JP2005211418A - Traveling toy - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a traveling toy capable of traveling forward (or backward) and turn. <P>SOLUTION: The traveling toy travels by swinging both right and left legs backward and forward by a motor. The traveling toy has two independent swinging slider crank mechanisms for respective links of right and left legs. The traveling toy travels backward and forward by rotating cranks of the two swinging slider crank mechanisms in the same direction by rotating the motor in one direction, and turns by rotating the cranks of the two swinging slider crank mechanisms in the opposite directions by rotating the motor in the reverse direction. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to a traveling toy.

As a traveling toy that travels by swinging the left and right legs back and forth with motor power, the left and right legs attached to the horizontal axis so as to be able to rotate back and forth, and other parallel to the one axis. Left and right rotators attached to be rotatable with respect to a horizontal axis, and motors that respectively rotate the left and right rotators, and the left and right legs are attached to the rotator at an eccentric position corresponding thereto. It is known that the engagement positions of the left and right rotating bodies are different from each other, and the left and right legs rotate back and forth as the left and right rotating bodies rotate. (Patent Document 1). In this traveling toy, grips are provided on the soles of the left and right legs, and the grips protrude from the soles of the feet when the legs rotate from the front to the rear. Yes.
JP 2002-360942 A

  However, in the traveling toy in the above-mentioned Patent Document 1, when the guide is not used, the left and right legs are alternately forward forward and only travel forward, although the travel speed can be changed, It was impossible to switch between forward or reverse and turning.

  Then, this invention is made | formed in view of this problem, and it aims at providing the traveling toy which can advance (or reverse) and turn.

  The traveling toy according to claim 1 is a traveling toy that travels by swinging the left and right legs back and forth with motor power. Each of the two swing slider crank mechanisms is rotated in the same direction by rotating the motor in one direction to move forward or backward, and the two swing slider crank mechanisms The cranks are configured to rotate by rotating in the opposite directions by rotating the motors in the opposite directions.

  A traveling toy according to a second aspect is the traveling toy according to the first aspect, wherein the motor toy is transmitted to a crank of one of the two swing slider crank mechanisms. A power transmission mechanism, and a one-way clutch, which rotates in one direction of the motor and is linked to the first power transmission mechanism via the one-way clutch. A second power transmission mechanism for rotating the crank in the same direction as the crank of the one oscillating slider crank mechanism; and another one-way clutch when the motor rotates in the reverse direction. The crank of the other swing slider crank mechanism is connected to the first power transmission mechanism via the crank of the one swing slider crank mechanism. Characterized in that it comprises a third power transmission mechanism for rotating the click opposite direction.

  A traveling toy according to a third aspect is the traveling toy according to the first aspect, wherein a first motor for transmitting motor power to a crank of one of the two swinging slider crank mechanisms is provided. A power transmission mechanism and a one-way clutch, which includes a one-way clutch, rotates the motor in one direction, and is linked to the first power transmission mechanism via the one-way clutch to drive the crank of the other swing slider crank mechanism. A second power transmission mechanism for rotating in the same direction as the crank of the swinging slider crank mechanism, and the power of the first power transmission mechanism when the motor includes a planetary gear and rotates in the reverse direction. This is transmitted to the crank of the other swing slider crank mechanism via a planetary gear, and the crank rotates in the opposite direction to the crank of the one swing slider crank mechanism. Characterized in that it comprises a third power transmission mechanism for.

  According to the first aspect of the present invention, the respective cranks of the two swing slider crank mechanisms are rotated in the same direction by rotation of the motor in one direction to move forward or backward, and each of the two swing slider crank mechanisms. The cranks are rotated in the opposite directions by the rotation of the motor in the opposite direction. When the two cranks are rotated in the same direction, they may be rotated in synchronization with each other, or may be rotated with a slight phase shift. When rotating in synchronism, the left and right legs are used to kick the floor. On the other hand, when the phase is shifted, the left and right legs are alternately thrown forward. The rotation direction of the motor in this case may be controlled by remote operation, may be switched by a switch attached to the toy main body, or may be performed by automatic control using a built-in IC or the like.

  According to invention of Claim 2 or 3, the advancing direction of a traveling toy can be easily changed by controlling the rotation direction of one motor.

1. First Embodiment As shown in FIG. 1, the traveling toy 1 includes a body 2, front legs 3 and 3, and rear legs 4 and 4.

