DK141126B - Stiffening member for a structural member. - Google Patents

Description

(11) PUBLICATION MANUAL 141126 DENMARK «*> intci.'ε oi c s / οβ • (21) Application no. 5579/75 (22) Filing on 5 Oct. 1973 (23) Life Day 3 Oct. 1973 (44) The application submitted in accordance with the prospectus' published on 21. Jan. 1980 DIRECTORATE OF. .

THE PATENT AND TRADEMARK BASIS <* »Priorit« begot from it

Oct 4 1972, I2777 / 72, SE

<71> HIS CHRISTER GEORGII, Rindoegatan 42, 115 35 Stockholm, SE.

(72) Inventor: Same (74) Clerk of the case:

The company Chas. Hate. ____ (B4) Stiffening member for a structural element.

BACKGROUND OF THE INVENTION 1. Field of the Invention The invention relates to a stiffening member for a structural member and consisting of threaded threads that follow the contour of a conceived tubular body.

It is known to produce beam or mast-like structures by winding rod or wire material in helical form around a number of longitudinal rods to which the rod or wire turns are attached e.g. by welding. It is also known to produce reinforcement for concrete structures by winding thread in screw form over various groups of longitudinal reinforcing bars, but this construction is not in itself supportive but must be used in conjunction with large amounts of concrete.

2 141126

The object of the invention is to provide a stiffening member of the kind suitable for use in a load-bearing plate structure, such as a load-bearing tire, especially in the manufacture of sandwich structures.

The stiffener according to the invention is characterized in that the threads are wound in several different webs, each containing several threads, and which follow the contour of each conceivable tubular body, whose cross sections have straight sides, so that the thread portions in said sides form straight stiffeners. wherein the webs are arranged so that sides of their cross-sections are coincident, and the straight threads in these sides of the webs are interconnected at intersecting points.

Such a stiffening member forms a rigid mat or plate which acts as shear force transmitting element, the interconnected straight strands forming stiffeners in the interconnecting wire webs together constituting a grid of struts capable of transferring forces from one side of the stiffening member to the other side. The lattice works of stiffeners can be considered as rigid discs which stiffen the supporting structure.

As stated in claim 2, the straight sides lying between the collapsed sides of the wire webs can steplessly overlap, thereby forming a support for a plate-shaped structural element, and the embodiments described in claims 3 and 4 constitute stiffening means which can be used respectively to produce a plane bearing plate construction or a curved plate-shaped element.

The stiffener according to the invention can be conveniently used in a sandwich construction, as can be seen in claim 5.

Furthermore, these embodiments may also be applicable to other forms of curved structural elements which may be both single curved and e.g. can be used in the construction of boat hulls, bodywork and airplane wings.

In order to increase the bearing capacity of the stiffener, it can according to the invention be designed with longitudinal rods as claimed in claim 6.

3 141126

The invention will be explained in greater detail in the following with reference to the drawing, showing some embodiments of the stiffener according to the invention cooperating with structural elements.

In the drawing, FIG. 1 and 2 show two different embodiments from one end; FIG. 3-5 schematically still three embodiments also seen from one end; FIG. 6 and 7 show two further embodiments from one end and constituting a helical wire carrying structure; 8-10 diagrammatically show three further embodiments of a supporting structure shown in cross-section and fig. 11 the upper side of a supporting structure.

In the embodiment shown in FIG. 1, wires are twisted in four different lanes 1-4 with several wires in each lane, the wires in all lanes 1-4 being twisted in the same direction. Each web follows the contour of a straight-sided section 5-8 which, in the embodiment shown, is square, but as e.g. also may be rectangular, triangular or trapezoidal. The thread sections in the right sides of the sections 5-8 form the right stiffeners. The threads in all sections usually have the same cross section, but it will be understood that they can also have different cross sections. Usually, the wires are made of iron, but they can also be made of other material, such as aluminum, the aluminum wires may be provided with hollows for reducing weight and material consumption.

The sections 1-4 with the straight sides 5-8 are arranged in such a way that opposite sides 5 and 7 are joined together, and the straight threads on adjacent sides 5 and 7 are e.g. by welding interconnected in coinciding points.

