BE1022602B1 - Construction set - Google Patents

Abstract

Construction set for forming objects, the construction set comprising a plurality of torus elements and at least one connecting element, the torus elements each having an annular surface formed by rotating a circle about a straight line lying in the plane of the circle, the circle being a radius and wherein the circle has a center which is spaced from the straight line, the distance being less than 7 times the radius and wherein the at least one connecting element is provided to press two toric elements together with their ring surface.

Description

Construction set

The present invention relates to a construction set for forming objects. More specifically, the invention relates to a construction toy set and a construction designer set.

Construction sets are known in all sizes and shapes. A construction set makes it possible to create a large number of shapes and mechanical constructions with a limited number of unique elements. Examples of known construction sets are: LEGO® and MECCANO®. Such construction sets make it possible to connect several elements from the construction set, also referred to as building blocks or blocks, in different ways to form different objects. In addition, the number of unique blocks, that is, blocks with a unique design, is typically much smaller than the total number of blocks. When the construction set is a toy construction set, the construction set stimulates the creativity of the player as well as the motor skills of the player during the formation of objects. When the construction set is a construction designer set, the construction set makes it possible to form a prototype in a relatively cost-efficient manner. The construction set is relatively cost-efficient because the limited number of unique elements greatly reduces the production cost of the construction set.

It is an object of the invention to provide a construction set as an alternative to the existing construction sets, whereby a great freedom of form is obtained with a minimum number of unique elements.

To this end, the invention provides a construction set for forming objects, wherein the construction set comprises a plurality of torus elements and at least one connecting element, the torus elements each having a ring surface formed by rotation of a circle about a line which lies in the plane of the circle , wherein the circle has a radius and wherein the circle has a center that is spaced from the line, the distance being less than 7 times the radius, and wherein at least one connecting element is provided to align at least two torus elements with their ring surface against each other to press.

In the construction set according to the invention, torus elements are used as basic element as basic element for forming objects. Multiple torus elements can be connected to each other via connecting elements. The connecting elements are thereby provided to press against each other with the ring elements with their ring surfaces. The toruses are thereby formed with a relatively small central opening in the torus. This means that the diameter of the opening is not too large compared to the diameter of the tube part that forms the torus. This is defined in the claim by describing the outer surface of the torus as a ring surface. A ring surface is defined as a surface formed by rotation of a circle about a line that lies in the plane of the circle. The circle has a radius and the center of the circle is at a distance from the line. The circle forms a tubular part through rotation around the straight line that ultimately forms the torus. When the distance between the center of the circle and the line is less than 7 times the radius of the circle, tests have shown that the aperture in the torus is small enough with respect to the tube part that forms the torus. The consequence of the relatively small opening in the torus is that the frontal surface of the torus is relatively large with respect to the space occupied by the torus. Because the toruses have a relatively large frontal surface, the open spaces that arise are relatively limited, for example when several toruses are placed in one plane with their ring surfaces against each other. These limited open spaces can then in a simple manner be filled at least partially by connecting elements such that the surface generates a solid visual impression. In this way objects can be formed that are aesthetically superior to similar objects with large open spaces in their structure. The choice of a torus element as a basic element in the construction set, and the connection of torus elements by pressing their ring surfaces against each other, offers many advantages. Namely, two toruses can be placed in different relative positions with respect to each other, the connecting element being able to press the toruses against each other in the same way. This will be further clarified in the detailed description on the basis of a few examples. As a result, complex three-dimensional surfaces can be formed with the donuts and the connecting elements according to the invention. As a further consequence, objects with complex three-dimensional shapes can be manufactured in a simple manner by the construction set according to the invention.

Preferably, the connecting element is formed to clamp two torus elements with their ring surface when the torus elements are mutually positioned such that their respective lines intersect. It will be clear here that the term cutting is a mathematical term that is defined in the context of this description such that rights that are parallel intersect each other at infinity and that rights that coincide intersect each other at multiple locations. This definition of intersecting rights can alternatively be defined as intersecting two rights when they lie in the same plane. Connection elements can hereby be provided for pressing two tube parts of the toruses against each other. Because the tube parts of a torus are circular and have a constant radius over the tube part, toruses can take an infinite number of relative positions with respect to each other and yet be interconnected by one simply formed connecting element. This gives the construction set according to the invention a great deal of flexibility so that various different shapes of objects can be created.

