JP7048805B1 - Moving toys - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a new toy capable of moving moving parts while rotating them on the way back and forth. A rotating shaft to which a moving component is attached is provided, and a spiral first engaging portion is formed on one of a fixed portion and the rotating shaft along the axial direction of the rotating shaft, and the other is formed with the spiral first engaging portion. A second engaging portion that engages with the first engaging portion is formed, and the second engaging portion is engaged with the first engaging portion by linearly moving the rotation axis along the axial direction. The rotating shaft was rotated by imitating the joint portion, and the moving component was made to make a spiral motion. [Selection diagram] FIG. 14

Description

The present invention relates to a motion toy.

Conventionally, a toy described in Patent Document 1 is known as a toy that operates a moving component by using a spiral mechanism.
This toy is equipped with a spiral shaft that stands up from the base and an elevating table on which an automobile toy is placed. A protrusion protruding from the inner wall surface of the insertion hole is engaged with the strip. In this toy, the elevator is raised by rotating the spiral shaft, and the elevator is lowered by its own weight.

Jitsukosho No. 63-24957

In this toy, when the elevator is raised, the rotation of the elevator is stopped and the rotating shaft is rotated to raise the elevator as it is, and when the elevator is lowered, the rotation of the rotating shaft is stopped and the elevator is rotated by its own weight. It is descending while letting it go. That is, the rotation of the elevating table had to be stopped when the elevating table was raised, and it was not possible to move the elevating table in the axial direction of the rotation axis while rotating the elevating table at both the time of raising and lowering and the time of lowering.
The present invention has been made in view of such problems, and an object of the present invention is to provide a new toy capable of moving moving parts while rotating them on the way back and forth.

The first means is
Equipped with a rotating shaft to which moving parts are attached,
A first spiral engaging portion is formed on one of the fixed portion and the rotating shaft along the axial direction of the rotating shaft, and the other engages with the first engaging portion. A joint is formed,
By linearly reciprocating the axis of rotation along the axial direction, the second engaging portion is made to imitate the first engaging portion to rotate the rotating shaft, and the moving component is spirally moved. To let
A linear third engaging portion parallel to the axis is connected to at least one end of the first engaging portion.
At least one end side of the first engaging portion, the third engaging portion is made to imitate the second engaging portion so that the rotation axis is moved only linearly without rotation. Make the moving parts move linearly,
It is characterized by that.

The second means is the first means, characterized in that the first engaging portion is formed on the rotating shaft and the second engaging portion is formed on the fixed portion. do.

The third means is a second means , in which the engaging portion on the side where the first engaging portion is formed is a groove and the second engaging portion is a protrusion. It is a feature.

The fourth means is any one of the first to third means , comprising a movable support that rotatably supports the rotation axis and moves in the axial direction of the rotation axis, and the movable support. It is characterized in that the rotation axis is linearly moved in one direction from the initial position by being pulled by a string, and the rotation axis is returned to the initial position by a predetermined urging force.

The fifth means is any one of the first to fourth means , the rotating shaft is provided extending in the vertical direction, and the moving component is a first article in which an article can be placed on the upper surface. It is characterized by being a pedestal having a mounting portion.

The sixth means is the fifth means ,
A second article placing portion connected to the first article placing portion is provided outside the pedestal in a state where the pedestal is in either the uppermost position or the lowest position, and the second article placing portion is provided. The article is configured to be able to enter the first article placing portion from the article placing portion, and the second article placing portion is provided with a stopper that appears and disappears from the upper surface.
The stopper is
When the pedestal is in the one position, it sinks from the upper surface of the second article placing portion and allows the article to pass through.
When the pedestal leaves the one position, it protrudes from the upper surface of the second article placing portion and stops the article.
It is characterized by that.

