JP7199062B2 - Disc body guide device - Google Patents

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a disc body guiding device that feeds out disc bodies one by one in a predetermined direction.
More specifically, the present invention relates to a disc body guiding device capable of feeding disc bodies one by one and finally feeding them to a plurality of predetermined positions.
More specifically, the present invention guides a first guide passage to a second guide passage that is rotatable around a support shaft, and adjusts the relative angle between the first guide passage and the second guide passage. It relates to a disc body guide device that can be sent out to a plurality of predetermined positions by changing the outlet position of a second guide passage by changing.
In this specification, a disk body means a circular body having a predetermined thickness, and examples thereof include coins and game medals. Also, the surface or the back surface of the disc does not have a strict meaning. For example, the surface located on the right side in FIG. 1 is described as the back surface, and the surface located on the left side is the front surface.

The following prior art is known as a disc body guiding device.
As a first conventional technique, there is provided a disc dispensing device in which a disc (disk body) ejecting means pushes up a guide passage and ejects the disc from an upper end ejecting port and ejects the disc from an upper first outlet. A disk drop chute branched from the upstream side of the first outlet and provided adjacent to the guide passage and formed in communication so that the disc can be introduced and dropped, and a disc drop chute provided below the drop chute. A disc distribution device for a disc dispensing device, comprising: an outlet through which discs are ejected; and a plurality of protrusions for suppressing the disc falling speed, which are formed on the inner surface of the drop chute so as to come into contact with the falling discs. It is known (see Patent Document 1, for example).
As a second prior art, there is a disc feeding device for feeding discs (disks) stored in a bowl in a bulk state one by one from a feeding port, and a guide path for guiding the discs fed from the feeding port in a row. a ejecting mechanism provided at the tip of the guide passage for ejecting the disc out of the guide passage; and an ejecting port for the disc. A disk guiding device provided with guide passages for selectively ejecting from a plurality of exits at different distances, each having exits at different distances from said discharge opening, and a plurality of disks rolling toward each of these exits and path selection means disposed in the immediate vicinity of the discharge port for selectively sorting and guiding the disk to one of the plurality of paths (see, for example, Patent Document 2).
As a third conventional technique, a cylindrical guide passage formed along a vertical guide base guides the peripheral surfaces of discs (disc bodies) in contact with each other, and is then placed at the top of the guide passage. In a disc body supply device in which a disc body is ejected to a sorting passage by a flipping device and then discharged from a plurality of outlets arranged at different positions, a lateral passage located on an extension of the sorting passage and a guiding passage from the sorting passage. a downward passage extending downward along a lateral passage, a lateral passage forming position forming a side wall guiding the lateral passage in the diverting passage; A disc body feeding device is known in which divided bodies are arranged, and a lower guide rail constituting a lower wall of the laterally directed passage is formed integrally with the distributing body at the laterally directed passage forming position. (See Patent Document 3, for example).
As a fourth conventional technique, a coin (disc body) introduced into a coin guide passage through a coin receiving port has a coin pusher provided so as to protrude into the coin guide passage, and a coin pusher is provided. a coin conveying device in which a coin is conveyed vertically upward by a plurality of rotary discs that rotate around corresponding rotation axes substantially perpendicular to a guide surface that guides the front and back surfaces, and then ejected in a substantially horizontal direction through a coin outlet; A first sorting section introduces a coin into one of the second and third coin drop passages branching below the coin drop passage for guiding the coin ejected from the coin conveying device. A coin transport and payout device is known that includes a coin sorting and payout device that selectively pays out coins from first and second payout openings corresponding to coin drop passages (see, for example, Patent Document 4).

JP 2010-97237 (Figures 1 to 4, paragraph 0006) JP 2007-172272 (Figures 1 to 6, paragraph 0013) JP 2010-186222 (Figures 1 to 16, paragraphs 0008 and 0009) JP 2015-99490 (Figures 1 to 3, paragraphs 0014 and 0068)

In the first prior art, discs sent out one by one by a sending device are pushed up in a line in a guide passage, at the upper end of the guide passage. After being laterally ejected by a ejecting mechanism, it rolls on a communication chute or falls down a communication chute, and is selectively released from different outlets.
In the second prior art, discs delivered one by one by a disc delivery device are pushed up in a line in a guide passage, and at the upper end of the guide passage. After being laterally ejected by the ejection mechanism, the ejection is selectively ejected from different outlets by being sorted by the path selecting means.
In the third prior art, discs fed out one by one by a disc feeding device are lined up and pushed up by a guide device at the upper end of the guide passage. After being pushed out in the lateral direction by a flipping device, the particles are sorted into a lateral passage or a downward passage by a sorting device so as to be selectively released from different outlets.
In the fourth prior art, after a disk body is transported by a coin pusher protruding from a coin guide passage and a plurality of rotating discs, it is ejected laterally by a coin ejection mechanism at the tip of the coin guide passage, and then shaken. It is designed to be selectively discharged from different outlets by guiding to different passages by a minute mechanism.

The disc body guide device is arranged in, for example, a token game machine, and feeds out medals, which are disc bodies, from an exit.
In medal game machines, the exit position of the disk body guide device must be set for each model because the exit for medals differs from model to model. In other words, although the function of sending out medals from a predetermined position is the same, it is necessary to set a disk guiding device for each model of game machine, and although part of the sending device and guiding device can be shared. , and outlet portions must have different specifications, which complicates manufacturing and repair, and is relatively expensive due to the limited number of manufactured products.

A first object, which is a basic object of the present invention, is to provide a disc body guiding device capable of flexibly changing the outlet position of the disc body.
A second secondary object of the present invention is to provide a disc body guiding device capable of flexibly changing the outlet position of the upward passage.
Note that being able to flexibly change is a concept that includes both gradual position changes and arbitrary position changes.

In order to achieve this object, the first invention according to claim 1 is configured as follows.
a first guide passage defined by a first circumferential guide and a second circumferential guide for guiding opposing circumferential surfaces of a disc; A third peripheral guide body arranged on the same side as the first peripheral guide body with respect to the surface, and a fourth peripheral guide body arranged on the same side as the second peripheral guide body. A disc body guide device configured to guide and feed the disc bodies delivered one by one from the disc body delivery device from the first guide channel to the second guide channel in a single row by constructing two guide passages. and
The first peripheral guide body, the second peripheral guide body, the third peripheral guide body, the fourth peripheral guide body, and the first guide passage and the second guide passage are in the same plane. is placed in
A disc body guide device, wherein the second guide passage is rotatable with respect to the first guide passage about a support shaft having an axis perpendicular to the plane and an extension axis. be.

In order to achieve this object, the second invention according to claim 2 is configured as follows.
The first peripheral guide body is arranged below the second peripheral guide body, the third peripheral guide body is arranged below the fourth peripheral guide body, and the first peripheral guide body is arranged below the fourth peripheral guide body. The disc body guide device according to the first invention, characterized in that the extension line of the first guide edge of the guide body is constructed so as to be able to intersect the third guide edge of the third circumferential guide body. be.

In order to achieve this object, the third invention according to claim 3 is configured as follows.
at least a first guide passage defined by a first circumferential guide and a second circumferential guide for guiding opposing circumferential surfaces of a disc; a third peripheral guide body arranged on the same side as the first peripheral guide body with respect to the peripheral surface of the second peripheral guide body; and a fourth peripheral guide body arranged on the same side as the second peripheral guide body. A disc body guide configured to guide and feed the disc bodies delivered one by one from the disc body delivery device from the first guide channel to the second guide channel in a single row. a device,
The first peripheral guide body, the second peripheral guide body, the third peripheral guide body, the fourth peripheral guide body, and the first guide passage and the second guide passage are in the same plane. is placed in
The second guide passage is rotatable with respect to the first guide passage about a support shaft having an axis perpendicular to the plane and an extension axis,
The extension line of the first guide edge of the first circumferential guide body is configured to intersect the third guide edge of the third circumferential guide body,
The disc body guide device is characterized in that an ejection device is arranged at the end of the first guide passage, and the disc body is ejected to the second guide passage by the ejection device.

In order to achieve this object, the fourth invention according to claim 4 is constructed as follows.
In a state where the extension line of the first guide edge of the first peripheral guide body intersects the third guide edge of the third peripheral guide body, the first peripheral guide tip of the first peripheral guide body rotation of the second guide passage is restricted at a position where the distance between the portion and the base end of the third peripheral guide body facing the third peripheral guide body is less than the diameter of the disk body. The disk guide device according to the second aspect of the invention is characterized in that a rotation amount regulating device is provided.

In order to achieve this object, the fifth invention according to claim 5 is configured as follows.
At least, the disc bodies are moved one by one in a row while being guided to the first guide passage, and the second guide arranged downstream of the first guide passage from the end of the first guide passage by an ejection device A disc body guide device configured to be ejected into a passage,
The second guide passage is arranged in the same plane as the first guide passage and is rotatable about a support shaft having one axis,
An extension axis of the axis is orthogonal to the plane, extends from the first guide passage, and traverses the second guide passage after the disc body has been ejected by the ejection device. It is a disc body guiding device characterized by being configured as follows.

In order to achieve this object, the sixth invention according to claim 6 is configured as follows.
a disc body feeding device for feeding the disc bodies one by one;
a first guide passage device that constitutes a first guide passage that guides upward in a line the discs delivered by the disc delivery device;
an ejection device for ejecting the guided disc at the end of the first guide passage;
A disc body guide device constituted by a second guide passage device constituting a second guide passage for guiding the ejected disc body in a predetermined direction,
The second guide passage device is rotatably connected to the first guide passage device by a support shaft having one axis in the same plane as the first guide passage and the second guide passage. ,
An extension axis of the axis is orthogonal to the plane, extends from the first guide passage, and traverses the second guide passage after the disc body has been ejected by the ejection device. It is a disc body guiding device characterized by being configured as follows.

