JP2013003673A - Coin selector - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a coin selector including a thread suspension preventing device capable of preventing fraudulent counting by a coin suspended by thread.SOLUTION: A true coin TC supplied to a coin entrance 108 is held by a pair of pawls of a cradle, is moved in a transverse direction by turning of the cradle, and falls onto a guide rail. The fallen true coin rolls on the guide rail, then falls down from the guide rail, and collides with an upward slope of an anvil at a prescribed speed. The true coin which has collided bounces back to reach a receiving path, passes through a cotton checker, falls down from a true coin port 144, and is then detected by a count sensor 242. When a true coin suspended by thread is pulled up, it gets in between coils of a coil spring 124 at a guide rail end and is held between them by close contact force of the coils. Since the coin suspended by the thread cannot be moved vertically due to holding force of the coils, it is impossible to make the count sensor perform fraudulent detection.

Description

The present invention relates to a coin selector that is used in a vending machine, a game machine, and the like, and discriminates and sorts whether a coin is true or false.
More specifically, the present invention relates to a coin selector having a so-called device that can prevent thread fishing, in which a tengu thread or the like is connected to a coin and a sensor unit of the coin selector is reciprocally moved to illegally count the number of true coins.
More specifically, the present invention relates to a coin selector having a thread fishing prevention device in a coin selector that mechanically discriminates and sorts coins.
The “coin” used in this specification includes coins as a currency as well as substitute coins such as game medals and tokens.

  As a first conventional technique for preventing line fishing, coins inserted from a coin insertion slot roll on a coin rail and are then guided to a coin sensor. However, the coin V is placed on the shortest path between the coin rail and the coin sensor. It is known to arrange a character-shaped thread trimming board and cut a fishing line connected to a coin by the thread trimming board (see, for example, Patent Document 1).

  As a second conventional technique for preventing line fishing, a pressing member made of soft rubber and sponge is arranged between the coin rail and the coin sensor, and the fishing line of the thread fishing coin is sandwiched so that the fishing line cannot be moved up and down. It is known to prevent repeated fraud (see, for example, Patent Document 1).

   As a third conventional technique for preventing line fishing, it is known to use the thread cutting plate in the first conventional technique as a cutter (see, for example, Patent Document 1).

62-199881 (Figures 5 and 10, pages 2-5)

  In the first prior art, when the cutting performance of the thread trimming plate deteriorates, the cut thread remains sandwiched between V-shaped thread trimming plates. Thereafter, when a line fishing coin is inserted, the fishing line overlaps with the previous fishing line, so that the subsequent fishing line does not come into contact with the thread trimming plate, so that it may not be cut. As a result, there is a problem in that the later thread fishing coins are moved up and down and illegally counted.

  In the second prior art, when one thick fishing line is sandwiched between pressing members, when the fishing line of coins inserted later is thin, the fishing line slides up to the front thick fishing line and can freely move up and down. As a result, there is a problem in that the later thread fishing coins are moved up and down and illegally counted.

 In the third prior art, the fishing line is cut by the cutter, so that the fringing by the later fishing coin is enabled by the protective action of the previous fishing line as in the first prior art and the second prior art. Can be prevented. However, since the cutter is used, there is a risk that an operator may be injured during the manufacturing process or maintenance of the coin selector, and it cannot be used as a bag.

A first object of the present invention is to provide a coin selector including a line fishing prevention device that can prevent unauthorized counting by a line fishing coin.
A second object of the present invention is to provide a coin selector provided with a line fishing prevention device that is not injured and that can prevent illegal counting by a line fishing coin.
The third object of the present invention is to provide a coin selector equipped with a thread fishing prevention device that can be retrofitted without injury and is low in cost and can prevent unauthorized counting by thread fishing coins. It is to be.

In order to achieve this object, the coin selector provided with the line fishing prevention device according to the present invention is configured as follows.
The first invention is a vertically extending coin path defined by a flat backboard and a movable guide board that are vertically opposed to each other with an interval slightly larger than the coin thickness, and formed at the upper end of the coin path. A coin entrance, a cradle disposed below the coin entrance, and a guide rail disposed obliquely below the cradle, and a coin inserted from the coin entrance rolls on the guide rail. In the coin selector that is free to fall obliquely downward from its tip under its own weight and guided to a receiving passage or a return passage positioned below the coin passage in the course of the free fall, A thread fishing prevention device characterized in that a coil spring formed by adjoining adjacent windings is disposed at the downstream end. A coin selector equipped with.

