JPS63318978A - Simulator toy - Google Patents

Abstract

(57) [Summary] This bulletin contains application data before electronic filing, so abstract data is not recorded.

Description

[Detailed Description of the Invention] [Industrial Application Field] The present invention provides a simulator toy that allows users to enjoy the sensation of driving by operating their own vehicle, which is projected along with obstacles such as a running road and buildings. It is related to.

[Conventional technology]

Conventionally, simulator devices for toys have either been equipped with an endless film or a transparent disc displaying a desired image on the back side of a transparent screen, and the image is displayed on the screen using a light source, or a simulator that has been recorded in advance. A simulator device is known in which the image is displayed on a cathode ray tube by an electronic control system using VDP or CRTC.

[Problem that the invention seeks to solve]

In the above-mentioned conventional technologies, those using endless films or transparent disks not only have flat and simple images, but also have difficulty in perfectly matching the images with operating mechanisms such as handles and operating rods. It lacked a sense of realism.

Furthermore, although the problems of the conventional technology that display images on a cathode ray tube using an electronic control system have been solved, the device itself is large-scale and expensive, making it unsuitable as a device for toys. It was something.

[Means for solving problems]

The present invention has been made to solve the above-mentioned problems of the prior art, and a three-dimensional object model made of a transparent material with transparency is erected on the front side of the main body housing the drive mechanism, and the three-dimensional object model made of a transparent material is installed on the back side. A rotary plate made of a transparent material having permeability and protrudingly provided with obstacle protrusions at positions corresponding to the arrangement of the three-dimensional object model is provided rotatably in conjunction with the drive mechanism, and is disposed above the rotary plate. The support arm, which has a light source attached to its tip, has a branching plate projecting thereon, and the tip of the branching plate has a protruding piece shaped like a silhouette of a car that is projected as the own vehicle, and the protruding piece is attached to the rotary plate. The support arm is slidable in conjunction with a rotary knob protruding from the upper shell constituting the main body, and the support arm has a light source at the tip thereof. is configured to be movable in a direction transverse to the radius of the rotation direction of the rotary plate.

[For production]

In a simulator toy having the above-mentioned configuration requirements, a three-dimensional object model on a rotating rotary plate and the own car are projected as images on a projection surface such as a screen or a projection wall placed in front of the main body.

As the rotating plate rotates, the image of the three-dimensional object model moves in the direction of the image of the player's car on the projection surface, and the player operates the rotating knob protruding from the main body to control the image of the three-dimensional object model on the projection surface. The purpose is to move the car so that the image of the own car does not collide with the image of the three-dimensional object model.

〔Example〕

As shown in FIGS. 1 and 2, the main body 1 is formed into a substantially flat casing, and is constructed by screwing together an upper outer shell 3 and a lower outer shell 5 using suitable joining means such as screws. has been done. The front end of the main body 1 is open and there is a rotary plate 55, which will be explained in detail later.
is removable.

A lid-shaped opening/closing member 1c is pivotally attached to the front end of the upper shell 3 to facilitate attachment and detachment of the rotary plate 55. A rotary knob 48 is protruded from the center of the upper shell 3. This rotary knob 48 is used to move the own vehicle, which will be described later, and has the function of a steering wheel for operating the steering of the vehicle. Furthermore, a handle 7 protrudes from the lower surface of the lower outer shell 5, and the player supports the main body 1 by holding the handle 7 with his left hand, as shown in FIG. 1, and operates the rotary knob 48 with his right hand. It is something to do. A slot 1a is provided on the upper surface of the upper outer shell 3.

1b is bored, and a pointer 41 is fitted into the slot la so as to be slidable in the longitudinal direction of the slot 1a. This pointer 41 is used to display the score when the game is played as a driving game, and the score is displayed as a numerical value (not shown) along the slot 1a.

Further, a knob 39 protruding from the slot 1b is slidable within the slot 1b and is used to return the slide plate 34 that engages with the pointer 41.

FIG. 2 shows the main body 1 with the upper outer shell 3 removed, and a battery storage section 9 is formed on the front side of the lower outer shell 5. Batteries 11 and 11 can be stored in the battery storage part 9, and the lid body 9a is formed in the battery storage part 9 so that it can be attached to and removed from the battery storage part 9.

