DE29712466U1 - 3D modular system - Google Patents

Description

3D modular system

The invention relates to a 3D modular system. Modular systems for the creation of three-dimensional structures of various kinds are known per se. The well-known interlocking bricks as well as simple so-called building block systems are common.

Such modular systems are primarily used for learning and practice purposes, but can also be used for games. Their use challenges and promotes coordination, spatial thinking, logic and memory.

A labyrinth toy is known from US 4,861,036, in which several cubes of the same size with different passageways are combined to form a large cube. The combined cube therefore has a labyrinth system inside with forks, branches, intersections, blind passages and the like. The labyrinth system of the combined cube has an entrance and an exit, each of which is formed by a channel opening of a cube with a passageway and through which a ball can be inserted into the labyrinth system.

It is therefore a three-dimensional design of a known labyrinth toy, in which a ball is guided by a predetermined

point through the labyrinth system to a predetermined end point,

In the labyrinth toy according to US 4,861,036, the combination options for building a labyrinth system with forks, branches, intersections, blind passages and the like, due to the large number of different cubes, each with a passageway, are too extensive and confusing, especially for children. Due to the complexity that can be created as a result of the confusing combination options, a user is usually overwhelmed when using the labyrinth toy, so that coordination, spatial thinking, logic and memory are not promoted to the desired extent. If, for example, a ball ends up in a blind passage or the like when using the labyrinth toy, i.e. deviates from the direct connection path between the entrance and exit, the task of transporting the ball from the entrance to the exit as quickly as possible is made considerably more difficult and almost impossible due to the complexity of the labyrinth system. The user becomes discouraged if he fails and the game becomes boring and unexciting because it is uncontrollable.

A further disadvantage of the labyrinth toy known from US 4,861,036 is its production, which is extremely complex and costly due to the large number of different cubes, each of which has a passageway.

The invention is based on the object of providing a three-dimensional (3D) modular system with which, in contrast to the known modular systems, a demand and promotion of the coordination of spatial thinking, logic and memory can be achieved in a simple and effective manner and with which, independently of the external three-dimensional contour, hidden connecting paths can be connected which connect at least two openings in the contour.

To solve this problem, the invention proposes a three-dimensional (3D) modular system consisting of a large number of

substantially uniform, each having at least two mutually complementary surfaces and, in the interior, a body element having a channel connecting the at least two surfaces and a receiving box having at least one inlet and at least one outlet bore, into which the body elements can be inserted, wherein channel openings of the body elements can be positioned in alignment under the at least one inlet and the at least one outlet bore.

With the 3D modular system according to the invention, operators can arrange the individual body elements in the casing so that they touch each other with surfaces that complement each other. The connecting channels located inside the body elements open into the area of these surfaces, so that an internal connection is created from body element to body element. With a large number of body elements put together accordingly, the openings in a casing that delimits a volume can be connected via a channel system that can be designed in almost any way.

By selecting and arranging the body elements within the shell that delimits a volume space to connect the openings in the shell and form a channel system, spatial and logical thinking as well as memory are challenged and promoted in addition to coordination.

In contrast to a labyrinth system, which has forks, branches, intersections, blind passages and the like, the present invention creates a channel system for connecting two openings. There are therefore no "dead ends" that would mislead, overwhelm and frustrate an operator during use and thus thwart the learning and training goals.

According to an advantageous embodiment of the invention, the channel openings in the respective surfaces are arranged at the same location. The channel openings in the respective surfaces are thus congruent, which means that any elements can be placed next to one another.

According to a further advantageous embodiment of the invention, the channel is a channel connecting two opposite surfaces, in a further embodiment a channel connecting two adjacent surfaces. The channels can thus either be guided as a through channel between two opposite surfaces inside the body element or connect two adjacent surfaces to one another by forming an angle or at an angle. In this way, an almost endless channel system can be developed by placing body elements together accordingly. Body elements are placed together in such a way that the channel opening in one surface is aligned with a channel opening in the surface of another body element. The channels formed inside thus represent a connected path. By using through holes and angle holes, any channel path can be created.

The invention advantageously proposes that the body elements are cubes. These have six complementary surfaces and are therefore suitable for constructing large three-dimensional channel structures inside large, three-dimensional external contours, namely the receiving box.

It is particularly advantageous that the body elements are prisms, preferably straight prisms. By placing two prisms together, a cube can be formed, for example. The use of prisms is particularly advantageous because only one type of body element needs to be produced when manufacturing the body elements. By placing two prisms with a corresponding through hole together, a cube with a through hole can be formed, for example, and by rotating a prism by 180° around the "cutting plane", a cube with an angled hole can be formed. The two prisms can also be connected to one another to form a corresponding cube, for example by gluing, plugging or the like. This means that greater flexibility and variability can be achieved with fewer body elements when forming a channel system. Since fewer types of body elements need to be produced at the same time, costs can be reduced.

