SK279903B6 - Construction toy - Google Patents

Abstract

A construction toy system uses, as principle components, a connector (10) having one or more gripping sockets (14), and rod-like struts (13) having end portions configured to be received in the gripping sockets (14). The sockets (14) comprise pairs of gripping arms (16), formed of deflectable plastic material. Outer portions of the gripping arms (16) have concave grooves for lateral, snap-in assembly of struts (13) having complimentary cylindrical connector portions. The gripping arms (16) have locking projections (24) arranged to interlock with annular recesses (27) near the ends of the struts (13). The struts (13) have end flanges (26), received in a cavity at the closed end of the gripping socket (14). Certain forms of the connecting elements are designed so that an assembly of two such connector elements provides for sockets in each of two planes oriented at right angles to each other to form a right angle corner structure, for example, or a Tee-shaped structure. The system comprises a variety of connector elements, having one or more sockets arranged to be joined with struts, to form complex structural units. A plurality of single socket connector elements can be connected with a succession of crosswise oriented struts to form an articulated structure, of endless or finite length.

Description

The children's kit includes couplings (10) and rod-shaped spacers (13) that are releasably interconnectable with other elements, at least some of the couplings (10) comprising a collar (14). The sleeve (14) comprises a pair of clamping elements (16) provided with first locking means for detachably locking the spacer (13) and firmly holding the spacer (13) in a position aligned with the axis (19). The sleeves (14) are provided with second locking means for releasably locking the spacer (13) and firmly holding the spacer (13) in a predetermined axial position against its movement along the axis (19), the opposite end portions of the spacer (13) being provided with third locking means. for interlocking with the first locking means arranged on the clamping elements (16) and securing the spacer (13) in a position symmetrical to the axis (19) and the fourth locking means for interlocking with the second locking means arranged in the sleeves (14), and securing the spacer (13) in a predetermined axial position on the axis (19). The clamping elements (16) are resiliently detachable for laterally snapping the end portion of the spacer (13) transverse to the axis (19).

Technical field

The invention relates to a children's kit comprising couplings and spacers adapted to be removably engaged and to form a composite structure.

BACKGROUND OF THE INVENTION

Various types of children's kits are known which consist of a combination of couplings and spacers, which can be combined into a variety of shapes to form a composite structure. An example of such a known kit is given e.g. DE-A-3524467.

SUMMARY OF THE INVENTION

The kit according to the invention comprises rod-shaped connectors and spacers made of molded plastic and removably interlockable with other elements to form a cohesive assembly, at least some of the connectors comprising a sleeve arranged on a predetermined axis. Some spacers are formed by an elongated rod-like body comprising opposing end portions of the spacer, and the middle portion of the spacer integrally joining opposite end portions.

SUMMARY OF THE INVENTION The invention is based on the fact that the sleeve comprises a pair of spaced apart clamping elements substantially parallel to the cantilever arrangement and symmetrically aligned with respect to the axis. In the clamping elements, first locking means are provided for releasably locking the spacer and firmly holding the spacer in a position aligned with the axis, and second sleeves are provided for releasably locking the spacer and firmly holding the spacer in a predetermined axial position against its movement along the axis. Opposite end portions of the spacer are provided with third locking means for interlocking with the first locking means arranged on the clamping elements and securing the spacer in a symmetrical position with the axis and fourth locking means for interlocking with the second locking means arranged in the sleeves and securing the spacer in the spacer. axial position on the axis. Each pair of clamping members defines a laterally open and axially positioned collar, and the clamping members are resiliently detachable to laterally snap the end portion of the spacer transverse to the axis. After insertion into the sleeve, the spacer is fixed therein and positioned in a fixed position relative to the sleeve.

The couplings are provided with a plurality of substantially radially arranged sleeves for supporting and blocking the insertion of the end portions of typical spacers. Sockets are provided on the couplings for insertion and snapping of the spacers. The end parts of the spacers are provided with annular recesses defining a flange-like end. The sleeves on the couplings are delimited by separate pairs of clamping elements, each clamping element comprising an inwardly projecting locking projection adapted to receive the annular recess of the spacer. Therefore, the spacer is locked in the lateral engagement against axial withdrawal from the coupling. The spacers, cast with a circular cross-section at their ends, are arranged such that they have a substantially X-shaped groove section in the space between the two ends. This "X" cross-section is arranged to engage the opposite locking lugs of the fasteners so that when the spacer is rotated 90 ° from its "normal" radial orientation in the coupling, it can be laterally pushed between a pair of snap-in fasteners. locking position, with locking projections engaging in a groove portion with an "X" profile to immobilize it. The aforementioned feature of cross-fastening spacers provides design possibilities, such as articulated belt construction, which can be incorporated into dynamically operated toy structures such as bulldozers, tanks, conveyor belts and the like, as well as static structures such as chain-hinged elements.

One type of connector allows one connector to be connected to the other in planes arranged at right angles to each other. The pair of couplings so connected is designed to couple the spacers in two basic planes. In addition, each of the available sleeves can still retain the spacers rotated at right angles to the base plane of the coupling in a blocking manner. In one embodiment, the assembly of the couplings can be carried out which allows the spacers extending in four planar directions from the central axis. Modified shapes of such clutch assemblies are also provided where the spacers extend in three planar directions (forming a 'T' joint) or in two planar directions (forming a rectangular corner joint). The design and construction of the recess in the sleeve, on the one hand, and the ends of the spacers, on the other hand, have the advantage that the engagement of the recess projection serves to press the spacer into close contact with its end face with the base wall of the recess. This creates the conditions for a sufficient degree of additional stability in the connection between the spacer and the coupling.

A particular advantage is that this baby kit system includes a series of spacers of graduated lengths, graduated according to a predetermined formula, such as when two spacers of a given length in series are connected to the couplings to form a rectangular joined structure, the spacer with the next larger length in series has such a suitable a length that can be joined to the assembly after the transition of the triangular structure. In this way, a large assembly can be formed using rigid triangular assembly subgroups of different sizes to achieve maximum strength and rigidity.

In a new system in which a series of spacers of graduated lengths is formed according to the above principle, the structure consisting of a pair of spacers of a given length mounted coaxially on opposite sides of the coupling has the same length as the spacers in a series greater by two size degrees. This arrangement creates conditions for an extra degree of flexibility when using spacers in any assembly.

An important aspect of said geometric relationship is the fact that the spacers can be joined to the couplings by lateral snapping, so that the center distances of the coupler couplings do not need to increase. This arrangement allows easy addition of structural members and / or modification of the structure even after the structure has reached a certain state of substantial stiffness.

In dynamic constructions, a drive relationship may be required between the spacer requiring axle function and the connected clutch. For this purpose, the children's kit comprises a drive element with a recess forming a sleeve of the type described, which is intended to cross-grab a spacer, performing the function of an axis on an adjacent coupling. The drive element is formed with a laterally extending drive pin arranged to engage between adjacent spoke-like clutch ribs to provide a drive coupling for the spreader of the supported clutch.