The seventh means is the sixth means ,
A linear third engaging portion parallel to the axis is connected to at least one end of the first engaging portion, and the third engaging portion engages with the second engaging portion. When doing so, the axis of rotation is configured to move only linearly without rotation.
When the pedestal is in the one position, the third engaging portion engages with the second engaging portion.
On the upper surface of the pedestal, a sliding contact wall is provided outside the first article placing portion.
The sliding contact wall is
When the pedestal leaves the one position, the third engaging portion enters the first article placing portion only in the front portion while the third engaging portion engages with the second engaging portion. Lift the front part of the article by the protrusion of the stopper,
After that, the first engaging portion engages with the second engaging portion to slide into the front portion of the article and push the article back toward the second article placing portion.
It is characterized by that.

The eighth means is the sixth or seventh means ,
Outside the pedestal, a third article placing portion having a step from the second article placing portion is provided at a position different from the second article placing portion.
The third article placing portion is connected to the first article placing portion in a state where the pedestal is in the other position of the uppermost position or the lowest position, and the third article placing portion is connected to the first article placing portion. It is characterized in that the article is configured to be transferred to the article placing portion.

The ninth means is any one of the fifth to seventh means , wherein the article is a vehicle toy, and the article placing portion constitutes a part of the track of the vehicle toy. It is a feature.

According to the first means, the rotation axis is rotated linearly along the axis direction to cause the moving parts to make a spiral motion, so that the operation parts can be operated back and forth with a simple structure. The part can be made to spiral.
Further, a linear third engaging portion is continuously provided, and when the third engaging portion engages with the second engaging portion, the rotation axis only moves linearly without rotation. In addition to being able to bring about changes in movement, it is possible to keep the rotational positions of moving parts constant when stopped.

According to the second means, since the spiral first engaging portion is formed on the rotating shaft, a special space for providing the first engaging portion outside the shaft is not required, which is space-like. It is also advantageous.

According to the third means , since the first engaging portion having a spiral shape is a groove and the second engaging portion is a protrusion, the second engaging portion is a second even if the device is shaken to some extent. The first engaging portion can be reliably traced to the engaging portion.

According to the fourth means , the movable support is pulled by a string to linearly move the rotation axis in one direction from the initial position, and the rotation axis is returned to the initial position by a predetermined urging force. The configuration is simplified, and the power source can be installed away from the axis of rotation, increasing the degree of freedom in design.

According to the fifth means , the rotating shaft is provided so as to extend in the vertical direction, and the moving component is a pedestal having a first article placing portion on the upper surface on which the article can be placed. It is effective for showing the article being made from various directions. Further, at that time, the pedestal moves up and down, so that the effect as a display is high.

According to the sixth means , the article automatically enters the first article insertion portion from the second article placing portion at either the uppermost position or the lowest position of the pedestal, and the uppermost position or the lowest position of the pedestal. It is possible to realize a toy that spirally carries to the other position of the position.

According to the seventh means , when the pedestal leaves one position, only the front portion enters the first article mounting portion while the third engaging portion engages with the second engaging portion. The front part of the article is lifted by the protrusion of the stopper, and then the first engaging portion engages with the second engaging portion to slide into the front part of the article and the article is placed on the second article. Since it is pushed back to the placement side, the pedestal can surely leave one position with a predetermined number of articles placed on it.

According to the eighth means , the first article placing portion is connected to the third article placing portion in a state where the pedestal is in the other position of the uppermost position or the lowest position, and the first article placing portion is connected to the third article placing portion. Since the article is configured to be transferred to the third article placing portion, it is possible to realize a toy that spirally carries and discharges the article to one of the uppermost position and the lowest position of the pedestal.

According to the ninth means , since the article placing portion constitutes a part of the track of the vehicle toy, it is possible to realize a toy that raises and lowers the vehicle toy in a spiral shape.