In order to achieve this object, the seventh invention according to claim 7 is constructed as follows.
The disc body guide device according to any one of the first to sixth inventions is characterized by having a holding device that holds the second guide passage at a predetermined angle with respect to the first guide passage.

In order to achieve this object, the eighth invention according to claim 8 is configured as follows.
The disc body guide device according to any one of the first to seventh inventions is characterized in that the first guide passage changes its direction obliquely upward after standing upright.

In order to achieve this object, the ninth invention according to claim 9 is configured as follows.
The disk body guide device according to the eighth invention, wherein the second guide passage is rotatable upward from the extension of the first guide passage and downward from the extension. .

In order to achieve this object, the tenth invention according to claim 10 is constructed as follows.
The first guide passage device includes a first surface guide body that guides the surface of the disk body, a first back surface guide body that guides the back surface of the disk body, and the first surface that guides the peripheral surface of the disk body. including a first peripheral guide body and a second peripheral guide body arranged in parallel with each other at a predetermined distance between the guide body and the first back guide body;
The support shaft is integrated with the first guide passage device,
A bearing is integrated with the second guide passage device,
The disk according to the sixth aspect of the invention, wherein the bearing is rotatably combined with the support shaft so that the second guide passage device is rotatably combined with the first guide passage device. It is a body guide device.

In order to achieve this object, the eleventh invention according to claim 11 is configured as follows.
The support shaft includes a second support shaft fixed to the first front guide body and a first support shaft fixed to the first back guide body, wherein the first support shaft and the second support shaft are aligned with the plane surface. is arranged on the same axis that the extension axis is orthogonal to
The disc body according to the tenth invention, wherein the first bearing and the second bearing integrated with the second guide passage device are rotatably combined with the first support shaft and the second support shaft. It is a guide device.

In order to achieve this object, the twelfth invention according to claim 12 is constructed as follows.
A tenth aspect of the present invention is the disc body guide device, wherein the ejection device is attached to the first surface guide member.

In order to achieve this object, the thirteenth invention according to claim 13 is constructed as follows.
The second guide passage device includes a second surface guide body that guides the surface of the disk body, a second back surface guide body that guides the back surface of the disk body, and the second surface that guides the peripheral surface of the disk body. including a third peripheral guide body and a fourth peripheral guide body arranged in parallel with a predetermined distance between the guide body and the second back guide body,
The distal end portion of the first peripheral guide member and the base end portion of the third peripheral guide member of the third peripheral guide member constitute a first rotation amount restricting device, and the second peripheral guide member A tenth aspect of the present invention, characterized in that the distal end portion of the second peripheral surface guide of the surface guide and the base end portion of the fourth peripheral surface guide of the fourth peripheral surface guide constitute a second rotation amount regulating device. It is a disc body guiding device.

In order to achieve this object, the fourteenth invention according to claim 14 is constructed as follows.
The bearing includes a first bearing integrated with the second back guide,
including a second bearing integrated with the second surface guide;
The disk body guide device according to the eleventh invention, wherein the first bearing is rotatably supported by the first spindle, and the second bearing is rotatably supported by the second spindle.

According to the first invention, the first guide passage is defined by the first peripheral guide body and the second peripheral guide body.
A second guide passage is defined by the third peripheral guide and the fourth peripheral guide.
Since the first guide passage and the second guide passage are located in the same plane, movement from the first guide passage to the second guide passage can be performed without any obstacles.
The extension of the axis of the support shaft of the second guide passage is rotatable with respect to the first guide passage about an axis perpendicular to the plane.
This allows the disc body to be guided from the second guide passage to the first guide passage.
Therefore, the relative position of the second guide passage with respect to the first guide passage can be set by rotating the second guide passage to a stepwise position or an arbitrary position about the support shaft, so that the exit position of the disk can be flexibly changed. can achieve the first objective.

According to the second invention, since the basic configuration is common to the first invention, the first object can be achieved like the first invention. Furthermore, according to the second invention, the first peripheral guide body is arranged below the second peripheral guide body, and the third peripheral guide body is arranged below the fourth peripheral guide body. , and the extension line of the disc body guide portion of the first circumferential guide body can intersect the disc body guide portion of the third circumferential guide body. With this configuration, the disc body is conveyed in an upright state (a state in which the front and back surfaces of the disc body are approximately upright) while rolling on the first and third peripheral guide bodies positioned below. . A state in which the extension line of the disc body guide portion of the first circumferential guide body intersects the disc body guide portion of the third circumferential guide body is a state in which the third circumferential guide body is raised forward. In other words, the outlet of the second guide passage can be defined while the second guide passage constitutes the upward passage. As a result, the disc body can be guided upward and sent out from the exit set in stages or at an arbitrary position, and there is an advantage that the exit position of the disc body can be flexibly changed.

According to the third invention, since the first guide passage and the second guide passage are positioned on the same plane, the first guide passage and the second guide passage are positioned on the same plane, and the first guide passage Movement from the passage to the second guide passage can be performed without any obstacles.
The second guide passage is configured such that the extension of the axis of the support shaft with respect to the first guide passage is orthogonal to the plane and crosses the second guide passage on the extension of the first guide passage. there is
A ejecting device is arranged at the end of the first guide passage, and the disk body conveyed through the first guiding passage is ejected from the first guiding passage to the second guiding passage by the ejecting device.
As a result, the disc body can be vigorously delivered to the upward second guide passage and ejected from the outlet, so there is an advantage that the second object can be achieved.

According to the fourth invention, since the basic configuration is common to the second invention, the first object can be achieved like the second invention. Furthermore, according to the fourth invention, in a state in which the extension line of the disk body guide portion of the first circumferential guide body intersects the disk body guide portion of the third circumferential guide body, the first circumferential guide body A rotation amount restricting device is provided for restricting the rotation of the second guide passage at a position where the distance between the distal end and the facing distal end of the third circumferential guide body is less than the diameter of the disk body. As a result, the distance between the ends of the first and third peripheral surface guides that guide the lower peripheral surface of the disc does not exceed the diameter of the disc. In other words, there is an advantage that the disk body is not likely to leave the guide passages during the process of moving from the first guide passages to the second guide passages.

In the fifth aspect of the invention, since the first guide passage and the second guide passage are positioned on the same plane, the first guide passage and the second guide passage are positioned on one plane, and from the first guide passage Movement to the second guide passage can be performed without any obstacles. In the second guide passage, the extension of the axis of the support shaft is perpendicular to the plane of the first guide passage, and the second guide passage is an extension of the first guide passage. It is configured to traverse the second guide passage after the second guide passage. As a result, when the second guide passage is rotated around the support shaft, the second guide passage is positioned on the extension of the first guide passage, so that the disc body can be reliably guided to the second guide passage. can be done.
The disc bodies are guided in a line through the first guide passage and conveyed, and are ejected toward the second guide passage by an ejection device at the end of the first guide passage.
As a result, the disk can be vigorously sent out from the second guide passage, so there is an advantage that it can be used for the presentation of the disk. Therefore, the first object and the second object can be achieved.

According to the sixth invention, since the first guide passage formed by the first guide passage device and the second guide passage formed by the second guide passage device are positioned on the same plane, Movement from the first guide passage to the second guide passage can be performed without any obstacles.
The second guide passage is configured such that the extension of the axis of the support shaft with respect to the first guide passage is orthogonal to the plane and crosses the second guide passage on the extension of the first guide passage. there is
As a result, even when the second guide passage is rotated about the support shaft with respect to the first guide passage, the first guide passage and the second guide passage are communicated with each other by a passage having a diameter equal to or larger than the diameter of the disk body. Therefore, movement from the first guide passage to the second guide passage can be performed without any obstacles.
A ejecting device is arranged at the end of the first guide passage, and the disk body conveyed through the first guiding passage is ejected from the first guiding passage to the second guiding passage by the ejecting device.
As a result, the disk can be vigorously sent out from the second guide passage, so that it can be used for performance of the disk. Therefore, the first object and the second object can be achieved.

According to the seventh invention, since the main configuration is the same as the first to sixth inventions, it has the same effect as the first invention.
Furthermore, the seventh invention is a configuration in which a holding device is provided for holding the second guide passage at a predetermined angle with respect to the first guide passage. As a result, since the first guide passage and the second guide passage do not move relative to each other, there is an advantage that the disc body can be sent out stably from the outlet of the second guide passage.

According to the eighth invention, since the main configuration is the same as the first to seventh inventions, it has the same effect as the first invention.
Further, according to the eighth invention, the direction of the first guide passage is changed obliquely upward after being erected. Since the second guide passage is arranged on the downstream side of the first guide passage extending obliquely upward, it is possible to reduce the angle change of the second guide passage with respect to the first guide passage, and to smoothly guide the disk. There are benefits to be done.

According to the ninth invention, since the main configuration is the same as that of the eighth invention, it has the same effects as those of the first invention.
Furthermore, in a ninth aspect of the invention, the second guide passage is rotatable upward from the extension line of the first guide passage and downward from the extension line. This configuration has the advantage that the exit position of the second guide passage can be set at a position above or below the extension line of the first guide passage.