(body)
As shown in FIGS. 2 to 4, a motor 5 (see FIG. 2) is installed in the body 2. The motor 5 is installed such that a shaft 7 (see FIGS. 3 and 4) extends rearward. A gear (worm) 8 is attached to the shaft 7. Gears 10 and 11 are attached to both ends of a shaft 9 extending in a direction orthogonal to the shaft 7. Of these, the gear 10 meshes with the gear 8. Gears 13 and 14 are attached to a shaft 12 extending so as to be parallel to the shaft 9. Of these, the gear 13 meshes with the gear 11. On the other hand, the gear 14 can be linked to the gear 13 via the one-way clutch 15. Specifically, the gear 14 is linked to the gear 13 via the one-way clutch 15 only when the motor 5 rotates in the reverse direction, and rotates in conjunction with the gear 13. Further, gears 17 and 18 are attached to a shaft 16 extending so as to be parallel to the shaft 12. Of these, the gear 17 meshes with the gear 13. On the other hand, the gear 18 can be linked to the gear 17 via a one-way clutch 19. Specifically, the gear 18 is linked to the gear 17 via the one-way clutch 19 only when the motor 5 rotates in one direction (forward direction), and rotates in conjunction with the gear 17. An eccentric pin 22 is attached to the outer end surfaces of the gears 17 and 18. A crank C is formed between the eccentric pin 22 and the shaft 16 of the gears 17 and 18. The left and right eccentric pins 22 and 22 are inserted into holes 24 (see FIG. 1) formed in the thighs of the left and right rear legs 4 and 4, respectively. A gear 26 is attached to the shaft 25 extending so as to be parallel to the shaft 12, and the gear 26 meshes with the gears 14 and 18. In the traveling toy 1 of the embodiment, a screw or the like is screwed to the eccentric pin 22 so that the rear leg 3 does not fall off the eccentric pin 22.
The various power elements described above constitute the first power transmission mechanism 30, the second power transmission mechanism 31, and the third power transmission mechanism 32. Specifically, the first power transmission mechanism 30 includes a shaft 7, gears 8 and 10, a shaft 9, and gears 11, 13, and 17, and the second power transmission mechanism 31 includes a one-way clutch 19 and a shaft 16. The third power transmission mechanism 32 includes the one-way clutch 15 and the gears 14, 26, and 18.

(Back leg)
As shown in FIG. 1, a U-shaped notch 40 is formed at the base portion of each rear leg 4. Then, pins 41, 41 provided on the left and right of the body 2 are inserted into the notches 40, 40 of the left and right rear legs 4, 4. As a result, when the gears 17 and 18 rotate, the left and right rear legs 4 and 4 swing back and forth while being restrained by the pins 41 due to the rotation of the left and right cranks C and C, respectively. That is, in the traveling toy 1 of this embodiment, the swing slider crank mechanism is configured including the crank C and the rear leg (link) 4, and the rear leg 4 is swung back and forth by the rotation of the crank C. It has become.

(Front leg)
As shown in FIGS. 1 and 2, the left and right front legs 3, 3 can swing back and forth around a shaft (pin) 44. That is, the left and right eccentric pins 22, 22 are inserted into holes at one end of the left and right links 43, 43, and the pins 44, 44 at the other end of the left and right links 43, 43 are inserted into the eccentric holes 45, 45 is inserted. The front leg (link (insulator)) 3 is swung back and forth by rotation of the crank C. In other words, in the traveling toy 1 of this embodiment, the lever crank mechanism is configured including the crank C and the front leg 3.

(Operation)
When the motor 5 rotates in one direction (forward direction), the motor power is transmitted to the gear 17 via the shaft 7, the gears 8, 10, the shaft 9, and the gears 11, 13, and the gear 17 and thus one crank C is transmitted in one direction. (Clockwise when viewed in FIG. 4). On the other hand, the rotational power of the gear 17 is transmitted to the gear 18 via the one-way clutch 19 and the shaft 16, and the gear 18 and the other crank C are rotated in the same direction as the one crank C. When the left and right cranks C, C rotate, the rotational power of the left and right cranks C, C is transmitted to the left and right front legs 3, 3 via the left and right links 43, 43. As a result, the left and right rear legs 4, 4 and the front legs 3, 3 are swung back and forth, and the traveling toy 1 moves forward. In this case, the left and right cranks C, C may be rotated in synchronization, but may be rotated with a phase shift.