Overview of the figures in the drawing

For a better understanding of the foregoing and the following features of the invention, the invention will be described with reference to the accompanying drawing, in which: FIG. 1 is a front elevational view, partially in section, of a coupling according to the invention, with selected spacers connected to the coupling; FIG. 2 is an enlarged perspective view of a portion of the coupling of FIG. 1, FIG. 3 is an enlarged, partial view of the end portion of the spacer formed in accordance with the invention; FIG. 4 is a cross-sectional view taken along line 4-4 of FIG. 3, FIG. 5, 6 and 7 are sequential views, substantially taken along line 7-7 of FIG. 1, showing successively the lateral insertion with snapping of the spacer into the coupling sleeve of FIG. 1, FIG. 8 and 9 are on an enlarged scale, in cross-section in planes 8-8 of FIG. 1 shows the spacer and the coupling, FIG. 10 is a front elevational view of a spacer according to the invention; FIG. 11 is an enlarged, partial perspective view of the spacer of FIG. 10, positioned rectangularly in the coupling sleeve with respect to the normal radial orientation, FIG. 12 is a cross-sectional view of the spacer sleeve in the plane 12-12 of FIG. 11, FIG. 13 is a bottom perspective view of a modular attachment for attaching a baby kit to a popular type of similar kit; FIG. 14 is a front elevational view, partially in section, of the modular extension of FIG. 13, FIG. 15 is a plan view of the assembly of FIG. 14, FIG. 16 shows a perspective view of the coupling of a pair of a modified coupling; FIG. 17 are an exploded view of the coupling of FIG. 16, FIG. 18 is an enlarged, partial perspective view of the coupling of FIG. 16, FIG. 19 is an enlarged scale, partially sectioned, assembly of FIG. 16, FIG. 20 is an enlarged, partial cross-sectional view of the spacer insertion of FIG. 19 into one of the coupling sleeves, FIG. 21 is a side elevational view of a single-element coupling sleeve designed to receive a spacer disposed axially in a recess forming the sleeve and a second spacer in a bearing bore disposed at right angles to the first spacer; FIG. 22 is a side view of a two-element coupling sleeve; FIG. Figures 23 to 29 show further modifications of the couplings; 30 is a group view of a series of spacers of graded length as well as the ratio of the length of a given spacer from the series to smaller spacers connected axially to the coupling; FIG. 31 is an enlarged cross-sectional view of the coupling sleeve coupled to the spacer; FIG. 32 is a front elevational view of an assembly of spacers and couplings arranged in triangular subgroups in increasing sizes; FIG. 33 is a top plan view illustrating the construction of a link or tread strip constructed of a plurality of building connectors and spacers interconnected with one another in FIG. 34 is a cross-sectional view taken along line 34-34 of FIG. 33 shows the structure of FIG. 33, FIG. 35 to 39 show, in various views, modified coupling shapes with the possibility of coupling to similar couplings; FIG. 40 and 41, the couplings of the type of FIG. 35 to 39 in conjunction with the coupling of the type of FIG. 16 to 20, FIG. Fig. 42 is a perspective view of a drive element for transversely engaging a spacer for operating the axle and equipped with a drive protrusion; 43 is a front elevational view of the drive member of FIG. 42, disassembling the laterally clamped spacer, FIG. 44 is a view similar to FIG. 43 shows a clutch shown attached to a spacer with the possibility of a drive relative to one another; FIG. 45 is a front elevational view showing a component showing a pulley / wheel combination; FIG. 46 is a tire-shaped member adapted to be coupled to the member of FIG. 45, FIG. 47 and 48, the elements of FIG. 45 and 46, in cross-sectional planes 47-47 and 48-48 of FIG. 45, respectively. 46th

DETAILED DESCRIPTION OF THE INVENTION

In the accompanying drawing of FIG. 1, the coupling 10 comprises a central hub 11 and radial spokes 12. The illustrated shape of the coupling 10 allows coupling to axes with radially spaced spacers 13. The radial spokes 12 support a plurality of eight radial sleeves 14, each comprising a base wall 15 and spaced apart, opposing clamping elements. The radial sleeves 14 are radially spaced with respect to the central axis 17 of the coupling 10 and the individual pairs of clamping elements 16 are suitably arranged on opposite sides of the radial axis 19 of the radial sleeve 14, usually parallel to this radial axis 19. The clamping elements 16 are provided in their internal portions by concave grooves 18 concentrically disposed about the radial axis 19 of the sleeve 14 and preceding from the outermost portion 20 of the clamping elements 16 at a suitable distance to the base wall 15 of the radial sleeve 14, usually about half this distance. The spacers 13 generally have a cylindrical shape at their ends. The spacers 13 may have said diameter, for example about 6.35 mm, to engage the concave grooves 18 of the clamping elements 16 shaped to the same diameter. As shown in FIG. 5, the arc of the concave grooves 18 serves to narrow the inlet region 21 to a dimension considerably smaller than the diameter of the 6.35 mm spacer

13. The dimension of the throat or opening of the inlet region 21 in this arrangement may be 5.33 mm. Accordingly, it is desirable to shape the side edges 22 of the clamping element 16 into an extension from the inlet throat of the region 21 towards the outer side surface 23 of the clamping element 16. The measured extension angle is about 15 °. This facilitates the lateral insertion of the spacer 13 into the concave groove 18 by the lateral adjustment and opening of the clamping elements 16. When the spacer 13 is seated in the concave grooves 18, the clamping elements 16 are skidded around it and held in position.

Each clamping element 16 is provided with a locking protrusion 24 of a suitable semi-cylindrical shape extending perpendicular to the radial axis 19 of the radial sleeve 14 defined by the clamping elements 16. In the illustrated construction, the locking protrusions 24 typically have a uniform cross section and extend from one side edge 22 of the clamping element 16 to the other as is best shown on an enlarged scale, in a perspective view of FIG. 2. The locking lugs 24 are radially spaced outwardly from the outside of the base wall 15 of the radial sleeve and define together with it a recess 25 for engaging a flange on the inner or base wall of the sleeve 14.

As shown in FIG. 3, the end portion of each spacer 13 is arranged such that its longitudinal cross-section is approximately the same as the longitudinal cross-section of the radial sleeve

14, along its radial axis 19 in a plane parallel to the flat sides of the coupling 10. The spacers 13 have cylindrical end flanges 26 with a size and shape to be engaged in a recess 25 of the radial sleeve 14. Adjacent to the cylindrical end flange 26 is an annular recess 27 of semicircular cross section For engagement in a constricted space between opposing locking lugs 24. Close to the annular recess 27 is a cylindrical gripping portion 28 adapted to grip in concave grooves 18 and to shear the outer portions of the gripping elements 16. The axial length of the gripping portions 28 corresponds to the effective length of the concave grooves 18 The cylindrical flange 26 may have an axial length, for example 15.75 mm. The annular recess 27 and the locking lugs 24 may have a typical radius of approximately 15.75 mm. The spacer 13 with said diameter of 6.35 mm has an overall length for the collar 14 of about 8.9 mm.

