CA1251644A - Integrating toy - Google Patents

Abstract

ABSTRACT OF THE DISCLOSURE
The invention provides a series of toys each of which can be reconfigured between at least two different states, one of which states is, for example, a construction vehicle such as a crane or a bulldozer, while the other of which states is a humanoid robot. Each toy is also able at an intermediate state of reconfiguration to accept another element which permits it to be configured differently from the said first and second states. A number of different toys according to the invention can be connected together to form yet another toy configuration.

Description

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INTEGRATING TOY

BACKGROUND OF THE INVENTION

This invention relates to an integrating toy which is formed of a plurality of integrating elements.

An integrating toy is composed in general of a plurality of integrating elements associated in an integral unit which is entirely different from the respective integrating elements. A conventional integrating toy has no alteration of the integrating elements by themselves, and has a drawback that the toy is readily tired of within a short time of playing.

SUMMARY OF THE INVENTION

An object of the present invention is to provide an improved integrating toy which can eliminate the above-mentioned drawbacks and disadvantages and which can be played with in a variety of configurations of the integrating elements, thereby increasing the types oE play possible with the elements.

Accordingly, the present invention provides an integrating toy comprising a plurality of integxating elements having a plurality of movable elements for altering from a first state to a second state or to a third state, the integrating elements being capable of being integrated with each other when in a third state to form a fourth state~

The invention will become more fully apparent and more readily understandable from the following description and the appended claims when read in conjunction with the accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

Figs. l(a~ to l(g) are explanatory views showing various states of a first integrating element in a variety of 6~4 positions according to an embodiment of the present invention;
Figs. 2(a) to 2(f), 3(a) to 3(e), 4(a) to 4(e), 5(a~ to 5(f), and 6~a) to 6(e) are ex~lanatory views similar to those of Figs. l(a) to l(g) but showing second, third, fourth, fifth, and sixth integrating elements in variety of positions; and Fig. 7 is an explanatory view showing how the six integrating elements of Figs. 1 to 6 can be associated one with another to form an integral structure.

DESCRIPTION_OF THE PREFERRED EMBODIMENTS

As shown in the accompanying drawings the integrating toy of the invention is composed of a plurality of integrating elements. The respective integrating elements will be described with reference to Figs. 1 to 6.

In Fig. 1, reference character A1 designates an integrating element which in a first state represents a truck crane. Movable elements can be moved to alter the element to provide a representation of a robot. In addition the element can be transformed by moving the movable elements thereto to provide one part of a larger robotic figure. As shown in Fig.
l(a), the integrating element toy Al in truck crane form has a front base which has a pair of holding legs 10 and a pair of front bodies 11, and a rear base 2 which has a rear body 12 on its top surface and wheel retaining members 13 on each side.
The front base 1 is formed on its back surface to represent the legs of a robot and on one side with an engaging groove 14 as shown in Fig. l(e). The bodies 11 are rotatable about the ends of the legs 10. The rear base 2 is formed on its back surface to represent the body of the robot. The rear body 12 carries on its top surface a crane-like member 15 and a holding projection 16 as shown in Fig. l(d). Wheel retaining members 13 at each side of the base 2 are formed to be pulled outwardly therefrom.
A robot head 17 is telescopically provided at the rear end of the base 2 . The front base 1 and the rear base 2 are coupled through a connecting link 18, and can be connected or swivelled through the link 18.

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To change the integrating element Al from the truck crane into a robot (its second state), as shown in Figs. l(b) and l~c), the front bodies ll of the base 1 are half rotated through a revolution to form feet, and the wheel retaining 5 members 13 of the base 2 and the robot head 17 pulled out to form arms and a head, respectively. When these movable elements are returned to the original position the element Al again forms a truck crane.

The integrating element Al can also be altered from the truck crane form to a third state as shown in Figs. l(d) to l(g), if the front and rear bases 1 and 2 are first separated by pulling them apart as shown in Fig9 l(d), and then one part is rotated through 90 to the position shown in Fig. l(e). The projection 16 on the rear base 2 can then be rotated so that it projects outwardly then an additional member 70 comprising a robot head is affixed as shown in Fig. l(f) and l(g). This additional member 70 has a robot head 72 provided on the top of a U-shaped insert 71, having an engaging hole 73 and a holding projection 74 on its underside as shown in Fig. l(g). When the insert 71 is affixed at the rear of the integrating element Al, the element Al and the additional member 70 become coupled together to form a head and shoulder portions of a larger robot shown in Fig. 7. The holding projection 16 and the engaging groove 14 extend one on each side of the transformed element Al, and the hole 73 and the projection 74 are both on the lower side of the head and shoulder portions.

