JP5395928B2 - Disk-shaped body feeding device - Google Patents

Description

  The present invention relates to a disk-like body feeding device that feeds out a disk-like body such as coins as currency or substitute money (medals, tokens, etc.) used in a game facility one by one.

  In the conventional disk-shaped body feeding device, the mounting portion of the base has a plurality of through-holes or notches into which the disk-shaped body can enter, and the disk has entered into the through-holes or notches. There is provided a rotary transfer body that transfers the state body in a pressed state in the rotational direction along the transfer guide surface of the mounting portion, and is provided on the lower surface of the rotary transfer body and within the rotational radial direction of the through hole or notch. A mounting support surface capable of mounting and supporting the inner side and the outer side of the rotating radial direction of the disk-like body that has entered the through hole or the notch is provided on the outer side portion and the outer side portion in the rotating radial direction. A disk-shaped body that has been transferred into the through-hole or notch of the rotary transfer body and is transferred toward the outside in the rotational radial direction at a set delivery site of the rotary transfer path. Sending out means is provided (for example, patent Document reference 1-3).

  In constructing the rotary transfer body, in the former disk-shaped body feeding device shown in Patent Document 1 or 2, the upper rotary disk having the upper half side of the through hole or notch, the through hole or the cut Plural in a state in which the lower half of the notch is formed and the lower rotary transfer disk integrally formed with the annular receiving portions located on the inner side and the outer side in the rotational radial direction is overlapped. It is configured to be fixedly connected with a book screw.

  Further, in the latter disk-shaped body feeding device shown in Patent Document 3, an annular receiving portion located on the inner side in the rotational radius direction and an annular receiving portion located on the outer side in the rotational radius direction are rotated and transferred. It is integrally formed on the lower surface of the body.

JP 59-81784 A JP 61-15292 A Japanese Utility Model Publication No. 3-86472

  In this type of disk-shaped body feeding device, when the rotary transfer body provided in the mounting portion of the base swings during driving rotation, the upper and lower intervals between the lower surface of the rotary transfer body and the transfer guide surface of the mounting portion of the base A gap corresponding to two or more thicknesses of the disk-shaped body may be formed in the circular plate-like body, but even in this case, the annular receiving portions positioned on the inner side and the outer side in the rotational radial direction are the rotary transfer body. Therefore, another disk shape is formed between the upper surface of the disk-shaped body and the lower surface of the rotationally-transferred body, which are sent out outward in the rotational radial direction by the delivery means at the set-up delivery site of the rotational transfer path. There is an advantage that the body can suppress biting.

  On the other hand, in the former disk-shaped body feeding device, even when the rotary transfer body is formed of resin, a mold for forming a large upper rotating disk and a large lower rotation close to the outer diameter of the upper rotating disk. A mold for forming the transfer disk is necessary, and there is a problem in that the manufacturing cost increases.

  Further, in the latter disk-shaped body feeding device, an annular receiving portion located on the inner side in the rotational radius direction and an annular receiving portion located on the outer side in the rotational radius direction are integrated with the lower surface of the rotary transfer body. Due to the formation relationship, it is necessary to configure the mold into a complicated split mold, which causes a problem of increasing the manufacturing cost.

  The present invention has been made in view of the above-mentioned actual situation, and the main problem is that the resin molding cost of the disk-shaped body is low while suppressing the biting of the two disk-shaped bodies. The object is to provide a disk-shaped body feeding device that can improve the efficiency of assembly and assembly work.

A first characteristic configuration according to the present invention includes a plurality of through-holes or notches into which a disk-like body can enter in a mounting portion of a base, and a disc that enters into the through-holes or notches. A resin-made rotary transfer body is provided for transferring the state body in a pressed state in the rotational direction along the transfer guide surface of the mounting portion, and is rotated on the lower surface of the rotary transfer body and in the through hole or notch. On the radially inner side portion and the rotational radial direction outer side portion, a placement capable of placing and supporting the rotational radial direction inner side and the outer side of the disk-like body that has entered the through hole or the notch is provided. A resin receiving portion having a support surface is provided, and the disk-like body that has been transferred through the through hole or notch of the rotary transfer body is transferred to the rotation radius at the set delivery site of the rotary transfer path. There is a delivery means to send out the direction outward A that disc-shaped body feeding device,
Of the two receiving portions, at least the receiving portion located on the outer side in the rotational radial direction or the inner side in the rotational radial direction is formed separately from the rotary transfer body, and at least the outer side in the rotational radial direction or the rotational direction. The receiving portion on the inner side in the radial direction is formed with a locking portion that engages with the locked portion formed on the rotary transfer body from the lower side in a secured and fixed state. The vertical distance between the mounting support surface of the receiving portion and the lower surface of the rotary transfer body is set such that only one disk-like body that has entered the through-hole or the notch portion can move through. is there.

