JP2008033723A5 - - Google Patents

Description

Disc guide device

The present invention relates to an improvement in a disc guide device that guides discs arranged in a row with their peripheral edges in contact, and selectively distributes them to the left and right of a guide path.
Note that the “disc” used in this specification includes coins as currency, substitute money such as medals and tokens for game machines, and the like.

As conventional techniques, guide path means for guiding the disks in a line, opening / closing means for pushing out the disk disposed in the opening above the path means, a distribution path into which the disk extruded from the opening enters, A disk comprising sorting means for distributing and guiding the disk from one of the paths to one of the two paths, a disk ejected from the opening into the sorting path, a driven body disposed at a position where the disk hits, and a sensor for detecting the driven body What is provided with the detection means is known.
In this conventional apparatus, the disk is pushed up the passage means and reaches the opening.
The disc is pushed by the opening / closing means at the opening and moved from the passage means to the distribution passage.
In this process, since the body is moved by being pushed by the disk, it detect that the disk has been released by detecting the movement of the moving object.
Thereafter, the disc is selectively distributed to the left and right with respect to the passage means by the distributing means. (For example, refer to Patent Document 1).

Japanese Patent Laying-Open No. 2005-74098 (FIG. 1-6, page 4-9)

In the case of the above-described prior art, the disc is an opening above the guide passage and is pushed by the opening / closing means in the disc thickness direction, that is, the disc surface direction, and is moved from the guide passage to the sorting passage.
The disc is pushed up the guide passage and is moved as described above when the entire disc substantially coincides with the opening.
The sensor is then activated by the disk.
In the prior art, there is an advantage that the allowable range of the stop position of the disk increases.
However, there is a possibility that the disk will vigorously rebound due to the collision reaction and the sensor will detect multiple times.

  Therefore, the conventional apparatus that pushes the disk in the surface direction of the disk and sorts and discharges may cause the malfunction of the sensor as described above, and may cause a problem that the disk discharge control is not performed well. .

The present invention has been made in view of the above problems .
An object of the present invention is to provide a disc guide device that can accurately detect a disc dispensed from a guide passage, and can smoothly sort and eject the disc.
It is another object of the present invention to provide a disc guide device that can be compacted by constructing the disc with a simple configuration and mechanism by sorting the discs in the circumferential direction.

In order to achieve this object, the present invention comprises the following constituent elements.
A guide passage to guide and align the disk in a row, a discharge passage and release means of the disc to be released from the outlet of the guide path the disc in the circumferential direction, is released the disc is dropped guided, the release comprising a structure including a detection means for detecting the disk released in the passage, and the sorting path in which the disc from the discharge path is sorted discharged, the distributing means of the disc provided in the sorting path It is a disk guide device.
According to this arrangement, the disk when it is released into the discharge path by the release means from the guide channel, has become those distributed by distributing means in the sorting path, by extremely simple channel structure, by distributing the disc eject can do.
For this reason, the disk guide device can be provided at low cost.
Disc ejection is detected independently by the disc detection means disposed in the ejection path regardless of the operation of the disc ejection means, so that the disc can be detected stably and accurately.
Since the disc is ejected so as to pass through the exit of the guide passage in the direction in which the disc has been guided, even if the disc is slightly stuck to the exit, it does not greatly hinder the operation of the discharge means.
Therefore, since the disk can be ejected regardless of the position of the uppermost disk, even if the disk size is changed, it is not necessary to change the length of the guide path.

The present invention also includes a base plate serving as a passage plate, a guide passage formed along the base plate for guiding the disks aligned in a row, and biased toward the guide passage side at the exit of the guide passage. Disc discharge means, a discharge passage formed adjacent to the guide passage so as to guide a disc discharged laterally from the guide passage, a distribution passage communicating with the discharge passage, and the discharge passage Detecting means for detecting a disk passing through the first passage, a first passage and a second passage located below the distribution passage, an introduction opening for introducing the disk from the discharge passage to the distribution passage, and the vibration passage A distribution means for selectively switching and communicating the first passage and the second passage with respect to the branch passage, and bending the guide passage toward one side with respect to the base plate in the vicinity of the outlet. The discharge passage having a rectangular cross section parallel to the guide passage is formed in the space on the base plate which is vacated by the shift of the guide passage, and the distribution passage is formed in parallel with the discharge passage. A disk guide device is preferred .

With this configuration, if the guide passage is bent near the outlet and moved toward one end of the base plate, the passage is shifted.
A space vacated by the shift of the passage can be secured on the side opposite to the guide passage on the base plate.
Therefore, using this space, it is possible to form in parallel a discharge passage as a relay passage from the guide passage until the disc is discharged to the outside and a distribution passage from which the disc is discharged from the discharge passage. Since the discharge passage and the distribution passage can be installed within the width of the base plate, it is possible to provide an escalator device having a small overall width and to be made compact.

