detected. This is done by comparing the reference value. Specifically, it includes a fouling detection sensor having two light emitting elements arranged in parallel in a direction orthogonal to the coin conveying direction and a light receiving element disposed therebetween, and the two light emitting elements are provided on the lower surface of the coin. Light is irradiated, and reflected light from the lower surface of the coin is received by the light receiving element to detect the fouling state of the coin surface. Then, for the method of determining a soiled coin, the detection data of the soiling detection sensor is compared with the “discrimination reference value data” corresponding to the denomination of the target coin set by the denomination setting means such as a switch type. When the detection data of the stain detection sensor falls below the discrimination reference value data, it is determined that the coin is a dirty coin. Further, in this Patent Document 1, in order to ensure that a contaminated coin can be detected even if there is a variation in the contamination detection sensor or a change in mounting conditions, the light receiving element receives light before shipping the coin processor. The sensor characteristic of the fouling detection sensor is detected from the quantity level, the light emission amount of the light emitting element is determined according to the detected sensor characteristic, the discrimination reference value data is corrected according to the detected sensor characteristic, and the discrimination after the correction It is disclosed that reference value data is stored in a storage unit in advance, and the corrected determination reference value data is used during the coin counting process (see, for example, Patent Document 1).

Japanese Patent Laid-Open No. 7-296216

  By the way, like the coin processor described in Patent Document 1 described above, a conventional coin processor previously corrects (offset adjustment) the light emission amount of the contamination detection sensor and the reference value for contamination determination before shipment. As a result, there is no variation in the ability to detect contamination. However, since the detection of the fouling on the coin surface is performed optically, contamination of the sensor itself and the fouling of the coin transport surface that occur after shipment become a problem. For example, when a contamination detection sensor is provided at a position below a transparent coin conveyance path such as a glass plate, and the structure detects the contamination of the coin surface (lower surface) through the glass plate from below the coin conveyance path, the sensor itself Dirt can be avoided. However, since the coin passes through the coin transport path on the sensor, the coin transport surface (upper surface of the glass) is soiled with coin powder, and the problem is that the coin is determined not to be soiled even though it is not soiled. Was.

  Conventionally, glass stains on the coin transfer surface are cleaned during the maintenance to remove the stains on the coin transfer surface, set the reference coin or white plate on the sensor portion, and adjust the stain detection sensor. It was common. Furthermore, the conventional coin discriminating apparatus having the fouling discrimination function is a fouling detection only on one side of the coin, and since the fouling detection on both sides is not performed, there is a problem that even if the reverse side is dirty, it cannot be excluded as a fouling coin. . Moreover, since it is set as the form which performs a stain | pollution | contamination detection based on the light reception sensor output of the diffuse reflection light from the coin surface, the problem that a pattern is judged to be dirty or a new coin is judged to be a dirty coin has also occurred. It was.

  The present invention has been made under the circumstances as described above, and the object of the present invention is to solve the above-described problems of the prior art, to detect coin fouling on the upper and lower surfaces and to accurately detect the coin passage surface. Another object of the present invention is to provide a coin discriminating apparatus capable of determining a stain.

  The present invention relates to a coin identifying device, and the object of the present invention is to provide an irradiating means for irradiating light to the coin surface of the identifying coin, and a first light receiving means for receiving specularly reflected light from the coin surface of the light. 1st and 2nd stain | pollution | contamination detection module which integrated the 2nd light-receiving means which receives the diffuse reflection light from the coin surface of the said light at least as a component, And said 1st stain | pollution | contamination detection module These means and the respective means of the second fouling detection module are achieved by arranging the optical axes so as to face each other with respect to the coin path surface.

  Furthermore, the object of the present invention is to provide a control means for correcting the output of a light receiving sensor as the first and second light receiving means based on the result of determination of contamination on the upper and lower surfaces of the identifying coin, and the identifying coin. Included in the output of the light receiving sensor as the first and second light receiving means based on the light receiving signal of the light receiving means on the opposite side that has received the irradiation light from the irradiation means that has passed through the light transmitting passage through which the light passes. This is achieved more effectively by providing control means for correcting a dirt component caused by dirt in the light-transmitting passage.

  According to the present invention, the optical axes of the irradiation means for irradiating light on the coin surface, the first light receiving means for receiving the regular reflection light, and the second light receiving means for receiving the diffuse reflection light are arranged on the coin passage surface. Since it is configured so as to be opposed to each other, it has an excellent effect that it is possible to detect coin fouling on the upper and lower surfaces of the identification coin with high accuracy and substantially simultaneously. Further, it corrects the output of the light receiving sensor based on the result of determination of the contamination on the upper and lower surfaces of the identification coin, or receives the irradiation light from the irradiation means that has passed through the translucent passage through which the identification coin passes. By correcting the output of the light receiving sensor based on the light reception signal of the means and the contamination determination result of the upper and lower surfaces of the identification coin, there is an excellent effect that the contamination can be accurately determined even if the coin passage surface is contaminated. Further, even during operation in which a reference coin or the like cannot be used, there is an excellent effect that it is possible to effectively feed back the dirt in the translucent passage of the stain detection unit to the received light output.

  Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the drawings.

  FIG. 1 shows an example of the entire configuration of a coin identification device according to the present invention. The coin identification device 1 is roughly classified as a sensor module for coin identification (hereinafter referred to as “coin identification sensor”) 10. The main discriminating unit 20 identifies a coin denomination, authenticity, and the like, and a fouling detection sensor 30 that identifies the fouling of a coin.