  The second invention is characterized in that, in the first invention, the coil spring has a wire diameter of 0,25 to 0,3 mm.

In the first aspect of the invention, the true coin thrown into the coin entrance falls through the coin passage and is held in the cradle, and is further rolled laterally by a moment acting on the cradle and transferred onto the guide rail. The The true coin rolling on the guide rail rolls on the guide rail and the coil spring continuously arranged on the guide rail at a predetermined speed and falls from the end of the coil spring. The genuine coins dropped at a predetermined speed reach the receiving passage through a predetermined path, and then are detected by the count sensor, and then dropped and held in the safe. The fake coins reach the return passage through a predetermined route and are returned.
When the line fishing correct coin is inserted and reaches the receiving passage, after passing through the count sensor, the fishing line is pulled up and then pulled back over the count sensor to the receiving passage. At this time, the tension of the fishing line increases, and the coil spring is located between the windings in the extending direction of the fishing line, so that the coil spring enters between the windings and is sandwiched and held by the adjacent windings. As a result, the coin cannot be counted again illegally because it cannot fall again due to its own weight.
When a different line fishing coin is inserted, the coin inserted later will be located to the side of the previous line fishing coin, so the position of the fishing line may contact the coil spring at a position different from the previous line fishing coin. Is expensive. As a result, the fishing line is held between different windings. Therefore, the number of coins is not illegally counted.

  In the second invention, the coil spring has a wire diameter of 0,25 to 0,3 mm. The spring constant of the coil spring is proportional to the fourth power of the wire diameter. In other words, the deformation force of the spring increases in proportion to the fourth power of the wire diameter, making it difficult for the fishing line to enter between the windings. On the other hand, when the spring constant is small, the holding force due to the pressure contact force between the windings is small, and the coins also move up and down as the fishing line moves up and down, preventing illegal counting. Furthermore, if the wire diameter is significantly smaller than the fishing line, the fishing line may not be able to enter between the windings. However, it has been confirmed that there is no problem in entering and holding the fishing line between the windings when the diameter of the spring winding is about 0.3 mm.

FIG. 1 is a perspective view of a coin selector according to an embodiment of the present invention.
FIG. 2 is a front view of the coin selector according to the embodiment of the present invention.
FIG. 3 is a perspective view of the coin selector according to the embodiment of the present invention with the movable guide plate opened.
FIG. 4 is a schematic view of a coin passage of the coin selector according to the embodiment of the present invention.
FIG. 5 is a sectional view taken along line XX in FIG.
6 is a cross-sectional view taken along line YY in FIG.
FIG. 7 is an explanatory diagram of the operation of the coin selector according to the embodiment of the present invention.
FIG. 8 is an operation explanatory view of a coil spring in the coin selector of the embodiment of the present invention.

  A coin path extending in the vertical direction defined by a flat backboard and a movable guide board vertically opposed to each other with a distance slightly larger than the thickness of the coin, a coin inlet formed at the upper end of the coin path, and A cradle disposed below the coin entrance; and a guide rail disposed obliquely below the cradle. Coins inserted from the coin entrance roll on the guide rail and are inclined by their own weight from the leading end. In a coin selector that is allowed to fall freely downward and guides and selects a receiving passage or return passage located below the coin passage in the course of the free fall, an adjacent winding is provided at the downstream end of the guide rail. Coil springs are formed in which the wires are substantially closely attached, and the coil spring has a wire diameter of 0,25 to 0,3 mm. It is a coin selector provided with the line fishing prevention device characterized by these.

Next, an embodiment will be described with reference to FIGS.
The coin selector 100 according to the present embodiment roughly includes a fixed guide board 102, a movable guide board 104, a coin passage 106, a coin inlet 108, a cradle 112, a guide rail 114, a fixed magnet 116, a receiving passage 118, a return passage 122, and a coil. A spring 124 is included. Of the above configuration, the other components except the coil spring 124 are known and will be described briefly.