The discharge passage is provided with a detecting means for the disk, and the introduction opening is disposed at a position downstream of the detection means, and an introduction guide for guiding the disk to the introduction opening is provided. A disk guide device is preferred .
In the detection of the disc, since the disc detection device detects the released disc, it is not necessary to adjust the length of the guide path even if the size of the disc is changed.
The disc enters the distribution passage through its introduction opening due to its own weight in the process of dropping, and there is no conventional opening / closing means for pushing the disc into the opening. Further, since there is no disk detecting means that strokes in the thickness direction of the passage, the apparatus can be made thin.
Further, since there is an introduction guide for guiding the disc to the introduction opening in the discharge passage, it is possible to perform simple guidance of the disc from the guide passage to the distribution passage. Moreover, the disc can be smoothly dispensed.

Further, the guide passage is constituted by a rectangular base plate, a holding plate that is substantially the same shape as the base plate facing the base plate, and a pair of spacers disposed between the base plate and the holding plate so as to separate the passage width of the disk. The discharge passage is defined as a space having a rectangular cross section parallel to the guide passage between the base plate and the holding plate, and the guide passage is straight at a predetermined angle at the front end portions of the pair of spacers facing each other. It is preferable that the disk guide device has an inclined guide for forming a deflection passage bent from the passage.

According to this configuration, the pair of spacers having inclined guides facing each other at the tip end portions are arranged so as to be offset between the base plate and the holding plate having the same shape as the base plate. It is possible to easily form a guide passage that shifts to one end of the guide.
Thereby, a space can be made next to the guide passage. Utilizing this space, a rectangular space extending in parallel with the guide passage is defined between the base plate and the holding plate. This space can be used as a discharge passage. Even if the base plate is not wide, the guide passage and the discharge passage can be installed in parallel within the plate width, so that the conventional base plate can be used, and there is an advantage that it can be provided at low cost.

In addition, the introduction opening is provided by forming an opening in the base plate constituting a part of the discharge passage, and the introduction guide is formed by bending a part of the holding plate obliquely downward toward the introduction opening. It is preferable that the disc guide device be provided .
According to this configuration, as a means for guiding from the discharge passage to the distribution passage, it can be achieved simply by forming the introduction opening in the base plate, so there is no need to provide a disc pushing means such as a conventional opening / closing means. . Therefore, a simple configuration can be achieved.
Similarly, the introduction guide can be easily provided directly on the plate by bending a predetermined portion of the holding plate. Since the introduction guide is an inclined plate that faces obliquely downward toward the introduction opening, the disk is guided to the introduction opening while falling through the holding passage and smoothly enters the sorting passage. Even if the introduction guide protrudes into the discharge passage, it does not affect the passage of the disk because it is at a position slightly downstream of the introduction opening at a position downstream of the passage.

A base plate serving as a passage plate; a guide passage formed along the base plate for guiding the discs in a line; and a disc discharge means that is positioned at the exit of the guide passage and is biased toward the guide passage. A discharge passage for guiding a disk discharged laterally from the guide passage, a distribution passage communicating with the discharge passage, a detection means for detecting a disk passing through the discharge passage, and a distribution passage A first passage and a second passage positioned below, an introduction opening for introducing a disc from the discharge passage to the distribution passage, and the first passage and the second passage selectively with respect to the distribution passage. Distribution means for switching and communicating with the base plate, the guide passage is bent toward one side with respect to the base plate in the vicinity of the outlet, and the passage is shifted. Discharge passage having a rectangular cross section running parallel to the guide path in the space on the plate to form a disc guiding apparatus the formation of the sorting path in parallel with the discharge path.

Hereinafter , a disk guide device according to an embodiment of the present invention will be described with reference to the drawings.
1 is an overall perspective view of a hopper equipped with a disk guide device according to an embodiment of the present invention, FIG. 2 is a perspective view of the disk guide device of the present invention, and FIG. 3 is a perspective view of the disk guide device of the present invention from which a holding plate is removed. 4 and 4 are perspective views of the disk guide device of the present invention as seen from the back side.
5 is a perspective view of the disk guide device of the present invention from which the plate cover is removed as seen from the back side, FIG. 6 is a front view of the disk guide device of the present invention, and FIG. 7 is a plan view of the disk guide device of the present invention. 8 is a left side view of the disk guide device of the present invention, FIG. 9 is a rear view of the disk guide device of the present invention, and FIG. 10 is a right side view of the disk guide device of the present invention.
FIG. 11 is an exploded perspective view showing components on the front side where the guide passage of the disk guide device of the present invention is provided, and FIG. 12 shows the distribution passage of the disk guide device of the present invention. FIG. 13 is a front view of the disk guide device of the present invention, and FIG. 14 is a sectional view taken along line BB in FIG.