  The coin identification sensor 10 includes an image sensor (a two-dimensional image sensor in this example) 11 that captures an image of a coin, a magnetic sensor 12 that detects the magnetic characteristics of the coin, and a timing sensor 13 that detects the arrival of the coin. I have.

  The main identification unit 20 includes a basic module 21 having an input / output interface circuit with the coin identification sensor 10 and a control module 22 configured by a CPU, a computer program, and the like, and setting information such as an identification mode and an identification target coin. And a means for identifying the denomination, authenticity, etc. of the coin based on the detection information of the coin identification sensor 10 and outputting the identification result. In this example, the basic module 21 includes a power source 21a, an image sensor control circuit 21b, a memory 21c, a magnetic sensor processing circuit 21d, an A / D converter 21e, a light emitting / receiving circuit 21f, and a D / A converter 21g. The

  In the present invention, the configuration of the coin identification sensor 10 and the configuration of the main identification unit 20 are not limited, and those mounted on a general coin identification device can be applied. The configuration of the contamination detection sensor 30 according to the present invention will be described in detail.

  The contamination detection sensor 30 according to the present invention is an additional component of the coin identification device, and is configured to be integrally connectable to the sensor unit of the coin identification sensor 10 of the coin identification device 1. Can be added without changing the hardware. The contamination detection sensor 30 has a function of identifying a contamination on the surface of the coin to be identified (a degree of contamination and / or a contaminated coin) by incorporating a CPU uniquely. The denomination information necessary for the fouling identification process uses denomination information from the magnetic sensor 12 or the image sensor 11 (in this embodiment, denomination information received via the main identification unit 20). By adopting the form, it is possible to determine the contamination based on the material based on the denomination information, reduce the processing load related to the contamination identification, and realize the CPU of the contamination detection sensor 30 with an inexpensive CPU. CPU load distribution by parallel processing with the identification unit 20 side and speeding up of the entire identification process are realized. In the present embodiment, the fouling detection sensor 30 side identifies the fouling of the coin (the degree of fouling on the coin surface) and transmits the result to the main identification unit 20, and the main identification unit 20 side obtains a fouling coin (hereinafter referred to as fouling coin) An example of the determination of “soiled coins” is taken as an example.

  FIG. 2 is a block diagram showing an example of the configuration of the contamination detection sensor 30 according to the present invention. The contamination detection sensor 30 is an optical composite in which a plurality of optical sensors for optically detecting the contamination of coins are integrated. A sensor module 30a, 30b, a passage portion 30c serving as a passage for coins, and a control means 30d for identifying contamination on the surface of the coin to be identified are included in a single case in a compact form. The configuration is as follows.

  The two optical composite sensor modules 30a and 30b are composed of the same hardware, and each has an irradiation means 31 for irradiating light on the surface of the coin and a first light receiving means 32 for receiving regular reflection light from the coin surface. And second light receiving means 33 for receiving diffusely reflected light from the coin surface. In the present embodiment, two optical composite sensor modules (stain detection modules) 30a and 30b having the same configuration are arranged facing each other with the passage portion 30c interposed therebetween, and a coin upper surface (upper surface of the coin) and a coin lower surface. It is set as the structure which detects the stain | pollution | contamination of both surfaces of (the lower surface of a coin).

  Further, the first optical composite sensor module 30a (hereinafter referred to as “upper surface contamination sensor module”) and the second optical composite sensor module 30b (hereinafter referred to as “lower surface contamination sensor module”) are respectively irradiated. The light quantity monitoring means 34 for monitoring the light quantity of the irradiation light 31 and the light flux of the irradiation light from the irradiation means 31 are reflected and incident on the coin surface in the vertical direction, and the regular reflection light from the coin surface is transmitted. And optical path changing means 35 for making it incident on the light receiving surface of the light receiving means 32.

  In the present embodiment, an infrared light source (for example, an infrared LED) is used as the light source of the irradiation means 31 to irradiate the coin surface with infrared light in order to increase the light emission amount and increase the light receiving sensitivity. ing. As the first light receiving means 32, the second light receiving means 33, and the light quantity monitoring means 34, a light receiving sensor such as a photodiode is used, and as the optical path changing means 35, a half mirror is used.

  FIG. 3 schematically shows a unit structure of the fouling detection sensor 30 in a side view, and FIG. 4 shows a specific example of the unit structure in a perspective view. A specific configuration of the contamination detection sensor according to the present invention will be described with reference to these drawings.

  As shown in FIG. 3, a translucent passage 30 c is provided at the upper center of the unit of the contamination detection sensor 30. The passage portion 30c includes a bottom plate 30c1 serving as a passage surface of the coin 2, a side plate 30c2 serving as a guide piece on the coin side, and a top plate 30c3 on which a light receiving element of the second light receiving means 33 is installed (and a lower side of the bottom plate 30c1). Plate 30c4) or the like. The members of the bottom plate 30c1 and the top plate 30c3, which are located in the optical path of the light emitted from the irradiation means 31, and the lower plate 30c4 on which the light receiving elements of the second light receiving means 33 are installed are sapphire glass or the like. A light member is used.

  The first light receiving means 33, the second light receiving means 33, and the light quantity monitoring means 34, which are constituent elements of the upper surface contamination sensor module 30a and the lower surface contamination sensor module 30b, have their optical axes opposed to the coin path surface. It is the composition arranged to do. In the present embodiment, as shown in FIG. 3, the components of the upper surface contamination sensor module 30a and the lower surface contamination sensor module 30b are made the same, and the relationship between the position and orientation of each component of the contamination sensor modules 30a, 30b is the module. The components of both modules 30a and 30b are arranged to face each other so that they are mirror-symmetrical with respect to the central plane between 30a and 30b, and a light-transmitting portion is formed in the gap between the two modules 30a and 30b. The passage portion 30c is provided and integrated.