It is a perspective view of an orbital toy. It is a perspective view which shows the mounting structure of one track piece. It is a perspective view which looked at the state which disassembled the track piece and the pedestal of FIG. 2 from the bottom. It is a side view of the mounting structure of the stopper of the track piece of FIG. It is a perspective view of the state which the rotation mechanism is seen from above. It is a perspective view of the state which the rotation mechanism is seen from the bottom. It is a perspective view which shows the track piece of FIG. 2 and the attachment structure of the track piece connected to the track piece. It is a perspective view which shows the connection state of a pinch and a string fastening member. It is a perspective view which shows the coupling release state of a knob and a string fastening member. It is a figure which shows the state before the jumping of a jumping device. It is a figure which shows the state after the jumping of a jumping device. It is a perspective view which shows the connection state of some orbital pieces. It is a perspective view which shows the mounting structure of the stopper of one track piece. It is a figure which shows the structure of the rotary elevating device. It is a perspective view which shows the handle and a reel. It is a figure which shows the engaging relationship between a rotating shaft and an engaging member. It is a top view which shows the approach state of the automobile toy to one track piece. It is a top view which showed the push-back state of a car toy. It is an exploded perspective view which showed the discharge structure of the automobile toy of one track piece.

<< An example of how to play >>
FIG. 1 is a perspective view of the orbital toy 100.
The method of playing with the orbital toy 100 will be described by taking as an example the case where one automobile toy 1 is used.
When the automobile toy 1 is placed on the track piece 11 and then the button 2 is gently hit, the track piece 11 rises spirally around the rotation shaft 11a in small steps, and the direction of the track piece 11 changes by 180 degrees. The toy 1 transfers from the track piece 11 to the slope of the track piece 12. Since the track piece 12 constitutes a straight uphill, the automobile toy 1 stays on the slope.

Next, when the knob 3 is slowly slid to the left, the orbital piece 12 gently jumps up about the axis 12a, and the orbital piece 12 changes from an uphill to a downhill. Then, the automobile toy 1 descends from the track piece 12 and transfers to the track piece 13. The track piece 13 forms a counterclockwise hairpin curve and is slightly downhill. Therefore, the automobile toy 1 goes down the track piece 13 and gets on the track piece 14 and is stopped.

Next, when the handle 4 is rotated clockwise, the orbital piece 14 rises while rotating in place to reach the same height as the entrance of the orbital piece 15. Then, the automobile toy 1 transfers from the track piece 14 to the track piece 15. The track piece 15 constitutes a downhill on the left curve. Therefore, the automobile toy 1 goes down the track piece 15 and reaches the exit of the track piece 15. The exit of the track piece 15 and the entrance of the next track piece 16 are separated from each other, and the exit of the track piece 15 is at a higher position. Therefore, the automobile toy 1 jumps and jumps onto the track piece 16. The track piece 16 forms an S-shaped curve and is a downhill slope. Therefore, the automobile toy 1 goes down the track piece 16 and is stopped in front of the track piece 17.

The track piece 17 is a track that swings by the operation of the grip 5. When the grip 5 is operated, the track piece 17 swings, and when the position and timing are matched, the automobile toy 1 moves to the track piece 17 and the track piece 17. Return to 11.

<< Rotational lifting device 20 >>
The rotary elevating device 20 raises the track piece 11 while revolving around the rotation shaft 11a by repeatedly hitting the button 2.
The rotary elevating device 20 includes a rotary mechanism 20a that rotates the rotary shaft 11a, and a spiral mechanism 20b that causes the orbital piece 11 to make a spiral motion by the rotation of the rotary shaft 11a.

FIG. 2 is a perspective view showing the mounting structure of the track piece 11, and FIG. 3 is a perspective view showing a state in which the track piece 11 and the pedestal 27 are disassembled from below.
A track piece 11 is attached to the rotating shaft 11a via a pedestal 27.
That is, a groove 11b is formed on the outer periphery of the rotating shaft 11a along the axial direction. The rotating shaft 11a is inserted through the tubular portion 27a of the pedestal 27. A ridge 27b provided on the inner surface of the tubular portion 27a along the axial direction is engaged with the groove 11b. That is, the pedestal 27 is attached to the rotating shaft 11a so as to be non-rotatable and movable in the axial direction.
The pedestal 27 and the track piece 11 are connected by fitting.