First, the fixed guide board 102 will be described.
The fixed guide board 102 constitutes one surface of the coin passage 106 that extends in the vertical direction and has a function of fixing the movable guide board 104 and other components.
The fixed guide board 102 has a flat back board 126 arranged vertically, and a left side board 126L and a right side board 126R that are bent at both sides at a right angle forward.
The fixed guide board 102 can be integrally formed with a back board 126, a left side board 126L, and a right side board 126R by pressing a metal such as iron or a resin having a predetermined wear resistance and strength. In this embodiment, the resin is integrally molded.
The backboard 126 is a rectangular flat plate that is suspended.
Two cylindrical locking pins 128A, 128B and 132A, 132B project laterally from the left side board 126L and the right side board 126R, respectively, and are fixed to the bracket in the game machine (not shown). Stopped. Thereby, the coin selector 100 is built in a game machine or the like.
From the middle of the right side board 126R to the left side board 126L side, the first bearings 134A and 134B that are projected vertically at a predetermined interval vertically to the fixed shaft 136 attached to the middle near the upper and lower ends respectively. Shaft support portions 140A and 140B formed at the upper and lower ends of the right end portion of the plate-shaped movable guide board 104 are rotatably attached.

Next, the movable guide board 104 will be described.
The movable guide board 104 defines one surface of the coin passage 106 opposite to the back board 126, and has a function to which the cradle 112, the guide rail 114, the fixed magnet 116, and the coil spring 124 are attached.
In this embodiment, the movable guide board 104 is integrally formed of resin and is an inverted trapezoidal flat plate, and is parallel to the bag board 126 at a predetermined interval in the upper half between the right side board 126R and the left side board 126L. Placed in.
Specifically, the movable guide board 104 can be rotated in the horizontal direction with the fixed shaft 136 as a fulcrum at the right end, but is rotated toward the back board 126 by the spring 138 and the L-shaped portion 142 at the left end is backed. It strikes the board 126 and stops.
As a result, the back board 126 and the movable guide board 104 are arranged in parallel at an interval slightly larger than the thickness of the coin to form a coin passage 106 extending vertically in the vertical direction.

Next, the coin passage 106 will be described.
The coin passage 106 has a function in which the coin C inserted into the coin entrance 108 rolls or falls and is guided to the genuine coin port 144 or the false coin port 146.
The coin passage 106 is mainly defined by the back board 126, the right side board 126R, the left side board 126L, the movable guide board 104, and the front cover 130.

Next, the coin entrance 108 will be described.
The coin entrance 108 is an entrance for a coin C formed at the upper end of the coin passage 106.
The coin entrance 108 is formed at the upper end of the left end of the movable guide board 104 and the first recess 148 having a predetermined length in the lateral direction formed at the upper end of the left end of the backboard 126. It is demarcated and formed by a second recess 152 having a rectangular lower concavity. In other words, the coin inlet 108 is a passage extending in the up-down direction of a horizontally long slit shape that is located in the vicinity of the left side board 126L at the upper left end of the coin selector 100 and is formed in a lower recess. In other words, it is a slit-shaped opening formed by the first recess 148 and the second recess 152 to have a thickness and length slightly larger than the thickness and diameter of the coin C to be inserted.
As a result, the approximate coin diameter and coin thickness are selected at the coin entrance 108.
More specifically, as shown in FIG. 3, the diameter restricting piece 156 having the first guide surface 154 that is adjacent to the L-shaped portion 142 and is inclined toward the upper left is extended in the lateral direction of the movable guide board 104. It is fixed to the movable guide board 104 by a screw 162 that passes through the hole 158.

In the range of the long hole 158, the diameter regulating piece 156 can adjust the distance from the regulating surface 164 of the movable guide board 104 facing the diameter regulating piece 156.
That is, the minimum distance between the diameter restricting piece 156 and the restricting surface 164, that is, the length L is set slightly larger than the diameter of the selected coin C.
The thickness of the coin entrance 108 is set slightly larger than the thickness of the selected coin C.
Therefore, in FIG. 4, a coin having a diameter larger than the length L of the coin inlet 108 or a coin having a large thickness cannot pass through the coin inlet 108 and is primarily sorted.

