JP6249551B2 - Article delivery and storage device - Google Patents

Description

  The present invention relates to an article feeding and storing apparatus for feeding and storing articles such as prizes.

At game facilities such as pachinko parlors, the number of prizes according to the number of game media such as pachinko balls acquired by the player is paid out to the player. In addition to general prizes such as confectionery and cigarettes, there are special prizes in which objects having a predetermined monetary value are incorporated. The following explanation will be made on the assumption that the prize described below is a special prize.
The player can exchange the prize by bringing the paid prize to the prize exchange. In the prize exchange place, an article feeding and storing device is installed for feeding and storing prizes received from players.

  A prize reading device proposed in Patent Document 1 below as an article feeding and storing apparatus includes a feeding section on which a plurality of prizes are placed, an identification section for reading a barcode printed on the prize, a transport section, and a lateral direction. And four prize storage units arranged side by side. After a plurality of prizes set in the feeding unit are fed out one by one by a pushing piece driven by a motor in the feeding unit, and the barcode is read by the identification unit during conveyance in the conveying unit These are classified into the respective value information, and are sequentially dropped and stored in a predetermined prize storage unit.

JP 2004-351087 A

In the prize reading device described in Patent Document 1, since the four prize storage units are provided side by side in the lateral direction, the lateral dimension (wide dimension) of the prize reading device inevitably increases. The gift reading device requires a wide installation space.
Even if there are four prize storage units, if there are more types of prizes, different types of prizes are stored in any of the prize storage units.

Further, in order to distribute the prizes from the transport unit to the prize storage units, a drive mechanism such as a solenoid is required at a branch portion from the transport unit to each prize storage unit. Furthermore, in order to accurately distribute prizes from the transport unit to the prize storage units, the drive mechanism is required to have high accuracy. This inevitably increases the cost of the prize reading device.
The present invention has been made under such a background, and an object thereof is to provide an article feeding and storing apparatus capable of reducing the cost and reducing the size.

According to the first aspect of the present invention, the feeding unit for feeding the set article, the conveyance path for conveying the article fed from the feeding part, and adjacent to each other in the crossing direction with respect to the conveyance direction of the article in the conveyance path A plurality of storage areas that are arranged and are capable of distributing and storing articles that have passed through the transport path for each storage area, and an interval for adjusting the width of each storage area in the intersecting direction An article feeding and storing device including an adjusting means .

The invention according to claim 2 includes one storage for storing articles, and the plurality of storage areas are configured by dividing an internal space of the storage in the intersecting direction. An article feeding and storing apparatus according to claim 1.
The invention according to claim 3 is characterized in that the crossing direction is a vertical direction, the number of the storage areas is the same as that of the storage area, the internal space of the storage is divided in the vertical direction, and a stage on which an article is placed is included. The article feeding and storing device according to claim 2.

The invention according to claim 4 is the article feeding and storing apparatus according to claim 3, wherein two storage areas and two stages are provided.
According to a fifth aspect of the present invention, the lower storage area located relatively lower of the plurality of storage areas stores a majority of articles, and the lower storage of the plurality of storage areas. 5. The article supply and storage device according to claim 3, wherein the upper storage area located above the area stores a minority article.

The invention according to claim 6 is the article feeding and storing apparatus according to claim 5, wherein the minority article includes an article to be rejected .

The invention according to claim 7 is a switching unit that switches the storage area that is a storage destination of an article among the plurality of storage areas, and the switching of the storage area by the switching unit until the article passes through the conveyance path. so it completed, characterized in that it comprises a and a speed adjusting means for adjusting the conveying speed of the articles in the transport path, an article feeding storage device according to any one of claims 1-6.

According to the first aspect of the present invention, in the article supply and storage device, the plurality of storage areas for storing the articles are adjacently arranged side by side in the direction intersecting the conveyance direction of the articles on the conveyance path. It is possible to reduce the size of the article supply and storage device in the transport direction.
In addition, with a simple configuration that only changes the relative position between each storage area and the transport path, each storage area and the transport path are selectively connected, and articles (passed through the transport path) are stored for each storage area. Since the items can be sorted and stored, the article feeding and storing apparatus can reduce the cost. In addition, since each storage area can be adjusted in width in the crossing direction of each storage area so that it can be stored just enough to store the number of articles to be stored, the internal space of the storage can be used effectively, The dimension of the storage room in the crossing direction can be kept small. Therefore, it is possible to further reduce the size of the article supply and storage device.

According to the second aspect of the present invention, a plurality of storage areas can be secured only by dividing the internal space of one storage in the crossing direction.
According to the third aspect of the present invention, the plurality of storage areas can be provided vertically by dividing the internal space of the storage in the vertical direction by the same number of stages as the storage areas. In each storage area, articles can be stored by being placed on the stage.

As in the fourth aspect of the present invention, two storage areas and two stages may be provided.
According to the fifth aspect of the present invention, a majority item is stored in the lower storage area, and a minority item is stored in the upper storage area. Compared to a configuration in which the minority items are stored in the lower storage area, the internal space of the storage can be effectively used in the vertical direction, so that the vertical dimension of the storage can be kept small. Therefore, it is possible to further reduce the size of the article supply and storage device.

As in the sixth aspect of the invention, the minority item may be a rejected item .

According to the seventh aspect of the present invention, since the article conveyance speed in the conveyance path is adjusted, the switching of the storage area can be surely completed before the article passes through the conveyance path. It is possible to reliably distribute the articles to the storage area switched as the storage destination.

FIG. 1 is a perspective view of a prize reader 1 according to an embodiment of the present invention as seen from the front side. FIG. 2 is a block diagram showing an electrical configuration of the prize reader 1. FIG. 3 is a perspective view showing the conveyance unit 5 of the prize reader 1 extracted. FIG. 4 is a perspective view illustrating the belt 22 included in the transport unit 5. FIG. 5 is a schematic diagram showing the configuration of the prize 40. FIG. 6 is a schematic diagram illustrating how the identification unit 6 identifies the prize 40 in the prize reader 1. FIG. 7 is a perspective view of the reading unit 52 in the identification unit 6. FIG. 8 is a perspective view of the internal structure of the reading unit 52. FIG. 9 is a diagram showing the contents of the table 60 stored in the storage unit 16 of the prize reader 1. FIG. 10 is a diagram illustrating the contents of the table 61 stored in the storage unit 16. FIG. 11 is a perspective view showing the storage unit 8 extracted from the prize reader 1, and shows a state where the stage 76 is in the reject prize extraction position. FIG. 12 is a perspective view of the storage portion 8 and shows a state in which the stage 76 is in the normal prize accumulation position. FIG. 13 is a front view of the storage unit 8 according to the modification. FIG. 14 is a diagram showing an example of display contents on the display unit 7 of the prize reader 1. FIG. 15 is a diagram illustrating an example of display contents on the display unit 7. FIG. 16 is a diagram illustrating an example of display contents on the display unit 7. FIG. 17 is a diagram illustrating an example of display contents on the display unit 7. FIG. 18 is an exploded perspective view of the prize 40. FIG. 19 is a cross-sectional view of the prize 40. FIG. 20 is a perspective view showing an IC tag 43 that is an internal part of the prize 40. FIG. FIG. 21 is a cross-sectional view of the IC tag 43. FIG. 22 is a diagram illustrating an example of an illegal act against the prize 40. FIG. 23 is a perspective view of the main part (including the IC tag 43) of the prize 40 before and after the fraud in FIG. FIG. 24 is a diagram illustrating an example of an illegal act with respect to the prize 40. FIG. 25 is a perspective view of the IC tag 43 before and after the fraud in FIG.

Below, with reference to drawings, the premium reader 1 concerning one embodiment of this invention is explained concretely. The prize reader 1 is also an apparatus (article feeding and storing apparatus) for feeding and storing articles (here, prizes).
As for the prize reader 1, there is a facility called a prize exchange that exchanges prizes paid to players at amusement facilities such as pachinko parlors. The prize reader 1 Is installed. Incidentally, the prize mentioned here is not a general prize such as confectionery or tobacco but a special prize in which an object (valuable material) having a predetermined monetary value is built. This prize is generally a resin card having a substantially rectangular shape with a thickness of about 1 to 3 mm. This prize contains the above-mentioned valuables, for example, there are a plurality (four in this case) of types according to denominations such as 200 yen, 1000 yen, 2000 yen, and 5000 yen. The prize will be described in more detail later.

  As an operation of the prize reader 1, a staff at the prize exchange place sets the prize received from the player in the prize reader 1. Thereafter, the operation of the prize reader 1 is started, and the set prizes are taken into the prize reader 1 one by one, and are collected for each group after receiving identification about authenticity and denomination. The identification result (the breakdown of the prizes received from the player) in the prize reader 1 is output to a dispensing machine (not shown) that is communicably connected to the prize reader 1, and from the dispensing machine, Cash equivalent to the prize of the player is withdrawn to the player. The above is a series of flows related to the redemption of prizes. Note that the prize exchange is provided with a prize management machine (not shown) for managing the inventory data of the prize, and the identification result in the prize reader 1 is output to the prize management machine, so that the prize management is performed. Inventory data in the machine may be updated. The prize management machine may be integrated with the prize reader 1.

  FIG. 1 is a perspective view of a prize reader 1 according to an embodiment of the present invention as seen from the front side. In the following, the orientation of the prize reader 1 and its components is specified with reference to the left, right, up, down, front and rear directions of the prize reader 1 when viewed from the front side (front side in FIG. 1) in FIG. I will decide. Here, the horizontal direction and the width direction of the prize reader 1 are the same, and the vertical direction and the vertical direction are the same. The front-rear direction (depth direction of the prize reader 1) and the left-right direction (width direction) are included in the horizontal direction.

Referring to FIG. 1, the prize reader 1 has a rectangular parallelepiped shape that is slightly long in the width direction. If the main body 2 is the part that forms the outline of the prize reader 1, the main body 2 has an operation section 3, a printer section 4, a transport section 5, an identification section 6 ( Identification means) and a display unit 7 are provided, and a storage unit 8 is provided in a region about one third of the left side.
The operation unit 3 is a portion that is operated (pressed) by a staff member of the gift exchange, and is provided, for example, at the right end at the approximate center in the vertical direction on the front surface of the main body 2. The operation unit 3 includes a start switch 9 that is operated to start the operation of the prize reader 1 and a stop switch 10 that is operated to stop the operation of the prize reader 1. And the stop switch 10 are arranged side by side.

The printer unit 4 is provided approximately at the center in the width direction on the upper surface of the main body 2. The printer unit 4 can journal the processing contents of the prize reader 1 as a paper slip.
The transport unit 5 is configured to feed the prizes received by the staff from the player one by one and transport them in the prize reader 1, which will be described in detail later. With regard to the transport unit 5, the upper right corner (corner) of the main body 2 is recessed so as to be cut out from both the front side and the upper side. It is set in a state of being stacked on each other, and is a feeding portion 11 for feeding the prize into the main body 2. Note that the prize stacking direction (vertical direction) coincides with the thickness direction of each prize.

The identification part 6 is a part for identifying the authenticity or denomination of the prize fed from the feeding part 11 of the transport part 5, and will be described in detail later.
The display unit 7 is a liquid crystal touch panel that occupies a substantially lower half of the above-described right two-third region on the front surface of the main body 2 and has a rectangular shape that is long in the width direction. Information necessary for the prize reader 1 is displayed on the display unit 7. The display contents on the display unit 7 will be described in detail later.