  Since the components of the upper surface contamination sensor module 30a and the lower surface contamination sensor module 30b are the same, the arrangement of the components of the upper surface contamination sensor module 30a will be described in detail here.

  As shown in FIG. 3, an “infrared LED” as an irradiating means 31 is provided on the upper part of the passage portion 30 so that the light emission direction is, for example, a direction orthogonal to the conveying direction of the coins 2. The “half mirror” as the optical path changing means 35 is provided so as to be inclined so that the light beam of the infrared LED 31 is incident at an incident angle of 45 degrees. Above the half mirror 35, a light receiving sensor (hereinafter referred to as “regular reflection sensor”) is provided as the first light receiving means 32 that receives the specularly reflected light from the surface of the coin 2. At a position adjacent to the reflection sensor 32 (position on the infrared LED 31 side), a light receiving sensor (hereinafter referred to as “monitor sensor”) is provided as light amount monitoring means 34 for monitoring the amount of light emitted from the infrared LED 31. . In addition, diffuse reflection light from the surface of the coin 2 is received at a predetermined position on the top surface of the top plate 30c3 of the coin passage (in this example, a position below the gap between the infrared LED 31 and the half mirror 35). A light receiving sensor (hereinafter referred to as “diffuse reflection sensor”) is provided as the second light receiving means 33.

  Then, the processing substrate 30d1 on which the components (CPU or the like) of the control means 30d are mounted is installed in a vacant area below the passage portion 30c, as shown in FIG.

  In the present embodiment, the light emitted from the irradiation means 31 to the coin surface is spot light. In a preferred embodiment, an infrared LED in which a condenser lens or the like is integrally formed is used. Thus, a beam-shaped infrared spot light in which light rays are substantially parallel is emitted. The reason why infrared light is used as irradiation light is that infrared light has a larger light quantity than red and has a large reflectivity from the coin surface, so that the SN ratio of the sensor is remarkably improved. The reason for using spot light is that the detection area is small, the influence of coin data collection sites (holes and edges) due to the state of coin transportation and gathering is reduced, and the detection accuracy of partial dirt on coins is increased. Because.

  In the configuration of the contamination detection sensor 30 as described above, the optical path of the light beam emitted from the infrared LED 31 will be described. The description in parentheses is for the lower surface contamination sensor module 30b.

  The spot light L1 emitted from the infrared LED 31 of the upper surface contamination sensor module 30a (lower surface contamination sensor module 30b) is reflected by the half mirror 35, and the reflected light L2 is perpendicular to the upper surface (lower surface) of the coin 2. Irradiated. The regular reflection light L3 from the upper surface (lower surface) of the coin 2 passes through the half mirror 35 and is incident on the light receiving surface of the regular reflection sensor 32. On the other hand, the diffuse reflection light L4 from the upper surface (lower surface) of the coin 2 is incident on the light receiving surface of the diffuse reflection sensor 33. Further, a part of the irradiation light L5 emitted from the infrared LED 31 is incident on the light receiving surface of the monitor sensor 34.

  Further, the spot light emitted from the upper (lower) infrared LED 31 in the absence of the coin 2 is the light reflected by the half mirror 35, the translucent passage portion 30 c and the opposite half mirror 35. And enters the light receiving surface of the lower (upper) regular reflection sensor 32. The output signal of the regular reflection sensor 32 is used to detect dirt on the light-transmitting passage portion 30 c and to correct dirt on the outputs of the regular reflection sensor 32 and the diffuse reflection sensor 33.

  Here, the unit structure of the contamination detection sensor 30 will be described with reference to FIG. Each component of the upper surface contamination sensor modules 30a and 30b shown in FIG. 3 is mounted inside the sensor case 30A as shown in FIG. In FIG. 4, the diffuse reflection sensor 33 and the monitor sensor 34 are in an invisible position on the back side. The sensor cover 30B has a heat radiating or moisture permeable hole formed in an area corresponding to the processing substrate 30d1 of the control means 30d, and the area is covered with a dust-proof filter 30B1 that can be ventilated such as a porous material. It becomes the composition. Thus, the contamination detection sensor 30 unitized by one housing | casing is provided as a high-performance unit which has a coin identification function and a double-sided contamination detection function by integrally connecting with the unit of the coin identification sensor 10, for example. Can do.

  Next, the positional relationship between the coin identification sensor 10 and the stain detection sensor 30 with respect to the coin conveyance direction will be described with reference to the schematic diagram of FIG.

  The passage portion 10 a of the coin identification sensor 10 and the passage portion 30 c of the contamination detection sensor 30 constitute a part of the coin passage of the coin processor, and the passage portion 30 c of the contamination detection sensor 30 is the passage of the coin identification sensor 10. It arrange | positions in the downstream of the part 10a. In the example of FIG. 5, an example in which the contamination detection sensor 30 is installed adjacent to the image sensor 11 is shown, but the installation position of the contamination detection sensor 30 is not limited to this position. What is necessary is just to be the downstream of the sensor (magnetic sensor 12 or image sensor 11) for denomination discrimination.