As shown in FIG. 6, the lower shell 5 is provided with a machine frame 6° in which a drive mechanism, which will be described later, is accommodated. A support arm 51 is disposed near a rotating plate 55 rotatably supported on the upper shell 3. (See Figure 2) A light bulb 52, which is a light source, is attached to the tip side of the support arm 5-1. (See Figure 6) A branch plate 56 is protruded from the lower surface of the middle of the support arm 51. . A projecting piece 54 in the shape of an automobile silhouette is formed at the tip of the branching plate 56. (See FIGS. 6 and 9) This protrusion 54 becomes a self-vehicle when projected onto the projection surface by the light source 52, and an obstacle protrusion 59 protruding from the back surface of the rotary plate 55.
It is provided at a position where it can be engaged with a. Furthermore, the support arm 5
The base end of 1 is attached to a slide member 49 slidably disposed on the upper surface of the machine frame 60. The slide member 49 has a guide member 53 and a guide member 53 whose both sides are erected on the machine frame 60 as shown in the second figure.
It is guided by ... and can freely slide in the direction across the main body 1. A rack 47 is carved on one side of the slide member 49, and this rack 47 meshes with the gear 43. A shaft portion of the rotary knob 4 is rotatably attached to a cylindrical body 45 having a protruding bearing portion of the gear 43. Therefore, the rotary knob 48
By rotating the slide member 49, the slide member 49 slides in the direction across the main body 1, and the light source 52 attached to the support arm 51 is located above the rotating plate 55, and the light source 52 is located above the rotating plate 55, and the slide member 49 slides in the direction across the main body 1. That is, it reciprocates on a transverse line that crosses the center of the rotary plate 55, which is rotating clockwise, in the lateral direction, and on a radius on the same side as the rotation direction (rightward direction) of the rotary plate 55, that is, on the right side. It is something.

The main switch 13 is provided so that it can be operated by protruding upward from an opening provided in the upper outer shell 3, and the lower part is connected to the machine frame 6.
It is guided by guide protrusions 17, 17 provided protrudingly from the bottom and can freely slide. The speed conversion knob 29 is connected to the upper outer shell 3.
It is provided so that it can be operated by protruding upward from an opening formed in the machine frame 6'O, and the lower part has a guide protrusion 33,
33 and can freely slide.

The rotary plate 55 is made of a transparent material, and a plurality of three-dimensional object models 59 made of a transparent material are erected in front of the rotary plate 55. (Refer to Figures 8 and 9) The three-dimensional object model 59 is a model of a building or a gas station, a car or a tree, or a large-diameter model of multiple discs with different circumferences. They can be layered in order to form a model of a mountain. Since each of the three-dimensional object models 59 is made of transparent (including colored transparent) synthetic resin, etc., the end face of this synthetic resin and the ridge line where the two faces match are different from each other. Since it is difficult for light to pass through compared to the other parts, that part is projected as the outline of the three-dimensional object model 59 on the projection plane. Further, if the three-dimensional object model 59 is formed of a synthetic resin colored with a transparent pigment as necessary, the image will be colored and projected. Also,
A slit 62... is bored in the rotary plate 55,
The slit 62 is provided so that a transparent plate displaying a desired pattern can be inserted therein. A large number of transparent plates 58 are provided on the rotary plate 15 to adjust the difficulty level of the game when operated by a skilled player. Obstacle protrusions 59a, 58a, . . . are provided on the back surface of the rotary plate 55 at positions corresponding to the three-dimensional object model and the transparent plate 58 erected on the front surface. These obstacle protrusions 59a..., 58a...
... engages with a car-shaped protrusion 54 formed at the tip of a branch plate 56 branching from the support arm 51, and when the rotary plate 55 is in operation, the rotary knob 48 that operates the support arm 51 If the operation is incorrect, the protrusion 54 will cause an obstruction to the protrusion 5.
9a and 58a, the rotation of the rotating plate 55 is prevented and stopped. At this time, the image projected on the projection surface shows the vehicle colliding with a building or the like.