  According to the above configuration, a disc-like shape is formed between the lower surface of the rotating transfer body and the transfer guide surface of the mounting section of the base due to the swing movement during the rotation of the rotating transfer body provided in the mounting section of the base. Even when a gap corresponding to two or more thicknesses of the body is formed, both receiving portions located on the inner side and the outer side in the rotational radius direction swing together with the rotary transfer body, and both receiving portions are placed. Since the vertical distance between the support surface and the lower surface of the rotary transfer body is set such that only one disk-like body entering the through hole or notch can pass through, the rotation transfer path is set. It is possible to satisfactorily prevent another disk-like body from being caught between the upper surface of the disk-like body that is sent outward in the rotational radial direction by the delivery means at the delivery site and the lower surface of the rotary transfer body. Can do.

  Moreover, since at least the receiving portion located on the outer side in the rotational radial direction or the inner side in the rotational radial direction is formed separately from the rotational transfer body, for example, the rotational transfer. When the body is molded with resin, an annular receiving portion located on the inner side in the rotational radius direction and an annular receiving portion located on the outer side in the rotational radius direction are integrally formed on the lower surface of the rotary transfer body. Thus, it is not necessary to form the molding die into a complicated split mold, and it can be manufactured with a simple mold with a small number of divisions.

  Further, even when the rotary transfer body formed separately and the receiving portion on the outer side in the rotational radial direction or the inner side in the rotary radial direction are assembled, the rotary transfer body is at least rotated with respect to the locked portion of the rotary transfer body. It is only necessary to engage the engaging portion formed on the receiving portion on the radially outer side or the rotating radially inner side from the lower side, and at the time of use, the disk-like body acting on the rotating transfer body Since the load acts in the direction of deepening the engagement between the locked portion of the rotating transfer body and the locking portion of the receiving portion, the rotating transfer body and the receiving portion on the outer side in the rotating radial direction or the inner side in the rotating radial direction Can be reliably rotated integrally while maintaining a predetermined arrangement relationship.

  Therefore, it is possible to reduce the resin molding cost of the rotary transfer body and increase the efficiency of the assembling work while suppressing the biting of the two disk-shaped bodies.

  A second characteristic configuration according to the present invention is that at least the receiving portion on the outer side in the rotational radial direction or the inner side in the rotational radial direction formed separately from the rotary transfer body is configured to be deformable. is there.

  According to the above-described configuration, at least between the mounting support surface of the receiving portion on the outer side in the rotational radial direction or the inner side in the rotational radial direction formed separately from the rotational transport body and the lower surface of the rotational transport body. When a foreign material bites into the disc-shaped body that is in contact with the foreign material and a feeding force is applied to the outer side in the rotational radial direction, at least the receiving portion on the outer side in the rotational radial direction or the inner side in the rotational radial direction is applied. The foreign object biting portion is bent and deformed, and the foreign object biting is eliminated.

  According to a third characteristic configuration of the present invention, the upper surface of the rotary transfer body has at least a receiving portion on the outer side in the rotational radial direction or the inner side in the rotary radial direction engaged with the locked portion of the rotary transfer body. The release operation port for releasing the engagement of the locking portion of the portion is formed.

  According to the said structure, from the release operation port formed in the upper surface of the said rotation transfer body, the latching | locking part of a rotation transfer body and the receiving part of a rotation radial direction outer side or a rotation radial direction inner side are latched. Since the engagement with the part can be easily released, foreign matter is present at least between the mounting support surface of the receiving part on the outer side in the rotational radial direction or the inner side in the rotational radial direction and the lower surface of the rotary transfer body. Even when it is bitten, this foreign matter can be easily removed.