The storage unit 8 has a storage 71 for storing prizes that have been transported by the transport unit 5, and will be described in detail later.
FIG. 2 is a block diagram showing an electrical configuration of the prize reader 1.
Next, the electrical configuration of the prize reader 1 will be described with reference to FIG.
The prize reader 1 includes a control unit 15 (authentication discrimination means, denomination discrimination means, front / back discrimination means, identification means, control means, interval adjustment means, switching means, speed adjustment means) that controls the operation thereof. . The control unit 15 includes a CPU, a ROM, a RAM, and the like. In the prize reader 1, the operation unit 3, the printer unit 4, the transport unit 5, the identification unit 6, the display unit 7, and the storage unit 8 and the storage unit 16 are electrically connected to the control unit 15. Has been. The storage unit 16 stores various information.

Below, each detail of the conveyance part 5, the identification part 6, and the accommodating part 8 is demonstrated in this order.
FIG. 3 is a perspective view showing the conveyance unit 5 of the prize reader 1 extracted. FIG. 4 is a perspective view illustrating the belt 22 included in the transport unit 5. The postures of FIGS. 3 and 4 are the same as the posture of the prize reader 1 of FIG.

Referring to FIG. 3, the conveying unit 5 includes a frame 20 fixed to the main body 2 described above, the feeding unit 11 described above, a rotating shaft 21, a belt 22 as an (endless) conveying member, and a drive. The motor 23 is mainly included.
The frame 20 has a box shape that is long in the width direction and slightly thin in the front-rear direction when viewed from the front, and the entire front and bottom surfaces are open. That is, the frame 20 integrally includes an upper wall 20A, a left wall 20B, a right wall 20C, and a rear wall 20D.

  The upper wall 20A has a plate shape that is elongated in the width direction and thin in the vertical direction. The longitudinal dimension of the upper wall 20A is somewhat larger than the lateral dimension of the rectangular prize. The left wall 20B has a thin plate shape in the width direction, and extends downward from the left end of the upper wall 20A. The right wall 20C has a thin plate shape in the width direction, and extends downward from the right end of the upper wall 20A. The rear wall 20D has a thin plate shape in the front-rear direction, is laid between the rear ends of the left wall 20B and the right wall 20C, and is connected to the rear end of the upper wall 20A. In addition, in each of the upper wall 20A, the left wall 20B, the right wall 20C, and the rear wall 20D, a lightening hole (see the left wall 20B) may be formed as necessary.

  And the 1st vertical wall 24 extended thinly upwards in the width direction is connected to the width direction approximate center of 20 A of upper walls. A gap 25 is formed between the lower end of the first vertical wall 24 and the upper surface of the upper wall 20A so that one prize can pass through. That is, the vertical dimension of the gap 25 is slightly larger than the thickness of one premium, and the front-back dimension of the gap 25 is slightly larger than the short dimension of one premium. In addition, a second vertical wall 26 that extends thinly upward in the front-rear direction is connected to the substantially right half of the rear end of the upper wall 20A. The rear end of the first vertical wall 24 and the left end of the second vertical wall 26 are connected over substantially the entire area in the vertical direction, and the first vertical wall 24 and the entire second vertical wall 26 are entirely viewed in plan view. , Which is substantially L-shaped. A guide portion 27 is attached to the right end portion of the upper wall 20A. The guide part 27 has a hollow box shape, and is disposed to face the first vertical wall 24 from the right side. If the left side surface of the guide portion 27 facing the first vertical wall 24 is referred to as a guide surface 27A, the guide surface 27A extends substantially vertically upward, and then tilts to the upper right side away from the first vertical wall 24. doing.

  The substantially right side portion of the upper wall 20A, the first vertical wall 24, the guide portion 27 and the second vertical wall 26, and the portion surrounded by these constitute the feeding portion 11 described above. Then, on the upper surface of the upper wall 20A, the portion sandwiched in the width direction by the first vertical wall 24 and the guide portion 27 and partitioned from the rear side by the second vertical wall 26 has the prizes stacked vertically in the feeding portion 11. It is the set part 28 set in a state. In the setting unit 28, a maximum of 30 prizes are set such that the longitudinal direction of the prize is along the width direction of the prize reader 1. Since the guide surface 27A inclined in the guide part 27 guides the prize to the setting part 28, the prize can be smoothly set on the setting part 28.

  In the set portion 28, a notch 29 that cuts out the set portion 28 over the entire width direction is formed in a portion located directly below the front portion of the set prize. The notch 29 has a groove shape extending in the width direction. A cutout 30 is formed at a lower end portion of the guide surface 27A of the guide portion 27 at a portion that is in the same position as the cutout 29 in the front-rear direction. The notch 30 communicates with the notch 29 and communicates the inside and outside of the guide portion 27.

  On the upper surface of the upper wall 20A, a pair of guide rails 31 is provided in a region on the left side of the first vertical wall 24 (hereinafter referred to as “substantially left half region”). Each guide rail 31 extends in the width direction so as to extend over substantially the entire region of the substantially left half region (the entire region in the width direction). The pair of guide rails 31 extend in parallel in the front-rear direction at an interval. Of the pair of guide rails 31, the front guide rail 31A is opposed to the front end portion of the upper surface of the upper wall 20A with a gap corresponding to the thickness of one premium. Of the pair of guide rails 31, the rear guide rail 31B is opposed to the rear end portion of the upper surface of the upper wall 20A with a gap corresponding to the thickness of one premium. In the prize reader 1, a space from the upper surface of the upper wall 20 </ b> A in the substantially left half region to the pair of guide rails 31 is referred to as a conveyance path 32. The conveyance path 32 is a belt-like space that extends substantially horizontally in the width direction with the same thickness as that of one prize. Further, a surface that divides the conveyance path 32 from the bottom (that is, the upper surface of the upper wall 20A) is referred to as a conveyance surface 32A. The transport surface 32A is flat along the horizontal direction and extends in the width direction.

  The conveyance path 32 communicates with the set unit 28 through the gap 25 described above, and extends leftward from the set unit 28 in a horizontal state. The conveyance path 32 can convey the prize set in the setting unit 28 to the left side while being placed on the conveyance surface 32 </ b> A while maintaining the same posture as when set in the setting unit 28. In the prize that is being conveyed on the conveyance path 32, the guide rail 31 is positioned right above the front and rear ends, so that the prize is conveyed on the conveyance path 32 without being lifted. A guide surface 31C extending to the upper right side is formed at the right end portion of the lower end surface of each guide rail 31 so that the prize of the set portion 28 is smoothly transferred to the conveyance path 32 without being caught by each guide rail 31. Has been.

Further, in the upper wall 20A in the substantially left half region, a notch 33 is formed in a region located between the pair of guide rails 31 in a plan view, by notching the upper wall 20A in the thickness direction (vertical direction). ing. The above-described identification unit 6 is assembled below the upper wall 20 </ b> A and exposed from the notch 33 into the conveyance path 32.
The rotating shaft 21 is a shaft-like body extending in the front-rear direction, and four rotating shafts are provided in total. These rotating shafts 21 are rotatably supported by the frame 20 in a state of being discretely arranged in a front view. Hereinafter, each of the four rotation shafts 21 may be distinguished as a rotation shaft 21A, a rotation shaft 21B, a rotation shaft 21C, and a rotation shaft 21D. The rotation shaft 21 </ b> A is disposed at the upper left corner of the frame 20. The rear end portion of the rotation shaft 21 </ b> A protrudes rearward from the rear wall 20 </ b> D of the frame 20. The rotation shaft 21 </ b> B is disposed at a position slightly on the right side from the lower left corner of the frame 20. The rotation shaft 21 </ b> C is disposed at a position slightly above the lower right corner of the frame 20. The rotation shaft 21 </ b> D is disposed at the upper right corner of the frame 20. In each rotary shaft 21, a pulley 34 is attached at the same position as the notch 29 of the set portion 28 in the front-rear direction so as to be integrally rotatable. The pulley 34 is a ring that is externally fitted to the rotary shaft 21, and flanges 34 </ b> A that project outward in the radial direction over the entire circumferential direction are integrally provided at both axial ends of the pulley 34. (Refer to the pulley 34 of the rotating shafts 21A and 21C).

  Referring also to FIG. 4, the belt 22 is an endless annular belt (so-called endless belt), and is formed of an elastic body such as rubber. The cross section of the belt 22 when cut along a flat surface orthogonal to the circumferential direction R has an elongated rectangular shape along the front-rear direction of the prize reader 1. A plurality (here, seven) of protrusions 35 are provided along the circumferential direction R at a constant interval on the outer peripheral surface 22 </ b> A of the belt 22. Each protrusion 35 has a substantially rectangular parallelepiped block shape that is elongated along the longitudinal direction of the cross section of the belt 22 (the front-rear direction of the prize reader 1), and is integrally formed with the belt 22. The longitudinal dimension L of each protrusion 35 is substantially the same as the longitudinal dimension of the cross section of the belt 22. The protrusion amount S of each protrusion 35 from the outer peripheral surface 22A of the belt 22 is substantially the same as the thickness T of one premium (denoted by reference numeral 40 in FIG. 4). Further, the interval P between the two protrusions 35 adjacent to each other in the circumferential direction R on the belt 22 is larger than a single dimension (longitudinal dimension Q) of the prize 40 by a predetermined amount or more (about several mm).

  As shown in FIG. 3, such a belt 22 is wound around the pulleys 34 of the four rotary shafts 21 in a state where a predetermined tension is applied. The belt 22 in this state is disposed in the frame 20. A portion of the belt 22 that is hooked on each pulley 34 has a bend C. In FIG. 3, the bending angle C of the belt 22 on the rotation shafts 21A and 21B is shown.

  The belt 22 bends along the outer peripheral surface of the pulley 34 at a turning angle C on the rotating shaft 21A, and then extends to the lower right side and hangs on the pulley 34 of the rotating shaft 21B. The belt 22 bends along the outer peripheral surface of the pulley 34 at a turning angle C in the rotating shaft 21B, and then extends to the upper right side and hangs on the pulley 34 of the rotating shaft 21C. The belt 22 bends along the outer peripheral surface of the pulley 34 at a turning angle C (not shown) on the rotating shaft 21C, and then extends substantially vertically upward and is hooked on the pulley 34 of the rotating shaft 21D. The belt 22 bends along the outer peripheral surface of the pulley 34 at a turning angle C (not shown) in the rotation shaft 21D, and then extends to the left side along the horizontal and hangs on the pulley 34 of the rotation shaft 21A.

  Here, the bending angle C of the belt 22 on the rotating shaft 21A is disposed adjacent to the storage unit 8 (specifically, the storage 71) from the right side. Further, the belt 22 is exposed from the notch 29 of the set portion 28 in the feeding portion 11 in the substantially right half region (the region on the right side of the first vertical wall 24) of the upper wall 20A of the frame 20, and the upper wall 20A. Is disposed at the front end of the conveyance path 32 in the substantially left half region. The belt 22 wound around the pulleys 34 of the four rotary shafts 21 is provided so as to go around the feeding unit 11, the conveyance path 32, and the storage unit 8 (storage 71).