Next, the track piece 11 will be described.
FIG. 4 is a side view of the mounting structure of the stopper 11d.
The floor of the track piece 11 has a downward slope toward the front of the automobile toy 1 on which the track piece 11 is placed. Therefore, if nothing is done, the automobile toy 1 will fall from the track piece 11. Therefore, at the front end of the track piece 11, a stopper 11d that can rotate around the shaft 11c and can be tilted, and a locking member 11f that can rotate around the shaft 11e and lock the stopper 11d in an upright position. And are provided.
The stopper 11d is urged by a torsion spring (not shown) in the direction of tilting. Further, the locking member 11f is urged by a torsion spring (not shown) in a direction in which the stopper 11d can be locked in the upright position.
In the locking member 11f, the claw 11g formed apart from the shaft 11e abuts on the shaft portion of the stopper 11d, and the stopper 11d is locked in the upright position.
In this stopper 11d, the locking member 11f is in sliding contact with the triangular sliding contact portion 12c formed on the support column 12b (FIG. 7) under the track piece 12 immediately before the track piece 11 spirally moves and is connected to the track piece 12. By moving downward, the tip portion falls on the track piece 12 and rides on the track piece 12. As a result, the automobile toy 1 on the track piece 11 is transferred to the track piece 12.
While the stopper 11d is tilted toward the track piece 12 and the tip portion is on the track piece 12, the ascending state of the track piece 11 is maintained by the urging force of the stopper 11d. Then, when the track piece 12 is flipped up, the stopper 11d stands up and is locked again by the locking member 11f.

FIG. 5 is a perspective view of the rotation mechanism 20a as viewed from above, and FIG. 6 is a perspective view of the rotation mechanism 20a as viewed from below.
When the button 2 is pressed, the rotation mechanism 20a transmits the power to the rotation shaft 11a via the lever 21, the rack 22, and the gears 23, 24, 25, 26, and rotates the rotation shaft 11a.
That is, the button 2 is configured to be movable up and down. Below the button 2, a lever 21 that can rotate about the intermediate shaft 21a is provided. One end of the lever 21 is pushed when the button 2 is pressed, and the lever 21 rotates in a predetermined direction about the shaft 21a. A rack 22 capable of reciprocating in a horizontal plane is engaged with the other end of the lever 21, and operates in one direction by pressing the button 2. A return spring 22b is hooked on the rack 22, and when the pressing of the button 2 is stopped, the rack 22, the lever 21, and the button 2 are returned to the initial positions.

The teeth of the rack 22 mesh with the gear 23. Below the gear 23, a gear 24 that rotates concentrically with the gear 23 is provided. Further, an arm 25a is provided on the shaft 23a of the gear 23, and the arm 25a is provided with a gear (planetary gear) 25 having the gear 24 as a sun gear. The arm 25a is rotatable within a predetermined range, and when the button 2 is pressed, the arm 25a is rotated in a predetermined direction by the rotation of the gear 24 to mesh the gear 25 with the gear 26. As a result, the gear 26 rotates. Since the gear 26 is a missing tooth gear and the rotating shaft 11a is erected on the gear 26, the rotating shaft 11a is integrally rotated by the rotation of the gear 26. The reason why the gear 26 is a missing tooth gear is that the gear 25 just reaches the missing tooth portion when the track piece 11 is fully raised, and the track piece 11 is not operated even if the button 2 is pressed further. To do.
A ratchet mechanism can be used instead of the planetary gear mechanism. However, in the case of the ratchet mechanism, since there is no reversion even if the hand is released from the button 2, the rotation shaft 11a rotates by the number of times the button 2 is pressed.