Second integrating element A2, as shown in Figs. 2(a) to 2(f), in a first state represents a power shovel. Movable elements can be moved to convert the element to a second robot state. Integrating element A2 has arm-like members 21 and 21 telescopically on each side of a truck base 3 having a power shovel member 20, an engaging projection 22 formed on the upper surface of one end, a pair of crawler members 23 rotatably , :' ~5~6'~
. 4 mounted on each side, an engaging arm 24 pivotally provided on the underside between crawl~r members 23 and a robot head membe~ ~
25 provided at the rear end. Ends 26 of the crawler members 23 are rotatably arranged to be rotated relative to the remainder of the members 23.

To convert the integrating element A2 into a robot state, as shown in Figs. 2(a) to 2(c), the crawler members ~3 are rotated by half a revolution relative to the base 3 to form legs. Then, the arm-like members 21 are telescopically projected to form arms, and the head-like member 25 is pulled out. Portions 26 and the ends of members 23 are rotated to form feet. Reversal of these moves returns the element to the power shovel form.

The integrating element A2 can also be altered from the power shovel to a third state, as shown in Figs. 2(d) to 2(f).
The engaging projection 22 of the base 3 can then be engaged with an engaging hole 81 formed at the base end of an auxillary arm member 80, and the engaging arm 24 erected and laterally projected. When the integrating element A2 in its third state is coupled to the arm member 80, one robot arm for the larger robot of Fig. 7 is produced.

Integrating element A3, as shown in Figs. 3(a) to 3(e), in a first state represents a bulldozer. Movable elements can be moved to convert the integrating element A3 into a robot state. Integrating element A3 has a bucket member 30, two crawler members 31 rotatably mounted one on each side of base 4, a pair of upper body cover members 32 pivotally mounted on the upper surface of base 4, a robot head member 33 telescopically mounted within base 4 and a rotatably mounted roof member 34.
The cover members 32 each comprise three joint members 35, 36, 37 coupled so that first and second joint members 35 and 36 are relatively rotatably on a common axis and the second and third joint members 36 and 37 are pivotable relative to each other.

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The ends of the crawler members 31(a) are telescopically mounted on the remainder of the members 31 and when pulled can be rotated through 90 relative to the remainder of member 31. An engaging projection 38 is formed at the rear end of the base 4, and a boss 39 having an axial bore is formed at the center of base 4.

To alter the integrating element A3 into a robot state, as shown in Figs 3(b) and 3(c), the head member 33 is pulled out from the base 4, the roof member 34 is raised, the cover members 32 and 32 are laterally rotated and the second joint member 36 is rotated with respect to the first joint member 35, and the third joint member 37 is bent to form the arm of the robot. Them the bucket member 30 is raised and the bucket 30a is turned towards the surface of the base 4 to form a breast.
Further, a pair of crawler members 31 are each rotated through a half revolution and the ends 31a and 31a are pulled out and turned at right angles to form legs and feet. When these movable elements are moved reversely to the above, the integrating element A3 can be returned to the bulldozer state.

The integrating element A3 can also be altered from the bulldozer state to a third state, as shown in Figs. 3(d) and 3(e) in which the engaging projection 38 of the base 4 is engaged with the hole 81 at the end of an auxilliary arm member 80 to form another arm for the larger robot of Fig.7 and the engaging hole of the boss 39 is laterally opened.

Integrating element A4 as shown in Figs. 4(a) to 4(e) provides in a first state a shovel dozer. When the movable elements are moved, the shovel dozer state can be altered into a robot state. The integrating element A4 has, as shown, a shovel member 40, a pair of holding legs 42 and 42 backwardly extending from a front body 41 carrying the rotatable shovel member 40, a rear body 43 rotatably carrying wheels rotatably mounted on the legs 42 and laterally split into right and left halves wheel retaining members 44 on each side carrying front wheels at each side of the body 41, and a robot head-like member 45 mounted telescopically within the front body 41.

The integrating element A4 thus constructred can be altered into a robot state, as shown in Figs. 4(b) and 4(c).
The rear bodies 43 are turned through a half a revolution with respect to the legs 42 to form feet and the head-like member 45 at the end of the front body 41 is pulled out. The front body 41 is formed on its back side surface to simulate a robot body, and the wheel retaining members 44 are formed as arms. When these members are moved reversely to the abover the integrating element A4 can be again returned to the shovel dozer state.

The integrating element A4 can also be altered from the first state to a third state as shown in Figs. 4(d) and 4(e), if the wheel retaining members 44 and 44 are rotated and projected forwardly, the shovel member 40 is raised and the members 44 moved downwardly. In this manner, one robot leg of the larger robot form of Fig~ 7 is constructed.