In FIG. 10 shows the typical shape of the spacer 13. The spacer 13 may, of course, be of any length, and a typical baby kit according to the principle of the invention uses a large number of these elements of different suitable lengths. It is particularly advantageous that the spacing portions 13 between their end portions 30 have a " X " grooved cross-sectional shape comprising ribs 31 extending radially at typically 90 [deg.] Spacing and especially with the outer surfaces 32 of ribs 31 lying in the cylindrical casing of spacers 13. By appropriately dimensioning the thickness 33 of the ribs 31 and slightly sloping their blocks 34, the spacer 13 can be laterally slid into the open end of the radial sleeve 14 and pushed between a pair of opposing locking lugs 24, as shown in FIG. 11 and 12 by fitting the beacons 24 into the passage grooves 39 between adjacent ribs 31. The X-shaped cross-section of the spacer 13 may be regularly interrupted by one or more pairs of cylindrical portions 35 spaced apart approximately at a width of approximately 36 When the spacer 13 is snapped in the locked position by the locking lugs 24 as shown in FIG. 11 and 12, in this position it is locked axially, laterally and rotatably. Alternatively, when the spacer 13 is inserted laterally into the radial sleeve 14 at some point in its longer groove portion 37, which extensively separates adjacent cylindrical portions 35, how the axial position of the spacer 13 can be adjusted within that portion.

In a particularly preferred embodiment of the invention, the thickness 33 of the ribs 31 may be about 2.362 mm which taper outwardly, as shown in particular in FIG. Of course, the arrangement of the X-shaped spacer 13 is not principally limited to the use of two pairs of ribs 31. For example, three pairs of ribs 31 arranged at 60 ° angular intervals may be used. Accordingly, the "X" term used herein may be interpreted to include these alternatives.

As shown in FIG. 13 and 15, the present invention includes a modular extension 40 with a block arrangement that is adapted to connect conventional block-type elements and elements of a child kit according to the invention. In FIG. 14 and 15 are, for example, modular elements 41 and 42, block construction elements of a known type, constructed in the form of a block with open sides equipped with an "upper" wall 44 to 48 forming an open cavity 49. The upper wall 44 is provided with many shorts. Three elongated tubular friction supports 51 also pass from the top wall 44 through the cavity 49. According to the known construction of the block-type modular elements 41, 42, the internal dimensions of the open cavity 49 are such that they are skidded around the outer cylindrical projections 50. the friction supports 51 are sized so that they are in tangential contact with the sides of the short cylindrical protrusions 50 when the building elements 41, 42 are placed one on top of the other. This makes it possible to form a composite structure by frictional connection from many modular blocks. The modular extension 40 comprises a top wall 52 and side walls 53. In the illustrated embodiment, the modular extension is square, but other configurations are possible within the scope of the invention. Four elongated cylindrical protrusions 54 with a diameter and spacing extend from the top wall 52, corresponding to the short cylindrical protrusions 50 of the hundred unit elements 41, 42. These elongated cylindrical protrusions 54 may be inserted into the open cavity 49 of the modular element 41, 42 and The tubular sleeve 55 extends through the open recess 56 from the top wall 52 of the modular extension 40. The inner diameter of the tubular sleeve 55 is such that it skips the end portion 30 of the spacer 13 as shown in FIG. 14. The tubular sleeve 55 is recessed below the open edge 57 of the side walls of the modular extension 40 so that the modular extension 40 can be connected to a conventional structural block in a known manner.

In FIG. 16 and 17 show a clutch 70 in a general "snowflake" configuration according to the present invention and has many design features of the previously described invention, but is specially adapted to engage a second similarly arranged clutch facing the clutch at right angles. The connector 70 is generally arranged in a flat, open design, typically with a thickness of 6.35 mm. The connector 70 has a solid semi-cylindrical core 71 in its center. Guiding walls 72, 73 extend from opposite sides of the core 71, which are spatially separated and parallel to one another. The distance between the guide walls 72, 73 is substantially the same as the thickness of the coupling 70 and permits engagement of a second such coupling in the recess 74 defined by the spatially separated guide walls 72, 73 and the flat transverse wall 75 which forms one wall of the core 71 and is located in an axial A plurality of spoke elements 76 to 78 extending radially outwardly from the core 71 in a radially outward direction, connected at their outer ends to edge walls 79, 80. In the illustrated arrangement, the edge walls 79, 80 define seven sides of a generally octagonal structure, the eighth side open the location of the recess 74. As shown in FIG. 17, some of the edge walls 79 of the continuous beam pass to the other (or from the beam to the guide walls 72, 73). However, the edge wall 80, which lies directly opposite the recess 74, is provided with a slot 81, the function of which will be explained in the following. Each of the edge walls 79, 80 forms the base wall of the radial sleeve 82 for receiving the spacer (in the case of the edge walls 79) or 83 (in the case of the broken wall 80). Each of these sleeves 82, 83 is delimited by a pair of opposing clamping members 84 provided within the semi-cylindrical locking protrusions 85 that extend perpendicular to the generally radial axis of the sleeve. The locking protrusions 85 in connection with the edge walls 79, 80 define a flange recess 86 for receiving the flange. The extremities of the clamping elements 84 are formed by concave grooves 87 concentrically arranged with respect to the generally radial axis 88 of the sleeve 82, 83.

As shown in FIG. 19, the spacers 90 are provided with cylindrical flanges 91, adjacent annular recesses 92 and cylindrical portions 93 arranged for sliding fit in the concave grooves 87 of the clamping members 84. The structural member, referred to as spacers 90, is normally coupled to the clutch 70 laterally pushed into one of The lateral inlet of the sleeve 82 is partially closed by a narrow mouth defined by the upper and lower edges 94 of the concave groove 87. To facilitate the lateral insertion of the spacer 90, the guide surface 95 is open in the sleeve 82, 83. when the end of the spacer is engaged in the sleeve where the flat end wall 91a of the cylindrical flange 91 of the spacer 90 is resiliently pressed into firm front contact with the flat edge wall 79 (or 80) of the radial sleeve 82, 93. This arrangement significantly increases stability and stiffness . The desired relationship is achieved by slightly sliding the locking lugs 85 in the direction of the edge wall 79 of the sleeve 82, taking into account the "normal" position of the annular recess 92 of the spacer 90. After the spacer 90 clicks in the assembled position contact between the end wall 91a and the edge wall 79.

Referring to the exploded view of FIG. 17, the second clutch 70a is identical to the clutch 70, but rotated so that its base plane is perpendicular to the base plane of the clutch 70 and its recessed wall (not shown in FIG. 17) abuts the recess 74 of the clutch 70. 70a slid together in the direction of the arrow 96, engaging a portion of the connector 70 to the left of the transverse wall 75 into the recess of the connector 70a. Also, the recess 74 of the clutch 70 engages the right portion of the clutch 70a. The complete connection of the two couplings 70, 70a is evident from the perspective view of FIG. 16. The assembled couplings 70, 70a form a radially oriented recess in two planes to receive the spacers so that the design capabilities of the system are greatly increased. In order to secure the two couplings 70, 70a in the assembled state, retaining ribs 98 and grooves 97 are provided in individual parts. The guide walls 72, 73 are provided with transverse retaining grooves 97. They are arranged to engage suitably positioned retaining ribs 98 on the opposite coupling. The retaining ribs 98 as shown in FIG. 17, are formed on the radial spoke elements 77. During coupling, a pair of couplings 70, 70a, when the retaining ribs 98 reach the extreme end of the guide walls 72, 73, the guide walls 72, 73 spring elastically to a distance sufficient to accommodate the retaining ribs 98. its elastic opening facilitates the mutual opening of the guide walls 72.73. This process is performed simultaneously on both couplings 70, 70a.

