KR101028444B1 - Coin processing device - Google Patents

Abstract

A first object of the present invention is to provide a coin processing device that does not cause coin jams in storing and returning of coins by securing a smooth operation even when a plurality of coins having different diameters are suspended. The object is to provide an inexpensive and reliable hardening processing apparatus in which imported purge can be withheld, and the storage and return ports of the purged purge are disposed on the lower surface of the apparatus. It is possible to provide a coin treatment device that can hold a purge and can be replaced with a coin treatment device which is a defect standard by arranging the storage opening and the return port of the reserve coin on the lower surface of the device.

In order to achieve this object, the coin processing device according to the present invention is configured as follows. The authenticity of the coin (C) injected into the inlet (104) is discriminated and selected by import hardening (TC) and return hardening (FC), and the import hardening is placed above the payload placed in the lower part from the import port 334 and the payload. Moreover, it is arrange | positioned at the side and selectively imports and hold | holds to the holding | maintenance apparatus 124 comprised by the pair of support bodies 132 and 134 which move to holding positions SP1 and SP2 and non-holding positions CP2 and RP, In the coin processing device in which the holding coin is selectively fed to the storage port 106 or the return port 108 by selectively moving to the holding position and the non-holding position of the pair of supports, the payload is the upper portion. It is attached to the oscillator 225 freely rotatable about the support point, and the pair of supports are individually moved to the holding position and the non-holding position, and the payload is moved to the non-holding position of the support. A curing device for being drawn by moving together in the direction of the movement.

Input port, storage port, return port, detection passage, coincidence detection sensor, distribution passage, return passage, distribution body, holding device, holding room

Description

Hardening Equipment {COIN PROCESSING DEVICE}

The present invention relates to a coin processing device capable of determining the authenticity of a coin and returning the coin to be returned, withholding the coin to be imported, and storing or returning the retained coin according to the selected treatment.

In detail, it is possible to determine the authenticity of the coin and return the counterfeit to be returned, and to withhold the purge to be imported, and to send the deferred coin to the storage or return port arranged on the floor according to the selected treatment. It is related with the hardening processing apparatus.

More specifically, a coin that can determine the authenticity of a coin of different diameters and return the counterfeit to be returned, withhold a purge of differing diameters to be imported, and send the hold coin to a receiving or return port according to the selected treatment. It relates to a processing device.

The present invention also relates to a coin processing device capable of determining the authenticity of a coin and returning a counterfeit to be returned, withholding a purge to be imported, and smoothly supplying the pending coin to a storage or return port according to a selected process.

Moreover, the coin processing device which concerns on this invention can be used for a coin operated game machine, a vending machine, etc.

In this specification, "hardening" is a general term of hardening | curing as a currency, the medal of a game machine, a token, etc.

The prior art is described with reference to FIGS. 17 and 18.

The hardening C is thrown in from the inlet 12 formed in the upper left surface of the sorting apparatus 10, the hardening discrimination information is acquired by the sensor 14, and the authenticity of the injected hardening is judged based on the said discriminating information.

When it is determined that it is imported hardening purification (TC), the gate 16 enters the hardening passage 18 and leads to the purification passage 20, and when the gas is not imported, the gate 16 is hardened. Exit from (18) and return to return port 22.

Imported purification TC is arranged in the thickness direction between the storage openings 24, and the holding chamber 26 holding the inclined bottom 28 toward the second inclined end wall 32 from the first inclined end wall 30. Slit-shaped purification inlet 34 having a width corresponding to the purification thickness is provided at a position adjacent to the upper end of the first inclined end wall 30 and is inclined downward with respect to the horizontal, and the center of the purification inlet 34 ( The water line L1 passing through the center is configured to hang on the second inclined end wall 32, and the inclined bottom 28 is an upper end of the purification import ramp 36 inclined downward toward the storage opening 24. And the upper end of the purification return ramp 38 inclined downward in the opposite direction toward the return opening 22, and is formed by the intersecting ridge line.

First gate pins 40 protruding into the holding chamber 26 on both sides of the inclined bottom 28 and on both sides of the inclined bottom 28 and the purification return inclined passage 36 of the inclined bottom 28; Up and down movement is provided freely by interlocking with the second gate pins 42, thereby keeping the purification TC held in the holding chamber 26 on the inclined bottom 28 and holding one gate pin. A purifying accumulation type coin sorting device is known in which a holding purge TC is fed to the storage port 24 or the return port 22 by moving the other gate pin downward from the holding fat and upward from the position (for example, See Patent Document 1.).

Since the first gate pin 40 and the second gate pin 42 are attached to a lever capable of swinging with an upper support point as an axis, the first gate pin 40 and the second gate pin 42 interlock with each other and hold hardened. Arcs move along the outer edge of the gate, one gate pin moves downward to approach the inclined bottom from the holding position, and the other gate pin moves upward from the holding position and contacts above the center of hardening. In this case, the retention hardening falls to the side to be pressed against the ridgeline.

[Patent Document 1]: Japanese Utility Model Publication Hei 6-7433 (FIGS. 1 to 3 and 2 to 3 pages)

This prior art has the advantage of being able to suspend the authenticity and purification of the curing in a 3.5-inch-wide size, which is the standard standard in the technical field of the curing treatment.

However, since the prior art targets one type of hardening, when the hardening of different diameters is to be held, the first gate pin 40 and the second gate pin 42 cannot be moved smoothly. There exists a problem that a return of hardening or a bad storage occurs.

This will be described with reference to FIG. 20.

When large diameter purification (TCL) and small diameter purification (TCS) are held together, the largest diameter purification (TCL) is positioned at the bottom end on the inclined bottom 28, while the small diameter purification (TCS) is out of the bottom end. Is supported by the inclined bottom 28 and is held.

In the situation shown in FIG. 20, when the small diameter purge TCS is moved to the storage opening 24 side, the small diameter purge TCS is moved by the movement of the first gate pin 40 to the inclined bottom 28 and the first. It becomes a movement like sandwiched between one gate pin 40, and smooth storage is not possible.

In the worst case, there is a problem that the small-diameter purification (TCS) is sandwiched between the inclined bottom 28 and the first gate pin 40 so that the first gate pin 40 is locked to cause coin jam.

In addition, it is required to simplify the structure and to provide at low cost.

In addition, as shown in Fig. 18, the inlet 12 is disposed on the upper left side of the upper surface of the apparatus, and the receiving opening 24 and the returning opening 22 are adjacent to the lower surface.

Since the storage opening 24 of the prior art is disposed on the right side of the apparatus, there is a problem that it cannot be replaced by a defect standard hardening apparatus.

A first object of the present invention is to provide a coin processing device that does not cause coin jams in storing and returning of coins by ensuring a smooth operation even when a plurality of coins of different diameters are suspended.

A second object of the present invention is to provide an inexpensive and highly reliable hardening treatment apparatus which can hold the imported purification and arranges the storage port and the return port of the pending purification on the lower surface of the apparatus.

A third object of the present invention is to provide a coin processing device which can hold the imported purification and can be replaced with a coin processing device that is a defect standard.