  When the motor 5 rotates in the reverse direction, the motor power is transmitted to the gear 17 via the shaft 7, gears 8, 10, shaft 9, and gears 11, 13, and the gear 17 and one crank C are transmitted in one direction (see FIG. Rotate it counterclockwise when looking at 4. On the other hand, the rotational power of the gear 13 is transmitted to the gear 18 through the one-way clutch 15 and the gears 14, 26, and the gear 18 and the other crank C are rotated in the opposite direction to the one crank C. When the left and right cranks C, C rotate, the rotational power of the left and right cranks C, C is transmitted to the left and right front legs 3, 3 via the left and right links 43, 43, and the left and right front legs 3, 3 swing back and forth. To do. As a result, the left and right rear legs 4, 4 and the left and right front legs 3, 3 are swung back and forth, and the traveling toy 1 turns. That is, since the direction of kicking the ground is different between the left and right legs, the traveling toy 1 easily turns in a predetermined direction.

2. Second Embodiment As shown in FIG. 5, the traveling toy 101 includes a body 102, front legs 103 and 103, and rear legs 104 and 104.

(body)
As shown in FIGS. 6 to 8, a motor 105 is installed in the body 102. The motor 105 is installed such that the shaft 107 extends forward. A gear (worm) 108 is attached to the shaft 107. Gears 110, 111, and 112 are attached to a shaft 109 that extends in a direction orthogonal to the shaft 107. Of these, the gear 110 meshes with the gear 108. On the other hand, the gear 111 is a sun gear, and the planetary gear 113 is engaged with the sun gear 111. The planetary gear 113 meshes with a gear 117 described later only when the motor 105 rotates in the reverse direction. In the figure, reference numeral 114 denotes an arm that supports the planetary gear 113. Further, gears 116 and 117 are attached to a shaft 115 extending so as to be parallel to the shaft 109. Of these, the gear 116 meshes with the gear 112. On the other hand, the gear 117 can be linked to the gear 116 via the one-way clutch 118. Specifically, the gear 117 is linked to the gear 116 via the one-way clutch 118 only when the motor 105 rotates in one direction (forward direction), and rotates in conjunction with the gear 116. Further, eccentric pins 119 are attached to the outer end surfaces of the gears 116 and 117, respectively. That is, the crank C is constituted between the shaft 115 of the gears 116 and 117 and the eccentric pin 119 as in the first embodiment. The left and right eccentric pins 119, 119 are inserted into holes 120 formed in the thighs of the left and right front legs 103, 103, respectively.
The various power elements described above constitute the first power transmission mechanism 121, the second power transmission mechanism 122, and the third power transmission mechanism 123. Specifically, the first power transmission mechanism 121 includes a shaft 107 and gears 108, 110, 112, and 116, and the second power transmission mechanism 122 includes a shaft 115, a one-way clutch 118, and a gear 117. The third power transmission mechanism 123 is constituted by gears 111, 113, and 117.

(Front leg)
As shown in FIG. 5, a U-shaped notch 140 is formed at the base of each front leg 103. And the pin 141 provided in the left and right of the trunk | drum 102 is inserted in the notch 140 of the right and left front legs 103 and 103, respectively. As a result, when the gears 117 and 116 rotate, the left and right front legs 103 and 103 swing back and forth while being restrained by the pins 141, respectively. That is, the traveling toy 101 of this embodiment includes a swing slider crank mechanism including the crank C and the front leg 103, and the front leg 103 is swung back and forth by the rotation of the crank C.

(Back leg)
As shown in FIGS. 6 and 7, the left and right rear legs 104, 104 can swing back and forth about a shaft (pin) 142. That is, the left and right eccentric pins 119 and 119 are inserted into the holes at one end of the link 143, respectively, and the pins 144 and 144 at the other ends of the left and right links 143 and 143 are inserted into the eccentric holes 145 and 145 of the left and right rear legs 104 and 104, respectively. Has been inserted. The rear legs (links) 104 are swung back and forth by the rotation of the crank C. In other words, the traveling toy 101 of this embodiment includes the crank C and the rear leg 104 to constitute a lever crank mechanism.

(Operation)
When the motor 105 rotates in one direction (forward direction), the motor power is transmitted to the gear 116 via the shaft 107 and the gears 108, 110, and 112, and the gear 116 and thus one crank C is viewed in one direction (see FIG. 5). Rotate counterclockwise. On the other hand, the rotational power of the gear 116 is transmitted to the gear 117 via the shaft 115 and the one-way clutch 118, and the gear 117 and the other crank C are rotated in the same direction as the one crank C. When the left and right cranks C, C rotate, the rotational power of the left and right cranks C, C is transmitted to the left and right rear legs 104, 104 via the left and right links 143, 143. As a result, the left and right front legs 103 and 103 and the rear legs 104 and 104 are swung back and forth, and the traveling toy 101 moves forward. This state is shown in FIG. In this case, the left and right cranks C, C may be rotated in synchronization, but may be rotated with a phase shift.