The individual clutch described in FIG. 1 to 5, it is formed with a symmetrical array of eight spacers for receiving spacers 13. The individual couplings 70, 70a on the other hand have one sleeve that is not intended to receive the spacers because they have an open recess 74 on one side of the coupling. However, when two couplings 70, 70a are assembled, as shown in FIG. 16, in fact each coupling provides a sleeve for engaging the spacer in the other coupling, so that there are four pairs of opposing sleeves in each plane. When the two couplings 70, 70a are assembled according to FIG. 16, the three opposing pairs of sleeves on each connector 70, 70a are open and accessible for lateral insertion of the spacer 90. However, in the case of one of the opposing pairs of sleeves 83, 83a, the normal lateral insertion of the spacer 90 is excluded. carried by the opposite connector of this assembly.

The insertion of the spacer 90 into the partially inaccessible sleeves 83, 83a is facilitated by a slot 81 in the edge wall 80. This slot 81 allows limited external opening of adjacent clamping elements 84, allowing "snapping" into position by a lever movement schematically shown in FIG. 19 and 20. 19, the position of the spacer 90, shown in broken line, is a typical initial position for inserting the spacer 90 into the sleeve 83a of the clutch 70a. The end surface 100 of the spacer 90 is positioned opposite the end surface 101 of the adjacent clamping element 84, which serves essentially as a guide when the spacer 90 is pushed into the sleeve 83a, while generally maintaining the angular direction shown in FIG. 19. During this operation, the opening of the opposing clamping elements 84, caused by the slot 81, tends to open to a greater width than the normal width. In addition, the recess guide wall 72 is easily deflected outwardly, and this is due to the lever movement of the spacer 90 in the direction of the first arrow 102 in FIG. As a result, the lever is moved upwardly against the leading edge surface 101, so that the adjacent clamping element 84 is displaced in the direction of the second arrow 103 in FIG. 20. The lever movement of the spacer 90 continues until the end flange 91 of the spacer 90 clicks in place in the recess as shown by the solid line in FIG. 19. The removal of the spacer 90 from the partially locked sleeves 83, 83a is generally performed in the opposite manner.

As shown in FIG. 31, the recess arrangement in the sleeve 150 and the spacer 140 is preferably such that the center of curvature of the locking lugs 130, 131 is disposed on an axis 151 that is offset from the surface 152 of the base wall 125 by a distance slightly smaller than the offset between the axis 153 containing the center of curvature. As a result, when the spacer 140 is laterally pushed into the clamping position in the sleeve 150, the locking lugs 130, 131 are in pressure contact with the side portion of the annular recess 147 to force the end surface 154 of the spacer 140. to the rigid front contact with the surface 152 in the recess of the base wall 125. By tightly maintaining the two faces in the front contact, this spacing-coupling connection is given the desired degree of additional rigidity.

Couplings may be formed in a wide variety of types and methods having from one to many sleeves 150. Couplings having more than one sleeve are arranged such that the sleeves are angularly spaced at 45 ° or a multiple of that angle, although other arrangements are possible within the scope of the invention.

In FIG. 21 shows a single sleeve clutch 160. It includes a hub 161 defined by a cylindrical wall 162. The internal diameter of the hub 161 is approximately the same as the diameter of the cylindrical shell formed by the spacer 140. The diameter of the cylindrical shell corresponds to the diameter of the cylindrical end portions of the end flange 146. thus, the spacer 140 is loosely engaged in the cylindrical bore 163 of the hub 161 and with a slight clearance to allow free rotation and free longitudinal displacement of the spacer 140 in the hub 161. The hub axis 164 is positioned perpendicular to the longitudinal axis The wall 167, which forms the base wall of the sleeve 150, is separated from the hub axis 161 by a pair of spacers 166, which are an integral part of the base wall 167 and the cylindrical wall 162. The couplings are generally designed with predetermined uniform thicknesses in the axial direction. 164 hub 161 Preferably, the thickness is approximately equal to the diameter of the cylindrical casing of the spacers 140. A thickness of about 6.19 mm has been considered particularly suitable, in many cases allowing lateral joints to be joined transversely relative to the spacer across the entire length of the central spacer body. leaving an effective space at either end. This allows the construction of truly solid walls from clutch elements transversally connected by spacers over the entire width of the spacer body portion.

In FIG. 22, a clutch 170 similar to that shown in FIG. 21, but with a pair of radial sleeves 150 angularly rotated through 180 ° and aligned coaxially in a longitudinal axis 171 that intersects the center axis 172 of the clutch hub 170. The clutch 170 of FIG. 22 is particularly suitable for joining the ends of the spacers into axially aligned connections as shown in FIG. 30. For this and other reasons, the distance d from the hub hub axis 172 to the base wall of the sleeve recess (corresponding to the surface 152) is the same for the two sleeves 150 of the coupling 170 of FIG. 22, as for the single sleeve coupling 160 of FIG. 21. This geometric relationship is also applied to the various coupler variants shown in the drawings. In all cases, the spacer is secured in the recess of the clutch sleeve, located at a fixed, predetermined distance d from the central axis of the clutch hub.

In FIG. 23, a clutch 180 is also shown that is also provided with two sleeves 150. The sleeves 150 are aligned with radial axes 181 intersecting the center axis 182 of the hub 185 positioned perpendicular to these radial axes 181. The design of the hub 185, the sleeves 150, etc. is essentially the same as described for the couplings 160 and 170. However, in the modifications of FIG. 23, the spacer retaining sleeves 150 are spatially separated at 45 °. The couplings 190 and 200 of FIG. 24, respectively. 25 are equipped with three, respectively. four sleeves 150, grouped along axes 191 and 201, which intersect the transverse centerline 192 and 202 of the hub 195, 205 and the spaces separated at 45 °. As shown in FIG. 23 and 25, the shown couplings comprise central, radially spaced spoke walls 183, 193, 203 that extend radially from the hub center axes 182, 192, 202 and are integrally connected to the base walls of adjacent sleeves 150. The outer walls 184,194, 204 on the other side they project tangentially relative to the hubs 185, 195, 205.

The couplings 210, 220, 230 shown in FIG. 26 to 28, are equipped with five, respectively. six and seven radial sleeves 150, grouped along radial axes 211, 221 and 231 intersecting the center axes and extending from the center axes 212, 222 and 232 of hubs 215, 225 and 235. The individual radial axes 211, 221, 231 are spatially separated at an angle 45 ° as in the case of the couplings of FIG. 23 to 25. The outer walls 214, 224 and 234 of each connector of FIGS. 26 to 28 are preferably arranged tangential to the hubs 215, 225 and 235, for both aesthetic and functional reasons. For example, the outer wall 214 of the coupling 210, in conjunction with the continuing wall of the connected sleeve, forms a wide, flat surface to support the coupling and / or to define the outer edge of the structure.