In order to achieve this object, the coin processing device according to the present invention is configured as follows. The authenticity of the coin (C) injected into the inlet (104) is discriminated and selected by import hardening (TC) and return hardening (FC), and the import hardening is placed above the payload placed in the lower part from the import port 334 and the payload. Moreover, it is arrange | positioned at the side and selectively imports and hold | holds to the holding | maintenance apparatus 124 comprised by the pair of support bodies 132 and 134 which move to holding positions SP1 and SP2 and non-holding positions CP2 and RP, In the coin processing device in which the holding coin is selectively fed to the storage port 106 or the return port 108 by selectively moving to the holding position and the non-holding position of the pair of supports, the payload is the upper portion. It is attached to the oscillator 225 freely rotatable around the support point, the pair of supports are individually moved to the holding position and the non-holding position, and the payload is the non-holding of the support.A curing device for being drawn by moving together in the same direction as the movement of the value.

According to the present invention, the pair of supports are circularly movable toward the payload along the outer edge of the hardening from the holding position to the non-holding position with the support shafts 246 and 294 as the supporting points, and the oscillator in the circular movement process. It is preferable to walk the driven portion 282 to guide the payload together.

In addition, the present invention is carried out by the mounting body 130 disposed below the purification inlet 334 and a pair of supports disposed above and also to the side of the tower body, and selectively moved to the holding position and the non-holding position. A hardening process for importing and holding the configured holding device, and selectively feeding the held hardening to the holding and returning holes 108 by selectively moving the holding hardening to the holding position and the non-holding position of the pair of supports; In the apparatus, the detection passage 112 inclined to the front side downward and connected to the inlet, the coin detection sensor 114 disposed adjacent to the detection passage, the distribution passage 116 extending downward from the detection passage, the distribution Return passage 118 leading to the passage, return opening 108 leading to the return passage, downwardly formed laterally in the radial direction of the imported hardening of the return opening The storage device 106, a distribution body 122 freely placed in the distribution passage, a holding device 124 connected to the distribution body and disposed below the distribution body, and the holding device can swing the upper end portion as a supporting point. And a first support that can be selectively positioned at an unsupported position positioned above and at the side of the mount and below and at the side of the mount. And a three-dimensional holding chamber 126 constituted by a second support, wherein the payload, the first support and the second support are inclined parallel to the thickness direction of the curing, and the first support and the second support are from the support position. It is preferable that it is a hardening apparatus characterized by hooking together the said surface holding body in the same direction in being movable to an unsupported position.

In the present invention, the inlet, the import port, the receiving port and the return port is attached to the main body, the mounting body and the swinging body is preferably attached to the sub-base detachable to the main body.

The hardening put into the inlet arranged in the upper part is authenticity discriminated based on the data acquired by the hardening detection sensor, the falsification which is not imported is guided to a return opening, and the purification which should be imported is guided to a holding room, and is suspended.

The holding chamber is located above the storage port and the return port, and is formed three-dimensionally by at least the mounting body, the first support, and the second support.

The hardening which the lower end of the main surface is supported on the mounting body has the movement force to the said inclination direction by self weight.

The left and right of the main surface of the diameter part of the retention hardening which the lower end of the main surface is supported on the mounting body are supported by the 1st support body and the 2nd support body, and are hold | maintained in the holding room.

Then, the cure supplied to the holding room is sequentially held while the lower surface is in surface contact with the upper surface of the reserved cure.

When the first support is moved from the holding position of the curing to the non-holding position, the payload is rotated together in the same direction in the process.

As a result, the payload on which the hardening is mounted is displaced from below the center of hardening.

Therefore, since the retention hardening rolls by itself to the center of gravity with respect to the payload, it is fed in the direction.

If the feeding direction is the return port direction, the coin is returned to the return port.

In the case where the second support is moved from the holding position to the non-holding position, the holding hardening rolls on its own weight toward the center of gravity relative to the payload, so that it is fed to the storage port in the direction and falls from the storage port.

As a result, the retention hardening can be supplied to a storage port or a return port located below the coin processing device, thereby providing a retention type coin processing device compatible with the size of the defect standard.

Moreover, since the retention hardening supported by the payload rolls out by own weight, it can move smoothly and it does not produce coin jam.

Moreover, since it is comprised by a mounting body, a 1st support body, and a 2nd support body, a structure is simple, and a compact and inexpensive hardening processing apparatus can be realized.

In the present invention, hardening falling into the holding chamber is first biased in a direction obliquely in the same direction as the surface holding body by the directing body to fall on the surface holding body, and the surface is slid so that the lower end is mounted on the payload. The lower surface is supported by the surface retainer, and the left and right diameter portions are held and held by the first support and the second support.

The hardening held by this is certainly held in the surface contact with the surface retainer.

As a result, the retention hardening is held in a predetermined posture, and there is an advantage that the predetermined number of sheets can be withheld at all times since there is no reduction in the holding room volume due to the abnormal holding.

In addition, since the hardening is caused to fall on the surface retainer by the deflection surface, the hardening holding device can be placed directly under the hardening import port, and the predetermined number of sheets is held without increasing the size of the hardening direction. This has the advantage that a compact hardening apparatus can be obtained.

Moreover, according to the present invention, curing information for position determination is acquired by the curing detection sensor while the coin put into the inlet is driven in the detection path down to the front side, and the authenticity is determined based on the information.

Based on the authenticity discrimination, when the input hardening that advances through the distribution passage is displaced by the distribution device, it is guided to the return passage and returned from the return port.

In the case of purification, the purification guided by the distribution device to the purification passage is held in a holding room below the distribution device.

The holding chamber is located above the storage port and the return port, and is formed three-dimensionally by at least the mounting body, the first support, and the second support.

The hardening of which the lower end of the main surface is supported on the payload can slide in the inclination direction of the payload due to its own weight.

Subsequently, the purification which is supplied to the holding chamber is sequentially held in the state where the lower surface and the upper surface of the lower purification are in surface contact with the lower peripheral surface in contact with the upper surface of the holding purification.

Even when the lower end of the main surface is supported on the mounting body, even when the lower end of the main surface is not in surface contact with the surface holding member, the curing is shifted to the lower side of the inclination of the mounting body by the horizontal force received by the falling curing.

Therefore, since a predetermined number of pieces of curing can be held in the limited holding room, a retention type curing apparatus compatible with the size of the defect standard can be realized.

In addition, when the inlet, the import port, the receiving port and the return port are attached to the main body, and the payload and the oscillator are attached to the sub-base detachable to the main body, the payload and oscillator constituting the holding chamber of hardening Is attached to the sub base.

Therefore, in the case of repair and repair thereof, there is an advantage in that it is easy to work because it can work separately from the base.