A gear-shaped rack 55a is provided on the outer peripheral edge of the rotary plate 55.
This rack 55a is engraved with a gear of a drive mechanism which will be described later.

A through hole 57 is bored in the center of the rotary plate 55, and the through hole 57 can be attached to and detached from a support shaft 3a protruding from the upper shell 3. Further, an annular magnetic body 6 is attached to the periphery of the through hole 57, and this magnetic body 6 is attracted to the permanent magnet 4 disposed on the outer periphery of the spindle 3a, so that This prevents the plate 55 from easily deviating from the support shaft 3a.

Next, the drive mechanism housed in the machine frame 60 will be described with reference to FIGS. 3 and 4.

A U-shaped elastic protrusion 13c with a hollow center portion is provided on the side surface of the main switch 13 to protrude.

A protrusion (not shown) is provided on the outside of the elastic protrusion 13C, and the protrusion is attached to the machine frame 60 on the side of the main switch 13.
The stop position of the main switch 13 is determined by fitting into a concave portion 15a formed on a protrusion 15 protruding from the upper surface of the main switch 13. A projecting piece 13a protruding from the lower side of the main switch 13 is provided so as to be able to engage with the conductive contact piece 19. The conductive contact piece 19 has its base end on the main switch 13 side locked to the machine frame 60, and its free end on the distal side abuts against the bent part 21b on the base end side of the conductive contact piece 21 arranged in parallel. It is attached with elastic force applied to it. Conductive contact piece 2
An arcuate protrusion 21a is formed at the tip of the holder 1, and the arcuate protrusion 21a can be freely engaged with and disengaged from a timer mechanism, which will be described later. The conductive contact piece 23 is arranged in parallel with the conductive contact piece 21, and the bent portion at the tip can be freely engaged with and detached from the conductive contact piece 21, so that when the conductive contact piece 21 engages with the timer mechanism and is bent, They are always in contact with each other.

A protruding piece 1 protruding from the lower side of the other side of the main switch 13
An engagement slope is formed at the lower end of the gear 3b, and the engagement slope is removably connected to the upper end of the gear shaft 145 that is slidable in the axial direction. A gear 147 that is pivotally attached to a gear shaft 145 can be freely engaged and disengaged from a worm gear 143 that is pivoted to a gear shaft 139, and a worm wheel 141 that is pivoted to the same shaft 139 as the reworm gear 143 meshes with a worm gear 137 that is pivoted to a gear shaft 135. ing. Worm gear 137 and coaxial 13
A gear 133 pivotally attached to the gear shaft 71 meshes with a small gear 67 pivotally attached to the gear shaft 71. The crown gear 65 which is coaxially attached to the small gear 67 and the same shaft 71 is the motor pinion 6 of the motor 61.
It meshes with 3. A protruding piece 149 is pivotally attached to the gear shaft 145, and the tip of the protruding piece 149 is provided so as to be able to engage and detach from the arc-shaped protrusion 21a formed at the tip of the electrically conductive contact piece 21. In addition, a push spring 2 is attached to the gear shaft 145.
7 is wound around the gear shaft 145, and the push spring 27 pushes the gear shaft 145 upward. A pin 147 is provided on the bottom surface of the gear 147.
A protrudes from the pin 147a, and one end of the tension spring 25 is locked to the pin 147a.

A timer mechanism is constituted by a plurality of transmission gears from the crown gear 65 to the gear 147, the protruding piece 149, and the conductive contact piece 21, and the time for one game is set. That is, the main switch 1313a connects the motor 61 and the power source in order to press the bent bulge of the electrically conductive contact piece 19 and separate the free end of the electrically conductive contact piece 19 from the bent part 21b of the electrically conductive contact piece 21. The circuit is opened and the motor 61 is stopped. Then, the engagement slope formed at the lower end of the protruding piece 13b of the main switch 13 engages with the upper end of the gear shaft 145, and the gear shaft 145 is moved downward against the elastic force of the pressing spring 27. . At this time, the gear 147 is in contact with the worm gear 143, and the gear shaft 145 is completely free and rotatable. Therefore, the gear shaft 14
5 is rotated by the tension spring 25, and the tip of the protruding piece 149 is stopped at a position near the tip side of the arcuate protruding piece 21a. At this time, the conductive contact pieces 21 and 23 are in contact with each other.

