JP5789813B2 - Coin hopper - Google Patents

Description

The present invention relates to a coin hopper that reduces the weight of coins applied to a rotating disk by disposing coins one by one and disposing coins one by one in a hopper head that holds coins in a stacked state.
More particularly, the present invention relates to a coin hopper that reduces the weight of coins applied to a rotating disk by arranging an inclined plate in a hopper head that holds coins in a stacked state, and does not cause a coin jam caused by the inclined plate.
Specifically, in the coin hopper that reduces the weight of coins applied to the rotating disk by arranging an inclined plate in a hopper head that holds coins in a stacked state, a coin jam is generated by forming the inclined plate in a bowl shape. It is related to the coin hopper that has not been.

As a first conventional technique, the present applicant has proposed a rotating disk for sorting and discharging coins one by one, and a coin disposed and disposed above the rotating disk to be stored in a stacked state. A cylindrical main tank, and a downwardly inclined plate fixedly positioned directly above the rotating disk, and an opening smaller than the upper large opening is formed on the side of the lower end of the inclined plate. A cylindrical auxiliary tank disposed in a stacked relationship on the main tank so that the small opening communicates with an opening at an upper end of the main tank, and a bottom wall of the main tank extending through the bottom wall. And a stirring shaft that is rotated by the drive means of the rotating disk, and is located on the tip of the stirring shaft at the side of the inclined plate through the small opening of the auxiliary tank, and with respect to the stirring shaft. Eccentric There is known a coin hopper device in which a spiral stirring member is attached (see, for example, Patent Document 1).
As a second conventional technique, a coin storage for temporarily holding coins and a plurality of holes having a diameter larger than the diameter of the handling coin are provided along the direction of rotation provided rotatably at the bottom of the coin storage. Installed on the upper part of the coin storage, and connected to the coin storage, the formed coin supply disk, a drive motor as a rotational drive source of the coin supply disk, a control unit for controlling the drive motor An auxiliary storage that supplements the coin storage capacity, and the coins introduced into the coin storage through the auxiliary storage and captured in the holes are conveyed by the rotation of the coin feeding disk, and a predetermined coin A coin dispensing device that leads to a dispensing unit, the coin dispensing device being fixed to a predetermined money processing device in the auxiliary storage, and the coin feeding disk on the inner wall of the coin storage A coin-throwing device is known which is provided with a placing member which is configured to be capable of placing the inserted coins and is inclined downwardly above the coin (for example, Patent Documents). 2).
Further, as a third prior art, a medal lending machine having a medal storage part and a medal payout part disposed below the medal storage part, and paying out a predetermined number of medals according to the amount of money inserted. And a front decompression plate and a rear decompression plate are provided in the medal storage portion, and the front decompression plate is inclined backward with respect to the vertical to guide the medal stored in the medal storage portion to the medal payout portion. The rear decompression plate is formed as an inclined plate that is inclined downward with respect to the horizontal to guide the medal stored in the medal storage portion to the medal payout portion, and has a medal at its front end. A medal clogging prevention mechanism provided with a notch for dropping is known (see, for example, Patent Document 3).

Patent No. 4217789 (FIGS. 1 to 4, 0009 to 0029) JP2004-348368 (FIGS. 1 to 4, 0008 to 0036) JP 2000-202090 (FIGS. 2-5, 0003-0021)

In the first prior art, coin jam in the small opening can be prevented by rotation of the eccentric spiral stirring member disposed in the small opening located on the side of the lower end of the inclined plate. However, there is a problem that coin jam that occurs on the inclined plate cannot be completely prevented. This is because the stirring effect by the stirring member may not reach the coin on the inclined plate.
The second prior art is the same as the first prior art except for the structure in which the inclined plate can swing up and down. Therefore, it is possible to eliminate coin jamming by the swinging of the inclined plate, but the frequency of the first coin jamming than the prior art occurs is reduced, when the inclined plate is not such as to swing occurs on the inclined plate There is a problem that prevents coin jamming.
In the third prior art, since the tip is formed in a zigzag shape by providing a notch at the tip of the inclined plate, the occurrence of coin jam is reduced compared to the first conventional technology. Similar to the technology, there is a problem that a coin jam occurring on the inclined plate cannot be prevented.

