JP2018088158A - Coin conveying device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To reduce the size of a coin processing machine.SOLUTION: A coin conveying device 10b is applied to a coin processing machine 1 that stores deposited coins for every denomination and dispenses the stored coins according to a payment instruction, and comprises: a rail part 70 that forms a predetermined conveyance path HK with an elevation portion extending curved upward; a conveying part 80 that is formed of a holding part 81 capable of holding coins one by one joined in an endless manner, and is deformed in one direction along the rail part 70 to convey the deposited coins from a lower part toward an upper part; and an attitude regulating member 101 that presses, against the rail part 70, the coins conveyed toward the upper part by the conveying part 80 at the elevation portion to regulate the attitude of the coins.SELECTED DRAWING: Figure 16

Description

  The present invention relates to a coin transport device, and more particularly to a coin transport device that is applied to a coin processing machine that stores deposited coins for each denomination and dispenses coins stored in accordance with a withdrawal instruction. is there.

  Conventionally, for example, a coin processing machine applied as a change machine, after identifying the authenticity and denomination of a coin inserted into a deposit slot, automatically takes in the coin identified as a genuine coin and provides it for each denomination. To be stored in the coin storage. Further, the coin processing machine pays out coins stored in the coin storage to the dispensing port as coins of the requested amount according to a change payout request from an external device or the like (see, for example, Patent Document 1). ).

JP 2011-39773 A

  By the way, in the coin processor, a plurality of endlessly stretched belts are provided on a pair of rollers, and the most upstream portion of the downstream belt is disposed below the most downstream portion of the upstream belt. We were carrying coins. Each belt requires a certain conveyance length, and as a result, it is difficult to reduce the size of the entire apparatus.

  An object of this invention is to provide the coin conveying apparatus which can achieve size reduction of a coin processing machine in view of the said situation.

  In order to achieve the above object, a coin transport device according to the present invention is applied to a coin processing machine that stores received coins for each denomination and dispenses coins stored according to a withdrawal instruction. A rail part that constitutes a predetermined transport path having a rising part that extends in a manner that curves upward, and a holding part that can hold coins one by one are connected endlessly. A transfer unit configured to transfer the received coins upward from below by displacing in one direction along the rail unit; and a coin to be transferred upward by the transfer unit at the rising portion. It is provided with the attitude | position regulation member which regulates the attitude | position of this coin by pressing toward the said rail part.

  Moreover, the present invention is characterized in that, in the above coin transport device, the holding portion is displaced along the rail portion in such a manner that the rail convex portion formed in the rail portion enters the holding concave portion formed in itself. And

  In the coin transport device according to the present invention, the transport path has a descending portion extending in a curved manner downward, and when the transport section is displaced in one direction, the descending portion While allowing a portion of the coin that is transported downward by the transport section to pass, the coin transported by the transport section is detached from the holding section when the transport section is displaced in the reverse direction. And a passage restricting member that restricts the coin from passing through the descending portion.

  According to the present invention, the transport unit configured by endlessly connecting the holding units capable of holding coins one by one has a rising portion extending in a manner of bending upward. Displaced in one direction along the rail part that constitutes the transport path, the received coins are transported from the bottom to the top, so the belt stretched endlessly on a pair of rollers as in the prior art. The installation area of the coin processor to be applied can be reduced as compared with the case where a plurality of coin processors are provided, thereby achieving an effect that the coin processor can be reduced in size.

  In addition, since the posture regulating member regulates the posture of the coin by pressing the coin conveyed upward by the conveying portion at the rising portion toward the rail portion, the coin is detached while passing the rising portion. This can prevent the occurrence of coin clogging during conveyance.

FIG. 1 is a perspective view showing an internal structure of a coin processing machine to which a coin transport device according to an embodiment of the present invention is applied. FIG. 2 is a perspective view showing an internal structure of a coin processing machine to which a coin transport device according to an embodiment of the present invention is applied. FIG. 3 is a perspective view showing the coin check device shown in FIGS. 1 and 2. FIG. 4 is a perspective view in which some components of the coin checking device shown in FIG. 3 are omitted. FIG. 5 is a block diagram schematically showing a characteristic control system of the coin check device shown in FIGS. 3 and 4. FIG. 6 is a plan view showing a main part of the coin checking device shown in FIGS. 3 and 4. FIG. 7 is a bottom view showing a main part of the coin check device shown in FIGS. 3 and 4. FIG. 8 is a perspective view showing a main part of the coin check device shown in FIGS. 3 and 4. FIG. 9 is an enlarged perspective view showing an attachment portion between the conveyance belt and the pressure conveyance member. FIG. 10 is an enlarged plan view showing the pressing and conveying member displaced rearward by the conveying belt. FIG. 11 is an explanatory view showing the guide member and its peripheral structure shown in FIGS. 3 and 4 in an enlarged manner. FIG. 12 is an exploded perspective view showing the main components of the coin coin separating unit shown in FIGS. 3 and 4 separately. FIG. 13 is a plan view of the separation main body shown in FIG. FIG. 14 is a left side view showing the movable flapper shown in FIG. FIG. 15 is a longitudinal sectional view of the discrimination unit shown in FIGS. 3 and 4. FIG. 16 is a perspective view showing the coin transport device shown in FIGS. 1 and 2. FIG. 17 is a perspective view in which some components of the coin transfer device shown in FIG. 16 are omitted. FIG. 18 is a plan view in which some components of the coin transport device shown in FIG. 16 are omitted. FIG. 19 is a block diagram schematically showing a characteristic control system of the coin transport device shown in FIGS. 16 and 17. FIG. 20 is a perspective view showing the rail portion shown in FIGS. 16 and 17. FIG. 21 is a perspective view illustrating the rail portion illustrated in FIGS. 16 and 17. FIG. 22 is a perspective view showing a transport unit constituting the coin transport device shown in FIG. FIG. 23 is an explanatory view showing the components of the holding unit shown in FIG. 22 in an exploded manner. FIG. 24 is an enlarged perspective view showing main parts of the second rail forming member and the fourth rail forming member. FIG. 25 is an enlarged cross-sectional view showing a facing portion between the upper end portion of the curved upper extending portion of the third rail forming member and the right end portion of the second left extending portion of the fourth rail forming member. FIG. 26 is an enlarged perspective view showing a continuous portion of the curved lower extending portion of the first rail forming member and the first left extending portion of the second rail forming member. FIG. 27 is an enlarged left side view of the upper portion of the reverse roller. FIG. 28 is a schematic diagram of the attitude regulating member shown in FIG. FIG. 29 is a front view of the main part of the third rail forming member. 30 is a schematic diagram of the passage restricting member shown in FIG. FIG. 31 is a schematic view of the passage restricting member shown in FIG. FIG. 32 is a schematic view of the passage restricting member shown in FIG. FIG. 33 is a perspective view showing the sorting gate shown in FIGS. 16 and 17. FIG. 34 is a schematic diagram showing the operation of the sorting gate shown in FIG. FIG. 35 is a schematic diagram showing the operation of the sorting gate shown in FIG. FIG. 36 is a schematic diagram showing the operation of the sorting gate shown in FIG. 33 from above. FIG. 37 is an explanatory view showing the operation of the holding and pressing member in the third rail forming member. FIG. 38 is an explanatory view showing the operation of the holding and pressing member in the fourth rail forming member.