The sections 1-4 with the straight sides 5-8 are arranged in such a way that the straight sides 6 between the adjacent sides 5 and 7 of the adjacent sides 5 and 7 integrate seamlessly and together form the substrate for one with the threads in these sides connected plate-shaped structural element 9, which may consist of a disc, plate or similar layer. The plate-shaped element 9 is e.g. by welding, gluing or with clamps attached to the wires in the substrate consisting of the sides 6, thus stiffening the very surface of the element 9 · In the drawing, the sides 6 are shown lying in a common plane, thus forming a support for it with the wires in The sides of the flat structural element 9 · The right sides 6 can, according to another embodiment, form angles with one another, whereby they together form the basis of a curved plate-shaped structural element connected to the threads in the sides.

In the embodiment of FIG. 1, the straight sides 8 of the sections 1, which are opposite to the straight sides 9 to which the structural element 9 is attached, are arranged so that they form a support for another plate-shaped structural element 10. The right sides are connected to the wires in these sides. 8 is shown in the drawing lying in one and the same plane, forming a support for a flat structural element 10 which is parallel to the plane element 9.

In the embodiment of FIG. 2, each lane 11-14 of the coiled wires follows the contour of a rectangular section 15-18 which is rectangular without being square. In addition, the embodiment of FIG. 2 only from the embodiment of FIG. 1, in that the planar structural member 10 is replaced by longitudinal structural members 20 consisting of rods or similar parts. These elements 20 are connected to the wires, wherein the sides 18, which lie opposite the sides 16 with the planar structural element 19, are infinitely intertwined, i.e. in the middle of the adjacent and interconnected sides 15 and 17. In addition, the elements 20 are arranged at the outer edge of the sides 18 at the lanes II and 14.

The embodiment of FIG. 3 differs from the embodiment of FIG.

1 only in that the webs 21-27 of the coiled threads follow the contour of triangles instead of squares. The arrows in the figure serve to show that the threads in all lanes 21-27 are twisted in the same direction. By 29 and 30, the flat, plate-shaped structural elements are associated with the spiral mat.

At least one of these elements may be replaced by structural members corresponding to the rods 20. In the embodiment of FIG. 4, the webs 31-35 of the coiled wires in the same direction follow the contour of trapezius, the flat coil mats produced by these wires being connected to the two flat, plate-shaped structural members 39 and 40.

Also in the embodiment of FIG. 5, the webs 41-48 of the coiled wires in the same direction follow the contour of the trapeze. However, these trapezes are arranged in relation to each other such that the straight sides between the adjacent, interconnected sides form an angle to each other and together form a support for a pair of the tubular structural members 49 and 50 connected to the wires in these sides. Other embodiments with both single-curved and double-curved structural elements can of course also be considered.

The webs winding in webs do not always have to follow the entire length of the coils along the contour of the same straight-sided section, but in some cases, said section can be changed, especially with regard to stiffening single and double curved structural elements. Thus, changes can occur by changing the rise of the spirals. The change can also be made by changing the cross-section of the core on which the coils are wound during twisting. In addition, the contour can of course be changed by changing both the core and the rise of the spirals. The embodiment of FIG. 5, e.g. exposed to such change. Hereby, the size of the trapezoidal sections is successively reduced or increased, so as to obtain a mast structure or similar object with a cross section decreasing towards one end.

Each spiral system consists of several strands. The number of threads in the spiral system depends on the cross-section of the threads, the desired rise and the bending length. The appearance of the section is determined by the distance between the structural elements at the two sides, the desired stiffening effect and the distribution of longitudinal and lateral moments. Thus, for example, the triangular shape allows the transfer of large moments in the lateral direction.

A large number of threads give it a large surface stiffness with these bonded layers which allows a smaller thread diameter.

141126 6

In the manufacture, the spiral mat is first manufactured, thus joining adjacent spirals by welding or similarly at the contact points. Then attach one disc or plate to the spiral mat. In the next phase, the second structural element is secured to the spiral mat. The finished construction can be easily filled with a mass of material such as urethane foam.

The supporting structure of FIG. 6, like the other embodiments shown, has a rectangular cross section. The supporting structure includes two multithreaded systems of coiled wires, the wires 52 in one system being wound in one direction and the wires 53 in the other system being wound in the other direction. The metal wires 52 and 53 of the two systems preferably have the same cross-section, but the wires 52 and 53 may also in some cases have different sized cross sections.

