DE841351C - Shell body node connection for bar structures - Google Patents

Description

Shell body node connection for bar structures As connecting elements for rod structures, e.g. B. tubular steel scaffolding, node body are known in which the longitudinal axes of all rods that are connected to such a body, themselves cut in one and the same point. These connecting bodies consist of solid balls, which have centrally drilled, threaded holes for the rod connections, in which the centrally located in the conically tapering rod ends, threaded bolts that can be unscrewed in the direction of the rod longitudinal axes are screwed in. These threaded bolts, the heads of which sit inside the rod tube ends and these against Tighten the spherical bodies using key nuts that can be slid on the bolts twisted so that these screw connections are in front of the solid ball pieces and are easily accessible.

Furthermore, for half-timbered structures, which are made of pipes or the like. exist, also known shell-like or ring-like connecting pieces, which at least have a spherical shape at the fastening points of the tubular rods, so that the rod axes too of all those rods that are against such a cup-shaped or ring-shaped connector be screwed tight, intersecting at one point. The inside and outside surfaces of the spherical part of each connector have a common one Focus. These connecting pieces are completely open shell bodies on one ring side, so that the bolts with which the bars are tightened, comfortably put through holes of this body from the inside to the outside and their heads, which lie against the inner surface of the body, easily accessible with a Wrenches can be handled.

While the former are made with full ball knot pieces 'The scaffolding is ideal for assembly scaffolding that can be assembled and dismantled quickly mainly scaffolding built with the bowl-shaped or ring-shaped connecting pieces intended for the construction of tall and light masts, i.e. rod structures that do not have any have to endure great loads and 'where at each connector only few bars are connected.

In contrast to 'these two well-known node connection bodies the shell bodies of the present invention have the following advantageous properties: a) They are relatively thin-walled in order to save weight, but for transmission Sufficiently resistant to the greatest possible bar forces, closed on all sides Shell bodies, which are located in their cavity, on their inner wall adjacent wider parts (heads, edges or wedges) of the connecting means completely envelop so that both rods and almost all parts of the surface of each shell body, can be connected not only to a ring surface, as well as in cases in which each rod end only has a single connector on the shell body is tightened, all fasteners are deprived of all sight (every sight) and before any access by unauthorized hands, e.g. B. by children or saboteurs secured are, i.e. the stability of the rod scaffolding or rod structures not through solution is endangered or even destroyed by fasteners.

b) In contrast to the full ball knot pieces, they have both on their outer surface for the connection of the rod ends or heads as well as their inner surface for the attachment of the heads, edges or wedges of the fasteners appropriately shaped contact or mating surfaces which are directed in such a way that they, if they are flat, they are perpendicular to the relevant longitudinal center lines (Rod axes) or, if they are bulbous or hollow or angularly broken, 'those each of these contact surfaces at the intersection of the relevant rod longitudinal center line An imaginary plane applied tangentially is perpendicular to the relevant longitudinal axis of the member. Such bulky or high surfaces can be spherical, ellipsoidal or parabotoid be.

c) Your body cavity is dimensioned so large that on the inner surface of the shell the wider parts of the lanyard even then without interfering with one another lie on and be gripped well with a suitably shaped tool can, if the longitudinal center lines (axes) of closely spaced bars a much more pointed Form an angle of 4s ° with each other. d) They persist, especially if they are only intermediate or very small size, in contrast to the second-mentioned shell- or ring-shaped connecting pieces, for the purpose of easy gripping of the connecting means with the help of a tool made of partial shells, which are also the wider parts of the connecting means completely enclose and precisely fitting and interlocking edges have, so that the shell parts are not against each other under the pressure of the rods but, held together by fasteners, like a act as a single solid body.

e) In special cases, the shell bodies have the shape of a split or undivided spherical shell, which for a versatile connection of any Spatial directions merged rods the cheapest and practically the best shape represents, because on such shell bodies the necessary connection holes that sit at different points for each junction connection into the finished ones Shells can be drilled into them after a precise angle calculation beforehand can, whereby it is achieved that each shell body with stable bar structures only receives as many drill holes as are absolutely necessary. It is also closed Tubular rods the most suitable and technically most beautiful shape, the spherical or ellipsoidal shape Peel.

f) In the case of larger and large rod structures, the shell bodies are given in all cases in which the rods are connected with only one connector each additional small holes to accommodate pins, smaller screw bolts or of relatively small rivets that either secure themselves against Form rotation and detachment of the rods or hold such securing means.

g) For larger and large rod structures, the edges of the split Shell bodies (spherical shells) made on both shell parts with reinforced walls, with the occurrence of high forces acting on the body that are in themselves generate strong tangential tensile or compressive forces at the edges, in these No cracks or dents can appear on the edges. These margins are at appropriately relocated to the inside for larger bodies.