When the rotating shaft 11a rotates, the spiral mechanism 20b raises the pedestal 27 attached to the rotating shaft 11a while revolving along the slope 28a. The slope 28a is formed on a wall 28 surrounding a half of the rotating shaft 11a.
Near the rotating shaft 11a, a semicircular wall 28 in a plan view is provided concentrically with the rotating shaft 11a. A slope 28a is formed on the wall 28. The wall 28 provided next to the rotating shaft 11a may be a wall 28 that can be imitated by the pedestal 27, and the copying surface may simply be inclined with respect to the rotating shaft 11a.
On the other hand, a wheel 27c is attached to the pedestal 27, and the wheel 27c rides on the slope 28a. The pedestal 27 may rest directly on the slope 28a.
Then, the pedestal 27 smoothly spirals outside the rotating shaft 11a by rolling the wheels 27c on the slope 28a with the rotation of the rotating shaft 11a.
By spirally moving the pedestal 27 and the track piece 11 in this way, it is possible to realize a highly interesting elevating device.

<< Jumping device 40 >>
As shown in FIG. 7, one end of the track piece 12 is attached to the support column 41 via a horizontal shaft 12a. The jumping device 40 (see FIGS. 10 and 11) pushes up the track piece 12 near the shaft 12a by the operation of the knob 3.
The flip-up device 40 includes a hoisting mechanism 40a operated by the operation of the knob 3 and a rack mechanism 40b operated by the power of the hoisting mechanism 40a.

First, the picking 3 will be described.
FIG. 8 is a perspective view showing a state in which the knob 3 and the stringing member 45 are connected, and FIG. 9 is a perspective view showing a state in which the knob 3 and the stringing member 45 are released from each other.
The knob 3 is fixed to a slider 43 that operates along the guide groove 42. The slider 43 is coupled to a string fastener 45 to which one end of the string 44 is tied. The string fastener 45 connects the knob 3 and the winding mechanism 40a.
The slider 43 and the strap fastener 45 are connected by a snap fit. For example, it is connected by fitting the concave portion and the convex portion or by an elastic locking claw. It may be magnetically worn regardless of the snap fit.
Here, a columnar male tool 43a is formed on the slider 43, and the male tool 43a is engaged with a C-shaped female tool 45a formed on the strap fastener 45 and having elasticity. The male tool 43a and the female tool 45a are engaged by abutting from the operating direction of the slider 43, and when the slider 43 is operated, the string fastener 45 also operates integrally. Further, the female tool 45a of the slider 43 and the female tool 45a of the string fastener 45 are disengaged when a force more than necessary is applied to the knob 3, and the coupling between the slider 43 and the string fastener 45 is released. .. As a result, the transmission of the power of the knob 3 is cut off. In the embodiment, when the knob 3 is quickly operated to the left, the transmission of the power of the knob 3 is cut off to prevent the track piece 12 from jumping up quickly, and the automobile toy 1 riding on the track piece 12 flies. I try not to be done.

The winding mechanism 40a raises the movable rack 48 in the rack mechanism 40b via the string 44 tied to the string fastener 45 by the operation of the knob 3.
FIG. 10 is a diagram showing a state when the movable rack 48 is lowered, and FIG. 11 is a diagram showing a state when the movable rack 48 is raised.
The string 44 tied to the string fastener 45 is wound around a pulley 46 or the like and then guided into the support column 41 from below. In the support column 41, the pulley is wound around a pulley (constant pulley) 47 provided at the upper part of the fixed portion 41a, and the other end is connected to a movable rack 48 below the pulley. The movable rack 48 can be raised and lowered along the rail 49, and when the knob 3 is operated, the movable rack 48 is pulled by the string 44 and rises.

The rack mechanism 40b includes a movable rack 48, a double gear 51 attached to the push-up member 50, and a fixed rack 52 formed on the fixed portion 41a. The double gear 51 is composed of a large-diameter gear and a small-diameter gear that operate integrally, of which the large-diameter gear meshes with the teeth of the movable rack 48 and the small-diameter gear meshes with the teeth of the fixed rack 52.
As a result, when the knob 3 is operated and the movable rack 48 is pulled by the string 44 and rises, the double gear 51 rotates in one direction, and the small diameter gear of the double gear 51 runs up along the fixed rack 52. As a result, the push-up member 50 rises and pushes up the track piece 12. When the operation of the knob 3 is stopped, the push-up member 50 descends by its own weight, follows the reverse path, and the movable rack 48 and the knob 3 return to the initial positions. In this case, a return spring may be provided if necessary.