The coupling 240 of FIG. 29 has substantially the same configuration as in FIG. 1, in this case formed as part of a series of couplings of common dimensions. In this regard, the distance "d" from the hub axis 122 to the recess base wall is the same and uniform as in the other shown coupling shapes.

According to FIG. 30 and 32, the system of the invention includes spacers in different graduated lengths according to predetermined size grades, so that spacers of different sizes in a single kit can be coupled to the described couplings to form rectangular triangular assemblies of assemblies. In the drawing of the assembly of FIG. 30, various series of spacers 140a to 140f are shown, including progressively increasing lengths. This progressive increase is determined such that when any two spacers of a given length join with the clutch to form a rectangular triangle, the spacers of the next larger length are of such a suitable size that they form the hypotenuse of that triangle. For example, in FIG. 32, a right angle three-position clutch 190 is coupled to the two spacers 140a of the smallest size to form a rectangular triangle. The vertically oriented spacer 140a and in the figure is coupled to a four-position connector 200.

The spacer 140a and oriented horizontally is connected to the five-position clutch 210. The spacer 140b, forming the following length step against the spacer 140a, is connected to the couplings 200 and 210.

In FIG. 32, where the spacer 140b forms the prefix of the first rectangular member 250 described above, the spacer 140b simultaneously detaches the other rectangular member 260 of a larger size. In this regard, the connector 200 is coupled to the second spacer 140b to form two hinges of the triangular member 260. The second four-position connector 200 is connected to the upper end of the upper spacer 140b and the spacer 140c forming the third element in progressively increasing lengths is connected to the upper connector 200 and with said connector 210, forming a hypotenuse of the triangular member 260. As shown in FIG. 32, the pair of spacers 140c may gradually form the sides of an increasingly rectangular triangular structural unit 270, the extension of which is formed by a spacers 140 of the closest larger dimension. Thus, progressively larger rectangular triangular structural units may be mounted within the maximum spacer length in the kit.

In the system of the invention, the length of the progressive enlargement of the spacers is formed according to the formula given above. Thus, in a "for example" system of different lengths, the spacer length is defined by the following formula:

L, = / 1,414 / * x D _min - / 2 xd /, where

L _x = length of x th spacer 'in series from 1 to' n ',

Dmin ⁼ distance between the hub axis of the two couplings connected by the shortest spacer in the series, d = distance from the hub axis to the base wall of the sleeve.

The connection of the structures of rectangular triangular units, where the hypotenuse of one triangular unit forms the hinge of the other, larger rectangular triangular unit, is known.

However, in this baby kit system according to the invention, a unique advantage results from the construction of the couplings and spacers adapted to the lateral snap-fit connection of the spacers in the couplings. This allows joining and uncoupling components from the structure without changing the center distances between the couplings and joining points. Thus, the multi-dimensional structure can be constructed and assembled in a very easy manner. As shown in FIG. 30, there is also a preferred geometric relationship between the spacers 140a to 140f of graduated length and the couplings in which the sleeves are formed, oriented at 180 ° to each other. This is particularly true of the couplings 170 in FIG. 22, wherein the two-position clutch has its sleeves 150 aligned on the opposite sides. This coupling preferably serves as an adjustment coupling for joining two shorter spacers into a longer spacer assembly when one of the couplings 170 (which can usually be referred to as an adjustment coupling) is connected to two spacers of a given size, the spacer assembly formed of the same length as a spacer two degrees longer. Thus, as shown in FIG. 30, two of the shortest spacers 140a are joined to form a spacers assembly with spacing length 140c. Two of the next size step spacers 140b are joined to form an assembly of the same length as the spacers 140d. In FIG. 30 shows another corresponding connection. Of course, it is possible to connect spacers of different lengths to adjust spacing assemblies to lengths that differ from the standard progressive spacing lengths shown in FIG. 30. Because all couplings, regardless of the arrangement, use a common distance "d" from the hub axis to the base wall of the recess of the sleeve, the relationship shown in FIG. 30 can be achieved in any situation in which the spacers are connected to the couplings in a coaxial direction.

The assembly shown in FIG. 33 and 34 is comprised of a plurality of single-sleeve couplings 160 (FIG. 21) associated with a plurality of spacers of a predetermined uniform size such as the spacer 140c shown in FIGS. The first of the multi-sleeve couplings 150 (three in the figure) are laterally spaced apart from each other by the width of the coupler and are pivotally connected to the spacers 280 of FIG. 34. The spacer 280 extends through the hub opening 281 where it is loosely received. In conjunction with the first group couplings 282, the second group couplings 283 are provided.

The second group couplings 283 are snapped onto the spacers 280, with the clutch locking lugs 130, 131 firmly engaged in the spacing grooves 144, to firmly clamp the spacers. Thus, while the individual couplings 282 of the first group are freely movable with respect to the spacers 280, the alternating couplings 283 of the second group are firmly secured to the spacers against both rotation and displacement. The sequence of this connection forms a segmented belt structure which may be endless or of finite length as necessary and may be of any suitable width according to the intended purpose. As shown in FIG. 33, the edge portions of the spacers protrude at a short distance on each edge of the belt connection. The construction of the type of FIG. 33 and 34 have a wide range of preferred uses. Among them is the formation of tracks for tracked vehicles such as bulldozers, cranes, tanks and the like. A panel type construction for use in a children's building kit may also be provided, such as wall or roof panels, roofing and the like. For example, a tight connection may be used in cable-type flexible elements.

In FIG. 35 to 41 show a particularly preferred type of coupling arranged to engage another coupling having similar features to form coupling assemblies for connecting spacers extending in multiple planes and directions. The couplings 310 shown in FIG. 35, are formed with four sleeves 150 angularly separated by 45 °. Directly opposite one of the sleeves 150a of each coupling is a special recess 311 of the sleeve. The recess 311 of the sleeve is delimited by spatially separated side guide walls 312, 313 and a transverse bearing wall 314. The side guide walls 312, 313 are spatially separated over a distance equal to the standard clutch thickness and symmetrically arranged in an imaginary plane passing through the geometric center of the clutch 310 and comprising a longitudinal axis of the oppositely disposed spacer 150a. The free surface of the transverse bearing wall 314 lies in a plane which is at right angles to the above-mentioned plane and also extends through the geometric center of the connector 310, through the central axis 315. The connectors 310 are adapted to be joined together in the manner indicated in FIG. 35 to 37 by means of individual special recesses 311 of the sleeves which abut one another, the basic planes of the individual couplings 310 being rotated 90 °. The individual couplings 310 are pushed together until the transverse abutment walls 314 of the socket recess 311 are in close front contact so that the individual central axes 315 of each coupler 310 lie substantially in a common plane. Each of the side guide walls 312,313 is provided, if necessary, with a transverse restraining groove 316 adapted to engage in a locking manner the restraining ribs 317 protruding from opposite sides of the spike walls 319. Thus, when the two couplings 310 are assembled together, they are relatively rigidly interlocked against any separation, except intentional separation.