According to the tenth invention, since the main configuration is the same as that of the first invention, the same object as that of the first invention can be achieved.
Furthermore, in a tenth aspect of the invention, the first guide passage device comprises: a first surface guide body for guiding the surface of the disk body; a first back surface guide body for guiding the back surface of the disk body; and a peripheral surface of the disk body. including the first peripheral guide body and the second peripheral guide body arranged in parallel at a predetermined distance between the first front guide body and the first back guide body, which guide the
The support shaft is integrated with the first guide passage device,
A bearing is integrated with the second guide passage device,
By rotatably combining the bearing with the support shaft, the second guide passage device is rotatably combined with the first guide passage device.
With this configuration, the bearing integrated with the second guide passage device is rotatably combined with the support shaft integrated with the first guide passage device. As a result, there is an advantage that the assembly of the second guide passage device to the first guide passage device is easy.

According to the eleventh invention, since the main configuration is the same as that of the tenth invention, the same object as that of the first invention can be achieved.
Furthermore, in an eleventh aspect of the invention, the support shaft includes a second support shaft fixed to the first front guide body and a first support shaft fixed to the first back guide body, and the first support shaft and The second support shaft is arranged on the same axis orthogonal to the plane,
A bearing integrated with the first guide passage device is rotatably combined with the first support shaft and the second support shaft.
As a result, since the support shaft is supported by a plurality of bearings, there is an advantage that the durability is improved.

According to the twelfth invention, since the main configuration is the same as that of the tenth invention, the same object as that of the first invention can be achieved.
Furthermore, in a twelfth aspect of the invention, the ejection device is attached to the first surface guide body. As a result, even if the position of the second guide passage device with respect to the first guide passage device is changed, the position of the ejection device with respect to the first guide passage is not changed, so there is an advantage of easy handling.

According to the thirteenth invention, since the main configuration is the same as that of the tenth invention, the same object as that of the first invention can be achieved.
Further, in a thirteenth aspect of the invention, the second guide passage device comprises a second surface guide body for guiding the surface of the disk body, a second back surface guide body for guiding the back surface of the disk body, and a peripheral surface of the disk body. including a third peripheral guide body and a fourth peripheral guide body arranged in parallel at a predetermined distance between the second front guide body and the second back guide body,
The tip of the first peripheral guide body and the tip of the third peripheral guide body and the tip of the second peripheral guide body and the tip of the fourth peripheral guide body are connected to the first rotation amount regulating device and the third guide body. It constitutes a double rotation amount control device.
With this configuration, the tip of the first peripheral guide body and the tip of the third peripheral guide body and the tip of the second peripheral guide body and the tip of the fourth peripheral guide body are the first rotation amount restricting device, and the second rotation amount regulating device, the rotation of the second guide passage with respect to the first guide passage is restricted by the first rotation amount regulating device and the second rotation amount regulating device. There is the advantage that it is possible to prevent in advance the rotation that would cause inconvenience in the movement of the body from the first guide passage to the second guide passage, thereby preventing malfunction due to inadequate adjustment.

According to the fourteenth invention, since the main configuration is the same as that of the eleventh invention, the same object as that of the first invention can be achieved.
Furthermore, in a fourteenth aspect of the invention, the bearing includes a first bearing integrated with the second back guide body,
including a second bearing integrated with the second surface guide;
The first bearing is rotatably supported by the first spindle, and the second bearing is rotatably supported by the second spindle.
With this configuration, the second guide passage device is attached to the first guide passage device in a double-supported structure, so there is an advantage that the durability is improved.

FIG. 1 is a perspective view of a disc-body guide device according to a first embodiment of the present invention, in which the second guide passage faces downward with respect to the first guide passage. FIG. 2 is a perspective view of the disc body guiding device of the first embodiment according to the present invention, in which the second guide passage faces upward with respect to the first guide passage. FIG. 3 is a perspective view of a state in which the second guide passage of Example 1 according to the present invention is extended from the first guide passage. FIG. 4 is an exploded perspective view of the disc body guiding device of the first embodiment according to the present invention. FIG. 5 shows the first guide passage device of the disc body guide device according to the first embodiment of the present invention, where (A) is an exploded perspective view, (B) is a front view, and (C) is a rear view. FIG. 6 is an exploded perspective view of the second guide passage device of the disc body guiding device of the first embodiment according to the present invention. FIG. 7 is a perspective view of the second guide passage device of the disc body guide device of Embodiment 1 according to the present invention, (A) is a perspective view from above the front, (B) is a perspective view from above the back, ( C) is an enlarged perspective view of the connecting member. FIG. 8 is a cross-sectional view of a connecting portion of the first guide passage device and the second guide passage device of the disc body guiding device of the first embodiment according to the present invention. FIG. 9 is an enlarged explanatory view of the connecting portion of the first guide passage device and the second guide passage device of the disk guide device of the first embodiment according to the present invention, and (A) is the maximum clock of the second guide passage device. Rotation position, (B) is an enlarged explanatory view of the maximum counterclockwise rotation position of the second guide passage device. FIG. 10 is a perspective view of the ejection device of the disc body guiding device of the first embodiment according to the present invention. 11A and 11B are explanatory diagrams of the disc body guide device according to the first embodiment of the present invention, where (A) is the position where the second guide passage device is turned most counterclockwise, and (B) is the first guide passage. and the second guide passage are in a straight line, and (C) is an explanatory view of the most clockwise rotated position.

A disc body guiding device according to the present invention includes:
a first guide passage defined by a first circumferential guide and a second circumferential guide for guiding opposing circumferential surfaces of a disc; A third peripheral guide body arranged on the same side as the first peripheral guide body with respect to the surface, and a fourth peripheral guide body arranged on the same side as the second peripheral guide body. A disc body guide device configured to guide and feed the disc bodies delivered one by one from the disc body delivery device from the first guide channel to the second guide channel in a single row by constructing two guide passages. and
The first peripheral guide body, the second peripheral guide body, the third peripheral guide body, the fourth peripheral guide body, and the first guide passage and the second guide passage are in the same plane. is placed in
It is preferable that the second guide passage is rotatable with respect to the first guide passage about a support shaft having an axis perpendicular to the plane and an extension axis.
again,
The first peripheral guide body is arranged below the second peripheral guide body, the third peripheral guide body is arranged below the fourth peripheral guide body, and the first peripheral guide body is arranged below the fourth peripheral guide body. It is preferable that an extension line of the first guide edge of the guide body can intersect the third guide edge of the third circumferential guide body.
Furthermore,
at least a first guide passage defined by a first circumferential guide and a second circumferential guide for guiding opposing circumferential surfaces of a disc; a third peripheral guide body arranged on the same side as the first peripheral guide body with respect to the peripheral surface of the second peripheral guide body; and a fourth peripheral guide body arranged on the same side as the second peripheral guide body. A disc body guide configured to guide and feed the disc bodies delivered one by one from the disc body delivery device from the first guide channel to the second guide channel in a single row. a device,
The first peripheral guide body, the second peripheral guide body, the third peripheral guide body, the fourth peripheral guide body, and the first guide passage and the second guide passage are in the same plane. is placed in
The second guide passage is rotatable with respect to the first guide passage about a support shaft having an axis perpendicular to the plane and an extension axis,
The extension line of the first guide edge of the first circumferential guide body is configured to intersect the third guide edge of the third circumferential guide body,
It is preferable that the disc body guide device is characterized in that an ejection device is disposed at the end of the first guide passage, and the disc body is ejected to the second guide passage by the ejection device.
Furthermore,
In a state where the extension line of the first guide edge of the first peripheral guide body intersects the third guide edge of the third peripheral guide body, the first peripheral guide tip of the first peripheral guide body rotation of the second guide passage is restricted at a position where the distance between the portion and the base end of the third peripheral guide body facing the third peripheral guide body is less than the diameter of the disk body. It is preferable to provide a rotation amount regulating device.
again,
At least, the disc bodies are moved one by one in a row while being guided to the first guide passage, and the second guide arranged downstream of the first guide passage from the end of the first guide passage by an ejection device A disc body guide device configured to be ejected into a passage,
The second guide passage is arranged in the same plane as the first guide passage and is rotatable about a support shaft having one axis,
An extension axis of the axis is orthogonal to the plane, extends from the first guide passage, and traverses the second guide passage after the disc body has been ejected by the ejection device. It is preferably configured as follows.
moreover,
a disc body feeding device for feeding the disc bodies one by one;
a first guide passage device that constitutes a first guide passage that guides upward in a line the discs delivered by the disc delivery device;
an ejection device for ejecting the guided disc at the end of the first guide passage;
A disc body guide device constituted by a second guide passage device constituting a second guide passage for guiding the ejected disc body in a predetermined direction,
The second guide passage device is rotatably connected to the first guide passage device by a support shaft having one axis in the same plane as the first guide passage and the second guide passage. ,
An extension axis of the axis is orthogonal to the plane, extends from the first guide passage, and traverses the second guide passage after the disc body has been ejected by the ejection device. It is preferable that the disc body guide device is characterized by being configured as follows.
Furthermore,
It is preferable that the disc body guiding device has a holding device that holds the second guiding passage at a predetermined angle with respect to the first guiding passage.
again,
8. It is preferable that the first guide passage is turned obliquely upward after being erected.
moreover,
It is preferable that the second guide passage is rotatable upward from the extension of the first guide passage and downward from the extension of the first guide passage.
Furthermore,
The first guide passage device includes a first surface guide body that guides the surface of the disk body, a first back surface guide body that guides the back surface of the disk body, and the first surface that guides the peripheral surface of the disk body. including a first peripheral guide body and a second peripheral guide body arranged in parallel with each other at a predetermined distance between the guide body and the first back guide body;
The support shaft is integrated with the first guide passage device,
A bearing is integrated with the second guide passage device,
The disc body guide device is characterized in that the bearing is rotatably combined with the support shaft so that the second guide passage device is rotatably combined with the first guide passage device. is preferred.
again,
The support shaft includes a second support shaft fixed to the first front guide body and a first support shaft fixed to the first back guide body, wherein the first support shaft and the second support shaft are aligned with the plane surface. is arranged on the same axis that the extension axis is orthogonal to
A disc body guide device characterized in that the first bearing and the second bearing integrated with the second guide passage device are rotatably combined with the first support shaft and the second support shaft. is preferred.
moreover,
It is preferable that the ejecting device is a disc body guide device that is attached to the first surface guide body.
Furthermore,
The second guide passage device includes a second surface guide body that guides the surface of the disk body, a second back surface guide body that guides the back surface of the disk body, and the second surface that guides the peripheral surface of the disk body. including a third peripheral guide body and a fourth peripheral guide body arranged in parallel with a predetermined distance between the guide body and the second back guide body,
The distal end portion of the first peripheral guide member and the base end portion of the third peripheral guide member of the third peripheral guide member constitute a first rotation amount restricting device, and the second peripheral guide member A disc body guide device characterized in that a tip portion of a second circumferential guide member of a surface guide member and a base end portion of a fourth circumferential guide member of the fourth circumferential guide member constitute a second rotation amount regulating device. Preferably.
again,
The bearing includes a first bearing integrated with the second back guide,
including a second bearing integrated with the second surface guide;
Preferably, the first bearing is rotatably supported by the first spindle, and the second bearing is rotatably supported by the second spindle.