  In this example, the sensors of the coin identification sensor 10 are arranged in the order of the hole detection sensor 14 (additional component), the magnetic timing sensor 13a, the magnetic sensor 12, and the image sensor 11 from the upstream side toward the downstream side. In addition, two image timing sensors 13b are juxtaposed in a direction orthogonal to the coin transport direction at a predetermined position in the imaging area of the image sensor 11. The magnetic timing sensor 13a is a sensor for detecting the timing of starting sampling of magnetic data (material data) by the magnetic sensor 12, and the image timing sensor 13b is an imaging timing of the image sensor 11 (the entire coin is in the imaging area). It is a sensor for detecting the timing of entering. In this example, the right side with respect to the coin conveyance direction (the direction of the arrow x in FIG. 5) is the coin offset direction, and the hole detection sensor 14, the magnetic timing sensor 13a, and the detection unit 30C of the fouling detection sensor 30 are: Each is arranged on the coin side.

  In the example of FIG. 5, the passage on the upstream side of the coin identification sensor 10 is inclined, and an example is shown in which the coin passes through the passage portion 30 c of the contamination detection sensor by inertia force from the inclined portion. However, the present invention is not limited to such a transport form. For example, even in a form in which the upper surface of a coin is slid while being pressed by a conveyor belt, and the coins are conveyed at high speed in a chained state without a gap, it is possible to connect the passage portion 30c of the fouling detection sensor to the conveyance path. . In that case, the coin is conveyed on the passage portion 30c by the conveyance belt, but as shown in FIG. 5, the detection portion 30C of the fouling detection sensor is provided at the end of the passage portion 30c on the offset side. Therefore, it is not affected by the conveyor belt.

Next, the type and application of the sensor signal of the contamination detection sensor 30 will be described. For convenience of explanation, each sensor provided in the upper surface contamination sensor module 30a is referred to as "upper surface OO sensor", and each sensor provided in the lower surface contamination sensor module 30b is referred to as "lower surface OO sensor". The terms “upper surface” and “lower surface” are attached for distinction.
<Type of sensor signal>
The sensor signal of the contamination detection sensor 30 includes the following eight types of signals.
(1) Light reception signal of the upper surface regular reflection sensor 32 during coin passage (hereinafter referred to as “upper surface regular reflection signal DS1”)
(2) Light reception signal of upper surface diffuse reflection sensor 33 during coin passage (hereinafter referred to as “upper surface diffuse reflection signal DS2”)
(3) Light reception signal of the upper surface monitor sensor 34 (hereinafter referred to as “upper surface monitor signal DS3”)
(4) When there is no coin (for example, at the start of the counting operation), the light received by the lower regular reflection sensor 32 of the light emitted from the upper infrared LED and transmitted through the passage portion 30c (hereinafter referred to as “upper emission lower transmission signal”). DS4 ")
(5) Regular reflection light receiving signal when coins pass through the bottom regular reflection sensor 32 (hereinafter referred to as “bottom regular reflection signal DS5”)
(6) Diffuse reflected light receiving signal when the lower surface diffuse reflection sensor 33 passes a coin (hereinafter referred to as “lower surface diffuse reflection signal DS6”)
(7) Light reception signal of the lower surface monitor sensor 34 (hereinafter referred to as “lower surface monitor signal DS7”)
(8) When no coin is present (for example, at the start of the counting operation), light received from the lower infrared LED and transmitted through the passage portion 30c is received by the upper regular reflection sensor 32 (hereinafter referred to as “lower emission upper transmission). Called signal DS8 ")
The upper regular reflection signal DS1 in (1) and the lower emission upper transmission signal DS8 in (8), the lower regular reflection signal DS5 in (5), and the upper emission lower transmission signal DS4 in (4) are respectively Although it is physically the same light receiving sensor, it has two types of sensor functions due to different light emitting sources and optical paths.
<Application of each sensor signal>
The upper surface regular reflection signal DS1 and the upper surface diffuse reflection signal DS2 are used as sensor signals for determining the contamination on the upper surface of the coin, and for correcting contamination determination data (light reception outputs of the upper surface regular reflection sensor and the upper surface diffuse reflection sensor). It is also used as a sensor signal. The upper surface monitor signal DS3 is used as a sensor signal for adjusting the light amount of the upper infrared LED (for correcting the light emission intensity). The upper light emission lower transmission signal DS4 is a sensor for detecting dirt on the coin passage (translucent passage portion) and correcting dirt determination data (for correcting reduction in received light output due to contamination of the light transmission passage portion). Used as a signal. In addition, it is also used for acquiring coin entry / exit timing. For example, if the time from receiving a coin arrival notification from the upstream coin identification sensor to the coin entry is monitored and no coin entry (blocking of light by coins) is detected within the specified time, It determines and transmits the said code | cord | chord to high-order (a main identification part or a coin processor main body). Furthermore, the time from the coin entry detection to the escape detection is similarly monitored, and the upper emission lower transmission signal DS4 is detected so as to detect the presence or absence of coin flow failure in the passage portion in the contamination detection sensor. It is also used for detecting abnormalities such as coin flow failure due to dust or liquid contamination.

  On the other hand, the lower surface regular reflection signal DS5 and the lower surface diffuse reflection signal DS6 are used as sensor signals for determining the contamination on the lower surface of the coin, and are also used for the data for determining the contamination (light reception outputs of the lower surface regular reflection sensor and the lower surface diffuse reflection sensor). It is also used as a sensor signal for correction. The lower surface monitor signal DS7 is used as a sensor signal for adjusting the amount of light (for correcting the emission intensity) of the lower infrared LED. The lower emission upper transmission signal DS8 is used to detect dirt in the light-transmitting passage formed between the sensors and to correct the data for determining dirt (for correcting reduction in received light output due to dirt in the light-transmitting passage). ) As well as the upper emission lower transmission signal DS4, it is also used for acquiring coin entry / exit timing.