  When the motor 105 rotates in the reverse direction, the motor power is transmitted to the gear 116 via the shaft 107 and the gears 108, 110, and 112, and the gear 116 and thus one crank C is rotated in one direction (clockwise as viewed in FIG. 5). ) To rotate. On the other hand, the rotational power of the gear 110 is transmitted to the gear 111, causing the planetary gear 113 to revolve in the direction of meshing with the gear 117. As a result, the gear 117 and the other crank C are rotated in the opposite direction to the one crank C. As a result, the left and right front legs 103, 103 and the rear legs 104, 104 are swung back and forth, and the traveling toy 101 turns. That is, since the direction of kicking the ground is different between the left and right legs, the traveling toy 101 turns in a predetermined direction. This state is shown in FIG.

3. Third Embodiment As shown in FIG. 9, the traveling toy 201 includes a body 202, front legs 203 and 203, and rear legs 204 and 204.

(body)
As shown in FIGS. 10 to 12, a motor 205 is installed in the body 202. The motor 205 is installed such that the shaft 206 extends downward. A gear (worm) 207 is attached to the shaft 206. Gears 209, 210, and 211 are attached to a shaft 208 that extends in a direction orthogonal to the shaft 206. Of these, the gear 209 meshes with the gear 207. On the other hand, the gear 210 is a sun gear, and the planetary gear 212 meshes with the sun gear 210. The planetary gear 212 meshes with a gear 216 described later only when the motor 205 rotates in the reverse direction. In the figure, reference numeral 213 denotes an arm that supports the planetary gear 212. Gears 215 and 216 are attached to a shaft 214 extending in parallel with the shaft 208. Of these, the gear 215 meshes with the gear 211. On the other hand, the gear 216 can be linked to the gear 215 via the one-way clutch 217. Specifically, the gear 216 is linked to the gear 215 via the one-way clutch 217 only when the motor 205 rotates in one direction (forward direction), and rotates in conjunction with the gear 215. Further, eccentric pins 218 are attached to the outer end surfaces of the gears 215 and 216. That is, a crank C is formed between the shaft 214 of the gears 215 and 216 and the eccentric pin 218. The left and right eccentric pins 218 and 218 are inserted into holes 219 formed in the thighs of the left and right front legs 203 and 203, respectively.
The first power transmission mechanism 221, the second power transmission mechanism 222, and the third power transmission mechanism 223 are configured by the elements described above. Specifically, the first power transmission mechanism 221 includes a shaft 206 and gears 207, 209, 211, and 215, and the second power transmission mechanism 222 includes a shaft 214, a one-way clutch 217, and a gear 216. The third power transmission mechanism 223 includes gears 210, 212, and 216.
(Front leg)

As shown in FIG. 9, a U-shaped notch 230 is formed at the base of each front leg 203. Then, shafts 231 provided on both sides of the body 202 are inserted into the notches 230 of the left and right front legs 203, 203. As a result, on both the left and right sides of the body 202, a swing slider crank mechanism is formed in which the front leg 203 is a link and the crank C is between the shaft 214 of the gears 215 and 216 and the eccentric pin 218. When the gears 215 and 216 rotate, the front legs 203 and 203 swing back and forth. In this case, the crank C may be rotated in the same direction with the left and right cranks C having the same phase, or the crank C may be rotated in the same direction by shifting the phase.
(Back leg)

  As shown in FIGS. 10 and 11, the left and right rear legs 204, 204 can swing back and forth by a shaft (pin) 242. That is, the left and right eccentric pins 218 and 218 are inserted into the holes at one end of the link 243, respectively, and the pins 244 and 244 at the other ends of the left and right links 243 and 243 are inserted into the eccentric holes 245 and 245 of the left and right rear legs 204 and 204, respectively. Has been inserted. The left and right links 243 and 243 are each provided with a long hole 246 at the center. Then, pins 247 and 247 attached to the left and right sides of the body 202 are inserted into the left and right elongated holes 246 and 246, respectively. The rear leg 204 is swung by the rotation of the crank C.