First, in FIG. 1, a hopper 1 is fixed to the frame 2, a cylindrical bowl 3 that stores the disk d, and a rotating disk (not shown) for feeding the disk d that rotates at the bottom of the bowl 3. )).
The hopper 1 is disclosed in, for example, Japanese Patent Laid-Open No. 6-150102.
An escalator device 5 extending upward is fixed to the frame 2.
The escalator device 5 has a vertically long base 5a, a pair of elongated plate spacers (not shown) slightly thicker than the thickness of the disk d, and a pair of support plates 5b and 5c applied to the spacers.
The distance between the pair of spacers is slightly larger than the diameter of the disk d.
The distance between the support plates 5b and 5c is narrower than the distance between the spacers.
The screws 6 that penetrate the support plates 5b and 5c and the spacer are screwed into the base 5a so as to be integrated.
An escalator guide passage 7 is a space extending in the vertical direction of a rectangular cross section surrounded by the base 5a, the spacer, and the support plates 5b and 5c.

A sorting device 10 is attached to the upper end of the escalator 5.
Next, the sorting apparatus 10 will be described with reference to FIGS.
The distribution device 10 has a function of selectively distributing the disc d guided to the escalator guide passage 7 to the left and right thereof.
The sorting apparatus 10 includes a guide passage 20, an outlet 30 serving as a disc discharge port, a disc discharge means 40, a discharge passage 60, an introduction opening 70, a distribution passage 80, a first passage 90, a second passage 110, and a passage selection. The apparatus 120 and the disk detection means 130 are included.
First, the guide passage 20 will be described.
The guide passage 20 has a function of guiding the disk d guided by the escalator guide passage 7 in a predetermined direction.
As shown in FIGS. 2, 11, 14, etc., a rectangular base plate 21 whose lower end portion is formed in a crank shape is disposed substantially vertically.
Spacers 22 and 23 having different lengths are arranged in parallel in the vertical direction on the front side 21H of the base plate 21 (see FIGS. 3 and 7).
A guide spacer 24, which is a third spacer, is disposed on the extended line of the shorter spacer 23.

As shown in FIG. 6, the longer spacer 22 includes a linear guide portion 22a, an inclined guide portion 22b that is bent obliquely at a predetermined inclination angle, and a linear guide that is parallel to the linear guide portion 22a and has a short length. It is a vertically long rectangle including the portion 22c.
In addition, on the outside of the tip end portion of the short straight guide portion 22c, the disk d discharged from the outlet 30 (described later) at the tip end of the guide passage 20 to the side tends to roll down to the discharge passage 60 described later. A rolling guide portion 22e curved downward is formed.
On the other hand, the shorter spacer 23 is a vertically long rectangle including a straight guide portion 23a and an inclined guide portion 23b formed at the tip of the straight guide.
The inclined guide portion 23 b of the spacer 23 is formed at the same angle as the inclined guide portion 22 b of the spacer 22.
Further, the straight guide portion 23a of the spacer 23 and the straight guide portion 22a of the spacer 22 have substantially the same length.

When mounting the two spacers 22 and 23 on the base plate 21, as shown in FIGS. 3 and 6, the shorter spacer 23 extends along one side edge (left edge) 21L of the base plate 21. Arranged.
The long spacers 22 are then placed at a distance relative to the short spacers 23 so as to be slightly larger than the diameter of the disk d.
Thus, when the disk d that has traveled straight through the guide passage 20 by the deflection guide 22b of the spacer 22 and the guide edge 23b of the spacer 23 comes near the outlet 30 of the guide passage 20, the left side in FIG. A deflection passage portion 20b that is bent and guided is formed.
Further, on the upstream side of the deflection passage portion 20b, the straight guide portion 22a of the spacer 22 and the straight guide portion 23a of the spacer 23 are opposed to each other to form an inlet passage portion 20a.
Further, on the downstream side of the deflection passage portion 20b, a linear guide portion 22c of the spacer 22 and a passage guide cover piece 27k (see FIGS. 2 and 11) bent in an L shape of a holding plate 27 described later face each other. A short-length outlet passage portion 20c is configured.

An obliquely upward guide edge 24 b is formed inside the lower end portion of the guide spacer 24.
The guide spacer 24 is positioned relative to the distal end portion 22 f of the long spacer 22, and an outlet 30 is formed between the guide spacer 24 to discharge the disk d from the distal end of the guide passage 20 to the side.
The disk d exiting the guide passage 20 is guided to the outlet 30 by the guide edge 24 b of the guide spacer 24.

Note that the guide spacer 24 and the shorter spacer 23 positioned below the guide spacer 24 are spaced apart from each other in the vertical direction, so that the left side passage side wall of the guide passage 20 is missing at this separated portion.
However, the passage guide cover piece 27k of the holding plate 27 is fitted in the missing portion. That is, in order to fit the guide cover piece 25k, a locking step 35 (see FIG. 11) is cut out at the left side edge of the base plate 21.
The passage guide cover piece 27k of the holding plate 27 is fitted into the locking step portion 36, and a missing portion between the lower spacer 23 and the upper guide spacer 24 is captured by the guide cover piece 27k. Thus, the guide walls 20 are configured without being lost in the vertical direction.
The bending margin of the passage guide cover piece 27k that captures the guide passage 20 is larger than the thickness of the guide passage 20.