When the protrusion 13a is turned to the “ON” state, the protrusion 13a
The conductive contact piece 19 is spaced apart from the bent bulge of the contact piece 19 .
The free end on the distal side comes into contact with the bent portion 21b of the conductive contact piece 21b, the circuit connecting the motor 61 and the power source is closed, and the motor 61 is driven.

As the motor 61 is driven, the gear 147 is also wound around the tension spring 25 in an extended state a around a boss (not shown) located below the gear 147 and pivoted to the gear shaft 145. . When the gear shaft 145 rotates substantially, the tip of the protruding piece 149 engages with the proximal end of the arc-shaped protrusion 21a, bending the electrically conductive contact piece 21, and the electrically conductive contact piece 21.23.
is separated, the circuit for supplying power to the motor 61 is opened, and the motor 61 is stopped. And again motor 6
1, the main switch 13 is slid in the direction of arrow F in the warning diagram. By sliding the main switch 13 in the F direction, the bent portions 21b of the conductive contact piece 19 and the conductive contact piece 21 are separated, resulting in an "OF" state. Further, the gear shaft 145 engages with the engagement slope of the protruding piece 13b, moves downward in the axial direction, and the gear 147 separates from the worm gear 143. Therefore, in order for the gear shaft 145 to be in a free and rotatable state, a boss (not shown) is attached to the lower side of the gear 147.
The arcuate protrusion 21a of the electrically conductive contact piece 21 rotates together with the gear shaft 147 due to the tensile force of the tension spring 25 wound around the
It moves to a position near the tip side of and stops. The stopping position of the gear shaft 147 is determined by the direction in which the pulling spring 25 is pulled. Further, in this state, the conductive contact pieces 21 and 23 are in contact with each other. Main switch 1
By sliding the main switch 13 in the direction of the arrow F shown in the third figure, the timer mechanism is reset as described above. After completing the above reset, move the main switch 13 in the direction of the arrow R shown in the third figure. When it slides into the "ON" state, the motor 61 will be driven again.

Next, a driving mechanism for the rotary plate 55 driven by the motor 61 will be explained.

The motor pinion 63 meshes with a crown gear 65 mounted on the upper part of the gear shaft 71. The gear shaft 71, the rotating body 69, and the rotary gears 79.83 are used to switch the transmission of driving force, and this switching mechanism was disclosed in Japanese Patent Publication No. 56-33117, which was invented by an author. It has basically the same technical idea as "Gear Switching Mechanism".

That is, the motor pinion 63 is meshed with a crown gear 65 that is rotatably attached to the upper part of a gear shaft 71, and a drum-shaped rotating body 69 is loosely fitted in the middle part of the gear shaft 71 so as to be freely rotatable. A gear 73.75 is provided at the lower end of the gear shaft 71.
is attached to the shaft. Gear shafts 77 and 81 are erected on the lower end surface of the rotating body 69, and a rotating gear 79 that meshes with the gear 75 is loosely fitted into the gear shaft 77 so as to be freely rotatable. A rotary gear 83 that meshes with the gear 73 is loosely fitted into the gear 81 so as to be freely rotatable. On the outer circumferential surface of the rotating body 69, there are four engaging protrusions 69a arranged at predetermined angular intervals in the circumferential direction and at predetermined intervals in the axial direction.

69b, 69c, and 69d are provided in a protruding manner. A rotating claw piece 185 is disposed near the rotating body 69.

As shown in FIG. 4, the rotating claw piece 185 is pivoted on a support shaft 181 that is slidably supported in the axial direction with respect to the machine frame 60, and the base end side is attached to a support that is erected on the rotating lever 161. It is loosely fitted onto the shaft and supported so as to be slidable in the axial direction. And the spindle 1
A push spring 187 is wound around 81, and the rotating claw piece 1
85 is pushed upward together with the support shaft 181 by the elastic force of the push spring 187. A locking pawl 189 is formed at the tip of the rotating pawl piece 185, and the locking pawl 189 is connected to the engaging protrusions 69a, 69b, and
It is arranged so that it can be engaged with and detached from 9c.