Next, the cradle 112 will be described.
The cradle 112 has a function of selecting the genuine coin TC and the fake coin FC according to the diameter and weight of the coin C.
A known cradle 112 having a first claw 166A and a second claw 166B arranged at a predetermined interval is arranged immediately below the coin entrance 108.
The cradle 112 is rotatably attached to a second fixed shaft 168 that protrudes laterally on the front side of the movable guide board 104, and is formed on the movable guide board 104. The first cradle 112 forms an arc around the second fixed shaft 168. It protrudes to the coin passage 106 through the arc hole 172A and the second arc hole 172B, but its tip is located at a position close to the bag board 126.
When the true coin TC is held on the first claw 166A and the second claw 166B of the cradle 112, a predetermined moment acts on the cradle 112 counterclockwise in FIG. Moved.
The counterfeit coin FC smaller in diameter than the genuine coin TC is not held on the first claw 166A and the second claw 166B, so it falls directly below, and guides the cancellation path 230 on the front side by the baffle plate 160 located below it, It rolls on the inclined bottom wall 246 of the cancel passage 244 and falls from the cancel port 248.
Even if the diameter is the same as the true coin TC, if the weight is lighter than the true coin TC, a predetermined moment does not act on the cradle 112, so the cradle 112 does not rotate counterclockwise and stagnates.
Even if the diameter is the same as the true coin TC, if the weight is heavier than the true coin TC, a moment greater than a predetermined value acts, so the cradle 112 is rotated counterclockwise at a predetermined rotation speed or more, It rolls on the guide rail 114, and the amount of rebound by an anvil 222, which will be described later, is small and falls to the false coin port 146 via the return passage 122.

Next, the guide rail 114 will be described.
The guide rail 114 has a function of rolling and guiding the coin C (true coin TC) dropped by the rotation of the cradle 112.
As shown in FIG. 4, the guide rail 114 is disposed obliquely below the side on which the cradle 112 is rotated and is formed linearly.
In this embodiment, the guide rail 114 is constituted by a guide rail piece 170 and an upper surface of a coil spring 124 described later.
The guide rail piece 170 is a rectangular small piece of resin having wear resistance such as polyacetal. The guide rail piece 170 has a thickness of 2.5 mm, and a slider 174 that can slide in a straight long hole 172 formed in the movable guide board 104 is integrally formed on the side surface, and a flat washer is formed from the front side of the movable guide board 104. A flat washer 176 is pressed against the movable guide board 104 by screwing a screw 178 into the slider 174 through 176 and is fixed at a predetermined position.
The straight elongated hole 172 is inclined at a predetermined angle so as to descend in a direction away from the cradle 112.
Therefore, the guide rail piece 170 is also arranged so as to be inclined at a predetermined angle in the same direction, that is, on the left side in FIG. 4, and the position can be adjusted within the range of the straight elongated hole 172. The guide rail piece 170 may be made of metal. The upper surface 182 of the guide rail piece 170 and the upper surface of the coil spring 124 are arranged in a straight line.

Next, the fixed magnet 116 will be described.
The fixed magnet 116 causes a magnetic force to act on the coin C rolling on the guide rail 114, and an internal electromotive force generated in the coin C due to the magnetic force generates a magnetic force in the coin C so that the two magnetic forces attract each other. As a result, a braking force is applied to the coin C. Thereby, the true coin TC is selected based on the conductive characteristics of the material of the true coin TC and the false coin FC.
The fixed magnet 116 is fixed to the bracket 184.
The bracket 184 has a right end rotatably attached to the fixed shaft 136 and is urged toward the movable guide board 104 by a spring 138.
A guide portion 186 formed in the shape of a rectangular block is provided in the middle of the bracket 184, and part of the movable guide board 104 is advanced and retracted into a rectangular opening 188 formed partially above the guide rail 114. The side surface 192 faces the coin passage 106.
The distance between the guide portion 186 and the backboard 126 is slightly smaller than the thickness of the coin C by contacting the screw 194 screwed into the tip of the bracket 184 with the head of the fixed shaft 185 protruding from the movable guide board 104. It is set large.
That is, the coin path 106 is between the side surface 192 of the guide portion 186 and the backboard 126.
A circular second opening 180 is formed in the backboard 126 facing the fixed magnet 116, and a disk-shaped magnetic material, for example, an iron magnetic reinforcement 190 is fixed.
By disposing the magnetic force reinforcing body 190 relative to the fixed magnet 116, a magnetic flux path can be secured and the magnetic force of the fixed magnet 116 can be effectively applied to the coin C.