Further, the belt 22 is positioned in the front-rear direction by being disposed between the pair of flanges 34 </ b> A in the pulley 34 of each rotating shaft 21. Therefore, the belt 22 is in the same position in the front-rear direction as the notch 29 of the set portion 28 in any part in the circumferential direction R.
Note that when any two protrusions 35 adjacent to each other in the circumferential direction R of the belt 22 are in a position that sandwiches the set portion 28 from the left and right directions, the belt 22 that is stationary in this state is in a standby position. A sensor 37 that detects whether or not the belt 22 is in a standby state is provided on the right wall 20C of the frame 20. Of the two projections 35 described above, there is a projection 35 located on the right side of the set portion 28 (strictly speaking, the notch 30 of the guide portion 27), and with respect to this projection 35 (from the upstream side in the forward rotation direction described later) ) There is another adjacent protrusion 35, but if the other protrusion 35 is always located in the detection range of the sensor 37, the sensor 37 detects that the belt 22 is in a standby state.

  The drive motor 23 is fixed to the rear wall 20 </ b> D within the frame 20. A timing belt 36 is wound around the output shaft (not shown) of the drive motor 23 and the rear end portion of the rotating shaft 21A. When the drive motor 23 is driven by receiving electric power, the driving force of the drive motor 23 is transmitted to the rotating shaft 21A via the timing belt 36, and the rotating shaft 21A rotates around the axis. As a result, the belt 22 rotates in a state of being wound around the pulleys 34 of the four rotary shafts 21. In FIG. 3, the counterclockwise direction when viewed from the front is the forward rotation direction of the belt 22 (a normal circumferential movement direction), and the clockwise direction is the reverse rotation direction of the belt 22. Since the belt 22 is in the same position in the front-rear direction as the notch 29 in any part in the circumferential direction R as described above, some part in the circumferential direction R moves forward and backward when moving around. There is no blur. The drive of the drive motor 23 (in other words, the circular movement of the belt 22) is controlled by the control unit 15 (see FIG. 2). Specifically, the drive motor 23 is a stepping motor, and when the clerk sets the prize 40 received from the player in the setting unit 28 and then presses the start switch 9 (see FIG. 1), the control unit 15 By controlling the step angle and the like of the drive motor 23, the circular movement of the belt 22 is started.

  When the belt 22 rotates in the forward rotation direction, each protrusion 35 on the outer peripheral surface 22A of the belt 22 moves in the forward rotation direction. At this time, the protrusions 35 are formed on the upper wall 20A of the frame 20 (that is, in the region between the rotating shaft 21A and the rotating shaft 21D) by the notch 29 of the set portion 28 and the front end portion of the conveying path 32. In this order, it passes to the left along the horizontal direction. Therefore, among the prizes 40 (see FIG. 4) set in a stacked state on the set part 28 of the feeding part 11, the lowermost prize 40 is hooked by the projection 35 coming from the right side at the front end of the right edge. And moved to the left. Thereby, the prize 40 is sandwiched between the protrusion 35 hooked on the right edge and another protrusion 35 adjacent to the protrusion 35 from the downstream side (in the forward rotation direction of the belt 22). Then, it is fed out from the feeding unit 11. That is, the belt 22 having such a projection 35 constitutes a feeding means for feeding out the prize 40 set in the set portion 28 of the feeding portion 11 by the projection 35. Note that the drive motor 23 and the control unit 15 that move the belt 22 around may be regarded as a part of the feeding unit.

  As described above, the prize 40 fed from the feeding section 11 passes through the gap 25 below the first vertical wall 24 as the belt 22 rotates, and is conveyed along the horizontal direction (conveying surface 32A). Is transported to the left. Then, when the prize 40 reaches the rotating shaft 21A (the bending angle C of the belt 22 on the rotating shaft 21A), it has passed through the conveyance path 32 and is pushed out to the left by the protrusion 35 that has been hooked up to now. It is thrown into the storage 71 of the storage unit 8 on the left side. In this way, the prizes 40 set in the stacked state in the setting unit 28 are fed out one by one from the lowest prize 40, pass through the transport path 32, and thrown into the storage unit 8 (storage 71). It is done. In other words, the belt 22 that moves in a revolving manner throws the prize 40 into the storage 71 at the corner C, thereby reliably delivering the prize 40 to the storage 71 disposed adjacent to the corner C. be able to.

  As described above, the belt 22 moves in a circular motion, so that the prize 40 of the feeding unit 11 is hooked by the protrusion 35 and fed out, and is transported to the storage unit 8 (storage 71) via the transport path 32. Therefore, in the prize reader 1, the prize 40 is fed out in the feeding unit 11, the fed prize 40 is transported in the transport path 32, and the prize 40 that has passed through the transport path 32 is stored in the storage 71. This can be achieved only by the same (one) belt 22 moving around. Therefore, since this belt 22 and the common drive motor 23 (see FIG. 3) for rotating the belt 22 are only required for feeding, transporting and storing, the cost and size can be reduced accordingly. Can do.

  Further, when the prize 40 is fed out, transported and stored by the same belt 22 as described above, the prize 40 is provided between the feeding section 11 and the transport path 32 or between the transport path 32 and the storage 71. Can be delivered smoothly. In addition, the joint between the feeding unit 11 and the transport path 32 and the joint between the transport path 32 and the storage 71 can be eliminated (narrowed) as much as possible. Therefore, it is possible to suppress the occurrence of jam (clogging of the prize 40) at the joint, and it is possible to improve the quality related to the storage of the prize 40.

  Further, as described above, the interval P between the adjacent protrusions 35 on the belt 22 is larger than a single dimension (longitudinal dimension Q) of the prize 40 by a predetermined amount or more (see FIG. 4). Therefore, since any prize 40 set in the setting section 28 can be surely and sequentially entered between the adjacent projections 35, the belt 22 can continuously feed out, convey and store a plurality of prizes 40. . Therefore, it is possible to further improve the quality related to the payout and storage of the prize 40.

As described above, the prize 40 fed out from the feeding unit 11 is identified by the identifying unit 6 while being transported along the transport path 32.
FIG. 5 is a schematic diagram showing the configuration of the prize 40. Next, the prize 40 will be described in detail with reference to FIG. The prize 40 mainly includes a main body 41, a valuable material 42, an IC tag 43, and a hologram 44.

  The main body 41 is a resin card having a substantially rectangular shape and forms an outline of the prize 40. The outer surface on one side in the thickness direction of the main body 41 is the front surface 40A of the prize 40, and the outer surface on the other side is the back surface 40B of the prize 40 (see FIG. 4). In this embodiment, the color of the outer surface of the main body 41 (that is, the outer surface of the prize 40) is different for each denomination of the prize 40. Specifically, the outer color of the prize 40 is green for a denomination of 200 yen, blue for a denomination of 1000 yen, yellow for a denomination of 2000 yen, and red for a denomination of 5000 yen. is there. Therefore, the denomination of the prize can be distinguished visually by the color of the outer surface of the prize 40.

The valuable material 42 is, for example, a noble metal (gold or silver) chip and is embedded in the main body 41 so as to be visible from the outer surface of the prize 40. Incidentally, the prize 40 has a structure capable of preventing an unauthorized attempt to take out the valuable material 42 from the main body 41 (details will be described later).
The IC tag 43 stores information on the denomination of the prize 40, identification information assigned to each prize 40 (game facility store code and serial number), and the like. The IC tag 43 is embedded in the main body 41.

  The hologram 44 is a color variable hologram whose color changes depending on how it is viewed (viewing angle). The hologram 44 has, for example, a square seal shape and is attached to the surface 40A of the prize 40. As shown in FIG. 4, for example, on the surface 40 </ b> A of the substantially rectangular main body 41, the hologram 44 is arranged at the center in the short direction, but is arranged at one end or the other end in the longitudinal direction. ing. Since the hologram 44 is arranged at the center in the short direction of the surface 40A, the hologram 44 is moved from the belt 22 in the front-rear direction regardless of the direction in which the prize 40 is set on the setting unit 28 (see FIG. 3). It is shifted to. Therefore, when the prize 40 is identified by the identification unit 6, the hologram 44 of the prize 40 is not hidden behind the belt 22.

  In the prize reader 1, the hologram 44 is attached to the prize 40 at a position visible from the outside (that is, the real hologram 44 can be read from the prize 40), and denomination information can be read from the IC tag 43. Then, it is determined that the prize 40 is genuine (normal). On the other hand, in the prize reader 1, the prize 40 that could not read the hologram 44 and the prize 40 that could not read the denomination information from the IC tag 43 are determined to be fake.

FIG. 6 is a schematic diagram illustrating how the identification unit 6 identifies the prize 40 in the prize reader 1. FIG. 7 is a perspective view of the reading unit 52 in the identification unit 6. FIG. 8 is a perspective view of the internal structure of the reading unit 52.
Next, the identification unit 6 will be described in detail with reference to FIGS.
In FIG. 6, the lowest prize 40 set in the setting section 28 of the feeding section 11 (that is, the prize 40 about to enter the conveyance path 32 from now on) is illustrated. In FIG. 6, a thick black arrow extending horizontally toward the left side indicates the conveyance direction X of the prize 40 on the conveyance path 32. The conveyance direction X and the longitudinal direction of the prize 40 are the same.

The identification unit 6 includes an upper identification block 50 disposed above the conveyance path 32 and a lower identification block 51 disposed below the conveyance path 32. As described above, the portion of the identification unit 6 exposed from the notch 33 of the upper wall 20A into the conveyance path 32 is the lower identification block 51 (see FIG. 3).
Each of the upper identification block 50 and the lower identification block 51 includes one reading unit 52 that reads the hologram 44 from the prize 40 fed from the feeding unit 11. Therefore, when viewed as a whole of the upper identification block 50 and the lower identification block 51, the reading unit 52 is located on both sides in the vertical direction that intersects (strictly, orthogonally) the conveyance direction X described above with respect to the conveyance path 32. A pair is provided so as to be arranged. Further, in this embodiment, the pair of reading units 52 are arranged at the same position (position of the same phase) in the conveyance direction X, and are opposed to each other with the conveyance path 32 interposed therebetween. If the pair of reading units 52 are arranged to face each other in this way, the prize 40 having the hologram 44 provided only on either the front or back (here, the front surface 40A) is conveyed in a state in which the front and back directions are unknown. Even if it comes, either of the pair of reading units 52 located on both sides of the prize 40 can always read the hologram 44 from the prize 40.

Each reading unit 52 includes a casing 53, an LED light emitting unit 54 as light projecting means, and a plurality (two in this case) of color sensors 55.
The casing 53 has a box shape and accommodates the LED light emitting unit 54 and the color sensor 55 (see also FIG. 7). An opening 53 </ b> A that exposes the LED light emitting unit 54 and the color sensor 55 to the conveyance path 32 side is formed on the surface of the casing 53 that faces the conveyance path 32 (the upper surface in FIG. 7).

  The LED light emitting unit 54 emits light (for example, white) from the opening 53A of the casing 53 toward the upstream side (right side) in the transport direction X in a direction inclined with respect to the transport surface 32A (horizontal direction) (see a thin solid arrow). It is a light-emitting component that projects light. Here, unlike paper such as banknotes, the prize 40 has a certain thickness, so that the light from the LED light emitting part 54 in each of the pair of reading parts 52 does not pass through the prize 40. Therefore, even if the pair of reading units 52 are arranged so as to sandwich the conveyance path 32 at the same position in the conveyance direction X of the prize 40 on the conveyance path 32 as described above, the reading of the hologram 44 from the prize 40 is performed. Do not disturb each other.