An outline of a disc body guiding device 100 according to a first embodiment of the present invention will be described with reference to FIG.
The disc body guide device 100 of the first embodiment guides the disc body 102 from the first guide passage device 104 to the second guide passage device 106, sends it out from the outlet 108 of the second guide passage device 106, and guides the disc body 102 to the second guide passage device 106. has a function of changing the position of the outlet 108 of the second guide passage device 106 by rotating the first guide passage device 104 about the support shaft 112 as a fulcrum. The disc body guide device 100 in the first embodiment includes a support shaft 112, a disc body delivery device 114, a first guide passage 116, a second guide passage 118, and an ejection device 122. As shown in FIG.

First, the disc delivery device 114 will be described with reference to FIG.
The disc body delivery device 114 has a function of sequentially delivering a large number of disc bodies to the first guide passage 116 one by one. In the first embodiment, the disc delivery device 114 includes a rotating disc (not shown) that is inclined with respect to the horizontal line, and projections (not shown) that protrude from the top surface or the back surface of the rotating disc. A known disc delivery device is used which separates the discs 102 one by one and delivers them from a delivery port 124 formed in the circumferential direction of the rotating disc at a predetermined position to the first guide passage 116. (For example, see Japanese Patent No. 4072749 and Japanese Unexamined Patent Publication No. 2002-32824).

Next, the first guide passage device 104 will be described mainly with reference to FIG.
The first guide passage device 104 defines a first guide passage 116 and has the function of guiding upward the discs 102 delivered one by one from the disc delivery device 114 . In the first embodiment, the first guide passage device 104 is composed of at least a first guide passage device vertical portion 104V and a first guide passage device turning portion 104T. The first guide passage device upright portion 104V has a function of guiding the discs 102 delivered one by one from the delivery port 124 of the disc delivery device 114 vertically upward. The first guide passage device turning portion 104T has a function of guiding the disc body 102 guided by the first guide passage device vertical portion 104V obliquely upward, in this embodiment, obliquely upward and rightward in a front view.
The first guide passage device upright portion 104V and the first guide passage device turning portion 104T are composed of a first rear guide body 126, a first peripheral guide body 128, a second peripheral guide body 132, and a first front guide body 134. The first guide passage 116, which is a thin plate-shaped space, is configured by the .

Next, the first back guide body 126 will be described mainly with reference to FIGS. 4 and 5. FIG.
The first rear surface guide body 126 has a function of guiding the rear surfaces of the discs 102 delivered one by one from the disc delivery device 114 . In Embodiment 1, the first back guide body 126 is formed of a thin plate elongated in the traveling direction of the disk body 102 . The first back guide body 126 is an elongated flat plate that vertically stands at the first guide passage device vertical portion 104V, and extends in the vertical direction for a predetermined length at the first guide passage device turning portion 104T. It is composed of a dogleg-shaped flat plate that is curved to the right with a predetermined curvature after being formed, and then extends obliquely upward for a predetermined length. The first back guide body 126 is made of metal, resin, or the like having wear resistance against sliding against the disk body 102 . As shown in FIG. 9, the first back guide body front end portion 126E on the second back guide body 136 side is formed into a semicircular convex shape with a first radius r1 centered on the axis SL of the support shaft 112. .

The first peripheral surface guide body 128 has a function of guiding one peripheral surface of the disk body 102, and is one end surface of the first back surface guide body 126 in the longitudinal direction, which is the right side in the front view in the first embodiment. It is fixed at a position corresponding to the end or lower end. As shown in FIG. 5(A), the first peripheral surface guide 128 is an elongated flat bar-like body having a predetermined thickness and is formed in the same shape as the first back surface guide 126. As shown in FIG. The first circumferential guide body 128 is similarly made of wear-resistant metal, resin, or the like.

The second peripheral surface guide body 132 has a function of guiding the other peripheral surface of the disk body 102, and is one end surface of the first back surface guide body 126 in the longitudinal direction, which is the left side in the front view in the first embodiment. It is fixed at a position corresponding to the edge or the upper edge. In other words, the second circumferential guide 132 is spaced from the first circumferential guide 128 by a distance slightly greater than the diameter of the disc body 102 and arranged parallel to the first circumferential guide 128. Also, it is an elongated flat rod-shaped body having a predetermined thickness. The second peripheral guide body 132 and the first peripheral guide body 128 have the same thickness, and are slightly thicker than the disk body 102 . The second peripheral guide body 132 is similarly made of metal, resin, or the like having wear resistance.

The first surface guide body 134 has the function of guiding the surface of the disk body 102 .
In the first embodiment, the first surface guide body 134 is composed of a thin plate elongated in the traveling direction of the disk body 102 . The first surface guide body 134 is an elongated flat plate that vertically stands at the first guide passage device vertical portion 104V, and extends in the vertical direction for a predetermined length at the first guide passage device turning portion 104T. It is composed of a dogleg-shaped flat plate that is curved to the right with a predetermined curvature after being formed, and then extends obliquely upward for a predetermined length. The first surface guide body 134 is applied to the first peripheral surface guide body 128 and the second peripheral surface guide body 132 from the front side, and is integrated with the first back surface guide body 126 . In other words, the first surface guide body 134 has substantially the same shape as the first back surface guide body 126, and the thickness of the first peripheral surface guide body 128 and the second peripheral surface guide body 132 is the distance between the thickness of the first surface guide body and the first back surface guide body. It is a flat plate arranged parallel to the guide body 126 . The first surface guide body 134 is made of metal, resin, or the like having wear resistance. The first surface guide body tip portion 134E on the second surface guide body 144 side is formed in a semicircular convex shape with a first radius r1 centered on the axis SL of the support shaft 112. As shown in FIG. The first rear surface guide body tip portion 126E and the first surface guide body tip portion 134E are formed so as to overlap each other when viewed from the front.

Therefore, the first guide passage 116 has a first width W1 (FIG. 4) slightly larger than the diameter of the disk body 102, and a thickness T0 (FIG. 8) of the first peripheral guide 128 and the second peripheral guide. It is a flat space with the same vertical length as the 132 interval. In the first embodiment, the first guide passage 116 extends obliquely upward for a predetermined length after being curved with a predetermined curvature at the upper end. With this configuration, the disc bodies 102 delivered one by one from the delivery port 124 of the disc body delivery device 114 to the first guide passage 116 have the first back guide body 126 on the back surface of the disc body 102 and the first surface guide body on the front surface. Body 134, one peripheral surface is guided by the first guide edge 1281 of the first peripheral guide body 128, and the other peripheral surface is guided by the second guide edge 1321 of the second peripheral guide body 132, By pushing the peripheral surface of the rear end of the disc body 102 with the peripheral surface of the leading end of the disc body 102 on the rear side, the disc bodies 102 are conveyed in a line toward the second guide passage 118 described later. The first guide passage 116 is a passage of the disk body 102 until it is ejected by an ejection device 122, which will be described later, particularly a range immediately before the ejection device 122. In the first embodiment, at least it has a predetermined curvature. It shall refer to the obliquely upward passage located after being curved. Therefore, the first rear guide 126, the first front guide 134, the first peripheral guide 128, and the second peripheral guide 132 have a thickness T and are perpendicular to the horizontal line, as shown in FIG. located in the plane P on which it stands. In other words, the first guide passage 116 surrounded by the first rear guide 126, the first front guide 134, the first peripheral guide 128, and the second peripheral guide 132 lies within the plane P. It is a flat, elongated space.

Next, the second guide passage device 106 will be described mainly with reference to FIGS. 4 and 6. FIG.
The second guide passage device 106 is rotatably attached to the first guide passage device 104 about a support shaft 112 and guides the disk body 102 sent out from the first guide passage 116 so as to guide the first guide passage device 104. It has the function of delivering from the outlet 108 of the second guide channel device 106 located at a predetermined angle to the. In the first embodiment, the second guide passage device 106 is rotated by at least the support shaft 112 to the first guide passage device 104, more specifically, the tip portion of the first guide passage device turning portion 104T within a predetermined angle range. It is configured in a hollow thin plate structure that is movably supported.
The second guide passage device 106 is formed by a second back surface guide member 136, a third peripheral surface guide member 138, a fourth peripheral surface guide member 142, and a second surface guide member 144 to form a second guide passage which is a thin plate-like space. 118 are configured. In Embodiment 1, an outlet passage 156, which will be described later, also functions as part of the second guide passage 118, but the outlet passage 156 can be omitted if necessary.