  According to a fourth feature of the present invention, at least the engaging portion of the receiving portion on the outer side in the rotational radial direction or the inner side in the rotational radial direction is an inner portion in the rotational radial direction with respect to the locked portion of the rotary transfer body. It is in the point comprised so that it may engage from the side.

  According to the above configuration, when the disk-like body positioned on the upper surface of the rotary transfer body moves outward in the rotational radial direction along with the driving rotation of the rotary transfer body, Even if the disk-shaped body abuts from the inner side in the rotational radius direction, it acts in a direction to increase the engagement force between the locking portion of the receiving portion and the locked portion of the rotary transfer body, At least the receiving portion on the outer side in the rotational radius direction or the inner side in the rotational radius direction can be surely integrally rotated in an engaged state with no backlash.

  According to a fifth characteristic configuration of the present invention, the locked portion is provided on a side portion on the lower side in the rotational direction of each through-hole or notch in the rotary transfer body, and at least in the rotational radial direction. A receiving part on the outer side or the inner side in the rotational radial direction is formed in an annular shape, and the receiving part on the outer side in the rotational radial direction or the inner side in the rotational radial direction has a plurality of portions corresponding to the locked parts. The locking portion is integrally formed.

  According to the above configuration, the locking portion and the locked portion are formed between the lower surface of the rotary transfer body and at least the placement support surface of the receiving portion on the outer side in the rotational radial direction or the inner side in the rotational radial direction. Formed in a state of traversing a space for feeding the disk-shaped body outward in the rotational radius direction, and this locking portion and the locked portion are connected to each through hole or notch in the rotary transfer body. By placing it on the side of the lower side in the rotational direction (front side of rotation), the upper side in the rotational direction (rear side of rotation) of each through-hole or notch, and outward in the rotational direction by the delivery means A wide delivery area of the disc-like body to be delivered can be secured.

The perspective view of the whole at the time of hopper separation which shows 1st Embodiment of the disk-shaped object feeding apparatus of this invention A perspective view when the rotary transfer body and the delivery guide unit case are separated from the base Overall profile side view Exploded perspective view of the lower surface side of the rotary transfer body An enlarged plan view of the main part of the rotary transfer body Sectional view taken along line VI-VI in FIG. Longitudinal sectional view of the set delivery part of the base Exploded perspective view of delivery means 3 is a cross-sectional plan view taken along the line IX-IX in FIG. 3 showing an operation state during the rotational transfer of the disk-shaped body. Cross-sectional plan view showing the operating state of the disk-shaped body in the first half of delivery Cross-sectional plan view showing the operation state of the disk-shaped body during the delivery Cross-sectional plan view showing the operating state of the disk-like body in the latter half of delivery The enlarged plan view of the principal part which shows 2nd Embodiment of the disk-shaped object feeding apparatus of this invention.

[First Embodiment]
1 to 4 show a feeding device of a disk-like body 1 such as coins as currency or substitute money (medals, tokens, etc.) used in gaming facilities, subways, etc., and the bottom of a hopper H that opens upward The speed reduction mechanism 4 interlocked with the electric motor 3 protrudes upward at the center position of the circular mounting portion 6 formed in the upper surface of the base 2 so as to be depressed. The mounting portion 6 of the base 2 is detachably attached to the plurality of through holes 7 through which the disc-like body 1 can enter and the drive shaft 5 on the base 2 side. A synthetic resin rotary transfer body 8 provided with a boss portion 8A fitted in an integrally rotated state is provided.

  As shown in FIGS. 4 to 7, a part of the disk-like body 1 that has entered the through hole 7 is located on the lower surface (rear surface) of the rotary transfer body 8 at the position inward in the rotational radius direction of the through hole 7. The synthetic resin annular receiving portion 10A having the mounting support surface 10a for mounting and supporting a part of the disk-shaped body 1 that has entered the through hole 7 is disposed outside the through hole 7 in the radial direction of rotation. An annular receiving portion 10B made of synthetic resin and provided with a mounting support surface 10b for mounting and supporting at the side portion is provided.

