HU201835B - Frame structure particularly for children's climbing device - Google Patents

Abstract

FIELD OF THE INVENTION The present invention relates to a scaffold structure, in particular a children's climbing device, comprising tubular cylindrical connecting members and spherical node elements for receiving and securing the fasteners. It is an object of the present invention to provide node elements (2) with holes (9,10,11) and axes (9,10,11) (9,10,11) for the spatial coordinate system axes of the connecting elements - tubes (1), receiving the spatial coordinate system. (19) are provided with additional holes (13,16,17) to accommodate the perpendiculars (15, 20, 21), and the grid structure of the connecting elements (1) and the node elements (2) for the connecting elements - pipes ( 1) fixed tab elements (4, 5) and support legs (3) connected to the node elements (2). (Figure 1.2) Scope of the description: Page 3, Figure 2 EN 201 835 B -1-

Description

BACKGROUND OF THE INVENTION The present invention relates to a scaffold structure, in particular a child climbing cage, having tubular cylindrical coupling members and junction members for receiving and securing the coupling members.

We have encountered various scaffolding structures in many areas of everyday life. construction, maintenance, furniture and other installation structures where the bars are connected by clamps, straps, overlaps and other similar joints.

A common drawback of known releasable joints is that multiple clamps are required to form a suitable fastener. A further disadvantage is that the devices used generally allow only two elements to be connected to each other. Thus, the connection of more than two bars can only be achieved by means of rather complicated structures.

Node elements are known which allow multiple rods to be connected together. Such nodal elements are described e.g. see HU 183 674; U.S. Pat. The two elements are connected by a screw and this screw also secures the pipes and rods placed in the node element. The disadvantage of such a node element is that it is very expensive to produce due to the complicated inner arched nest.

The design of another node element is described in U.S. Pat. patent. It is a polygonal element with several threaded holes. Threaded rods are inserted into these threaded holes.

The disadvantage of such a design is that it is primarily suitable for use only for exhibition purposes and that the connection is made by means of threaded pipes, which further increases the cost.

A node design is also disclosed in U.S. Patent No. 183,642. Patent Specification comprising at least one mounting hole, two or three, but optionally several inlet holes perpendicular to and / or deflecting from each other, having recesses of a shape and position perpendicular to the perforations and axially clampable formed.

The disadvantage of such nodal element design is that its production is also expensive and its area of use is also limited.

It is an object of the present invention to provide a scaffold structure, including a junction member, which eliminates the disadvantageous properties of known scaffold structures and junction members, which can be easily and cheaply produced and which can be widely used anywhere.

This object is accomplished by a scaffold structure having nodes and bores in the direction of the axis of the spatial coordinate system that receive the connecting elements - tubes - and other bores having anchors perpendicular to the axes of these bores, it has filler plate elements fixed to the connecting elements - pipes - and support legs connected to the nodal elements.

In a preferred embodiment of the scaffold assembly according to the invention, the fasteners, which may be fastened to the connecting elements - tubes - are optionally threaded, which are preferably screws with an internal key hole.

In another preferred embodiment of the scaffold according to the invention, the panel members are provided with two asymmetrical connecting members at their parallel edges.

It is provided with a cylindrical cut-out along its component member, which is provided with an internal socket for receiving the connecting elements of the scaffold structure, and with a pin fixed to the flat element on the outer part of the socket.

In a further preferred embodiment of the scaffold structure according to the invention, the panel elements have different openings, e.g. they are provided with an opening corresponding to the child's shoulder width.

In a preferred embodiment of the scaffold according to the invention, the panel members are plastic sheets and the connecting members are provided with a protective coating.

A preferred embodiment of the scaffold according to the invention will be described in detail with reference to the accompanying drawings, in which:

Figure 1 is a schematic view of an exemplary scaffold structure of the invention, a

Figure 2 is a schematic view of a node member of the scaffold structure of Figure 1, a

Figure 3 is a sectional view of the node element taken along the plane A-A of Figure 2, while Figure

Fig. 4 is a side view of a coupling member of the panel members of the scaffold assembly of Fig. 1.

Figure 1 shows a schematic view of a scaffold structure according to the invention. The scaffold structure according to the invention consists essentially of pipes 1, nodes 2 which connect the pipes 1 and fasten them in their desired position, and plate elements 4 and 5 which fill the grids of the grid structure formed by the pipes 1 and nodes 2. At least one of the panel elements 5 is formed with an opening 6 having a diameter corresponding to the child's shoulder width.

The grid structure of Figure 1 is also provided with support legs 3 which serve to enhance the stability of the grid structure.

The nodal element 2 is spherical and has bores 9, 10 and 11 with axes including spatial coordinate axes (Fig. 2). In the junction element 2, further holes 13, 16 and 17 are formed perpendicular to the axes 14, 18 and 19 of the holes 9, 10 and 11, which are placed in the holes 13, 16 and 17 inserted into the node element 1. pipe fastening elements, which are preferably screws with an internal key hole. The axes 15,20 and 21 illustrate the axes of the bores 13,16 and 17.