(The best mode for carrying out the invention)

Best Mode for Carrying Out the Invention The best mode of the present invention is to provide a holding device constituted by a payload placed below the purge inlet and a pair of supports disposed above and laterally of the payload and selectively moving to a holding position and a non-holding position. A coin processing device configured to import and hold, and to selectively feed the holding coin to the holding position and the non-holding position of the pair of supports, and to supply the receptacle to the storage port or the return port. Of the inclined detection passage, a hardened detection sensor disposed adjacent to the detection passage, a distribution passage extending downward from the detection passage, a return passage leading to the distribution passage, a return passage leading to the return passage, and the imported coin of the return passage. Storage port formed downward in the radial direction, the distribution bin A dispensing body arranged freely on and off, a holding device disposed below the distributing body following the distributing body, and the holding device is fixed at right angles to the face retaining member and the face retaining member which are swingably mounted at the upper end with a support point. And a three-dimensional holding chamber constituted by the first support and the second support, which can be selected and positioned at an unsupported position located above and below the payload, and also below the payload. The first support and the second support are inclined in parallel in the thickness direction of the curing, and the first support and the second support can be moved from the support position to the unsupported position by walking the face retainer and pulling them together in the same direction. It is a hardening apparatus characterized by the above-mentioned.

(Example)

In the present embodiment, the coin processing device 100 includes the main body 102, the inlet 104, the storage port 106, the return port 108, the detection passage 112, the coin detection sensor 114, the distribution passage 116, Return passage 118, distributing body 122, holding device 124, holding room 126, subbase 128, mounting body 130, the first holder 132 and the second holder 134 ) Is included.

First, the main body 102 is described.

The main body 102 is formed with an inlet 104, a storage opening 106, a return opening 108, a distribution passage 116, a return passage 118, and the like, and a curing detection sensor 114 and a holding device 124 are formed. Has the function of being attached.

The main body 102 includes a rectangular central portion 136 to establish, and a longitudinally long rectangular front plate 138 fixed to a T-shape at the front end of the central portion 136.

Next, the inlet 104 for curing is described.

The inlet 104 is formed in the upper center of the front plate 138, and is a vertically long rectangular slit-shaped opening.

The inlet 104 is set to a thickness and a width (corresponding to a diameter) slightly larger than the thickness and diameter of the hardening C of the plurality of metal species in which the injecting is supposed.

In the present embodiment, the use of 10 yen, 50 yen and 100 yen of Japanese yen is assumed, so the maximum diameter is also set to a thickness and width slightly larger than the 10 yen hardening of the thickness.

Furthermore, 500 yen hardening can also be set to be available.

Next, the storage opening 106 will be described.

The storage opening 106 is a game machine that holds the purification TC held by the holding device 124 when the coin C inserted into the inlet 104 is a coin to be imported (hereinafter, conveniently referred to as "purification (TC)"). Purification (TC) has a function to fall in order to import to a safe (not shown).

Since the storage opening 106 is driven by the hardening (C) detection passage 112 introduced into the injection opening 104 and then distributed in the distribution passage 116, the storage opening 106 is held by the holding device 124. One side, in other words inwardly downwardly downwardly opening the bottom surface of the central portion 136 obliquely relative to the inlet 104, the width being slightly larger than that of the maximum diameter hardening, the thickness being the maximum held in the holding device 124. The hardening of the number of sheets increases, and it is formed in the size which can pass simultaneously.

Next, the return port 108 will be described.

Return hole 108 is for the curing (C) put into the inlet 104 is not the import target (hereinafter referred to as "comfort (FC)" for convenience) and the purification (TC) withheld in the holding device 124 In order to return to the injector, the purification TC has the function of falling.

The return port 108 is disposed adjacent to the side of the holding device 124 and is a rectangular opening opened in the center of the lower end of the front plate 138.

The cubic return chamber 142 is formed in the inner side of the return port 108, and return hardening falls to this room 142 in the horizontal direction, and awaits storage from the return port 108. As shown in FIG.

The return hole 108 is attached with a safety plate 144 for preventing the fingers of the infant.

Next, the detection passage 112 will be described.

The detection passage 112 guides the coin C injected into the inlet 104 in a predetermined direction, and provides a function of acquiring information for determining the authenticity of the coin C being guided by the coin detection sensor 114. Have

In the present embodiment, the detection passage 112 is supported by the bearing 145 so as to be rotatable with respect to the main body 102 and the main body 102, and tilted downward from the inlet 104 to the lower end at the front end. It is comprised by the rectangular movable control plate 148 in which the guide rail 147 was formed.

In other words, the detection passage 112 includes at least a flat plate-shaped first establishment guide wall 162 of the central portion 136 of the main body 102 (actually slightly inclined to increase the detection accuracy of curing) and the movable control plate ( The flat second-shaped guide wall 164 of 148 is juxtaposed at intervals slightly larger than the maximum thickness hardening (C), and the lower surface is a longitudinally thin plate-shaped space defined by the guide rail 146. , It is a downward inclined passage inclined downward as it moves away from the inlet 104.

The center part 136 and the movable control plate 148 are comprised by the nonmagnetic substance in relationship with the hardening detection sensor 114. As shown in FIG.

However, the detection passage 112 may be formed vertically from the inlet 104 and may be configured such that the coin C injected into the inlet 104 falls freely.

Next, the hardening detection sensor 114 is demonstrated.

The hardening detection sensor 114 has a function of acquiring hardening information, such as diameter, thickness, and a material which are necessary for the determination of the position of the hardening C which moves the detection path 112.

The curing detection sensor 114 is composed of a ferrite core and a coil attached to the central portion 136 and the movable control plate 148, and the curing information (C) is used for curing information regarding the material, diameter, thickness, and the like, which are the authenticity determining elements of the curing. It acquires in the process of rolling the detection path 112.

The coincidence information is compared with the reference information by the discriminating device 150, for example, a microcomputer, to determine authenticity.

Based on this determination, the distribution body 122 distributes the hardening C which moves the distribution channel | path 116 to the purification | cleaning channel | path 158 or the return channel | path 118. As shown in FIG.

In addition, the determination device 150 has a function for interworking with other devices in addition to the determination of the authenticity of the curing.

Next, the distribution passage 116 will be described.

The distribution passage 116 returns the coin C determined by the coin C that has dropped the detection passage 112 from the coin detection sensor 114 based on the coin information of the coin detection sensor 114. Has a function to distribute to

The distribution passage 116 is slightly larger than the thickness of the maximum thickness hardening (C) with respect to the first establishment guide wall 162 and the first establishment guide wall 162 of the main body 102 in succession to the detection passage 112. A partition is defined between the second establishment guide walls 164 of the movable restricting plate 148 arranged in parallel at intervals.

In FIG. 2, the passage substantially connected to the left side of the guide rail 146 following the detection passage 112 is the distribution passage 116.

The distribution passage 116 protrudes from the first establishment guide wall 162 and the second establishment guide wall 164 and the movable restricting plate 148 and at a predetermined distance greater than the diameter of the maximum diameter hardening from the guide rail 146. A partition is defined by the establishment wall 172 which extends in an up-down direction, and is a path | line | line.

In other words, the distribution passage 116 is a passage where the coin C that has transmitted the detection passage 112 falls.

Next, the movable restricting plate 148 is described.

The movable restricting plate 148 defines a section of the detection passage 112 and the distribution passage 116 between the main body 102, and has a function of attaching the thread hanging tamper prevention device 166.