  Exemplary embodiments of a coin transport device according to the present invention will be described below in detail with reference to the accompanying drawings.

  1 and 2 are perspective views showing an internal structure of a coin processor to which a coin transport device according to an embodiment of the present invention is applied.

  The coin processing machine 1 exemplified here is applied as, for example, a change machine, and stores coins received for each denomination while paying out coins stored according to a withdrawal instruction. Such a coin processing machine 1 includes a coin check device 10a and a coin transport device 10b.

<Coin checking device>
FIG. 3 is a perspective view showing the coin checking device 10a shown in FIGS. 1 and 2, and FIG. 4 is a perspective view showing some components omitted from the coin checking device 10a shown in FIG. FIG. 5 is a block diagram schematically showing a characteristic control system of the coin checking device 10a shown in FIGS.

  The coin check device 10a illustrated here discriminates the authenticity and denomination of coins deposited through the depositing unit 2. Here, the depositing unit 2 has a coin insertion slot 2a as shown in FIGS. 1 and 2, and is a portion where coins are deposited.

  As shown in FIGS. 3 to 5, the coin check device 10 a includes a check coin transfer unit (transfer means) 20, a guide member 30, a check coin separation unit 40, and a discrimination unit (discrimination means) 50. The quarantine control unit 60 is provided.

  6 and 7 show the main part of the coin check device 10a shown in FIGS. 3 and 4, respectively. FIG. 6 is a plan view and FIG. 7 is a bottom view. As shown in FIGS. 6 and 7, the coin-carrying conveyance unit 20 includes a conveyance pulley 21, a conveyance belt 22, a pressing conveyance member (conveyance member) 23, a delivery flapper 24, and a false coin opening 25. It is prepared for.

  As shown in FIG. 8, the transport pulley 21 is installed in a pair of front and rear inside the transport apparatus body 20 a that is a casing. The rear-side transport pulley 21a is linked to the output shaft of the check transportation motor 21c via a linkage gear unit 21d. Here, the change transport motor 21c is driven when a drive command is given from the change control unit 60, and is stopped when a drive stop command is given from the change control unit 60.

  The rear-side transport pulley 21a is a drive pulley that rotates about its own central axis as a central axis by driving of the check transportation motor 21c. The rear-side transport pulley 21a rotates in the counterclockwise direction when viewed from the left side when the driving force of the check transportation motor 21c is applied.

  The conveyor belt 22 is a pair of left and right, and is stretched between the conveyor pulleys 21 in an endless manner. Such a conveyance belt 22 is displaced along the extending direction when the conveyance pulley 21a on the rear side is rotated by the driving of the check conveyance motor 21c. More specifically, the conveyor belt 22 is displaced in such a manner that the lower part is directed forward while the upper part is directed rearward by the rotation of the rear conveyor pulley 21a.

  The front-side transport pulley 21b linked to the rear-side transport pulley 21a via the transport belt 22 is opposite to the left-hand side when viewed from the left with its own central axis as an axis due to the rotation of the rear-side transport pulley 21a. Rotate clockwise. That is, the front-side transport pulley 21b is a driven pulley that rotates according to the rotation of the rear-side transport pulley 21a.

  A plurality of the press conveying members 23 are provided, and each of them is provided in such a manner that each of the pressing conveying members 23 straddles the pair of left and right conveying belts 22 and is equally spaced along the extending direction of the conveying belt 22. As shown in FIG. 9, such a pressing and conveying member 23 is provided at the left end portion while the right end uneven portion 23 a provided at the right end portion is fitted to the right uneven portion 22 a provided at the right conveyance belt 22. The left end uneven portion 23 b is fixed to the left and right conveying belts 22 by being fitted to the left uneven portion 22 b provided on the left conveying belt 22. As a result, the pressing and conveying member 23 is displaced along the extending direction of the conveying belt 22 in accordance with the displacement of the conveying belt 22. The pressing and conveying member 23 is fixed by fitting the concave and convex portions 23a and 23b at both left and right ends with the concave and convex portions 22a and 22b of the conveying belt 22, but the movement in the horizontal direction relative to the conveying belt 22 is as follows. The left and right side portions 20a1 of the transport device main body 20a are restricted, and the upward movement with respect to the transport belt 22 is restricted by the top portion 20a2 of the transport device main body 20a, and the downward movement with respect to the transport belt 22 is restricted. It is regulated by the bottom (not shown) of 20a.

  The pressing and conveying member 23 has a surface 23c facing the downstream side in the displacement direction of the conveying belt 22, that is, a surface facing the rear in the upper part of the conveying belt 22 and a surface facing the front in the lower part of the conveying belt 22. It has a shape. That is, as shown in FIG. 10, the pressing and conveying member 23 has a surface 23 c that faces the downstream side in the displacement direction of the conveyance belt 22, and a surface that inclines toward the upstream side in the displacement direction toward the left. As it goes to the right, a surface inclined toward the upstream side in the displacement direction is continuous at the center portion to form a V shape.

  As shown in FIGS. 6 and 7, the delivery flapper 24 is provided on a conveyance base 26 provided between the pair of left and right conveyance belts 22. More specifically, the delivery flapper 24 is swingably provided at the left edge of the delivery port 24a formed in the transport base 26. Here, the delivery port 24a is an opening that communicates with the delivery path, and is capable of delivering coins passing through the delivery path to the coin transport device 10b through the delivery path.

  Such a delivery flapper 24 is normally closed in such a manner as to restrict the passage of coins through the delivery port 24a. When the delivery flapper drive mechanism 24b is driven, the delivery flapper 24 swings in the opening direction to open the delivery outlet 24a. Here, the delivery flapper drive mechanism 24b is driven by the drive command given from the change control unit 60 to swing the delivery flapper 24 in the opening direction, and the drive stop command is given from the change control unit 60. Thus, the driving is stopped and the delivery flapper 24 is allowed to close the delivery port 24a.