A pair of first push rods 191A and second push rods 191B projecting laterally from the front end of the bracket 184 to the backboard 126 side are provided. The push bar 191A is disposed so as to be able to enter the coin passage 106 through the opening 193A formed in the movable guide board 104 with respect to the coin passage 106 at the coin entrance 108.
Normally, the tips of the first push bar 191A and the second push bar 191B do not protrude into the coin passage 106, but are retracted into the second opening 193A and the third opening 193B.
The second push bar 191B is disposed between the pair of first claws 166A and the second claws 166B of the cradle 112 so as to be able to enter the coin passage 106 through a third opening 193B formed in the movable guide board 104. Yes.
The movable guide board 104 has a pin 198 that protrudes from the cancel lever 196 on the inner surface of the movable guide board 104 when the tip of the cancel lever 196 that is rotatably attached to the shaft 194 fixed to the back surface of the back board 126 is pushed downward. The formed cam 202 as an inclined surface is pushed and rotated so as to be separated from the backboard 126 with the fixed shaft 136 as a fulcrum.
At this time, since the bracket 184 is not moved, the guide portion 186, the first push rod 191A, and the second push rod 191B are held in their original positions and relatively protrude from the movable guide board 104.
As a result, the large-diameter coin C jammed between the diameter regulating piece 156 and the regulating surface 164 is pushed out by the first push rod 191A and dropped into the cancellation path 244 below, and as a result falls from the false coin port 146. .
Further, the coin C held in the cradle 112 is pushed out between the claws 166A and 166B by the push rod 191B and dropped into the lower cancel passage 244, and as a result, falls from the cancel port 248.

Next, the wiper 204 will be described.
The wiper 204 has a function of removing the coin C stagnated in the coin passage 106 from the coin passage 106, specifically, a function of removing the fake coin FC attracted to the fixed magnet 116 from the coin passage 106.
The wiper 204 is a cantilever lever that is rotatably supported at one end by a fixed shaft 185 that protrudes toward the movable guide board 104. A long hole 208 that is inclined at a portion close to the fixed shaft 185 is formed on the wiper 204. 198 is penetrated. When the wiper 204 is rotated, the tip of the wiper 204 is rotated to the front of the guide part 186, and the counterfeit coin FC adsorbed by the fixed magnet 116 is forcibly moved to release the relative state with the guide part 186. And drop by its own weight.
That is, when the pin 198 penetrating the long hole 208 formed in the wiper 204 moves downward, the wiper 204 is rotated counterclockwise in FIG. 4 to the front of the side surface 192 of the fixed magnet 116 in the coin passage 106. Can move.

