JP3229839U - Bead feeder - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a bead feeder capable of selecting beads to be discharged by a simple operation. A bead feeder 1 includes a rotary accommodating portion 3, a rotary base 2, a case 10, and a drive gear 71. The rotary accommodating portion 3 has a plurality of accommodating chambers accommodating beads, a first engaged portion 36, and a driven gear 37, and is formed around the first axis. The rotation base 2 has a first engaging portion 24 that engages with the first engaged portion and a plurality of second engaged portions 222, and a plurality of rotation accommodating portions 3 are arranged to form a second rotation base 2. It is formed around the axis A2. The case 10 has a second engaging portion 113 that engages with the second engaged portion, and arranges the rotation base 2. When the drive gear 71 meshing with the driven gear 37 rotates to one side, the rotation of the rotation accommodating portion 3 is restricted and the rotation of the rotation base 2 is allowed. When the drive gear rotates to the other side, the rotation of the rotation accommodating portion is allowed and the rotation of the rotation base is regulated. [Selection diagram] Fig. 2

Description

The present invention relates to a bead feeder.

Conventionally, bead toys for playing by creating a pattern or the like using beads have been known. Since such a bead toy is played by arranging a plurality of beads side by side, a sphere feeder of Patent Document 1 has been proposed as a tool for easily supplying beads.

The sphere feeder of Patent Document 1 includes a front discharge portion for discharging a sphere, a rotatable portion having a plurality of storage chambers for storing the sphere, and a rotatably movable portion rotatably attached and coaxial with the rotation center of the rotatably movable portion. A base member having the fixed gears of the above, and a storage chamber forming body having a movable gear housed in the storage chamber and meshing with the fixed gears. This sphere feeder makes each storage space smaller so that it can be easily held by children, while many different types of spheres can be separated and stored by a dividing plate, which is a storage space. It is possible to prevent the sphere inside from being clogged near the discharge outlet from the storage chamber.

JP-A-2015-136457

In the sphere feeder of Patent Document 1, the beads to be discharged are selected by rotating the rotating movable part to move the storage chamber, and further rotating the lid plate of the storage chamber to rotate the beads separated in the storage chamber. It is moved to the outside of the movable part. Therefore, in order to select the beads, it is necessary to operate a plurality of parts of the sphere feeder, and the operability may be complicated.

In view of the above points, it is an object of the present invention to provide a bead feeder capable of selecting beads to be discharged by a simple operation.

The bead feeder according to one aspect of the present invention has a plurality of accommodating chambers accommodating beads, a number of first engaged portions corresponding to the accommodating chambers, and a driven gear around the first axis. A rotation having a plurality of rotation accommodating portions, a first engaging portion engaging with the first engaged portion, and a number of second engaged portions corresponding to the rotation accommodating portions around a second axis. Discharge the base, the case having the second engaging portion that engages with the second engaged portion, the drive gear that meshes with the driven gear, and the beads in the accommodation chamber at predetermined positions. The rotation accommodating portion includes a bead discharging portion, and the rotation accommodating portion is arranged in an annular shape on the rotation base. The rotation base is arranged on the case, and when the drive gear rotates to one side, the first engaging portion is provided. And the first engaged portion engage with each other to regulate the rotation of the rotation accommodating portion around the first axis, and the second engaged portion and the second engaged portion are said to be the rotation base. Allows rotation around the second axis, and when the drive gear rotates to the other side, the first engaged portion and the first engaged portion allow rotation of the rotation accommodating portion around the first axis. At the same time, the second engaging portion and the second engaged portion engage with each other to regulate the rotation of the rotation base around the second axis, and the rotation operation of the rotation base and the rotation accommodating portion causes the rotation operation. Move the containment chamber to a position.

According to the above aspect, it is possible to provide a bead feeder capable of selecting beads to be discharged by a simple operation.

It is a figure which shows the bead feeder which concerns on embodiment of this invention, (a) is a perspective view seen from the upper left, (b) is a perspective view seen from the lower right. It is an exploded perspective view seen from the upper left of the bead feeder which concerns on embodiment of this invention. It is an exploded perspective view seen from the lower right of the bead feeder which concerns on embodiment of this invention. It is a figure which shows the rotation accommodating part which concerns on embodiment of this invention, (a) is a perspective view seen from the 1st end side of a rotating shaft, (b) is a perspective view seen from the 2nd end side of a rotating shaft. It is a figure. It is a VV cross-sectional view of the bead feeder shown in FIG. 1 (a) which concerns on embodiment of this invention. FIG. 3 is a VI-VI sectional view of the bead feeder shown in FIG. 1A according to the embodiment of the present invention. It is VII-VII sectional view of the bead feeder shown in FIG. 1 (a) which concerns on embodiment of this invention. It is a VIII-VIII cross-sectional view of the bead feeder shown in FIG. 1A according to the embodiment of the present invention, (a) shows a standby state of a discharge guide, and (b) shows an operating state of a discharge guide.

Hereinafter, embodiments of the present invention will be described with reference to the drawings. FIG. 1A is a perspective view seen from the upper left of the bead feeder 1, and FIG. 1B is a rear perspective view of the bead feeder 1 as viewed from the lower right. In the following description of the bead feeder 1, the right case 11 side of the bead feeder 1 is on the right, the opposite side is on the left, the discharge port 103 side is on the front, and the opposite side is on the back. Further, the side on which the discharge operation unit 6 is provided is on the top, and the opposite side is on the bottom.

The entire bead feeder 1 is formed in a substantially drop shape by the right case 11 and the left case 12. A bead accommodating portion 101 is formed on the rear side of the bead feeder 1, and a bead discharging portion 102 is formed on the front side. The bead feeder 1 includes a plurality of rotary accommodating portions 3 capable of accommodating spherical or polyhedral bead. The rotary accommodating unit 3 further has a plurality of (two in this embodiment) accommodating chambers 35. When the user moves the rotary accommodating portion 3 and the accommodating chamber 35 by operating the operating member 9, the beads housed in the accommodating chamber 35 selected by the user can be discharged from the discharge port 103. Hereinafter, each configuration will be specifically described.