  As shown in FIGS. 6 and 7, the false coin opening 25 is a rectangular opening formed on the rear side of the delivery port 24 a in the transport base portion 26. The false coin opening 25 has a sufficient size to allow passage of coins. The coin that has passed through the false coin opening 25 is placed on the bottom of the transport apparatus body 20a.

  As shown in FIGS. 3 and 4, the guide member 30 is provided in an upper part of the delivery port 24 a in the top part 20 a 2 of the transport apparatus body 20 a. As shown in FIG. 11, the guide member 30 includes a guide shaft portion 31 and a guide action portion 32.

  The guide shaft portion 31 is a columnar member that extends along the left-right direction. The guide action portion 32 is a portion that extends outward in the radial direction of the guide shaft portion 31, more specifically, rearward.

  In such a guide member 30, the guide action portion 32 passes through the guide opening 20a3 formed in the top portion 20a2, and the guide shaft portion 31 is installed on the guide support piece 20a4 provided in the top portion 20a2. Accordingly, the guide shaft portion 31 is provided so as to be swingable around the central axis.

  More specifically, the guide member 30 is provided so as to be swingable in such a manner that the lower end portion of the guide action portion 32 moves forward and backward to the coin passage area A conveyed backward by the coin coin conveyance portion 20. In a normal state, the lower end portion of the guide action portion 32 is in a posture of moving forward into the passing area A. When the delivery outlet 24a is closed by the delivery flapper 24, the guide member 30 is pressed by the coin passing through the passage area A and swings in a manner of retreating from the passage area A. While allowing the coin to pass rearward, when the delivery port 24a is opened by the delivery flapper 24, the coin abuts on the coin passing through the passage area A and guides the coin to the delivery port 24a It is.

  The coin-carrying coin separating unit 40 sends coins deposited through the depositing unit 2 in a state in which the coins are separated into the coin-carrying coin transport unit 20 one by one.

  FIG. 12 is an exploded perspective view showing the main components of the coin coin separating unit 40 shown in FIGS. 3 and 4 separately. As shown in FIG. 12, the check coin separating unit 40 includes a separation main body 41, a rotating body 42, and a separation lid 43.

  The separation main body portion 41 has a bottomed cylindrical rotating body storage portion 41a, and a drive for applying a rotational driving force to the supply port 41b and the rotating body 42 for supplying coins to the coin coin transporting portion 20. A force giving opening 41c is formed. As shown in FIG. 13, a plurality of guide protrusions 41a2 for guiding coins to the supply port 41b are formed on the bottom surface portion 41a1 of the rotating body storage portion 41a in the separation main body portion 41 so as to protrude upward. Yes.

  The rotating body 42 has a substantially disk shape, and is stored in the rotating body storage portion 41a of the separation main body portion 41 so as to be rotatable around its own central axis. In such a rotating body 42, a plurality of (four in the illustrated example) coin passage holes 42a are formed on the same circumference around the central axis.

  A gear 44a of the driving force transmission unit 44 is engaged with the side surface of the rotating body 42 through the driving force applying opening 41c. As shown in FIG. 4, the driving force transmission unit 44 is interposed between the front conveying pulley 21 b and the rotating body 42 and transmits the rotational driving force of the conveying pulley 21 to the rotating body 42. .

  As described above, since the front-side transport pulley 21b is a driven pulley that rotates in accordance with the rotation of the rear-side transport pulley 21a, the rotational driving force of the rotating body 42 is given by the check transport motor 21c. That is, the rotation of the rotating body 42 and the rotation of the conveying pulley 21 are given from a common drive source, and the rotation of the rotating body 42 and the displacement of the conveying belt 22 are synchronized.

  The separation lid 43 is installed in such a manner as to cover the rotating body storage portion 41 a of the separation main body 41. The separation lid 43 is provided with an introduction port 43a and a movable flapper 45. The introduction port 43a is an opening for introducing the coin deposited by the depositing unit 2 into the rotating body 42 in the rotating body storage unit 41a.

  The movable flapper 45 has a movable shaft part 45a and a movable action part 45b. The movable shaft portion 45a is a columnar member that extends along the left-right direction. The movable action portion 45b is a portion that extends outward in the radial direction of the movable shaft portion 45a, more specifically, toward the lower rear side.

  Such a movable flapper 45 is configured such that the movable action portion 45 b passes through the introduction port 43 a, and the movable shaft portion 45 a is installed on the movable support piece 43 b provided on the separation lid body 43. It is provided so as to be swingable around the central axis 45a. More specifically, as shown in FIG. 14, the movable flapper 45 is provided so as to be able to swing with a part of the tip of the movable action portion 45 b in contact with the upper surface of the rotating body 42.

  As shown in FIG. 3 and FIG. 4, the discrimination unit 50 is installed at a location on the rear side of the coin coin separation unit 40 and on the front side of the delivery port 24a. The discrimination unit 50 discriminates the authenticity and denomination of the coin when the coin conveyed backward by the coin coin conveyance unit 20 passes through a predetermined discrimination area. The discrimination unit 50 gives the discrimination result to the coin change control unit 60 as a discrimination signal. Furthermore, as shown in FIG. 15, the discrimination unit 50 is provided with a plurality of ball pressures 51. These ball pressures 51 are for pressing coins passing rearward from above.

  The check control unit 60 controls the operation of the coin check device 10a in accordance with programs and data stored in the memory 61. The quarantine control unit 60, for example, causes a processing device such as a CPU (Central Processing Unit) to execute a program, that is, may be realized by software or realized by hardware such as an IC (Integrated Circuit). Alternatively, software and hardware may be used in combination.

  In the coin check device 10a having the above-described configuration, a plurality of coins are deposited through the deposit unit 2, and the coin control unit 200 controls the operation of the coin processor 1 from the coin processing main control unit 200. When the operation command is given to 60, the change control unit 60 gives a drive command to the change transport motor 21c.

  As a result, the coin transportation motor 21c is driven, and in the coin coin transportation section 20, the transportation pulley 21 rotates counterclockwise as viewed from the left, whereby the transportation belt 22 is displaced along the extending direction. Further, due to the rotation of the transport pulley 21, the rotating body 42 of the coin separation unit 40 rotates in the clockwise direction through the driving force transmission unit 44 as viewed from above.

