JP2000306132A - Coin carrying disk rotor for hopper type coin discharging device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To improve the durability by preventing in advance the fear that a backward curved blade, which pushes coins forward, of a coin carrying disk rotor may be worn out or may be broken or cracked from its front end corner part. SOLUTION: In this coin carrying disk rotor R for hopper type coin discharging device, a backward curved blade 40 projecting to the rear side from a synthetic resin disk rotor body 34 is divided into at least two of a roof-side blade piece 40a and a front-side blade piece 40b by a relief recessed groove 42 for coin guide notched in the middle part of its curve. And metallic reinforcing pins 43a and 43b which are to be brought into contact with a coin C are implanted in the front end corner part of the root-side blade piece 40a or/and that of the front-side blade piece 40b and are integrated with them.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention is used to pay out a required number of coins (including medals and other pseudo coins) by being installed in a slot machine, a money changing machine, a vending machine for various kinds of products, and the like. The present invention relates to a coin transport disk rotor of a hopper type coin payout device to be used.

[0002]

2. Description of the Related Art A hopper type coin payout apparatus most similar to the present invention has a coin transporting disk rotor as follows.
JP-A-6-187533 and JP-A-10-240993
No. has been proposed.

Since these known inventions have substantially the same configuration, the coin feeding piece (3) of the coin feeding disk body (1) made of a synthetic resin will be described in Japanese Patent Application Laid-Open No. Hei 10-240993. As a preventive measure against accidents such as wear, chipping and cracking, the coin feeding piece (3) is reinforced by a reinforcing member (4) made of a metal plate piece in FIG.

[0004]

However, in the above construction, the reinforcing member (4) made of a separate metal plate piece is used as shown in FIG.
It is necessary to attach and fix the coin feeding piece (3) in a circular arc shape along the front surface that comes into contact with the coin with high precision such as its degree of curvature and positional relationship. In particular, in the case of repeated strong contact with the biting coin, there is a possibility that the reinforcing member (4) may be illegally deformed, peeled off or dropped off, and its durability and reliability are poor.

When the size and number of coin receiving holes (2) distributed in the opening of the coin feeding disk body (1) change according to the size of the coin to be applied, the coin feeding piece (3) and its It is also necessary to change the degree of curvature of the reinforcing member (4) made of a metal plate piece, which is extremely troublesome in bending and mounting work of the reinforcing member (4), and is compatible with various coin feeding disk bodies (1). Neither can it demonstrate compatibility or versatility.

[0006]

SUMMARY OF THE INVENTION The present invention is intended to improve such problems. For the purpose, the center of a disk rotor body formed of a synthetic resin material into a disk shape is provided with a rotary drive. While the mounting boss to the motor is also provided in the periphery with a plurality of circular coin receiving holes each opening in a radially symmetric distribution type, from the mutually adjacent coin receiving holes in the disk rotor body, A plurality of tapered back-curved wings having a concave surface along the opening edge of each coin receiving hole and a front surface having a convex curved surface are integrally projected face-to-face with the rear surface in the rotation traveling direction, and the respective rear-curved wings Of a hopper-type coin payout device, which is divided into at least two of a root side wing piece and a tip side wing piece by a relief groove for a coin inductor cut out in the middle of the curve. In the transport disk rotor,

[0007] As the rotation of the disk rotor body progresses, a metal reinforcing pin that comes into contact with the coin to be fed out of the coin receiving hole is connected to the front end of the root-side wing piece that forms the convex curved surface of each backward curved wing. It is characterized in that it is implanted and integrated into the corner or the front corner of the tip-side wing piece.

[0008]

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is an exploded perspective view showing a hopper type coin dispensing apparatus according to the present invention; FIG.
Reference numeral (10) denotes an installation base integrated with a frame from a metal plate. A substantially square metal base plate (11) is fixedly attached to the opening surface inclined from the metal plate from above by a cover from above.

(12) is a built-in case (1) of the reduction gear mechanism.
This is a disk rotor rotation drive motor provided with 3), and is attached to the back surface of the base plate (11) in the inclined installation state in a suspended and fixed state. (1
4) is an output shaft of the motor (12), through which a key (15) is inserted in an orthogonal state.