  Further, as shown in FIG. 7, the receiving support surface 10 a of the receiving portion 10 </ b> A (hereinafter referred to as an inner receiving portion) 10 </ b> A located on the inner side in the rotational radial direction and the outer side in the rotational radial direction. A vertical distance h between the mounting support surface 10b of the receiving portion (hereinafter referred to as an outer receiving portion) 10B and the lower surface of the rotary transfer body 8 enters the through hole 7 of the rotary transfer body 8. Only a single disk-like body 1 is set at an interval at which it can pass and move from the inner side to the outer side in the rotational radius direction.

  Among them, the inner receiving portion 10 </ b> A is integrally formed with the rotary transfer body 8 with a relatively hard synthetic resin excellent in wear resistance, and the outer receiving portion 10 </ b> B is formed with the rotary transfer body 8. Is molded separately from the resin, and the outer receiving portion 10B is secured to the plurality of (five in this embodiment) to-be-locked portions 11 formed on the rotary transfer body 8 respectively. In this state, a plurality of locking portions 12 that are engaged from below are integrally formed.

  Therefore, even when the rotary transfer body 8 formed separately and the outer receiving portion 10B are assembled, the outer receiving portion 10B is connected to the locked portion 11 of the rotary transfer body 8. It is only necessary to engage the engaging portion 12 formed from the lower side, and in use, the load of the disk-shaped body 1 group accommodated in the hopper H is applied to the engaged portion of the rotary transfer body 8. 11 and the engaging portion 12 of the receiving portion 10B acts in a direction to deepen the engagement, so that the rotary transfer body 8 and the outer receiving portion 10B are reliably integrally rotated while maintaining a predetermined arrangement relationship. be able to.

  The width of the outer receiving portion 10B in the rotational radius direction is smaller than the width of the inner receiving portion 10A in the rotational radius direction, and the outer receiving portion 10B is inward. The outer receiving portion 10B is configured to be able to bend and deform against an elastic restoring force. The outer receiving portion 10B is molded from a synthetic resin softer than the receiving portion 10A.

  Therefore, the outer receiving portion 10B has a structure that is more easily bent and deformed in the radial direction and the vertical direction than the inner receiving portion 10A, and the mounting support surface 10b of the outer receiving portion 10B and the rotary transfer body. When a foreign object is caught between the lower surface of the disk 8 and a feeding force to the outer side in the rotational radial direction is applied to the disc-like body 1 that is in contact with the foreign object, the foreign object biting of the outer receiving portion 10B is performed. The encroaching portion is bent and deformed, and the foreign object is eliminated.

  As shown in FIGS. 2, 3, and 7, the upper surface of the mounting portion 6 has both receiving portions 10 </ b> A, 10 </ b> A, 10 </ b> A, 10 </ b> B, 10 </ b> A, 10 </ b> B in a state where they are flush with each other. An annular rotation guide groove 13A, 13B into which 10B enters is formed, and further, an inner portion of the rotation guide groove 13A on the inner side on the upper surface of the mounting portion 6 in the rotation radial direction and adjacent to both rotation guide grooves 13A, 13B. The disc-like body 1 mounted and supported on both receiving portions 10A and 10B of the rotary transfer body 8 is provided along the rotary transfer path on the outer radial direction outer side part of the rotation guide groove 13B on the outer side and the outer side. Annular transfer guide surfaces 6A, 6B, 6C for sliding guide are formed.

  In the peripheral portion of each through-hole 7 on the lower surface of the rotary transfer body 8 and on the upper side in the rotational direction (rear position after rotation) corresponding to the location of the inner receiving portion 10A, A pressing wall portion 14 </ b> A that presses the disk-shaped body 1 that has entered is pressed along the rotational transfer path is integrally formed.

  In addition, the disk-like body 1 that has entered the through hole 7 moves inward in the rotational radial direction at the peripheral portion on the inner side in the rotational radius direction of each through hole 7 on the lower surface of the rotary transfer body 8. An arc-shaped first regulating wall portion 14B that regulates contact is integrally formed.