FIG. 2 is an exploded perspective view of the bead feeder 1 as viewed from the upper left. Further, FIG. 3 is an exploded perspective view of the bead feeder as viewed from the lower right. The bead feeder 1 includes a bead accommodating portion 101 and a bead discharging portion 102 inside the right case 11 and the left case 12. The bead accommodating portion 101 includes a rotating base 2, a plurality of rotating accommodating portions 3, and a lid 4. Further, the bead discharge unit 102 includes a discharge guide 5 and a discharge operation unit 6.

The rotation base 2 is formed in a disk shape as a whole, and has a circular through hole 21 centered on the second axis A2. A cylindrical wall 211 is erected from the peripheral edge of the through hole 21 toward the left. On the tip edge of the cylindrical wall 211, eight substantially U-shaped notched bearings 212 (first bearings) are provided at equal intervals.

A cylindrical outer peripheral side wall 22 extending to the left is formed on the outer peripheral edge of the rotation base 2. As shown in the enlarged view of the part A in FIG. 2, a plate-shaped swinging protrusion 221 is erected on the outer peripheral side wall 22. The swinging protrusion 221 extends in the circumferential direction of the outer peripheral side wall 22. Further, the swinging protrusion 221 has an inclined portion 221a on the clockwise side when viewed from the left side of the rotation base 2, and a locking end 221b substantially perpendicular to the outer surface of the outer peripheral side wall 22 on the counterclockwise direction side. Has.

The outer peripheral side wall 22 has an engaged portion 222 (second engaged portion) on the bottom surface 23 side with respect to the swinging projection 221. The engaged portion 222 is formed as an elongated rectangular through hole whose longitudinal direction is from the bottom surface 23 to the end portion 22a of the outer peripheral side wall 22. The edge portion of the engaged portion 222 on the bottom surface 23 side is formed so as to be slightly cut out toward the through hole 21 side. The edge portion 222a on the counterclockwise side of the engaged portion 222 is inclined in a tapered shape from the outer surface of the outer peripheral side wall 22. On the other hand, the edge portion 222b on the clockwise side of the engaged portion 222 is formed so as to connect to the inner surface of the through hole (engaged portion 222) substantially at a right angle from the outer surface of the outer peripheral side wall 22.

Further, the outer peripheral side wall 22 has a bearing 223 (second bearing) on the end portion 22a side with respect to the swinging projection 221. The bearing 223 is formed as a through hole having a U-shaped arc edge on the end 22a side. Further, the bearing 223 is provided in the groove portion 224 extending from the swinging projection 221 to the end portion 22a.

The outer peripheral side wall 22 has a substantially rectangular notch 225 between the locking end 221b of the swinging protrusion 221 and the end 22a. The edges of the three sides of the notch 225 on the through hole 21 side are formed so as to be inclined in a tapered shape (not shown).

An engaging portion 24 (first engaging portion) is formed on the bottom surface 23 of the rotation base 2. The engaging portion 24 has a main body portion 241 fixed to the bottom surface 23 and an arm portion 242 extending from the main body portion 241. The main body 241 is fixed to the bottom surface 23 by screwing or the like.

The arm portion 242 is formed in a cantilevered leaf spring shape so as to be erected from the bottom surface 23 in an L shape after extending inward from the main body portion 241 in the rotation base 2. At the tip of the arm portion 242, an engaging claw 242a projecting in the counterclockwise direction when viewed from the left side of the rotation base 2 is formed. Further, on the bottom surface 23, a pressing member 231 is formed at a portion on the base end side of the arm portion 242 to be erected. The pressing member 231 can prevent the base end portion of the arm portion 242 from shifting.

Further, the bottom surface 23 of the rotation base 2 is formed so as to project in a chevron shape when viewed from the left side shown in FIG. 2, and is formed so as to be recessed in a mortar shape when viewed from the right side shown in FIG.

The rotation accommodating portion 3 will be described. FIG. 4A is a perspective view of the rotary accommodating portion 3 as viewed from the first end 33a side of the rotary shaft 33, and FIG. 4B is a perspective view of the rotary accommodating portion 3 as viewed from the second end 33b side of the rotary shaft 33. It is a perspective view. The rotation accommodating portion 3 is formed in a substantially truncated cone shape as a whole. The rotation accommodating portion 3 has a substantially circular bottom portion 31 and an outer peripheral portion 32 formed so that the inner diameter gradually expands from the bottom portion 31. Therefore, the rotation accommodating portion 3 is formed with a diameter larger in the opening 3a than in the bottom portion 31.

The rotation accommodating portion 3 has a columnar rotary shaft 33 which is a first shaft A1 formed so as to penetrate the bottom portion 31. The first end 33a of the rotation shaft 33 is formed so as to protrude from the opening surface of the opening 3a of the rotation accommodating portion 3.

The rotation accommodating portion 3 has a flat plate-shaped partition plate 34 including a rotation shaft 33. The edge 34a of the partition plate 34 projects in a protruding arc shape from the opening surface of the opening 3a. The edge 34a of the partition plate 34 becomes substantially parallel to the inner surface of the outer peripheral side wall 22 when housed in the rotation base 2. The inside of the rotary accommodating portion 3 is divided into two accommodating chambers 35 by the dividing plate 34. Two ribs 311 are formed substantially parallel to the bottom 31. The rib 311 is arranged so as to intersect the dividing plate 34 substantially perpendicularly.

An engaged portion 36 is formed on the outer peripheral portion 32 of the rotary accommodating portion 3 corresponding to each accommodating chamber 35. The engaged portion 36 (first engaged portion) is formed as a substantially isosceles triangular through hole with the base facing the opening 3a side. Further, the inner wall 36a of the engaged portion 36 is formed in a tapered shape, and the outer surface side is larger than the inner surface side of the outer peripheral portion 32.