  Next, the acquisition timing of the eight sensor signals DS1 to DS8 will be described with reference to the timing chart of FIG.

  The control unit 30d of the contamination detection sensor reads each of the eight signals DS1 to DS8 once during one cycle of the sensor signal acquisition interval St (for example, 500 μs) as one cycle. This sensor signal acquisition processing is executed for a plurality of cycles, for example, from the arrival of a coin to the detection unit 30C of the fouling detection sensor 30 until the escape of the coin, and data of one point or a plurality of points (for example, a coin) The data of the central 4 points from the time of entry to the escape of coins) is used as data for identifying damaged coins.

  First, as shown in FIG. 6, the upper infrared LED 31a emits light at the start of one cycle, and the upper surface regular reflection signal DS1, the upper surface diffuse reflection signal DS2, the upper surface monitor signal DS3, and the upper light emission lower transmission signal DS4 are read. After turning off the upper infrared LED 31a, the lower infrared LED 31b emits light, reads the lower regular reflection signal DS5, the lower diffuse reflection signal DS6, the lower monitor signal DS7, and the lower emission upper transmission signal DS8, and the lower infrared LED 31b Is turned off to complete one cycle, and the process proceeds to the next cycle.

  In the above configuration, an operation example of the coin discriminating apparatus and the contamination detection sensor according to the present invention, and the dirt correction function of the light receiving sensor output of the contamination detection sensor will be described.

  First, an outline of an overall operation example of the coin identifying device according to the present invention will be described with reference to the data flow of FIG. Note that the data flow in FIG. 7 is for exchanging data such as commands between the processor main body and the main identifying unit in the coin processor, and exchanging data such as commands between the main identifying unit and the fouling detection sensor. Show.

  When receiving the start command from the CPU of the coin processing machine main body, the main identification unit 20 of the coin identification device transmits the command to the fouling detection sensor 30 and receives a response, and then receives the response to the coin processing machine main body. Send a response. When the coin is conveyed, the main identification unit 20 of the coin identification device detects the arrival of the coin by the signal of the magnetic timing sensor 13a, collects the coin information by the magnetic sensor 12, and discriminates the material, the diameter, and the like. To determine the denomination. In parallel with this, when the arrival of coins is detected by the image sensor timing sensor 13b on the downstream side of the magnetic sensor 12 (see FIG. 5), the main identification unit 20 transmits a coin arrival notification to the contamination detection sensor 30. At the same time, a surface image of the coin is collected by the image sensor 11. At this time, the main discriminating unit 20 comprehensively discriminates the denomination and authenticity of the coin based on the denomination information determined by the information of the magnetic sensor 12 in the previous stage and the image information of the coin surface collected by the image sensor 11. To do. Then, the denomination information determined based on the data collected by the magnetic sensor 12 (or the denomination information determined by the image sensor 11) is transmitted to the contamination detection sensor 30.

  On the other hand, in the last stage contamination detection sensor 30 that has received the coin arrival notification from the main identification unit 20, reading operation of the signals DS1 to DS8 of each sensor is started in the above-described cycle, and the collected contamination identification data (coin Based on the received light data of regular reflection light and diffuse reflection light from the surface) and denomination information received from the main identification unit 20, the degree of contamination of the coin is determined, and the result of contamination on the upper and lower surfaces of the coin (degree of contamination) And the like) are separately notified to the main identification unit 20.

  The main identification unit 20 checks the degree of fouling of the upper and lower surfaces received from the fouling detection sensor 30 and determines whether or not it is a fouled coin according to a set level (threshold). For example, the denomination code of the coin Then, identification results such as authenticity information and defaced currency information are transmitted to the processor main body.

  In addition, you may make it determine not the main identification part 20 but the contamination detection sensor 30 side whether it is a corruption coin. In that case, it is good also as a form which receives the authenticity information of a coin from the main identification part 20, and identifies a dirty coin only in the case of a true coin.

  Next, the dirt correction function of the light receiving sensor output of the dirt detection sensor 30 will be described.

  The “dirt correction function” referred to in the present invention means a regular reflection sensor 32 and a diffuse reflection sensor 33 used for determining a dirty coin so that the dirt can be accurately determined even if the coin passage portion 30c is dirty. This is a function that corrects the dirt component contained in the output of. In addition, the “dirt component” included in the light receiving sensor output is, for example, a dirt component caused by peeling of dirt adhered to a coin, dirt on a translucent passage part such as coin powder, and the light receiving part of the sensor itself. This refers to a dirt component of the light receiving sensor output caused by dirt on a member in the optical path until irradiation light is received, such as a dirt component caused by dirt.

  As shown in FIG. 3, the upper surface regular reflection sensor 32 and the upper surface diffuse reflection sensor 33 are specular reflection light and diffuse reflection light (in this example, a hard glass top plate) transmitted through the top plate 30c3 of the passage portion 30c. The reflected light from the upper surface of the coin is received, but if the lower surface of the top plate 30c3 is soiled by coin powder or the like, the sensor signal becomes small due to the soiling, and there is a probability that normal coins that are not actually soiled will become dirty. To increase. On the other hand, the lower surface regular reflection sensor 32 and the lower surface diffuse reflection sensor 33 receive regular reflection light and diffuse reflection light (reflected light from the lower surface of the coin) transmitted through the bottom plate 30c1 (in this example, a hard glass bottom plate) of the passage portion 30c. Each light is received, but if the upper surface of the bottom plate 30c1 that becomes the coin passage surface becomes dirty due to coin dust or dirt adhering to the coin, the sensor signal becomes small due to the dirt, and the actual dirt that is not actually dirty is soiled. The probability that it will be determined as a currency increases.