The connecting element is preferably formed substantially symmetrically with respect to a plane of symmetry. By forming the connecting element symmetrically with respect to the plane of symmetry, the use of the connecting element is simplified because its orientation does not have to be taken into account when using the connecting element. Furthermore, it is advantageous if the connecting element is symmetrical with regard to production of the connecting elements. Namely, a connecting element that is formed with respect to a plane of symmetry can typically be produced in a simple manner by injection molding. The symmetry plane will preferably coincide with the plane where the mold opens and closes. It is noted in this context that also a torus element is formed with respect to a plane of symmetry and can thus be manufactured in a simple manner by injection molding. This way, all elements from the construction set can be produced in a cost-efficient manner.

The connecting element preferably has a basic body that extends between two legs that are complementary to the torus elements. Because the legs are complementary to the torus elements, the legs are suitable for pressing the torus elements together with their ring surfaces. The basic body can then be provided with further functions and / or shapes, as will be further explained below.

The legs are preferably concave at the location of an inner side so that each of the legs is provided to lie against a ring surface of a torus element. By concave forming the inside of the legs, the legs can abut against the ring surface of a torus element at least over a significant part of their length and preferably over their entire length. A friction between torus element and connecting element is hereby obtained which ensures that the structure formed with the connecting elements and torus elements gives a firmness.

Preferably, the concave surface describes a circular arc with a circular arc radius equal to the radius of the circle of the ring surface of the torus elements and with a center angle that is greater than 90 degrees. By making the center angle of the arc larger than 90 degrees, the two legs are provided to extend over more than half of the tube parts of the torus elements. As a result, two torus elements can be clamped in a simple manner, namely hooking the legs behind the thickest point of the pipe sections. In this way, torus elements can be pressed together with their ring surfaces in a technically simple manner. Preferably the center angle is greater than 95 degrees, preferably greater than 100 degrees, more preferably greater than 105 degrees. Furthermore, the center point angle is less than 180 degrees, preferably less than 140 degrees, preferably less than 130 degrees and more preferably less than 120 degrees. Tests have shown that legs with a concave surface that describe an arc with such a center angle work optimally.

Preferably, the two legs have an intermediate distance that is substantially equal to four times the radius of the circle of the torus elements such that two torus elements can be placed between two legs and thus pressed against each other. The intermediate distance is measured on the inside of the legs. This allows the legs to grip around two tube parts of torus elements that lie against each other with their ring surface, so as to press these torus elements against each other.

The basic element preferably has a diamond shape and the legs are placed substantially transversely to the diamond shape at the opposite corners of the diamond shape. By forming the basic element as a diamond, and positioning the legs at corners of the diamond and transversely to the surface of the diamond, the diamond-shaped surface covers at least a portion of the open spaces between adjacent torus elements when torus elements be connected to each other. A surface with a high visual density can be obtained by concatenating a plurality of such connecting elements with a diamond-shaped basic body. This will be further demonstrated in the detailed description on the basis of a few examples. The opposite corners of the diamond shape will preferably each be essentially 60 or 90 degrees.

The construction set preferably comprises a plurality of torus elements and at least a first and a second connecting element, wherein the opposite angles of the diamond shape of the basic body of the first connecting element are each substantially 60 degrees and wherein the opposite corners of the diamond shape of the basic body of the second connecting element each are essentially 90 degrees. When the opposite angles of the diamond shape are 60 degrees, three toruses can be connected to each other by means of three connecting elements in one plane, the basic bodies of the connecting elements forming a continuous plane without appreciable openings between adjacent basic bodies. When the opposite angles are each substantially 90 degrees, four toruses can be connected to each other in one plane by four connecting elements, the basic bodies of the connecting elements forming a substantially continuous surface with no appreciable openings between adjacent basic bodies. By providing the construction set with three unique elements being a torus element, a first connecting element with opposite angles being 60 degrees and a second connecting element with opposite angles being 90 degrees, the toruses can be connected to each other in various complex ways, depending on the connection chosen for one or the other connecting element. Complex three-dimensional shapes can thus be visually formed as one plane.