Next, coin jam that occurs on an inclined plate common to the first to third prior arts will be described with reference to FIGS.
First, an outline of the coin hopper 10 will be described.
The coin hopper 10 includes a frame 12, a base 14, a rotating disk 16, and a standard hopper head 18.
The frame 12 has a three-dimensional shape obtained by cutting a right triangular body horizontally and cutting it to a predetermined length, and an electric motor (not shown) for driving the rotating disk 16 is disposed in the hollow internal space. . Accordingly, the upper surface 22 of the frame 12 is formed in a roughly square shape inclined in one direction.
The base 14 is molded into a rectangular thick plate shape, and is fixed to the upper end of the frame 12 so as to be directed to the upper surface 22 and close the internal space of the frame 12.
Accordingly, the base 14 is inclined at the same angle and in the same direction with respect to the upper surface 22 of the frame 12.
A shallow circular storage hole 24 is formed in the base 14, and a lower end portion of the rotary disk 16 having a slightly smaller diameter than the storage hole 24 is disposed. The rotary disk 16 is predetermined by an electric motor disposed in the frame 12. Forward or reverse.

  The rotary disk 16 has a disk shape, and a through hole 26 through which a coin C can pass from the top to the bottom is formed at a position eccentric with respect to the center of rotation.

The standard hopper head 18 is a cylindrical body as a whole, but the lower end portion 30 is a circular cylindrical shape, and a circular bottom hole 28 is formed along an axis L that is suspended from the base 14. Above the predetermined distance from 28, the horizontal section is a rectangular portion 32 having a rectangular shape, and the upper end of the bottom hole 28 and the lower end of the rectangular portion 32 are a connecting portion 34 formed of a straight line or a curve so that they are smoothly connected. Is formed.
More specifically, the rear connecting portion 34B facing the rotating disc 16 is inclined at an angle of about 30 degrees with respect to the horizontal line, and the front connecting portion 34F positioned on the front side with respect to the rotating disc 16 is approximately parallel to the rotating disc 16. In other words, it is inclined at an angle of about 40 degrees with respect to the horizon.
A flat plate-like rear side wall 36 that is suspended from the end of the rear connecting portion 34B is provided, and a flat plate-like front side wall 38 that is suspended from the end of the front connecting portion 34F is provided. Are connected by a flat left side wall 42 and a right side wall 44 to form a rectangular portion 32.

The reason why the upper portion is the rectangular portion 32 is to increase as much as possible the retention amount of coins C in a limited space.
The height of the rectangular portion 32 is determined in consideration of the balance between the output of the electric motor and the amount of reserved coins. In other words, the height of the standard hopper head 18 is determined so as not to exceed the rotational resistance of the rotating disk 16 added by the amount of coins C to be held.

The case where the coin C is retained beyond the height of the standard hopper head 18 is dealt with by connecting an auxiliary hopper head 48 having a horizontal cylindrical section to the upper end of the standard hopper head 18. In this case, the combination of the standard hopper head 18 and the auxiliary hopper head 48 is the increasing hopper head 52.
The auxiliary hopper head 48 has a horizontal cross section formed in a rectangular shape by an auxiliary rear side wall 54, an auxiliary front side wall 56, an auxiliary left side wall 58 and an auxiliary right side wall 62 relative to the standard hopper head 18.
When the auxiliary hopper head 48 is mounted on the standard hopper head 18, the amount of coins C stacked on the rotating disk 16 increases, so that it is assumed that the rotating disk 16 cannot be rotated with a standard electric motor. .
In this case, the it is conceivable to change the electric motor to the high-output, since the cost increases and power consumption increases, it is difficult to adopt the sudden.

Therefore, as in the first to third prior arts described above, the inclined plate 64 is disposed above the rotating disk 16, and the weight of the coin C placed on the inclined plate 64 is supported by the inclined plate 64. Only the coin weight below the inclined plate 64 is added to 16 so that the number of retained coins can be increased without changing the output of the electric motor.
However, it has been newly found that there is a problem that coin jam occurs on the inclined plate 64 when the inclined plate 64 is used.

In principle, the same specification is applied to all coins C in the coin hopper 10. For example, when dealing with euro coins, the same coin hopper 10 is adopted for all 8 denominations from 1 cent to 2 euros, the only change is the size of the through hole 26 for each denomination or Only the rotating disk 16 is suitable for each denomination group with a close diameter.
Specifically, the first distance L1 between the clear width of the auxiliary left side wall 58 and the auxiliary right side wall 62 is equal to or smaller than the 3.0 times 2.5 times with respect to the diameter D of the coin C, coin jamming on the inclined plate 64 is This causes a problem that the jammed coin C is not paid out by the rotation of the rotary disk 16.