The second back surface guide body 136 has a function of guiding the back surface of the disc body 102 that is sent out one by one from the first guide passage 116 . In the present embodiment 1, the second back guide body 136 is composed of a thin plate that is long in the traveling direction of the disk body 102 and positioned on the same plane as the first back guide body 126 of the first guide passage device turning portion 104T. ing. The second back guide body 136 is made of metal, resin, or the like having wear resistance against sliding against the disk body 102 . As shown in FIG. 9, the second back guide body base end portion 136B of the second back guide body 136 on the first back guide body 126 side has a semicircular shape with a second radius r2 around the axis SL of the support shaft 112. is formed in a concave shape. Needless to say, the second radius r2 is formed to be slightly larger than the first radius r1. It is configured so as not to get caught on the step between them.

The third peripheral surface guide body 138 has a function of guiding one peripheral surface of the disk body 102, and is one end surface of the second back surface guide body 136 in the longitudinal direction. It is fixed at a position corresponding to the side end (right end), and as shown in FIG. 9(B), it also takes a position that intersects the extension line EL of the first guide edge 1281 of the first circumferential guide body 128. configured to be able to As shown in FIG. 6, the third peripheral guide body 138 is an elongated flat plate rod-shaped body having a predetermined thickness T and is made of metal, resin, or the like having wear resistance. The third peripheral guide 138 is arranged at least in the same plane P as the first peripheral guide 128 of the first guide passage device turning portion 104T.

The fourth peripheral surface guide body 142 has a function of guiding the other peripheral surface of the disk body 102, and is one end surface of the second back surface guide body 136 in the longitudinal direction, which is the upper side in the front view in the first embodiment. It is fixed at a position corresponding to the end (left end). In other words, the fourth circumferential guide 142 can be positioned on the extension of the second circumferential guide 132 and is slightly larger than the diameter of the disk 102 with respect to the third circumferential guide 138. It is an elongated flat plate rod-shaped body having a predetermined thickness T, which is spaced apart by a large second width W2 (FIG. 4) and arranged parallel to the third circumferential guide body 138. The fourth peripheral guide body 142 and the third peripheral guide body 138 have the same thickness, and are made of metal, resin, or the like having wear resistance. Therefore, the thickness T of the first peripheral guide body 128, the second peripheral guide body 132, the third peripheral guide body 138, and the fourth peripheral guide body 142 are configured to be the same. In other words, at least the first peripheral guide body 128, the second peripheral guide body 132, the third peripheral guide body 138, and the fourth peripheral guide body 142 in the first guide passage device turning portion 104T are identical. placed in the plane P. Further in other words, the first guide passage 116 and the second guide passage 118 are arranged in the plane P.

The second surface guide body 144 has the function of guiding the surface of the disk body 102 .
In the first embodiment, the second surface guide body 144 is composed of a thin plate elongated in the traveling direction of the disk body 102 . The second surface guide body 144 is composed of a flat plate extending obliquely upward with a predetermined length. The second surface guide body 144 is applied to the third peripheral surface guide body 138 and the fourth peripheral surface guide body 142 from the front side, and is integrated with the second back surface guide body 136 . In other words, the second surface guide body 144 has substantially the same shape as the second back surface guide body 136, and is spaced by the thickness T between the third peripheral surface guide body 138 and the fourth peripheral surface guide body 142. It is a flat plate arranged parallel to the back guide body 136 and is made of metal, resin, or the like having wear resistance. The second surface guide 144 is arranged in the same plane as the first surface guide 134 of the first guide passage device turning portion 104T. A third peripheral surface guide tip portion 138T following a third guide edge 138E at the tip portion of the third peripheral surface guide portion 138 is formed on an inclined surface 138S that slopes forward toward the outlet 108 side. A second surface guide body base end portion 144B of the second surface guide body 144 on the side of the first surface guide body 134 is formed into a semicircular concave shape with a second radius r2 around the axis SL of the support shaft 112. . The second back guide body base end portion 136B and the second front guide body base end portion 144B are formed so as to overlap when viewed from the front. Specifically, as shown in FIG. 9, the third peripheral guide body 138 is composed of a first third peripheral guide body 1381 and a second third peripheral guide body 1382 to form a single thin plate. is configured to In other words, the second guide passage 118 is a thin plate surrounded by at least the second back guide 136, the second front guide 144, the third peripheral guide 138, and the fourth peripheral guide 142. space, which lies in the plane P.

Therefore, the second guide passage 118 has a second width W2 that is slightly larger than the diameter of the disk body 102, and a thickness T that is the same as the thickness T of the third peripheral guide 138 and the fourth peripheral guide 142. It is a flat space with a horizontal orientation and a flat plate shape. With this configuration, the discs 102 are sent out one by one from the delivery port 124 of the disc body delivery device 114 and guided by the first guide passage 116, and are delivered to the second guide passage 118, and the back surface of the disc 102 is the first. Two back surface guides 136, the surface of which is the second surface guide 144, the peripheral surface of which is the third guide edge 138E of the third peripheral surface guide 138, and the other peripheral surface of which is the fourth guide edge 138E of the fourth peripheral surface guide 142. While being guided by the guide edge 1421, the peripheral surface of the rear end of the disk body 102 on the anterior side is pushed by the peripheral surface of the distal end of the disk body 102 on the posterior side, thereby forming a line toward the outlet 108 described later. transported by

Next, outlet 108 will be described mainly with reference to FIG.
The exit 108 is an opening at the most downstream end of the second guide passage 118, and has a function of sending out the disk body 102 outward from the exit 108. As shown in FIG. In the present embodiment 1, the outlet 108 includes a second front outlet guide plate 146 arranged approximately on the extension of the second front guide body 144, and a second rear outlet guide plate integrally formed with the second rear guide body 136. 148, the end of the exit passageway 156 constituted by a fifth circumferential guide 152 and a sixth circumferential guide 154 positioned between the second front exit guide plate 146 and the second rear exit guide plate 148; It is organized into parts.

The second surface exit guide plate 146 will be described.
The second surface outlet guide plate 146 has the function of guiding the surface of the disk body 102 following the second surface guide body 144 . In Embodiment 1, the second surface outlet guide plate 146 has a trapezoidal flat plate shape and is arranged in the same plane as the second surface guide body 144 . A fifth peripheral surface guide 152 is fixed to the lower end side surface of the second surface outlet guide plate 146 . The fifth peripheral guide body 152 has the same thickness as the third peripheral guide body 138 and is positioned within the same plane P. As shown in FIG.

The second back exit guide plate 148 will be explained.
The second rear exit guide plate 148 has the function of guiding the rear surface of the disk body 102 following the second rear guide body 136 . In the first embodiment, the second rear exit guide plate 148 is integrally formed with the second rear guide body 136 and linearly extends from the lower portion of the tip of the second rear guide body 136 for a predetermined length. there is The second rear exit guide plate 148 has approximately the same length as the second front exit guide plate 146 .

The fifth circumferential guide body 152 will be explained.
The fifth peripheral guide body 152 has the function of guiding the lower peripheral surface of the disk body 102 following the third peripheral guide body 138 . A fifth peripheral guide 152 is positioned between the lower ends of the second front exit guide plate 146 and the second rear exit guide plate 148 to determine the width of the exit passageway 156 .

The sixth peripheral surface guide body 154 will be described.
The sixth peripheral surface guide body 154 has a function of guiding the upper peripheral surface of the disk body 102 in the outlet passage 156 . In the first embodiment, the sixth peripheral guide body 154 is arranged parallel to the fifth peripheral guide body 152 at a distance slightly larger than the diameter of the disk body 102 with respect to the fifth peripheral guide body 152. there is In the first embodiment, the sixth peripheral surface guide body 154 is formed integrally with the second surface outlet guide plate 146 by bending the upper end portion of the second surface outlet guide plate 146 sideways. In the first embodiment, an impact-absorbing outlet elastic sheet 158 is attached to the fifth peripheral guide body 152 side of the sixth peripheral guide body 154 to dampen the bouncing of the disk body 102 in the outlet passage 156. I am trying to

The outlet passage 156 will now be described.
The outlet passage 156 has the function of guiding the disc body 102 that has passed through the second guide passage 118 to the outlet 108 . In the first embodiment, the outlet passage 156 is a flat space surrounded by the second front outlet guide plate 146, the second rear outlet guide plate 148, the fifth peripheral guide 152, and the sixth peripheral guide 154. , and the tip portion of the second guide passage 118 is configured to face downward toward the downstream side with respect to the upstream side. Exit passage 156 is located in plane P.

Furthermore, in the first embodiment, an exit guide 162 is arranged in front of the exit 108 . The outlet guide body 162 has a function of guiding the disk body 102 coming out of the outlet 108 on one side and upper side. In the first embodiment, the outlet guide body 162 is composed of an outlet side plate 164 located on the extension of the second surface outlet guide plate 146 and an outlet upper plate 165 formed by bending the upper end of the outlet side plate 164 in the horizontal direction. there is Therefore, the disk body 102 is guided on its surface by the outlet side plate 164 and on its upper peripheral surface by the outlet upper plate 165, and is guided generally obliquely downward. It should be noted that the disc body 102 can be sent out from the second guide passage 118 without providing the exit passage 156 . In the first embodiment, the upper portion of the second surface outlet guide plate 146 is formed with a long viewing hole 168 formed along the longitudinal direction of the outlet passage 156 in order to observe the behavior of the disc body 102 .
In the present invention, the outlet passage 156 and/or the outlet guide 162 may be provided as required and are not essential components.