Preferably the distance is less than four times the radius, more preferably less than three times the radius, most preferably the distance is substantially equal to twice the radius. This means that the torus elements most preferably have an opening with a diameter that is the same size as the diameter of the tube part that forms the torus. Tests have shown that such a torus element is an optimum basic element to connect via the connecting elements from the construction set.

The invention will now be described in more detail with reference to an exemplary embodiment shown in the drawing.

In the drawing: figure 1 shows a connecting element and a torus element from a construction set according to an embodiment of the invention; Figure 2 shows a section of a connecting element that presses two torus elements against each other; figure 3 shows a top view of the cross-section of figure 2; Figure 4 shows several applications of the construction set according to a further embodiment of the invention; and figure 5 shows an alternative connecting element from the construction set according to the invention.

In the drawing, the same reference numeral is assigned to the same or analogous element.

The invention relates to a construction set for forming objects. In a construction set, several blocks are assembled by connecting the blocks together so that a whole can be formed that is many times larger than the individual blocks. In addition, the number of unique blocks from a construction set is typically as small as possible. The shape and dimensions of a block will mainly determine whether a block is unique. Cubes with the same shape and dimensions can be formed in different colors, but these cubes can be formed in the same mold and via the same method without the cost price rising appreciably, and therefore will not be understood as unique cubes despite the difference in color. Also, when forming an object with the construction set, blocks with multiple colors can be used interchangeably without affecting the shape of the object. By taking the color of the blocks into account when building objects, the realism of the formed object can be further increased and the visual impression can be further optimized.

The construction set according to the invention essentially comprises two, and in a further embodiment at least three unique blocks which will be further described below.

These blocks are preferably made from plastic, and are preferably made by injection molding in a mold. As will become apparent from the description below, objects can be formed by connecting a few, tens, hundreds, or even thousands of these blocks. In addition, a substantially proportional number of each of the unique blocks will typically be used in the construction set according to the invention.

Figure 1 shows the two unique blocks from the construction set according to a first embodiment of the invention. Figure 1 shows a torus element 1, which forms a first block, and shows a connecting element 2, which forms a second block. The construction set according to the invention comprises at least two torus elements 1, and at least one connecting element 2.

The torus element 1 is formed as a tube part with a radius r, the central axis 7 of the tube part forming a circle with radius d. The surface of the torus element can be described as a ring surface formed by rotation of a circle about a line in the plane of the circle, the circle having a radius r and the circle having a center at a distance d lies straight. By rotating the circle around the line lying in the plane of the circle, the tube part with radius r is formed that forms the torus. An optimum torus element for the construction set according to the invention is formed such that: d = 2 x r. It will be clear to those skilled in the art that this optimum form can be deviated from without making the construction set functioning impossible. Therefore, the torus element is described as d <7 x r, preferably d <5 x r and more preferably d <3 x r and as d> 1.5 x r. The shape of the torus element can alternatively be described as a donut shape.

The connecting element 2 is provided for connecting two torus elements 1. For this purpose, the connecting element 2 is provided with a basic body 3 with two legs 4 and 5 which extend from the basic body 3 in substantially the same direction. A connecting element is hereby obtained with a C-shaped longitudinal section (Figure 1 shows the connecting element 2 in longitudinal section) wherein the back of the C-shape is formed by the basic element 3 and wherein the legs of the C-shape are formed by the legs 4 and 5 of the connecting element 2. The intermediate distance a between the two legs 4 and 5 is chosen such that two torus elements 1 can be clamped between the legs 4 and 5. As a result, the following comparison is mainly applicable: a = 4 x r. Those skilled in the art will understand that the flexibility and tolerances of the connecting element must be taken into account when dimensioning and applying this comparison. Namely during use, the connecting element will typically be tensioned and thus exert a force on the torus elements, as a result of which the distance a between the legs of the connecting element at rest is a little smaller than 4 x r.