  Then, when the coins deposited by the depositing unit 2 are introduced into the upper surface of the rotating body 42 through the introduction port 43a of the separation lid 43, the coin checking unit 40 separates these coins into the respective coin passage holes 42a. Guidance in the state of lying down. As described above, since the movable flapper 45 is swingably provided on the separation lid 43 with a part of the tip portion of the movable action portion 45b being in contact with the upper surface of the rotating body 42, the movable flapper 45 is provided. The movable action portion 45b presses the coin on the upper surface of the rotating body 42, and guides the coin to the coin passage hole 42a in a sideways posture. Thereby, the coins guided to the coin passage hole 42a are stacked in the coin passage hole 42a.

  Of the coins guided and stacked in the coin passage hole 42 a, the lowest coin comes into sliding contact with the bottom surface portion 41 a 1 of the rotating body storage portion 41 a in the separation main body portion 41 by the rotation of the rotating body 42. And since the guide protrusion 41a2 is formed in the bottom face part 41a1 of the rotary body storage part 41a, as shown in FIG. 13, the coin change coin separating part 40 has the lowest position in contact with the guide protrusion 41a2. The coin is separated from the coin passage hole 42a and supplied to the coin-conveying coin transport unit 20 through the supply port 41b. That is, the coin coin separating unit 40 sends out the coins deposited through the depositing unit 2 in a state where the coins are separated one by one into the coin coin transporting unit 20.

  Coins supplied from the supply port 41b to the coin coin transport unit 20 are placed on the upper surface of the transport base 26 in a sideways posture. Since the conveyor belt 22 is displaced in the extending direction as described above, the pressing and conveying member 23 fixed to the conveyor belt 22 is placed on the upper surface of the conveyor base 26 as shown in FIG. The coin is pressed backward to convey the coin backward.

  Here, since the surface 23c facing the downstream side in the displacement direction of the transport belt 22 is V-shaped, the surface 23c facing the downstream side of the press transport member 23 is the transport belt 22 as shown in FIG. It becomes a surface which presses a coin from this displacement, and can be conveyed toward the back in a state where the coin is brought close to the central portion in the left-right direction.

  In this way, the coin is conveyed backward while being pressed by the pressure conveying member 23. When the conveyed coin reaches the discrimination region by the discrimination unit 50, the discrimination unit 50 determines whether the coin is true or false. Species distinguish. The discrimination unit 50 sends the discrimination result to the quarantine control unit 60 as a discrimination signal.

  The coin change control unit 60 inputs a discrimination signal from the discrimination unit 50, and gives a drive command to the sending flapper drive mechanism 24b when the discrimination result is a true coin. Thereby, the delivery flapper drive mechanism 24b is driven, and the delivery flapper 24 swings in the opening direction to open the delivery outlet 24a. When the delivery flapper 24 opens the delivery port 24a in this way, the coins that are conveyed backward through the discrimination region while being pressed by the pressure conveying member 23 abut on the guide member 30 and change the posture. , It passes through the outlet 24a and is sent to the coin transport device 10b. After the coins identified as genuine coins pass through the outlet 24a, the check control unit 60 gives a drive stop command to the delivery flapper drive mechanism 24b. As a result, the delivery port 24a is closed by the delivery flapper 24.

  On the other hand, the quarantine control unit 60 receives the discrimination signal from the discrimination unit 50, and when the discrimination result is a false coin, the sending control by the sending flapper 24 without giving a driving command to the sending flapper driving mechanism 24b. The closing of the outlet 24a is maintained.

  As a result, the coins that pass through the discrimination area and are conveyed backward while being pressed by the pressing and conveying member 23 pass through the upper surface of the delivery flapper 24, pass through the false coin opening 25, and fall downward. The coins that have dropped down in this way are placed in a sideways posture on the bottom of the transport apparatus body 20a.

  By the way, due to the rotation of the transport pulley 21, the lower part of the transport belt 22 is displaced forward. Therefore, as shown in FIG. 7, the pressing and conveying member 23 fixed to the conveying belt 22 moves forward below the coin coin conveying unit 20, so that the coins placed on the bottom are It can convey in the state which the press conveyance member 23 pressed toward the front. At this time, since the surface 23c facing the downstream side in the displacement direction of the conveyor belt 22 is V-shaped, the pressing and conveying member 23 conveys the coin toward the rear in a state where the coin is brought to the central portion in the left-right direction. can do.

  In this way, the coin coin transport unit 20 sends the coins (fake coins) transported forward to the payout unit 3 (see FIG. 4).

  The payout unit 3 includes a payout belt 3b stretched endlessly between a pair of left and right payout pulleys 3a. The payout unit 3 is configured such that the right payout pulley 3a is rotated by the drive of the payout motor 3c so that the payout coins are sent to the payout unit 4 and the coins provided in the payout unit 4 are provided. It is to be paid out from the payout opening 4a.

  As described above, the coin checking device 10a discriminates the authenticity and denomination of the coins deposited through the depositing unit 2, and sends the coins identified as genuine coins to the coin transport device 10b, Coins identified as fake coins are paid out to the outside through the withdrawal unit 4.

  And according to such a coin check apparatus 10a, the check coin conveyance part 20 is made to pass the fake coin opening 25 about the coin conveyed to back and discriminated from the fake coin by the discrimination part 50. Since it is conveyed forward, the length in the front-rear direction of the coin coin transport unit 20 can be shortened, whereby the coin processor 1 can be reduced in size.

  According to the coin coin checking device 10a, the pressing and conveying member 23 that constitutes the coin checking and conveying unit 20 has a V-shaped surface 23c that presses the coin by the displacement of the conveying belt 22. The coins can be transported in a state of being moved toward the central portion in the left-right direction, whereby the coins can be stably transported in a state where the transport position of the coins is restricted, and the accuracy of discrimination by the discrimination unit 50 is improved. Can be achieved.

<Coin transport device>
16 is a perspective view showing the coin transport device 10b shown in FIGS. 1 and 2, and FIG. 17 is a perspective view showing a part of the coin transport device 10b shown in FIG. 16 with some components omitted. 18 is a plan view in which some components of the coin transport device 10b shown in FIG. 16 are omitted, and FIG. 19 is a characteristic view of the coin transport device 10b shown in FIGS. It is a block diagram which shows typically a control system.

  The coin conveyance device 10b exemplified here conveys a coin whose trueness and denomination have been identified by the coin checking device 10a, determines the denomination of the coin in the middle of the conveyance, and removes the coin for each denomination. To the coin storage unit 5 (see FIGS. 1 and 2). Here, the coin storage unit 5 stores the coins sorted by the coin transport device 10b for each denomination. When a withdrawal instruction is given, the corresponding coin is sent to the withdrawal unit 4. Then, the money is paid out to the outside through the withdrawal unit 4.