When the motor (12) detects a biting phenomenon of the coin (C) by a sensor (not shown),
It is a reversible motor driven in reverse rotation by receiving an output signal from the sensor.

Reference numeral (16) denotes a synthetic resin rotor receiving plate which is integrally joined to the surface of the base plate (11), which is also installed at an angle, from above in a stacked state, and is substantially the same as the base plate (11). It has a corresponding size and shape, and is provided with a circular rotor receiving groove (G) which is depressed to a certain depth.

The coin transporting disc rotor (R) fitted into the rotor receiving groove (G) of the rotor receiving board (16) from above is rotated by the rotation drive motor (12) in FIG. 4, the coin (C) in the coin receiving hopper (17) is pushed and conveyed to a coin payout opening described later.

The coin receiving hopper (17) is a synthetic resin product having an open bottom surface which communicates with the above-mentioned rotor receiving groove (G), and its mounting seat (18) is attached to the surface of the rotor receiving plate (16). By being attached and fixed from above, the disc rotor (R) is restrained in a state where it cannot be pulled out upward.

The circular rotor receiving groove (G) of the rotor receiving plate (16) mentioned above has a substantially C-shape which is partially cut away at an obliquely upper position as shown in FIG. There is a disk rotor (R) in the center of the C-shape.
Boss release holes (1)
9), a plurality of dust discharge holes (20), which are scattered and distributed, are respectively formed in the lower circular arc portion in the inclined installation state.

In this case, one boss escape hole (19)
Is the rotor receiving board (16) and the base plate (1
1) and a plurality of dust discharge holes (2).
0) is distributed only in the rotor receiving plate (16) and communicates with one large dust discharge slot (21) formed in the corresponding lower end of the base plate (11).

(22) indicates a positional relationship facing one end of the notch of the rotor receiving groove (G), and a coin guiding piece of a metal plate joined and fixed to the surface of the rotor receiving plate (16) from above, Reference numeral 23) denotes a count roller slide guide slot formed in the rotor receiving plate (16) as a positional relationship facing the notch other end of the rotor receiving groove (G). As an elliptical shape penetrating through the base plate (11) and the base plate (11), a pivot pin (24) for a count roller is inserted and vertically erected from the back side of the base plate (11).

An opposing gap between the idle counter roller (25) fitted to the pivot pin (24) and the coin guiding piece (22) in the fixed state is formed by a disc rotor (R). ) Is defined as the payout port (O) for the coin (C) pushed and conveyed. (W) indicates the opening width of the coin payout slot (O).

The pivot pin (24) for the count roller.
As shown in FIGS. 9 and 10, the count lever (26), which is made of a substantially triangular metal plate, is vertically integrated with a middle part of the count lever (26). 27), it is attached to the back surface of the base plate (11).

On the other hand, the other end of the count lever (26), which is rotatable about the pivot screw (27), is bent in a substantially L-shape facing backward, and is supported by the base plate (11). It is adapted to be received by the back-and-forth cut-out stover piece (28).

(29) is the coin payout slot (O)
A tension coil spring for urging the count roller (25) to a state of advancing to the coin payout port (O) in order to always keep the opening width (W) of the counter roller smaller than the diameter of the coin (C). A spring receiving piece (30) cut and raised rearward from the base plate (11) and a vicinity of a tip end of the count lever (26) are connected to each other and are connected and suspended.

As a result, the coin (C) which is going to pass through the coin payout opening (O) is moved by the tension coil spring (2).
The count roller (25) that has received the urging force of (9) is inevitably contacted, and the number of payouts is reliably counted by the rotating action of the count lever (26).

Further, at (31), the disc rotor (R) rotating (forward) in the clockwise direction (A) once receives the pushed and conveyed coin (C), and goes to the coin payout slot (O). It is a coin inductor for guiding to change the direction, and is attached to and integrated with a back surface of the base plate (11) via a fixing screw (32).

Numeral (33) denotes a coin guide hole formed in a penetrating state between the rotor receiving plate (16) and the base plate (11), through which the coin guide (31) extends from the back side of the base plate (11). ) Has a constant height (h) which always corresponds to the thickness of the coin (C) in the rotor receiving groove (G) of the rotor receiving board (16).
It is kept in the state of being pressed and protruding.