The base plate 21 is formed with an introduction opening 70 for guiding the disk d entering the discharge passage 60 from the outlet 30 from the discharge passage 60 to a distribution passage 80 described later.
As shown in FIG. 11, a rectangular holding plate 27 is applied to the surface side 21H of the base plate. A rectangular holding plate is applied to the surface side 21H of the base plate so as to sandwich the spacers 22, 23 and the guide spacer 24.
Screws (not shown) penetrating the holding plate 27, the spacers 22, 23 and the guide spacer 24 are screwed into the base plate 21 and integrated. When the guide spacer 24 is clamped and fixed between the base plate 21 and the holding plate 27, the disk discharging means 40 is also fixed to the surface side of the holding plate 28 at the same time with a screw for fixing the guide spacer.

Therefore, the base plate 21, the spacers 22 and 23, the guide spacer 24, and the holding plate 27 form a guide passage 20 that has a rectangular cross section and is bent near the discharge port 30 and extends in the vertical direction.
The guide passage 20 has a width slightly larger than the diameter of the disk d and a thickness slightly larger than the thickness of the disk d.

The guide passage 20 formed in this way bends to one side of the base plate 21 in the vicinity of the outlet 30, and the guide 30 has a structure in which the outlet 30 is shifted to one side (left side in FIG. 12) with respect to the inlet 31 of the guide passage 20. It is a passage 20.
Thus, the passage is bent and shifted to one end (left) side of the base plate 21, so that a space S (see FIG. 3) is created in the adjacent portion of the guide passage 20, that is, the right portion.
Using this space S secured on the base plate 21, it is possible to provide a discharge path 60 for the disk d next to the guide path 20.
Further, an introduction opening 70 can be provided in the space S, and a disk detection means 130 , a disk distribution path 80, and the like can be installed.
As a result, the constituent elements constituting the sorting apparatus 10 can be accommodated within the plate width of the base plate 21, and the escalator apparatus can be made compact.

Next, the disk ejecting means 40 will be described with reference to FIG.
The disc ejection means 40 includes a regulation roller 41, an arc-shaped guide slot 42 that guides the regulation roller 41 in a reciprocating manner, a pivot lever 44 that rotatably supports the regulation roller 41 on a shaft 43 at the tip, A mounting bracket 45 of the lever 44 and a stopper 46 of the rotating lever 44 are included.
The guide long holes 42 through which the regulating roller 41 is guided are formed in the base plate 21 and the holding plate 27, respectively.
As shown in FIG. 3, the rotating lever 44 is urged in a direction facing the outlet 30 by a string spring 48 provided on the fixed shaft 47. At that time, the lower end of the distal end portion of the rotation lever 44 abuts against a stopper 46 protruding horizontally from the mounting bracket 45 and is held in a horizontal state as shown in FIGS. A cushion material 49 (see FIG. 2) is provided on the upper surface of the stopper 46.

The disk d travels along the guide path 20, bends in an S shape at the deflection path 20 b, and then comes into contact with the regulating roller 41 when reaching the outlet 30.
The restriction roller 41 is pushed up by the disk d to move through the guide slot 42, and at the same time, the turning lever 44 is pushed up and turned away from the outlet 30 against the elastic force of the string winding spring 48.
When the diameter portion of the disk d passes through the discharge port 30 between the regulating roller 41 and the front end portion 22 f of the spacer 22, the rotation lever 44 is returned and rotated in the direction of the outlet 30 by the string winding spring 48.
At this time, the disc d is flipped sideways from the outlet 30 by the restriction roller 41 provided at the end of the rotation lever 44 and enters the discharge passage 60.
In this case, it is preferable to set the elasticity of the string spring 48 to such an extent that the disk d falls into the discharge passage 60 very naturally from the outlet 30 of the guide passage 20.
If the elastic force of the string spring 48 blows off the disk d with such a force that it strikes the side wall of the discharge passage 60, the durability of the device is reduced, and the disk d is released in the discharge passage 60, and the detection is good. This is because there is a problem that it is not performed.

The sorting apparatus 10 inserts the upper end portion of the base 5a of the escalator 5 into the vertically long space 8 (see FIG. 10) formed in the lower end portions of the base plate 21 and the spacers 22 and 23, and is fixed by a screw (not shown). It is.
When the sorting device 10 is fixed to the tip of the escalator 5, the spacers 22 and 23 are located on an extension of the spacer (not shown) of the escalator device 5.
Therefore, the guide passage 20 is located on an extension of the escalator guide passage 7.

Next, the discharge passage 60 will be described.
The discharge passage 60 is a passage through which the disk d discharged from the outlet 30 by the disk discharge means 40 is guided to fall.
The disk d enters an introduction opening 70 (described later) provided downstream of the discharge passage 60 in the middle of dropping.