Next, the support shaft 112 will be described mainly with reference to FIG.
The support shaft 112 has a function of rotatably supporting the second guide passage device 106 on the tip portion of the first guide passage device 104 . In the first embodiment, the support shaft 112 is composed of a pair of support shafts consisting of a first support shaft 1121 and a second support shaft 1122 having the same axis line SL. The axis SL is perpendicular to the first guide passage 116 in its thickness direction. In other words, the extension axis ESL of the axis SL intersects the first guide passage 116 at right angles. In other words, the extension axis ESL is perpendicular to the plane P.

Next, the first support shaft 1121 will be explained.
The first support shaft 1121 is a columnar shaft, one end surface of which is fixed to the side surface of the first back guide body 126 so that the axis line SL of the first support shaft 1121 coincides with its own axis line, and the tip portion of which is attached to the bearing 166 (first bearing 1661 ) is rotatably supported. In Embodiment 1, the bearing 166 is composed of a first bearing 1661 that supports the first support shaft 1121 and a second bearing 1662 that supports the second support shaft 1122 .

Next, the second support shaft 1122 will be explained.
The second support shaft 1122 is a columnar shaft, one end surface of which is fixed to the side surface of the first surface guide body 134 so that the axis line SL and its own axis line are aligned. Therefore, the first support shaft 1121 and the second support shaft 1122 substantially function as one support shaft 112. As shown in FIG. Second support shaft 1122 is rotatably supported by second bearing 1662 . Therefore, a first guide passage 116 (plane P) exists between the first support shaft 1121 and the second support shaft 1122 .
Either one of the first support shaft 1121 and the second support shaft 1122 can be used.

Next, the bearing 166 will be explained.
The bearing 166 has a function of supporting the support shaft 112 (the first support shaft 1121 and the second support shaft 1122) so as to be rotatable at least by a predetermined angle. In Embodiment 1, the bearing 166 is composed of a first bearing 1661 that rotatably supports the first support shaft 1121 and a second bearing 1662 that rotatably supports the second support shaft 1122 . The bearing 166 is mounted on a bearing support device 172 that is integral with the second guideway device 106 . As the first bearing 1661 and the second bearing 1662, rotary bearings such as ball bearings or bushes are used. Also, the axes of the first bearing 1661 and the second bearing 1662 are arranged coaxially with the axis SL.

Next, the bearing support device 172 will be explained.
The bearing support device 172 has the function of supporting the bearing 166 and supporting the second guide passage device 106 rotatably with respect to the first guide passage device 104 . In the first embodiment, the bearing support device 172 is integrated with the base of the second guide passage device 106 . The bearing support device 172 is composed of a first bearing support device 1721 and a second bearing support device 1722 .

The first bearing support device 1721 will be explained.
The first bearing support device 1721 is made of sheet metal, and is formed into a crank shape in plan view by the second rear guide body mounting portion 1741, the first lateral portion 1761, and the first bearing mounting portion 1781. As shown in FIG.

The second back guide body mounting portion 1741 will be described.
The second back guide body attachment portion 1741 is fixed to the outer surface of the second back guide body 136 in a surface contact state and integrated with the second guide passage device 106 .

Next, the first lateral portion 1761 will be described.
The first lateral portion 1761 is continuous with the second rear guide body attachment portion 1741 and extends for a predetermined length in the direction away from the second guide passage 118 perpendicularly in plan view.

Next, the first bearing mounting portion 1781 will be described.
The first bearing mounting portion 1781 has a flat plate shape, is continuous with the second rear guide body mounting portion 1741, is bent at a right angle to the first lateral portion 1761 in a plan view, and extends toward the first guide passage 116. arranged in parallel. Therefore, the first bearing mounting portion 1781 is arranged in parallel to the side of the tip portion of the first back guide body 126 with a predetermined space therebetween. A circular first bearing hole 1821 is formed in the first bearing mounting portion 1781 . A first bearing 1661 is fixed in the first bearing hole 1821 .

Next, the second bearing support device 1722 will be explained.
The second bearing support device 1722 is configured substantially symmetrically with respect to the first bearing support device 1721 with the first guide passage 116 and the second guide passage 118 interposed therebetween. That is, the second bearing support device 1722 is made of sheet metal, is formed in a crank shape in plan view, and is composed of a second surface guide mounting portion 1742, a second lateral portion 1762, and a second bearing mounting portion 1782. It is

Next, the second surface guide mounting portion 1742 will be described.
The second surface guide body attachment portion 1742 is fixed to the outer surface of the second surface guide body 144 in a surface contact state and integrated with the second surface guide body 144 .

Next, the second lateral portion 1762 will be described.
The second lateral portion 1762 is continuous with the second surface guide mounting portion 1742 and extends for a predetermined length in a direction away from the second guide passage 118 perpendicularly in plan view. In other words, the second lateral portion 1762 extends a predetermined length in the opposite direction to the first lateral portion 1761 .

Next, the second bearing mounting portion 1782 will be described.
The second bearing mounting portion 1782 has a flat plate shape, is continuous with the second lateral portion 1762, is bent at right angles to the second lateral portion 1762, and is arranged parallel to the first guide passage 116 in plan view. It is Therefore, the second bearing mounting portion 1782 is arranged in parallel with the front end portion of the first surface guide body 134 with a predetermined space therebetween. A circular second bearing hole 1822 is formed in the second bearing mounting portion 1782 .
The second bearing 1662 is inserted into a second bearing hole 1822 formed in the second bearing mounting portion 1782 and fixed.

With these configurations, when the second guide passage device 106 is assembled to the tip of the first guide passage device 104, the support shaft 112 is rotatably supported by the bearings 166 (first bearing 1661, second bearing 1662). be done. Specifically, the first support shaft 1121 is rotatably supported by a first bearing 1661 and the second support shaft 1122 is rotatably supported by a second bearing 1662 . In this assembled state, the first guide passage 116 and the second guide passage 118 lie in the same plane P perpendicular to the horizontal. In other words, the first back surface guide 126 and the second back surface guide 136 are also positioned in the same plane, and the first circumferential surface guide 128, the second circumferential surface guide 132, the third circumferential surface guide 138, And the fourth peripheral surface guide 142 is located in the plane P, and the first surface guide 134 and the second surface guide 144 are located in the other same plane. The amount of rotation of the second guide passage device 106 about the support shaft 112 with respect to the first guide passage device 104 is regulated by a rotation amount regulating device 184 (see FIG. 9(A)).

When the end of the second guide passage device 106 is attached to the tip of the first guide passage device 104 and the first guide passage 116 and the second guide passage 118 are apparently aligned (Fig. 11(B)), the second The fourth guide edge 1421, which is the lower edge of the fourth peripheral guide body 142, is positioned on the extension of the second guide edge 1321, which is the lower edge of the peripheral guide body 132. As shown in FIG. The third guide edge 138E, which is the upper edge of the third peripheral guide body 138, is positioned slightly below the extension line EL of the first guide edge 1281, which is the upper edge of the first peripheral guide body 128, in parallel. is set to In other words, the first center line CL1 of the first guide passage 116 and the second center line CL2 of the second guide passage 118 are shifted by the distance d1. In this way, by determining the positional relationship between the first guide edge 1281 and the third guide edge 138E, the disk body 102 ejected by the ejection device 122 can move toward the second guide passage 118 without losing momentum. has the advantage of being able to proceed With this configuration, as shown in FIG. 9, the axis SL of the support shaft 112 is located below the first center line CL1 at a position facing the disk body 102 immediately before being ejected by the ejection device 122. It is

Next, the rotation amount restricting device 184 will be described with reference to FIG.
The rotation amount restricting device 184 has a function of preventing the second guide passage device 106 from rotating with respect to the first guide passage device 104 by a predetermined angle or more.
In the first embodiment, the rotation amount restricting device 184 is composed of a first rotation amount restricting device 1841 and a second rotation amount restricting device 1842 .

Next, the first rotation amount regulating device 1841 will be explained.
The first rotation amount restricting device 1841 has a function of preventing the second guide passage device 106 from rotating clockwise about the support shaft 112 by a predetermined angle or more in FIG. In the present embodiment 1, the first rotation amount regulating device 1841 is configured so that the first peripheral guide body distal end portion 128T on the first peripheral guide body 128 side and the third peripheral guide body base end of the third peripheral guide body 138 It is composed of the part 138R. Specifically, when the second guide passage device 106 is rotated clockwise in FIG. 9, the maximum clock at which the first peripheral guide member distal end portion 128T and the third peripheral guide member proximal end portion 138R abut against each other. Further rotation is prevented at the directional rotation position MCP. In this state, the second guide passageway 118 rests at an obtuse downward angle with respect to the first guide passageway 116 . In other words, the second guide passage 118 is rotated clockwise with respect to the state in which the first guide passage 116 and the second guide passage 118 form a straight line.