In this respect, in the illustrated embodiment, one metal leaf spring material is bent into a forked shape and its base end is fixed to the base plate (11) by a common fixing screw (32).
And a pair of coin guides (31) having their free ends bent side by side as a pair of coin inductors (31) arranged in parallel from the back side of the base plate (11). Through the rotor receiving board (16)
In the rotor receiving groove (G).

Moreover, as is apparent from the enlarged view of FIG.
The coin receiving surface of each of the coin inductors (31) working during the normal rotation of the disc rotor (R) is flattened as a vertical surface (31a) perpendicular to the groove bottom surface of the rotor receiving groove (G). Contrary to each coin inductor (3
The inclined surface or the arc-shaped surface (31b) that easily sinks into the indentation hole (33) so that the coin (C) pushed forward by the reverse rotation of the disk rotor (R) escapes from the back surface of 1).
It is shaped as.

However, the coin inductor (31) and the hole (33) may be reduced one by one or increased by three or more. Further, according to the configuration of the illustrated embodiment, there is an advantage that the coin inductor (31) can be easily formed from a single metal leaf spring material. However, the coin inductor (31) is provided with a pin separate from the metal leaf spring material. Alternatively, it may be possible to attach the pin to the leaf spring material in a standing state, or to urge the pin to project to the rotor receiving groove (G) by a separate compression coil spring.

The above-mentioned coin transport disc rotor (R)
Is molded from a synthetic resin material as shown in FIGS. That is, in FIGS. 11 to 16 in which the disk rotor (R) is extracted and shown, (34) denotes a disk-shaped disk having a constant thickness corresponding to the rotor receiving groove (G) of the rotor receiving disk (16). The rotor itself,
The central portion of the coin (C) stands upright as a conical convex (35) for calming and falling down to the peripheral portion, and is also inserted from the central portion into the boss escape hole (19). Mounting boss (36) protrudes rearward.

Reference numeral (37) denotes a key groove cut out in the mounting boss (36), and the key groove is engaged with a key (15) passing through the output shaft (14) of the motor (12). The motor (12) and the disk rotor body (34) can rotate integrally. (3
8) indicates a reinforcing rib provided on the back surface of the disk rotor body (34) so as to be interposed between the central portion and the peripheral portion.

A plurality of circular coin receiving holes (39) are formed in the periphery of the disk rotor body (34). C. The aperture is formed in an overall radially symmetric distribution type maintaining D (Pitch Circle Diameter) (d1). Each coin receiving hole (39) corresponds to the size of the coin (C), and its opening edge is a conical receiving surface and is chamfered so as to easily receive the coin (C).

(40) The coin receiving hole (39)
As a positional relationship interposed between adjacent ones, a plurality of back-curvature wings protruding from the disk rotor body (34) integrally with each other so as to protrude from the disc rotor body (34) by a certain height (h) substantially corresponding to the thickness of the coin (C). The coin (C) is pushed and conveyed with the rotation of the disc rotor (R).

That is, as opposed to the rearwardly protruding portion of the rearwardly curved wing (40), the back surface left as a notch in the periphery of the disk rotor main body (34) and the rotor backing disk (16). The upper and lower mutual gaps facing the groove bottom of the rotor receiving groove (G) are defined so as to function as the coin transport path (P). The coin inductor (31) faces this coin transport path (P).

As indicated by the dashed line in FIG. 15, the rear surface of each of the above-mentioned curved back wings (40) has a rear surface in the rotation (forward) traveling direction (A) of the disc rotor (R) in the coin receiving hole (39). ) Concave surface along the opening edge (41r)
And the front surface also extends in a tapered shape having a convex curved surface (41f), and the coin (C) is pushed forward by the convex curved surface (front surface) (41f).

Moreover, the disk rotor body (3
A coin inductor (31) protruding into the above-mentioned rotor receiving groove (G) is provided in the middle of each of the back curved wings (40) curved as a taper of a fixed length from the center to the periphery of 4). Escape slot for coin inductor (4
2) is cut out, so that each of the backwardly curved wings (40) has at least two of a base wing piece (40a) and a tip wing piece (40b), as is clear from the solid line in FIG. Has been split.