<< Stopper 60 >>
FIG. 12 is a perspective view showing the track pieces 13 to 15, and FIG. 13 is a perspective view showing a mounting structure of the stopper 60 of the track pieces 13.
A case 61 containing a stopper 60 is attached to the lower side of the exit of the track piece 13. The stopper 60 is configured to be rotatable in the vertical direction about the shaft 60a, and is urged upward by a torsion spring (not shown).
The stopper 60 has a tongue piece-shaped base 60b, and a locking projection 60c is erected on the upper surface of the base 60b in the middle portion in the longitudinal direction. The locking projection 60c is composed of a first portion extending in the longitudinal direction of the substrate 60b and a second portion extending in the width direction and having an intermediate portion connected to the first portion, and is formed in a T shape as a whole. ing.
Then, when the track piece 14 of the next stage is in the descending position, the stopper 60 is moved downward by pushing the tip end portion of the substrate 60b downward by the rotary table 72 described later, and the locking projection 60c is the upper surface of the track piece 13. Die from. Further, when the rotary table 72 rises, the tip of the substrate 60b is released from the restraint of the stopper 60, and the stopper 60 is moved upward by a torsion spring (not shown) so that the locking projection 60c projects onto the upper surface of the track piece 13. The automobile toy 1 is stopped by the protruding locking protrusion 60c.

<< Rotational lifting device 70 >>
FIG. 14 is a diagram showing a rotary elevating device 70.
A rotary table 72 is provided on the housing 71, and a track piece 14 is provided on the rotary table 72. A rotary shaft 78 is vertically installed at the center of the rotary table 72, the rotary shaft 78 extends into the housing 71, and a movable support 73 is attached to a lower end portion thereof. The movable support 73 rotatably supports the rotating shaft 78, and is configured to be able to move up and down integrally with the rotating shaft 78.
The rotary elevating device 70 includes a winding mechanism 70a operated by operating the handle 4 and a spiral mechanism 70b operated by the power of the winding mechanism 70a.

FIG. 15 is a perspective view showing the handle 4 and its surroundings.
The winding mechanism 70a moves the movable support 73 upward through the string 75 by operating the handle 4. The handle 4 is connected to the reel 74 via a gear 4b attached to the shaft 4a of the handle 4 and a gear 74b attached to the shaft 74a of the reel 74 for winding the string 75. A one-way clutch (not shown) is provided between the handle 4 and the reel 74.
The string 75 pulled out from the reel 74 is guided into the housing 71 from below. Then, in the housing 71, the string 75 is wound around a pulley (constant pulley) 76 provided at the upper part, the other end is tied to the movable support 73, and the movable support 73 is operated by operating the handle 4. Raise it. The movable support 73 is urged downward by a coil spring (not shown), but if it is lowered by its own weight, the coil spring is unnecessary.

A spiral groove 78b extending along the axial direction is formed on the outer periphery of the rotating shaft 78. Further, on the outer periphery of the rotating shaft 78, a straight groove 78c which is continuously provided at the upper end of the groove 78b and extends in the axial direction is formed.
As shown in FIG. 16, the rotating shaft 78 is inserted into the insertion hole 77a of the fixed engaging member 77, and the protrusion 77b on the inner surface of the insertion hole 77a engages with any of the grooves 78b and 78c.
The spiral mechanism 70b operates the handle 4, and when the movable support 73 and thus the rotating shaft 78 rises, the rotating shaft 78 is rotated by the engagement between the groove 78b and the protrusion 77b. As a result, the rotary table 72 rises while operating in a spiral shape on the spot.
In the initial position, since the straight groove 78c and the protrusion 77b are engaged with each other, when the rotary shaft 78 rises, the rotary table 72 rises vertically without rotating.
Further, when the rotary table 72 is released from the handle 4, the rotary table 72 returns to the initial position while spirally moving in the opposite motion due to its own weight and the urging force of the spring acting on the movable support 73. Immediately before returning to the initial position, the immediately preceding groove 78c and the protrusion 77b are engaged with each other, so that the rotary table 72 descends straight.