  The coin transfer device 10b includes a rail unit 70, a transfer unit 80, a reverse roller 90, a regulation unit 100 (see FIGS. 26 and 27), a determination unit 110, a return unit 120, and a distribution unit 130. And a conveyance control unit (control means) 140.

  As shown in FIG. 20, the rail portion 70 includes a first rail forming member 71, a second rail forming member 72, a third rail forming member 73, and a fourth rail forming member 74.

  The 1st rail formation member 71 forms the conveyance path | route HK of the rear side right part in the coin conveying apparatus 10b. The first rail forming member 71 has a curved extending portion 71a that curves downward in a convex manner rearward. That is, the 1st rail formation member 71 comprises the descent | fall part extended in the aspect curved toward the downward direction.

  The 2nd rail formation member 72 forms the conveyance path HK of the lower part in the coin conveying apparatus 10b. The second rail forming member 72 has a first left extending portion 72a, a front extending portion 72b, and a first right extending portion 72c.

  The first left extending portion 72a is a portion that is continuous with the curved lower extending portion 71a in the first rail forming member 71 and extends toward the left. The front extension 72b is a part extending forward from the extension end of the first left extension 72a. The 1st right extension part 72c is a part extended toward the right from the extension edge part of the front extension part 72b. The second rail forming member 72 is formed with a slot 72d into which a coin discriminated as a genuine coin by the coin check device 10a is inserted.

  The 3rd rail formation member 73 forms the conveyance path HK of the front side right part in the coin conveying apparatus 10b. The third rail forming member 73 has a curved upper extending portion 73a that is continuous with the first right extending portion 72c in the second rail forming member 72 and curves upward in a manner that protrudes backward. . That is, the 3rd rail formation member 73 comprises the raising part extended in the aspect curved toward upper direction.

  The 4th rail formation member 74 forms the upper conveyance path HK in the coin conveyance apparatus 10b. The fourth rail forming member 74 has a second left extension 74a, a rear extension 74b, and a second right extension 74c.

  The second left extension 74a is a part extending toward the left. The second left extension 74 a is curved such that the right end 74 a 1 faces the upper end 73 a 1 of the curved upper extension 73 a of the third rail forming member 73. The rear extension 74b is a part that extends rearward from the extension end of the second left extension 74a. The second right extending portion 74c is a portion extending rightward from the extending end portion of the rear extending portion 74b. The second right extension 74 c is curved such that the right end 74 c 1 faces the upper end 71 a 1 of the curved lower extension 71 a of the first rail forming member 71.

  Thus, the rail part 70 is provided with the first rail forming member 71, the second rail forming member 72, the third rail forming member 73, and the fourth rail forming member 74 in order, thereby providing an endless conveyance path. HK is configured.

  Further, in the rail portion 70, the fourth rail forming member 74 is supported in such a manner that the first protrusion 75a formed at the right end portion 74a1 of the second left extending portion 74a sandwiches the third rail forming member 73 forward and backward. A second protrusion 75b that is inserted through the first support hole 76a of the first support plate 76 and is formed at the right end 74c1 of the second right extension 74c supports the first rail forming member 71 in a manner that sandwiches the first rail forming member 71 in the front-rear direction. 2 A second support hole (not shown) of the support plate 77 is inserted. Here, the 1st protrusion 75a and the 2nd protrusion 75b are provided in the aspect with which a mutual center axis corresponds. Therefore, the fourth rail forming member 74 can swing about the central axis of the first protrusion 75a and the second protrusion 75b, for example, by an angle of about 60 ° around the axis. That is, as shown in FIG. 21, the fourth rail forming member 74 can swing in the vertical direction with the central axes of the first protrusion 75a and the second protrusion 75b as the axis.

  FIG. 22 is a perspective view showing a transport unit 80 constituting the coin transport apparatus 10b shown in FIG. As shown in FIG. 22, the transport unit 80 is configured by connecting a plurality of holding units 81 in an endless manner.

  A part of such a conveyance unit 80 meshes with the drive conveyance pulley 85 a and a plurality of (three in the illustrated example) driven conveyance pulleys 85 b, and the drive conveyance pulley 85 a is rotated by driving the conveyance drive motor 83. By doing so, it is displaced along the transport path HK.

  Here, the conveyance drive motor 83 is driven by a drive command from the conveyance control unit 140 and can be driven in forward and reverse rotation. When the conveyance drive motor 83 is driven in the forward rotation direction, each holding portion 81 of the conveyance unit 80 has the first rail forming member 71, the second rail forming member 72, the third rail forming member 73, and the fourth rail forming member. The rail part 70 is displaced in such a manner that it moves in one direction in the order of 74.

  On the other hand, when the conveyance drive motor 83 is driven in the reverse rotation direction, each holding portion 81 of the conveyance unit 80 has the fourth rail forming member 74, the third rail forming member 73, the second rail forming member 72, and the first rail. The rail part 70 is displaced in such a manner that it moves in the reverse direction in the order of the forming member 71.

  In the transport unit 80, the posture of the holding unit 81 that passes through the second rail forming member 72 and the holding unit 81 that passes through the fourth rail forming member 74 are inverted up and down due to the form of the transport path HK. Yes.

  The holding unit 81 which is a component of the transport unit 80 holds coins one by one, and a holding pressing member 82 and a holding regulating member 83 are connected to a holding connecting member 84 as shown in FIG. It is constituted by.

  The holding and pressing member 82 is a rod-like body that extends from the inside to the outside of the transport path HK. Such a holding and pressing member 82 presses coins toward the downstream side of the transport path HK due to the displacement of the transport section 80, and the pressing surface 82a facing the downstream side of the transport path HK is outward from the inside. As it goes, it is gradually inclined to the upstream side.

  Further, as shown in FIGS. 24 to 26, the holding pressing member 82 includes a rail convex portion 71A formed on the first rail forming member 71, a rail convex portion 72A formed on the second rail forming member 72, and a third portion. A first concave portion 82b that allows the rail convex portion 73A formed on the rail forming member 73 to enter, and a second concave portion 82c that allows the rail convex portion 74A formed on the fourth rail forming member 74 to enter. An inclined surface 82d is formed on the pressing surface 82a at the bottom of the first recess 82b.

  The holding regulating member 83 has the same form as the holding pressing member 82 and is a rod-like body extending from the inside to the outside of the transport path HK. Such a holding regulating member 83 is connected to the holding pressing member 82 on the inner side via the holding connecting member 84, and a coin that is pressed against the holding pressing member 82 by displacement in one direction of the transport unit 80 is required. As described above, separation from the holding and pressing member 82 is restricted. The holding regulating member 83 is connected to the holding pressing member 82 constituting the holding unit 81 on the downstream side of the holding unit 81 on the inner side.