In this respect, in the illustrated embodiment, since the coin inductor (31) is projected into the rotor receiving groove (G) as a pair of two in parallel as described above, the coin inductor The relief grooves (42) are notched in the so-called two rows corresponding to these, in the middle of the curve of each backward curved wing (40), but may be cut off as one row or three or more rows.

Reference numerals (43a) and (43b) denote convex corners (front surfaces) (41f) of the respective rearwardly curved wings (40). 40b) are metal reinforcing pins that are implanted and integrated in a dotted distribution at two places with the front corner of the front end, and are the same as the rearward curved wing (40) facing backward from the disk rotor body (34). It protrudes by the height (h).

Then, as the reinforcing pins (43a) and (43b) rotate (forward) in the clockwise direction (A) in the disk rotor (R), the rotating centrifugal force causes the reinforcing pins (43a) and (43b) to move out of the coin receiving hole (39). The coin comes into contact with the coin (C) to be delivered to the coin payout opening (O), and the root side wing piece (40a) and the tip side wing piece (40b) of each of the above-mentioned backward curved wings (40) are worn or their front end angles. Prevent chipping or cracking from corners.

In this case, the reinforcing pins (43a) (43)
The reinforcing pins (43a) are in close contact with the respective front end corners so that b) forms the front end corners of the root side wing piece (40a) and the front end corners of the tip side wing piece (40b). (4
3b) may be implanted and integrated, but as is evident from the illustrated embodiment, the root wings (40
By cutting out both the front end corner of (a) and the front end corner of the tip side wing piece (40b) as a concave curved surface (44), the circle of the concave curved surface (44) and the reinforcing pins (43a) (43b) is cut. It is preferable to secure a certain gap (s) between the facing surfaces.

Then, the reinforcing pins (43a) (43)
The receiving force of the coin (C) due to b) does not directly propagate to the front end corner of the root-side wing piece (40a) or the front end corner of the tip-side wing piece (40b). Chipping and cracking can be more effectively prevented, and the durability of the disc rotor (R) can be increased.

A reinforcing pin (43a) that is implanted and integrated into the corner at the front end of the root-side wing piece (40a) is shown in FIG.
Evident from its overall P.C. C. D (Pitch Ci
rcleDiameter) (d2) is inserted into the coin receiving hole (39) of the disc rotor body (34). C. It is desirable to set the diameter smaller by a certain amount (L) than D (d1).

In this case, since the reinforcing pin (43a) comes into contact with the eccentric position of the coin (C) as soon as possible, it is possible to give the coin (C) an assisting force for sending out from the coin receiving hole (39). Yes, disk rotor (R)
In combination with the rotational centrifugal force, the coin (C) can be more reliably and stably sent out.

The reinforcement pin (43a) implanted in the corner of the front end of the root side wing piece (40a) has a P.I. C. D (d2)
Is the overall P.I. of the reinforcing pin (43b) implanted in the front corner of the tip wing piece (40b). C. D (d3)
Needless to say, the diameter is smaller than that.

Further, the root-side wing piece (40) which forms the convex curved surface (front surface) (41f) of each backward curved wing (40).
It is preferable that a guide step (D) for assisting coin feeding is provided between the front surface of a) and the front surface of the tip-side wing piece (40b).

That is, as suggested by the chain line in FIG. 15, the radius of curvature (r1) for curving the front surface of the root-side wing piece (40a) as a convex curved surface (41f) is large, and the front surface of the tip-side wing piece (40b) is set to be large. The curvature radius (r2) for shaping as a convex curved surface (41f) is changed slightly differently, and the convex curved surface (front surface) (41f) of the tip side wing piece (40b) is rotated (forward rotation) in the disk rotor (R). Due to the relationship with the traveling direction (A), the reinforcement is disposed behind the convex curved surface (front surface) (41f) of the root-side wing piece (40a) and is implanted in the front end corner of the tip-side wing piece (40b). Pin (4
The circumferential surface of 3b) is kept in a state of being inscribed from the rear side with an imaginary line having a large radius of curvature (r1) in the root-side wing piece (40a).

At this time, it is preferable that the center of the reinforcing pin (43a) to be implanted in the corner at the front end of the root-side wing piece (40a) is arranged on an imaginary line having a large radius of curvature (r1).