  The color sensor 55 is a sensor that reads the color of the outer surface by receiving reflected light on the outer surface of the projected object. As an example of the layout, in each reading unit 52, the two color sensors 55 are arranged on the upstream side (right side) of the LED light emitting unit 54 in the transport direction X. The two color sensors 55 in each reading unit 52 are distinguished into a color sensor 55A and a color sensor 55B. The color sensor 55A faces the conveyance surface 32A (conveyance path 32) along the vertical direction (from the top in the case of the upper identification block 50 and from directly below in the case of the lower identification block 51). On the other hand, the color sensor 55B has the conveyance surface 32A (conveyance path 32) from the upstream side in the conveyance direction X along the direction inclined with respect to the conveyance surface 32A (in the case of the upper identification block 50, from the upper right side, In the case of the lower identification block 51, it faces (from the lower right side). Specifically, in each reading unit 52, a surface (light receiving surface 58) that receives reflected light from an object (detection target) in the color sensor 55A and a light receiving surface 58 of the color sensor 55B are orthogonal to each other in a front view. Has been placed. The layout of the color sensors 55 and the LED light emitting units 54 in the reading units 52 described above is merely an example, and another configuration (for example, two color sensors 55 in the reading unit 52 of the lower identification block 51). May be arranged on the downstream side of the LED light emitting portion 54).

In each reading unit 52, the LED light emitting unit 54 and the two color sensors 55 are connected to a substrate 56 accommodated in the casing 53 (see FIG. 8).
In the lower identification block 51, an IC reader / writer 57 is provided on the left side of the reading unit 52 (downstream in the transport direction X). The IC reader / writer 57 can read information stored in the IC tag 43 by wirelessly communicating with the IC tag 43 of the prize 40.

  The left end portion of the prize 40 that has been fed out from the feeding section 11 and entered the conveyance path 32 (one end portion in the longitudinal direction of the prize 40 and also the downstream end portion in the conveyance direction X) is read in the conveyance direction X. When the position reaches the same position as the section 52 (strictly speaking, the position where the light from the LED light emitting section 54 strikes), the control section 15 (see FIG. 2) temporarily stops the circumferential movement of the belt 22. Thereby, the prize 40 stops. The position of the prize 40 in the transport direction X at this time is referred to as a first stop position. Since the protrusions 35 of the belt 22 are located on both sides of the prize 40 in the transport direction X so as to sandwich the prize 40, the prize 40 may go too far according to the temporary stop of the circular movement of the belt 22. Instead, stop immediately at the first stop position.

When the delivered prize 40 stops at the first stop position, light is emitted from the LED light emitting portion 54 of the upper identification block 50 to the upper surface (one of the front surface 40A and the rear surface 40B) of the premium 40, and the LED of the lower identification block 51 Light is emitted from the light emitting unit 54 to the lower surface (the other of the front surface 40A and the back surface 40B) of the prize 40.
The light projected on the upper surface of the prize 40 becomes reflected light that is reflected upward on the upper surface, and is received by the respective light receiving surfaces 58 of the two color sensors 55 of the upper identification block 50. The direction of the reflected light here differs between the reflected light received by the color sensor 55A (one-dot chain arrow) and the reflected light received by the color sensor 55B (two-dot chain arrow). That is, the two color sensors 55 of the upper identification block 50 read the color of the upper surface of the prize 40 projected by the LED light emitting unit 54 from different angles.

  The light projected on the lower surface of the prize 40 becomes reflected light reflected downward on the lower surface, and is received by the respective light receiving surfaces 58 of the two color sensors 55 of the lower identification block 51. The direction of the reflected light here differs between the reflected light received by the color sensor 55A (one-dot chain arrow) and the reflected light received by the color sensor 55B (two-dot chain arrow). That is, the two color sensors 55 of the lower identification block 51 read the color of the lower surface of the prize 40 projected by the LED light emitting unit 54 from different angles.

  Here, if the hologram 44 is positioned at the left end portion of the prize 40, the light projected by the LED light emitting unit 54 in either the upper identification block 50 or the lower identification block 51 is reflected by the hologram 44. Then, the two color sensors 55 in any one of the upper identification block 50 and the lower identification block 51 read the color of the hologram 44 in the prize 40 projected by the LED light emitting unit 54 from different angles. However, in the case of FIG. 6, the hologram 44 is located not at the left end portion of the prize 40 but at the right end portion (the other end portion in the longitudinal direction of the prize 40 and also the upstream end portion in the transport direction X). Yes. Therefore, neither reading unit 52 of the upper identification block 50 and the lower identification block 51 can read the hologram 44 from the prize 40 at the first stop position.

  When the hologram 44 cannot be read from the prize 40 at the first stop position, the control unit 15 resumes the circular movement of the belt 22. When the right end portion of the prize 40 reaches the same position as the reading unit 52 in the transport direction X (a position where light from the LED light emitting unit 54 hits), the control unit 15 temporarily stops the circular movement of the belt 22 again. . Thereby, the prize 40 stops at a position slightly shifted to the downstream side in the transport direction X from the first stop position. The position of the prize 40 in the transport direction X at this time is referred to as a second stop position. Also at this time, thanks to the protrusions 35 (of the belt 22) located on both sides in the transport direction X of the prize 40, the prize 40 stops immediately at the second stop position without going too far. Even when the hologram 44 can be read from the prize 40 at the first stop position, the hologram 44 may be read by stopping the prize 40 at the second stop position.

When the prize 40 stops at the second stop position, light is again projected from the LED light emitting portion 54 of the upper identification block 50 to the upper surface of the prize 40, and light is projected again from the LED light emitting portion 54 of the lower identification block 51 to the lower surface of the prize 40. Is done.
The light projected on the upper surface of the prize 40 becomes reflected light that is reflected upward on the upper surface, and is received by each of the two color sensors 55 of the upper identification block 50, and the two color sensors 55 are LED light emitting units. The color of the upper surface of the prize 40 projected by 54 is read from different angles.

The light projected on the lower surface of the prize 40 becomes reflected light that is reflected downward on the lower surface, and is received by each of the two color sensors 55 of the lower identification block 51, and the two color sensors 55 emit LED light. The color of the lower surface of the prize 40 projected by the unit 54 is read from different angles.
In the case of FIG. 6, the upper surface of the prize 40 is the surface 40A, and the hologram 44 is located at the right end of the surface 40A. Therefore, the reading unit 52 of the upper identification block 50 located on the upper surface side of the prize 40 The hologram 44 can be read from the prize 40 at the stop position. At this time, the two color sensors 55 of the upper identification block 50 read the color of the hologram 44 from different angles.

  As described above, the color of the hologram 44 changes depending on how it is viewed. Therefore, when the two color sensors 55 of the upper identification block 50 read the color of the hologram 44 from different angles as in this case, for example, the color sensor 55A reads red from the hologram 44, whereas the color sensor 55B reads the hologram. Read green from 44. The color read from the hologram 44 by each color sensor 55 is transmitted to the control unit 15. The control unit 15 determines the color difference of the hologram 44 read by each of the two color sensors 55 of the identification unit 6 (the upper identification block 50 or the lower identification block 51) (strictly speaking, the color in the reflected light from the hologram 44). The authenticity of the hologram 44 in the prize 40 on the transport path 32 (in other words, the authenticity of the prize 40 itself) is discriminated (that is, identified) from the RGB data). Specifically, in the upper identification block 50 or the lower identification block 51, if the color sensor 55A reads red from the hologram 44 while the color sensor 55B reads green from the hologram 44, the reading unit 52 indicates that the real hologram 44 can be read from the prize 40, and the control unit 15 determines that the hologram 44 is genuine. Conversely, the color sensor 55A and the color sensor 55B read the same color from the hologram 44, the color sensor 55A reads a color other than red from the hologram 44, and the color sensor 55B reads a color other than green from the hologram 44. When the reading is performed, the reading unit 52 cannot read the real hologram 44 from the prize 40, and the control unit 15 determines that the hologram 44 is a fake.

  In the case of FIG. 6, since only the reading unit 52 of the upper identification block 50 can read the hologram 44 from the prize 40, the control unit 15 not only determines the authenticity of the hologram 44 (prize 40) but also the prize. The direction of 40 front and back sides can also be grasped. That is, the control unit 15 depends on which of the pair of upper and lower reading units 52 (the reading unit 52 of the upper identification block 50 and the reading unit 52 of the lower identification block 51) has read the hologram 44 from the prize 40 on the conveyance path 32. Can discriminate the front and back of the prize 40. Therefore, if the prize reader 1 is provided with a mechanism for reversing the front and back of the prize 40, the prize 40 that has been identified can be stored in the storage 71 with the front and back aligned.

  As described above, when any reading unit 52 can read the hologram 44 from the prize 40 at the second stop position, the control unit 15 resumes the circular movement of the belt 22. Then, when the IC tag 43 of the prize 40 reaches almost the same position as the IC reader / writer 57 of the lower identification block 51 in the transport direction X, the control unit 15 temporarily stops the circumferential movement of the belt 22 again. As a result, the prize 40 stops at a position slightly shifted downstream in the transport direction X from the second stop position. The position of the prize 40 in the transport direction X at this time is referred to as a third stop position. Also at this time, thanks to the protrusions 35 (of the belt 22) located on both sides in the transport direction X of the prize 40, the prize 40 stops immediately at the third stop position without going too far.

When either reading unit 52 can read the hologram 44 from the prize 40 at the first stop position, the control unit 15 resumes the circular movement of the belt 22 and then stops the prize 40 for the second stop. The belt 22 continues to move around without stopping at the position, and when the prize 40 reaches the third stop position, the belt 22 turns around temporarily.
The IC reader / writer 57 can read information stored on the IC tag 43 of the prize 40 stopped at the third stop position (in particular, information on the denomination of the prize 40). Since this information is sent to the control unit 15 (see FIG. 2), the control unit 15 determines the denomination of the prize 40 based on this information.

  Then, the control unit 15 determines that the hologram 44 of the prize 40 is genuine at the first stop position or the second stop position as described above, and the IC reader / writer 57 uses the IC tag of the prize 40 at the third stop position. Only when the denomination of the prize 40 is determined based on the information read from 43, the prize 40 is determined to be genuine (normal prize). On the other hand, for a prize 40 in which the hologram 44 cannot be determined to be genuine or a denomination cannot be determined, the control unit 15 determines that the prize 40 is a fake (reject prize). Incidentally, if the hologram 44 of the prize 40 cannot be determined to be genuine at the first stop position or the second stop position, the control unit 15 may determine that the prize 40 is fake regardless of the denomination. . In any case, the control unit 15 automatically determines (automatic identification) the authenticity of the prize 40 depending on whether any of the upper and lower reading units 52 has read the real hologram 44 from the prize 40 on the transport path 32. . Therefore, the prize reader 1 can improve the security of the prize 40 by using the hologram 44. In particular, since the hologram 44 is a color variable hologram, the colors of the holograms 44 read by the color sensors 55 are different from each other. Therefore, the control unit 15 determines the color of the hologram 44 read by each of the plurality of color sensors 55. From the difference, the authenticity of the prize 40 can be accurately determined.