Next, a mechanism for generating a coin jam on the inclined plate 64 will be described with reference to FIGS.
The coin jam is a state in which one side wall, for example, the left side wall 58 of the auxiliary side wall 58 is placed in a lying state in which the coins C are in contact with the inclined plate 64 due to complicated movement of the coins C in the auxiliary hopper head 48. The first sleeping coin group LC1G stacked on the first sleeping coin LC1 sleeping with its peripheral surface in contact with one wall, for example, the auxiliary right side wall 62 with a plurality of standing coins contact coins group SCG stood aligned into bars exist towards starting coins SC which stood to assist left side wall 5 8, the inclination between the coin group SCG standing the first sleeping coin group LC1G This occurs when the second sleeping coin group LC2G stacked on the second sleeping coin LC2 in surface contact with the plate 64 bites into a wedge shape when trying to enter.

That is, as shown in FIG. 15 (A), the second sleeping coin group LC2G has its own weight and other acting on the second sleeping coin group LC2G located on the upstream side with respect to the inclination direction of the inclined plate 64. Due to the pressing force of the medals, the first force F1 acts on the first sleeping coin group LC1G in the direction from the center of the second sleeping coin LC2 toward the contact point. Accordingly, as a component force of the first force F1, pressing the auxiliary left side wall 58 by a first pushing force F1V acting perpendicularly to the auxiliary left side wall 58.
On the other hand, on the standing coin SC, the second pushing force F2V, which is a component force of the first force F1 with respect to the reaction force F2, acts at right angles to the surface of the standing coin SC and forms a stick-shaped coin SC. Are sequentially propagated and the auxiliary right side wall 62 is pushed.
At this time, if the second sleeping coin group LC2G is piled up at least about the radius with respect to the diameter of the standing coin SC, the standing coin group SCG cannot fall down.
These first sleeping coin group LC1G, by the second sleeping coins group LC2G and standing coins group SCG are balanced, the coin jamming the inclined plate 6 4 above without being able to slide down by gravity It is thought to occur.

More specifically, the coin jam is a surface of the coin SC standing by the frictional force between the peripheral surface of the coin LC1 group sleeping by the first pressing force F1V and the auxiliary left side wall 58, and the second pressing force F2V. This occurs when the frictional force between the auxiliary right side wall 62 and the auxiliary right side wall 62 becomes larger than the downward force generated by the gravity acting on the coin group due to the inclination of the inclined plate 64.
Note that the occurrence of coin jam is not limited to the above, but can also occur when the first sleeping coin LC1 and the second sleeping coin LC2 are one piece. The frequency is low.
In the present invention, the first distance L1 between the auxiliary left side wall 58 and the auxiliary right side wall 62 is not limited to be not less than 2 times and not more than 3 times the coin diameter.
In addition, as in the first prior art, a stirring member that rotates to the side of the inclined plate can be arranged to reduce the frequency of occurrence, but adding a stirring device increases costs and increases power consumption. Because it invites, it is difficult to adopt it as a bag.

A first object of the present invention is to provide a coin hopper that does not cause a coin jam on an inclined plate.
A second object of the present invention is to provide a coin hopper that does not cause a coin jam on an inclined plate without using additional parts or the like.
A third object of the present invention is to provide a coin hopper that does not cause coin jam on an inclined plate at a low cost.
In the present specification, “coin” includes coins as currency, as well as substitute money such as medals and tokens of game machines, or similar items.

In order to achieve this object, a preferred first embodiment of the present invention is configured as follows.
A first side wall, a second side wall facing the first side wall, a third side wall connected to the first and second side walls, and facing the third side wall and connected to the first and second side walls A hopper head for holding coins in a stacked state, wherein the cross-sectional shape perpendicular to the first to fourth side walls is rectangular and a circular bottom hole is formed at the bottom. A rotating disk that is rotatably disposed in a bottom hole of the hopper head and has a through-hole penetrating in the vertical direction, and stores coins stored in the hopper head as the rotating disk rotates. A coin hopper that drops into the through-holes and pays out one by one , wherein the hopper head has a first inclined plate that is inclined downward from the first side wall toward the second side wall above the rotating disk; Front above the first inclined plate A second inclined plate inclined downward from the second side wall toward the first side wall, wherein the first inclined plate has a flat plate shape, and the second inclined plate is the third and fourth side walls. A lower end of the first inclined plate and the second inclined side when viewed from a direction parallel to the first to fourth side walls. The length in the downward direction of the first and second inclined plates is set so that a predetermined gap is formed between the downward tip of the plate and the vertical movement of the coin due to the rotation of the rotating disk is A coin hopper characterized in that the coin spills upward from the downward tip of the first inclined plate and causes the coins in the lying position parallel to the width direction to interfere with each other on the second inclined plate .