<< Extruded structure 80 >>
17 and 18 are plan views for explaining the operation of the extruded structure 80.
When the rotary table 72 is lowered, the locking projection 60c of the stopper 60 is submerged from the upper surface of the track piece 13. Therefore, the front portion of the next automobile toy 1 may enter the track piece 14 due to the difference in the total length of the automobile toy 1 to be driven. If the rotary table 72 is raised in this state, there is a risk that the next automobile toy 1 may be shaken off.
Therefore, the rotary table 72 is provided with a plan-viewing bow-shaped sliding contact wall 81 on the upstream side of the track piece 14 so that the radius of movement of the outer surface increases with rotation.
On the outer surface of the sliding contact wall 81, the rotary table 72 rises vertically from the descending position, the locking projection 60c of the stopper 60 lifts the front portion of the next automobile toy 1, and then the rotary table 72 begins to rotate. Occasionally, it begins to slide into the front part of the automobile toy 1. Then, the automobile toy 1 is pushed back as the rotary table 72 rotates. The pushed back automobile toy 1 is stopped by the stopper 60.

<< Discharge structure 90 >>
FIG. 19 is an exploded perspective view showing the discharge structure of the automobile toy 1.
The track piece 14 is pivotally supported via a shaft 14b on the front side of the mounted automobile toy 1, and can rotate up and down about the shaft 14b. Under the floor of the track piece 14, an angle changing lever 91 that can rotate around the shaft 91a and changes the inclination angle of the floor of the track piece 14 is provided. A wedge-shaped cam 91b is provided on one end side of the angle changing lever 91, and a projecting piece 91c is formed on the other end side. The cam 91b is in contact with a protrusion (not shown) on the lower surface of the track piece 14, and is configured so that the inclination angle of the floor of the track piece 14 is changed by the rotation angle of the angle changing lever 91.
Specifically, the angle changing lever 91 is urged by a coil spring (not shown), and normally, the projecting piece 91c makes a downward slope toward the rear side of the vehicle toy 1 on which the floor of the track piece 14 is placed. It is in a position to maintain. Then, just before the track piece 14 moves upward and matches the track piece 15, the protrusion 91c hits the protrusion 15b attached to the pedestal 15a of the track piece 15, and the angle changing lever 91 rotates. As a result, the track piece 14 rotates about the shaft 14b and has a downward gradient toward the front side of the mounted automobile toy 1, and when the track piece 14 moves upward and matches the track piece 15. The automobile toy 1 is discharged onto the track piece 15.

<< Modification example >>
In the above embodiment, in the spiral mechanism 70b, grooves 78b and 78c are provided on the rotating shaft 78 and engaged with the protrusion 73b of the engaging member 77 on the fixed side. The 77 may be provided with a spiral groove or a linear groove.

Further, in the above embodiment, in the spiral mechanism 20b, a linear groove 11b is formed on the rotation shaft 11a and a spiral slope 28a is formed on the wall 28. However, a cylinder surrounding the rotation shaft 11a is provided to form a cylinder. A spiral groove may be formed in the orbital piece 11 and engaged with a protrusion provided on the track piece 11.

Further, in the above embodiment, the track toy 100 traveling on the automobile toy 1 has been described, but the present invention can also be applied to toys for transporting or moving balls or other articles.

Further, in the above embodiment, the rotation shafts 11a and 78 are provided so as to extend in the vertical direction, but the orbital pieces may be moved horizontally or diagonally by being horizontally or inclined.