The control unit 15 can count each of the normal prize 40 and the reject prize 40 by determining the authenticity of the prize 40 one by one. Furthermore, the control unit 15 can also count the normal prize 40 for each denomination.
In addition, since the prize 40 that is fed out and transported stops at the first to third stop positions as described above, the control unit 15 allows the belt 40 when the prize 40 is being fed and / or being conveyed. The circular movement of 22 is stopped. In this way, if the circumferential movement of the belt 22 is temporarily stopped and the control unit 15 identifies the prize 40 in a stationary state (not moving) by the identification unit 6, the identification accuracy of the prize 40 is improved. You can also.

  Here, the control unit 15 may not only stop the circulation movement of the belt 22 but also reverse the rotation direction of the belt 22 as necessary. In addition, the control unit 15 stops the circular movement of the belt 22 or the belt 22 when a defective feeding of the prize 40 in the feeding unit 11 and / or a defective identification of the prize 40 by the control unit 15 (identification unit 6) occurs. The rotating direction of 22 may be reversed. Thereby, for example, when a feeding failure (such as a jam of the prize 40 at the joint between the setting unit 28 and the conveyance path 32) occurs, the circular movement of the belt 22 is stopped to take out the prize 40 in the middle of conveyance, and the feeding unit 11 Can be reset to On the other hand, when an identification failure occurs (the identification unit 6 cannot read necessary information from the prize 40), by reversing the rotation direction of the belt 22, the protrusion 35 that transports the previous prize 40, The prize 40 having the identification failure can be returned to the identification area (any one of the first to third stop positions) of the control unit 15 and re-identified. Therefore, usability can be improved when a problem occurs.

  When the authenticity determination (determination of denomination) of the prize 40 at the third stop position is completed as described above, the control unit 15 resumes the circular movement of the belt 22. As a result, as described above, when the prize 40 that has received the true / false determination reaches the bend angle C of the belt 22 on the rotation shaft 21A, the protrusion 35 of the belt 22 (the protrusion 35 hooked on the prize 40 from the upstream side). Is thrown into the storage 71 of the storage unit 8 on the left side.

In the above description, there is only one type of hologram 44, and regardless of the denomination 40, the color sensor 55A reads red from the hologram 44, and the color sensor 55B reads green from the hologram 44. In this case, the hologram 44 is determined to be genuine. On the other hand, a plurality of types of holograms 44 may exist depending on the denomination of the prize 40.
For example, as shown in the table 60 of FIG. 9, the color sensor 55A (simply referred to as “color sensor A” in FIG. 9; the same applies to FIG. 10) reads red, and the color sensor 55B (in FIG. 9, simply The gift 40 with the hologram 44 from which the green color can be read by “color sensor B” (same as in FIG. 10) may be used as a gift 40 of a denomination of 5000 yen. Further, the prize 40 with the hologram 44 whose yellow is read by the color sensor 55A and blue is read by the color sensor 55B may be a 2000 yen denomination prize 40. Further, the prize 40 with the hologram 44 whose color is read by the color sensor 55A and blue is read by the color sensor 55B may be a prize 40 of 1000 yen denomination. Alternatively, the prize 40 with the hologram 44 that is read by the color sensor 55A and is read by the color sensor 55B may be used as a prize 40 of a denomination of 200 yen.

  In this way, what color the color sensor 55A reads and what color the color sensor 55B reads in the hologram 44 of which denomination of prize 40 is summarized in the table 60. This table 60 is stored in the storage unit 16 ( (See FIG. 2). Based on the color read by the color sensor 55A from the hologram 44 of the prize 40 and the color read by the color sensor 55B, the control unit 15 determines the authenticity and denomination of the prize 40 from the table 60. . For example, in the case of the table 60 in FIG. 9, if the color sensor 55A reads red from the hologram 44 of the prize 40 and the color sensor 55B reads green, the control unit 15 determines the prize. 40 is determined to be a genuine prize 40 (normal prize 40) for a denomination of 5000 yen. Thus, if the control unit 15 determines the denomination of the prize 40 based on the reading result of the hologram 44 by the color sensor 55 of the reading unit 52, the denomination of the prize 40 can be determined without the IC tag 43. In other words, the prize reader 1 can determine not only the authenticity of the prize 40 but also the denomination of the prize 40 by using a plurality of holograms 44 provided according to the denomination of the prize 40.

  In addition, as described above, the color of the outer surface of the prize 40 (portion other than the hologram 44) is different for each denomination (200 yen denomination: green, 1000 yen denomination: blue, 2000 yen denomination). : Yellow, 5000 yen denomination: Red). In each of the upper identification block 50 and the lower identification block 51, the colors that the color sensor 55A and the color sensor 55B read from the outer surface of the prize 40 are collected in a table 61 for each denomination as shown in FIG. The table 61 is stored in the storage unit 16 (see FIG. 2). When the color sensor 55A and the color sensor 55B read the same color from the outer surface of the prize 40, the control unit 15 can determine the denomination of the prize 40 from the color by referring to the table 61. For example, in the case of FIG. 10, if both the color sensor 55A and the color sensor 55B read red from the outer surface of the prize 40, the control unit 15 determines that the prize 40 has a denomination of 5000 yen. It is determined that the gift 40 is. The authenticity of the prize 40 is determined by the color read by the color sensor 55A and the color sensor 55B from one type of hologram 44 (common regardless of the denomination of the prize 40) as described above.

However, in the prize 40, either the front surface 40A or the back surface 40B may be a single color and the other may have a pattern or the like. In that case, based on the position of the hologram 44, one of the front surface 40A and the back surface 40B (a single color outer surface) is grasped in advance, and then the gold of the prize 40 is determined by the color read from the one. It is good to distinguish the species.
In the identification unit 6 described above, the number of color sensors 55 constituting each reading unit 52 is not limited to two, and may be three or more. In this case, each color sensor 55 Read the color of the hologram 44 at different angles. Then, the hologram 44 can be identified with higher accuracy.

Further, instead of the configuration of reading information from the IC tag 43 provided on the prize 40, a configuration in which a barcode (not shown) provided on the prize 40 is read by the identification unit 6 (in this case, provided with a barcode reader). Can be used. Of course, the IC tag 43 and the barcode may be used in combination.
In addition, the identification unit 6 described above is not limited to the present prize reader 1, but a device for identifying a medium in which a discrimination unit such as an IC tag 43 or a hologram 44 is incorporated (the prize 40 is given to the player at the game facility). The present invention can also be applied to a gift dispenser that pays out. For example, if the present prize reader 1 is provided with a function of paying out the prize 40 from the storage unit 8, the prize reader 1 can also be a prize dispenser.

Next, the storage unit 8 that is the storage destination of the prize 40 that has been identified by the identification unit 6 will be described in detail.
FIG. 11 is a perspective view showing the storage unit 8 extracted from the prize reader 1, and shows a state where the stage 76 is in the reject prize extraction position. FIG. 12 shows a state in which the stage 76 is in the normal prize accumulation position. The postures of FIGS. 11 and 12 are the same as the posture of the prize reader 1 of FIG.

The storage portion 8 shown in FIG. 11 is shown in a state where the outer decorative cover 70 in FIG. 1 is removed. The storage unit 8 mainly includes the storage 71 described above and a drive motor 72 (interval adjustment means, switching means).
The storage 71 stores the prize 40 that has passed through the conveyance path 32, and only one is provided in one prize reader 1. Therefore, the prize reader 1 can be reduced in size.

The storage 71 is a vertically long hollow body, and includes a left wall 73, a right wall 74, a rear wall 75, and a stage 76.
The left wall 73 and the right wall 74 are both rectangular plates that are thin in the left-right direction and long in the up-down direction, and are opposed to each other with an interval left and right. The right wall 74 is a portion adjacent to the transport unit 5 from the left side in the storage 71, and a through hole 74A is formed at a position on the right wall 74 that coincides with the transport path 32 in the vertical direction. The through hole 74 </ b> A has a size that allows the prize 40 that has passed through the transport path 32 to pass through with sufficient margin, and is positioned at the substantially vertical center of the right wall 47. The rear wall 75 is a rectangular plate shape that is thin in the front-rear direction and long in the vertical direction, and extends between the rear end edges of the left wall 73 and the right wall 74. On the right side of the rear wall 75, a guide groove 75 </ b> A is formed that extends vertically over substantially the entire area of the rear wall 75 in the vertical direction. The guide groove 75A penetrates the rear wall 75 in the thickness direction (front-rear direction). A vertically long rectangular parallelepiped space surrounded by the left wall 73, the right wall 74, and the rear wall 75 is an internal space 77 of the storage 71. The internal space 77 is opened (exposed) forward (from the front of the prize reader 1) from between the front edge of the right wall 74 and the front edge of the rear wall 75. Further, the internal space 77 communicates with the transport path 32 through a through hole 74A in the right wall 74 (see FIG. 6).

  The stage 76 has a thin plate shape in the vertical direction, and has a substantially rectangular shape that fits in the internal space 77 in plan view. A plurality (two in this case) of stages 76 are provided. These stages 76 are accommodated in the internal space 77 in a state of being spaced apart vertically. Of the two stages 76, the lower stage 76 is referred to as a lower stage 76A, and the upper stage 76 is referred to as an upper stage 76B. The internal space 77 (strictly speaking, the region above the upper stage 76B) is divided into two upper and lower storage areas 79 by the lower stage 76A and the upper stage 76B. Specifically, of the two storage areas 79, one is the lower storage area 79A (relatively located on the lower side) between the lower stage 76A and the upper stage 76B, and the other is the upper side. This is an upper storage area 79B located above the stage 76B (lower storage area 79A). Since the transport direction X of the prize 40 in the transport path 32 is the horizontal direction as described above (see FIG. 6), the upper and lower two storage areas 79 are intersecting the transport direction X (strictly, the orthogonal direction). The internal space 77 is divided by a stage 76 in the up-down direction, and is arranged adjacent to each other in the up-down direction. Therefore, the prize reader 1 in the transport direction X can be reduced in size compared to the case where the storage areas 79 are arranged side by side in the transport direction X (width direction). Further, since two storage areas 79 and two stages 76 are provided, it can be seen that the same number of storage areas 79 and stages 76 are provided.

  Further, an insertion portion 78 that is inserted into the guide groove 75A is provided at the right end portion of the rear end edge of each stage 76. Here, in the prize reader 1, the drive motor 72 and the conversion mechanism 80 (spacing adjustment unit, switching unit) described above are provided on the rear surface of the rear wall 75. The drive motor 72 generates rotational force by being driven by receiving electric power. The conversion mechanism 80 includes a belt 81 that circulates along a circular locus that extends vertically. The belt 81 is connected to the output shaft of the drive motor 72 and receives a rotational force of the drive motor 72 to move around. An insertion portion 78 of each stage 76 is connected to the belt 81. Therefore, according to the circular movement of the belt 81, both the stages 76 are raised or lowered in a state where the vertical distance between the adjacent stages 76 is maintained (that is, in an integrated state). That is, the conversion mechanism 80 is a mechanism that converts the rotation generated by the drive motor 72 into the vertical movement of both stages 76. The drive of the drive motor 72 is controlled by the control unit 15 (see FIG. 2). Specifically, the drive motor 72 is a stepping motor, and the controller 15 controls the step angle and the like of the drive motor 72 to thereby obtain the amount of circular movement of the belt 81 (the amount of movement of the stage 76 up and down). Control.