Such shell body node connections are in two drawing sheets shown in various examples, namely the Fig. t and 4 angular Shapes of the shell bodies a and b with flat contact and abutment surfaces inside and outside, against which the heads of the connecting means, z. B. screws, or the rod heads a and 3 but spherical shell bodies c and d with spherical Contact surfaces inside and outside. These figures are cross-sections through the Intersection of the rod longitudinal center lines and show split body shells with inwards or outwards protruding edges. Fig. 3a shows the one for drawing vertical cross-section through the connection of the upper Rod e Fig. 3. Fig. 5 shows an example of one with rods and such shell bodies built system, namely the skeleton of a horizontal swing.

In A11>. 6 you can see the cross section of a spherical, undivided Shell body f with an opening r, the beaded edge of which is moved inwards and has reinforced \ -Vandung. This body f is an example of the node connections, which are used in larger and large stable metal or steel structures of which Fig. 7 shows an example, namely the system of the above Part of an observation tower with an overhanging platform. Fig. 6 is the right upper node of the front system square under the platform in Fig. 7. Fig. 6a is the cross-section of rod g in Fig. 6 perpendicular to the plane of the drawing, which struck against the outer surface of the upper right hole of this shell body will. Instead of on four supports, as shown in Fig. 7, such bodies can be used a tower standing on three, five, six or eight supports can also be built.

The shell body of this invention, like the figures mentioned show, have different forms of manufacture. Fig. T shows one made from deep-drawn Sheet formed, divided at the bottom, Fig. .4 one formed from metal or cast steel, Split-top shell designed for greater forces. Both bodies a and b have such shaped outer and inner surfaces that each of the outer surface parts, on which the bars connected to the body abut, and each of the inner surface parts, against which the heads or edges of the lanyards rest, is flat and is perpendicular to the longitudinal center line of the rod in question.

Both of these shell bodies in Figs. 4 and 4 have mutually fitting, inwardly protruding edges h and i shaped in such a way that the parts cannot be displaced against one another when fastened. Both parts of the body in Fig. F @@ er <le @ l for example by means of a screw pin /, which at the same time holds the top rod in place. The lower part l of the shell body a in Fig. t is because no rod needs to be connected to it, e.g. designed as a cover, which is attached to rings in by means of two screws, which sit on the horizontally drawn bolt egg.

Easier to manufacture and more useful shell bodies are divided or undivided spherical shells, as shown in Figs. 2, 3 and 6. The exterior and interior surfaces this body are spherical surfaces, which have the advantage that the rods at any Position, except at the edge of the division, and the corresponding holes for Rod fastening at appropriate points after precise angle calculation beforehand can be drilled or punched. The outer and inner surfaces of the shell bodies If necessary, instead of spherical surfaces, surfaces of an ellipsoid or Be paraboloids. For special purposes, one of the spherical shell parts can be attached to a Where the bar connections are free, it can also be flattened to save space it, e.g. B. directly under canvas covers of tents or under roofs or is expedient.

The shell body c of Fig. 2 consists of two spherical shells made of deep-drawn Sheet metal, which on their flanged, outwardly protruding edges o exactly non-slip fit together and be connected with a screw bolt p, which at the same time holding two sticks. The body d according to Fig. 3 consists of two hemispherical shells made of sheet metal or cast metal, which q are soldered or welded to one another at their edges after the rod mounting holes have been previously drilled or punched. One of the two shells has a slightly larger hole through which the necessary Connecting screws with their heads inserted and when screwing the Rods are held in place with a special key. This hole of the cup ball but with a matching cap, similar to that of the shell ball in Fig. 6, to close tightly.

The shell body f in Fig. 6 represents a shell ball made of metal or cast steel with a relatively thicker wall and has at one point an opening s that is so large that for a corresponding special tool there is still enough freedom of movement to tighten the locking means x, and one because of the annular compressive or tensile stress that occurs there has reinforced, inwardly laid, edge s shaped in such a way that this opening with a matching cap t, the z. B. made of sheet metal or metal or cast steel is, can be tightly closed, e.g. B. with a screw u with nut and nut cap. The edge s of this opening r is cast on according to Fig. 6 and is attached to the contact surface edited for the cap t expedient. In relation to the steel pipe diameters of the rods shown in Fig. 6, the screws would have something as a connecting means stronger and the shell ball must be drawn a little larger. This shell body f of Fig. 6 can also consist of two spherical part shells that fit into each other Have margins.

The rods can be connected to the shell bodies with either two or more Screws are connected, such as. B. the rods of Fig. 3 and 3a, or only with a single lanyard, which must then sit so that its center line coincides with the longitudinal center line of the rod, and must be so strong that it greatest tensile force occurring in the rod with multiple safety on the shell body can transfer.