Integrating element AS, as shown in Figs. 5(a) to 5(f), in a first state represents a concrete mixer truck. When the movable elments are moved, the concrete mixer truck can be altered into a robot. The integrating element A5 has, as shown, a rear body member 50, a pair of holding legs 51 and 51 provided at one end of the rear body member 50, wheel retaining members 52 carrying wheels pivotally mounted on both sides of the rear body member 50 a front body retaining member 53 slidably mounted on the legs 51 and a front body member 54 pivotally mounted with respect to the front body retaining member 53.

When the integrating element A5 thus constructed is altered into the robot state, as shown in FigsO 5(b), 5(c) and 5(d) the front body retaining member 53 is slid away from rear .

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body member 50 along legs and front body member 54 is rotated through 180 with respect to the retaining member 53. In this manner, a robot state is constructed with the rear body member 50 as upper body, the wheel retaining members 52 as arms, the holding legs 51 as legs, and the front body member 54 as feet.
When these move~ents are reversed the integrating element A5 may be returned to the concrete mixer truck state.

The integrating element A5 can also be altered from the concrete mixer truck state to a third state, as shown in Figs.
5(b), 5(e) and 5(f). The front body retaining member 53 is slid to the ends of the legs 51, and turned at 90 . Thus, the other robot leg of the larger robot of Fig. 7 is constructed.

Finally, an integrating element A6, as shown in Figs.
6(a) to 6(e), in a first state represents a dump truck state.
When the movable elements are moved, the dump truck can be altered into a robot. In the dump truck state, the integrating element A6 has, as shown, a front body member 60 and a rear body member 61 rotatable perpendicularly to each other. A front body portion 60a is formed on the upper surface of the front body member 60, and a robot head-like member 62 is tiltably formed.
A roof member 63 is rotatably mounted on the upper surface of the front body member 60. Similarly, wheel retaining members 64 carrying wheels are mounted on both sides of the front body member. The rear body member 61 has a pair of holding legs 65 pivoted to the front body 60 and a longitudinally split load carrier 66 pivoted at the ends of the legs 65. A holding projection 67 and an engaging hole 68 are formed in parallel on the upper surface of the body member 60, and the projection 67 and the hole 68 are disposed ~nderneath the roof member 63.
Further, engaging holes 69 are formed on the front and lower surfaces of the front body member 60, and an engaging space S is is formed at the rear end of the rear body member 61.

When the integrating element A6 thus constructred is ....

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altered to the robot state, as shown in Figs. 6(b), 6(c) and 6(d), the front body member 60 is rotated at right angles to the rear body member 61, and the head-like member 62 is erected to form a robot upper body. Then, load carrier 66 is rotated S through 180 with respect to the legs 65 of the rear body member 61 to form legs 65. The wheel retaining members 64 are constructed as the arms of the robot. When these movements are reversed, the integrating element A6 is returned to the dump truck state.

The integrating element A6 is then altered from the first state to a third state, as shown in Figs. 6(b) and 6(e).
The front and rear body members 60 and 61 are rotated through 90, decorative members 85 which represent the body front and waist of the larger robot are engaged with the engaging holes 69 on the front and lower surfaces of the front body 60a, and another waist coupling member 90 is mounted on the lower part of the rear body member 61.

The waist coupling member 90 has an engaging projection 91 at its upper center and engaging portions 92 and 93 on each lower side in such a manner that the projection 91 can be engaged with the space S formed at the lower end of the rear body member 61. When the decorative members 85 and waist coupling member 90 are engaged with varous engaging holes 69 and space S of the integrating element A6, the element is held firmly together.

The integrating elements Al to A6 thus constructed can be used when their third state to form a larger robot, as shown in Fig 7, as follows:- The end of the engaging arm 24 of integrating element A2 is engaged with the groove 14 formed at one side of the integrating element Al, and the projection 16 formed at the other side of the integrating element A1 is engaged within the hole formed at the boss 39 of the integrating element A3. Then, the engaging hole 68 and the holding ~5~

g _ projection 67 formed on the upper surface of the integrating element A6 are respectively engaged with the holding projection 74 and the engaging hole 73 formed on the lower portion of the head-like member 70 mounted on the integrating element Al, s thereby coupling the integrating elements Al and A6. Next, the engaging holes 92, 93 on the lower sides of the waist coupling member 90 mounted on the integrating element A6 are engaged with the rear ends of the integrating elements A4 and A5. Thus, the integrating toys Al to A6 are combined, thereby altering them into a large-sized robot state of entirely different appearance from the construction toy states or the robot states of the elements.

In the embodiments described above, the first states of the integrating toys are civil engineering trucks, and the second states are robots, in the third states the elements are components of a larger robot body, and in the fourth state the elements are combined to form a large-sized robot~ However, the present invention is not limited to the particular embodiments, and the first, second, third, and fourth states can be arbitrarily selected.