The upper guide rail 168 protrudes from the guide rail 146 and the guide rail 146 above and parallel to the lower part of the 2nd establishment guide wall 164 of the movable control plate 148.

As shown in FIG. 2, the movable restricting plate 148 is rotatably supported by the bearing 178 of the upper end on the support shaft 176 supported by the pair of bearings 144 of the upper end of the center 136. In addition, the spring 180 is pressurized with a predetermined force to approach the first establishment guide wall 162.

The movable restricting plate 148 abuts a stopper (not shown) on the first establishment guide wall 162 so that the first establishment guide wall 162 and the second establishment guide wall 164 are at the predetermined intervals. It is regulated.

The movable restricting plate 148 is rotated by a predetermined angle to the support point by pressing the cancel lever 181 protruding forward from the front plate 138 downward, and the second establishment guide wall 164 is moved. By falling away from the first establishment guide wall 162, the hardening C jammed between them is dropped into the return passage 118 and returned.

When the cancel lever 181 is pressed for a predetermined amount, a sensor (not shown) detects and the determination device 150 excites the second electronic actuator 236, which will be described later, for a predetermined time.

The return passage 118 is described next.

The return passage 118 has a function of guiding the dispersal FC distributed by the distribution body 122 to the return port 108.

The return passage 118 is a passage continuously formed downstream of the distribution body 122 continuously to the distribution passage 116, and to the third guide wall 184 formed in the first establishing guide wall 162 and the central portion 136. The partition is determined and formed.

The lower surface of the return passage 118 is defined by the upper surface 185 of the linear return guide rail 182 extending downstream of the distributor 122.

In other words, the return passage 118 is a passage constituted by the return guide rail 182 which is inclined downward in the front side downstream of the distributor 122.

The return passage 118 is also the gas passage 188 as the gas passages FC pass therethrough.

Next, the distribution body 122 is demonstrated.

The distribution body 122 has a function of distributing the curing C, which moves the distribution passage 116, to the return passage 118 or the purification passage 158.

Distributing body 122 is rectangular plate shape, and is comprised so that the support shaft 190 which protrudes in the horizontal direction from a downstream side (lower end part) can be rotated to a support point just above the 3rd guide wall 184.

Distributing body 122 is a relief groove formed in the first establishing guide wall 162, with a return position CP located at the same plane as the second establishing guide wall 164, and a distal end located in the distribution passage 116. The tip rushes into 192, whereby purification TC can be placed at the receiving position RP which guides the purification passage 158.

Next, the distribution position control apparatus 194 of the distribution body 122 is demonstrated.

The distribution position control device 194 has a function of selectively positioning the distribution body 122 at the return position CP or the reception position RP.

Therefore, the device can be changed to a device having the same function.

The distribution position control device 194 of the embodiment includes a first electronic actuator 196 and a first link 198.

The first electronic actuator 196 is fixed to the central portion 136 by the first bracket 202 and is linked to the distributor 122 with the first link 198 interposed therebetween.

The iron core (not shown) of the first electromagnetic actuator 196 is urged in the always protruding direction by a spring (not shown), and when in the protruding position, the distributor 122 is positioned at the return position CP.

When the first electromagnetic actuator 196 is excited, the distribution body 122 is moved to the receiving position RP in conjunction with this by the movement of the first iron core.

In other words, the first electronic actuator 196 is usually demagnetized, and the distribution body 122 is held at the return position CP.

Thereby, the curing which moves the distribution passage 116 both in the case where the curing detection sensor 114 is not in the detected state and when it is determined to be displaced (FC) based on the curing information from the curing detection sensor 114. (C) is guided to the return passage 118 and returned to the return port 108.

When the first electromagnetic actuator 196 is excited, since the iron core is moved, the distribution body 122 is moved to the receiving position RP with the first link 198 interposed therebetween.

Thereby, hardening C which moves the distribution channel | path 116 is guide | induced to the purification | purification channel | path 158 by the distribution body 122. As shown in FIG.

Next, the holding device 124 will be described.

The holding device 124 has a function of holding a maximum number of purification TCs guided to the purification passage 158 and selectively feeding the storage TC 106 or the return opening 108.

The holding device 124 includes a holding room 126, a sub base 128, a mounting body 130, a first support 132, and a second support 134.

Since the holding device 124 may constitute the holding room 126 by at least the mounting body 130, the first supporting body 132, and the second supporting body 134, the sub base 128 is not an essential component requirement.

The holding device 124 is attached to the sub base 128 and detachably attached to the central portion 136.

Since the holding device 124 can be attached to or detached from the main body 102 by the sub base 128, the holding device 124 can be attached to or detached from the main body 102 by a simple operation. There is an advantage that the inspection work becomes easy.

The sub base 128 is fastened to the pair of horizontal U-shaped retaining grooves 214 formed at the lower end of the central portion 136 of the main body 102 by the support shaft 212 at the lower end, and to the lower end of the central portion 136. It is fastened to the center part 136 by hooking by the hook 216 which extends from the center part, and attaching to the center part 136 the attachment pin 222 which penetrates the attachment hole 218 of the upper end part of the sub base 128. It is.

Preferably, the sub base 128 is elastically attached to the central portion 136 via a spring (not shown) between the head of the attachment pin 222 and the sub base 128.

This is because when excessive force is applied, it is possible to prevent damage to the holding device 124 and the like, and the holding device 124 can be easily attached to or detached from the main body 102, thereby making inspection and maintenance work easy.

First, the holding room 126 will be described.

The holding chamber 126 has a function to hold the maximum number of sheets by aligning the purification TC guided to the purification passage 158 in the thickness direction.

The predetermined number of sheets to be held is, for example, about 6 sheets at maximum when securing compatibility with the standard size, and about 10 sheets can be set if the thickness is not limited.

The holding chamber 126 is disposed below and sideways of the distributing body 122, and at least by the mounting body 130, the first support body 132, the second support body 134, and the surface retainer 226. It is composed of three dimensions with depth.

The payload 130 will be described.

The payload 130 supports the main surface of the lower end of the purification TC falling from the purification passage 158, and also slides itself downward in the thickness direction due to its own weight by the inclination thereof. Have

The payload 130 is fixed to the lower end of the inverted triangular face retainer 226 which is a swing 225 which is freely supported by the swing shaft 232 which is inclined to the upper end of the sub base 128. And a column 228 having a predetermined length.

The surface retainer 226 is inclined so as to cross the lower end at an angle of about 30 with the first water line L1 in contact with the lower end surface of the distribution body 122.

In other words, the swing shaft 232 is inclined at an angle of about 30 degrees with respect to the horizontal line.

As a result, the mounting body 130 is arranged in parallel with the swing shaft 232, and is configured to be inclined upward toward a direction away from the first establishment guide wall 162 at an angle of about 30 degrees.

The inclination of the mounting body 130 is configured such that the purification TC slides on the mounting body 130 in the horizontal direction due to its own weight, and the lower surface of the purification TC is in surface contact with the surface holding member 226.

Next, the first support 132 will be described.

The first support body 132 is in contact with one main surface of the purification TC in the holding position SP1 that is above and laterally of the mounting body 130 so that the purification TC is positioned on the mounting body 130. It supports, and has a function to selectively move to the return position (CP2), which is a non-holding position when returning the pending hardening.