According to the onset bright, the second inclined plate is formed in a gutter shape. In other words, the cross section of the second inclined plate is in a concave shape. When the cross-section is concave, the sleeping coin tends to move to the center of the bowl shape by its own weight, so the chance that two coins are adjacent to each other on the slope plate is greatly reduced.
Even if two sleeping coins are lined up side by side on the inclined plate, the extension of the center line of the sleeping coins will overlap in the concave inward direction, and the coins will be stacked sequentially on the sleeping coins. Even if they try to do so, the coins on the top will interfere with the adjacent coins, making it difficult to stack them. Even if a few coins are stacked, they will be destroyed by the adjacent coins. Further, standing coins make point contact on the saddle curved surface, and in principle, the condition for continuing standing is not satisfied. Therefore, it is extremely difficult to construct a standing coin group .
From the above, it is extremely rare that the conditions for generating a coin jam are satisfied, so that a coin jam is not substantially generated.

According to the present invention , the coin load applied to the rotating disk mainly depends on the amount of coins below the lowermost first inclined plate. Therefore, setting this position appropriately does not increase the output of the electric motor. There is an advantage that the storage capacity of the coin of the hopper head can be increased.

According to the present invention, the first inclined plate lowermost Ru flat der.
The lowermost inclined plate is pushed up from below by the coins stirred by the rotating disk.
When the first inclined plate has a bowl shape, a triangular space is formed, and there is a possibility that coins may be jammed in the triangular space. However, if the first inclined plate is flat, Ru can avoid the risk of coin jams since triangular space is not formed.

1 is a partially transparent perspective view of a coin hopper according to a first embodiment of the present invention. FIG. 2 is a plan view of the coin hopper according to the first embodiment of the present invention. 3 is a cross-sectional view taken along line XX in FIG. FIG. 4 is a perspective view of the inclined plate of the coin hopper according to the first embodiment of the present invention. FIG. 5 is a diagram for explaining the operation of the coin hopper according to the first embodiment of the present invention. FIG. 6 is a cross-sectional view of the inclined plate of the coin hopper according to the second embodiment of the present invention. FIG. 7 is a cross-sectional view of the inclined plate of the coin hopper according to the third embodiment of the present invention. FIG. 7 is a cross-sectional view and an operation explanatory view of the inclined plate of the coin hopper according to the fourth embodiment of the present invention. FIG. 9 is a perspective view of the coin hopper according to the fifth embodiment of the present invention. FIG. 10 is a cross-sectional view similar to FIG. 3 of the coin hopper according to the fifth embodiment of the present invention. FIG. 11 is a partially transparent perspective view of a conventional coin hopper. FIG. 12 is a cross-sectional view of a conventional coin hopper. FIG. 13 is a plan view of a conventional coin hopper. FIG. 14 is a cross-sectional view for explaining the occurrence of coin jam on an inclined plate of a conventional coin hopper. FIG. 15 is an explanatory diagram for explaining the occurrence of coin jam on the inclined plate of the conventional coin hopper.

  The best mode of the present invention comprises a hopper head having a rectangular portion that rises in a vertical direction from a circular bottom hole formed in the bottom portion and has a rectangular horizontal section at a predetermined height from the bottom hole, A rotating disk having a through-hole penetrating in the vertical direction is arranged in the hole, and an inclined plate having a front lowering is arranged above the rotating disk in the rectangular portion. In a coin hopper in which coins held in a state are dropped into the through holes and paid out one by one, the width of the hopper head is not less than 2 times and not more than 3 times the coin diameter, and the inclined plate is the inclined plate. The cross-sectional shape in a plane perpendicular to the inclined direction line is formed in a downward arcuate shape, and a plurality of the inclined plates are arranged while being shifted in the vertical direction of the hopper head. Inclined plate disposed adjacent to the lower are inclined in mutually different directions, the bottom of the inclined plate is a flat plate, and a coin hopper which is characterized in that it is arranged directly above the rotating disk.