The threads 52 of one system are wound in a web that follows the contour of the rectangular section of the supporting structure, the thread portions of the sides of the structure forming straight stiffeners. The threads 53 of the second system are wound in several separate webs 54-58, each of which follows the contour of a rectangular section, the thread portions of the sides of the sections forming proper struts. The rectangular sections of the webs 54-58 together completely fill the cross-section of the supporting structure, the sections 54-58 sides joining one another and the sides of the supporting structure section.

The wires 52 and 53 of the two systems are e.g. by welding connected to each other in coinciding points. In addition to wires 52 and 53, the carrier also includes longitudinal metal bars 59 'which are located at least at the corners of the cross-section of the structure. However, longitudinal bars 59 may also be arranged at common corners of such sections 54-58 which together completely fill the cross-section of the supporting structure.

As shown in FIG. 6, the wires 52 of one system are externally mounted relative to the longitudinal bars 59 of the supporting structure, while the wires 53 of the other system are internally mounted relative to the longitudinal rods 59.

For example, the number of threads 52 in the multithreaded coil enclosing the entire cross section of the carrier structure may be seven, while each coil 54-58 may include two threads 53. The number of threads 52 in the enclosing coil depends on the geometric shape of the cross section of inner spirals 54-58 and the number of threads in these inner spirals. For example, the structure may be designed such that the adjacent spirals meet in adjacent corners and that a longitudinal rod 59 strikes at the same point. At the same crossing point, one of the surrounding spiral wires is also connected so that a spatial grid is obtained, i.e. an in-room static design system.

As the longitudinal rods 59 are spread over the supporting structure, loads towards its center can be easily absorbed partly by putting the adjacent pull and thrust rods into operation and partly by the spatial grating distributing the load on adjacent rods so that a distribution of the effects of the load and the entire construction are forced to contribute.

The embodiment of FIG. 7 differs substantially from the embodiment of FIG. 6, in that the wires 53 of the second system are twisted in several separate webs 60-68, each of which follows the contour of a triangular cross-section. These triangular sections 60-68 together complete the entire rectangular cross-section of the supporting structure, which is provided with longitudinal rods only at the corners 59 · Here, only the spirals make the lateral load distribution without two pull and thrust rods. 59 ·

The supporting structure of FIG. 7 consists of seven strands 52 ', while each of the spirals 60-68 includes three strands 53 · Also in this case there is a spatial grid. A concentrated force towards the center of the structure is transmitted to the longitudinal bars 59 »by the tensile and compressive forces being transmitted in the wire mesh formed by the spirals on the upper or lower side of the supporting structure, respectively. The 60-68 bars of the inner spirals in the vertical plane transmit transverse forces between these two planes.

In one embodiment, the load-bearing structure is made up of only two systems of coiled wires 52 and 53 · One of several wires 52

Claims (2)

Thus, existing enveloping spirals are filled in with several threads 53 consisting of small inner spirals. In FIG. 8-10, it can be seen that the inner coils 53 can be varied in many ways within the space enclosed by the outer coil 52. Thus, the inner coils 53 can be of different sizes, as shown in FIG. 9, wherein all inner spirals have a rectangular cross section. The inner spirals can have different shapes, while the other inner spirals have a triangular cross section. The number of longitudinal bars 59 may also vary within wide limits. From the arrows in FIG. 8-10, it will be seen that only the outer coil 52 is twisted in one direction, while all the inner coils 53 are twisted in the other direction. The supporting structure, the upper side of which is shown in FIG. 11 may be of the nature shown in FIG. 8 and 9. The sides of three inner spirals 53 thus join the upper side of the supporting structure, which is determined by the outer spiral 52. The reference numeral 59 denotes rods extending at the longitudinal edges of the upper side. At least part of the coils 53 may be filled with insulation. The insulation may consist of loose wool filled in plastic bags. The bags are introduced into the structure under vacuum, so the insertion can be easily performed. When the vacuum is raised, the at least partially elastic insulating material fills the space of the structure well. Claims. A stiffener for a structural member and consisting of helically wound threads that follow the contour of a conceived tubular body, characterized in that the threads are wound in several different paths (1-4, 11-14, 21-27, 31-35 , 41-48, 54-58, 60-68), each of which contains several threads, and which follows the contour of each conceivable tubular body, whose cross sections have straight sides (5-8, 15-18), so that the thread portions of said sides form proper stiffeners,