The first support 132 is selectively moved to the holding position SP1 and the return position CP2 by the first moving device 234.

The first moving device 234 includes a second electronic actuator 236 and a first link mechanism 238.

The second electronic actuator 236 is fixed to the sub base 128 by the first bracket 242.

The first iron core 244 of the second electronic actuator 236 is linked to the first link mechanism 238.

The first iron core 244 is pressed in the protruding direction (the right direction in FIG. 8) by the first spring 246.

The 1st link mechanism 238 protrudes on the back side of the 1st lever 248 and the sub base 128 which rotational movement is supported by the support shaft 246 which protrudes on the back side of the sub base 128 freely. The first cone rod 254 and the first iron core 244 and the second connecting the second lever 252, the second lever 252 and the first lever 248, the swing of the shaft 250 is freely supported. And a second cone rod 256 connecting the lever 252.

The first lever 248 has a horizontal crank shape, the rotation of which is freely supported by the support shaft 146 at a lever ratio of approximately one to three, and the first support member 132 is fixed to one end thereof, and the other end thereof. The first balance weight 258 is fixed to it.

The first support 132 penetrates through the first arc-shaped long hole 260 formed with the center of the support shaft 246 formed in the sub base 128 in a predetermined direction toward the third guide wall 184. Extends to the length of.

The first support 132 is perpendicular to the surface retainer 226, and the amount of protrusion is set to be the same as the mounting body 130.

By employing the first balance weight 258, the second electronic actuator 236 of low power can be used, which has the advantage of reducing the cost and power.

The second lever 252 is a straight lever that approximately establishes a middle portion near the lower end in the standby state in which rotation is supported freely on the support shaft 250. The second lever 252 is formed in the shaft hole formed in the upper end of the first cone rod 254. The pin 262 protruding from the lower end is freely inserted into the rotation.

The upper end of the first cone rod 254 is freely rotated by the pin 264 to the first lever 248 between the support shaft 246 and the first support 132.

One end of the second cone rod 256 is fixed to the first iron core 244, and the biscrew 272 twisted into the sub base 128 penetrates the long hole 268 of the other end. The 1st guide mechanism 274 is comprised, and the pin 278 which protrudes to the axial hole 276 from the lower end part of the 2nd lever 252 in the horizontal direction is inserted in the rotational movement freely.

With this configuration, when the second electromagnetic actuator 236 is elementd, the first iron core 244 protrudes by the first spring 246, and the second cone rod 256 is as shown in FIG. 8. Stop at the position moved to the far right.

As a result, the second lever 252 is rotatably moved to the established position with the pin 278 interposed therebetween, and the second lever 252 and the first cone rod 254 are in a state of being substantially aligned with each other. The first cone rod 254 and the first lever 248 are set to form an approximately right angle, and the first lever 248 is rotated in the most clockwise direction around the support shaft 246 as shown in FIG. 8. Is kept in position.

Thereby, the 1st support body 132 of the front-end | tip of the 2nd lever 252 is hold | maintained in holding position SP1.

By setting the second lever 252 and the first cone rod 254 to form a straight line and the first cone rod 254 and the first lever 248 to be substantially perpendicular to each other, This is to prevent a large torque from acting on the first lever 248 even when an external force by the retention purge TC is applied.

When the second electronic actuator 236 is excited, the second cone rod 256 is pulled to the left in FIG. 8, so that the second lever 252 is rotated clockwise with the pin 258 interposed therebetween. , The first lever 248 is rotated in the counterclockwise direction with the pin 262, the first cone rod 254, and the pin 264 interposed therebetween (FIG. 12).

As a result, the first support 132 is moved to the return position CP2 (FIG. 11).

At this time, the first support 132 presses the driven portion 282 of the surface retainer 226 to slightly rotate the surface retainer 226 together around the support shaft 252.

Thereby, the mounting body 130 is moved in the same direction, and the mounting body 130 is moved to the 2nd support body 134 side rather than a normal position.

The amount of movement of the payload 130 is set such that the support of the payload 130 is located on the second support 134 side rather than the center of the purification TC of the smallest diameter whose movement is restricted by the first support 132. do.

It is because the support part of the mounting body 130 moves to the 2nd support body 134 side even if it is 50 yen of minimum diameter hardening, and hold | maintenance hardening TC can be rolled by self weight.

The second lever 252 and the first cone rod 254 constitute a toggle action mechanism 276.

When the first support 132 is moved to the rightmost direction as shown in FIG. 10 by the first spring 246, the center of the pin 262 is the center of the pins 264 and 268. The end of the long hole 268 is caught by the bis 272 in a state located slightly to the right of the line (L2) connecting the stops.

In this state, when the moment of anticlockwise rotation acts on the first lever 248, the counterclockwise force acts on the second lever 252, but the second cone rod 256 is caused by the screw 272. Since the movement of the first support 132 is not moved.

In other words, even when the first support 132 receives the force moved from the holding position SP1 to the return position CP2, it is mechanically restrained to hold the holding position SP1.

By employing the toggle action mechanism 276, there is an advantage that the position of the first support 132 can be stabilized by the inexpensive configuration.

The toggle action mechanism 276 can also be configured by the projection formed on the second lever 252 and the projection formed on the first cone rod 254.

Next, the second support 134 will be described.

When the 2nd support body 134 contacts one main surface of the purification | cleaning TC in the holding position SP2, it supports so that the said purification | cleaning TC may be located on the mounting body 130, and accommodates hold hardening It has a function to selectively move to the storage position RP2.

The second support 134 is selectively moved to the holding position SP2 and the storing position RP2 by the second moving device 278.

The second moving device 278 includes a third electronic actuator 282 and a second link mechanism 284.

The third electromagnetic actuator 282 is fixed to the sub base 128 by the second bracket 286.

The second iron core 288 of the third electromagnetic actuator 282 is linked to the second link mechanism 284.

The second iron core 288 is urged in the protruding direction (left direction in FIG. 9) by the second spring 292.

The second link mechanism 284 supports the third lever 296 on which the rotational movement is freely supported by the support shaft 294 protruding on the back side of the sub base 128 and the support protruding on the back side of the sub base 128. A third cone rod 306 and a second iron core 288 and a fourth connecting the fourth lever 304, the third lever 296, and the fourth lever 304 to which the swing is freely supported on the shaft 298. And a fourth cone rod 308 connecting the lever 304.

The third lever 296 has a horizontal crank shape, the rotation of which is freely supported by the support shaft 294 at a lever ratio of approximately one to three, and the second support member 134 is fixed to one end thereof, and the other end thereof. The second balance weight 312 is fixed.

The second support 134 penetrates through the second arc-shaped long hole 314 centered around the support shaft 294 formed in the sub base 128 and faces the third guide wall 184. Extends to.

The second support 134 forms a right angle with respect to the surface holding member 226, and the amount of protrusion is set to be the same as the mounting body 130.

In other words, the payload 130, the first support 132, and the second support 134 protrude at the same length at right angles to the surface retainer 226.