  The holding restricting member 83 is configured such that the downstream surface 83a facing the downstream side of the transport path HK is gradually inclined toward the upstream side from the inside toward the outside. The holding restricting member 83 includes a rail convex portion 71A formed on the first rail forming member 71, a rail convex portion 72A formed on the second rail forming member 72, and a rail convex portion formed on the third rail forming member 73. A third recess 83b allowing entry of the portion 73A, and a fourth recess 83c allowing entry of the rail projection 74A formed in the fourth rail forming member 74, and a bottom portion of the third recess 83b. An inclined surface 83d is formed on the downstream surface 83a.

  As described above, the upper end portion 73a1 of the curved upper extending portion 73a of the third rail forming member 73 and the right end portion 74a1 of the second left extending portion 74a of the fourth rail forming member 74 are opposed to each other. Therefore, as shown in FIG. 25, in the holding portion 81 that passes through this portion, the rail convex portion 73 </ b> A of the third rail forming member 73 enters the first concave portion 82 b of the holding press member 82, and the holding press member 82. The rail convex portion 74A of the fourth rail forming member 74 enters the second concave portion 82c. Similarly, the rail convex portion 73A of the third rail forming member 73 enters the third concave portion 83b of the holding regulating member 83, and the rail convex portion of the fourth rail forming member 74 enters the fourth concave portion 83c of the holding regulating member 83. 74A enters.

  Further, as described above, the upper end portion 71a1 of the curved lower extending portion 71a of the first rail forming member 71 and the right end portion 74c1 of the second right extending portion 74c of the fourth rail forming member 74 are opposed to each other. Therefore, although not clearly shown in the drawing, the holding portion 81 that passes through such a portion, the rail convex portion 71A of the first rail forming member 71 enters the first concave portion 82b of the holding pressing member 82, and the holding pressing member 82. The rail convex portion 74A of the fourth rail forming member 74 enters the second concave portion 82c. Similarly, the rail convex portion 71A of the first rail forming member 71 enters the third concave portion 83b of the holding restricting member 83, and the rail convex portion of the fourth rail forming member 74 enters the fourth concave portion 83c of the holding restricting member 83. 74A enters.

  As shown in FIG. 17, the reverse roller 90 is rotatably provided on the first support plate 76 so as to face the third rail forming member 73. The reverse roller 90 is linked to a conveyance drive motor 83 via a conveyance linkage unit 91, and rotates about its own axis by driving the conveyance drive motor 83.

  The restriction unit 100 includes a posture restriction member 101 and a passage restriction member 102. As shown in FIG. 27, the posture regulating member 101 is attached to the posture regulating support portion 103 attached to the first support plate 76 in a mode facing the third rail forming member 73 in the upper region of the reverse roller 90. ing. As shown in FIG. 28, the posture regulating member 101 has a posture regulating shaft portion 101a and a plurality of posture regulating action portions 101b. The attitude regulating shaft portion 101 a is a columnar member extending along the front-rear direction, and both end portions thereof are supported by the attitude regulating support portion 103. The posture regulating action portion 101b is a disk-like member having a diameter larger than that of the posture regulating shaft portion 101a, and a through hole 101c is formed in the center portion thereof. These posture regulating action portions 101b are separated from each other along the extending direction of the posture regulating shaft portion 101a, and the posture regulating shaft portion 101a penetrates the through-hole 101c, so that the posture regulating shaft portion 101a It is provided so as to be rotatable. Here, the thickness in the front-rear direction of the posture regulating action portion 101 b is set to a size capable of entering the second concave portion 82 c of the holding pressing member 82 and the fourth concave portion 83 c of the holding regulating member 83.

  As shown in FIG. 29, the posture regulating member 101 presses the coins conveyed upward by the curved upper extending portion 73a of the third rail forming member 73 toward the third rail forming member 73 (rail portion 70). By doing so, the posture of the coin is regulated.

  As shown in FIG. 26, the passage restricting member 102 is opposed to a continuous portion of the curved lower extending portion 71 a of the first rail forming member 71 and the first left extending portion 72 a of the second rail forming member 72. The second support plate 77 is provided. As shown in FIG. 30, the passage restricting member 102 is configured by integrally forming a passage restricting shaft portion 102a and a passage restricting action portion 102b.

  The passage restricting shaft portion 102a is a columnar member extending along the front-rear direction, and both end portions thereof are pivotally supported by the second support plate 77 so as to be swingable around the central axis of the passage restricting shaft portion 102a. Yes. Two passage restriction action portions 102b are provided in a pair of front and rear, and are separated from each other from the central region portion of the passage restriction shaft portion 102a toward the outside in the radial direction of the passage restriction shaft portion 102a. It is an extended part.

  The passage restricting member 102 is urged rightward by a passage restricting spring 102c that is an urging means, and the leading end portion of the passage restricting action portion 102b is placed in a passage area B of a coin conveyed by the conveying portion 80. Have entered the market.

  Such a passage regulating member 102 moves the first rail forming member 71 downward as shown in FIG. 31 when the conveyance unit 80 is displaced in one direction when the conveyance drive motor 83 is driven in the forward direction. The coin is allowed to pass by abutting against the coin conveyed toward the left and swinging leftward against the urging force of the passage restriction spring 102c.

  On the other hand, when the conveyance drive motor 83 is driven in the reverse direction and the conveyance unit 80 is displaced in the reverse direction, the passage restricting member 102 has the conveyance unit in the second rail forming member 72 as shown in FIG. The coins conveyed in the reverse direction by 80 are separated from the holding portion 81, and the passage of the coins through the curved extending portion 71 a of the first rail forming member 71 is restricted.

  The determination unit 110 is provided on the fourth rail forming member 74. The discriminating unit 110 discriminates the denomination of coins that are conveyed while being pressed by the holding pressing member 82 of the holding unit 81 in a predetermined discrimination region in the fourth rail forming member 74. The discrimination result at the discrimination unit 110 is output to the transport control unit 140 as a discrimination signal.

  The return unit 120 is provided on the downstream side of the determination unit 110 (determination region) in the transport path HK formed by the fourth rail forming member 74 and includes a return opening 121 and a return gate 122.

  The return opening 121 is an opening having a size that allows passage of all denomination coins conveyed by the conveying unit 80, and communicates with the dispensing unit 4.