Next, the second rotation amount regulating device 1842 will be explained.
The second rotation amount regulating device 1842 has a function to prevent the second guide passage device 106 from rotating counterclockwise around the support shaft 112 by a predetermined angle or more in FIG. 9 with respect to the first guide passage device 104. . In the first embodiment, the second rotation amount regulating device 1842 is composed of the second peripheral guide body distal end portion 132T and the fourth peripheral guide body base end portion 142R of the fourth peripheral guide body 142. As shown in FIG. Specifically, when the second guide passage device 106 is rotated counterclockwise in FIG. 9 (FIG. 9(B)), the tip portion 132T of the second peripheral guide body and the base of the fourth peripheral guide body Further rotation is prevented at the maximum counterclockwise rotation position MCCP where the end portion 142R abuts. In this state, the second guide passageway 118 rests at an upwardly obtuse angle with respect to the first guide passageway 116 . In other words, the second guide passage 118 is rotated counterclockwise with respect to the state in which the first guide passage 116 and the second guide passage 118 form a straight line.
When the rotation of the second guide passage device 106 is restricted by the second rotation amount restricting device 1842, the first peripheral surface guide tip portion 128T of the first peripheral surface guide 128 and the third peripheral surface guide 138 A distance d2 between the third peripheral guide body base end portion 138R and the peripheral guide body 138R is set smaller than the diameter of the disk body . This is to prevent the disk body 102 from leaving the first guide passage 116 from the circumferential guide body interval d2 between the first circumferential guide body distal end portion 128T and the third circumferential guide body base end portion 138R. The second guide channel arrangement 106 is preferably retained in a position where the second guide channel arrangement 106 is at a predetermined angle to the first guide channel arrangement 104 by a retaining device 186 .

The holding device 186 will now be described with reference to FIG.
The holding device 186 has the function of holding the second guide channel arrangement 106 in a predetermined angular position with respect to the first guide channel arrangement 104 . In the first embodiment, the holding device 186 is a rod arranged below the tip of the second guide passage device 106 . This holding device 186, which is a bar, is fixed to a housing (not shown) in which the disc body guide device 100 is built so that the position thereof can be adjusted.
As shown in FIG. 11(A), when the holding device 186 is arranged relatively upward, the maximum counterclockwise rotation position where the rotation of the second guide passage device 106 is restricted by the second rotation amount restricting device 1842. It can be rotated to MCCP, and the position of the exit 108 can be set at a height position H1 from the reference position RP.
As shown in FIG. 3B, when the holding device 186 is arranged in the middle, the first guide passage device 104 and the second guide passage device 106 are aligned, in other words, the first guide passage 116 is extended. The second guide passage 118 can be positioned above, and the position of the exit 108 can be set at a height H2 from the reference position RP.
As shown in FIG. 4C, when the holding device 186 is arranged relatively downward, the maximum clockwise rotation position MCP where the rotation of the second guide passage device 106 is restricted by the first rotation amount restricting device 1841. , and the position of the exit 108 can be set at a height H3 from the reference position RP.
Any other device can be used as the holding device 186 as long as it can perform its function. For example, the amount of rotation between the distal end portion of the first guide passage device 104 and the proximal end portion of the second guide passage device 106 may be fixed.

Next, the ejection device 122 will be described mainly with reference to FIGS. 9 and 10. FIG.
The ejection device 122 has a function of ejecting the disc body 102 guided to the first guide passage 116 from the end of the first guide passage 116 to the second guide passage 118 . In the first embodiment, the ejection device 122 is composed of an ejection board 192 , an ejection lever shaft 194 , an ejection lever 196 , an ejection spring 198 , an ejection roller 202 and a stopper 204 .

First, the ejection board 192 will be described.
The ejection board 192 has a function of supporting the ejection lever shaft 194 , the ejection lever 196 , the ejection spring 198 , the ejection roller 202 and the stopper 204 . In the first embodiment, the ejection base plate 192 is made of sheet metal, and has a mounting portion 1921 having an approximately inverted triangular shape in the middle, and a spring bent horizontally in the upper end portion of the mounting portion 1921 so as to have an L shape when viewed from the front. The receiving portion 1922 and the lower end portion of the mounting portion 1921 have a stopper receiving portion 1923 that is bent sideways in an oblique direction. The ejection board 192 is fixed to the outer surface of the first surface guide 134 .

Next, the ejection lever shaft 194 will be explained.
The ejection lever shaft 194 has a function of supporting the ejection lever 196 so as to be rotatable. In the first embodiment, the ejection lever shaft 194 is a support shaft in the shape of a cantilevered round bar projecting laterally and horizontally from the ejection base plate 192 .

Next, the ejection lever 196 will be explained.
The ejection lever 196 has a function of supporting the ejection roller 202 and receiving the elastic force of the ejection spring 198 . In the first embodiment, the ejection lever 196 is made of sheet metal, has a channel-shaped cross section, and is formed into a bar shape having a predetermined length, and one end thereof is rotatable on the ejection lever shaft 194. attached to the This configuration allows the ejection lever 196 to reciprocate in a plane parallel to the first guide passage 116 .

Next, the ejection spring 198 will be explained.
The ejection spring 198 has a function of applying a turning force in a predetermined direction to the ejection lever 196 . In the present embodiment 1, the ejection spring 198 is a torsion coil spring, the middle coil is attached to the ejection lever shaft 194, one free end is locked to the lower part of the spring receiving part 1922, and the other The free end portion penetrates through a through hole 1961 formed in the ejector lever 196 and is engaged with the ejector lever 196 . As a result, the ejection lever 196 is given a predetermined rotating force in the clockwise direction in FIG. Various known springs can be adopted as the ejection spring 198 .

Next, the ejection roller 202 will be explained.
The ejection roller 202 comes into contact with the disk body 102 conveyed through the first guide passage 116, and the applied elastic force of the ejection spring 198 pushes the disk body 102 toward the second guide passage 118. It has the function of throwing out. The ejection roller 202 is rotatably supported by a roller support shaft 206 projecting laterally from the tip of the ejection lever 196 toward the second guide passage 118 . As shown in FIG. 5, the ejection roller 202 is positioned within an arcuate hole 208 formed in the first guide passageway device 104 . Specifically, the first guide passage passes through a first arcuate hole 2081 formed at the tip of the first back guide body 126 and a second arcuate hole 2082 formed at the tip of the first front guide body 134. It is arranged to cross 116. Therefore, the ejection roller 202 swings within the arc-shaped hole 208 .

Next, the stopper 204 will be explained.
The stopper 204 has a function of regulating the position of the ejection roller 202 after the disc body 102 has been ejected. In other words, it has the function of determining the position of the ejection roller 202 when the ejection roller 202 is not in contact with the disk body 102 and the function of buffering the impact of the ejection lever 196 . In the first embodiment, the stopper 204 is composed of the stopper receiving portion 1923 described above and the cushioning sheet 210 that cushions the impact. The cushioning sheet 210 is made of a material such as a silicon sheet that has a shock absorbing function and durability, and is attached so as to cover the upper surface of the stopper receiving portion 1923 . As a result, when the ejection lever 196 collides with the stationary stopper 204 after ejecting the disc body 102, the ejection lever 196 immediately becomes stationary without rebounding. At the position where the movement of the ejection lever 196 is blocked by the stopper 204, the ejection roller 202 is positioned at the standby position SP indicated by the chain line in FIG. 9(A). At this standby position SP, the distance between the ejection roller 202 and the tip of the first circumferential guide body 128 is set smaller than the diameter of the disk body 102 . This is because the disk body 102 pushes the ejection roller 202 and bends the ejection spring 198, thereby increasing the repulsive force of the ejection spring 198 and ejecting the disk body 102 vigorously. The disc body 102 ejected to the second guide passage 118 by the ejection device 122 is detected by the disc body detection device 212 .

Next, the disc body detection device 212 will be described.
The disk body detection device 212 has a function of detecting the disk body 102 ejected toward the second guide passage device 106 (second guide passage 118). In Example 1, a photoelectric detection device composed of a light emitter 2121 and a light receiver 2122 is used. However, the disc body detection device 212 can use other detection devices such as a mechanical type. In the first embodiment, the light projector 2121 is fixed to the first back guide body 126 and faces the first through hole 214 (FIG. 5A) formed in the first back guide body 126. not shown) are placed. The light receiver 2122 is fixed to the first surface guide body 134 and has a light projecting section (not shown) arranged opposite to a through hole (not shown) formed in the first surface guide body 134 . Therefore, light projected from the light projector 2121 crosses the second guide passage 118 and reaches the light receiver 2122 . The second guide passage 118 traversed by the light projected from the light projector 2121 is a position through which the light is passed immediately after being ejected by the ejection device 122, as shown in FIG. By detecting that the projection of light from the light emitter 2121 to the light receiver 2122 is interrupted for a predetermined time, the passage of the disc body 102 can be detected.

Next, the operation of Example 1 will be described.
The disc body guide device 100 is arranged in, for example, a medal game machine (not shown), and a delivery command is output to the disc body delivery device 114 according to a command from the medal game machine. The disc body delivery device 114 that has received the delivery command delivers the stored disc bodies 102 one by one from the delivery port 124 to the first guide channel device upright portion 104V of the first guide channel device 104 . As a result, the disk body 102 in the first guide passage 116 is pushed up in the first guide passage 116 by pushing the rear end of the front disk body 102 by the front end of the rear disk body 102 . The disk body 102 in the first guide passage 116 is conveyed from the first guide passage device upright portion 104V to the first guide passage device turning portion 104T, and is turned obliquely upward and to the right. After that, the disc body 102 reaches the ejection device 122 .