Their spacing in the state where the first support 132 and the second support 134 are located in the holding positions SP1 and SP2 is set slightly larger than the diameter of the maximum diameter curing used.

Moreover, in the state which is located in holding position SP1 and SP2, the 1st support body 132 and the 2nd support body 134 may be located to the left and right of the diameter part of the purification | cleaning TC in which the lower main surface was mounted in the mounting body 130. FIG. Is set.

In detail, when the 1st support body 132 and the 2nd support body 134 are located in holding positions SP1 and SP2, the left-right center of the center of the maximum diameter and minimum diameter of a retention purification | cleaning TC is left and right. It is preferable to set the first support 132 and the second support 134 to be located.

In addition, by employing the second balance weight 312, the third electronic actuator 282 having a small output can be used, which is advantageous in that cost can be reduced and power can be saved.

The fourth lever 304 is a straight lever that approximately establishes a middle portion near the lower end in the standby state in which rotation is freely supported by the support shaft 298. The fourth lever 304 is formed in the shaft hole formed in the upper end of the third cone rod 306. The pin 312 protruding from the lower end is freely rotated.

The upper end of the third cone rod 306 is freely rotated by the pin 314 to the third lever 296 between the support shaft 294 and the second support 134.

One end of the fourth cone rod 256 is fixed to the second iron core 288, and the vis 318 twisted into the sub base 128 passes through the long hole 316 of the other end. The pin 326 which comprises the 2 guide mechanism 322, and protrudes to the shaft hole 324 from the lower end part of the 4th lever 304 in the horizontal direction is inserted freely.

With this configuration, when the third electromagnetic actuator 282 is elementd, the second iron core 288 protrudes by the second spring 292, and the fourth cone rod 308 as shown in FIG. 8. Stop at the leftmost position.

As a result, the fourth lever 304 is rotatably moved to the established position with the pin 326 interposed therebetween, and the fourth lever 304 and the third cone rod 306 are aligned in a straight line. The three cone rods 306 and the third lever 296 are set to form approximately right angles, and the third lever 296 is rotated in the most anticlockwise direction around the support shaft 294 as shown in FIG. 8. Is kept in position.

Thereby, the 2nd support body 134 of the front-end | tip of the 3rd lever 246 is hold | maintained in holding position SP2.

By setting the fourth lever 304 and the third cone rod 306 to form a substantially straight line, and the third cone rod 306 and the third lever 296 to form a substantially right angle, the second support 134 This is to prevent a large torque from acting on the third lever 296 even when an external force caused by the hold purge TC is applied.

When the third electromagnetic actuator 282 is excited, since the fourth cone rod 308 is moved to the right in FIG. 9, the fourth lever 304 is rotated counterclockwise with the pin 326 interposed therebetween. The second lever 296 is rotated in the clockwise direction with the pin 312, the third cone rod 306, and the pin 314 interposed therebetween (FIG. 10).

Thereby, the 2nd support body 134 is moved to the storage position RP2 (FIG. 13).

At this time, the second support 134 presses the driven portion 282 of the surface retainer 226 to slightly rotate the surface retainer 226 together around the support shaft 252.

Thereby, the mounting body 130 is moved in the same direction, and the mounting body 130 is moved to the 1st support body 132 side rather than a normal position.

The amount of movement of the payload 130 is set such that the support of the payload 130 is located on the second support 134 side rather than the center of the purification TC of the smallest diameter whose movement is restricted by the second support 134. do.

It is because the support part of the mounting body 130 is moved to the opposite side to the 2nd support body 134 even if it is 50 yen of minimum diameter hardening, and hold | maintenance hardening TC can be rolled by self weight.

In addition, the fourth lever 304 and the third cone rod 306 constitute a toggle action mechanism 328.

When the second support 134 is moved to the rightmost direction as shown in FIG. 10 by the second spring 292, the center of the pin 312 is the center of the pins 326 and 314. The end of the long hole 316 is caught by the vis 318 in a state located slightly to the right side of the line (L3) connecting the stops.

In this state, when the clockwise moment acts on the third lever 296, the clockwise force acts on the fourth lever 304, but the fourth cone rod 308 is moved by the screw 318. Since this is impossible, the second support 134 is not moved.

In other words, even if the 2nd support body 134 receives the force moved from the holding position SP2 to the storage position RP2, it is mechanically restrained and hold | maintains the holding position SP2.

By employing the toggle action mechanism 328, there is an advantage that the position of the second support 134 can be stabilized by the inexpensive configuration.

The toggle action mechanism 328 can adopt a configuration different from the embodiment.

When the first support 132 and the second support 134 are located in the holding positions SP1 and SP2, the face holder 226j has left and right protrusions 330 and 331 formed therein. It is caught by the two support bodies 134, and it stops unstable in the state which the mounting body 130 is just below.

Next, the alignment drop device 332 will be described.

The alignment drop device 332 is used when the purification TC falls from the purification inlet 334 which is the import port 333 which is the upper end of the purification passage 158 by the distribution body 122 and is held in the holding chamber 126. , Must have a function to align in the thickness direction of the purification (TC).

The alignment dropping device 332 is a plate-shaped body which faces the distributing body 122 and juxtaposed in the establishing direction, and the lower end portions of the directing body 335 and the directing body 335 extending below the distributing body 122 are opposed to each other. The deflection surface 336 is included.

The directing body 335 is a plate shape, and is a plate-shaped body which faces the distribution body 122, in other words, the purification inlet 334 at a predetermined interval, and is inclined in the same direction as the surface retainer 226 with respect to the vertical. .

It is preferable that the director body 335 is comprised by the transparent resin board so that the movement state of purification | cleaning (TC) can be confirmed.

Moreover, since the directing body 335 is wiped off by hardening (C), it is preferable to arrange the at least one metal wear prevention piece (not shown) extended in the movement direction (up-down direction) of hardening.

The directing body 335 is located on the side of the second establishment guide wall 164, and is a wall surface above the holding chamber 126 below the purification inlet 334, and is a face retainer 214 on the opposite side of the return passage 118. It is curved in arc shape to the side.

The lower end 338 of the directing body 335 faces the upper end of the third guide wall 184 at predetermined intervals.

The upper end of the third guide wall 184 is the deflection surface 336.

The predetermined interval is an interval of about two sheets of the curing (C) thickness.

The water line L4 in contact with the edge of the lower end 338 of the directing body 335 is disposed so as to intersect with the face holding member 226.

The lower portion of the deflection surface 336 of the third guide wall 184 is a collapsed portion 342.

The fall down part 342 is located so that the upper end part may be biased toward the cotton holding body 226 when the purification TC held by the holding room 126 is established.

In other words, the water line L5 in contact with the collapsed portion 342 is set to intersect the surface retainer 226.

Purification TC guided to the purification passageway 158 by the distributor 122 is guided downward by the directing body 335, and the surface retainer 226 between the deflection surface 336. It is inclined in the same direction as the fall to the holding chamber 126.