  Further, the outer peripheral portion of each through-hole 7 on the lower surface of the rotary transfer body 8 and the outer side in the rotational radius from the lower side portion in the rotational direction (front of rotation) corresponding to the placement portion of the inner receiving portion 10A. In the region extending to the side, there is an arc-shaped second regulating wall portion 14 </ b> C that regulates contact with the disc-like body 1 that has entered the through-hole 7 and moves to the lower side in the rotational direction (front side of the rotation). Integrally formed

  As shown in FIGS. 4 to 6, the locked portion 11 on the side of the rotary transfer body 8 is seen in a plan view at a side portion on the lower side in the rotation direction (front rotation side) of each through hole 7 in the rotary transfer body 8. A substantially diamond-shaped locking hole 11a is formed through in the vertical direction, and a locking step portion 11b is formed at an intermediate position between the inner surface of the locking hole 11a on the outer side in the rotational radius direction. Configured.

  As shown in FIGS. 4 to 6, each locking portion 12 on the side of the receiving portion 10 </ b> B has a square plate shape that can be inserted into the locking hole 11 a of the rotary transfer body 8 from the lower side and is on the outer side. A locking base portion 12a formed to have the same width as the width of the receiving portion 10B in the rotational radius direction, and protruding from the upper end of the locking base portion 12a outward in the rotational radius direction, thereby locking the locked portion 11 It is comprised from the latching claw 12b engaged with the step part 11b from the inner side of a rotation radial direction.

  In a state where the locking claw 12b of the locking part 12 is engaged with the locking step part 11b of the locked part 11, the back of the locking base 12a and the locking claw 12b of the locking part 12 and the locking hole 11a. Disengagement between the opposing surfaces of the inner surface facing the inner surface portion located on the inner side in the rotational radius direction by bending deformation of the locking base 12a and the locking claw 12b toward the inner side in the rotational radius direction. A gap S that allows operation is formed.

  Therefore, the upper opening of the locking hole 11a of the rotary transfer body 8 is released to disengage the locking claw 12b of the locking portion 12 engaged with the locking step portion 11b of the locked portion 11. The operation port 11c is configured.

  A sending means B for sending the disc-like body 1 that has entered the through-hole 7 of the rotary transfer body 8 and transferred to the outlet port A in the rotational radial direction at the set transfer portion of the rotary transfer path; The passage sensor C provided with the rotation sensing body 31 as a passage sensing body that rotates in accordance with the contact with the disk-shaped body 1 delivered by the delivery means B and the rotation in accordance with the contact with the disk-shaped body 1. Rotation position holding means D is provided for holding the rotation sensing body 31 in a center angle unit corresponding to the passing movement range of the disk-shaped body 1 (120 ° center angle unit in the first embodiment). .

  As shown in FIGS. 1, 2, and 9 to 12, the upper and disc-like bodies 1 are formed in a recess in the outer peripheral side of the mounting portion 6 in the base 2 and in the region including the delivery port A. In the first mounting recess 15 that opens on the lower side in the delivery direction, the unit case 32 that is assembled in a state in which the delivery port A is formed and the passage sensor C and the rotation position holding means D are installed is detachable. It is installed.

  As shown in FIGS. 2 and 3, the outlet portion A is formed on the upper surface of the unit case 32 with a passage width slightly larger than the diameter of the disk-shaped body 1 with respect to the set delivery portion of the rotary transfer path. A feed passage 16 communicating from the rotational radius direction is formed, and a feed guide surface 16a of the feed passage 16 is formed on the same plane as the transfer guide surfaces 6A to 6C of the mounting portion 6 and A chute 16b is provided on the outlet side of the passage 16 to guide the discharged disk-like body 1 to a predetermined location in a downhill state.

  As shown in FIGS. 1, 2, and 8 to 12, the delivery means B is configured so that the setting delivery sites of the transfer guide surfaces 6 </ b> A and 6 </ b> B on the inner side and the center side in the rotational radius direction of the mounting portion 6 are provided. A cylindrical first member that enters into the through hole 7 of the rotary transfer body 8 and contacts the disk-like body 1 transferred along the rotary transfer path to feed the disk-like body 1 outward in the rotational radial direction. The first and second delivery guide bodies 17 and 18 are provided, and the second delivery guide body 18 provided on the transfer guide surface 6B on the central side in the rotational radius direction is provided on the transfer guide surface 6A on the inner side in the rotational radius direction. The first delivery guide body 17 is disposed on the lower side in the rotational direction (before rotation) than the first delivery guide body 17.