As shown in FIG. 4B, the rotation accommodating portion 3 has a driven gear 37 having a diameter smaller than that of the bottom portion 31 on the second end 33b side of the rotation shaft 33 on the side opposite to the opening 3a. The driven gear 37 is a spur gear. As described above, the rotary accommodating portion 3 has a plurality of accommodating chambers 35, an engaged portion 36 corresponding to each accommodating chamber 35, and a driven gear 37 around the first axis A1.

In FIG. 2, the rotation accommodating portions 3 are arranged in an annular shape in a number corresponding to the swinging projections 221 and the engaged portions 222, the bearings 223, and the notch portions 225. Each rotation accommodating portion 3 is arranged with the driven gear 37 facing the center side. Then, the rotation accommodating portion 3 arranged in an annular shape is arranged on the rotation base 2. The first end 33a of the rotating shaft 33 is inserted into the bearing 223. The second end 33b of the rotating shaft 33 is mounted on the bearing 212.

In FIG. 2, a circular mounting surface 111 on which the rotation base 2 is mounted is provided on the bead storage portion 101 side in the right case 11. A circular through hole 111a is formed substantially in the center of the mounting surface 111. A cylindrical shaft 112 is erected from the peripheral edge of the through hole 111a toward the left case 12.

As shown in FIG. 3, a circular frame-shaped inner frame 111b and an outer frame 111c are erected on the outer side of the right case 11 around the through hole 111a. The inner frame 111b is arranged between the outer frame 111c and the through hole 111a. Further, the inner frame 111b is formed lower than the outer frame 111c (see also FIG. 5).

Returning to FIG. 2, a cantilever leaf spring-shaped engaging portion 113 (second engaging portion) is arranged at a position between the bead discharging portions 102 side of the mounting surface 111. The engaging portion 113 is fixed to the right case 11 and the left case 12 by the base plate 113a. An engaging claw 113c protruding toward the through hole 111a is formed at the tip of the arm portion 113b extending from the base plate 113a to the mounting surface 111 side. An inclined surface 113d having a side view protrusion arc shape is formed on the base end side of the engaging claw 113c on the arm portion 113b side. Further, a vertical surface 113e substantially perpendicular to the plate surface of the arm portion 113b is formed on the tip end side of the engaging claw 113c.

A lid 4 is arranged at the rear ends of the right case 11 and the left case 12. The lid 4 has a function of opening and closing a supply port for supplying the beads formed by the notch 123a to the rotation accommodating portion 3. The lid 4 is formed in a substantially plate shape and has a rotating shaft 41. Further, the lid 4 has a pressing plate 42 for preventing the beads from flowing back from the rotary accommodating portion 3 formed on the inner side of the case 10. Further, the lid body 4 has a plate-shaped knob 43 for opening and closing the lid body 4 projecting outward from the case 10. The lid 4 can be rotated about the rotation shaft 41 by the operation of the knob 43.

A discharge guide 5 is arranged in the bead discharge unit 102. The discharge guide 5 is formed with a bead discharge passage 51 that extends in the front-rear direction and opens in a groove shape on the left side. A rotation shaft 52 is formed at substantially the center of the discharge guide 5. The discharge guide 5 is rotated by engaging a cylindrical protrusion 116 (see FIG. 2) provided in the right case 11 with a circular groove 525 (see FIG. 3) provided on the right side of the rotation shaft 52. It can rotate around the moving shaft 52. Further, the side walls 521 and 522 of the rotating shaft 52 are inserted into the bearing 534 which is erected in a substantially cylindrical shape from the left case 12. The discharge passage 51a on the rear side of the rotating shaft 52 is inclined toward the right case side at the front and toward the left case 12 at the rear. Further, the discharge passage 51b on the front side of the rotation shaft 52 is formed linearly in the front-rear direction.

The discharge guide 5 has a locking plate 512 on the back surface on the rear end side shown in FIG. The locking plate 512 comes into contact with the swinging protrusion 221 when the user presses the discharge operation unit 6 to rotate the discharge guide 5. As a result, the locking plate 512 can be prevented from being clogged when the beads housed in the rotation accommodating portion 3 are discharged by giving a slight vibration to the rotation base 2 in the rotation direction.

On the front side of the engaging portion 113 of the right case 11, an elastic body accommodating groove 114 formed in a groove shape by a plurality of ribs is formed. By arranging the coil spring S1 between the elastic body accommodating groove 114 and the protrusion 5a protruding from the rear outer surface of the discharge guide 5, the rear end 52a of the discharge guide 5 is moved downward and the front end of the discharge guide 5. 52b is urged upward.

In the bead discharge unit 102, the discharge operation unit 6 is arranged at a position above the front end of the discharge guide 5. The discharge operation unit 6 is formed in a substantially plate shape, and is formed so as to be able to appear and fall up and down from the infestation hole 104 provided above the case 10 shown in FIG. 1 (a). Ribs 61 are formed on the left and right sides of the discharge operation unit 6. When the upper end of the rib 61 comes into contact with the regulation protrusion in the indentation hole 104, the upward movement of the discharge operation unit 6 is restricted. Further, the lower end 62 of the discharge operation unit 6 comes into contact with the front end 52b of the discharge guide 5. The discharge operation unit 6 is urged upward by the front end 52b of the discharge guide 5.

In FIG. 3, on the bead accommodating portion 101 side in the left case 12, a circular opening 121 slightly larger than the outer diameter of the entire rotating accommodating portion 3 arranged in an annular shape is provided. The transparent cover member 122 shown in FIG. 1 can be arranged in the opening 121. A substantially rectangular notch 121b is formed on the inner wall 121a of the opening 121 on the bead discharge portion 102 side. The edge of the notch 121b on the bead discharge portion 102 side is formed in a tapered shape (see also FIGS. 8 (a) and 8 (b)). Further, a substantially rectangular notch 121c is formed on the inner wall 121a on the rear side of the left case 12.