Here, as shown in FIG. 11, the lower stage 76A is substantially at the lowest position in the internal space 77 (strictly speaking, the thickness of several prizes 40 is the upper position from the lowest position), and the upper stage 76B is at the inner position. When the space 77 is approximately at the center in the vertical direction, the vertical position of both stages 76 will be referred to as a “reject prize extraction position”.
Referring to FIG. 6, the upper surface of the upper stage 76 </ b> B is substantially flush with the transport surface 32 </ b> A of the transport path 32 through the through hole 74 </ b> A of the right wall 74 among the both stages 76 in the reject prize extraction position. , It continues from the left with a slight gap with respect to the transport surface 32A. At this time, the upper surface of the upper stage 76B of the storage 71, the transport surface 32A of the transport path 32, and the set portion 28 of the feeding unit 11 are arranged along the same straight line Y extending in the horizontal direction. Strictly speaking, however, there may be a slight deviation, so that the upper surface of the upper stage 76B, the conveying surface 32A of the conveying path 32, and the set portion 28 of the feeding unit 11 are substantially along the same straight line Y. It only has to be arranged. In this way, since the movement distance of the prize 40 from the feeding unit 11 to the storage 71 can be made the shortest, the prize reader 1 can be further miniaturized.

  Then, as shown in FIG. 11, when the drive motor 72 is driven in a state where each stage 76 is in the reject prize extraction position, both stages 76 rise in the internal space 77. As shown in FIG. 12, the vertical position of both stages 76 when raised to the upper limit is referred to as a “normal prize accumulation position”. The lower stage 76A at the normal prize accumulation position is substantially at the center in the vertical direction of the internal space 77, and the upper stage 76B at the normal prize accumulation position is substantially at the top of the internal space 77. However, the upper storage area 79B at this time has a margin enough to accommodate several prizes 40.

  Referring to FIG. 6, the upper surface of lower stage 76 </ b> A of both stages 76 at the normal prize accumulation position is substantially flush with conveyance surface 32 </ b> A of conveyance path 32 through through hole 74 </ b> A in right wall 74. And is continuous from the left with a slight gap with respect to the transport surface 32A. At this time, in the same manner as in the reject prize extraction position, the upper surface of the lower stage 76A of the storage case 71, the conveying surface 32A of the conveying path 32, and the set portion 28 of the feeding unit 11 extend in the same straight line. It is arranged along (almost) Y. Therefore, the movement distance of the prize 40 from the feeding unit 11 to the storage 71 can be made the shortest, so that the prize reader 1 can be further downsized.

As shown in FIG. 12, when the control unit 15 reversely drives the drive motor 72 in a state where each stage 76 is in the normal prize accumulation position, as shown in FIG. 11, both stages 76 descend to the reject prize extraction position. . Note that the stage 76 in the standby state (home position) is in the reject prize extraction position.
As a result of identification by the identification unit 6, the storage location of the prize 40 (normal prize 40) determined to be genuine is the lower storage area 79A. As a result of identification by the identification unit 6, the storage location of the prize 40 (reject prize 40) that is discriminated as a fake and rejected is the upper storage area 79B. Most of the prizes 40 set in the setting unit 28 of the prize reader 1 are normal prizes 40. Therefore, the normal prize 40 is a majority and the reject prize 40 is a minority.

The control unit 15 moves the stage 76 up and down with the drive motor 72 and the conversion mechanism 80, so that the storage area that is the storage destination of each prize 40 (each of the normal prize 40 and the reject prize 40) out of the two storage areas 79. 79 can be switched.
Specifically, when the control unit 15 determines that the prize 40 is genuine in accordance with the identification of the prize 40 (in the third stop position) by the identification unit 6, the belt 22 moves around as described above. Before and after restarting, the stage 76 is moved up from the reject prize collection position to the normal prize accumulation position (see FIG. 12). Then, since the upper surface of the lower stage 76A that forms the bottom of the lower storage area 79A is connected to the transport surface 32A of the transport path 32 (see FIG. 6), the projection 35 of the belt 22 that has resumed circular movement causes the prize 40 is pushed to the left and thrown into the lower storage area 79A and placed on the upper surface of the lower stage 76A. Thereby, the normal prize 40 is stored in the lower storage area 79A.

  Incidentally, there is a case where the subsequent normal prize 40 is stored in the lower storage area 79A in a state where the normal prize 40 is already stored in the lower storage area 79A. In this case, the control unit 15 controls the drive motor 72 so that the upper surface of the top normal prize 40 among the normal prizes 40 already stored in the lower storage area 79A is substantially flush with the transport surface 32A. Until that time, the stage 76 is lowered by the thickness of one prize 40. When the circular movement of the belt 22 is resumed in this state, the subsequent normal prize 40 is pushed to the left by the protrusion 35 of the belt 22 and thrown into the lower storage area 79A, and the uppermost normal in the lower stage 76A. The premium 40 is laminated from above. As a result, the subsequent normal prize 40 is stored in the lower storage area 79A. Prior to storing the subsequent normal prize 40, the uppermost normal prize 40 already stored in the lower storage area 79A is substantially flush with the transport surface 32A. Therefore, it is possible to keep the subsequent normal prize 40 neatly stacked on the top normal prize 40.

As described above, when the subsequent normal prize 40 is stored in the lower storage area 79A in a state where the normal prize 40 has already been stored in the lower storage area 79A, both stages 76 store the original normal prizes. Gradually descend from position. In the lower storage area 79A, a maximum of 21 normal prizes 40 can be stored in a vertically stacked state.
On the other hand, when the control unit 15 determines that the prize 40 is a fake according to the identification of the prize 40 (at the third stop position) by the identification unit 6, the revolving movement of the belt 22 is resumed as described above. Before and after this, the stage 76 is lowered to the reject prize extraction position (see FIG. 11). Incidentally, if the stage 76 is already in the reject prize extraction position, the control unit 15 does not move the stage 76. In a state where the stage 76 is in the reject prize extraction position, the upper surface of the upper stage 76B, which forms the bottom of the upper storage area 79B, is connected to the transport surface 32A of the transport path 32 (see FIG. 6). The giveaway 40 is pushed to the left by the protrusion 35 of the belt 22 and thrown into the upper storage area 79B, and placed on the upper surface of the upper stage 76B. Thereby, storage of the reject prize 40 in the upper storage area 79B is achieved.

  Incidentally, there is a case where the subsequent reject prize 40 is stored in the upper storage area 79B in a state where the reject prize 40 is already stored in the upper storage area 79B. In this case, similarly to the description of the normal prize 40, the control unit 15 controls the drive motor 72 so that the upper surface of the uppermost reject prize 40 already stored in the upper storage area 79B is the transport surface 32A. The stage 76 is slightly lowered (by the thickness of one prize 40) until it is substantially flush with the surface. When the circumferential movement of the belt 22 is resumed in this state, the subsequent reject prize 40 is pushed to the left by the protrusion 35 of the belt 22 and thrown into the upper storage area 79B, and the uppermost reject prize 40 in the upper stage 76B. Are stacked from above. Thereby, storage of the subsequent reject prize 40 in the upper storage area 79B is achieved. Therefore, when the rejected prize 40 is already stored in the upper storage area 79B and the subsequent rejected prize 40 is stored in the upper storage area 79B, both stages 76 gradually lower from the original rejected prize sampling position. To go. In the upper storage area 79B, a maximum of three reject prizes 40 can be stored in a stacked state. When each stage 76 is in the reject prize extraction position, as described above, the lower stage 76A is positioned above the lowest position of the internal space 77 by the thickness of several prizes 40 (the above-mentioned three sheets). . That is, the lower stage 76A of the reject prize extraction position can be further lowered by the thickness of several prizes 40. Therefore, both of the stages 76 (particularly the lower stage 76A) are lowered from the original reject prize sampling position, so that the three reject prizes 40 can be reliably stored in the upper storage area 79B.

  In addition, when the control unit 15 determines that a given prize 40 is genuine and then determines that the next prize 40 is a fake, or determines that the identification of the next prize 40 is unnecessary, the preceding normal prize 40 is lowered. In response to being stored in the side storage area 79A, both stages 76 are switched from the normal prize collection position to the reject prize collection position. As a result, the subsequent reject prize 40 is stored in the upper storage area 79B. After the reject prize 40, when the control unit 15 determines that the next prize 40 is genuine, the control unit 15 switches both stages 76 from the previous reject prize sampling position to the normal prize accumulation position. Thereby, each of the normal prize 40 and the reject prize 40 can be distributed to the corresponding storage area 79.

  When all the prizes 40 set in the setting unit 28 are distributed to the storage areas 79, the control unit 15 returns the stage 67 to the reject prize extraction position. Thereafter, the prize 40 in each storage area 79 is collected by an attendant. When the clerk who has finished collecting the prize 40 from each storage area 79 presses the stop switch 10 (see FIG. 1), the prize reader 1 feeds, discriminates, and distributes the prize 40 set in the setting unit 28. This completes a series of processes of storage and storage. In addition, the control part 15 is also the information about the amount of money (counting result) for every denomination of normal prize 40 stored in the lower storage area 79A, and the amount of purchase (when there is a reject prize). ) May be displayed on the display unit 7 (see FIG. 1), or a withdrawal instruction may be issued to the dispensing machine (described above) so as to withdraw the amount corresponding to the exchange amount. Further, when the storage area 79 for storing rejected prizes becomes full (three), the prize reader 1 may be automatically stopped. In this case, since a rejected prize more than expected has occurred, the prize reader 1 is stopped in order to read the prize 40 again.

  As described above, in the prize reader 1, the storage 71 has a two-stage configuration with the lower storage area 79 </ b> A for the normal prize 40 and the upper storage area 79 </ b> B for the reject prize 40. Thereby, the width direction dimension (wide dimension) of the prize reader 1 whole can be made small. The prize reader 1 sorts and stores the prizes 40 that have passed through the transport path 32 after receiving the authenticity determination, for each storage area 79 (lower storage area 79A or upper storage area 79B). . Distribution of the prize 40 to each storage area 79 can be achieved only by moving the stage 76 up and down. That is, with a simple configuration that only changes the relative position between each storage area 79 and the transport path 32, each storage area 79 and the transport path 32 are selectively connected to each other (the product that has passed through the transport path 32). 40 can be sorted and stored for each storage area 79. As described above, since the prizes 40 can be sorted and stored for each storage area 79 only by changing the relative positions of the respective storage areas 79 and the conveyance path 32, the configuration for distributing the prizes 40 to the respective storage areas 79 can be simplified. Therefore, the prize reader 1 can reduce the cost.

Furthermore, since the lower storage area 79A and the upper storage area 79B are arranged close to each other, the vertical movement distance of the stage 76 for distributing the prize 40 to each storage area 79 can be kept short. Therefore, the prize 40 can be quickly distributed to each storage area 79.
In the storage 71, the majority normal prize 40 is stored in the lower storage area 79A, and the minority reject prize 40 is stored in the upper storage area 79B. In this case, the internal space 77 of the storage 71 is compared to the reverse configuration (a configuration in which the majority prize 40 is stored in the upper storage area 79B and the minority prize 40 is stored in the lower storage area 79A). Can be effectively used in the vertical direction, so that the vertical dimension of the storage 71 can be kept small. Therefore, the prize reader 1 can be further reduced in size.

