RU2616200C1 - Connection of thin-walled steel profiles using volumetric shaped elements - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: thin-walled profiles connection assembly using a volumetric shaped element comprises belts, braces, corner plates, fasteners, belt connected to the braces by means of fasteners and the volumetric shaped member which consists of metal plates - two parallel side plates with holes for bolts and one perpendicular plate. The upper belt is embedded inside the corner plate with wall parallel to the connecting plate and is attached by flanges to the side plates on both sides, while the braces are opposite directions at an angle providing rod axes intersection at one point. Bracing, as well as the belt are fastened by flanges to the side plates using bolts, and the side plates have a hexagonal shape.

EFFECT: increased rigidity and steel consumption optimisation for hinged-rod structures.

8 cl, 33 dwg

Description

The invention relates to construction of hinged-rod structures for various purposes and can be used in civil, industrial, rural and transport construction.

A known method of connecting thin-walled elements of open section. The joining method includes laying the ends of thin-walled elements with walls on a sheet gusset, installing a central bolt in pre-drilled holes in the walls of thin-walled elements and gussets, a central bolt screed and installing self-tapping screws (see patent RU 2521214 C1, EV 1/51, publ. 27.06. 2014, Bull. No. 18).

However, this connection method does not provide for the connection of several multidirectional rods that are used in articulated-rod structures.

The closest analogue is the solution of the nodal connection of a segment rafter truss from C-shaped profiles or channels, having a triangular lattice with a cross section of one type of profile and assembled by welding or lap-welded on the shelves of the lattice rods to the walls of the waist profiles or to the nodular trusses of the truss (see patent RU 2487221 C1, Е04С 3/11, publ. 07/10/2013, Bull. No. 19).

However, shaped elements of this type are intended for trusses of a segment outline and are not suitable for trusses with parallel belts.

The task of the invention is to increase the bearing capacity of the hinged-rod structure of thin-walled profiles and reduce the consumption of steel.

The essence of the invention lies in the fact that in the node connecting thin-walled steel profiles using a volumetric shaped element, including belts, braces, fittings, fasteners, the belt is connected to the braces using fasteners - bolts, washers, nuts and volumetric shaped element, which consists of metal plates - two parallel side and one perpendicular connecting, connected by welding, and the side plates have holes for bolts, the upper belt is inserted inside the gusset with a parallel wall it is attached to the connecting plate and is fastened by shelves to the side plates on both sides, and the braces are directed in different directions at an angle so that the axis of the rods intersect at one point, the braces, like the belt, are fastened with shelves to the side plates with bolts, and the side plates have the shape of a hexagon.

- The belt is connected to the braces and to the rack using an ordinary shaped element, and the rack is located between the braces, perpendicular to the belt and the side plates have additional holes for fastening the rack using bolts.

- Two belts are connected at an angle relative to each other with one brace or stand using an external ridge / cornice shaped element, and the belts are inserted with the ends into the shaped element parallel to each to two joined plates welded at an angle to each other to the side plates, and the side plates have the shape of a truncated rhombus.

- Two belts are connected to two braces and a stand at an angle relative to each other and at an angle relative to the connecting plate of the inner ridge / cornice element, and the side plates are octagonal in shape.

- The belt is connected to the rack using an intermediate shaped element, the rack is perpendicular to the belt, and the side plates are hexagonal.

- The end of the belt is connected to the stand using an angular / supporting shaped element, the stand being located perpendicular to the belt, and the shaped element has two additional supporting plates welded perpendicular to the side plates and parallel to the rack from the outside, the supporting plates are connected to the side plates and two kerchiefs each, with the side plates having a pentagonal shape.

- The end of the belt is connected to the strut and the brace using an angular / supporting shaped element, the strut being perpendicular to the belt and the bracing between the strut and the belt, while the shaped element has two additional support plates welded perpendicular to the side plates and parallel to the strut from the outside, the support plates are connected to the side plates and the scarves, two for each, while the side plates have a rectangular shape.

- Thin-walled core elements of the belt are connected using a connecting shaped element end-to-end, and the side plates are rectangular.

The technical result consists in increasing the stiffness and optimizing the consumption of steel articulated-rod structures.