A rectangular notch 123a is formed at the rear end of the side plate 123 that covers the outer periphery of the left case 12. The notch portion 123a is used together with the notch portion 121c as a supply port for beads to the rotation accommodating portion 3.

A top rib 53, an elastic body accommodating rib 54, and a separating rib 55 are provided on the bead discharge portion 102 side in the left case 12. Details of the top rib 53, the elastic body accommodating rib 54, and the separating rib 55 will be described later in the description of FIGS. 8 (a) and 8 (b).

The notch 103a provided at the front end of the left case 12 is overlapped with the notch 103b of the right case 11 to form the discharge port 103 (see FIG. 1 (b)). Further, the notch 104a provided above the front end of the left case 12 is overlapped with the notch 104b of the right case 11 to form the indentation hole 104 (see FIG. 1A).

In FIG. 3, the crown gear 7 has a drive gear 71 and a shaft portion 72. The drive gear 71 meshes with the driven gear 37 of each rotation accommodating portion 3 arranged in an annular shape on the rotation base 2. The shaft portion 72 is provided in a columnar shape so as to project to the right of the drive gear 71. The shaft portion 72 has an engaging end 72a at its tip. The engaging end 72a is formed in a hexagonal columnar shape having a circumscribed circle substantially the same as the outer diameter of the shaft portion 72. Further, a screw hole 72a1 is formed in the shaft portion 72 from the tip surface of the engaging end 72a.

The tubular member 8 is formed in a cylindrical shape and has a through hole 8a having an inner diameter through which the shaft portion 72 can be inserted. Further, the tubular member 8 has a flange portion 81 on one end side.

The operating member 9 is used to rotate the crown gear 7. The operation member 9 is formed in a substantially disk shape and has an operation knob 91. A hole 911 having a substantially hexagonal bottom is formed at substantially the center of the operation knob 91. A circular through hole 911a having a diameter slightly smaller than the inscribed circle of the hole 911 is provided at the bottom of the hole 911.

As shown in FIG. 2, the operation member 9 has an annular inner frame 912 forming a through hole 911a on the opposite surface side of the surface on which the operation knob 91 is located. Further, the operating member 9 has an inner frame 913 on the outer periphery of the inner frame 912 and an outer frame 914 on the outer periphery of the inner frame 913. Further, the outer frame 914 is formed on the outer edge of the operating member 9.

The fixing member 92 is formed in a substantially hexagonal columnar shape. The fixing member 92 has a circular groove portion 921 and a hexagonal groove portion 922 on the opposite side of the groove portion 921. The bottom of each groove portion 921,922 is penetrated by a common through hole 921a for a screw. The fixing member 92 is inserted into the hole portion 911 of the operating member 9 from the groove portion 922 side.

Next, a state in which each member of the bead feeder 1 is combined will be described. FIG. 5 is a VV cross-sectional view of the bead feeder 1 shown in FIG. 1 (a). FIG. 6 is a VI-VI cross-sectional view illustrating the engaging portion 113 of the bead feeder 1 shown in FIG. 1 (a). Further, FIG. 7 is a sectional view taken along line VII-VII of the bead feeder 1 shown in FIG.

The rotation base 2 is mounted on the mounting surface 111 of the right case 11. The cylindrical shaft 112 of the right case 11 is inserted into the through hole 21 of the rotation base 2. The outer peripheral edge 232 of the rotation base 2 comes into contact with the annular peripheral protrusion 111d formed on the outer edge side of the mounting surface 111 of the right case 11.

The tubular member 8 is inserted into the cylindrical shaft 112 from the right case 11 side. The crown gear 7 is arranged coaxially with the rotation base 2 and the right case 11 by inserting the shaft portion 72 into the through hole 8a of the tubular member 8 from the left case 12 side. The engaging end 72a of the shaft portion 72 protrudes from the through hole 8a.

Each rotation accommodating portion 3 is rotatably arranged with respect to the rotation base 2 by the crown gear 7. The drive gear 71 of the crown gear 7 meshes with the driven gear 37 of each rotation accommodating portion 3. Further, the crown gear 7 has an annular frame portion 73 that stands upright on the shaft portion 72 side. The tip 73a of the frame portion 73 is formed on substantially the same plane. The tip 73a of the frame portion 73 suppresses the second end 33b side of the rotating shaft 33 from the opening side of the bearing 212. Therefore, it is possible to prevent the first end 33a and the second end 33b of the rotating shaft 33 from coming off the bearings 223 and 212.

The operating member 9 is attached from the outside of the right case 11. The outer frame 914 of the operating member 9 is arranged in the outer frame 111c provided around the through hole 111a of the right case 11. The middle frame 913 of the operating member 9 is arranged in the inner frame 111b provided around the through hole 111a of the right case 11.

A fixing member 92 is arranged in the hole 911 of the operating member 9. An engaging end 72a penetrating the right case 11 side engages in the groove 922 of the fixing member 92. Then, the fixing member 92 is fixed to the crown gear 7 by screwing a screw having a head arranged in the groove 921 into the screw hole 72a1 via the through hole 921a. At this time, since the engaging end 72a and the groove portion 922 are formed in a hexagonal shape, the relative rotational operation of the crown gear 7 and the fixing member 92 in the rotational direction is restricted.

Further, the inner diameter of the through hole 911a of the operating member 9 is formed to be smaller than the outer diameter of the fixing member 92. Therefore, if the shaft portion 72 penetrating the through hole 911a is fixed by the fixing member 92 with the operating member 9 attached to the right case 11, the operating member 9 is prevented from falling off. Further, since the hole 911 and the fixing member 92 of the operating member 9 are formed in a hexagonal shape, the relative rotational operation of the crown gear 7 and the operating member 9 in the rotational direction is restricted.