  Moreover, the control part 15 can adjust the circumference speed of the belt 22 by controlling the drive of the drive motor 23 (refer FIG. 3) mentioned above. The circumferential speed of the belt 22 is equal to the conveyance speed of the prize 40 in the conveyance path 32. In this case, the control unit 15 can adjust the conveyance speed of the prize 40 in the conveyance path 32 so that the switching of the storage area 79 is completed before the prize 40 passes through the conveyance path 32. Specifically, a sensor (not shown) for detecting the position of the prize 40 in the transport path 32 is provided. Then, according to the detection result of this sensor, the control unit 15 has a timing (referred to as “passing timing”) when the prize 40 passes through the transport path 32 and reaches the through hole 74A of the storage 71. A timing (hereinafter referred to as “switching timing”) at which the storage area 79 that stores the prize 40 is connected to the conveyance path 32 is predicted and compared. When it is found that the switching timing is delayed from the passage timing, the control unit 15 stops the circumferential movement of the belt 22 or delays the circumferential speed of the belt 22.

By adjusting the conveyance speed of the prize 40 in the conveyance path 32 in this way, switching of the storage area 79 can be surely completed before the prize 40 passes through the conveyance path 32. The prize 40 can be reliably distributed to the storage area 79 switched as the storage destination.
FIG. 13 is a front view of the storage unit 8 according to the modification.

  11 and 12, two stages 76 are provided, and the internal space 77 of the storage 71 is divided into two storage areas 79. As shown in FIG. The number of stages 76 and the number of storage areas 79 can be arbitrarily changed. As described above, since the stage 76 forms the bottom of the storage area 79, the same number of stages 76 and storage areas 79 are provided as described above. A plurality of stages 76 and storage areas 79 are provided. In FIG. 13, four stages 76 are provided at an interval in the vertical direction, and four storage areas 79 are provided in the vertical direction. In this case, the reject prize 40 may be stored in the uppermost storage area 79, and the normal prize 40 may be stored separately for each denomination in the lower three storage areas 79.

  Moreover, the conversion mechanism 80 mentioned above may be provided for every stage 76, and each stage 76 may move independently up and down. In this case, the entire conversion mechanism 80 (including the drive motor 72 and the control unit 15) functions as an interval adjustment unit that adjusts the interval between the stages 76 adjacent in the vertical direction (the crossing direction with respect to the conveyance direction X described above). By using the interval adjusting means here, as the operation of the prize reader 1, the interval between adjacent stages 76 (that is, each storage area 79 is set so that each storage area 79 is just large enough to store the number of prizes 40 to be stored. , And the number of prizes 40 that can be stored in each storage area 79) can be arbitrarily adjusted by software setting. In this way, by adjusting the size of each storage area 79 in accordance with the planned number of stored prizes 40, the internal space 77 of the storage 71 can be used effectively. It can be kept small. Therefore, the prize reader 1 can be further reduced in size.

14 to 17 are diagrams showing examples of display contents on the display unit 7 of the prize reader 1.
Next, the display unit 7 will be described in detail with reference to FIGS. As described above, the display unit 7 occupies substantially the lower half of the area on the right side of the front side of the main body 2 and is relatively large (see FIG. 1). Further, the display unit 7 is surrounded by the transport unit 5 (the feeding unit 11 and the transport path 32) and the storage unit 8 in a front view (see FIG. 1). Therefore, the display unit 7 can display the size and layout effectively.

  For example, it is detected whether or not the reject prize 40 has been stored in the upper storage area 79B in which the reject prize 40 is stored (hereinafter referred to as “reject storage”) up to the maximum number of sheets that can be stored (the three described above). Sensor (referred to as “reject storage residual sensor”, not shown) is provided. A similar sensor may be separately provided for detecting the number of normal prizes 40 in the lower storage area 79A.

  When the reject prize 40 is stored up to the upper limit in the reject storage, the reject storage residual detection sensor enters an abnormal state. In response to this, the control unit 15 provides an arrow 85, an illustration 86, and a message 87 on the display unit 7, as shown in FIG. 14, as guidance for prompting the clerk to cancel the error (reject the reject prize 40). Is displayed. An arrow 85 is a large black arrow located at the upper left corner of the display unit 7. An arrow 85 points to the actual reject storage. Therefore, the attendant can recognize that the reject prize 40 is actually stored up to the upper limit in the reject storage by looking at the actual object in the reject storage indicated by the arrow 85.

  Further, the illustration 86 schematically shows the prize reader 1. In the illustration 86, the portion corresponding to the target reject storage is highlighted as shown by dots in FIG. 14. ing. The illustration 86 also displays a mini arrow 88 that points to a location corresponding to the reject storage. Therefore, the clerk can also recognize that the reject prize 40 is stored in the reject storage box up to the upper limit by looking at the illustration 86. If the illustration 86 is displayed on the display unit 7 at a position as close as possible to the arrow 85 (in other words, the actual object in the reject storage), it is possible to strongly notify the attendant.

  The message 87 is displayed in the remaining area other than the arrow 85 and the illustration 86 on the display unit 7. The message 87 is related to the headline indicating the type of error (in FIG. 14, “! Reject storage residue detection sensor error”), the method of canceling the error to the staff (each sentence under the headline), and the error cancellation. Touch keys 89 and the like for operating the staff. When the clerk completes the error cancellation, the display unit 7 does not display the arrow 85, the illustration 86, and the message 87.

  As another example, when an abnormality occurs in the lower right portion of the prize reader 1, the control unit 15 provides a guidance for prompting the staff to cancel the error, as shown in FIG. In addition, an arrow 85, an illustration 86, and a message 87 are displayed. An arrow 85 points to the actual part of the target part (the lower right part of the prize reader 1). Therefore, the clerk can actually visually confirm that an abnormality has occurred in the lower right portion of the prize reader 1 indicated by the arrow 85.

  Further, in the illustration 86, a portion corresponding to the target portion is highlighted as shown by a black circle in FIG. In addition, the illustration 86 also displays a mini arrow 88 that points to a portion corresponding to the part. Therefore, the clerk can also recognize that an abnormality has occurred in the lower right portion of the prize reader 1 by looking at the illustration 86. In this case as well, the illustration 86 is preferably displayed at a position as close as possible to the arrow 85 (lower right portion of the prize reader 1) on the display unit 7. Further, the message 87 displayed in the remaining area other than the arrow 85 and the illustration 86 on the display unit 7 is a headline indicating the type of error ("! Start SW (switch) abnormality" in FIG. 15) or to a staff member. Error canceling method (each sentence under the heading), touch key 89, and the like. When the clerk completes the error cancellation, the display unit 7 does not display the arrow 85, the illustration 86, and the message 87.

Further, guidance for normal operation operation in the prize reader 1 may be displayed on the display unit 7 as shown in FIG.
For example, when the additional prize 40 is set in the setting unit 28 (see FIG. 3) by the clerk with the prize 40 remaining in the storage 71 (here, the lower storage area 79A), the control is performed. The unit 15 displays an arrow 85, an illustration 86, and a message 87 on the display unit 7 as shown in FIG. 16 in order to prompt removal of the prize 40 from the storage 71. The arrow 85 points to the actual thing in the lower storage area 79A. In the illustration 86 of FIG. 16, a portion corresponding to the target lower storage area 79A is highlighted with dots. The message 87 has a content that prompts the user to remove the prize 40 from the storage 71 before setting the additional prize 40.

Further, when a rejection (specifically, jam) occurs, guidance for prompting re-identification (re-counting) of the prize 40 may be displayed on the display unit 7 as shown in FIG.
When the rejection occurs, the control unit 15 displays an arrow 85, an illustration 86, and a message 87 on the display unit 7, as shown in FIG. A plurality of arrows 85 are displayed so as to point to the actual thing of the portion (each storage area 79 and the set unit 28) where the prize 40 to be re-identified exists. In the illustration 86 in FIG. 17, a portion corresponding to a portion where the prize 40 to be re-identified exists is highlighted with dots. The message 87 has a content that prompts the user to remove the prize 40 from each storage area 79 and the setting unit 28 and set it again. When the clerk pulls out the prize 40, the arrow 85 pointing to the portion disappears from the display unit 7 in sequence from the portion where the removal is completed. At the same time as all the arrows 85 disappear, the illustration 86 and the message 87 disappear from the display unit 7.

  Moreover, regarding the guidance display on the display unit 7 described above, the display mode can be arbitrarily changed. For example, if the above-described arrow 85 is to be highlighted, the arrow 85 may be oversized and displayed in a conspicuous color (for example, red). Further, if the level of urgency is not so high (for example, a warning level), if the arrow 85 is displayed in a color that is not as conspicuous as red (for example, a color close to yellow), the attendant can determine the level of urgency by the color of the arrow 85. I can grasp. Further, in the case of the operational operation guidance as described above (that is, the level of assistance for normal operation), the arrow 85 is displayed in, for example, a green fluorescent color to emphasize to the staff that it is a normal guide. May be. Thus, there may be a setting in which the color of the arrow 85 can be changed according to the situation. If necessary, the arrow 85 may be blinked in addition to being lit. In addition to changing the color of the arrow 85, the background color in the display unit 7 may be changed.

Next, in the prize 40, a structure capable of preventing an unauthorized attempt to take out the valuable material 42 from the main body 41 will be described with reference to FIGS.
The prize 40 includes the main body 41, the valuables 42, the IC tag 43, and the hologram 44 described above. In the following, description and illustration of the hologram 44 (illustrated in FIGS. 18 to 25) are omitted.

With reference to FIG. 18, main body 41 includes a case 90, an intermediate plate 91, and a lid 92.
The case 90 is a rectangular plate having a predetermined thickness (corresponding to the thickness of the prize 40 as a whole), and a recess 93 is formed on one side surface in the thickness direction. The recess 93 includes a first recess 94, a second recess 95 that is further recessed from the bottom surface 94 </ b> A of the first recess 94, and a third recess 96 that is further recessed from the bottom surface 95 </ b> A of the second recess 95. When viewed from the thickness direction of the case 90, the contours of the first concave portion 94, the second concave portion 95, and the third concave portion 96 have a rectangular shape similar to the contour of the case 90, and gradually decrease in this order. When viewed from the thickness direction of the case 90, the bottom surface 94A of the first recess 94 has a rectangular frame shape surrounding the second recess 95, and the bottom surface 95A of the second recess 95 has a rectangular frame shape surrounding the third recess 96. The bottom surface 96A of the third recess 96 has a rectangular shape surrounded by the bottom surface 95A of the second recess 95. The side surface (the lower surface in FIG. 18) opposite to the side where the concave portion 93 is formed in the case 90 is the above-described back surface 40 </ b> B of the prize 40.

The middle plate 91 is a rectangular plate having a thickness substantially the same as the depth of the second recess 95, and the contour of the middle plate 91 when viewed from the thickness direction substantially matches the contour of the second recess 95. ing. A through hole 91 </ b> A having a size that can accommodate the valuable material 42 is formed at the center position (center of gravity position) of the intermediate plate 91.
The lid 92 is a rectangular plate having a thickness substantially the same as the depth of the first recess 94, and the contour of the lid 92 when viewed from the thickness direction substantially matches the contour of the first recess 94. . The entire lid 92 is transparent or translucent.