The result is achieved due to the fact that the occurrence of a torque by combining the axes of thin-walled structural elements is eliminated in the connection node with the help of the volumetric shaped element, concentrated loads on the rods of the building structure are transmitted through the shaped element, which eliminates local crushing of the element wall, the shape of the volumetric shaped element reduces the calculated the length of the rod and allows the use of profiles of a composite section or single profiles and select the desired number of bolts per rod item.

The invention is illustrated by drawings, where:

FIG. 1 - General view of the hinge-rod frame

FIG. 2 - node connecting the farm belt with two braces using an ordinary shaped element;

FIG. 3 is an isometric view of a junction of a truss belt with two braces using an ordinary shaped element;

FIG. 4 is an isometric view of an ordinary shaped element;

FIG. 5 - node connecting the farm belt with two braces and a rack using an ordinary shaped element;

FIG. 6 is an isometric view of a junction of a truss belt with two braces and a rack using an ordinary shaped element;

FIG. 7 is an isometric view of an ordinary shaped element;

FIG. 8 - connection node truss belts with brace with the help of an external ridge / cornice shaped element;

FIG. 9 is an isometric view of a junction of truss belts with a brace using an outer ridge / cornice shaped element;

FIG. 10 is an isometric view of an outer ridge / cornice shaped element;

FIG. 11 - node connecting the elements of the belt of the farm using a connecting shaped element;

FIG. 12 is an isometric view of a junction member of a truss belt element using a connecting shaped member;

FIG. 13 is an isometric view of a connecting shaped member;

FIG. 14 - connection node truss belts with a rack using an intermediate shaped element;

FIG. 15 is an isometric view of a junction of truss belt joints with a stand using an intermediate shaped member;

FIG. 16 is an isometric view of an intermediate shaped member;

FIG. 17 - node connecting the farm belt with the rack using an angular / supporting shaped element;

FIG. 18 is an isometric view of a junction of a truss belt with a stand using an angular / supporting shaped member;

FIG. 19 is an isometric view of a corner / support shaped member;

FIG. 20 - node connecting the farm belt with the stand and brace with the help of an angular / supporting shaped element;

FIG. 21 is an isometric view of a junction of a truss belt with a strut and brace using an angular / supporting shaped member;

FIG. 22 is an isometric view of a corner / support shaped member;

FIG. 23 - connection node truss belts with brace using the internal ridge / cornice shaped element;

FIG. 24 is an isometric view of a junction of truss belts with a brace using an internal ridge / cornice shaped element;

FIG. 25 is an isometric view of an inner ridge / cornice shaped element;

FIG. 26 - connection node of the composite core elements of the box section;

FIG. 27 is an isometric view of a joint assembly of box-shaped composite core members;

FIG. 28 - section 1-1;

FIG. 29 - section 2-2;

FIG. 30 - section 3-3;

FIG. 31 - section 4-4;

FIG. 32 - section 5-5;

FIG. 33 - options for the main sections of thin-walled profiles,

options for performing composite sections;

The connection node for thin-walled steel profiles using a volumetric shaped element, depending on its location in the structure, consists of a shaped element 1, 2, 3, 4, 5, 6, 7, 8, belt 9, braces 10, rack 11, bolts 12 or self-tapping screws. The inventive connection node using shaped elements differs in the number, direction and purpose of the connecting rod elements 9, 10, 11 and the shape of the gusset and is divided into ordinary 1 and 2, the outer ridge / cornice 3, connecting 4, intermediate 5, angular / supporting 6 and 7, inner ridge / cornice 8. Each version of the volumetric shaped element included in the connection node of thin-walled elements has its location in the structure. The thin-walled profile of the truss belt 9, the braces 10 and the struts 11 are fastened with bolts 12 inside the shaped element 1, 2, 3, 4, 5, 6, 7, 8 from two sides. The thin-walled profile can have a different cross-sectional shape 13, 14, 15, 16, 17, 18, 19, 20 and attach to the shaped element separately or join in the form of a composite section of a box-shaped 21 or open 22 shape. Other cross-sectional options for the thin-walled profile are also possible. According to the example of the connecting unit 4, the element shows how, when using a composite section of the box-shaped form 21, the technological hole 23 for the bolt fastening 12 is cut out in the wall of one of the profiles 12. The shaped element 1, 2, 3, 4, 5, 8 is two side welded together 24 and one connecting 25 sheet metal plate. The shaped element 6.7 is two side panels 24 welded together, one connecting 25, two supporting plates 26 and four kerchiefs 27 made of sheet metal. Side plates 24 have holes 28 for bolts 12 and have different sizes, depending on the required number of bolts for connecting the rod elements and the location of the node. So in the connection nodes two and three rows of bolts 12 are shown, but the number of rows can increase or decrease depending on the rated voltage that occurs in the considered rod element when the structure as a whole is under load. The support plates 26 have a cutout 29 for the anchor bolt. The plate 25 interconnects the side plates 24.