Therefore, when the user rotates the operating member 9 in the clockwise direction or the counterclockwise direction, the rotational force in the same direction is transmitted to the crown gear 7.

In FIG. 5, the coil spring S2 is arranged between the outer surface of the shaft portion 72 and the inner wall of the through hole 911a. Both ends of the coil spring S2 come into contact with the flange portion 81 and the fixing member 92. Since the coil spring S2 is compressed and arranged, the coil spring S2 is pressurized in a direction in which the flange portion 81 and the fixing member 92 are separated from each other. As a result, the drive gear 71 and the frame portion 73 of the crown gear 7 are urged toward the driven gear 37 and the cylindrical wall 211 side. The movement of the crown gear 7 is restricted by the contact between the frame portion 73 and the cylindrical wall 211.

Further, a coil spring S3 is arranged between the inner frame 912 and the middle frame 913. One end of the coil spring S3 comes into contact with the groove portion 111e formed between the through hole 111a and the inner frame 111b. The other end of the coil spring S3 comes into contact with a bulging portion (not shown in FIG. 5) of the step portion 912a provided on the outer periphery of the inner frame 912. Since the coil spring S3 is compressed and arranged, the coil spring S3 is pressurized in a direction in which the right case 11 and the operating member 9 are separated from each other. As a result, the operating member 9 is urged to the outer side of the right case 11. The movement of the operating member 9 is restricted by the step portion provided on the inner surface of the through hole 911a coming into contact with the fixing member 92.

By arranging the coil spring S2 and the coil spring S3, the operating member 9, the fixing member 92, and the crown gear 7 can form a meshing position adjusting mechanism of the rotation accommodating portion 3. A method of adjusting the meshing position between the driven gear 37 of the rotation accommodating portion 3 and the driving gear 71 of the crown gear 7 will be described.

In FIG. 1B, the fixing member 92 is arranged so as to be slightly recessed with respect to the operation knob 91. When the user pushes the operation knob 91 toward the case 10, the operation knob 91 shown in FIG. 6 moves toward the case 10 side against the elastic force of the coil spring S3, and the fixing member 92 protrudes. After that, when the fixing member 92 is pushed toward the case 10 side together with the operation knob 91, the fixing member 92 also moves to the case 10 side against the elastic force of the coil spring S3. When the fixing member 92 moves to the case 10 side, the crown gear 7 connected to the fixing member 92 via the shaft portion 72 moves so as to be separated from the left case 12 side. Therefore, the mesh between the drive gear 71 and the driven gear 37 is released. While the teeth are released, the user can manually rotate the rotation accommodating portion 3. After that, when the load on the operation knob 91 and the fixing member 92 is released, the crown gear 7 moves to the left case 12 side, and the drive gear 71 and the driven gear 37 mesh with each other. As a result, even if the rotation accommodating portion 3 is displaced due to gear licking or the like, the rotation accommodating portion 3 can be returned to the normal rotation position.

In FIG. 6, the engaging portion 113 abuts on the outer peripheral side wall 22 of the rotation base 2 from the outside toward the rotation base 2 side. The engaging claw 113c of the engaging portion 113 is engaged with the engaged portion 222 of the rotation base 2.

The engaged portion 222 has an edge portion 222a that is inclined with respect to the outer peripheral side wall 22 of the rotation base 2, and the engaging claw 113c also has an inclined surface 113d that is inclined with respect to the outer peripheral side wall 22 of the rotation base 2. .. Therefore, when the rotation base 2 of FIG. 6 rotates clockwise, the edge portion 222a pushes the inclined surface 113d against the elastic force of the engaging portion 113 in the outer diameter direction of the rotation base 2, and rotates in the clockwise direction. Is allowed.

On the other hand, the engaged portion 222 has an inner surface (edge portion 222b) connected substantially vertically from the outer surface of the outer peripheral side wall 22, and the engaging claw 113c also has a vertical surface 113e. Therefore, even if the rotation base 2 tries to rotate in the counterclockwise direction, the rotation of the rotation base 2 in FIG. 6 in the counterclockwise direction is restricted by the surface contact between the inner surface of the engaged portion 222 and the vertical surface 113e. To.

Further, in FIG. 7, the engaging portion 24 comes into contact with the rotation accommodating portion 3 side from the outside. The engaging claw 242a is engaged with the engaged portion 36 of the rotation accommodating portion 3.

The engaged portion 36 has a V-shaped groove-shaped inner wall 36a with respect to the outer surface of the rotation accommodating portion 3. Further, the engaging portion 24 also has an engaging claw 242a projecting toward the outer surface of the rotation accommodating portion 3. The engaging claw 242a is formed in a substantially triangular protruding shape in the cross-sectional view of FIG. 7. When the engaging claw 242a is engaged with the inner wall 36a, the two surfaces of the engaging claw 242a are in contact with the inner wall 36a. The first surface of the engaging claw 242a is obliquely in contact with the surface 36a1 on the counterclockwise side of the inner wall 36a, and is in contact with the outer edge of the engaged portion 36 by substantially linear contact. Therefore, when the rotation accommodating portion 3 rotates in the clockwise direction when viewed from the first end 33a side, the surface 36a1 on the counterclockwise direction side rotates and accommodates the engaging claw 242a against the elastic force of the arm portion 242. Extrude in the outer shape direction of the part 3. Then, the rotation accommodating portion 3 is allowed to rotate in the clockwise direction.

On the other hand, the second surface of the engaging claw 242a is in contact with the surface 36a2 on the clockwise side of the inner wall 36a substantially parallel to the surface 36a2. Therefore, when the rotation accommodating portion 3 tries to rotate in the counterclockwise direction when viewed from the first end 33a side, the rotation accommodating portion 3 is restricted from rotating in the counterclockwise direction by the engaging claw 242a. In this way, when the engaging portion 24 is engaged with the engaged portion 36, the rotation accommodating portion 3 can rotate clockwise when viewed from the first end 33a side of the rotating shaft 33, which is counterclockwise. Rotation is regulated clockwise.