  Therefore, the control means 30d of the contamination detection sensor 30 uses the sensor output difference between the upper and lower surfaces of the past flowing coins, distributes the upper and lower surface stains, and corrects the signal for each stain so that the sensor glass stains. We try to prevent a drop in detection capability. The sensor output difference refers to the number of appearance of fouling coins, the level obtained from sensors such as the product and sum of sensor signals, and the information obtained from the result of fouling determination (for example, the level indicating the degree of fouling). The information obtained from the sensor output of “2” and the “difference in detection information on the upper and lower surfaces” obtained from the sensor output of the lower surface contamination sensor module. Further, as a process for correcting the signal for each stain, the coin is flowed in the state where the above correction is performed, the correction is continuously performed, and the correction is performed until it converges.

  Specifically, for example, the reference value (reference transmission data used for the correction process) of each sensor set at the time of initial adjustment is stored in a storage medium such as a RAM, and the infrared ray immediately before the start of the coin counting process. The light amount of the LED 31 is confirmed by the monitor sensor 34, and if it is a specified value, the upper and lower glass surfaces are passed by the specular reflection sensor 32 on the opposite side to the light emitting side in order to detect dirt on the glass surface of the passage portion 30c. Receives transmitted light. This is compared with the reference transmission data, which is the initial value, to calculate the glass stain rate. Further, after the counting, if the number of coins determined to be fouled exceeds a predetermined number, a glass fouling correction value is calculated based on the upper and lower fouling numbers. These two values are used for correction of regular reflection data and diffuse reflection data being counted, so that more accurate contamination determination is performed. By doing in this way, even if the operation | use which cannot use a reference | standard coin etc. is in operation, the glass surface stain | pollution | contamination of a runway can be effectively fed back to a light reception output. Note that the correction processing includes the first embodiment and the second embodiment, and specific examples will be described below with reference to flowcharts.

  Next, the details of the operation example of the contamination detection sensor 30 according to the present invention and the details of the contamination coin identification processing and the contamination correction processing of the light receiving sensor output will be described. In the following description, the operation of “before counting”, “during counting”, and “after counting” of coins by the coin processor will be described separately.

  First, an operation example before counting in the contamination detection sensor 30 will be described along the flow of the flowchart of FIG.

The control unit 30d of the contamination detection sensor first inputs detection signals (upper surface monitor signal DS3, lower surface monitor signal DS7) of the monitor sensor 34 as processing before counting, and the light emission amounts of the upper and lower LEDs 31 are specified amounts. Whether or not it is within a specified value or within a specified range is determined (step S1), and if it is not the specified amount, the light emission amount of the corresponding LED 31 is adjusted (step S2). Subsequently, the glass stain rate is calculated based on the upper emission lower transmission signal DS4 and the lower emission upper transmission signal DS8. The “glass contamination rate” referred to here is the contamination rate of the translucent passage portion 30c (a region entering the optical path of the spot light) through which coins pass. This glass stain ratio is obtained by setting the AD conversion value of the upper emission lower transmission signal DS4 to “lower transmission data”, its reference value as “reference lower transmission data”, and the AD conversion value of the lower emission upper transmission signal DS8 as “upper transmission”. “Data” and its reference value as “transmission data on reference” are calculated by the following equations 1 and 2, for example (step S3).
(Equation 1)
Glass stain ratio 1 = Bottom transmission data / Standard bottom transmission data (Equation 2)
Glass stain ratio 2 = upper transmission data / reference upper transmission data In the above step S3, a “transmission output decrease rate” may be calculated instead of the “glass contamination ratio”. The “transmission output decrease amount rate” here refers to (a) the ratio of the decrease amount of the light reception output of the upper light emission lower transmission signal DS4 (the ratio of the actual measurement value to the reference value), that is, in the absence of coins. The decrease rate of the received light signal at the lower surface regular reflection sensor (opposite light receiving sensor) of the infrared light emitted from the upper infrared LED and transmitted through the passage portion 30c, or (b) the lower light emitting upper transmitted signal DS8. Ratio of the amount of decrease in the received light output (the ratio of the measured value with respect to the reference value), that is, the regular reflection of the upper surface of the infrared light emitted from the lower infrared LED and transmitted through the passage portion 30c in the absence of coins This is the rate of decrease in the received light signal at the sensor 32.

  Hereinafter, the case where “glass stain rate” is used as the correction factor of the damaged coin determination data is referred to as the first embodiment, and the case where “transmission output decrease amount rate” is used as the correction factor of the dirty coin determination data is referred to as the second embodiment. The portions of the steps that differ in processing depending on these forms will be described separately in the first embodiment and the second embodiment.

  Next, an operation example during counting in the contamination detection sensor 30 will be described along the flow of the flowchart of FIG. 9. Note that the processing on the upper surface of the coin and the processing on the lower surface of the coin have only a difference between using the sensor signal on the upper surface and the sensor signal on the lower surface, and therefore will be described in a simplified manner.