Each of the legs of the connecting element 2 is preferably concave on an inner side. More preferably, the inside of each of the legs 4 and 5 describes a circular arc with a radius r 'that is substantially equal to radius r of torus element 1. The legs 4 and 5 furthermore preferably extend over a circular arc angle γ that is larger than 90 degrees. A circular arc angle γ greater than 90 degrees has the consequence that the legs can click over the thickest point of the torus elements and thus clamp the torus elements together, as shown in the following figures. Preferably the arc angle γ is greater than 95 degrees, more preferably greater than 100 degrees, most preferably greater than 110. Furthermore, the arc angle γ is less than 180 degrees, preferably less than 140 degrees, preferably less than 130 degrees and more preferably, less than 120 degrees. The arc angle γ can be optimized, taking into account the dimensions of the connecting element and the flexibility of the plastic from which the connecting element is made, in order to obtain an optimum clamping of torus elements.

The basic body 3 of the connecting element 2 preferably has a width, as shown in Figure 3, which is appreciably greater than the width of the legs 4 and 5. Namely, the legs 4 and 5 are intended to enter the central opening of the torus 1. to grab. The thickness of the connecting element 2 is chosen such that the flexibility of the connecting element 2 is substantially constant along its longitudinal section. This means that the thickness at the location of the broad basic body 3 is considerably smaller than the thickness of the narrow leg 4 or 5.

Figure 2 shows an assembly of two torus elements 1 and 1 'which are mutually connected by a connecting element 2. Thereby two tube parts of torus elements 1 and 1' are pressed against each other such that a point of contact 9 between the ring surfaces of the respective toruses 1 and 1 ' arises. The legs 4 and 5 of connecting element 2 extend around at least a portion of the tube parts of torus elements 1 and 1 "to clamp them together. As Fig. 2 shows, at the point of contact 9 more than half of the tube parts of the torus elements at the point of contact 9 are enclosed by the C-shaped connecting element. Furthermore, Figure 2 illustrates that the legs are in contact with the torus elements over more than 90 degrees. As a result, a frictional force will arise between connecting element 2 and torus elements 1 and 1 "that hold the position of the torus elements 1 and 1" relative to connecting element 2. By choosing the right materials for manufacturing torus elements and connecting elements and by optimizing the tolerances and dimension choices, the frictional force can be optimized such that modeling the shape of the object is possible, but that the object after modeling its shape retains.

Figure 3 shows a top view of the situation from Figure 2. Figure 2 shows a cross-section of the situation from Figure 3. Figure 3 shows a specific embodiment of the connecting element 3, wherein the basic body of the connecting element 3 is diamond-shaped and the corners of the diamond shape containing legs 4 and 5 have an angle α of approximately 60 degrees. The advantages of the diamond-shaped basic body will be explained with reference to Figure 4a. Alternatively, the basic body can also be differently shaped. For example, the diamond shape can have angles of 90 degrees, as shown in Figure 4b and the benefits of which will be explained with reference to Figure 4b.

Figure 3 further illustrates that the connecting element 2 is made symmetrically. It will be clear to those skilled in the art that a symmetrical connecting element 2 is only a preferred embodiment, and that the connecting element 2 can also be made non-symmetrically. When connecting element 2 connects two torus elements with each other, the point of contact 9 of the two torus elements 1 and 1 "will lie in the symmetry plane of the connecting element 2. Figure 3 further illustrates how the tangent 10 on the central axis 7 of the tube part of the torus element 1 at the location of the tangent 9 touches parallel to tangent 10 'on the central axis 7' of the tubular part of the torus element 1 'when the connecting element connects the torus elements 1 and 1' to each other press. The torus elements 1 and 1 "can be rotated relative to each other in different ways without the tangent lines 10 and 10" being brought out of a mutually parallel position. Thus, the torus element 1 can rotate as illustrated in Figure 3 with arrow 8. Also, the torus element 1 can be rotated as illustrated in Figure 2 with arrow 6. By combining these two rotation options 6 and 8, the toruses 1 and 1 'can be infinitely assume a number of different mutual positions, while the respective tangent lines 10 and 10 'on the central axes 7 of the tube parts nevertheless remain parallel to each other. As a result, the clamping of the tube parts between the legs 4 and 5 with respect to connecting element 2 will remain technically the same regardless of the rotational position of the torus elements relative to each other. Namely, the rotations 6 and 8 have no influence on the way in which the tube parts are positioned relative to each other at the point of contact 9.