Then, the disk rotor body (3
The coin (C) in the process of being sent out by receiving the rotational centrifugal force from the coin receiving hole (39) of (4) is located at the front end corner of the root-side wing piece (40a) as suggested by the chain line in FIG. The reinforcing pin (43b) which comes into contact with the reinforcing pin (43a) to be formed quickly and continues from the convex curved surface (front surface) (41f) of the root side wing piece (40a) to the front end corner of the tip side wing piece (40b). Contact with the tip side wing piece (40
As the coin (C) is fed through the convex curved surface (front) (41f) of (b), a so-called stepwise assisting force is applied to the coin (C) in the feeding direction, so that the coin is more reliably and stably sent out. Therefore, there is no possibility of accidental return to the coin receiving hole (39) of the disk rotor body (34).

In any case, each of the reinforcing pins (43a)
As (43b), a stepped cylindrical type as shown in FIG. 16 is adopted, and a pin implantation hole (45) in a stepped form corresponding to this is formed in the disk rotor body (34), By pressing the small-diameter legs (46) of the reinforcing pins (43a) and (43b) into the pin implantation holes (45) from the back side of the disk rotor body (34), the reinforcing pins (43a) and (43b) are also pressed. It is desirable that the large-diameter head (47) protrudes from the back surface of the disk rotor body (34) by the same constant height (h) as the above-mentioned curved back wing (40). Cover each reinforcing pin (43a) (43
This is because the reinforcing pins (43a) and (43b) can be easily and correctly implanted by using the step (b) and the step portion of the implant hole (45) as a positioning stopper.

In the embodiment illustrated in FIGS. 11 to 16, the front corners of the root wings (40a) forming the respective rearwardly curved wings (40) and the front corners of the tip wings (40b) are also formed. The reinforcing pins (43a) and (43b) are implanted and integrated at two locations. However, as shown in the modified embodiment of FIGS. 17 and 18, the reinforcing pins (43b) are provided only at the front corners of the tip wing piece (40b). ) May be implanted, and although not shown, a reinforcing pin (43a) may be implanted only in the corner at the front end of the root side wing piece (40a).

Further, as apparent from the modified embodiment of FIG. 19, when each reinforcing pin (43a) (43b) is implanted, its leg (46) is connected to the disk rotor body (3).
By intentionally projecting a predetermined height (h1) from the surface of 4), the protruding leg (46) can also function as a coin stirring pin.

Then, the reinforcing pins (43a) (4)
3b), the protruding legs (46) are interspersed and distributed between adjacent ones of the coin receiving holes (39) in the disk rotor body (34). Can be efficiently stirred.

Since the other configurations in the modified embodiment of FIGS. 17 to 19 are substantially the same as those of the above-described embodiment of FIGS. 11 to 16, the corresponding reference numerals to FIGS. , And a detailed description thereof will be omitted.

In the hopper type coin payout apparatus having the above-described structure, when the disk rotor (R) is rotated (forward) in the clockwise direction (A) in FIGS. The coins (C) accommodated in the hopper (17) pass through the coin receiving holes (39) of the disk rotor body (34) one by one, and the coin transport path (P) defined on the back side thereof. The coin is conveyed to the coin transport path (P) by a backward curved wing (40) protruding backward from the disk rotor body (34).
Is pushed toward the coin inductor (31).

The coin inductor (31) faces the inside of the coin transport path (P), but is located in the vicinity of the coin payout opening (O) cut out in the rotor receiving groove (G). Therefore, the pushed coin (C) is once received by the coin inductor (31), and is guided to change its direction from the coin transport path (P) to the coin payout slot (O). Coupling with the rotational centrifugal force of the disc rotor (R) acting on the coin (C) results in the coin being paid out from the coin payout opening (O).

The coin (C) which has been subjected to the rotational centrifugal force in the process flows from the coin receiving hole (39) of the disk rotor body (34) along the convex curved surface (front surface) (41f) of the backward curved wing (40). And the reinforcing pins (43a) (4
3b), the paper is gradually fed out to the coin payout opening (O), and there is no possibility that the coin is returned to the coin receiving hole (39) so as to be accidentally involved. This is also effective when the rotor receiving plate (16) is in an inclined installation state, and the coin payout opening (O) is cut off at an obliquely upper position of the rotor receiving groove (G). It can be said that it works.