As shown in FIG. 36, when the side guide walls 312, 313 first engage the protruding retaining ribs 317, these walls 312, 313 expand. A small slot 318 formed in the oppositely positioned collar 150a allows the clamping elements of the collar to be brought closer together while the side guide walls 312, 313 are open ribs 317. When the individual parts are pressed together, to their final position, with the transverse bearing walls 314 seated on top of each other, the seating of each set of restraining ribs 317 in each of the set of restraining grooves 316 is substantially as shown in FIG. 37th

The couplings assembled according to FIG. 35 to 39 provide conditions for supporting the spacers in each of the two planes arranged at right angles. The coupling arrangement thus forms a perfect, suitable connection of the outer corners of the structure, as can be seen in FIG. 38 and 39.

In the assembly of FIG. 40 is a connector 310 of the type shown in FIG. 35 to 39 adapted to be coupled to the second seven-position clutch 410. The clutch 410 includes a special recess 411 aligned coaxially opposite the sleeve 150a to receive the spacer. Assembly of the couplings 310 and 410 to form a multi-plane assembly is performed in the same manner as described in FIG. 35 to 39. The resulting connection is arranged in the form of "T" in a top view as shown in FIG. 41 and creates conditions for mounting the spacers in each of the three planes. In the T-shaped connection of FIG. 40, 41, the upper sleeve 150a is not accessible for normal lateral snapping of the spacer due to the attached coupling. However, by forming a slot 318 in the seating wall of the sleeve 150a, it is possible to first insert the spacer at an angle and to set it in a rotary motion, as previously described. The slot 318 allows easier opening of the clamping elements 126, 127 to accommodate the mounting of the spacer in a rotating manner.

However, in certain applications, it may be desirable to lock the clutch together with the spacer extending through its hub bore to rotate together and / or to secure the clutch in an axial direction with respect to the spacer. For this purpose, the system comprises a drive element as shown in FIG. 42 and 44, for frictional and non-rotatable clamping of the spacer. In the illustrated embodiment, the drive element comprises a drive block 510 made by injection molding of a suitable plastic and preferably comprising a sleeve 150 having the shape already described. The sleeve 150 is mainly provided with opposing locking lugs 130, 131 defining a narrow space between the clamping elements 126, 127. Just close to the closed end of the sleeve 150, a drive pin 511 is preferably mounted on the drive block laterally projecting from the end face 512 substantially parallel to the direction of the locking pins. protrusions 130 and 131. In a typical use of drive block 510, the clutch 240, typically in the form of a complete "snow" flake, is provided with eight spacing engagement positions and mounted on the spacer 513. The drive block 510 is mounted on the spacer body 513 so the locking lugs 130, 131 are engaged and locked in engagement with opposing passage grooves 144 of the spacer 513. Thus, the drive block 510 is fixedly fixed to the spreader 513 against rotation and is also frictionally braked against longitudinal displacement over the spacer 513 (but longitudinally displaceable therewith forces). Such positioning of the drive pin 511 is possible when the clutch 240 and the drive block 510 abut one another and the drive pin 511 is disposed in the trapezoidal space between a pair of adjacent, radially disposed hub-shaped walls 123, substantially filling the space. Thus, the spacer 513 and the clutch 240 are locked against relative rotation so that the rotary drive imparted to one of these elements is correspondingly transmitted to the other element. By placing the drive block 510 on the opposite side of the clutch 240, the clutch may be axially locked in the spacer position.

In FIG. 45 shows a preferred combination drive element 610, pulley / wheel. It is a wheel-shaped injection molded part formed with an outer rim 611 and a central bore 612 adapted to be tightly gripped on the spacer. In the radial direction from the central hole 612 to the edge, on the drive element 610, e.g. one or more drive grooves 613 are formed. They are intended to engage the drive pin 511 of the drive block 510 of FIG. 42. As shown in FIG. 47, the drive element 610 is e.g. a pulley equipped with an annular recess 614 for the pulley function in conjunction with a suitable drive belt (not shown). When it has this driving element

610, the drive pulley is coupled to the spacer using drive block 510 and may act either as a drive pulley or as a driven pulley, as desired. The drive element 610 may be provided with an annular element 620, e.g. tire to create a wheel.

The tire is formed from a resilient elastomer such as neoprene. The inner portion 621 of the tire has a width corresponding to a tight engagement in the annular recess 614. The outer portion 622 of the tire is wider than the inner portion 621, preferably with a width such as the thickness of the outer edge

Flanges 623 are formed on each side of the tire. These flanges 623 engage the outer flanges 624 of the wheel rim to concentrically fit the tire at the outer outer edge 611. If the drive member is a wheel, the wheel may or may not be driven. . When it is to be driven, the drive block 610 is used as already mentioned.

The construction of the children's construction kit according to the invention creates an exceptionally simplified, yet extremely versatile construction means for creating unlimited variety of assemblies of both static and dynamic character. This construction system is perfectly suited for production, namely for economically advantageous mass production by injection molding techniques of standardized construction elements of great variety and enables relatively quick and simplified assembly of various assemblies. According to the basic concepts of the invention, it is possible to create simplified shapes of dynamic assemblies such as belts or belts, driven rotary systems and the like. This is achieved by consistently using standardized spacers and standardized couplings. That is, the couplings utilize standardized sleeves, although varying in number, but which are located within standardized spacings from the base of the coupling axis. Also, the spacers have a standard arrangement of end portions, in conjunction with a body of different lengths. Further, by using an adjusting coupling capable of joining the ends of the two spacers, the design combination available from a relatively limited number of standardized lengths of the individual spacers is multiplied. The components of the child kit according to the invention are readily adapted to the productive production of parts by injection molding from a suitable plastic. There are many suitable plastic materials for this purpose, but it is of course necessary to select a material with a reasonable degree of strength and flexibility to allow the clamping elements to function properly, for example, to perform many joining and disengaging operations. Since the couplings can be joined to the spacers by lateral snapping, it is practical to join large and complex assemblies, as the center span between the couplings does not need to change during joining. Conversely, when assembling the individual elements requires axially inserting one part into the other, the center span temporarily widens, which at best requires great attention, and in the worst case, certain types of assemblies may not be assembled. The arrangement according to the invention creates a unique possibility of two-way clamping between the couplings and spacers, where the extreme flexible portions of the clamping elements form a lateral fit, while the innermost parts of the clamping elements form a relatively stationary recess to retain the flange flange during the lateral connection,

Claims (33)