  The return gate 122 normally closes the return opening 121, and swings to open the return opening 121 when a return command is given.

  The sorting unit 130 is provided on the downstream side of the return unit 120 in the transport path HK formed by the fourth rail forming member 74. The distribution unit 130 includes a plurality of distribution passage ports 131 and a distribution gate 132.

  Each of the plurality of sorting passage openings 131 is an opening having a size sufficient to allow coins to pass therethrough. The sorting gates 132 are provided so as to cross the transport path HK formed by the fourth rail forming member 74 corresponding to each sorting passage port 131. More specifically, the sorting gate 132 is configured by attaching a plurality of sorting gate action pieces 132b to the tip of a long cylindrical sorting gate shaft portion 132a, and the sorting gate shaft portion 132a. Is supported so as to be rotatable around the central axis of the shaft.

  Then, as shown in an enlarged view in FIG. 33, a locking claw portion 134 attached to the distal end portion of the plunger 133 is locked to the proximal end portion of the sorting gate shaft portion 132a. Here, when the sorting drive solenoid 135 is in a non-energized state, the plunger 133 causes the sorting gate action piece 132b to carry a coin as shown in FIG. 34 by the biasing force of the spring 136 attached thereto. The posture is taken away from the route HK.

  On the other hand, when the distribution drive solenoid 135 is energized when a drive command is given from the conveyance control unit 140, the plunger 133 is pulled by the distribution drive solenoid 135, and as shown in FIG. The distribution gate 132 is rotated around the central axis of the distribution gate shaft portion 132a, and the distribution gate action piece 132b is advanced to the transport path HK.

  When the sorting gate action piece 132b advances into the transport path HK in this way, as shown in FIG. 36, the end of the sort gate action piece 132b moves toward the sorting passage port 131 toward the downstream side in the carrying direction. An inclined portion K that is inclined in the direction is formed, and the coins conveyed along the conveying path HK by the inclined portion K can be guided to a predetermined sorting passage port 131.

  The conveyance control unit 140 comprehensively controls the operation of the coin conveyance device 10b according to programs and data stored in the memory 141. For example, the transport control unit 140 may cause a processing device such as a CPU (Central Processing Unit) to execute a program, that is, may be realized by software, or may be realized by hardware such as an IC (Integrated Circuit). Alternatively, software and hardware may be used in combination.

  Further, as described above, the transport control unit 140 gives a drive command to the transport drive motor 83 to drive the transport drive motor 83 in the forward rotation direction or the reverse rotation direction. When driving in the rolling direction, PWM control is performed so as to approximate a predetermined conveying force.

  On the other hand, when driving the conveyance drive motor 83 in the reverse direction, the conveyance control unit 140 controls the conveyance force to be larger than the conveyance force when driving in the forward direction.

  That is, the conveyance control unit 140 displaces the conveyance unit 80 in such a manner that the driving force for displacement in one direction is relatively smaller than the driving force for displacement in the reverse direction.

  In the coin transport device 10b having the above-described configuration, a coin discriminated as a genuine coin is sent from the coin check device 10a and an operation command is given from the coin processing main control unit 200 to the transport control unit 140. It works as follows.

  That is, the conveyance control unit 140 gives a drive command in the reverse direction to the conveyance drive motor 83 to drive the conveyance drive motor 83 in the reverse direction, and displaces the conveyance unit 80 in the reverse direction for a predetermined time. Thereby, the coins thrown into the second rail regulating member from the slot 72d are transported in the reverse direction by the transport unit 80 in the second rail forming member 72.

  By the way, the passage restricting member 102 causes the second rail forming member 72 to disengage the coins conveyed in the reverse direction by the conveying unit 80 from the holding unit 81, and the coins are bent downwardly extending 71 a of the first rail forming member 71. The coins inserted from the insertion port 72d can be stored in the second rail forming member 72.

  Then, after a predetermined time has elapsed, the conveyance control unit 140 gives a drive command in the forward rotation direction to the conveyance drive motor 83 to drive the conveyance drive motor 83 in the forward rotation direction, and causes the conveyance unit 80 to be Displace in the direction. Thereby, the coin stored by the 2nd rail formation member 72 can be conveyed in one direction along the conveyance path | route HK.

  Since the holding portion 81 of the conveying portion 80 has an inclined surface 82d formed on the pressing surface 82a of the bottom portion of the first concave portion 82b of the holding pressing member 82, the curved upward extending portion 73a of the third rail forming member 73 is formed. When passing, the inclined surface 82d is moved away from the rail by being displaced with the rail convex portion 73A of the third rail forming member 73 entering the first concave portion 82b.

  Therefore, even when two coins are overlapped in the lower region of the reverse roller 90 and are conveyed while being pressed by the holding and pressing member 82, as shown in FIG. 37, the coins are held using the inclined surface 82d. It can be detached from the pressing member 82. As a result, it is possible to suppress the occurrence of transport clogging or the like due to two coins being sandwiched between the reverse roller 90 and the transport unit 80.

  Further, in the upper region of the reverse roller 90, the posture regulating member 101 directs the coins conveyed upward by the curved upward extending portion 73a of the third rail forming member 73 toward the third rail forming member 73 (rail portion 70). Since the posture of the coin is restricted by pressing, it is possible to prevent the coin from being separated during the passage through the curved upper extension 73a.

  Furthermore, the upper end portion 73a1 of the curved upper extending portion 73a of the third rail forming member 73 and the right end portion 74a1 of the second left extending portion 74a of the fourth rail forming member 74 are opposed to each other and pass through this portion. In the holding portion 81, the rail convex portion 73A of the third rail forming member 73 enters the first concave portion 82b of the holding pressing member 82, and the fourth rail forming member 74 of the fourth rail forming member 74 enters the second concave portion 82c of the holding pressing member 82. Since the rail convex portion 74A enters the state, the coin pressed by the holding pressing member 82 is also sandwiched between the upper end portion 73a1 of the curved upper extension portion 73a and the right end portion 74a1 of the second left extension portion 74a. There is no possibility that the coins are separated from the transport path HK.

  In this way, in the holding portion 81 that has passed through the third rail forming member 73, one coin is held. And since the pressing surface 82a of the holding | maintenance press member 82 which comprises each holding | maintenance part 81 of the conveyance part 80 is comprised, it can convey stably in the state which brought the coin to the outer side of the conveyance path | route HK. it can.