The rotating lever 161 is a support shaft 181 fitted into the bearing hole 179.
A tension spring 177 is tensioned between a locking piece 173 protruding from the proximal end and a locking piece 175 protruding from the bottom of the machine frame 60. 161 is rotated clockwise as shown in FIGS. 5 and 6 by a tension spring 177. In addition, the rotation lever 161
An upright piece 163 is provided upright on the tip side of the upright piece 1.
A locking pawl 165 is formed at the tip of 63.

Furthermore, a projecting piece 169 is provided on the base end side of the rotating lever 161, and a locking pawl 17 formed at the tip of the projecting piece 169
1 is a retaining protrusion 69d protruding from the outer peripheral surface of the rotating body 69;
It is possible to connect and disconnect.

Above the rotation lever 161 is a rod-shaped slide member 15.
1 is arranged. (See Figure 7) Slide member 15
A push spring 159 is elastically loaded at the base end of the slide member 151, and the slide member 151 is biased in the rightward direction as shown in FIG. An engaging piece 153 is provided protruding from the tip side of the slide member 151, and the retaining piece 153 is connected to a first engaging step portion 29a and a first engaging step portion 29a formed on the side surface of a protruding piece 29c protruding from the speed conversion knob 29. It is provided so as to be freely engageable and detachable from the second engagement step portion 29b. A protrusion 155 is provided in the intermediate portion of the slide member 151.
An engagement slope 157 is formed at the rear end of the connector 5 . The engagement slope 157 formed on this protrusion '155 has a support shaft 18.
1 is in contact with the upper end.

An elastic projecting piece 29a is provided on the side of the speed conversion knob 29 and has elasticity by cutting out the center part. (See FIG. 7) A protrusion 29b is provided at the center of the elastic protrusion 29a, and the protrusion 29b is connected to a protrusion 31 that is provided on the side of the speed conversion knob 29 and protrudes from the upper surface of the machine frame 60. The stop position of the speed conversion knob 29 is determined by fitting into a recessed portion 31a formed therein.

When the motor 61 is driven, a large-diameter gear 73 and a small-diameter gear 75 that are attached to the lower end of a gear shaft 71 rotate. gear 7
3 transmits the rotational force to the rotational gear 83, the gear 75 transmits the rotational force to the rotational gear 79, and the rotational gear 83.79
The gear 73 is connected to the rotating body 69 via the gear shaft 81.77.
．． The rotary gears 83 and 79 are rotatably supported on the gear shafts 81 and 77 and rotated along with the rotation of the rotor 69. A gear 85 is disposed in contact with the rotation trajectory of the rotation gears 83 and 79 to transmit driving force to the rotary plate 55.

When the speed conversion knob 29 is pulled toward the front side in FIG. 2, the protrusion 29c integrally formed with the speed conversion knob 29 shown in FIG. The provided engagement piece 153 is connected to the second engagement step portion 30b.
It will be out of place. In this state, the slide member 151 is moved by the push spring 159 to the limit position in the rightward direction shown in FIG. The support shaft 181, whose upper end is in contact with the engagement slope 157 of the protrusion 155, has reached its upper limit of movement. At this time, the locking claw 1 of the rotating claw piece 185
Reference numeral 89 denotes a retaining protrusion 69 protruding from the outer peripheral surface of the rotating body 69.
It will engage with a. The rotating body 69, whose rotational operation is prevented by the locking pawl 189 engaged with the locking protrusion 69a, is supported on the gear shaft 71 and rotates idly, and the rotating gears 83 and 79 are rotating, but the other parts including the gear 85 are rotated. The gear will not mesh with any of the gears on the driven side. In this state, the rotating plate 5
5 and a "neutral state" in which the counter mechanism described later stops and the timer mechanism operates.