Furthermore, according to a particularly advantageous proposal of the invention, pyramids with different bases, tetrahedrons, wedges and the like are suitable as body elements. The only important thing is that the body elements can be placed together in almost any way to form a channel system.

According to a further advantageous proposal of the invention, the receiving box is made up of several parts. The receiving box can, for example, have a removable lid or the like, so that the arrangement of body elements connected together by placing them next to one another in the receiving box is made easier. According to a further advantageous proposal of the invention, the receiving box is expandable, so that a correspondingly larger channel system can be formed by placing several receiving boxes next to one another.

Wood, plastic, aluminum, steel, stainless steel and similar materials can be used as materials for the modular system. A special appeal can arise if the individual elements of the modular system are made transparent, for example from acrylic glass and the like.

If a large number of body elements are inserted into a receiving box in such a way that an endless channel system is created, and if care is taken to ensure that the channel openings of the body elements are aligned with the holes, the inlet and outlet holes, in the receiving box, it is possible to insert a body, in particular a ball, into a channel opening from outside the receiving box and to guide the ball through all the components in a sequential path from the inlet hole to the outlet hole of the receiving box by moving the receiving box.

According to a particularly advantageous proposal of the invention, the at least one inlet bore and the at least one outlet bore in the receiving box are identical, i.e. the receiving box has only one bore. For example, a ball can be inserted into the receiving box bore in the channel system located inside and moved back and forth in the channel system by moving the receiving box or - similar to a

Tour - can be carried out. It can be interesting, for example, to precisely reproduce a sequence of movements in reverse order or something similar, for example in a game played by two or more people or even just one person, where one person or an instruction manual can specify the sequence of movements, for example depending on the channel system.

The invention can be used in a variety of ways. The use of the modular system described challenges and promotes coordination, spatial thinking, logic and memory. Even children can use the system, for example to build a continuous ball track inside a box. By varying the arrangement of the body elements inside the receiving box, the level of difficulty can be gradually adapted to the individual needs and abilities of the respective operator.

Another particularly advantageous application of the 3D modular system is a software solution. The body elements are visualized as objects on a monitor or similar. The operator can then arrange these according to the 3D modular system and connect two openings in a virtual shell to form a channel system.

Further advantages and features of the invention emerge from the following description based on the figures. They show:

Fig. 1 is a perspective schematic representation of a

embodiment of a body element;

Fig. 2 is a perspective schematic representation of a

further embodiment of a body element;

Fig. 3 is a perspective schematic representation of a

construction box;

Fig. 4 a lid plate for the box according to Fig. 3;

■· ·

Fig. 5a to 5d an embodiment of a schematic

canal flow plan;

Fig. 6a to 6c show another embodiment of a schematic

canal flow plan;

Fig. 7 is a perspective schematic representation of a

further embodiment for a body element and

Fig. 8a and 8b each show a further perspective schematic

Representation of the embodiment according to Fig. 7.

Figures 1 and 2 show exemplary embodiments of body elements 1. These are cubes 2 which have the respective inlet and outlet openings of a channel 5 on the two surfaces 3 and 4. In the case of Figure 1, the channel inside the cube 2 makes a 90° bend so that the adjacent surfaces 3 and 4 show the channel openings or mouths. In the case of Figure 2, it is the opposite surfaces 3 and 4 into which the channel 5 exits.

It turns out that by placing body elements together in the appropriate way, any channel path can be connected.

Fig. 3 shows an embodiment of a box 6, consisting of the side walls 7, 8, 10 and 11 and the base 9. In the embodiment shown, holes 12 are arranged in the base 9. Inside the side walls 7, 10 and 11, a groove 13 runs around the upper edge.

A cover 14 as shown in Fig. 4 can be inserted into the groove 13, which in turn has holes 15.

If a box 6 is now filled with body elements 1 according to Fig. 1 and/or 2, so that one of the entry openings into one of the levels in the upper area is located in such a way that it is accessible through one of the holes 15 through the pushed-over cover 14, and an exit opening is located on the base element 9 in such a way that it is accessible through one of the holes 12 in the

If the floor element 9 is accessible and all the cubes 2 arranged between them, which fill the entire box 6, are placed in such a way that a continuous channel path is created, then a ball (not shown) can be thrown in at the top and guided through the box 6 by pivoting it until it falls out of the lower opening.