  Each delivery guide body 17, 18 is rotatably supported by a contact force with the disk-like body 1 entering the through hole 7 of the rotary transfer body 8 and being transferred along the rotary transfer path. A tip guide portion that protrudes upward from at least the transfer guide surfaces 6A to 6C of each delivery guide body 17 and 18 and abuts against the disk-like body 1 is formed in a cylindrical surface, and a tip guide of each delivery guide body 17 and 18 is formed. The protrusion margin of the part is configured to be the same as or substantially the same as the thickness of the disc-like body 1.

  And with respect to the front-end | tip guide part of both the delivery guide bodies 17 and 18 which protrudes upwards rather than the transfer guide surface 6A-6C of the mounting part 6, it penetrates in the through-hole 7 of the rotation transfer body 8, and transfer guide surface 6A- When the disc-like body 1 transferred along 6C comes into contact, the disc-like body 1 is slidably guided along the circumferential surface of the tip guide portion of the delivery guide bodies 17 and 18, and this Since the delivery guide bodies 17 and 18 are rotated by the contact force with the disc-like body 1, the disc-like body 1 is moved outward in the rotational radial direction against a large load acting on the delivery guide bodies 17 and 18. The delivery can be guided reliably and smoothly.

  Moreover, since the position of contact with the disk-like body 1 that has been transferred into the through hole 7 of the rotary transfer body 8 is changed by the rotation of the respective delivery guide bodies 17 and 18, the respective delivery guide bodies 17 and 18 are changed. It is possible to suppress wear and loss of 18 and maintain excellent delivery guiding performance over a long period of time.

  When a pressing force more than a set value is applied to the delivery guide bodies 17 and 18 via the disc-like body 1 that abuts from the direction along the transfer guide surfaces 6A to 6C, the delivery guide bodies 17 and 18 are moved to it. A passage permitting means E is provided for changing the posture to allow the passing movement of the disk-shaped body 1 in contact.

  The passage permitting means E is a movable support mechanism that supports each of the delivery guide bodies 17 and 18 in a state of permitting the backward movement in the direction along the transfer guide surfaces 6A to 6C and the retraction movement toward the inner side of the base 2. E1 and a retraction guide mechanism E2 that retreats the delivery guide bodies 17 and 18 to the inner side of the base 2 as the delivery guide bodies 17 and 18 move backward.

  The movable support mechanism E1 of the passage permitting means E includes a movable support 21 provided with the delivery guide bodies 17 and 18 arranged on the inner side of the base 2, and the movable support 21 with transfer guide surfaces 6A to 6C. And a coil spring 22 that is an example of an elastic biasing body that is supported so as to be movable in the retracting direction and the retracting direction.

  The movable guide 21 is provided with the delivery guide bodies 17 and 18 from the side where the disc-like body 1 transported along the delivery guide surfaces 6A to 6C of the mounting portion 6 contacts the delivery guide bodies 17 and 18. A fitting support portion 21A that is rotatably fitted and supported in a detachable state, and the disk-like body 1 that transports the delivery guide bodies 17 and 18 along the transfer guide surfaces 6A to 6C of the mounting portion 6. A backup receiving portion 23 that is rotatably received and supported while being detachable from the side opposite to the abutting side is integrally formed, and each receiving portion 23 has a corresponding delivery portion. An arcuate rotation guide receiving surface 23 a is formed along the outer peripheral surfaces of the guide bodies 17 and 18.

  The retraction guide mechanism E2 of the passage permitting means E intersects with the retreating movement direction at the time of the retreating movement of each of the delivery guide bodies 17 and 18 at the opposite part of the mounting portion 6 of the base 2 and the movable support 21. An inclined guide portion 24 for reciprocating and guiding the movable support 21 by sliding relative to the inclined direction is formed.

  The coil spring 22 of the movable support mechanism E1 is arranged so as to be biased toward the backward movement side with respect to the axis (cylindrical center line) of each delivery guide body 17 and 18.