When the speed conversion knob 29 is pushed out in the rightward direction as shown in FIG.
3 engages with the second engagement step 30b, and the support shaft 181, whose upper end abuts against the engagement slope 157 formed on the protrusion 155, moves down one step. At this time, the locking claw 189 of the rotary claw piece 185 disengages from the engagement protrusion 69a of the rotating body 69 and descends to the position where it engages with the engagement protrusion 69b. Since a rotational force in a fixed direction is always applied to the rotating body 69, the engagement protrusion 69b rotates by a predetermined angle and engages with the locking pawl 189, and the rotation of the rotating body 69 is prevented. At this time, the rotating gear 79 that meshes with the small diameter gear 75 and rotates is connected to the rotating plate 55.
The rotary plate 55 can be rotated at a low speed by meshing with the gear 85 that transmits driving force to the rotary plate 55 .

When the speed conversion knob 29 is moved to the rightmost position shown in FIG. The support shaft 181 that has come into contact with this is lowered to the lowest position. At this time, the locking pawl 189 of the rotating pawl piece 185 releases the engagement with the engagement protrusion 69b of the rotating body 69, and is always applied to the zero-rotating body 69, which descends to the position where it engages with the engaging protrusion 69c. The engaging protrusion 69C is rotated by a predetermined angle due to the rotational force, and is engaged with the locking pawl 189, so that rotation of the rotating body 69 is prevented. A rotating gear 83 that meshes with the large-diameter gear 73 and rotates.
meshes with the gear 85 and can rotate the rotating plate 55 at high speed. (See FIG. 5) The driven gear 85 that transmits the driving force to the rotating plate 55 has its outer peripheral edge connected to the rotating gear 79.
It is arranged in contact with the rotation locus of 83. A small gear 89 is attached to a gear shaft 87 on which a gear 85 is attached, and the small gear 89 meshes with a gear 93 loosely fitted to a gear shaft 91. A gear 95 and a clutch member 97, which are integrally formed with the gear 93, are loosely fitted and supported on the gear shaft 91.
It is slidable in the axial direction of the gear shaft 91. A push spring 127 is wound around the lower part of the gear shaft 91, and the push spring 127 pushes the gear 93 upward. Radial engagement teeth are carved on the upper end of the cylindrical clutch member 97, and cough engagement teeth are carved on the lower end of the gear 99 which is located above the clutch member 97 and is pivotally attached to the gear shaft 91. It meshes with the engaging teeth that are also carved radially. The gear 99 rotates the rotary plate 55 by meshing with a rack 55a formed on the outer peripheral edge of the rotary body 55, which is fitted onto a support shaft 3a protruding from the upper shell 3.

Next, a counter mechanism for displaying scores when the present invention is implemented as a game will be explained.

The gear 95 meshes with a gear 115 that is rotatably mounted on a gear shaft 107 . A cylindrical clutch member 117 formed integrally with the gear 115 is pivotally attached to the gear shaft 107, and engagement teeth are radially carved on the upper end surface of the clutch member 117. Above the clutch member 117, a gear 113 whose lower end face is radially carved with engaging teeth that engage with the engaging teeth of the clutch member 117 is loosely fitted onto the gear shaft 107 and slides in the axial direction of the gear shaft 107. Bearing possible.

A push spring 111 is wound above the gear shaft 107, and the upper end of the push spring 111 comes into contact with a collar 109 that is pivoted on the gear shaft 107, and the lower end comes into contact with the upper end surface of the gear 113. The push spring 111 presses the gear 113 against the clutch member 117. A rack 35 engraved on a slide plate 34 slidably disposed on the upper surface of the machine frame 60 meshes with the gear 113 . A projecting piece 37 having an angular cross section is provided on the upper surface of the slide plate 34, and a knob 39 is provided on the side surface thereof. When the rotary plate 55 rotates normally and the game is progressing, the protruding piece 37 protruding from the slide plate 34 meshes with the gear 113 whose rotational force is transmitted to the gear 95, so that the slide plate 34 moves to the third position. The pointer 4 slides in the rightward direction shown and fits into the slot 1b of the upper outer shell 3.
1 to move the pointer 41 along the slot 1b. Scores are displayed as numerical values (not shown) on the side of the slot 1b, and the scores obtained in one game are displayed. The knob 39 is for returning the slide plate 34, and its upper end protrudes upward from the slot 1a of the upper shell 3.