Next, the coil spring 124 will be described.
The coil spring 124 has a function as a guide rail 114 and a function to prevent fraud due to fishing coins TC.
The coil spring 124 is preferably a round wire coil spring in which adjacent windings 200 are in close contact with each other with a predetermined force. This is because when the adjacent windings 200 are in close contact with each other, even if the fishing line is extremely thin, it can be held between the adjacent windings 200. The winding 200 is preferably made of metal. This is because even if it is forcibly pulled with a large force, it is not easily permanently deformed. Furthermore, it is preferable that the wire diameter is approximately the same as the thickness of the fishing line LC that is normally used. If the wire diameter is too thick, the spring constant becomes large, and the tension that pulls the fishing line LC cannot be inserted between the windings 200 where the fishing line LC is pressed, and the wire diameter is less than one-half that of the fishing line LC. In this case, the fishing line LC is placed on the winding 200 and is difficult to enter between the windings 200.
The coil spring 124 in this embodiment is a round wire made of stainless steel, and has a wire diameter of 0.3 mm and a winding diameter of 5 mm. The coil spring 124 has a predetermined length, in this embodiment. Cut to 7 mm. However, the wire diameter is preferably in the range of 0,25 to 0,3 mm.
The coil spring 124 is fixed to the movable guide board 104. Specifically, the slider 174 is fixed by being inserted into a circular mounting hole 212 formed at the inclined lower end portion. Specifically, the mounting hole 212 is formed to have a hole diameter slightly smaller than the outer diameter of the coil spring 124. Accordingly, the outer diameter is reduced by turning one end of the coil spring 124 toward the mounting hole 212 in the winding direction, so that the coil spring 124 can be inserted into the mounting hole 212. Then, if the rotation in the winding direction is stopped, the outer diameter is returned to the original outer diameter, so that the outer surface of the coil spring 124 comes into close contact with the inner surface of the mounting hole 212 and is fixed. The free end of the coil spring 124 is in intimate contact with the surface of the backboard 126.
Therefore, when the fishing line comes into contact with the peripheral surface of the coil spring 124 with a predetermined LC tension, the adjacent winding 200 is deformed and enters between them. As a result, the fishing line LC is sandwiched with a predetermined force by the spring force of the winding 200 and held. Accordingly, by setting the holding force to exceed the weight of the coin C, the coin C pulled up by the fishing line LC cannot fall downward due to its weight.
Therefore, by using the slider 174 having the mounting hole 212, the coil spring 124 can be easily retrofitted.
In addition, it is preferable that the backboard 126 part facing the free end of the coil spring 124 is recessed in a concave shape. This is to stabilize the resistance of the coil spring 124 when the fishing line LC enters between the windings 200.

Next, the receiving passage 118 will be described.
The receiving passage 118 is a passage through which the true coin TC falls, and a lower end is the genuine coin port 144.
The receiving passage 118 is formed on the right side in FIG. 4 of the sorting plate 216 extending below the movable guide board 104 of the L-shaped plate 214 fixed to the back surface of the back board 126 so as to be adjustable. 126, a vertical flat space surrounded by the right side board 126R and the flat front cover 130.
The left side of the sorting plate 216 is a return passage 122, and the lower end thereof is a counterfeit coin 146.
The return passage 122 is a vertical flat space surrounded by the backboard 126, the left sideboard 126L, and the front cover 130.
The sorting plate 216 is adjusted in position in the lateral direction (the width direction of the backboard 126) so as to be sorted into the genuine coin TC and the fake coin FC, and is fixed at a predetermined position.

Next, the anvil 222 will be described.
The anvil 222 has a function of selecting whether it is a genuine coin TC or a fake coin FC by the rebound determined by the collision speed, material, weight, etc. of the coin C that has fallen obliquely downward from the guide rail 114. Have.
The anvil 222 is made of a triangular metal that is fixed to the backboard 126 adjacent to the right sideboard 126R.
Anvil 222 has an upward slope 224.
The coin C that has fallen obliquely downward from the guide rail 114 collides with the upward slope 224 of the anvil 222 and rebounds by a predetermined amount at a predetermined angle.
As a result of the rebound, the coin C that has reached the receiving passage 118 on the right side of the sorting plate 216 falls as the true coin TC from the true coin port 144.
The coin C that has fallen into the return passage 122 on the left side of the sorting plate 216 falls from the false coin port 146 as a false coin FC.

The coin passage 106 of the genuine coin TC is a route that reaches the guide rail 114, the receiving passage 118, and the genuine coin entrance 144 from the cradle 112 through the coin entrance 108.
The coin passage 106 of the false coin FC is a route that reaches the false coin mouth 146 from the guide rail 114 and the return passage 122.

Next, the cotton checker 226 will be described.
The cotton checker 226 has a function of preventing the threaded coin LC from being pulled up to the coin inlet 108 side above the genuine coin port 144.
The cotton checker 226 includes a regulating body 228 and a rocking body 232.
The restricting body 228 is a rod body that protrudes from the center lower end of the front cover 130 toward the backboard 126 side. In other words, the regulating body 228 substantially connects the front cover 130 and the back board 126 immediately below the sorting plate 216.