    As shown in FIGS. 1, 2, and 8 to 11, each of the delivery guide bodies 17, 18 is provided in the second mounting recess 25 that opens upward and is formed in the set delivery site of the mounting portion 6 in the base 2. And the delivery guide unit case 26 assembled with the passage allowing means E is detachably mounted.

  Further, on the outer peripheral side of the lower surface of the rotary transfer body 8 and at a position corresponding to the adjacent portion of the through hole 7, the disk-like body 1 sent out in the rotational direction by the second delivery guide body 18 is sent out to the delivery passage. An arcuate delivery protrusion 19 is further formed integrally to feed outward in the rotational radius direction toward the 16 side.

  The delivery protrusion 19 is disposed at a position slightly biased to a position on the upper side in the rotational direction (rear position after rotation) with respect to the pressing wall portion 14A located corresponding to the inner side in the rotational radius direction of the delivery projection 19 and the delivery guide thereof. The surface 19a is formed in an arcuate surface or an inclined surface that is positioned on the upper side in the rotational direction (rear side after rotation) toward the outer side in the rotational radius direction.

  Arc-shaped receiving recesses 31 a that come into contact with the disk-shaped body 1 to be fed out are formed at a plurality of circumferential positions (three positions in the present embodiment) of the rotation sensor 31 of the passage sensor C.

  The rotation position holding means D is provided on the outer peripheral surface of the rotating body 33 that rotates integrally with the rotation detecting body 31 of the passage sensor C in a central angle range corresponding to the passing movement range of the disc-like body 1. A plurality of (three in this embodiment) arc-shaped recesses 33a formed in a circular arc shape on the rotation axis side of the rotating body 33 and a roller 34 engageable with the arc-shaped recess 33a of the rotating body 33 on one end side And a second coil spring 36 that is an example of an elastic biasing member that biases the arm 35 toward the engagement side.

  Further, a circle sent out on an extension line passing through the first and second delivery guide bodies 17 and 18 on the side of the delivery path 16 at the lower peripheral side (pre-rotation position) of the delivery passage 16 at the outer peripheral edge of the mounting portion 6. A feed roller 37 that feeds the plate-like body 1 to the entrance of the feed passage 16 and a third coil spring 38 that moves and biases the feed roller 37 to the protruding side are arranged.

[Second Embodiment]
In the first embodiment described above, the outer receiving portion 10B is formed in an annular shape, and a plurality of objects formed on the rotary transfer body 8 are formed at a plurality of locations in the rotational direction of the outer receiving portion 10B. The locking portion 12 that is engaged with the locking portion 11 from the lower side in a secured state is integrally formed. However, as shown in FIG. 13, the outer receiving portion 10B is divided into a plurality of portions in the rotational direction. The resin-made divided receiving members are configured to be engaged with each of the divided receiving members from the lower side in a fixed state with respect to the plurality of locked portions 11 formed on the rotary transfer body 8. The part 12 may be integrally formed.
In addition, since the other structure is the same as the structure demonstrated in 1st Embodiment, the same number is attached to the same structure location as 1st Embodiment, and the description is abbreviate | omitted.

[Other Embodiments]
(1) In the above-described first embodiment, the rotary transfer body 8 in which the plurality of through holes 7 into which the disk-like body 1 can enter is described as an example, but instead of the through holes 7. You may implement using the rotational transfer body 8 in which the notch part opened to a rotation direction outer side is formed.

  (2) In the first embodiment described above, the inner receiving portion 10A is integrally formed with the rotary transfer body 8, and the outer receiving portion 10B is formed separately from the rotary transfer body 8. The outer receiving portion 10B is integrally formed with a plurality of locking portions 12 that engage with the plurality of locked portions 11 formed on the rotary transfer body 8 from the lower side in a secured state. However, the outer side receiving portion 10B is integrally formed with the rotary transfer body 8, and the inner side receiving portion 10A is formed separately from the rotary transfer body 8, and this inner side receiving portion is formed. A plurality of locking portions 12 that are engaged with the plurality of locked portions 11 formed on the rotary transfer body 8 from the lower side in a secured state may be integrally formed with 10A.

  (3) Furthermore, the outer receiving portion 10B and the inner receiving portion 10A are formed separately from the rotary transfer body 8, and the outer receiving portion 10B and the inner receiving portion. Even if each of 10A is integrally formed with a plurality of locking portions 12 that are engaged with the plurality of locked portions 11 formed on the rotary transfer body 8 from the lower side in a secured state. Good.