Figure 3 is a sectional view taken along the plane A-A of the junction element of Figure 2. The figure shows clearly the bore 9 receiving the tube 1 and the

-2EN 201835 Β Relative position of the 13 bore holes for receiving the respective pipe clamps. The axis 15 of the bore 13, which is a threaded bore, is perpendicular to the axis 9 of the bore receiving the tube 1, the axis 15 of the two bores 13 is parallel to one another and symmetrical to the center of the node element 2.

Fig. 4 illustrates the construction of a coupling element 7 for fastening the lattice sections of the lattice structure formed by the tubes 1 and the junction elements forming the scaffold structure according to the invention.

The coupling member 7 is formed by a cylindrical shell cut out along its component and receiving the tube 1 and a pin 8 on the outside of the receptacle 22 on the opposite side of the tube 1.

The construction of the scaffold according to the invention from the elements listed and described can be accomplished as follows:

Insert the tube 1 into the hole 9 of the node element 2 and insert the fastener 13 into the holes 13 which are perpendicular to the axis 14 of the hole 9 and screw the tube 1 inwards into the hole 13 and press the tube 1 in the hole 9 .

Then, the fastening element in the other bore 13 is tightened to fix the tube 1 in the bore 9.

The next tube 1 is then inserted into the bore 10 and meets the component of the tube already inserted and fixed inside the node element 2. The newly inserted tube 1 is secured by means of a fastening element in the bore 17.

The next tube 1 is then inserted into the bore 11 of the node element 2, which also meets the periphery of the tube 1 fixed inside the node 2 in the first step. This post-inserted tube is secured again by means of the fastener in the bore 16. At this time, tubes are formed from the nodal element 2 in the direction of the three coordinate axes of space.

The lattice structure is continued by the appropriate multiplication or clustering of the tubes 1 and the nodal elements 2 l until the desired lattice structure is formed.

Once the grid structure has been completed, the grid spaces can be filled as desired. This is done by the 4 and 5 panel elements. For securing the panel members 4 and 5 to the tubes 1, two coupling members 7 are provided on two parallel sides facing each other. The coupling elements on the two parallel edges have an asymmetrical arrangement, which allows the overlapping grid spacing of the grid structure to be covered, since the coupling elements 7 do not obstruct the coverage.

The panel element (s) 5 have different openings 6, e.g. it may have a circular opening corresponding to the child's shoulder width.

In the manner described above, various structures adapted to the particular requirements may be provided in accordance with the present invention.

From the aesthetic point of view, the pipes 1 of the lattice structure and optionally the nodal elements 2 are provided with various protective coatings. This protective coating can be made e.g. epoxy spray.

The sheet elements 4.5 of the lattice structure are preferably made of plastic sheets of different colors.

The main advantage of the scaffold structure according to the invention is that it has a wide range of applications, is cheap to manufacture and easy to assemble at any location.

Claims (8)

A scaffold structure, in particular a child climbing cage, having tubular cylindrical couplers and spherical nodes for receiving and securing the couplers, characterized in that its nodal members (2) are arranged in the direction of the axes of the spatial coordinate system to receive the connecting elements (1). (9,10,11) and further bores (13,16,17) having anchors (9,10,11) perpendicular to the axes (14, 18, 19) of the said holes (14, 18, 19), and the sheet members (4, 5) for filling the lattice structure of the connecting elements (1) and the node elements (2) fixed to the connecting elements (1) and the support members (3) connected to the node elements (2). The rack structure according to claim 1, characterized in that the connecting elements inserted into the node elements (2) have in particular fastening, optionally threaded fastening elements for fixing the pipes (1), which are preferably screws with an internal key hole. A rack structure according to claim 1 or 2, characterized in that the panel members (4,5) are provided with two asymmetrical switching members (7) along two parallel edges. Rack structure according to Claim 3, characterized in that it is cylindrical in shape, cut along the member of the coupling element, from the inner receptacle (22) receiving the connecting elements of the scaffold, in particular the tubes (1) and the outer part of the receptacle (22). 4,5) is formed from a fixed pin (8). 5. A scaffold structure according to any one of claims 1 to 4, characterized in that at least one panel element (5) is provided with an opening (6) of a size corresponding to the child's shoulder width. 6. A rack structure according to any one of claims 1 to 4, characterized in that it has plastic sheet elements (4,5). 7. A scaffold structure according to any one of claims 1 to 3, characterized in that its connecting elements, pipes (1) are provided with various protective coatings. Rack structure according to claim 7, characterized in that its connecting elements, pipes (1) are provided with a protective coating formed by epoxy spraying.