(Operation)
When the motor 205 rotates in one direction (forward direction), the motor power is transmitted to the gear 215 via the shaft 206 and the gears 207, 209, 211, and the gear 215 and thus one crank C is viewed in one direction (see FIG. 9). Rotate counterclockwise. On the other hand, the rotational power of the gear 215 is transmitted to the gear 216 via the shaft 214 and the one-way clutch 217, and the gear 216 and thus the other crank C is rotated in the same direction as the one crank C. At the same time, the rotation of the left and right cranks C is transmitted to the left and right rear legs 204 and 204 via the left and right links 243 and 243, whereby the left and right front legs 203 and 203 and the rear legs 204 and 204 swing back and forth. Then, the traveling toy 201 moves forward. This state is shown in FIG. In this case, the left and right cranks C, C may be rotated in synchronization, but may be rotated with a phase shift.

  When the motor 205 rotates in the reverse direction, the motor power is transmitted to the gear 215 via the shaft 206 and the gears 207, 209, 211, and the gear 215 and thus one crank C is rotated in one direction (clockwise as viewed in FIG. 9). Rotate. On the other hand, the rotational power of the gear 209 is transmitted to the gear 210, causing the planetary gear 212 to revolve in the direction of meshing with the gear 216. As a result, the gear 216 and the other crank C are rotated in the opposite direction to the one crank C. As a result, the left and right front legs 203, 203 and rear legs 204, 204 are swung, and the traveling toy 201 turns. That is, since the direction of kicking the ground differs between the left and right legs, the traveling toy 201 turns in a predetermined direction. This state is shown in FIG.

(Modification of the present invention)
Although the embodiment of the present invention has been described above, the present invention is not limited to such an embodiment, and it is needless to say that the present invention can be applied to a biped traveling toy.

It is a perspective view at the time of seeing the running toy of 1st Embodiment from back. It is a perspective view which notches and shows a part of traveling toy of FIG. It is a top view which shows the internal mechanism of the traveling toy of FIG. It is a side view which shows the internal mechanism of the traveling toy of FIG. It is a side view of the traveling toy of 2nd Embodiment. It is a perspective view which shows the state which removed the trunk | drum of the traveling toy of FIG. It is a perspective view which shows the state which removed the trunk | drum of the traveling toy of FIG. It is a rear view of the state which removed the trunk of the running toy of FIG. It is a side view of the traveling toy of 3rd Embodiment. It is a perspective view which shows the state which removed the trunk | drum of the traveling toy of FIG. It is a perspective view which shows the state which removed the trunk | drum of the traveling toy of FIG. FIG. 10 is a rear view of the traveling toy of FIG. 9 with the body removed.

Explanation of symbols

1,101,201 Traveling toy 2,102,202 Body 3,103,203 Front leg 4,104,204 Rear leg 5,105,205 Motor 15, 19, 118,217 One-way clutch 113,212 Planetary gear C Clutch

Claims (3)

  A traveling toy that travels by swinging the left and right legs back and forth with motor power has two independent swing slider crank mechanisms each having the left and right legs as one link. The respective cranks of the slider crank mechanism are rotated in the same direction by rotating the motor in one direction to move forward or backward, and the cranks of the two swing slider crank mechanisms are moved in the opposite directions of the motor. A traveling toy configured to rotate by rotating in opposite directions with each other.   A first power transmission mechanism for transmitting motor power to the crank of one of the two swing slider crank mechanisms and one one-way clutch, and rotation of the motor in one direction For rotating the crank of the other swing slider crank mechanism in the same direction as the crank of the one swing slider crank mechanism in conjunction with the first power transmission mechanism via the one one-way clutch. A second power transmission mechanism and another one-way clutch, and the other swing slider linked to the first power transmission mechanism via the other one-way clutch when the motor rotates in the reverse direction. A third power transmission mechanism for rotating a crank of the crank mechanism in a direction opposite to the crank of the one swing slider crank mechanism; Running toy as claimed in claim 1, wherein.   A first power transmission mechanism for transmitting motor power to the crank of one of the two swing slider crank mechanisms and a one-way clutch, and when the motor rotates in one direction The second power for rotating the crank of the other swing slider crank mechanism in the same direction as the crank of the one swing slider crank mechanism linked to the first power transmission mechanism via the one-way clutch. A transmission mechanism and a planetary gear, the power of the first power transmission mechanism is transmitted to the crank of the other swing slider crank mechanism via the planetary gear when the motor rotates in the reverse direction. And a third power transmission mechanism for rotating the first oscillating slider crank mechanism in a direction opposite to the crank of the one oscillating slider crank mechanism. Traveling toy according to.

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