Further, in the above embodiment, the straight groove 78c is continuously provided at the upper end of the spiral groove 78b of the rotation shaft 78, but the straight groove may be continuously provided at the lower end. If a straight groove is provided, for example, alignment with an adjacent track piece can be reliably performed.

1 Automobile toy 2 Button 3 Picking 4 Handle 5 Grip 11 to 17 Track piece 11a Rotating shaft 20 Rotating lifting device 20a Rotating mechanism 20b Spiral mechanism 23 to 26 Gear 28 Wall 28a Slope 40 Lifting device 70 Rotating lifting device 70a Winding mechanism 70b Spiral mechanism 78 Rotating axis 100 Orbital toy

Claims (9)

Equipped with a rotating shaft to which moving parts are attached,
A first spiral engaging portion is formed on one of the fixed portion and the rotating shaft along the axial direction of the rotating shaft, and the other engages with the first engaging portion. A joint is formed,
By linearly reciprocating the axis of rotation along the axial direction, the second engaging portion is made to imitate the first engaging portion to rotate the rotating shaft, and the moving component is spirally moved. To let
A linear third engaging portion parallel to the axis is connected to at least one end of the first engaging portion.
At least one end side of the first engaging portion, the third engaging portion is made to imitate the second engaging portion so that the rotation axis is moved only linearly without rotation. A motion toy characterized in that the motion component is made to move linearly . The motion toy according to claim 1 , wherein the first engaging portion is formed on the rotating shaft, and the second engaging portion is formed on the fixed portion. The motion toy according to claim 2 , wherein the engaging portion on the side where the first engaging portion is formed is a groove, and the second engaging portion is a protrusion. A movable support that rotatably supports the rotation axis and moves in the axial direction of the rotation axis is provided, and the movable support is pulled by a string to linearly move the rotation axis in one direction from the initial position. The motion toy according to any one of claims 1 to 3 , wherein the rotation axis is returned to the initial position by a predetermined urging force. Claims 1 to claim 1 , wherein the rotating shaft is provided so as to extend in the vertical direction, and the moving component is a pedestal having a first article placing portion on which an article can be placed. The motion toy according to any one of 4 . A second article placing portion connected to the first article placing portion is provided outside the pedestal in a state where the pedestal is in either the uppermost position or the lowest position, and the second article placing portion is provided. The article is configured to be accessible from the article placing portion to the first article placing portion, and the second article placing portion is provided with a stopper that appears and disappears from the upper surface.
The stopper is
When the pedestal is in the one position, it sinks from the upper surface of the second article placing portion and allows the article to pass through.
When the pedestal leaves the one position, it protrudes from the upper surface of the second article placing portion and stops the article.
The motion toy according to claim 5 . A linear third engaging portion parallel to the axis is connected to at least one end of the first engaging portion, and the third engaging portion engages with the second engaging portion. When doing so, the axis of rotation is configured to move only linearly without rotation.
When the pedestal is in the one position, the third engaging portion engages with the second engaging portion.
On the upper surface of the pedestal, a sliding contact wall is provided outside the first article placing portion.
The sliding contact wall is
When the pedestal leaves the one position, the third engaging portion enters the first article placing portion only in the front portion while the third engaging portion engages with the second engaging portion. Lift the front part of the article by the protrusion of the stopper,
After that, the first engaging portion engages with the second engaging portion to slide into the front portion of the article and push the article back toward the second article placing portion.
The motion toy according to claim 6 . Outside the pedestal, a third article placing portion having a step from the second article placing portion is provided at a position different from the second article placing portion.
The third article placing portion is connected to the first article placing portion in a state where the pedestal is in the other position of the uppermost position or the lowest position, and the third article placing portion is connected to the first article placing portion. The motion toy according to claim 6 or 7 , wherein the article is configured to transfer to the article placing portion. The motion toy according to any one of claims 5 to 7, wherein the article is a vehicle toy, and the article placing portion constitutes a part of the track of the vehicle toy. ..

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