The same parts as those of the conventional apparatus are denoted by the same reference numerals, and different structures will be described.
A coin hopper 100 according to an embodiment of the present invention has a function of paying out coins of a predetermined denomination one by one.
In the coin hopper 100, a payout opening 102 is formed at the upper end of the slope of the base 14 through which the coin C rotated by the rotary disk 16 is ejected along the base 14 by an unillustrated ejecting device. Accordingly, the coin C is flipped off and is paid out.
A coin sensor 104 is arranged opposite to the coin passage immediately downstream of the payout opening 102, and detects the coin C paid out from the payout opening 102. As the coin sensor 104, a photoelectric sensor, a magnetic sensor, a mechanical sensor, or the like is selected according to use conditions and the like, and a detection signal from the coin sensor 104 is used to count the coin C that has been paid out.

In the coin hopper 100, the lower end portion of the square tube type auxiliary hopper head 48 is tightly inserted above the standard hopper head 18, and the auxiliary left side wall 58 of the lower end portion of the auxiliary hopper head 48 is provided from the four side surfaces of the standard hopper head 18. The right side wall 62, the auxiliary front side wall 56, and the auxiliary rear side wall 54 are fixed using flat screws or the like. However, the auxiliary hopper head 48 can be configured to be easily detachable from the standard hopper head 18.
For example, it can be configured to be easily detachable by using a popular name snap lock.
Further, the standard hopper head 18 and the auxiliary hopper head 48 can be configured integrally. However, it is preferable to configure the auxiliary hopper head 48 so that it can be easily attached to and detached from the standard hopper head 18 in case a coin jam occurs.

First, the auxiliary hopper head 48 will be described in detail.
In the first embodiment, the auxiliary hopper head 48 is a rectangular tube type having a predetermined length (height) formed by bending a stainless steel flat plate to have a rectangular horizontal cross section.
The first distance L1 between the auxiliary left side wall 58 and the auxiliary right side wall 62 of the auxiliary hopper head 48 is formed to be 2.5 times to 3.0 times the diameter of the coin C.
As a general rule, the same auxiliary hopper head 48 is used for all denominations, so the above condition is not satisfied in the case of small-diameter coins. This applies to the above conditions.

Next, the inclined plate 64 will be described.
The inclined plate 64 has a function of reducing the load of the coin C applied to the rotating disk 16. In other words, by supporting the load of the coin C placed on the inclined plate 64 by the inclined plate 64, the rotating disk 16 has a function of receiving only the load of the coin C below the inclined plate 64.
Inclined plate 64 is upwardly different distances of the rotary disk 16 can have multiple arrangement, in this case, are alternately arranged.
This is because the load of the coin C is not applied to the rotating disk 16 as much as possible.
In the first embodiment, a lower inclined plate 106 and an upper inclined plate 108 are arranged.
However, any one of the lower inclined plate 106 and the upper inclined plate 108 can be arranged and formed into a bowl shape. Further, one or more bowl-shaped inclined plates can be alternately arranged above the upper inclined plate 108.

First, the lower inclined plate 106 will be described.
As shown in FIG. 3, the lower inclined plate 106 is a metal flat plate-like inclined plate as in the prior art, and is inclined forwardly downward at an angle of about 30 degrees. In other words, it is inclined forward and downward at an angle of about 30 degrees from the auxiliary front side wall 56 toward the auxiliary rear side wall 54 side.
The shortest second horizontal distance L2 in the horizontal direction of the lower drop opening 118 formed between the tip 106T of the lower inclined plate 106 and the auxiliary rear side wall 54 is set to be at least twice the diameter of the coin C. It is.
The lower inclined plate 106 has its left and right ends bent downward at right angles to form a left ear piece 112 and a right ear piece 114. The left ear piece 112 and the right ear piece 114 are the auxiliary left side wall 58 and the auxiliary right side wall. And the left ear piece 112 and the right ear piece 114 are fixed by screws 116 screwed through the auxiliary left side wall 58 and the auxiliary right side wall 62.