FIG. 8A is a sectional view taken along line VIII-VIII of the bead feeder 1 shown in FIG. 1A. A part of the discharge guide 5 on the rotation base 2 side is a ceiling rib 53 (531 to 534) erected from the inner surface of the left case 12 (see FIG. 3) to the right case 11 side (the back side of FIG. 8A). ) To form a closed drainage passage.

On the rear side of the discharge passage 51a, a discharge passage closed by inclined ribs 531, 532 is formed. The discharge passage 51a is inclined from the left case 12 side to the right case 11 side as it goes from the rotation base 2 side to the discharge port 103 side. Further, the inclined ribs 531 and 532 are also inclined from the left case 12 side to the right case 11 side from the rotation base 2 side toward the discharge port 103 side.

The rotating shaft 52 has arcuate facing side walls 521 and 522. The side walls 521 and 522 are formed so as to stand higher than the side walls of the discharge passages 51a and 51b (see also FIG. 2). From the side wall 522, two ribs 522a and 522b extend in the direction of the side wall 521. The rotation shaft 52 forms a closed discharge passage by the side wall 521, the tips of the ribs 522a and 522b, and the rotation restriction rib 533.

The left case 12 has a linear elastic body accommodating rib 54 that stands upright on the right case 11 side at the position of the elastic body accommodating groove 114. The elastic body accommodating rib 54 can form an elastic body accommodating groove 114 having an opening on the discharge guide 5 side by the frame rib 115 of the left case 12 and the inner wall 11a of the right case 11. Therefore, the coil spring S1 arranged in the elastic body accommodating groove 114 can be stably arranged.

From the elastic body accommodating rib 54, the bead separation rib 55 extends on the rotation base 2 side. The separation rib 55 is formed in an L shape from the side surface of the elastic body accommodating rib 54. The tip 55a of the separation rib 55 is arranged on the discharge guide 5 side. The tip 55a is inserted into a substantially rectangular notch 51a1 formed in a part of the side wall of the discharge passage 51a.

Next, the operation of the bead feeder 1 will be described. The bead feeder 1 described in this embodiment includes eight rotary accommodating portions 3, and each rotary accommodating portion 3 has two accommodating chambers 35. Therefore, the bead feeder 1 has a total of 16 storage chambers 35. Each storage chamber 35 may contain beads of different colors and shapes, or some storage chambers 35 may contain beads of the same type. The rotation accommodating portion 3, the mounting surface 111 of the right case 11, and the rotation base 2 can be formed of a translucent material. Therefore, it is possible to make it possible to visually recognize what kind of beads are accommodated in each rotary accommodating portion 3 from the outside of the bead feeder 1.

In FIG. 1A, the user can eject the beads housed in the storage chamber 35 at the marker 126 formed in the left case 12. When the rotary accommodating portion 3 and the accommodating chamber 35 accommodating the beads to be discharged are not located at the position of the marker 126, the user rotates the operating member 9 shown in FIG. 1 (b) to accommodate the target. The chamber 35 can be moved.

In FIG. 1 (b), when the operation member 9 is rotated counterclockwise by the operation knob 91, the crown gear 7 shown in FIG. 1 (a) is linked with the operation member 9 and is viewed from the crown gear 7 side. Obtains rotational force in the clockwise direction. Then, since the driven gear 37 of each rotation accommodating portion 3 meshes with the drive gear 71 of the crown gear 7, the rotation accommodating portion 3 is viewed from the first end 33a (see also FIG. 2) side of the rotating shaft 33. Gains rotational force counterclockwise. However, as shown in FIG. 7, the rotation accommodating portion 3 rotates in the counterclockwise direction about the first axis A1 shown in FIG. 4 due to the engagement between the engaging portion 24 and the engaged portion 36. Is regulated (see also paragraph [0057]). Therefore, the force transmitted to the driven gear 37 becomes the rotational force in the clockwise direction of the rotation base 2 as seen from the crown gear 7 side.

In FIG. 6, the rotation base 2 is allowed to rotate in the clockwise direction due to the engagement between the engaging portion 113 and the engaged portion 222 (see also paragraph [0053]). Therefore, the rotational base 2 rotates in the clockwise direction about the second axis A2 due to the rotational force transmitted from the crown gear 7. In this way, when the operating member 9 is rotated to one side (counterclockwise), the user can move the arbitrary rotation accommodating portion 3 to the position of the marker 126 shown in FIG. 1A.

Further, in FIG. 1 (b), when the operation member 9 is rotated clockwise by the operation knob 91, the crown gear 7 shown in FIG. 1 (a) is viewed from the crown gear 7 side in conjunction with the operation member 9. Gains rotational force in the counterclockwise direction. Then, the rotation accommodating portion 3 obtains a rotational force clockwise when viewed from the first end 33a (see also FIG. 2) side of the rotation shaft 33. As shown in FIG. 7, the rotation accommodating portion 3 is allowed to rotate in the clockwise direction about the first axis A1 shown in FIG. 3 by engaging the engaging portion 24 and the engaged portion 36. (See also paragraph [0056]).

On the other hand, in FIG. 6, the rotation base 2 is restricted from rotating in the counterclockwise direction by the engagement between the engaging portion 113 and the engaged portion 222 (see also paragraph [0054]). Therefore, due to the rotational force transmitted from the crown gear 7, the rotation accommodating portion 3 rotates in the clockwise direction about the first axis A1. In this way, when the operating member 9 is rotated to the other side (clockwise), the user can move any storage chamber 35 of the rotation storage unit 3 to the left case 12 side.

As described above, the user can move the accommodation chamber 35 of the arbitrary rotation accommodation unit 3 to the position of the marker 126 by combining the clockwise and counterclockwise rotation operations of the operation member 9.