These relative movements 6 and 8 can alternatively be described as any position of torus elements 1 and 1 'relative to each other where the lines from the ring surface intersect, and whose ring surfaces touch each other, can be connected to a connecting element 2.

Figure 4A illustrates how an object can be formed by means of a plurality of torus elements 1 and a plurality of connecting elements 2. A plane is formed in Figure 4A, but it will be clear to a person skilled in the art on the basis of the above description of possible rotational positions of the torus elements relative to each other that one or more planes can together form an object. The connecting elements of figure 4A have a diamond-shaped basic body 3, the angles α at the location of the legs 4 and 5 being approximately 60 degrees. In addition, approximately 60 degrees is defined as 60 degrees +/- 5 degrees, preferably 60 degrees +/- 2 degrees. Due to the angle α of approximately 60 degrees, torus elements can lie against each other in triangles, and when these torus elements are mutually connected by means of the connecting elements, the basic bodies 3 of the connecting elements will form a plane without appreciable open spaces between adjacent basic bodies 3. As a result an object can be formed that generates a solid visual impression.

Figure 4B shows how torus elements 1 can be placed in squares against each other and connected by connecting elements 2. The connecting elements are formed with a base body 3 whose angles α at the location of the legs 4 and 5 are approximately 90 degrees. In addition, approximately 90 degrees is defined as 90 degrees +/- 5 degrees, preferably +/- 2 degrees. Because the basic bodies have 3 angles α of approximately 90 degrees, the connecting elements will be close to each other without significant open spaces so that a surface with a solid visual impression is obtained.

By optimizing the dimensions and tolerances of torus elements 1 and connecting elements 2, the planes of Fig. 4A and Fig. 4B can be provided with a two-dimensional or three-dimensional curve where the plane can take on both convex, concave, or combinations of convex and concave shapes. Objects with various shapes can hereby be created via the construction set according to the invention.

In a preferred embodiment of the invention, the construction set comprises torus elements 1 and at least a connecting element 2 with a diamond-shaped basic body 3, wherein the angles α at the location of the legs 4 and 5 are approximately 60 degrees, and at least a second connecting element 2 with a diamond-shaped basic body 3 the angles α at the location of the legs 4 and 5 being approximately 90 degrees. With such a preferred construction set, a combination can be made of concatenation of torus elements 1 as shown in Figure 4A and as shown in Figure 4B. This gives the builder a high degree of construction freedom so that complex surfaces with three-dimensional shapes can nevertheless be provided with a solid visual impression by combining diamond-shaped connecting elements as shown in figure 4A and as shown in figure 4B.

The construction set according to the invention offers many possibilities for a builder to form objects. Figures 4A and 4B show how all connecting elements 2 are provided on one side with the torus elements 1. However, this is not necessary and a builder may, for example to construct a sharp angle between two planes, choose to attach the connecting elements 2 to the other side of the torus elements 1. This can also be done for aesthetic reasons to achieve a visual effect.

Figure 5 shows an alternative connecting element 2 according to the invention. The alternative connecting element 2 has a first leg 4 and a second leg 5 which is provided for clamping two torus elements 1 and 1 ". The basic body 3 of the connecting element of Figure 5 is provided with two further legs 4 "and 5" which are, for example, shaped so as to clamp one torus element. For this purpose the legs 4 'and 5' can be formed, for example, in the same way as the conventional legs 4 and 5, but with an intermediate distance a equal to twice the radius r of the tubular element forming the torus element 1. Figure 5 shows only one example of an alternative shaped connecting element that can be used in the construction set according to the invention.

The blocks from the construction set according to the invention are preferably provided to at least partially fuse together at a predetermined temperature. Thus, a builder of an object can be informed that an object formed with the construction set according to the invention can be fixed by heating an object at a predetermined temperature for a predetermined time, for example by placing the object in an oven. Alternatively, the construction set according to the invention may further comprise an adhesive which, for example, is sprayed onto the formed object by means of a spray can in order to fix the mutual position of the blocks of the construction set.