With this configuration, the rotation of the rotary disk 16 causes the coin C, which is retained in the standard retaining portion 20 of the standard hopper head 18 in a stacked state , to fall in a state standing in the through hole 26 in FIG. The coin C located in the lower drop opening 118 formed between the tip 106T of the lower inclined plate 106 and the auxiliary rear side wall 54 is sequentially propagated to the coins C stacked up and down in the vertical direction. Is also moved up and down. Thereby, even if the second distance L2 of the lower drop opening 118 is about twice the diameter of the coin C, there is an advantage that the coin C does not cause a coin jam that stays in a bridge shape.
The lower inclined plate 106 can also be formed in a bowl shape like the upper inclined plate 108, but the coin C that is moved upward by the rotation of the rotary disk 16 is located below the auxiliary left side wall 58 or the auxiliary right side wall 62. It is necessary to have a shape and mounting structure that is not sandwiched between triangular recess spaces formed by the inclined plate 106.

Next, the upper inclined plate 108 will be described mainly with reference to FIG.
The upper inclined plate 108 is disposed above the lower drop port 118, and has a function of supporting the load of the coin C placed thereon and reducing the load of the coin C applied to the rotating disk 16.
In the first embodiment, the upper inclined plate 108 is disposed so as to be inclined forward and downward from the auxiliary rear side wall 54 side to the auxiliary front side wall 56 side, and orthogonal to the inclination direction line SDL. The cross section in the plane P to be formed is formed into a ridge 122 shape. Specifically, the flange 122 is formed in a downwardly convex shape.

More specifically, a downwardly convex ridge 122 is formed at the center, and a narrow left flat portion 124 and a right flat portion 126 are formed on both sides thereof, and the outer ends of the left flat portion 124 and the right flat portion 126 face downward. The left mounting ear 128 and the right mounting ear 132 are formed by bending at a right angle, and the distance between the outer surfaces of the left mounting ear 128 and the right mounting ear 132 is the auxiliary left side wall 58 and the auxiliary right side wall of the auxiliary hopper head 48. It is slightly smaller than or equal to the first distance L1, which is the inner distance of 62. Two attachment through holes 134 are formed in the left attachment ear portion 128 and the right attachment ear portion 132, respectively.

  In other words, the upper inclined plate 108 is inserted between the auxiliary left side wall 58 and the auxiliary right side wall 62 and is opposite to the inclination direction of the lower inclined plate 106 at a predetermined distance above the lower inclined plate 106. In the inclined state, a nut (not shown) is attached to the tip of the bolt inserted into the left mounting ear 128 and the through hole 134 of the right mounting ear 132 through the through holes formed in the auxiliary left side wall 58 and the auxiliary right side wall 62. ) Is fixed by screwing.

The left mounting ear portion 128 and the right mounting ear portion 132 are configured as screw holes, and bolts can be directly screwed in. In this case, it is possible to screw the bolt after attaching an anti-rotation adhesive or the like to the tip of the bolt. Further, the through hole 134 may not be provided by fixing the left mounting ear 128 and the right mounting ear 132 to the auxiliary left side wall 58 and the auxiliary right side wall 62 by welding or the like.
That is, the left flat portion 124 and the right flat portion 126 may not be provided, and the left mounting ear portion 128 and the right mounting ear portion 132 may be connected by the concave plate 136 having a concave cross section.
The length of the upper inclined plate 108 is preferably set so as to approximately coincide with the peripheral edge on the auxiliary rear side wall 54 side of the rotating disk 16 as shown in FIG.

Further, it is preferable to provide a gap of the third distance L3 in plan view between the tip end 106T of the lower inclined plate 106 and the tip end 108T of the upper inclined plate 108.
In other words, it is preferable that the front end 106T of the lower inclined plate 106 and the front end 108T of the upper inclined plate 108 are set so as not to overlap when viewed in plan.
Furthermore, in other words, it is preferable that the lower end portion of the rotary disk 16 can be seen over when viewed in plan as shown in FIG.
This is to further prevent coin jam as much as possible by spreading the vertical movement of the coin C due to the rotation of the rotary disk 16 to the holding portion above the tip 106T of the lower inclined plate 106.

Next, the shape of the concave plate 136 will be described.
The concave plate 136 may be concave along the inclined direction line SDL. In other words, the cross section in the plane P can be formed in the arc-shaped ridge 136A that is arcuate downward as shown in FIG.

In the first embodiment, the depth of the groove of the ridge 122 is preferably set to 10 to 15 mm when the diameter of the coin C is about 28 mm.
Referring to FIG. 5, the depth D2 of the groove of the flange 122 (concave plate 136) refers to the fourth distance L4 connecting the left and right ends of the arc-shaped flange 136A and the depth D2 of the deepest portion.
When the depth D2 is small, in other words, when the depth D2 of the 樋 122 is shallow, the pressing force due to gravity on the adjacent coin C is small, and the coin jam clearing force is insufficient, and if it is too deep, the groove is not a ridge. This is because a coin jam is likely to occur in the groove.