As the disk body 102 advances, the disk body 102 positioned at the extreme end of the first guide passage 116 pushes up the ejection roller 202 against the elastic force of the ejection spring 198 (see FIG. 9). As a result, the ejector lever 196 is rotated counterclockwise in FIG. 9 around the ejector lever shaft 194, and the elastic force of the ejector spring 198 is increased ((B) in FIG. 9). A straight line L connecting the first contact point P1 between the ejection roller 202 and the disk body 102, the first peripheral guide body tip portion 128T of the first peripheral guide body 128, and the second contact point P2 of the disc body 102 is defined as the disk body. Immediately after the center C of the body 102 has passed, the ejection roller 202 ejects the disc body 102 toward the second guide passage 118 .

When the second guide passage 118 is set upward with respect to the first guide passage 116 (FIG. 11(A)), the disk body 102 is guided to the second guide passage 118 obliquely upward by the momentum of being pushed out. It advances and is thrown out from the exit 108 into a predetermined receiving opening of the coin-operated game machine. When the second guide passage 118 is set upward with respect to the first guide passage 116, the disk body 102 ejected by the ejection roller 202 is guided by the third circumferential guide body 138 (second third circumferential guide 1382), rebounding toward the fourth peripheral guide body 142, and then rebounding toward the third peripheral guide body 138, while being guided. Therefore, the bullet force of the bullet roller 202 must be determined in consideration of the force attenuated by the collision. However, the circumferential guide body spacing d2 between the first circumferential guide body tip portion 128T and the third circumferential guide body 138 (second and third circumferential guide body 1382) is smaller than the diameter of the disk body 102. In this state, the disk body 102 does not drop out of the second guide passage 118 because it is regulated by the second rotation amount regulating device 1842 .

When the second guide passage 118 is set on the extension of the first guide passage 116 (FIG. 11(B)), the disk body 102 advances while being guided through the second guide passage 118 by the momentum of being pushed out, and exits. From 108, it is thrown out to a predetermined receiving slot of the coin-operated game machine.

When the second guide passage 118 is set downward with respect to the first guide passage 116 (FIG. 11(C)), the disk body 102 advances while being guided through the second guide passage 118 by the thrust force and gravity. , and is thrown out from the exit 108 to a predetermined reception opening of the game.

The disc body 102 ejected toward the second guide passage 118 by the ejection roller 202 is detected by the disc body detection device 212 . In other words, since the disk body 102 blocks the projection of light from the light projector 2121 to the light receiver 2122, the movement of the disk body 102 can be detected by detecting the blocking of the projected light.

102 disk
104 first guide passage device
106 Second Guide Passage Device
112 Spindle
1122 second spindle
1121 first spindle
114 Disc delivery device
116 1st Guidance Walkway
118 Second Guidance Walkway
122 Launcher
126 first back guide
128 first circumferential guide
1281 first guide edge
1281 first guide edge
128T Tip of first circumferential guide
132 second circumferential guide
132T Tip of second circumferential guide
134 first surface guide
136B Base end of second back guide body
138 third circumferential guide
138E Third guide edge
138T 3rd circumferential guide base end
142 Fourth circumference guide body
142T 4th circumferential guide base end
166 Bearing
1661 first bearing
1662 Second bearing
184 Rotation amount control device
1841 1st rotation amount control device
1842 2nd rotation amount control device
186 Holding Device
d2 Distance between peripheral guides
EL extension line
ESL extension axis
P-plane
SL axis

Claims (13)

a first guide passage (116) defined by at least a first circumferential guide (128) and a second circumferential guide (132) that guide the opposing circumferential surfaces of the disc body (102); a third circumferential guide (138) arranged downstream of the guide passage (116) and on the same side as the first circumferential guide (128) with respect to the circumferential surface of the disk (102); , and a fourth peripheral guide (142) arranged on the same side as the second guide (132). ), the disk bodies (102) are guided in a row from the first guide passage (116) to the second guide passage (118),
The first circumferential guide (128), the second circumferential guide (132), the third circumferential guide (138), the fourth circumferential guide (142), and the first guide the passageway (116) and the second guide passageway (118) are arranged in the same plane (P),
The second guide passage (118) extends relative to the first guide passage (116) about a support shaft (112) having an axis ( SL ) perpendicular to the plane (P) and the extension axis (ESL). provided rotatably,
The extension line (EL) of the first guide edge (1281) of the first peripheral guide (128) can cross the third guide edge (138E) of the third peripheral guide (138). configured to
An ejection device (122) is disposed at the end of the first guide passage (116), and the disk body (102) is ejected into the second guide passage (118) by the ejection device (122). A disc body guide device characterized by: The first peripheral guide body (128) is arranged below the second peripheral guide body (132), and the third peripheral guide body (138) is located below the fourth peripheral guide body (142). and the extension line (EL) of the first guide edge (1281) of the first peripheral guide (128) is aligned with the third guide edge (138E) of the third peripheral guide (138). 2. The disk body guide device according to claim 1, wherein the disk body guide device is configured to be able to intersect with. When the extension line (EL) of the first guide edge (1281) of the first peripheral guide (128) intersects the third guide edge (138E) of the third guide (138), The first peripheral guide body distal end (128T) of the first peripheral guide body (128) and the facing third peripheral guide body base end (138T) of the third peripheral guide body (138) A rotation amount restricting device (184) is provided to restrict the rotation of the second guide passage (118) at a position where the circumferential guide body interval (d2) is less than the diameter of the disk body (102). The disc body guiding device according to claim 2. At least, the discs (102) are moved one by one in a row while being guided along the first guide passage (116), and are ejected from the end of the first guide passage (116) by the ejection device (122). A disc body guide device configured to eject a second guide passage (118) arranged downstream of the guide passage (116),
The second guide passageway (118) is arranged in the same plane (P) as the first guide passageway (116) and rotates around a support shaft (112) having one axis (SL). provided that it is possible to
An extension axis (ESL) of the axis (SL) is orthogonal to the plane (P) and is an extension of the first guide passage (116), and the disk body (102) is aligned with the ejector. A disk guide device configured to traverse the second guide passage (118) after being ejected by the device (122). A disc body sending device (114) for sending out the disc bodies (102) one by one;
a first guide passage device (104) forming a first guide passage (116) that guides the discs (102) delivered by the disc delivery device (114) upward in a line;
an ejection device (122) for ejecting the guided disc (102) at the end of the first guide passage (116);
A disc body guiding device comprising a second guide passage device (106) forming a second guide passage (118) for guiding the ejected disc body (102) in a predetermined direction,
With respect to the first guide passage device (104), the second guide passage device (106) has the first guide passage (116) and the second guide passage (118) in the same plane (P), rotatably connected by a support shaft (112) having one axis (SL);
An extension axis (ESL) of the axis (SL) is orthogonal to the plane (P) and is an extension of the first guide passage (116), and the disk body (102) is aligned with the ejector. A disk guide device configured to traverse the second guide passage (118) after being ejected by the device (122). A disc according to any one of claims 1 to 5 , characterized in that it comprises a holding device (186) for holding said second guide passage (118) at a predetermined angle with respect to said first guide passage (116). body guidance device. 7. The disc body guide device according to claim 1, wherein the first guide passage (116) is turned in an obliquely upward direction after being erected. 8. The second guide passage (118) according to claim 7 , wherein the second guide passage (118) is rotatable upward from the extension of the first guide passage (116) and downward from the extension. disc guide device. The first guide passage device (104) includes a first surface guide body (134) that guides the surface of the disk body (102) and a first back surface guide body (126) that guides the back surface of the disk body (102). , the first guide body (134) and the first back guide body (126), which guide the peripheral surface of the disk body (102), are arranged in parallel at a predetermined distance between the first guide body (134) and the first back guide body (126). including a peripheral guide (128) and a second peripheral guide (132),
The support shaft (112) is integrated with the first guide passage device (104),
A bearing (166) is integrated with the second guide passage device (106),
By rotatably combining the bearing (166) with the support shaft (112), the second guide passage device (106) is rotatably combined with the first guide passage device (104). 6. A disc body guiding device according to claim 5 , characterized in that: The support shaft (112) includes a second support shaft (1122) fixed to the first front guide body (134) and a first support shaft (1121) fixed to the first back guide body (126). , the first support shaft (1121) and the second support shaft (1122) are arranged on the same axis ( SL ), the extension axis (ESL) of which is perpendicular to the plane (P),
A first bearing (1661) and a second bearing (1662) integrated with the second guide passage device (106) rotate the first support shaft (1121) and the second support shaft (1122). 10. The disk body guiding device according to claim 9 , wherein the two are combined. 10. A disc body guiding device according to claim 9 , wherein said ejection device (122) is attached to said first surface guiding body (134). The second guide passage device (106) includes a second surface guide body (144) that guides the surface of the disk body (102) and a second back surface guide body (136) that guides the back surface of the disk body (102). , the third guide body (144) and the second back guide body (136), which guide the peripheral surface of the disk body (102), are arranged in parallel with a predetermined distance between the second guide body (144) and the second back guide body (136). including a peripheral guide (138) and a fourth peripheral guide (142),
The first circumferential guide body distal end (128T) of the first circumferential guide body (128) and the third circumferential guide body base end (138T) of the third circumferential guide body (138) The second peripheral guide body tip (132T) of the second peripheral guide body (132) and the fourth peripheral guide body of the fourth peripheral guide body (142). 10. The disk body guiding device according to claim 9 , wherein the body base end portion (142T) constitutes the second rotation amount regulating device (1842). The bearing (166) includes a first bearing (1661) integrated with the second back guide (136),
including a second bearing (1662) integrated with the second surface guide (144);
10. The first bearing (1661) is rotatably supported by the first spindle (1121), and the second bearing (1662) is rotatably supported by the second spindle (1122). 2. The disc body guiding device described in 1.

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