When receiving the coin arrival notification from the main identification unit 20 of the coin identification device (step S11), the contamination detection sensor control means 30d starts taking data from each sensor in a predetermined scan cycle (the above-described cycle), Data for identifying coins is collected (step S12). Subsequently, when a denomination notification is received from the main identification unit 20 (step S13), the AD conversion value of the regular reflection signal included in the dirty coin identification data is “regular reflection data”, and the AD conversion value of the diffuse reflection signal is “ The data (diffuse reflection data) and data having at least both regular reflection data and diffuse reflection data as contamination determination elements (the sum of both in this example) are calculated as “determination data”. At that time, in the case of the first embodiment, the determination data (upper surface determination data and lower surface determination data) is corrected by the following Equation 3 or Equation 4 using a “glass stain correction value” to be described later. In the case of the second embodiment, the determination data (upper surface determination data and lower surface determination data) is corrected by the following equation 5 using a “fouling determination rate” described later.
(Equation 3)
Judgment data = (regular reflection data + diffuse reflection data) * (glass stain correction value / K)
(Equation 4)
Judgment data = (regular reflection data + diffuse reflection data) * (glass stain correction value / K) /
((1-α) + α * glass stain rate 1+ (1-β) + β * glass stain rate 2)
Here, “K” in the above formulas 3 and 4 is a reference value (constant) of the correction amount of the determination data, and in this example, K = 128. Further, the “glass stain correction value (initial value = K)” in the above formulas 3 and 4 is a variable that is changed according to the count value of the damaged coins (see “after count” processing described later). Further, “α” and “β” in the above equation 4 are eigenvalues depending on the denomination.
(Equation 5)
Determination data = (regular reflection data + diffuse reflection data) / (1−transmission output decrease rate)
* Fouling judgment rate)
Here, the “fouling judgment rate (initial value = 1)” in the above equation 5 is a variable that is changed according to the count value of the fouled coins (see “after counting” processing described later).

  The control unit 30d of the contamination detection sensor corrects the determination data by any one of the equations 3 to 5 (step S14), and then the determination data after the correction and the contamination determination reference information corresponding to the denomination of the coin (E.g., reference level data indicating a plurality of levels of contamination degree judgment reference values set for each denomination), and the level of coin contamination (in this example, the level of contamination of multiple levels of contamination) The degree of contamination on the upper surface of the coin and the degree of contamination on the lower surface of the coin, which indicate whether the degree is a degree, are determined (step S15). Then, the result of the determination on the upper and lower surfaces is transmitted to the main identification unit 20 (step S16), and for example, the degree of contamination of the coin is compared with a reference value (threshold value) for determining the damaged coin to determine whether it is a damaged coin. If it is determined that it is a dirty coin, the count value indicating the number of dirty coins is incremented by 1 (step S17), and the processing of the coin is terminated. The count value of the damaged coins calculated in step S16 is a correction parameter used to obtain the “glass stain correction value” used in Equation 3 or Equation 4 or the “dirt determination rate” used in Equation 4. .

  In the above-described embodiment in the “counting” operation, the main identification unit 20 is notified of the degree of coin fouling (the degree of fouling on the upper surface of the coin and the degree of fouling on the lower surface of the coin) obtained by the control means 30d of the fouling detection sensor. However, it is possible to adopt a mode in which the determination of the dirty coin is performed on the main identification unit side, but the dirty detection sensor side may determine the dirty coin and notify the determination result to the main identification unit 20. It is also possible to adopt a form in which the operator can select and set any form by a selection operation from the operation unit of the processor main body.

  Next, an example of the operation after counting in the contamination detection sensor 30 will be described along the flow of the flowchart of FIG.

The control unit 30d of the contamination detection sensor determines whether or not the count value (number) of the contaminated coins obtained in step S16 is equal to or greater than a specified value (for example, 1000) as the processing after counting (step S21). If the value is equal to or greater than the specified value, the “glass stain correction value” used in the expression 3 or 4 in the first embodiment is corrected by the following process. For example, if the upper stain determination number is equal to or greater than (lower stain determination number +50), correction is performed using the following equations 6 and 7. If the lower stain determination number is equal to or greater than (upper stain determination number +50), the following number is corrected. Correction is performed by 8 and Equation 9.
(Equation 6)
Upper glass stain correction value = Upper glass stain correction value + 1
(Equation 7)
Lower glass stain correction value = Lower glass stain correction value -1
(Equation 8)
Lower glass stain correction value = Lower glass stain correction value + 1
(Equation 9)
Upper glass stain correction value = Upper glass stain correction value-1
On the other hand, in the case of the second embodiment, the “fouling determination rate” used in Equation 5 is corrected by the following Equation 10 and Equation 11, for example.
(Equation 10)
Upper fouling judgment rate = number of upper fouling / (number of upper fouling + number of lower fouling)
(Equation 11)
Lower fouling judgment rate = lower fouling number / (upper fouling number + lower fouling number)
Then, the “glass stain correction” of the upper and lower surfaces is calculated according to the equations 6 and 7, or the equations 8 and 9, or the “dirt determination rate” of the upper and lower surfaces is calculated and stored according to the equations 10 and 11. After (step S22), the count value (number) of the damaged coins is cleared (step S23), and the operation after counting the coins is finished.

  By setting it as the above embodiments, it becomes possible to identify a dirty coin and a normal coin (unstained coin) with high accuracy regardless of the presence or absence of a pattern on the coin surface. In addition, by providing the “dirt correction function” described above, it is possible to maintain stable stain detection capability even if the passage portion in the stain detection sensor is soiled with coin powder or the like. In addition, it is possible to reduce the frequency of the cleaning request (notification by screen display etc.) to the operator.

  In the following, with reference to the actual experimental results shown in FIG. 11, the reason why a damaged coin and a normal coin can be identified regardless of the presence or absence of a pattern on the coin surface will be described.