According to a first embodiment of the invention, the radius r of the tube part of the torus element is approximately equal to 2 mm. Approximately 2 mm is defined here as 2 mm +/- 0.5 mm, preferably 2 mm +/- 0.2 mm. As a result, the outer dimension of the torus element 1 is approximately equal to 12 mm. Tests have shown that blocks of such a size are easy to handle and that with blocks of such a size an object can be formed with an acceptable level of detail. According to an alternative embodiment, the blocks can be made larger such that they can be handled by small children, or that they can be used to form objects with large dimensions.

In the context of this description, a circle is defined as a spatial figure in which all points of the circle are spaced from a center point, which distance is approximately the radius. In addition, approximately the radius is defined as the average radius +/- 20% of the average radius, preferably the average radius +/- 10% of the average radius. The consequence of this definition of circle is that polygons with more than eight angles also fall under this definition and are considered as a circle according to the invention. Because a torus element has an outer surface that is formed by a combination of two circular movements, this definition of circle will also apply to the torus element. This has the consequence that, for example, an octagonal donut-shaped element will also be regarded as a torus element in the context of this description. Also a torus element in which the tube part does not have a round cross-section but, for example, a hexagonal cross-section, will be regarded as a torus element in the context of this description. The legs of the connecting elements can then be adapted accordingly to be compatible with the polygonal cross-section of the torus elements. The torus element preferably has a continuous or non-angled outer surface. A continuous outer surface will significantly simplify the use of a torus element in forming an object with the construction set according to the invention.

The above description and accompanying figures show only a few possible embodiments of the construction set according to the invention. Those skilled in the art will understand that different variants can be devised without departing from the principles of the invention. The connecting element can thus be provided with a basic body with an alternative shape than the shapes described above. One example of this is described with reference to Figure 5, but a person skilled in the art will be able to devise more alternatives. According to the invention, although the surface of the polygonal element does not contain rounded surfaces, polygonal elements that approximate the shape of a torus will also be considered as torus elements. The invention is not limited to the examples described above, but will only be defined in the claims.

Claims (14)

Conclusions A construction set for forming objects, the construction set comprising a plurality of torus elements and at least one connecting element, the torus elements each having a ring surface formed by rotation of a circle about a line lying in the plane of the circle, the circle has a radius and wherein the circle has a center spaced from the line, the distance being less than 7 times the radius and wherein the at least one connecting element is provided to press two torus elements together with their ring surface. 2. Construction set according to claim 1, wherein the connecting element is formed to clamp two torus elements with their ring surface when the torus elements are mutually positioned such that their respective lines intersect. 3. Construction set as claimed in claim 1 or 2, wherein the connecting element is formed substantially symmetrically with respect to at least one symmetry surface. 4. Construction set as claimed in any of the foregoing claims, wherein the connecting element has a basic body that extends between two legs that are complementary to the torus elements. 5. Construction set as claimed in claim 4, wherein the two legs are concave at the location of an inner side so that each of the legs is provided to lie against the ring surface of a torus element. The construction set of claim 5, wherein the concave surface describes a circular arc with a circular arc radius equal to the radius and with a center angle that is greater than 90 degrees. The construction set of claim 6, wherein the center angle is greater than 95 degrees, preferably greater than 100 degrees, more preferably greater than 105 degrees and less than 140 degrees, preferably less than 130 degrees and more preferably is less than 120 degrees. A construction set according to any one of claims 4-7, wherein the two legs have an intermediate distance that is substantially equal to 4 times the radius. Construction set according to any of claims 4-8, wherein the basic body has a diamond shape and wherein the legs are placed substantially transversely of the diamond shape at the opposite corners of the diamond shape. The construction set of claim 9, wherein said opposite angles of the diamond shape are each substantially 60 degrees. The construction set of claim 9, wherein said opposite angles of the diamond shape are each substantially 90 degrees. A construction set according to claim 9, wherein the construction set comprises a plurality of torus elements and at least one first and a second connecting element, wherein said opposite angles of the diamond shape of the basic body of the first connecting element are each substantially 60 degrees and wherein said opposite angles of the diamond shape of the basic body of the second connecting element are each substantially 90 degrees. A construction set according to any one of the preceding claims, wherein the distance is less than 4 times the radius, preferably less than 3 times the radius. A construction set according to any one of the preceding claims, wherein the distance is substantially equal to 2 times the radius.