As shown in FIG. 8A, when the user does not operate the discharge operation unit 6, the storage chamber 35 in which the beads to be discharged are housed is arranged with the opening 3a facing inside the notch 121b. Ru. The notch 121b and the notch 225 are arranged so as to substantially overlap each other. However, since the rear end of the side wall 51a2 in which the cutout portion 51a1 of the discharge passage 51a of the discharge guide 5 is formed is located substantially in the center of the cutout portion 121b, the beads housed in the storage chamber 35 move to the discharge guide 5 side. Is prevented from being discharged.

As shown in FIG. 8B, when the user presses the discharge operation unit 6, the front end 52b of the discharge guide 5 is urged by the lower end 62 of the discharge operation unit 6, and the discharge guide 5 pushes the rotation shaft 52. Rotate to the center. Then, the opening 511 of the discharge passage 51a moves to the position of the notch 121b. Therefore, when the user presses the discharge operation unit 6 with the discharge port 103 of the bead supply tool 1 down, the beads are discharged from the storage chamber 35 through the notches 225 and 121b to the opening 511. Ru.

The ejected beads are restricted in movement by the separating rib 55 at the opening 511. The other beads remaining in the containment chamber 35 are restricted from moving in the opening 511 direction by the beads located in the already discharged opening 511. Therefore, the separation rib 55 limits the number of beads discharged to the discharge guide 5 to one.

When the user stops pressing the discharge operation unit 6, the discharge guide 5 rotates about the rotation shaft 52 so that the front end 52b pushes up the discharge operation unit 6 by the elastic force of the coil spring S1. , Return to the state where the discharge operation unit 6 is not operated. As a result, as shown in FIG. 8A, the beads located in the opening 511 pass through the discharge passage 51 by releasing the closed state of the discharge passage 51 by the separation rib 55, and the beads pass through the discharge passage 51. It is discharged from the discharge port 103 formed at the front end of the feeder 1.

Further, the other beads whose movement to the opening 511 is restricted are not discharged to the discharge guide 5 side because the rear end of the side wall 51a2 returns to the state where it is located substantially in the center of the notch 121b. Therefore, when the user presses the discharge operation unit 6 and releases the discharge operation unit 6 with the discharge port 103 of the bead feeder 1 down, the left case 12 in the vicinity of the predetermined marker 126 is operated. One bead in the storage chamber 35 arranged at the side position can be discharged from the discharge port 103.

According to the embodiment of the present invention as described above, the bead feeder of the following aspects can be provided.

The bead feeder according to the first aspect has a plurality of storage chambers for accommodating beads, a plurality of first engaged portions corresponding to the storage chambers, and a plurality of driven gears around a first axis. A rotation base having a rotation accommodating portion, a first engaging portion that engages with the first engaged portion, and a number of second engaged portions corresponding to the rotation accommodating portion around a second axis. , A case having a second engaging portion that engages with the second engaged portion, a drive gear that meshes with the driven gear, and a bead discharge that discharges beads in the storage chamber at a predetermined position. The rotation accommodating portion is arranged in an annular shape on the rotation base, the rotation base is arranged on the case, and when the drive gear rotates to one side, the first engaging portion and the rotation base are provided. The first engaged portion engages to regulate the rotation of the rotation accommodating portion around the first axis, and the second engaged portion and the second engaged portion are the second of the rotation base. When the drive gear rotates to the other side, the first engaging portion and the first engaged portion allow the rotation accommodating portion to rotate around the first shaft, and also allow rotation around the shaft. The second engaging portion and the second engaged portion engage with each other to regulate the rotation of the rotation base around the second axis, and the rotation operation of the rotation base and the rotation accommodating portion causes the rotation base to reach the position. The containment chamber is moved.

According to this configuration, even when a plurality of rotary accommodating portions 3 having a plurality of accommodating chambers 35 are provided, an arbitrary accommodating chamber 35 is moved to a position where beads can be discharged by one operating member 9. be able to. Therefore, it is possible to provide a bead feeder that can easily select the beads to be discharged even if there are many types of accommodation.

In the bead feeder according to the second aspect, the rotary base has a first bearing that supports a first end of a shaft portion that is the first shaft around the second shaft, and is outside the first bearing. It has a second bearing that supports the second end of the shaft portion on the radial side.

According to this configuration, the rotation accommodating portion 3 can be arranged radially in the bead feeder 1 and rotate about a second axis in a direction different from the first axis which is the revolution axis.

In the bead feeder according to the third aspect, the rotary base has a cylindrical wall on which the first bearing is formed and a cylindrical outer peripheral side wall on which the second bearing and the second engaged portion are formed. The accommodating chamber of the rotary accommodating portion has a partition plate in which a protruding arc-shaped end edge protruding from the opening is formed parallel to the inner surface of the outer peripheral side wall.

According to this configuration, the rotation is regulated by engaging the outer portion of the rotation base 2 that rotates around the second axis A2. Therefore, the second engaging portion is used to regulate the rotation of the rotation base 2. It is possible to reduce the burden related to. Further, the protruding arc-shaped edge 34a allows the beads to be moved without overflowing when the rotation accommodating portion 3 revolves and rotates.

In the bead feeder according to the fourth aspect, the first engaging portion is formed in a cantilevered leaf spring shape having a protruding engaging claw having a triangular cross section, and the first engaged portion is The second engaging portion is formed in a tapered shape, the second engaging portion is formed in a cantilevered leaf spring shape having an inclined surface on the base end side and a vertical surface on the tip end side, and the second engaged portion is unidirectional. The side edge portion is formed so as to be inclined from the outer surface of the outer peripheral side wall, and the other side edge portion is formed at a right angle from the outer surface of the outer peripheral side wall.

According to this configuration, it is possible to easily regulate and allow the revolution around the first axis A1 and the rotation around the second axis A2 of the rotation accommodating portion 3 with a simple configuration.