  FIGS. 11A and 11B show the distribution of the received light output of specular reflection light / diffuse reflection light in the fouling detection sensor 30. The vertical axis represents the output of the regular reflection sensor and the horizontal axis represents the output of the diffuse reflection sensor. The sensor output on the coin surface (front side) is indicated by “●” for current currency, “○” for new currency, and the sensor output on the reverse side of coin, “▲” for current currency, New coins are indicated by “△”. Moreover, the site | part of the coin surface (front side and back side) which extract | collected data is an annular | circular shaped site | part (12 site | parts) for every 30 degree | times. In this example, the irradiation light is a spot light having a diameter of about 3 mm, and the data of the front and back sides of the 500 yen coin new coin and current currency and the 1 yen coin new currency and current currency are collected. ing. Here, the explanation will be made assuming that the current currency is regarded as a corrupt currency and the new currency is regarded as a normal currency.

  Since the “patternless portion” of the coin does not diffuse even when exposed to light, the specular reflection component is large and the diffusion component is small. As a result, as shown in FIG. 11, the sensor output is distributed in the diagonally upper left direction. On the other hand, since the “patterned portion” of the coin is diffused when exposed to light, the specular reflection component decreases and the diffusion component increases. As a result, the sensor output is distributed in the diagonally lower right direction. In addition, when comparing the new currency and the current currency, the current currency is less glossy, so the reflection component of both regular reflection light and diffuse reflection light decreases, so the sensor output is distributed in the diagonally lower left direction, As a result, the distribution of the data of the new currency and the current currency is divided into an upper side and a lower side from the line segment La in FIG.

  Therefore, when sensor outputs of both regular reflection light and diffuse reflection light are used, if a contamination threshold value (for example, a contamination threshold value represented by a function obtained from the distribution of measured values) is set with the line segment La, the presence or absence of a pattern Regardless of the current currency (soiled currency) and new currency (normal currency) can be identified. On the other hand, in the conventional diffuse reflection method (method using only diffuse reflection light), when the contamination threshold is set with the line segment Lb, both the new coin and the current currency are distributed on both sides of the threshold, and therefore cannot be separated. I understand that. Even in the case of the regular reflection method (method using only regular reflection light), the new currency and the current currency are distributed on both sides of the threshold (line segment Lc) as in the case of the diffuse reflection method. I understand.

  In the above-described embodiment, the coin identification device mounted on the coin processor having the coin counting function has been described as an example. However, the present invention is not limited to the presence or absence of the counting function. That is, the coin identification device and the contamination detection sensor according to the present invention can be applied to all coin processing machines that require the detection of coin contamination, and can also be applied to arcade game machines using medals and the like. Moreover, the coin identifying device according to the present invention is not limited to identifying a damaged coin, but can also be applied as a device for identifying a new coin and a current currency. Furthermore, in the above-described embodiment, the unit of the fouling detection sensor has been described as an example in which the unit of the fouling detection sensor is integrally connected to the unit of the coin identification sensor. However, the unit can be independently installed in the conveyance path. . Moreover, although the denomination information of the coin discriminated by the upstream coin discriminating sensor has been described as an example received from the main discriminating unit, the image sensor (or magnetic sensor) discriminates the denomination by its own CPU. When it has a function, it is good also as a form which receives denomination information from an image sensor (or magnetic sensor).

It is a block diagram which shows an example of the whole structure of the coin identification device which concerns on this invention. It is a block diagram which shows an example of a structure of the contamination detection sensor which concerns on this invention. It is a side structure figure showing typically an example of the structure of the pollution detection sensor concerning the present invention. FIG. 4 is a perspective structural diagram illustrating an example of a unit structure of the contamination detection sensor of FIG. 3. It is a schematic diagram which shows an example of arrangement | positioning structure of the main sensors which the coin identification device which concerns on this invention has. It is a timing chart for demonstrating the signal taking-in timing of the contamination detection sensor which concerns on this invention. It is a figure for demonstrating the operation example of the whole coin identification device which concerns on this invention. It is a 1st flowchart for demonstrating the operation example of the pollution detection sensor which concerns on this invention. It is a 2nd flowchart for demonstrating the operation example of the pollution detection sensor which concerns on this invention. It is a 3rd flowchart for demonstrating the operation example of the pollution detection sensor which concerns on this invention. It is a figure for demonstrating the detection principle of the fouling coin in the fouling detection sensor which concerns on this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Coin identification apparatus 2 Coin 10 Coin identification sensor 11 Image sensor 12 Magnetic sensor 13 Timing sensor 20 Main identification part 21 Basic module 22 Control module 30 Fouling detection sensor 30a Upper surface pollution sensor module 30b Lower surface pollution sensor module 30c Passage part 30d Control means 31 Irradiation means (infrared LED)
32 1st light-receiving means (regular reflection sensor)
33 Second light receiving means (diffuse reflection sensor)
34 Light intensity monitoring means (monitor sensor)
35 Optical path conversion means (half mirror)

Claims (3)

  Irradiation means for irradiating light on the coin surface of the identification coin, first light receiving means for receiving regular reflection light from the coin surface of the light, and second light receiving means for receiving diffuse reflection light from the coin surface of the light Are integrated as at least a component, and each means of the first stain detection module and each means of the second stain detection module are The coin discriminating apparatus is characterized in that each optical axis is arranged to face the coin passage surface.   2. The coin identification according to claim 1, further comprising a control unit that corrects an output of a light receiving sensor as the first and second light receiving units based on a result of determination of contamination on the upper and lower surfaces of the identification coin. apparatus.   Outputs of light receiving sensors as the first and second light receiving means based on the light receiving signal of the light receiving means on the opposite side that has received the irradiation light from the irradiation means that has passed through the light transmitting passage through which the identification coin passes. 3. The coin identifying device according to claim 1, further comprising a control unit that corrects a dirt component caused by dirt of the light-transmitting passage included in the light-transmitting passage.

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