The dropped purification TC is dropped on the surface retainer 226 or the payload 130 so that the left and right main surfaces are held on the first support 132 and the second support 134 and finally mounted on the payload 130. In addition, the bottom surface of the mounting body 130 is slid by the inclination of the mounting body 130 to be held in surface contact with the surface holding member 226.

Even when the purification TC falls vertically, the purification TC mounted on the mounting body 130 with its lower end is biased by the collapsed part 342, so that its center G is mounted. Since it is located on the surface retainer 226 side than the rotation point TP on the 130, the purification TC falls to the surface retainer 226 side and makes surface contact with the surface retainer 226.

Subsequent purge TC likewise falls on hold purge TC and is likewise suspended.

Thereby, the retention purification | cleaning TC is aligned and hold | maintained in the thickness direction of purification | cleaning TC in the surface contact state.

Next, the thread hanging prevention device 166 will be described.

The thread hanging prevention device 166 has a function of tying cloth yarns and the like to the purification TC, pulling the hardening once determined to be purification by the cloth yarns, and preventing fraud to be determined to be purification again.

In the present embodiment, the support shaft 344 in the horizontal direction is disposed on the movable restricting plate 164, and the linear anti-traction member 346 is freely attached to the rotational movement.

One end of the anti-traction body 346 is downstream of the detection passage 112, traverses the distribution passage 116 by a magnetic moment, and protrudes into the step hole 348 of the first establishment guide wall 114. (When chained in FIG. 3).

By this structure, hardening (C) can push through the pull prevention body 346 when moving the distribution passage 116 downstream, but the movement to the reverse direction is attracted to the step hole 348. Since it is impeded by the prevention body 346, it is impossible to attract hardening which passed through the pull prevention body 346 once.

Next, the return guide rail 350 will be described.

The return guide rail 350 serves to guide the purification TC conveyed from the holding chamber 126 to roll down toward the return hole 108 by the movement of the first support 132 to the return position CP2. Have

The return guide rail 350 is formed by the flat plate shape inclined downward toward the return hole 108 below the holding chamber 126, specifically, below the first support 132.

Purification TC which drives the return guide rail 350 falls to the return chamber 142.

Next, the storage guide rail 352 will be described.

The storage guide rail 352 guides the purification TC sent out from the holding chamber 126 to roll down toward the storage opening 106 by the movement of the second support 134 to the storage position RP2. Have

The storage guide rail 352 is formed of the flat plate shape inclined downward toward the storage opening 106 below the holding chamber 126, specifically, below the second support 134.

Purification TC which drives the storage guide rail 352 falls to the storage opening 106.

Next, the operation of the present embodiment will be described.

The case where the coin processing device 100 of the present embodiment is built in a game machine and the one-time fee is set to 150 yen will be described.

In other words, it is the case of setting that game is possible only when one 100 yen cure and five 10 yen cure are imported, or when one 100 yen cure and one 50 yen cure are imported.

Therefore, when 10 yen, 50 yen, and 100 yen are put in, imports as purification (TC), hardening and medals other than that are returned as counterfeit (FC).

When the power is not turned on, the first electronic actuator 196, the second electronic actuator 236, and the third electronic actuator 282 remain as they are.

In other words, the distribution body 122 is held at the return position CP, the first support 132 is held at the holding position SP1, and the second support 134 is held at the holding position SP2 ( 7).

When the purification is input in this state, since the coin detection sensor 114 does not output the coin information, the first electronic actuator 196 is not excited and continues the return position CP.

Therefore, the injected purge TC and the counterfeit FC pass through the return passage 118 and are returned to the return port 108.

Then, when the power is turned on, the curing detection sensor 114 is in a curing detection ready state, but the first electromagnetic actuator 196, the second electromagnetic actuator 236, and the third electronic actuator 282 change the device state. Continue.

First, when the counterfeit FC is thrown in, the hardening information is acquired by the coin detecting sensor 114 in the process of dropping the detection passage 112, and the discriminating apparatus 150 displaces the counterfeit FC based on the acquired hardening information. Is determined.

In the case of counterfeit FC, the first electromagnetic actuator 196 is not excited.

As a result, since the distribution body 122 continues the return position CP, the counterfeit FC passes through the return passage 118, falls to the return chamber 142, and can be taken out from the return port 108. FIG.

We explain case that put correct 100 yen hardening.

On the basis of the coincidence information acquired by the coincidence detection sensor 114 in the process of dropping the detection passage 112, the discrimination apparatus 150 determines that it is purification (TC) of 100 yen, and the 1st electronic actuator 196 Be a woman for a certain time.

Thereby, the distribution body 122 is pivoted and moved to the import position RP (when solid line in FIG. 3).

Purification TC which drives the distribution passage 116 is guided to the purification passage 158 by the distribution body 122 located in the import position RP.

After sufficient time has elapsed for the purification TC to move to the purification passage 158, the first electronic actuator 196 is demagnetized and the distributor 122 is returned to the return position CP.

Purification TC guided to the purification passage 158 is directed at the lower end thereof by the directing body 335 and the deflection surface 336 of the alignment drop device 332 and directed to the lower holding chamber 126. The inclination similar to that of the surface holding member 226 falls to the holding chamber 126.

The purification TC dropped on the surface retainer 226 or the mounting body 130 has its lower main surface supported by the mounting body 130, and the left and right diameter portions thereof are supported by the first support 132 and the second support 134. It is supported, and the lower surface is held in the holding chamber 126 in surface contact with the surface holding member 226 (FIG. 14).

Even when the purification TC falls vertically, the upper end portion of the purification TC is biased toward the surface retainer 226 by the collapsed portion 342, and thus similarly suspended.

Subsequently, when the correct 50 yen hardening is put in, it is guided to the purification | cleaning passage 158 as mentioned above by the distribution body 122, is guided by the directing body 335 and the press part 342, and it is withhold 100 yen. Falls on top of hardening.

As a result, the lower end of the 50 yen purge (TC) slides on the upper surface of the 100 yen purge, and the lower main surface is supported by the mounting body 130, and the left and right diameter portions are provided in the first support 132 and the second support 134. It is held in a state in which it is supported and held in surface contact with the upper surface of the holding 100 yen coin.

Since 150 yen was reserved by the holding room 126 by this, the discrimination apparatus 150 outputs a game enable signal to a game machine.

If the purge TC is input after outputting the game enable signal, the purge TC is returned to the return port 108 as described above as a counterfeit.

In the case where the correct 10 yen curing is added following the 100 yen purification (TC), the lower main surface is supported by the mounting body 130, the left and right diameter portions are supported by the first support body 132 and the second support body 134 in the same manner as the 50 yen curing. Is held in contact with the upper surface of the 100 yen coin in the holding chamber 126.

Subsequent 10 yen purification TC is also arranged in the thickness direction and held in the holding chamber 126.

When 5 sheets of 10 yen coins are added, the total amount is 150 yen, so the discriminating device 150 outputs a game playable signal as described above.

When 10-yen hardening is added following 100-yen hardening, when 50-yen or 100-yen hardening is injected thereafter, it is determined as counterfeit (FC) and returned from the return port 108. This is to prevent excessive collection.

When the player gives a start instruction to the game machine, the third electronic actuator 282 is excited for a predetermined time.