A children's kit comprising rod-shaped connectors and spacers made of molded plastic and removably interlockable with other elements to form a coherent assembly, wherein at least some of the connectors include a sleeve arranged on a predetermined axis and at least some of the spacers are formed by an elongated rod-shaped body; comprising opposing spacing end portions and intermediate spacing portions integrally connecting opposing end portions, characterized in that the sleeve (14) comprises a pair of spaced apart clamping members (16) substantially parallel cantilevered and symmetrically aligned with respect to the axis (19), wherein first locking means for detachably locking the spacer (13) and firmly holding the spacer (13) in a position aligned with the axis (19) are provided in the clamping elements (16), and second locking means for detachably locking the spacer (13) are provided a pev holding the spacer (13) in a predetermined axial position against its movement along the axis (19), the opposing end portions of the spacer (13) being provided with third locking means for interlocking with the first locking means arranged on the clamping elements (16) and securing the spacer (13) in a position symmetrical to the axis (19) and fourth locking means for interlocking with the second locking means arranged in the sleeves (14) and securing the spacer (13) in a predetermined axial position on the axis (19), each pair of clamping means The elements (16) define a laterally open and axially positioned collar (14) and the clamping elements (16) are resiliently detachable for lateral snapping of the end portion of the spacer (13) in the transverse direction of the basket (19). (14) fixed therein and positioned in a fixed position relative to the sleeve (14). Children's building set according to claim 1, characterized in that the end parts of the spacer (13) have a substantially circular cross-section and are formed by cylindrical clamping parts (28), the distance between the pairs of clamping elements (16) being smaller than the diameter of the circular cross-section. and that the first locking means arranged on the clamping element (16) is formed by a concave groove (18) whose spatial shape substantially corresponds to the shape of a corresponding part of the surface of the cylindrical clamping part (28). Children's building set according to claim 2, characterized in that the coupling (10) comprises a base wall (15) connecting the end portions of the pair of clamping elements (16), the base wall (15) defining a recess together with the pair of clamping elements (16) substantially in the "U" shape for lateral engagement of the end portion of the spacer (13), wherein the cross-section through this recess in the direction of the axis (19) and in the plane separating the clamping elements (16) is substantially coincident with the longitudinal cross-section of the end portion of the spacer (13). Children's building set according to claim 1, characterized in that the second locking means is formed by a convex protrusion (24) which is arranged substantially from one edge of the clamping element (16) to the other and the fourth locking means is formed by an annular groove. (27) in the spacer (113) into which, after the spacer (13) has been inserted into the sleeve (14), engages The locking lug (24) and the spacer (13) are a sleeve (14) locked from separation from the coupling (10) in the direction of the axis (19). Children's building set according to claim 4, characterized in that the spacers (13) have at least part of their length a substantially circular cross-section as well as at least a part of the length of the "X" cross-section whose size is defined by the outline of said circular cross-section. the spacers (13) having an "X" -shaped cross-section have dimensions that allow this part of the spacers (13) to be retained in the space between the pair of clamping elements (16) at the axial position of the spacers (13) at right angles to the axis (19); 13) is tightly mounted between the locking projections (24) on the clamping elements (16) to allow for a force push of the spacer (13) between the pair of opposing locking projections. Children's building set according to claim 1, characterized in that the second locking means are formed by opposing projections (130, 131) arranged transversely on the clamping elements (126, 127) and extending into the space between the clamping elements (126, 127), the spacer (140) has an end flange (26) delimited by an annular recess (147) and an end face (154) spatially separated from the annular recess (147), the annular recess (147) and locking projections (130, 131), surface (152) ) of the base wall (125) and the end surface (154) are in such a geometric relationship that when the spacer (140) is connected to the sleeve (150), the end surface (154) of the spacer (140) is pressed firmly and resiliently in the axial direction with a base wall surface (152) (125). Children's building set according to claim 1, characterized in that the first coupling (70; 310) is formed by a central core (71) defining a centerline of the first coupling (70; 310) and sleeves (82, 83; 150, 150a), arranged substantially radially around the core (71), to receive the spacers (90, 140) has a substantially flat configuration and has a predetermined thickness, further an open recess (74; 311) on one side of the first coupling (70; 130) extending to the central axes and having the same width as the thickness of the first coupling (70; 310), wherein said open recess (74; 311) is adapted to engage the second coupling (70a; 310, 410) to form a composite coupling group with sleeves (82, 83 150) 150a) extending radially in two planes. Children's building set according to claim 7, characterized in that the first coupling (70, 310) has a collar (83, 150a) arranged directly against the open recess (74, 311), wherein in connection of the first and second coupling (70, 70a); 310, 410), the second coupling (70a, 310, 410) has a sleeve (82, 150) for engaging the spacer (90, 140) at the open recess (74, 311) in the first coupling (70, 310) Children's building set according to claim 7, characterized in that the open recess (74; 311) is defined by a pair of spatially separated parallel guide walls (72, 73; 312, 313) for receiving a second coupling (70a, 310, 410) equipped with retaining grooves (97, 316) engaging the retaining ribs (98, 317) of the second coupling (70a, 310, 410) to retain the coupled pair of couplings (70, 70a; 310, 410) in the coupled state. A children's building kit according to claim 9, wherein the first coupling (70; 310) has a plurality of sleeves (82, 83; 150, 150a) each comprising a pair of clamping elements (84, 126, 127) and an edge wall. (79, 80), wherein the edge walls (79, 80) of adjacent sleeves (82, 83, 150, 150a) are tightly and integrally connected and at least one of these edge walls (80) is divided by a slot (81, 318) to facilitate an outer deflection in the diac walls (72, 73; 312, 313) during connection of the first and second couplings (70, 70a; 310, 410) prior to the connection of the retaining grooves (97,316) and the retaining ribs (98,317). Children's building set according to claim 10, characterized in that the first coupling (70, 130) has a sleeve (83, 150a) positioned directly against the open recess (74, 311) and the sleeve (83, 150a) has a split edge wall (80 ). Children's building set according to claim 11, characterized in that the sleeves (82, 83; 150, 150a) are adapted to latch the end portions of the spacers (90,140) and the clamping elements (84, 1236, 127) of the sleeves (83, 150a). they are detachable by means of a split edge wall (80) for attaching the spacer (90, 140) by other than lateral snapping. Children's building set according to claim 7, characterized in that the open recess (74, 311) is provided with retaining grooves (97, 316) and the parts of the first coupling (70, 310) opposite the open recess (74, 311) are provided with retaining grooves (74, 311). the ribs (98, 317) for engagement with the retaining grooves (97, 316) for locking engagement of the pair of couplings (70, 70a; 310, 410) in the coupled state. A children's building kit according to claim 7, characterized in that the first coupling (310) has a plurality of sleeves (150, 150a), each comprising a pair of clamping elements (126, 127) and a bearing wall (314), wherein the bearing walls (150). 314) adjacent sleeves (150, 150a) are tightly and integrally connected and at least one of said sleeves (150a) is arranged directly opposite the open recess (311) and that the other sleeves (150) are uniformly arranged on the same side of the plane containing the open a recess (311) and said sleeve (150a), wherein if the first coupling (310) is connected to a second coupling (310, 410) that is in a plane in which the axes of their sleeves (150, 150a) are, then the planes of both couplings (310,410) are perpendicular to each other. A children's building kit according to claim 14, characterized in that the first coupling (310) comprises one sleeve (150a) positioned directly opposite the open recess (311) and all other sleeves (150) on one side of the plane containing the one sleeve (150). 