The discharge passage 60 is disposed and formed in the upper right region 21R (see FIG. 11) of the base plate 21.
That is, as shown in FIG. 11, the discharge passage 60 is positioned so as to face the base plate 21, the extended surface 27 m of the upper right portion of the holding plate 27, the spacer 22, and the spacer 22. This is a space having a rectangular cross section defined and surrounded by a flange 21F protruding at a right angle at the right end of the base plate 21.
The space, that is, the discharge passage 60 extends in the vertical direction. Therefore, the discharge passage 60 is positioned next to the guide passage 20 and extends in the vertical direction.
The extending surface 27m of the holding plate 27 is positioned so as to cover most of the introduction opening 70. Further, the flange 21F of the base plate also functions as a mounting bracket for a disk detection sensor 131 described later.

An introduction guide 29 that faces the introduction opening 70 is provided at the lower end of the extended surface 27 m of the holding plate 27. The introduction guide 29 is formed by bending the lower end portion of the extending surface 27 m of the holding plate 27 obliquely downward toward the base plate side 21. The introduction guide 29 can be formed integrally with the holding plate 27 by a simple forming method called bending.
The introduction guide 29 guides the disk d from the discharge passage 60 to the rear distribution passage 80 in parallel with the discharge passage 60 through the introduction opening 70.
The introduction guide 29 has a width that is slightly shorter than the entire width of the introduction opening 70 and is bent toward the introduction opening 70, and therefore serves as a bottom plate member that closes the lower end of the discharge passage 60.

Next, the introduction opening 70 will be described.
The introduction opening 70 is an opening through which the disk d that has fallen into the discharge path 60 is introduced into the distribution passage 80. As shown in FIG. 11, an introduction opening 70 is formed in the upper right region 21 </ b> R of the base plate 21 so as to be largely cut into a substantially square shape.
The upper edge of the introduction opening 70 is formed in a downwardly inclined window edge 70d having a fitting notch 70c, and the upper part of the disk detection means 130 is fitted to the window edge 70d as shown in FIG. It is installed at an angle.
The width of the introduction opening 70 is larger than the diameter of the largest disk d used.
The height of the introduction opening 70 is preferably 1.5 to 2 times the diameter of the disk d in the extending direction of the discharge passage 60 so that the disk d is smoothly introduced.

As shown in FIG. 14, the introduction guide 29 is positioned so as to block the lower end of the discharge passage 60 at the lower position of the introduction opening 70, and crosses the introduction opening 70, that is, the rear side of the base plate 21, that is, the distribution. It enters and protrudes toward the passage 80.
For this reason, the disk d that has fallen through the discharge passage 60 slides down by the introduction guide 29 and is guided through the introduction opening 70 from the discharge passage 60 to the distribution passage 80 provided behind it. The

Next, the distribution passage 80 will be described with reference to FIGS. 2, 3, 4, 12 and 14.
In the distribution passage 80, a device for selectively separating the disk d entering from the discharge passage 60 through the introduction opening 70 into left and right is arranged.
As shown in FIGS. 2, 3, 4, etc., a channel-shaped guide channel 81 is provided in parallel in the thickness direction of the discharge passage 60 on the back surface 21 </ b> I side of the base plate 21.
As shown in FIG. 12, the guide channel 81 has a base plate 21, a bracket 21B in which the left end portion (in FIG. 12) of the base plate 21 is bent at a right angle, and an L shape fixed to the right end portion (in FIG. 12) of the base plate 21. The second bracket 85 and the plate cover 88 interposed between the bracket 21B and the second bracket 85 and positioned in parallel with the base plate 21 constitute a channel shape.

The base plate 21 and the plate cover 88 are formed by two upper and lower inverted L-shaped hook pieces 21x and 21x protrudingly formed on the bracket 21B of the base plate 21 so as to be cut out at two upper and lower portions on the plate cover 88 side. By engaging the stop portions 88y, 88y in a hook shape, it can be assembled into a channel shape.
The second bracket 85 has an attachment flange 85f applied to the base plate 21, and is fixed to the base plate 21 by a screw (not shown).
The stay 88t of the plate cover 88 is fixedly attached to the second bracket 85 with a screw (not shown).

Therefore, in the distribution passage 80, a space having a rectangular cross section is defined by the base plate 21, the base plate bracket 21B, the second bracket 85, and the plate cover 88. The space, that is, the distribution passage 80, extends in the vertical direction on the back portion 21 </ b> P of the base plate 21 in parallel with the discharge passage 60.
Therefore, the discharge passage 60 and the distribution passage 80 are juxtaposed in the thickness direction thereof.
In addition, there is a cover portion 88 c that is formed by cutting and raising a portion at an intermediate portion of the plate cover 88 and projecting obliquely to the distribution passage 60. As shown in FIG. 14, the cover portion 88 c has a hook shape extending obliquely downward toward the base plate 21 side.
Accordingly, the cover portion 88c is configured such that when a passage switching plate 122 described later swings to the plate cover 88 side and stops on the inner surface of the plate cover 88, the upper end portion 122u of the passage switching plate 122 is placed below the cover portion 88c. Position and hide.
This prevents the falling disk d from being caught. Therefore, the disk d is smoothly advanced to a predetermined path.