Instead of screws, other known fastening means, e.g. B. spline fasteners can be used. In the case of wedge connections, the rod ends would expediently with ring-shaped beads or edges, which matching contact surfaces for the joints on the shell body, and with protruding in the direction of the rod Steel extension pegs that pass through the shell holes from outwards inwards - pushed through and tightened in the body cavity by wedges -, verden, which are driven through the tenon slots and to the inner surface of the shell body be created.

As an example of securing rods and fasteners against Rotation and detachment from the shell body in bar structures of larger structures In Fig. 6, the bottom bar v is secured by a pin w that goes through the wall of the shell body is inserted into the rod head, next to the screw x and at the same time the washer located under the screw head against rotation secures. This washer is after tightening the screw head with your protruding tongue, which is beveled and attached to the relevant screw head side surface is used to secure the screw. A pinning would be even more useful directly between the rod end and the extension projecting into the rod cavity of the screw bolt x such that the pin in front of the shell body across the Rod end is driven and riveted at its protruding end.

Claims (6)

PATEN TA NS PR t; CHE: i. Junction connections for rod structures, in particular scaffolding, in which the longitudinal axes of all rods connected to a connection intersect at one point and which consist of known connecting means and shell-shaped bodies, against the inner surface of which the wider parts of these connecting means are applied and tightened, characterized in that each Nodal point body is a thin-walled shell body (a, b, c, d or f) that is sure to transmit the greatest bar forces that occur, of any shape, but suitable for the purpose, which with its shell wall completely encloses its cavity on all sides and the wider parts located in this cavity, z. B. heads, edges or wedges of all of its connecting means completely enveloped so that bars can be connected to almost all points of its outer surface. 2. Junction connections according to claim i, characterized in that each shell body, especially if it is only of medium or small size, is composed of partial shells (a, b, c or d) which have edges (h, i, o or q) , which prevent mutual displacement of the partial shells when the rods are in readiness and act like a single rigid body after they have been tightened or welded to one another with one or more connecting means. 3. Junction connections according to claim i, characterized in that each shell body (f), if it is made in large form and does not consist of partial shells, for the purpose of introducing rod connecting means into the cavity and fastening the same by means of a tool at a point free of rod connections Has opening (r) which has an edge (s) shaped in such a way that this opening can be closed with a correspondingly shaped cap (t) which fits well and tightly onto it, which in turn is secured with a fastening means (u) that does not protrude outwards. is being held. 4. Junction preventions according to claims i and 21> zw. i and 3, thereby characterized in that, if the edges of the shell body part shells as well as the The edges of the openings of the undivided shell bodies form bulges or flanges, these bulges or flanges protrude into the body cavity and that these edges, if the bodies in larger structures have to withstand strong stresses, in their Wall thickness are reinforced accordingly. 5. Junction connections after the Claims i and 2 or i and 3 or 4, characterized in that the shell bodies both on the outer surface to rest the rod head ends or rod head edges as also on the inner surface for the attachment of the heads, edges or wedges of the fasteners have appropriately shaped mating surfaces located on the shell bores, which are intended to be applied to them at the point of intersection of the relevant rod longitudinal axes Tangential planes are perpendicular to these relevant rod longitudinal axes. 6. Junction connections according to claims i and 2 or i and 3 or claim 4 or 5, characterized in that each shell body is a spherical shell with said opening and closure cap (f) or consists of partial spherical shells in small design sizes appropriately from hemispherical shells (c and d), so that the longitudinal axes of the rods led to a spherical shell intersect in the center of this spherical shell. Junction connections according to claims i to 6, characterized in that many or some of the shell bodies (a, l and b), in particular the spherical shells and partial spherical shells, are flattened at a point free of rod connections for special purposes and, if these bodies are subject to greater forces have transferred, the wall of the flattened part of the body is reinforced. B. junction connections according to claims i to 5 or 6 or j, characterized in that, in order to achieve a great diversity of the rod construction systems, the shell bodies are produced in such a size that on each such body also very closely adjacent, at an angle much more acute than 45 ' converging rods can still be connected. G. Junction connections according to claims t to 6 or 7 or 8, characterized in that between each shell body and the head ends of the rods repelling on it, which are not yet secured to other bodies, or between the rod head ends and their connecting means each have a special fastening is attached, which prevents the rod in question from twisting on the shell body or detachment from its connecting means or secures it against such, e.g. by inserting a pin (w) or by driving a pin transversely through the rod end and through one into the Extension of the screw bolt protruding into the tubular rod cavity. Cited publications: German Patent Specifications Nos. 212214, 30943t