Next, a mechanism for preventing the occurrence of coin jam on the upper inclined plate 108 according to the present invention will be described with reference to FIG.
First, when the coin C is to be aligned in a standing state, in the arc-shaped ridge 136A, the peripheral surface on the side wall side contacts the arc surface at one point P1 to Pn in a point contact state. The SC acts as a force PR that tends to fall toward the center side of the arc-shaped ridge 136A due to its own weight, and does not stabilize in a standing state, and when the balance with other coins C is lost, it falls to a sleeping state It becomes easy.

Further, since the sleeping coin LC1 tries to move to the center of the arc-shaped ridge 136A by its own weight, the chance that two coins are adjacent to each other on the arc-shaped ridge 136A is greatly reduced.
When the coins LC lying on the arc-shaped ridges 136A try to stack adjacently, the coins C try to stack along the first perpendicular line PL1 or the second perpendicular line PL2 perpendicular to the arc-shaped arc-shaped ridges 136A. . The first perpendicular line PL1 and the second perpendicular line PL2 are in a relationship of crossing in front view. In other words, the amount of interference increases toward the top. Therefore, since adjacent coins C interfere with each other, it is extremely difficult to pile up in an aligned state.

Further, as shown in FIG. 5, a coin group SCG in which the standing coins SC are arranged in a bar shape constitutes a coin group SCG, and the first sleeping coins LC1 are aligned and stacked to form a first sleeping coin group Even if it is composed of LC1G, even if it is composed of the second sleeping coin group LC2G where the second sleeping coin LC2 is stacked, the coin on which the second sleeping coin group LC2G stands When trying to enter between the group SCG and the first sleeping coin group LC1G, the stacking part of the first sleeping coin group LC1G and the stacking part of the second sleeping coin group LC2G interfere with each other Since it interferes in IT and enters while collapsing the stacked part of the first sleeping coin group LC1G or the stacked part of the second sleeping coin group LC2G , the coin C enters the auxiliary left side wall 58 and the auxiliary right side wall 62. There is no jamming between them.

In addition, as shown in FIG. 3, the second upper inclined plate 142 and the third upper inclined plate 144 can be alternately arranged further upward on the upper inclined plate 108.
  The second upper inclined plate 142 and the third upper inclined plate 144 also have the same configuration and action as the upper inclined plate 108 described above.

  As Example 2, as shown in FIG. 6, the upper inclined plate 108 can be formed into a polygonal collar 136B having a polygonal cross-sectional shape on the plane P. In the case of the second embodiment, the same operation as in the first embodiment is performed, and the accumulation of coins C is suppressed.

  Further, as Example 3, as shown in FIG. 7, the upper inclined plate 108 can be configured as a V-shaped rod 136C having a V-shaped cross-section in the plane P. In the case of the third embodiment, the same operation as in the first embodiment is performed, and the accumulation of coins C is suppressed.

  Next, Example 4 will be described with reference to FIG.
  As shown in FIG. 8, it is possible to configure a convex inverted arc-shaped ridge 146D that is convex upward by inverting the arc-shaped ridge 136A in the first embodiment.

The fourth embodiment is formed by a convex plate 146, the auxiliary left side wall 58, and the auxiliary right side wall 62 in which the convex direction of the flange 122 is formed to be convex upward in the opposite direction to the first to third examples. It is an example.
In the fourth embodiment, the convex plate 146 has a smooth arc shape as in FIG. 5, and is formed upward.
In the case of the fourth embodiment, the standing coin SC forms a standing coin group SCG and leans against the right side wall 62 and is easily stabilized.
Also, the first sleeping coin LC1 is likely to generate the first sleeping coin group LC1G.
However, when the second sleeping coin group LC2G enters between them, the first sleeping coin group LC1G is slanted, so the apparent diameter increases, and the second sleeping coin group the second interference range IT2 is formed between the peripheral surface of the LC2 G. The first sleeping coin group LC1G is pushed out by the interference in the second interference range IT2. In addition, if the forcibly proceed between them, the first sleeping coin group LC1G is slanted, so it is pushed upward by the second sleeping coin group LC2G, and the oblique angle becomes larger . In other words, since the first sleeping coin group LC1G escapes to the motion, can pass between second sleeping coins group LC2G of the first sleeping coin group SC G standing coin group LC1G , there is no possible to jam caught between the first sleeping coins group LC1G and standing coins group SCG.