An example of a circuit diagram is shown in Fig. 5a to 5d. Fig. 5a, 5b, 5c and 5d each show a level of body elements placed in a box 6. These body elements 16 according to Fig. 5a form the top level, which is located directly below the cover 14. The reference number 17 shows the inlet opening, which is located under one of the holes 15 in the cover 14. The level consists of a total of sixteen body elements 16, which are arranged in such a way that a ball thrown in at seven can be guided through the entire level by pivoting the box 6 and thus the level along the channel path 18, passing each body element and being transferred from the outlet opening 19 to the level below according to Fig. 5b. In this level too, the ball is guided from the inlet opening 17 through the channel path 18 to the outlet opening 19 and from there transferred to the level below as shown in Fig. 5c. After the further transfer from the outlet opening 19 to the inlet opening 17 as shown in Fig. 5d, the ball is guided to the outlet opening 19 and then falls out of one of the holes 12 in the base plate 9 of the box 6.

When using a correspondingly smaller box, the simpler variant according to Fig. 6a to 6c can be used, which corresponds in detail to the process described in Fig. 5.

Fig. 7 shows a perspective-schematic representation of another embodiment for body elements 20. This is a straight prism, the surface 3 of which has the inlet opening and the surface 4 of which has the outlet opening of a channel 5. In Figs. 8a and 8b, two prism-shaped body elements 20 according to Fig. 7 are placed next to each other to form a cube. Fig. 8a shows a cube formed from two prism-shaped body elements 20 with an angled hole corresponding to the body element 1 of Fig. 1.

By simply rotating one of the body elements 20 by 180° around the rotation surface designated 21, the cube shown in Fig. 8b is obtained with a through hole corresponding to the body element 1 according to Fig. 2.

By using prism-shaped body elements 20, the channel flow plans shown schematically in Figs. 5a to 5d and 6a to 6c can also be realized. In principle, only one type of body element is used, which reproduces the body elements 1 shown in Figs. 1 and 2 by placing them next to one another and simply rotating them by 180°.

Reference list

Body element 17 entrance opening

Cube 18 Canal Path

Surface 19 Exit opening

Surface 20 Body Element

channel

21 Turning surface

box

7 Wall 8th Wall 9 Wall 10 Wall 11 Wall 12 drilling 13 Groove 14 Lid 15 drilling

Body element

Claims (16)

Expectations 1. 3D modular system, consisting of a plurality of essentially uniform body elements (1, 16, 20), each having at least two mutually complementary surfaces (3, 4) and a channel (5) inside connecting the at least two surfaces (3, 4), and a receiving box (6) having at least one inlet (15) and at least one outlet bore (12), into which the body elements (1, 16, 20) can be inserted, wherein channel openings of the body elements (1, 16, 20) can be positioned in alignment under the at least one inlet (15) and the at least one outlet bore (12). 2. 3D modular system according to claim 1, characterized in that the channel openings in the respective surfaces (3, 4) are each arranged at the same location. 3. 3D modular system according to one or more of claims 1 or 2, characterized in that the channel (5) is a channel connecting two opposite surfaces. 4. 3D modular system according to one or more of claims 1 to 3, characterized in that the channel is a channel connecting two adjacent surfaces. 5. 3D modular system according to one or more of claims 1 to 4, characterized in that the body elements (1, 16) are cubes. 6. 3D modular system according to one or more of claims 1 to 5, characterized in that the body elements (20) are prisms. 7. 3D modular system according to one or more of claims 1 to 6, characterized in that the receiving box (6) is designed in several parts. 8. 3D modular system according to one or more of claims 1 to 7, characterized in that the receiving box (6) is expandable. 9. 3D modular system according to one or more of claims 1 to 8, characterized in that the channel openings in the respective surfaces (3, 4) are each arranged at the same location. 10. 3D modular system according to one or more of claims 1 to 9, characterized in that the elements are made at least partly from wood. 11. 3D modular system according to one or more of claims 1 to 10, characterized in that the individual elements are at least partially made of acrylic glass. 12. 3D modular system according to one or more of claims 1 to 11, characterized in that the individual elements are at least partially made of plastic. 13. 3D modular system according to one or more of claims 1 to 12, characterized in that the individual elements are at least partially made of aluminum. 14. 3D modular system according to one or more of claims 1 to 13, characterized in that the individual elements are at least partially made of steel, preferably stainless steel. 15. 3D modular system according to one or more of claims 1 to 14, characterized in that the at least one inlet bore (15) and the at least one outlet bore (12) are identical. 16. 3D modular system according to one or more of claims 1 to 15, characterized in that a ball can be passed through a plurality of body elements (1, 16, 20) placed against one another. RS/WT/left