The operation of the device lies in the fact that the shaped elements 1, 2, 3, 4, 5, 6, 7, 8 in nodal connections allow the use of single rods 13, 14, 15, 16, 17, 18, 19, 20 with rods of a composite section combined by type 21, 22 to perceive the required design load on a single rod. Also shaped elements allow you to place the required number of bolts by increasing or decreasing the size of the side plates 24, as well as changing their geometric shapes. The concentrated loads from the runs on the rods of the building structure are transmitted through the connecting plate 28 of the shaped element. The shape of the shaped element reduces the design length of the truss rods and align their axis. All rods 9, 10, 11 in the node perceive tensile or compression stresses.

Connection nodes are used in trusses with parallel belts, segment trusses and in trusses with non-parallel belts and in other hinged-rod structures.

Thus, the claimed nodal joints as a whole increase the bearing capacity of the pivot-rod structure using thin-walled profiles and reduce the consumption of steel.

The proposed device can be manufactured under industrial conditions, workshops of large and medium-sized factories using standard equipment manufactured by domestic and foreign industry.

The set of technical solutions gives this device new properties and allows you to solve the problem.

Claims (8)

1. The connection node of thin-walled steel profiles using a three-dimensional shaped element, including belts, braces, fittings, fasteners, characterized in that the belt is connected to the braces using fasteners - bolts, washers, nuts and three-dimensional shaped element, which consists of metal plates - two parallel lateral and one perpendicular connecting, connected by welding, and the side plates have holes for bolts, the upper belt is inserted into the wall gusset parallel to the connecting the second plate and is fastened by shelves to the side plates from two sides, and the braces are directed in different directions at such an angle that the axis of the rods intersect at one point, the braces, like the belt, are fastened by shelves to the side plates with bolts, and the side plates are shaped hexagon. 2. The connection node of thin-walled steel profiles using the volumetric shaped element according to claim 1, characterized in that the belt is connected to the braces and the rack using an ordinary shaped element, and the rack is located between the braces, perpendicular to the belt and the side plates have additional holes for mounting struts with bolts. 3. The connection node of thin-walled steel profiles using the volumetric shaped element according to claim 1, characterized in that the two belts are connected at an angle relative to each other with one brace or stand using an external ridge / cornice shaped element, the belts being inserted with the ends into the shaped element parallel to each of the two joined plates welded at an angle relative to each other to the side plates, and the side plates have the shape of a truncated rhombus. 4. The connection node of thin-walled steel profiles using the volumetric shaped element according to claim 1, characterized in that the two belts are connected to two braces and a stand at an angle relative to each other and at an angle relative to the connecting plate of the inner ridge / cornice element, and the side plates have octagon shape. 5. The connection node of thin-walled steel profiles using the volumetric shaped element according to claim 1, characterized in that the belt is connected to the rack using an intermediate shaped element, and the rack is perpendicular to the belt, and the side plates have the shape of a hexagon. 6. The connection node of thin-walled steel profiles using the volumetric shaped element according to claim 1, characterized in that the end of the belt is connected to the stand using an angular / supporting shaped element, and the stand is perpendicular to the belt, and the shaped element has two additional support plates, welded perpendicularly to the side plates and parallel to the strut from the outside, the supporting plates are connected to the side plates and two scarves each, while the side plates have a pentagonal uy form. 7. The connection node of thin-walled steel profiles using the volumetric shaped element according to claim 1, characterized in that the end of the belt is connected to the stand and the brace by means of an angular / supporting shaped element, the rack being located perpendicular to the belt, and the brace between the rack and belt while the shaped element has two additional support plates welded perpendicular to the side plates and parallel to the rack from the outside, the support plates are connected to the side plates and two scarves on each, while the side plates are rectangular. 8. The connection node of thin-walled steel profiles using the volumetric shaped element according to claim 1, characterized in that the thin-walled core elements of the belt are connected using the connecting shaped element end-to-end, and the side plates have a rectangular shape.

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