Next, the first passage 90 and the second passage 110 will be described.
As shown in FIGS. 5, 8, 9, 12, 14, and the like, below the distribution passage 80, a first guide plate portion 71 (see FIGS. 9 and 12) that is inclined rightward between the base plate 21 and the plate cover 88. ) And a second guide plate portion 72 inclined to the left (see FIG. 9) is disposed with a rectangular separate plate 73 integrally formed on the left and right surfaces of the vertical partition wall 73D.
The screw (not shown) penetrating the left end of the plate cover 88 and the separate plate 73 is integrated into the base plate 21 by screwing.

  In this case, the plate cover 88 and the separate plate 73 are screwed and fixed at one end side (left end side) where the mounting holes 78 and 78 (see FIGS. 5 and 12) are fixed. In order to secure the fixing, as shown in FIG. 12, a fixing rib 74 is projected on the upper end surface of the separation plate 73 on the right end side, and the fixing rib 74 is provided on the lower end of the second bracket 85. This is a structure (see FIG. 10) engaged with the formed pressing protrusion 86.

The first guide plate portion 71 has a first guide surface 75 that is lowered to the right (indicated by a chain line that is lowered to the right in FIG. 9), and is slightly thicker than the thickness of the disk d.
Therefore, the base plate 21 and the separate plate 73 define a first passage 90 whose right end surface is the first outlet 91 in FIG.
The first outlet 91 opens to the left end surface when viewed from the front.

The second guide plate portion 72 is opposite to the first guide plate portion 71, has a second guide surface 76 that is left-downward (indicated by a chain line that is left-downward in FIG. 9), and a disc. It is slightly thicker than the thickness of d.
Therefore, the plate cover 88 and the separate plate 73 define a second passage 110 whose left end surface is the second outlet 111 in FIG.
The second outlet 111 is open to the right end surface when viewed from the front.
Therefore, the discharge passage 60, the first passage 90, and the second passage 110 also have a passage structure arranged in parallel in the thickness direction thereof.
As a result, the thickness of the sorting device 20 can be made as thin as possible.
The heights of the first passage 90, the first outlet 91, the second passage 110, and the second outlet 111 are configured to be larger than the maximum diameter disc d used.
The passage of the disk d and its outlet can be three or more.
In that case, the passage selection device 120 can also be assigned according to the number of passages.

Next, the passage selection device 120 will be described.
The passage selection device 120 has a function of selectively guiding the disk d moving in the distribution passage 80 to the first passage 90 or the second passage 110.
The passage selection device 120 according to the embodiment is a passage switching device 121 and includes a rectangular passage switching plate 122 and its swing drive device 125.
The passage switching plate 122 is a lower portion of the sorting passage 80, and a lower end portion thereof is positioned on an extension of the separation plate 73.

As shown in FIG. 12, one shaft 122 a protruding from the lower end portion of the passage switching plate 122 is in the shaft hole 123 provided at the lower end of the bracket 21 </ b> B of the base plate 21, and the other shaft 122 b is the lower end of the second bracket 85. Are respectively inserted into shaft holes 126 and pivotally attached so as to be swingable.
From the right end of the passage switching plate 122 where the shaft 122b is provided, an operating pin 127 for swinging the passage switching plate 122 projects from a position slightly above the shaft 122b.
The operation pin 127 is loosely fitted in a long hole 128 provided in the second bracket 85.
The passage switching plate 122 is formed in a convex shape with the upper end portion 122u being narrowed, and is located substantially at the full width of the sorting passage 80.

The upper end portion 122u of the passage switching plate 122 is located below the cover portion 88c when the passage switching plate 122 pivots clockwise in FIG. 14, and is hidden under the cover portion 88c so that the disk d is not caught. It is like that.
This is because the passage switching plate 122 is elastically held by a weak spring at this position, so even if the passage switching plate 12 moves slightly, the upper end 122u does not come off the cover 88c, This is for surely guiding to a predetermined passage.

Next, the swing drive device 125 of the passage switching plate 122 will be described (see FIGS. 8 and 9).
A teardrop-type crank 52 is rotatably supported on a shaft 51 protruding from the second bracket 85.
One end of an arm 53 is pivotally attached to a shaft 52b fixed to the end of the crank 52. The operating pin 127 protruding from the upper side of the shaft 122b of the passage switching plate 122 to the side is inserted into the shaft hole 53b provided in the other end portion of the arm 53.
As a result, when the crank 52 pivots about the shaft 51, the passage switching plate 122 is pivoted via the operating pin 127.
The passage switching plate 122, the crank 52, and the arm 53 are preferably molded from a resin such as nylon for weight reduction.
When these parts are reduced in weight, the passage switching plate 122 can be moved quickly.