In the bead feeder according to the fifth aspect, the drive gear is a crown gear that rotates around the second axis.

According to this configuration, the accommodation chamber 35 can be easily moved by one drive source by the crown gear 7.

Although the embodiment of the present invention has been described above, the present invention is not limited to the above embodiment, and various modifications can be made without departing from the gist thereof.

For example, in the present embodiment, the example in which the rotary accommodating portion 3 has two accommodating chambers 35 has been described, but some of the rotary accommodating portions 3 may have one accommodating chamber 35, or a part or all of them. The rotary accommodating portion 3 of the above may be configured to have three or more accommodating chambers 35.

Further, the directions of the first axis A1 and the second axis A2 may be arranged substantially in parallel, and the rotation accommodating portion 3 may be arranged in an annular shape. In this case, instead of the crown gear 7, the spur gear may be arranged at the center of the rotary accommodating portion 3 arranged in an annular shape.

1 Bead feeder 2 Rotation base 3 Rotation accommodating part 3a Opening 4 Lid 5 Discharge guide 5a Protrusion 6 Discharge operation part 7 Crown gear 8 Cylindrical member 8a Through hole 9 Operation member 10 Case 11 Right case 11a Inner wall 12 Left case 21 Penetration Hole 22 Outer peripheral side wall 22a End part 23 Bottom surface 24 Engagement part 31 Bottom part 32 Outer part 33 Rotating shaft 33a First end 33b Second end 34 Separation plate 34a Edge edge 35 Storage chamber 36 Engagement part 36a Inner wall 36a1 Surface 36a2 Surface 37 Driven gear 41 Rotating shaft 42 Pressing plate 43 Picking 51 Discharge passage 51a Discharge passage 51a1 Notch 51a2 Side wall 51b Discharge passage 52 Rotating shaft 52a Rear end 52b Front end 53 Top rib 54 Elastic body accommodating rib 55 Separation rib 55a Tip 61 rib 62 Lower end 71 Drive gear 72 Shaft part 72a Engagement end 72a1 Screw hole 73 Frame part 73a Tip 81 Flange part 91 Operation knob 92 Fixing member 101 Bead storage part 102 Bead discharge part 103 Discharge port 103a Notch 103b Notch 104 Indentation hole 104a Notch 104b Notch 111 Mounting surface 111a Through hole 111b Inner frame 111c Outer frame 111d Peripheral protrusion 111e Groove 112 Cylindrical shaft 113 Engaging part 113a Base plate 113b Arm 113c Engaging claw 113d Inclined surface 113e Vertical surface 114 Elastic body accommodating groove 115 Frame rib 116 Projection 121 Opening 121a Inner wall 121b Notch 121c Notch 122 Cover member 123 Side plate 123a Notch 126 Marker 211 Cylindrical wall 212 Bearing 221 Rotating protrusion 221a Inclined part 221b Locking end 222 Engagement part 222a Edge part 222a Edge 223 Bearing 224 Groove 225 Notch 231 Presser member 232 Outer peripheral edge 241 Main body 242 Arm 242a Engagement claw 311 Rib 511 Opening 521 Side wall 522 Side wall 522a Rib 522b Rib 525 Circular groove 531 Inclination rib 533 Bearing 911 Hole 911a Through hole 912 Inner frame 913 Middle frame 914 Outer frame 921 Groove 921a Through hole 922 Groove A1 1st axis A2 2nd axis S1 to S3 Coil spring

Claims (5)

A plurality of accommodating chambers accommodating beads, a plurality of rotational accommodating portions having a number of first engaged portions corresponding to the accommodating chambers, and driven gears around the first axis.
A rotation base having a first engaging portion that engages with the first engaged portion and a number of second engaged portions corresponding to the rotation accommodating portions around the second axis.
A case having a second engaging portion that engages with the second engaged portion, and
The drive gear that meshes with the driven gear and
A bead discharge unit that discharges beads from the storage chamber at a predetermined position,
With
The rotation accommodating portion is arranged in an annular shape on the rotation base.
The rotating base is placed in the case and
When the drive gear rotates to one side, the first engaging portion and the first engaged portion engage with each other to regulate the rotation of the rotation accommodating portion around the first axis, and the second engaging portion. The joint and the second engaged portion allow rotation of the rotation base around the second axis.
When the drive gear rotates to the other side, the first engaging portion and the first engaged portion allow the rotation accommodating portion to rotate around the first axis, and the second engaging portion and the first engaged portion. The second engaged portion engages to regulate the rotation of the rotation base around the second axis.
By rotating the rotation base and the rotation accommodating portion, the accommodating chamber is moved to the position.
A bead feeder that is characterized by that. The rotation base has a first bearing that supports a first end of a shaft portion that is the first shaft around the second shaft, and a second end of the shaft portion on the outer diameter side of the first bearing. The bead feeder according to claim 1, further comprising a second bearing to support. The rotation base has a cylindrical wall on which the first bearing is formed, and a cylindrical outer peripheral side wall on which the second bearing and the second engaged portion are formed.
The accommodating chamber of the rotary accommodating portion has a dividing plate in which a protruding arc-shaped end edge protruding from the opening is formed parallel to the inner surface of the outer peripheral side wall.
The bead feeder according to claim 2. The first engaging portion is formed like a cantilever leaf spring having a protruding engaging claw having a triangular cross section.
The first engaged portion is formed in a tapered shape.
The second engaging portion is formed like a cantilever leaf spring having an inclined surface on the base end side and a vertical surface on the tip end side.
The second engaged portion is formed so that the edge portion on one direction side is inclined from the outer surface of the outer peripheral side wall, and the edge portion on the other direction side is formed at a right angle from the outer surface of the outer peripheral side wall.
The bead feeder according to claim 3. The bead feeder according to any one of claims 1 to 4, wherein the drive gear is a crown gear that rotates around the second axis.

Images