Next, the oscillator 232 will be described.
The oscillating body 232 is movable so as to allow the genuine coin TC to fall from the genuine coin port 144, but has a function of not moving so as not to be pulled up from the true coin port 144 to the receiving passage 118.
The rocking body 232 is a triangular plate whose upper end is rotatably supported by a third fixed shaft 234 that protrudes laterally from the backboard 126 toward the front cover 130, and receives no force from the outside. The distance between the tip (lower end) 236 and the regulating body 228 is smaller than the diameter of the true coin TC. When the true coin TC falls, the rocking body 232 is pushed and rotated by the true coin TC, the distance between the regulating body 228 and the tip 236 is wider than the diameter of the true coin TC, and the true coin TC passes between them. Can fall.
When the genuine coin TC that has been converted into the genuine coin port 144 is pulled up to the genuine coin port 144, the genuine coin TC is engaged with the tip 236, and the rocking body 232 is rotated clockwise in FIG. The protruding stopper pin 238 is locked to the lower end portion of the backboard 126 and cannot rotate.
As a result, the true coin TC cannot pass between the regulating body 228 and the tip of the rocking body 232 and cannot be pulled up. As a result, the tension of the fishing line LC increases.

Next, the count sensor 242 will be described.
The count sensor 242 has a function of detecting a genuine coin TC that is fixedly disposed below the genuine coin port 144 at a predetermined distance from the genuine coin port 144, and that outputs a signal for counting. Have
As the count sensor 242, various sensors such as a photoelectric type, an electromagnetic type, and a micro sensor can be used.
Therefore, the count signal for counting the passed true coin TC is illegally output by moving the true coin TC that has passed through the cotton checker 226 up and down to detect or not detect the count sensor 242. .

Next, the operation of this embodiment will be described.
First, a case will be described in which a bronze coin having low conductivity, for example, a genuine coin TC, which is a 100 yen coin, is inserted into the coin entrance 108.
The true coin TC inserted into the coin entrance 108 falls vertically downward and is supported by the first claw 166A and the second claw 166B of the cradle 112. Thereby, a counterclockwise moment in FIG. 4 acts on the cradle 112 and rotates in the same direction.
By this rotation, the center of gravity of the true coin TC moves to the left rather than vertically above the second claw 166B, so that the true coin TC gets over the second claw 166B and rolls down.
The rolled coin TC first rolls on the upper surface 182 of the guide rail piece 170 and then rolls on the upper surface of the coil spring 124. In this rolling process, due to the internal electromotive force generated by the magnetic force of the fixed magnet 116, a predetermined braking force corresponding to the material acts on the true coin TC and falls from the coil spring 124 to the lower left at a predetermined speed.
The falling genuine coin TC falls in a parabolic shape, collides with the upward slope 224 of the anvil 222, and bounces upward. As a result, the true coin TC reaches the receiving passage 118 over the sorting plate 216 and falls from the true coin port 144. The true coin TC dropped from the true coin port 144 is detected by the count sensor 242.

Next, a description will be given of an abnormal time such as when the inserted coin C is jammed.
When the coin C is jammed in the coin entrance 108 or the cradle 112, the cancel lever 196 is pushed down. As a result, the tip of the pin 198 pushes the cam 202 having an inclined surface, so that the movable guide board 104 is separated from the back board 126 against the spring 138. When the movable guide board 104 is moved, the first push rod 191A or the second push rod 191B formed at the tip of the bracket 184 is in a stationary state, so the first push rod 191A or the second push rod 191B is relatively Protrudes toward the coin passage 106 from the movable guide board 104. Due to this protrusion, the coin C held on the first claw 166A and the second claw 166B of the cradle 112 is pushed out by the tip of the second push rod 191B and dropped into the cancel passage 244, and dropped from the cancel port 248. It is done.
The large-diameter coin C jammed in the coin inlet 108 is pushed out by the tip of the first push rod 191A, dropped into the cancel passage 244, and dropped from the cancel port 248.

Next, the diameter, thickness, and weight are the same as those of the genuine coin TC, and when the iron fake coin FC is inserted, the fake coin FC is attracted to the side surface 192 of the guide portion 186 by a magnetic force and is stopped.
When the cancel lever 196 is pushed down, the wiper 204 is rotated counterclockwise in FIG. 4 through the long hole 208 due to the downward movement of the pin 198, and the periphery of the false coin TC adsorbed on the guide portion 186 is rotated. The surface is pushed down to be removed from the relative to the side surface 192 of the guide part 186, dropped into the cancellation path 244 below, and dropped from the false coin port 146.