A solenoid 100 is fixed to the second bracket 85. An operation plate 105 is connected and fixed to the plunger 101 of the solenoid 100 by a fixing pin 106. A connecting pin 102 for connecting to the crank 52 is provided at an intermediate portion of the operation plate 105.
The crank 52 is provided with a substantially L-shaped metal plate (described later) 56 on one side thereof. An attachment hole (not shown) is provided at one end of the metal plate 56, and the connection pin 102 of the operation plate 105 is inserted into the attachment hole.
Accordingly, the crank 52 is connected to the operating plate 105 via the connecting pin 102, and the crank 52 swings around the shaft 51 by the linear reciprocating motion of the plunger 100.
The plunger 101 of the solenoid 100 is always pulled down by a compression spring 104 disposed between a pin 103 fixed to the lower end portion of the operation plate 105 and a flange 85f bent into an L shape at the lower end portion of the second bracket 85. .
The solenoid 100 is selectively excited or demagnetized by a control device (not shown).
When the solenoid 100 is demagnetized, the plunger 101 is in the lowest position by the spring 104.
Accordingly, the crank 52 is rotated counterclockwise around the shaft 51 in FIG. 8 via the connecting pin 102, and the arm 53 moves forward in the right direction in FIG. For this reason, the passage switching plate 122 is swung within the hole width of the long hole 128 via the crank 52, the arm 53, and the operation pin 127, and is at the chain line position as shown in FIG.
Therefore, when the passage switching plate 122 is at this chain line position, the first passage 90 is closed by the passage switching plate 122 and the second passage 110 is opened.
At this time, the upper end 122u of the passage switching plate 122 is located below the introduction guide 29 so that the falling disk d is not caught.

When the solenoid 100 is energized, the plunger 101 is pulled upward, so that the crank 52 is rotated clockwise around the shaft 51 via the connecting pin 102, and the arm 53 is pulled back leftward in FIG. .
Therefore, the passage switching plate 122 swings in the reverse direction within the hole width of the long hole 128 via the crank 52, the arm 53, and the operating pin 127, and is rotated clockwise from the chain line position shown in FIG.
Therefore, in the passage switching plate 122, the first passage 90 is opened and the second passage 110 is closed. At this time, the upper end 122u of the passage switching plate 122 is positioned under the cover 88c so that the falling disk d is not caught.

A position detector 280 for confirming the position of the passage switching plate 122 is provided.
The position detection device 280 is a transmission type sensor 280S that detects the position of the crank 52.
In this embodiment, when the solenoid 100 is demagnetized, the crank 52 is detected by the sensor.
That is, as shown in FIG. 10, a substantially inverted L-shaped metal plate 56 is mounted on one surface side of the crank 52. The metal plate 56 has a substantially inverted L shape, and in FIG. 10, the action piece portion 56b of the metal plate 56 is located in the upward U-shaped groove 280m of the sensor 280S so as to shield the optical axis. This is a state where the part 56b is detected.
When the solenoid 100 is energized, the crank 52 is pivoted so as not to be detected by the sensor 280S.
That is, the crank 52 rotates clockwise in FIG. 8, and the action piece portion 56b of the crank 52 exits from the groove 280m of the sensor 280S, and the action piece portion 56b is not detected.
However, it can be reversed.
The position detection device 280 is fixed to a flange 88f formed by bending the lower end portion of the plate cover 88 at a right angle.

Next, the detection means 130 for the disk d will be described. As the detection means 130, a transmissive photoelectric sensor 131 can be used.
The detection sensor 131 has a bifurcated case body 131D as shown in FIG. 11, and has a structure in which a light projecting part and a light receiving part are provided at the front part of the bifurcated case parts 131a and 131b.
As shown in FIG. 3, the detection sensor 131 is inclinedly installed in the discharge passage 60 at a position between the outlet 30 and the introduction opening 70.
In this case, the light projecting unit and the light receiving unit are disposed across the discharge passage 60.
When the disk d passes through the discharge passage 60 and passes between the light projecting portion and the light receiving portion of the detection sensor 131, the optical axis is blocked. As a result, the disk d is detected, and a disk detection signal is issued from the detection sensor 131.

The detection sensor 131 is attached and fixed to the sensor attachment bracket 133 by a screw (not shown).
An L-shaped flange 133f is integrally bent to the sensor mounting bracket 133. The base plate 21 is provided with flanges 21F at right angles.
Therefore, the L-shaped flange 133f of the sensor mounting bracket 133 is attached to the flange 21F and fixed by a screw (not shown).
As a result, the detection sensor 131 is mounted and fixed to the base plate 21 as shown in FIGS.
As the detection sensor 131, a reflective photoelectric sensor, a proximity sensor, a microswitch, or the like can be used as long as it can detect a disk.