At the end of one game, when the knob 39 is moved in the leftward direction as shown in the third figure, the gear 113 meshing with the rack 35 passes over the engagement teeth of the clutch member 117 and presses the push spring 111.
The slide plate 34 moves upward and rotates against the
will return. At this time, the pointer 41 is left at the moved position within the slot lb, and the player who will play the next game will play the game with the goal of scoring the points displayed by the moved pointer 41.

The pointer 41 is simply fitted into the slot 1b, and can be slid by hand.

Next, the protrusion 54 projected as the own vehicle engages with the obstacle protrusions 59a and 58a protruding from the back surface of the rotary plate 55, and
The drive mechanism when a crash state occurs on the projection plane will be explained.

A gear 93 is loosely fitted to a gear shaft 91 on which a gear 99 that transmits driving force to the rotary plate 55 is attached, and a support shaft 121 is supported on a bearing member 123 provided on a machine frame 60 so that the gear 93 can swing freely. A swing lever 119 is provided. A cylindrical member 125 projects from the upper surface of the intermediate portion of the swing lever 119, and the upper end of the cylindrical member is in contact with the lower side surface of the gear 93. Also,
A push spring 2129 is loaded between the lower surface of the intermediate portion of the swing lever 119 and the bottom of the machine frame 60, and the push spring 12
9 pushes the tip side of the swing lever 119 upward. Further, a locking pawl 131 is provided protruding from the tip of the swing lever 119, and the locking pawl 131 is connected to the rotary lever 161.
It is provided so that it can be engaged with and detached from a locking piece 167 protruding from the base end.

When the rotary plate 55 is rotated by being transmitted with the driving force of the motor 61, the protruding piece 54 formed at the tip of the branch plate 56 branched from the support arm 51 causes the rotary plate 55 to rotate.
When the rotation plate 55 is prevented from rotating by engaging with the obstruction protrusions 59a and 58a protruding from the back surface of the gear shaft 91, the clutch member 97 that is loosely fitted on the gear shaft 91 rides on the engagement teeth of the gear 99, and the gear At 95 degrees 93, the gear shaft 91 moves downward in the axial direction of the gear shaft 91 against the elastic force of the push spring 127. When the gear 93 moves downward, the lower side surface of the gear 93 moves to the cylindrical member 1 of the swing lever 119.
25 from above, the swinging lever 119 moves downward, and the locking claw 131 at the tip and the locking piece 167 of the rotating lever 161 are disengaged, and the rotating lever 161 pivots around the support shaft 181. 0-rotation lever 1 that rotates clockwise as shown in Figure 6
Reference numeral 61 stops when the side surface contacts the stopper 217, and at this time, the locking claw 189 of the rotating claw piece 185 is disengaged from the retaining protrusion 69b (or 69C) protruding from the rotating body 69. The state will be as follows. At approximately the same time, the locking claw 171 formed at the tip of the protruding piece 169 provided on the rotary lever 161 moves to the position where it engages with the locking protrusion 69d provided on the rotating body 69. Engagement protrusion 6 at 171
9d engages to prevent the rotation of the rotating body 69, the rotating gear 79 (or 83) is separated from the gear 85, and the rotating plate 55 stops. 79 meshes with gear 191. (See Figure 6) A drive mechanism including a gear 191 operates a sounding mechanism that expresses a crash state in which the own vehicle collides with an obstacle, and also has a mechanism that automatically returns the crash state to a normal state after a predetermined period of time has elapsed. We are prepared.

A gear 191 pivotally attached to a gear shaft 193 is disposed in contact with the rotation locus of the rotating gear 79, and a small gear 195 is attached coaxially thereto. The small gear 195 meshes with a gear 197 that is rotatably mounted on a gear shaft 201, and a rotating plate 199 is coaxially mounted on the upper surface of the gear 197. The rotary plate 199 has a protrusion protruding from its outer peripheral edge with a rack carved therein, and has a structure in which the tip of the elastic piece 200 engages with the rack of the protrusion to produce a click sound. The small gear 203 that is pivoted on the upper part of the gear shaft 201 is connected to the gear 211 that is pivoted on the gear shaft 207.
It meshes with. A cam plate 2 is coaxially mounted on the top surface of the gear 211.
09 is attached to the shaft. A bottle 205 is erected on the cam plate 209, and an elastic piece 213 that engages with a cam protrusion of the cam plate 209 is disposed near the cam plate 209.