  As described above, in the transport unit 80, the holding unit 81 that passes through the second rail forming member 72 and the holding unit 81 that passes through the fourth rail forming member 74 are vertically inverted, so that the first When the rail convex portion 74A of the fourth rail forming member 74 is displaced into the second concave portion 82c, the inclined surface 82d is positioned below the upper end portion of the rail convex portion 74A as shown in FIG. That is, the holding and pressing member 82 can reliably press the coin and stably convey it.

  Then, when the denomination of the coin passing through the determination area is determined by the determination unit 110, the transfer control unit 140 gives a drive command to the corresponding distribution drive solenoid 135 in accordance with the determination result, so The minute drive solenoid 135 is energized. As a result, the corresponding sorting gate 132 is rotated around the central axis of the sorting gate shaft portion 132a, and the sorting gate action piece 132b is advanced to the transport path HK. The coins can be guided to the corresponding sorting passage port 131 and stored in the coin storage unit 5 by the inclined portion K formed by the sorting gate action piece 132b.

  By the way, when the denomination of the coin is not determined by the determination unit 110, the transport control unit 140 does not give a drive command to any of the sorting drive solenoids 135. In that case, since all the sorting gates 132 are in a state in which the sorting gate action piece 132b is detached from the transport path HK, the coin that has passed through the fourth rail forming member 74 passes through the first rail forming member 71 as it is. After that, the second rail forming member 72 is reached, the passage of the transport path HK described above is repeated, and the determination unit 110 determines again.

  In this way, when all the coins transported along the transport path HK are stored in the coin storage unit 5 for each denomination within the operation time determined in advance, the transport control unit 140 causes the transport drive motor 83 to A drive stop command is given to stop the transport drive motor 83, and then a signal to the effect that the transport of coins is completed is sent to the coin processing main control unit 200.

  On the other hand, when the operation time has elapsed with coins remaining in the transport path HK, the transport control unit 140 gives a return command to the return gate 122 to open the return opening 121, and the transport path The coin carrying the HK is guided to the return opening 121 and sent to the withdrawal unit 4, and is paid out to the outside from the withdrawal unit 4.

  As described above, according to the coin transport device 10b, the transport unit 80 configured by connecting the holding units 81 capable of holding coins one by one in an endless manner is curved upward. By moving in one direction along a rail portion 70 that constitutes a predetermined transport path HK having a curved upper extending portion 73a (ascending portion) that extends in the direction, the received coins are transported from below to above. Therefore, the installation area of the coin processor 1 can be reduced as compared with the case where a plurality of belts stretched endlessly on a pair of rollers is provided as in the prior art, and the coin handling machine 1 is reduced. The processor 1 can be downsized.

  And the attitude | position control member 101 presses the coin conveyed upward in the curved upward extension part 73a of the 3rd rail formation member 73 toward the 3rd rail formation member 73 (rail part 70), and this coin Since the posture is restricted, it is possible to prevent the coins from being separated during the passage through the curved upper extending portion 73a, thereby suppressing the occurrence of coin clogging during the conveyance.

  Further, according to the coin transport device 10b, when the coin is inserted into the transport unit 80, the transport control unit 140 displaces the transport unit 80 in the reverse direction for a predetermined time, and after the predetermined time has elapsed. Since the transport unit 80 is displaced in the one direction, the coins inserted from the insertion port 72d can be stored in the second rail forming member 72, and more coins can be received from the coin check device 10a.

  Furthermore, according to the coin transport apparatus 10b, the transport control unit 140 displaces the transport unit 80 in such a manner that the driving force for displacement in one direction is relatively smaller than the driving force for displacement in the reverse direction. When a trouble occurs when a coin is transported in one direction along the transport path HK and a coin clogging occurs, the transport drive motor 83 is driven in the reverse direction to displace the transport unit 80 in the reverse direction. In addition, the release force of the coin jam can be made larger than the force when the coin is jammed, and the coin jam can be eliminated.

  Furthermore, according to the coin transport device 10b, the fourth rail forming member 74 can swing in the vertical direction about the central axis of the first protrusion 75a and the second protrusion 75b. When coin clogging occurs in the second rail forming member 72 or the like, the fourth rail forming member 74 is swung upward to easily remove the coin causing the coin clogging from the second rail forming member 72. it can.

  The preferred embodiment of the present invention has been described above, but the present invention is not limited to this, and various modifications can be made.

  In the above-described embodiment, the check control unit 60 and the conveyance control unit 140 are configured separately. However, in the present invention, the same may be configured together with the coin processing main control unit 200. .

  Although not particularly described in the above-described embodiment, in the present invention, the curved portion from the second left extension 74a to the rear extension 74b of the fourth rail forming member 74, or the second extension 74b to the second extension. In the curved portion extending to the right extending portion 74c, the protruding height may be gradually reduced as the rail convex portion 74A goes outward. According to this, the coin to pass can be brought out to the outer side of the conveyance path | route HK.

  Further, in the present invention, a coin is formed on the curved portion from the first left extending portion 72a to the front extending portion 72b of the second rail forming member 72 or the outer portion of the curved portion from the front extending portion 72b to the first right extending portion 72c. You may provide the space for saving.

DESCRIPTION OF SYMBOLS 1 Coin processing machine 10a Coin inspection apparatus 10b Coin conveyance apparatus 20 Check coin conveyance part (conveyance means)
30 Guide member 40 Check coin separation part 50 Identification part (discrimination means)
60 Checking Control Unit 70 Rail Unit 80 Conveying Unit 90 Reverse Roller 100 Regulating Unit 101 Attitude Regulating Member 102 Passing Regulating Member 110 Discriminating Unit 120 Returning Unit 130 Sorting Unit 140 Conveying Control Unit (Control Unit)
HK transport route

Claims (3)

A coin transport device applied to a coin processing machine that stores coins received for each denomination while paying out coins stored according to a withdrawal instruction,
A rail portion that constitutes a predetermined transport path having a rising portion that extends in a manner that curves upward;
A holding part capable of holding coins one by one is connected endlessly, and is transferred in one direction along the rail part to convey the received coins upward from below. A transport section;
And a posture regulating member that regulates the posture of the coin by pressing the coin conveyed upward by the conveyance unit toward the rail portion at the rising portion.   2. The coin transport device according to claim 1, wherein the holding portion is displaced along the rail portion such that a rail convex portion formed on the rail portion enters a holding concave portion formed on the holding portion. . The transport path has a descending portion that extends in a manner that curves downward.
When the transport unit is displaced in one direction, the coins that are transported downward by the transport unit through the descending portion are allowed to pass, while when the transport unit is displaced in the reverse direction. 3. A passage restricting member that restricts the coins transported by the transporting part from being separated from the holding part and restricting the coins from passing through the descending part. Coin transport device.

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