Next, the operation of the embodiment will be described.
First, the operation when the passage switching plate 122 closes the first passage 90 as shown by the chain line in FIG. 14 will be described.
That is, the solenoid 100 is demagnetized, the plunger 101 is pushed down by the spring 104, and as a result, the second passage 110 is open.
In this state, the rotating disk rotates and feeds the disks d to the escalator guide passage 7 one by one.
The disks d are arranged in a row with their peripheral surfaces in contact with each other in the escalator guide passage 7.

The disk d is sequentially pushed up by the disk d newly fed from the rotating disk and reaches the guide path 20.
When the disc d is above push up the guide passage 20 is closer to the outlet 30, the flow proceeds to curve to the left direction by the deflection path part 20b, exiting the deflection path part 20b, the process proceeds straight upward again by the outlet passage portion 20c.
Then, the uppermost disk d in the guide passage 20 pushes up and rotates the regulating roller 41, and rotates the rotation lever 44 counterclockwise from the position shown in FIGS.

As the disk d is further pushed up and the disk d reaches the outlet 30, the rotation lever 44 is further rotated upward.
When the diameter portion of the disk d passes through the outlet 30, the disk d is elastically discharged from the outlet 30 to the discharge passage 60 by the regulating roller 41 when the turning lever 44 is returned by the string winding spring 48.

The disk d that has come out to the discharge passage 60 falls by its own weight, passes through the forked part of the detection sensor 131 in which the light projecting part and the light receiving part are arranged in the middle of the fall, and at that time the optical axis of the sensor is blocked. A detection signal is output.
The control device (not shown) counts this detection signal. The disc d that has passed through the detection sensor 131 reaches the introduction opening 70, and at the same time, by the introduction guide 29 that is inclined toward the distribution passage 80 , the distribution passage 80 is provided. Be guided to. The disk d further falls in the distribution passage 80 by its own weight, and is guided to the second passage 110 by the passage switching plate 122.
The disk d that has reached the second passage 110 rolls on the second guide surface 76 and is discharged from the second outlet 111.
When the above-described operation is continued and the count number of the disk d reaches a predetermined value, the control device stops the rotation of the rotating disk d.

When the disk d is paid out from the first outlet 91, the solenoid 100 is excited by a control device (not shown), and as a result, the passage switching plate 122 is pivotally moved from the chain line position in FIG. 10 to the opposite side (clockwise). The second passage 110 is closed and the first passage 90 is opened.
As described above, the disk d that has entered the discharge passage 60 from the guide passage 20 is detected by the sensor 131 in the process of falling by its own weight.
Thereby, the sensor 131 outputs a detection signal.
The control circuit that has received the detection signal performs the same control as described above.
The disk d that has passed the sensor 131 is guided and guided from the introduction opening 70 to the distribution passage 80 by the introduction guide 29.
Thereafter, the disk d falls by its own weight and is guided to the first path 90 by the path switching plate 122.
The disk d that has reached the first passage 90 rolls on the first guide surface 75 and is discharged from the first outlet 90.

FIG. 1 is an overall perspective view of a hopper equipped with an embodiment of the present invention. FIG. 2 is a perspective view of the disk guide device of the present invention. FIG. 3 is a perspective view of the disc guide apparatus of the present invention from which the holding plate is removed. FIG. 4 is a perspective view of the disk guide device of the present invention viewed from the back side. FIG. 5 is a perspective view of the disc guide device of the present invention from which the plate cover is removed as seen from the back side. FIG. 6 is a front view of the disk guide apparatus of the present invention. FIG. 7 is a plan view of the disk guide apparatus of the present invention. FIG. 8 is a left side view of the disk guide apparatus of the present invention. FIG. 9 is a rear view of the disk guide apparatus of the present invention. FIG. 10 is a right side view of the disk guide apparatus of the present invention. FIG. 11 is an exploded perspective view showing components on the front side where the guide passage of the disk guide device of the present invention is provided. FIG. 12 is an exploded perspective view showing components on the back side where the distribution path of the disk guide apparatus of the present invention is provided. FIG. 13 is a front view of the disk guide apparatus of the present invention. 14 is a cross-sectional view taken along line BB in FIG.

DESCRIPTION OF SYMBOLS 1 Hopper 5 Escalator 10 Distributing device 20 Guide channel | path 20b Deflection channel | path part 21 Base plate 22, 23 Spacer 22b, 23b Inclination guide 27 Holding plate 30 Outlet 29 Introduction guide 40 Disc discharge means 60 Release channel 70 Introduction opening 80 Distribution channel 90 First passage 110 Second passage 120 Passage selection device 122 Passage switching plate
131 Disc detection sensor

Claims (1)

A guide passage (20) for guiding the disks (d) in a line, and
And release means of the disc (40) to release the disc in the circumferential direction from the outlet (30) of the guide path,
Release passage released the disc is dropped guided (60),
Detecting means for detecting said disc released into the discharge path (130),
A sorting path (80) of said disk from said discharge passage is distributed discharged,
Disc guiding apparatus comprising configured from the distributing means (120) of the disc provided in the sorting path.