As described above, the integrating toy of the invention is composed of a plurality of integrating elements, which have a plurality of movable elements to be altered from the first state to the second state and further to the third state, and integrated with each other in the third states, and an integral modification is formed in the fourth state.
Therefore, the integrating toy of the invention can give pleasure in the alteration from the first states to the second states, or to the third states and in combining the third states to form the fourth state. Particularly, when the toy is altered to the fourth state the integrated toy is of entirely different scale from the first and second states. since the toy.s of the invention can also be played with in the first or second states as a plurality of toys or in combination of the first and second states, the toy of the invention gives a large variety of play possibilities thereby remarkably increasing the range of the conventional integrating toy.

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Claims (8)

THE EMBODIMENTS OF THE INVENTION IN WHICH AN EXCLUSIVE PROPERTY
OR PRIVILEGE IS CLAIMED ARE DEFINED AS FOLLOWS:

1. An integrating toy comprising: a plurality of integrating elements having a plurality of movable elements for altering from a first state to a second state or to a third state, said integrating elements being capable of being integrated with each other when in the third state to form a fourth state.

2. An integrating toy according to claim 1, also including additional elements for use in locking the integrating elements together in the fourth state.

3. An integrating toy according to claim 1, wherein said first state is a truck crane state, and said movable elements comprise a front base which has a pair of holding legs and a pair of front bodies, and a rear base which has a rear body on the top face and wheel retaining members at both sides, said front base is formed on the back surface with movable elements to form legs of a robot and on one side with an engaging groove, said front bodies are rotatably provided at the ends of the legs, said rear base is formed on its back surface with the representation of the body of a robot, said rear body is provided on its top surface face with a crane-like member and a holding projection, said wheel retaining members at both sides of the base are formed to be pulled outwardly, a robot head is telescopically provided at the rear end of the rear base and the front base and the rear base are coupled through a connecting link, and can be pushed together or slid apart through the link.

4. An integrating toy according to claim 1, or claim 2, wherein said first state is a power shovel state, and said movable elements comprise arm-like members telescopically at both sides of a truck body-like base having a power shovel-like member; an engaging projection being formed on the top of one end, a pair of crawler-like members rotatably provided at both sides, an engaging arm tiltably provided at the under side, and a robot head-like member provided at the other end, the crawler-like members being formed such that the ends at the opposite end to the point of rotation are rotatable relative to the rest of the members.

5. An integreting toy according to claim 1, or claim 2, wherein said first state is a bulldozer state, and said movable elements comprise a bucket member and crawler members rotatably provided at one side of a base, a pair of upper body cover members laterally pivotably secured to the upper surface of the other side of the base, a telescopic robot head-like member and a rotatable roof member, the cover members being respecitively composed of three joint members in such a manner that the first and second joint members are rotatable about the same axis and the second and third joint members are bendable relative to each other, the ends of the crawler member are telescopically mounted on the rest of the crawler members and when pulled out can be rotated relative to the rest of the members, and an engaging projection is formed at the side of the head-like members on the back surface of the base, and a boss having an engaging hole is formed at the centre of the base.

6. An integrating toy according to claim 1, or claim 2, wherein said first state is a shovel dozer state, and said movable elements comprise a shovel member, a pair of holding legs backwardly protruding from a front body carrying the rotatable shovel member, a rear body rotatably mounted on the legs and laterally divided into the right and left halves, rotatable wheel retaining members having wheels mounted on both sides of the front body and a robot head-like member formed telescopically at the end of the front body.

7. An integrating toy according to claim 1, or claim 2, wherein said first state is a concrete mixer truck state, and said movable elements comprise a rear body member formed with a concrete mixer element on the upper surface and the representation of a robot upper half body on the back surface, a pair of holding legs provided at one side of the rear body member, wheel retaining members having wheels rotatable at both sides of the rear body, a front body retaining member slidable on the legs, and a front body member rotable on the front body retaining member.

8. An integrating toy according to claim 1, wherein said first state is a dump truck state, and said movable elements comprise a front body member and a rear body member rotatable perpendicularly to each other, a front body portion on the upper surface of the front body member, and a tiltable robot head-like member, a rotatable roof member, rotatable wheel retaining members having wheels on both sides of the first body member, the rear body member having a pair of holding legs, and a longitudinally split load carrier at the ends of the legs and rotatable relative thereto, a holding projection and an engaging hold being formed in parallel on the upper surface of the body member the projection and the hole being disposed beneath the roof member, engaging holes being formed on the front and lower surfaces of the front body member, and an engaging space being formed at the rear end of the rear body member.