As the third iron core 292 is moved to the right side in FIG. 8 by the excitation of the third electromagnetic actuator 282, the fourth cone rod 308 is also moved in the same direction, and the third cone rod 306 is moved. It is rotated counterclockwise.

By the rotational movement of the fourth lever 304, the second lever 296 is rotated in the clockwise direction with respect to the support shaft 294 with the third cone rod 306 interposed therebetween, and the second support 134 is provided. Is moved to the storage position RP3.

During this movement, the second support 134 pushes the driven part 282 to rotate the surface retainer 226 in the same direction with the support shaft 232 as the support point.

As a result, the payload 130 moves in the same direction.

At this time, the amount of movement of the mounting body 130 is greater than that of the center of purification TC of the smallest diameter whose movement is restricted by the first supporting body 132. Since it is set so that it may be located, even if it is 50 yen which is minimum diameter hardening, it will start to roll on the opposite side to the 1st support body 132 by self weight, will fall on the storage guide rail 352, and will electrically fall to the storage opening 106. (FIG. 15).

The third electromagnetic actuator 282 is decomposed after a sufficient time has elapsed for the drop of the retention purge TC from the holding chamber 126, and the second support 134 is returned to the holding position SP2 again.

If the player does not play the game, a return operation is made.

By the return operation, the second electronic actuator 236 is excited for a predetermined time.

The excitation of the second electromagnetic actuator 236 causes the first iron core 244 to move to the left in FIG. 8, so that the second cone rod 256 also moves in the same direction.

As a result, since the second lever 252 is rotated in the clockwise direction in FIG. 8, the first lever 248 is rotated in the counterclockwise direction with the first cone rod 254 interposed therebetween, so that the first support body is rotated. 132 is moved from the holding position SP1 to the return position CP2.

In the process of moving the first support 132, the driven part 282 of the surface support 226 is pushed by the first support 132 to be rotated in the same direction.

Thereby, the support body of the mounting body 130 has the 2nd support body 134 rather than the center G of the purification | purification TC of the smallest diameter whose movement is restrict | limited by the 2nd support body 134 by this. Since it is located in the side, even 50 yen of minimum diameter hardening starts to roll to the opposite side to the 2nd support body 134 by self weight, and falls on the return guide rail 350 (FIG. 16).

The hardened | cured material fell further on the return guide rail 350, falls to the return chamber 142, and can be taken out from the return port 108. FIG.

In other words, it may return a hold purge (TC).

1 is a perspective view of a coin processing device of the embodiment.

2 is a left side view of the coin processing device of the embodiment.

3 is a cross-sectional view taken along the line A-A in FIG.

4 is a cross-sectional view taken along the line B-B in FIG. 2.

5 is a perspective view from the left side of the holding device of the coin processing device of the embodiment.

6 is a perspective view from the right side of the holding device of the coin processing device of the embodiment.

7 is a front view from the right side of the holding device of the coin processing device of the embodiment.

8 is a front view from the left side of the holding device of the coin processing device of the embodiment.

9 is a front view of a state in which some parts from the left side of the holding device of the coin processing device of the embodiment are deleted.

10 is a front view (when returning) from the left side of the holding device of the coin processing device of the embodiment.

It is a front view (at the time of storing) from the right side of the holding apparatus of the hardening apparatus of an Example.

It is a front view (at the time of storing) from the left side of the holding apparatus of the hardening apparatus of an Example.

It is a front view (at the time of return) from the right side of the holding apparatus of the hardening apparatus of an Example.

It is explanatory drawing of the operation | movement from the right side of the holding | maintenance apparatus of the hardening apparatus of an Example (at the time of hold).

It is explanatory drawing (at the time of operation) from the right side of the holding | maintenance apparatus of the hardening process apparatus of an Example.

It is explanatory drawing (at the time of return) of the operation | movement from the right side of the holding apparatus of the hardening apparatus of an Example.

17 is a schematic diagram for explaining the prior art.

18 is a cross-sectional view taken along the line Z-Z in FIG. 17.

It is a schematic diagram for demonstrating the defect standard hardening processing apparatus.

20 is an explanatory view of the operation of the prior art.

<Code description>

C… Curing G… Center of gravity

FC… Return Curing TC… Imported curing

RP1, RP2... Non-holding position SP1, SP2... Holding position

104... Inlet 106... Storage

108... Return port 112... An index passage

114... Curing detection sensor 116... Distribution passage

118... Return passage 122... Distributive

124... Holding device 126... Reserve Room

130... Payloads 132, 134... Support

225... Oscillator 246, 294. Support shaft

312... Import Zone

Claims (3)

The authenticity of the coin (C) injected into the inlet (104) is discriminated, and sorted by import hardening (TC) and return hardening (FC), and the import hardening is placed above the payload placed in the lower part from the import port 312 and the payload. Moreover, it is arrange | positioned at the side, and imports and hold | holds to the holding | maintenance apparatus 124 comprised by the pair of support bodies 132 and 134 which move to the holding position SP1, SP2 and a non-holding position selectively, and the said holding hardening is said, In the coin processing device which selectively feeds to the storage opening 106 or the return opening 108 by selectively moving to the holding position and the non-holding position of a pair of support body, The payload is attached to a swinging body 225 which can be rotated about an upper support point, The pair of supports are individually moved to the holding position and the non-holding position, And the payload is moved together in the same direction when the support is moved to the non-holding position. The method of claim 1, The pair of supports are circularly movable towards the payload along the outer edge of the hardening from the holding position to the non-holding position with the support shafts 246, 294 as support points, The hardening processing apparatus characterized by hooking the driven part (282) of the said oscillation body in this arc movement process, and carrying out the said mounting body together. Imported hardened | cured material injected into the inlet 104 was arranged in the lower part from the purification | inlet_inlet 334, and the upper part of the said mounting body is also arrange | positioned to the side, and is selectively connected to a pair of support body which moves to a holding position and a non-holding position. A coin which is imported into the hold device constituted by the hold device and held and selectively fed to the holding hole 106 or the return hole 108 by selectively moving the holding coin to the holding position and the non-holding position of the pair of supports. In the processing apparatus, A detection passage 112 inclined downward in front of the inlet and connected to the inlet; Curing detection sensor 114 disposed adjacent to the detection passage, Distribution passage 116 extending downward from the detection passage, A return passage 118 leading to the distribution passage, A return opening 108 following the return passage; Storage port 106 formed downward in the radial direction of the imported coin of the return port, Distributing body 122 disposed in the distribution passage to be retractable, It has the holding device 124 connected to the said distribution body and arrange | positioned below the said distribution body, The holding device is a surface holding member 226 installed so as to swing at an upper end portion as a support point, and a mounting body fixed at a right angle to the surface holding body, and a support position above and above the mounting body and below and to the side of the mounting body. A three-dimensional holding chamber 126 configured by a first support and a second support, the selectable position being in an unsupported position, The mounting body, the first support and the second support are inclined in parallel in the thickness direction of the curing, The first support and the second support can be moved from the supported position to the unsupported position, so that the surface retainer is hooked and pulled together in the same direction.

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