Therefore, the rotary plate 199, which is rotated by the driving force transmitted from the rotary gear 79, vibrates the elastic piece 200 and generates a click sound, and when the cam plate 209 rotates approximately one time in the clockwise direction shown in FIG. Upright piece 1 provided on rotating lever 161
The rotating lever 16 engages with the locking pawl 165 formed in the
1 in the counterclockwise direction shown in FIG. Rotating lever 1 rotated by locking pawl 165 pressed against bin 205
The locking piece 167 of 61 engages with the locking pawl 131 formed at the tip of the swing lever 119, which has already been moved upward to a position where it can be held by the push spring 129. At this time, the locking pawl 171 formed on the protruding piece 169 releases the engagement with the engagement protrusion 69d of the rotating body 69.
9 rotates, and the locking protrusion 69b (or 69c) engages the locking claw 189 again with the locking piece 16 of the zero-turn lever 161
7 and the locking pawl 131 of the swing lever 119 are engaged, the bottle 205 is in a state of pushing the locking pawl 165 from behind, and at this time, the bent portion 215 of the elastic piece 213 is pressed against the cam plate 209. Although it is located just in front of the cam protrusion leading to the straight part 210, the gear 191 separated from the rotary gear 79 rotates slightly due to inertia, so that the bent part 215 forms the straight part 2 of the cam protrusion.
10, and engages with the straight part, and the elastic piece 2
13 forcibly rotates the cam plate 209 and moves the bin 205 forward of the locking claw 131, completing the reset of the crush mechanism.

The rotating gear 79 (or 83) meshes with the gear 85 to transmit driving force to the rotating plate 55, allowing the game to continue.

〔effect〕

An image projected onto a projection surface by a three-dimensional object model placed upright on a rotary plate made of a transparent material that rotates in conjunction with a drive mechanism installed inside the main body, and an image of your own car. The rotary knob is operated so as not to collide with the image of the three-dimensional object model, and the three-dimensional object model with i3 transient properties is directly projected on the rotating plate, and the image is rich in three-dimensional effect. This makes it possible to provide an excellent simulator toy.

[Brief explanation of drawings]

The drawings show the implementation of the present invention, and FIG. 1 is an external perspective view of the main body, FIG. 2 is a perspective view of the main body with the upper outer shell removed, and FIG. 3 is a main part of the drive mechanism. FIG. 4 is a longitudinal sectional view showing the main parts of the drive mechanism, and FIG.
6 and 6 are plan views showing the main parts of the drive mechanism, FIG. 7 is a perspective view showing the operating mechanism of the speed conversion knob, FIG. 8 is a plan view of the rotary plate, and FIG. 9 is a sectional view of the rotary plate. It is. 1...Main body, 13...Main switch, 29...
Speed conversion knob, 51... Support arm, 52... Light bulb, 54... Protruding piece, 55... Rotating plate, 56... Branch plate, 59... Three-dimensional object model, 59a... obstacle protrusion,
60... Machine frame, 61... Motor. Agent Patent Attorney Kiyoshi Mizuno Fig. 7 29c Projection piece 151 Slide member 161 Drunk lever 185 Turning claw piece Fig. 8 Fig. 9

Claims (1)

[Claims] The main body housing the drive mechanism has a three-dimensional object model made of a transparent material with transparency on the front side, and a transparent object model on the back side with obstructing protrusions at positions corresponding to the arrangement of the three-dimensional object model. A rotary plate made of a transparent material is provided to be freely rotatable in conjunction with the drive mechanism, and a support arm having a light source attached to its tip disposed above the rotary plate has a branch plate protruding from the support arm. A projecting piece in the shape of a silhouette of a car projected as the own vehicle is formed at the tip of the branching plate, and the projecting piece is provided so as to be removable from an obstacle protrusion protruding from the back surface of the rotary plate, and the supporting arm is The support arm is slidable in conjunction with a rotary knob protruding from the upper outer shell constituting the main body, and the light source at the tip of the support arm is movable in a direction transverse to a radius on the rotation direction side of the rotary plate. A simulator toy characterized by its composition.