The coin (C) passing through the coin payout slot (O) necessarily comes into contact with the count roller (25) which urges the opening width (W) to be narrow.
Since the count lever (26) is rotated, the number of coins (C) paid out is accurately counted.

If a coin (C) bites during the pushing and transporting of the coin (C) by the disc rotor (R), the disc rotor (R) is detected by a sensor (not shown). The coin (C) gets over the coin inductor (31) by being reversely driven in the counterclockwise direction. After the bite phenomenon is released, the disc (R) is rotated forward again to thereby rotate the coin (C). Can be continued without any trouble.

[0056]

As described above, according to the present invention, the mounting boss (3) to the rotation driving motor (12) is provided at the center of the disk rotor body (34) formed in a disk shape from a synthetic resin material.
6), a plurality of circular coin receiving holes (39) each of which is also formed as a radially symmetric distribution type in the peripheral portion, respectively, while being adjacent to the coin receiving holes (39) in the disk rotor body (34). From each other,
The rear surface in the rotation traveling direction (A) is the coin receiving hole (3
The tapered back-curved wing (4) having a concave surface (41r) along the opening edge of (9) and a convex surface (41f) on the front surface.
0), and a plurality of the rear curved wings (40) are formed by the coin guide escape groove (42) cut out in the middle of the curve, and the root side wing piece (40a) is formed. ) And a tip-side wing piece (40b) are divided into at least two parts.

As the rotation of the disk rotor body (34) proceeds, metal reinforcing pins (43a) (43b) which come into contact with the coin (C) to be fed out from the coin receiving hole (39) are Each back wing (40)
Root side wing piece (40a) forming the above-mentioned convex curved surface (41f)
Are implanted and integrated into the front corner of the front end corner or / and the front end corner of the tip side wing piece (40b), so that the problems of the prior art described at the outset can be completely improved.

That is, according to the above configuration of the present invention, each of the back curved wings (40) projecting backward and integrally from the disk rotor body (34) is formed by cutting the coin guide escape groove (42). Even if it is divided into at least two of the base-side wing piece (40a) and the tip-side wing piece (40b) due to the chipping, the front-end corner or / and the tip-side wing piece (40b) of the base-side wing piece (40a). The metal reinforcing pins (43a) (43) that come into contact with the coin (C)
Since b) is implanted and integrated, the root-side wing piece (40a) and the tip-side wing piece (40b) are surely prevented from being worn or chipped or cracked from the front corners. This can enhance the durability of the coin transport disc rotor (R).

In particular, metal reinforcing pins (43a) (43)
b), which is implanted and integrated into the disk rotor body (34), so that even if it repeatedly and strongly comes into contact with the coin (C), there is no danger of unauthorized deformation or falling off. Even if the size and number of coin receiving holes (39) distributed in the disk rotor body (34) vary according to the size of the coin (C) to be applied, the same reinforcing pins (43a) (43) are always used.
Using b) again, the disk rotor body (34)
It can be implanted and integrated, and is extremely excellent in compatibility and versatility corresponding to various types of coin transport disc rotors (R).

[Brief description of the drawings]

FIG. 1 is a side view showing an assembled state of a hopper type coin payout apparatus according to the present invention.

FIG. 2 is a partially enlarged sectional view of FIG.

FIG. 3 is a plan view showing the coin storage hopper removed.

FIG. 4 is a plan view corresponding to FIG. 3, showing a cut-away coin transport disk rotor.

FIG. 5 is an enlarged sectional view taken along line 5-5 in FIG. 3;

FIG. 6 is a plan view showing an assembled state of a rotor receiving board and a base plate.

FIG. 7 is a side view of FIG. 6;

FIG. 8 is a cross-sectional view showing a rotor receiving board extracted.

FIG. 9 is a plan view extracting and showing a base plate.

FIG. 10 is a bottom view of FIG. 9;

FIG. 11 is a plan view showing a disk rotor extracted.