  (4) In the above-described first embodiment, in a plurality of portions in the rotation direction of the outer receiving portion 10B, with respect to the plurality of locked portions 11 formed on the rotary transfer body 8, in a retaining and fixed state. The locking portion 12 that engages from below is integrally formed. The locking portion 12 is formed separately from the outer receiving portion 10B, and the separately formed locking portion 12 is formed outward. You may attach to the predetermined location of the side receiving part 10B.

  (5) In the first embodiment described above, the width of the outer receiving portion 10B in the rotational radius direction is formed smaller than the width of the inner receiving portion 10A in the rotational radius direction. The width of the side receiving portion 10B in the rotational radius direction may be the same as or larger than the width of the inner side receiving portion 10A in the rotational radius direction.

  As described above, the disk-shaped body that can reduce the resin molding cost of the disk-shaped body and improve the efficiency of the assembly work while suppressing the biting of the two disk-shaped bodies satisfactorily. A feeding device can be provided.

DESCRIPTION OF SYMBOLS 1 Discoid body 2 Base 6 Mounting part 6A Transfer guide surface 6B Transfer guide surface 6C Transfer guide surface 7 Through-hole or notch 8 Rotating transfer body 10A Receiving part 10a on the inner side in the radial direction of rotation 10a Mounting support part 10B Receiving portion 10b on the outer side in the rotational radius direction 10b Placement support portion 11 Locked portion 11c Release operation port 12 Locking portion

Claims (5)

The mounting portion of the base is provided with a plurality of through holes or notches into which the disc-like body can enter, and the disc-like body that has entered into the through holes or the notch portions is transferred to the mounting guide. A resin-made rotary transfer body that is transferred in a pressed state in the rotational direction along the lower surface of the rotary transfer body, and an inner side portion in the rotational radial direction and the rotational radial direction in the through hole or notch A resin-made receiving portion having a mounting support surface capable of mounting and supporting the inner side and the outer side in the rotational radius direction of the disk-like body that has entered into the through hole or notch in the outer side portion. And a sending means for sending the disk-like body that has entered the through-hole or the notch of the rotary transfer body and is transferred outward in the rotational radial direction at the set-up delivery site of the rotary transfer path. A disc-shaped body feeding device provided,
Of the two receiving portions, at least the receiving portion located on the outer side in the rotational radial direction or the inner side in the rotational radial direction is formed separately from the rotary transfer body, and at least the outer side in the rotational radial direction or the rotational direction. The receiving portion on the inner side in the radial direction is formed with a locking portion that engages with the locked portion formed on the rotary transfer body from the lower side in a secured and fixed state. A disk in which the vertical distance between the mounting support surface of the receiving part and the lower surface of the rotary transfer body is set such that only one disk-like body that has entered the through-hole or the notch part can move through. A state feeding device.   The disc-shaped body feeding device according to claim 1, wherein at least a receiving portion on the outer side in the rotational radial direction or the inner side in the rotational radial direction formed separately from the rotary transfer body is configured to be able to bend and deform.   On the upper surface of the rotational transfer body, at least the engaging portion of the receiving portion on the outer side in the rotational radial direction or the inner side in the rotational radial direction engaged with the locked portion of the rotational transport body is disengaged. The disc-shaped body feeding device according to claim 1 or 2, wherein a release operation port is formed.   The locking portion of the receiving portion on the outer side in the rotational radius direction or the inner side in the rotational radius direction is configured to engage with the locked portion of the rotary transfer body from the inner side in the rotational radius direction. The disc-shaped body feeding device according to any one of claims 1 to 3.   The locked portion is provided at a side portion on the lower side in the rotation direction of each through hole or notch in the rotary transfer body, and at least the rotation radial direction outer side or the rotation radial direction inner side. The receiving portion is formed in an annular shape, and at least the receiving portion on the outer side in the rotational radius direction or the inner side in the rotational radius direction is integrally formed with a plurality of the locking portions corresponding to the locked portions. The disc-shaped body feeding device according to any one of claims 1 to 4.

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