Next, a case where a copper fake coin FC having high conductivity, for example, is inserted will be described.
The conductive false coin FC is guided by the upper surfaces of the cradle 112, the guide rail 114, and the coil spring 124 as described above and falls obliquely downward.
However, because it is highly conductive, it will not be attracted to the fixed magnet 116, but the internal electromotive force is large and it receives a large braking force, so the collision speed to the upward inclined surface 218 is small and the rebound is small. It falls to the passage 122 and falls from the false coin outlet 146.

Next, a case of fraud with a fishing line coin TC in which a true coin TC is connected to a fishing line LC will be described with reference to FIGS.
When the thread fishing true coin TC is inserted, it falls from the true coin port 144 as in the case of the true coin TC, and is detected by the count sensor 242 to output a signal for counting.
Thereafter, when the fishing line LC is pulled up, the true coin TC is prevented from moving upward by the regulating body 228 and the tip 236 of the rocking body 232. As a result, the tension of the fishing line LC increases and the fishing line LC is positioned to take the shortest distance.
Thus, with respect to the coil spring 124 located at the downstream end of the guide rail 114, the first straight line L1 tangent to the true coin TC and the coil spring 124, and the second tangent to the second claw 191B and the coil spring 124 Since the fishing line LC contacts at an obtuse angle with the straight line L2, it is pressed against the outer peripheral surface of the coil spring 124 by the resultant force F1 of the tensions T1 and T2 along the first straight line L1 and the second straight line L2.
As a result, the fishing line LC pushes the windings 200 of the coil spring 124, travels between them, and is held between the windings 200 with a predetermined force by the return force of the windings 200.
Since this holding force is larger than the downward moving force due to the weight of the true coin TC, the fishing line LC is held by the winding 200, and as a result, the fishing line coin TC cannot move downward due to its own weight.
Therefore, it is not possible to perform fraud in which the fishing line LC is moved up and down and the count sensor 242 outputs a count signal.

The present invention can be modified in various ways.
For example, the fixed magnet 116 can be omitted.

C coin
104 Movable guide board
106 Coin passage
108 coin entrance
112 cradle
114 Guide rail
118 Receiving passage
122 Return passage
124 coil spring
126 Backboard
200 windings

FIG. 1 is a perspective view of a coin selector according to an embodiment of the present invention. FIG. 2 is a front view of the coin selector according to the embodiment of the present invention. FIG. 3 is a perspective view of the coin selector according to the embodiment of the present invention with the movable guide plate opened. FIG. 4 is a schematic view of a coin passage of the coin selector according to the embodiment of the present invention. FIG. 5 is a sectional view taken along line XX in FIG. 6 is a cross-sectional view taken along line YY in FIG. FIG. 7 is an explanatory diagram of the operation of the coin selector according to the embodiment of the present invention. FIG. 8 is an operation explanatory view of a coil spring in the coin selector of the embodiment of the present invention.

Claims (2)

A coin passage (106) extending in the vertical direction defined by a flat backboard (126) and a movable guide board (104) arranged vertically opposite to each other with an interval slightly larger than the thickness of the coin (C);
A coin inlet (108) formed at the upper end of the coin passage (106), and a cradle (112) disposed below the coin inlet (108),
A guide rail (114) disposed obliquely below the cradle (112),
The coin (C) inserted from the coin entrance (108) rolls on the guide rail (114) and can freely fall obliquely downward from its tip by its own weight, and the coin path in the course of the free fall In the coin selector that guides and selects the receiving passage (118) or the return passage (122) located below (106),
A coin selector provided with a fishing line prevention device, characterized in that a coil spring (124) in which adjacent windings (200) are formed in close contact with each other is arranged at the downstream end of the guide rail (114). .   2. The coin selector provided with a fishing line prevention device according to claim 1, wherein the coil spring (124) has a wire diameter of 0, 25 to 0, 3 mm.

Images