150a) and said recess (311) are arranged at right angles to the plane of the first coupling (310). A children's building kit according to claim 15, wherein the coupled pair of likewise arranged couplings (310) defines a rectangular corner assembly. Children's building kit according to claim 15, characterized in that the second coupling (410) comprises one sleeve (150, 150a) in an array with an angle greater than 180 °, the pair assembled from the first and second coupling (310, 410) defining a "T" -shaped assembly. Children's building set according to claim 1, characterized in that the second locking means comprises locking projections (24) arranged opposite each other on the spaced apart clamping elements (16) and corresponding to an annular recess (27) on opposite end portions of the spacers (13), wherein the locking projections (24) are oriented transversely to the axis (19) to receive a corresponding annular recess (27) during lateral clamping of the end portion of the spacer (13) between the pair of clamping members (16). Children's building set according to claim 17, characterized in that the sleeve (150) comprises an end surface (152) of the base wall (125) integrally arranged with the clamping elements (126, 127) and separated from the locking projections (130, 131), area (154) 6 of the spacer (140) is separated from the corresponding annular recess (147), the distance between the locking lugs (130, 131) and the end surface (154) of the spacer (140) being such relative to the distance between the annular recess (147) and a surface (152) that the end surface (154) and the surface (152) are pressed into close contact when the spacer (140) is engaged in the sleeve (150). A children's building kit according to claim 1, characterized in that the second locking means comprise rib-like locking protrusions (24, 130, 131) on one of the sleeves (14, 150) or the spacer (13, 140) and corresponding annular recesses (27, 28). 147) on the other of said sleeves (14, 150) or spacer (13, 140). Children's building set according to claim 20, characterized in that the sleeve (14, 150) has a closed end formed by the end surface (152) of the base wall (125, 125), the spacer (13, 140) having an end surface (154), the second locking means formed by the projections (24, 130, 131) and the fourth locking means formed by the recess (27, 147) press the end surface (152) into close contact with the end surface (154). Children's building kit according to claim 1, characterized in that the coupling (160) comprises a hub (161) with a transverse bore (163) having a size and shape for axially clamping the spacer (140) and defining a hub hub axis (164), The hub (161) is disposed at right angles to the longitudinal axis (165) of the sleeve (150) intersected by the clutch (160) and includes a single sleeve (150) integrally connected to the single hub (161). A children's building kit according to claim 1, characterized in that the coupling (170) comprises a pair of sleeves (150) integrally connected to a single hub (161), wherein the sleeves (150) are aligned oppositely and aligned along a common axis (171). the sleeves (150). Children's building kit according to claim 1, characterized in that the coupling (180, 190, 200, 210, 220, 230, 240) comprises two to eight sleeves (150), wherein the longitudinal axes (181, 191, 201, 211, 221, 231, 241) of the two adjacent sleeves (150) are arranged substantially at an angle of 45 ° and all of these axes (181, 191, 201, 211, 221, 231, 241) intersect with each other in the axis (182, 192, 202) , 212, 222, 232,242) charges (185,195,205,215, 225,235,122). Children's building set according to claims 23 or 24, characterized in that all the sleeves (150) are arranged at a fixed, predetermined distance (d) from the hub axis (182, 192, 202, 212, 222, 232, 242). 185, 195, 205, 215, 225, 235, 122), wherein when the spacer (140) is held in any sleeve (150), the distance of the furthest end of the spacer (140) from the axis (182, 192, 202, 212, 222 , 232, 242) hubs (185, 195, 205, 215, 225, 235, 122) fixed and uniform. A children's building kit according to claim 25, characterized in that it comprises a series of spacers (140 _a - _f ) in graduated lengths, wherein the length L 1 of each spacers (140 a _. F) is given by the formula: L _x = / 1,414 / * '' x D _min - / 2 xd /, where L _x = the length of the xth spacer from the series 1 to "n", where n is the total number of different spacer lengths (140 _a . _F ), D _min ⁼ distance between the hub axes of the two couplings connected by the shortest spacer in the series from the hub axis to the base wall of the sleeve portion, wherein the connectors and spacers of the kit are adapted to be joined to at least one rectangular triangle (250, 260, 270). Children's building set according to claim 26, characterized in that the assembly comprises a coupling (170) with a pair of sleeves (150) connected to two spacers (140b) of length L _x in series, having the same length as the spacers (140d) of length L _{(x + 2)} in this series. Children's building set according to claim 1, characterized in that the clamping elements (16) are provided with rib-like locking lugs (24) extending transversely with respect to the axis (19) of the sleeve (14) and extending inwardly towards the axis (19) of the sleeve ( 14), wherein the spacers (13, 513) are provided in a predetermined region between their ends oppositely disposed longitudinally extending grooves (39) and the spacers (13) are received in the sleeve (14) at an angle of 90 ° to the sleeve axis (19) (14), wherein the rib-like locking lugs (24) are engaged by an opposed pair of grooves (39), the spacer (13) being non-rotatably clamped by the coupling (10) at a position perpendicular to the axis (19) of the sleeve (14). Children's building set according to claim 28, characterized in that the coupling (10, 160) comprises a hub portion with a transverse bore of size and shape for axially clamping the spacer (280) and defining a hub axis (164), wherein the hub axis (164) the hub (161) is arranged at right angles to the basket (165) of the sleeve (150) and substantially intersects it, the other couplings (282, 283) being coupled to form a belt assembly, wherein the first group couplings (282) are arranged laterally one next to the other, with spatial separation at least equal to the width of the coupling, wherein the hub axes (164) of each first group coupling (282) are axially aligned and wherein the first spacer (280) passes the hub of each first group coupling (282); the couplings (283) of the second group are arranged laterally one next to the other and distributed in the spaces between the couplings (282) of the first group, wherein the couplings (283) of the second group clamp the first spacer (280) by ribbed locking lugs (130, 131) into an opposing pair of longitudinal grooves (144) of the first spacer (280) and further comprising additional groups of couplings and spacers joined in elongated series to form a belt-shaped link assembly. Children's building kit according to claim 29, characterized in that the spacer (280) is of a length relative to the resulting width of the first and second couplings (282, 283) such that lateral end protrudes from each side of the coupler assembly (282, 283). part of the spacer (280). Children's building set according to claim 28, characterized in that the drive block (510) is provided with an integral, laterally projecting drive pin (511) and is attached to the spacer (513) by ribbed locking projections (130, 131) engaged in opposing grooves. (144) a spacer (513), the drive block (510) being locked in a fixed relationship with the spacer (513), the additional clutch (240) being slidably mounted on the spacer (513), wherein the drive pin (511) is in the drive coupling to adjacent parts of the additional coupling (240), the coupling (240) driving the spacer (513). A children's building kit according to claim 31, characterized in that it comprises a circular, wheel-shaped drive element (610) with an inner rim (611) and a hub, wherein the hub is provided with a spacer spacing central bore (612), the drive element (610). 1) is provided with a drive groove (613) disposed at a specified distance radially from the center of the hub for engaging the drive pin (511) of the clutch (510), the drive element (610) having an outer peripheral annular recess (614) formed. SK 279903 Β6 Children's building kit according to claim 32, characterized in that an annular tire-shaped annular member (620) of removable elastomer is mounted in the annular recess (614). 14 drawings Fig. 7 FIG. 8. FIG. 9th SK 279903-6 Fig. 10th