NL8105604A - Cube of eight sections - has identical curved groove on each inside face of each cube section - Google Patents

Abstract

The cube is built up of eight like cube sections in rows of two, the faces of four adjacent sections being coupled together and turning in relation to each other. Each section has in each of its three sides towards the inside of the cube an identical curved groove (7), centred precisely on the corner where the three sides concerned join. The grooves of adjacent cube sections fit precisely together, so as to form circular passages in lengthwise sectional view, filled with complementary circular components. Rails are included, whose maximum length is equal to one quarter of the circle periphery, and form the only coupling, broken by turning, between adjacent cube sectioned. Each rail is so positioned that except when turning it is only in contact with two cube sections simultaneously.

Description

* W.A.M. Osterholt in Delft

Title: 2x2x2 cube

The invention relates to a cube consisting of eight sub-cubes and which is thus built up according to the arrangement of 2x2x2.

Such a cube is known from Hungarian Patent Specification 170062 and Japanese Patent Specification 55-8193 *

The object of the invention is now to provide a construction of a 2x2x2 cube which is less vulnerable than the already existing constructions in that the sub-cubes are interconnected by means of elements which allow rotations of discs of adjoining sub-cubes, but which do not allow the cubes deviate from each other.

The invention will be described in more detail below with reference to an exemplary embodiment, with reference to a drawing.

Herein: fig.1 shows a perspective view of a 2x2x2 cube; Fig. 2 shows a perspective view of a partial cube; Fig. 3 is a top view of a disc of partial cubes; Fig. 4 is a perspective view of a rail; fig.5 shows a perspective view of the system of rails and circles in their spatial position.

Fig. 1 shows a perspective view of the cube, which in each case shows four partial surfaces 2 on the outer surfaces, each outer surface having its own color in a preferred embodiment. For the sake of an unambiguous description, the figure shows an X, Y and Z direction.

In each of these directions the cube has two disks of four adjacent cubes, which are indicated by 3 and 4 in the X direction, 3f and 4 'in the Y direction and 3 "and 4" in the Z- direction.

Fig. 2 shows a perspective view of a sub-cube 5 pointing to each of the three. interior of the cube-turned faces 6 is provided with an identical circular-shaped groove 7, the center of which circle is always exactly on the corner point of the partial cube formed by these three faces.

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In the exemplary embodiment, a groove with an I-shaped profile is viewed in cross section.

Fig. 3 shows a top view of a disc of adjacent cubes 5 in which, on the one hand, the circular grooves 7 in the plane of the drawing connect exactly to each other and thus form a complete circle and, on the other hand, perpendicular to the plane of the drawing circular grooves 7 fit exactly together and thus form semicircular channels in this disc.

The adjacent circular grooves in the adjacent surfaces of the adjacent sub-cubes also adjoin each other exactly and form a profile in cross-section.

Fig. 4 shows a perspective view of a circular element 8, further indicated by a rail, which fits exactly into the aforementioned channels with a shaped profile, in that, viewed in cross-section, the shaped profile of a rail is enclosed exactly is formed by two adjacent L · shaped profiles of. grooves and in longitudinal section given that the length of a rail does not exceed a quarter of the circumference of the circle.

Each pair of adjacent cubes which are provided with a rail in their common channel has a coupling which can only be broken by rotation. It is noted that profiles other than the aforementioned and 1-shaped profiles can also provide a coupling which can be broken only by rotation. For example, one can imagine that the cross section of a rail would be an H-shaped or a dumbbell-shaped profile.

Figure 5 shows a perspective view of the array of rails 8 in their spatial position as they should occupy as shown in the situation of Figure 1.

If the rails have a length of a quarter of the circumference of the circle, they must be chamfered at both ends if they are not to cause problems in the places where the grooves intersect.

If a disk of the cube is then rotated, the upright rails contained in this disk will perpendicularly rotate perpendicular to the plane of the rotation.

The rails in the plane of the rotation are thought to remain in place, otherwise it may as well be said that the other disc is just turned.

If the rails now have a length of a quarter of the circle-5 circumference, the rails in the disc to be turned will prevent twisting because their ends, which are located between the rails in the plane of the rotation, cannot pass these rails. .

If the rails are now provided with a mechanism which makes it possible that they can be shortened temporarily, twisting is possible, after which they can resume their original length. The construction of such a mechanism is not simple and in the exemplary embodiment a solution has been chosen which can enable a rotation at all times.

The rails 8 in Fig. 5 have a length of less than a quarter of the circumference of the circle, so that space is created in the grooves to provide additional elements which have the function of spacer between the rails.

These elements must ensure that a rotation is possible because the rails in the disc to be rotated are no longer hindered by the other rails.

These elements can be seen in fig. 5 as circles 9, the diameter of which must be at least as large as the width of the rails. If their diameter is smaller then they do not keep a sufficient distance between the rails and if their diameter is larger they do not fit in the grooves.

These circles should always be located where the channels in the cube intersect.

It is noted that the circles can never change places and thus behave as one rigid body together. They can therefore easily be made as one body when the space required for this is present in the cube and are formed by means of recesses in the partial cubes.

It is noted that the position of the system of rails and circles outside the cube cannot be checked and corrected. To ensure that this system remains in position ________ 8105604 -4- - ^ + 'as shown in fig. 5, this position must be coupled to one of the partial cubes. This can be achieved by attaching the rails gripped by this sub-cube to this sub-cube.

The above described form of parts is, of course, completed by such a rounding of the surfaces located in the interior of the cube that essentially smooth guide surfaces and slots are obtained between the elements for smoothly guiding one element over the other .

It is noted that it is of course possible to give the exterior of the cube a different shape and possibly to provide it with a different color or deviating pattern, without departing from the scope of the invention.

8105604

Claims (3)

Cube consisting of eight equal sub-cubes according to the 2x2x2 arrangement, the discs of four adjacent sub-cubes of which are rotatably coupled to each other, characterized in that each sub-cube 5 in each of its three faces the interior of the cube Inverted faces are provided with an identical circular groove, the center of this circle being exactly on the corner point of the sub-cube formed by these three faces, the grooves of abutting 10 sub-cubes adjoining each other and seen in longitudinal section thus form fully circular channels, which, viewed in cross-section, have a symmetrical profile and are filled with circular identical elements complementary to the channel profile, further indicated by rails, the length of which does not exceed a quarter of the circumference of the circle, the shape of the grooves and rails , viewed in cross-section, is chosen such that the rails ee n provide nothing other than a breakable connection between each pair of adjacent sub-cubes and in which each rail is placed such that, except during a rotation, it only has contact with two sub-cubes at a time. Cube according to claim 1, characterized in that the system of rails in the cube is coupled to one of the 25 sub-cubes of said cube, in that the rails circumscribed by this sub-cube are fixedly connected to this sub-cube. Cube as claimed in claim 1 or 2, characterized in that at each intersection of the channels present in the cube there is included an element fitting in these channels, which keeps the rails present in these channels at some distance from each other in order to rotate to make the cube disks more easily possible, whereby these elements do not exchange places with each other, can therefore be understood as being together one rigid body and can be made as such, in which case sufficient space must be saved in the interior of the cube to place this body in. 8105504