The IC tag 43 described above has a rectangular plate shape having substantially the same thickness as the depth of the third recess 96, and the outline of the IC tag 43 when viewed from the thickness direction is the outline of the third recess 96. Is almost the same. Referring to FIGS. 20 and 21, IC tag 43 includes a main body 97, an antenna unit 98, and an IC chip 99.
The main body 97 is a rectangular substrate that forms an outline of the IC tag 43, and a plurality of slits 100 are formed at equal intervals throughout the outer peripheral edge (each of the long side and the short side). Each slit 100 cuts the main body 97 in the thickness direction from the outer peripheral edge of the main body 97 to the inside. Two slits 101 for cutting the main body 97 in the thickness direction are formed at the center position (center of gravity position) of the main body 97. Each slit 101 is substantially U-shaped, and the pair of slits 101 are arranged so as to bulge away from each other. These slits 101 are not connected to each other.

20 and 21, the upper surface of the main body 97 is referred to as a front surface 97A of the main body 97, and the lower surface of the main body 97 is referred to as a rear surface 97B of the main body 97.
The antenna unit 98 is a wire for the IC tag 43 to communicate with the IC reader / writer 57 of the prize reader 1. The antenna unit 98 mainly includes a front side antenna unit 98A (solid line portion in FIG. 20) provided on the front surface 97A of the main body 97 and a back side antenna unit 98B (broken line portion in FIG. 20) provided on the back surface 97B of the main body 97. Is included.

  The front surface side antenna portion 98A is disposed on the inner side (the central position side of the main body 97) on the front surface 97A of the main body 97 with respect to the outer peripheral edge (the portion where the slit 100 is formed). It has a spiral shape (coil shape) that extends to the center position of the main body 97 (the portion surrounded by the pair of slits 101). The back surface side antenna portion 98B extends so as to connect one end portion 98C on the outer peripheral edge side of the main body 97 and the other end portion 98D at the center position of the main body 97 in the front surface side antenna portion 98A.

  Referring to FIG. 21, a plurality of through holes (via holes) 102 penetrating through the main body 97 are formed at portions of the main body 97 that coincide with the one end portion 98 </ b> C and the other end portion 98 </ b> D. One end portion 98C of the front surface side antenna portion 98A and the back surface side antenna portion 98B are electrically connected by a through hole 102 (strictly, a conductive material filled in the through hole 102) in the one end portion 98C. Further, the other end 98D of the front surface side antenna portion 98A and the back surface side antenna portion 98B are electrically connected by a through hole 102 (strictly, a conductive material filled in the through hole 102) in the other end portion 98D. Has been. Thereby, in the antenna part 98, the electroconductivity with the front surface side antenna part 98A and the back surface side antenna part 98B is ensured.

The IC chip 99 is a part that actually stores information in the IC tag 43, and is interposed in the middle of the antenna unit 98 (here, the front surface side antenna unit 98A).
The entire area of the front surface 97A and the back surface 97B of the main body 97 is coated with the adhesive material 103 having strong adhesiveness. The adhesive material 103 covers not only the front surface 97A but also the front surface side antenna portion 98A and the IC chip 99 on the front surface 97A, and the back surface 97B covers not only the back surface 97B but also the back surface side antenna portion 98B. Each slit 100 of the main body 97 also cuts the adhesive material 103 on the front surface 97A and the back surface 97B, and each slit 101 of the main body 97 also cuts the adhesive material 103 on the front surface 97A.

  With reference to the posture of FIG. 18, such an IC tag 43 is fitted into the third recess 96 of the case 90 with the surface 97 </ b> A of the main body 97 facing upward. In the IC tag 43, the back surface 97 </ b> B of the main body 97 is fixed to the bottom surface 96 </ b> A of the third recess 96 with an adhesive material 103 (see FIG. 21) or a strong double-sided tape (not shown) provided on the bottom surface 96 </ b> A. . Accordingly, the IC tag 43 is fixed in the third recess 96 so as not to be detached.

  Next, the intermediate plate 91 is fitted into the second recess 95 of the case 90. The intermediate plate 91 is fixed to the bottom surface 95A of the second recess 95 by a strong double-sided tape (not shown) provided on the bottom surface 95A. Thereby, the middle plate 91 is fixed in the second recess 95 so as not to be detached. In a state where the intermediate plate 91 is fixed in the second recess 95, the through hole 91A at the central position of the intermediate plate 91 and the central position of the main body 97 of the IC tag 43 (the portion surrounded by the pair of slits 101) Are coincident when viewed from the thickness direction of the case 90. The aforementioned valuables 42 are fixed to the surface 97A of the main body 97 (strictly, the adhesive material 103 of the surface 97A, see FIG. 21) while being accommodated in the through hole 91A of the intermediate plate 91.

  Finally, the lid 92 is fitted into the first recess 94 of the case 90. The lid 92 is fixed to the bottom surface 94A of the first recess 94 by ultrasonic welding. Accordingly, the lid 92 is fixed so as not to be detached in the first recess 94 in a state in which the cover 91 and the valuable material 42 are covered from the outside of the case 90. The lid 92 and the intermediate plate 91 are fixed to each other by ultrasonic welding.

As a result, the prize 40 is completed as shown in FIG. Note that the upper surface of the lid 92 in FIG. Since the lid 92 covers the concave portion 93 of the case 90 from the surface 40A side, the intermediate plate 91, the valuables 42, and the IC tag 43 are sealed in the concave portion 93.
In this prize 40, since the IC tag 43 has weak portions called slits 100 and 101 (see FIG. 18) in the main body 97, the IC tag 43 is a vulnerable IC tag (vulnerable IC tag).

  22A, the lid 92, the intermediate plate 91, and the IC tag 43 are separated from the case 90, and the IC tag 43 is peeled off from the intermediate plate 91 as shown in FIG. There may be fraudulent attempts to extract. In this case, after extracting the valuables 42, there is an unjust intention to return the prize 40 to its original state and exchange the prize 40 without the valuables 42.

  However, if the IC tag 43 is to be peeled off from the intermediate plate 91, the IC tag 43 is changed from the original state shown in FIG. 23A (the state before the IC tag 43 is peeled) as shown in FIG. In addition, the main body 97 is broken starting from one of the slits 100, and the antenna portion 98 (see FIG. 20) is broken halfway. In this case, since the antenna unit 98 cannot function, the IC tag 43 cannot communicate with the IC reader / writer 57 of the prize reader 1. Therefore, the prize 40 returned to the original state after the valuable object 42 is extracted is determined as a fake in the prize reader 1.

  As shown in FIG. 22, unlike the injustice to take the valuables 42 from the back surface 40 </ b> B of the prize 40, a hole 104 is formed in a portion of the lid 92 that overlaps the through hole 91 </ b> A of the intermediate plate 91 as shown in FIG. It is also conceivable that the user opens the valuable material 42 from the surface 40A of the prize 40 through the hole 104 as shown in FIG. In this case as well, there is an unjust intention to return the prize 40 to the original state after extracting the valuables 42 and to exchange the prize 40 without the valuables 42.

  However, the valuable material 42 fixed to the surface 97A of the main body 97 of the IC tag 43 is to be peeled off from the IC tag 43 in the original state (the state before the valuable material 42 is removed) shown in FIG. Then, as shown in FIG. 25 (b), the portion (the central portion 97 C of the main body 97) with the valuable material 42 in the main body 97 is separated from the main body 97 with the slit 101 as a boundary, and is pulled out together with the valuable material 42. End up. In this state, the main body 97 is broken at the center position, and the antenna portion 98 is broken halfway. Also in this case, since the antenna unit 98 cannot function, the IC tag 43 cannot communicate with the IC reader / writer 57 of the prize reader 1. Therefore, the prize 40 returned to the original state after the valuable object 42 is extracted is determined as a fake in the prize reader 1.

The present invention is not limited to the contents of the above embodiments, and various modifications can be made within the scope of the claims.
For example, the configuration in which the prize 40 is fed out, conveyed, and stored in the prize reader 1 can be applied to an apparatus that handles articles (such as cards) other than the prize 40.
In the prize 40, a two-dimensional barcode may be used instead of the IC chip of the IC tag 43. In this case, the denomination is determined by reading the two-dimensional barcode.

In the above-described embodiment, the endless transport body that transports the prize 40 is the belt 22, but a chain may be used instead of the belt 22.
Further, the arrangement of the plurality of storage areas 79 may be not the top and bottom but the front and back. In addition, the direction in which the prize 40 is conveyed and the direction in which the prize 40 is accumulated may be changed as appropriate.
In addition, as described above, the control unit 15 allows the color sensors 55 of the reading unit 52 to read a predetermined different color from the hologram 44 of the prize 40 (in the above-described embodiment, the color sensor 55A reads red) Further, it is assumed that the reading unit 52 can read the real hologram 44 when the color sensor 55B reads green. Then, the control unit 15 determines the authenticity of the prize 40 based on whether or not the reading unit 52 has read the (real) hologram 44 from the prize 40. Instead, the control unit 15 determines that the reading unit 52 has read the hologram 44 as long as each color sensor 55 reads a color (strictly different color) from the hologram 44, and then the color (that is, The authenticity of the prize 40 may be determined based on the information of the hologram 44 read from the prize 40 by each color sensor 55 of the reading unit 52. For example, when the color sensor 55A reads blue from the hologram 44 and the color sensor 55B reads yellow from the hologram 44, the control unit 15 determines that the reading unit 52 has read the hologram 44 from the premium 40 for the time being. Thereafter, the control unit 15 determines that the blue color read by the color sensor 55A is not red (which should be read) and the yellow color read by the color sensor 55B is not green (which should be read). Is identified as a fake.

DESCRIPTION OF SYMBOLS 1 Prize reader 11 Feeding part 15 Control part 32 Conveying path 40 Prize 71 Storage container 72 Drive motor 76 Stage 77 Internal space 79 Storage area 79A Lower storage area 79B Upper storage area 80 Conversion mechanism X Transport direction

Claims (7)

A feeding section for feeding set articles;
A transport path for transporting articles fed from the feed section;
A plurality of storage areas arranged adjacent to each other in a direction intersecting the conveyance direction of the article in the conveyance path, and a plurality of storage areas capable of sorting and storing the articles that have passed through the conveyance path for each of the storage areas;
An interval adjusting means for adjusting the width of each storage area in the intersecting direction;
An article feeding and storing device comprising: Including one storage for storing goods,
2. The article supply and storage device according to claim 1, wherein the plurality of storage areas are configured by dividing an internal space of the storage in the intersecting direction. The crossing direction is a vertical direction,
3. The article feeding and storing apparatus according to claim 2, further comprising a stage that is provided in the same number as the storage area, divides the internal space of the storage in the vertical direction, and on which the article is placed.   4. The article feeding and storing apparatus according to claim 3, wherein two storing areas and two stages are provided.   Among the plurality of storage areas, a lower storage area positioned relatively below stores a majority item, and among the plurality of storage areas, an upper side positioned above the lower storage area. The article supply and storage device according to claim 3 or 4, wherein the storage area stores a minority article.   6. The article feeding and storing apparatus according to claim 5, wherein the minority article includes an article to be rejected. Of the plurality of storage areas, switching means for switching the storage area that is a storage destination of articles,
Speed adjusting means for adjusting the conveying speed of the article in the conveying path so that the switching of the storage area by the switching means is completed before the article passes through the conveying path;
Characterized in that it comprises a article feeding storage device according to any one of claims 1-6.

Images