FIG. 12 is a side view of FIG. 11;

FIG. 13 is a sectional view taken along line 13-13 of FIG. 11;

FIG. 14 is a bottom view of FIG. 11;

FIG. 15 is a partially enlarged bottom view of FIG. 14;

FIG. 16 is an enlarged sectional view taken along line 16-16 of FIG.

FIG. 17 is a bottom view showing a modified embodiment corresponding to FIG. 14;

18 is a partially enlarged bottom view of FIG. 17;

FIG. 19 is an enlarged sectional view taken along line 19-19 in FIG.

[Explanation of symbols]

 (11) ・ Base plate (12) ・ Motor (16) ・ Rotor receiving board (20) ・ Dust discharge hole (21) ・ Dust discharge slot (25) ・ Count roller (26) ・ Count lever (31) ・ Coin guide Child (31a), vertical surface (31b), arc surface (34), disk rotor body (36), mounting boss (39), coin receiving hole (40), curved back wing (40a), root side wing piece (40b) ), Tip side wing piece (41f), convex curved surface (front surface) (41r), concave curved surface (rear surface) (42), relief groove for coin inductor (43a) (43b), reinforcing pin (44), concave curved surface ( 46) ・ Leg (47) ・ Head (A) ・ Rotating direction (C) ・ Coin (D) ・ Guide step (L) ・ Constant amount (h) ・ Constant height (h1) ・ Constant height ( s) ・ Void (d1) ・ Coin acceptance P. of C. D (d2) ・ P. C. D

Claims (5)

[Claims] 1. A disk rotor body (34) molded from a synthetic resin material in a disk shape has a mounting boss (36) at a center portion thereof for a rotation drive motor (12), and a peripheral portion thereof has an overall boss. A plurality of circular coin receiving holes (39) that open in a radially symmetric distribution type are provided, respectively, while the rotation advancing direction (A) is provided between adjacent ones of the coin receiving holes (39) in the disc rotor body (34). Is a concave surface (41r) along the opening edge of each coin receiving hole (39), and the front surface is a convex surface (4).
1f) A plurality of the tapered rearwardly curved wings (40) are made to protrude backward and integrally, and each of the aforementioned rearwardly curved wings (40) is cut out in the middle of the curve to form a relief groove for a coin inductor. According to (42), at least two of the root-side wing piece (40a) and the tip-side wing piece (40b)
In the coin transport disk rotor of the hopper type coin payout device divided into pieces, coins (C) to be delivered from the coin receiving holes (39) as the rotation of the disk rotor body (34) progresses. Metal reinforcing pin (4
3a) and (43b) are implanted into the front corners of the root wings (40a) or / and the front corners of the tip wings (40b) that form the convex curved surface (41f) of each of the posterior curved wings (40). A coin transport disk rotor of a hopper type coin payout device, which is integrated. 2. A convexly curved surface (41f) of each backward curved wing (40).
And the front wing piece (4a) of the root wing piece (40a)
A guide step (D) for assisting coin feeding in which the latter is retracted by a certain amount from the former between the front and the front of 0b)
2. The coin transporting disk rotor of a hopper type coin payout device according to claim 1, wherein: 3. The front-end corner of the root-side wing piece (40a) and / or
And the front end corner of the tip side wing piece (40b) is a concave curved surface (4
4. A constant gap (s) is secured between the concave curved surface (44) and the circumferential surfaces of the reinforcing pins (43a) (43b) by notching as (4). 2. The coin transport disk rotor of the hopper type coin payout device according to 1. 4. When the reinforcing pin (43a) is implanted and integrated into the corner at the front end of the root-side wing piece (40a), the overall P.I. of the reinforcing pin (43a) is increased. C. D (d2) is distributed over the entire coin receiving hole (39) of the disc rotor body (34). C. 2. The coin transporting disk rotor for a hopper type coin payout device according to claim 1, wherein the diameter is set smaller by a certain amount (L) than D (d1). 5. The reinforcing pin (43a) (43b) is formed as a stepped cylinder having a large diameter head (47) and a small diameter leg (46) from the back side to the disk rotor body (34). By being implanted and integrated in a penetrating state, a function of stirring the coin (C) is given to the leg (46) projecting to the front side of the disk rotor body (34) by a predetermined height (h1). The disc rotor for transporting coins of the hopper type coin payout device according to claim 1.