Next, Embodiment 5 shown in FIGS. 9 and 10 as a preferred example of the present invention will be described.
The fifth embodiment is an example in which the flat lower inclined plate 106 is movable in the vertical direction of the auxiliary hopper head 48. By making the lower inclined plate 106 movable in the vertical direction, when the coin C stirred by the rotation of the rotary disk 16 pushes up the lower inclined plate 106, the lower inclined plate 106 performs a escaping motion. Since no unnecessary load is applied to the rotating disk 16, there is an advantage that the power consumption can be reduced, the durability of the apparatus can be improved, and the coin jam on the lower inclined plate 106 that has occurred should be eliminated. is there.

The second lower inclined plate 148 has a rectangular flat plate shape, and one end thereof is inserted into a slit 152 formed along the horizontal line at the lower end portion of the auxiliary front side wall 56. The slit 152 does not substantially allow the vertical and horizontal movements of the end of the second lower inclined plate 148, but the tip 148T of the second lower inclined plate 148 moves about 10 mm in the vertical direction. It is formed in an allowable size.
A left screw ear piece (not shown) and a right screw ear piece 156 are formed by bending downward from the left and right ends in the vicinity of the tip 148T of the second lower inclined plate 148, respectively.
An arc-shaped left long hole (not shown) centered on the slit 152 is formed in the auxiliary left side wall 58 on the side of the left screw ear piece and the right screw ear piece 156, and the auxiliary right side wall 62 is similarly arcuate. The right elongated hole 158 is formed.

A screw (not shown) as a stopper penetrating the left long hole is screwed into the left screw ear piece and stopped by engaging with the lower end of the left long hole. The screw 162 penetrating the right long hole 158 is screwed into the right screw ear piece 156, and is similarly locked to the lower end of the right long hole 158, thereby determining the standby position in the normal state.
With this structure, in the normal state, the second lower inclined plate 148 is kept stationary by the screw 162 serving as a stopper being locked to the lower end of the left long hole (not shown) and the right long hole 158. Located in.
When the second lower inclined plate 148 is pushed up by the stirring of the coin C by the rotation of the rotating disk 16, the screw 162 is rotated until it is locked to the upper ends of the left long hole and the right long hole 158, and the second The lower inclined plate 148 can escape. When the push-up is finished, the screw 162 is rotated downward by the weight of the second lower inclined plate 148 or by the load of the coin C placed thereon, and the screw 162 is moved to the lower end of the left elongated hole and the right elongated hole 158. It is locked to the part and stopped.
As a result, the load on the rotating disk 16 is greatly reduced.

C coin
P plane
SDL tilt direction line
16 rotating disc
26 through holes
28 Bottom hole
32 rectangle
52 Hopper head
64 inclined plate
106 Lower inclined plate
108 Upper inclined plate
122 樋

Claims (1)

A first side wall, a second side wall facing the first side wall, a third side wall connected to the first and second side walls, and facing the third side wall and connected to the first and second side walls A hopper head for holding coins in a stacked state, wherein the cross-sectional shape perpendicular to the first to fourth side walls is rectangular and a circular bottom hole is formed at the bottom. ,
A rotating disk that is rotatably disposed in the bottom hole of the hopper head and has a through-hole penetrating in the vertical direction ; and
A coin hopper that drops coins stored in the hopper head in accordance with the rotation of the rotating disk, and drops them one by one ,
The hopper head includes a first inclined plate inclined downward from the first side wall toward the second side wall above the rotating disk, and the first inclined plate from the second side wall above the first inclined plate. A second inclined plate inclined downward toward the side wall,
The first inclined plate has a flat plate shape, and the second inclined plate has a bowl shape in which a central portion protrudes downward from a plane including a pair of side edges facing the third and fourth side walls,
The first and second gaps are formed so that a predetermined gap is formed between the downward tip of the first inclined plate and the downward tip of the second inclined plate when viewed from a direction parallel to the first to fourth side walls. The length in the downward direction of the inclined plate is set,
The vertical movement of the coin due to the rotation of the rotating disk is propagated upward from the downward tip of the first inclined plate, and the coins lying side by side in parallel in the width direction on the second inclined plate are made to interfere with each other. A coin hopper characterized by that.

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