RU2037026C1 - Covering lattice plate - Google Patents

Abstract

FIELD: civil engineering. SUBSTANCE: covering lattice plate has bearing four-link members forming lattice with hexagonal cells and guard in form of covering. Members are rigidly connected to each other by means of reinforcement bars passed through holes and secured by washers and nuts. EFFECT: enlarged operating capabilities. 4 dwg

Description

 The invention relates to the construction and can be used in the construction of coatings of buildings and structures, as well as false ceilings.

Known trellis plate cover, including a fence and a frame of rigidly interconnected load-bearing elements forming a lattice with hexagonal cells, while the load-bearing elements are made in the form of straight rods with a length on the side of the cell [1]
In this design of the lattice plate due to the cyclic symmetry of the lattice, a uniform distribution of forces in the supporting elements is ensured, which makes it possible to rationally use the material of the structure and thereby reduce its material consumption.

 The disadvantage of this coating is the need for docking in each node of three load-bearing elements, requiring a large number of connecting parts in the nodes, which increases the metal structure, complicates the installation of the coating and increases the complexity of its assembly.

The closest to the invention in technical essence and the achieved result is a grating cover plate including a frame and a fence, the frame being made of rigidly connected similar load-bearing elements forming a grating with hexagonal cells in such a way that the ends of the two elements are joined to the lateral opposite surfaces of the third elements in two different places, and at the ends there are reinforcing outlets installed in the upper and lower zones of the cross section, while the supporting elements are made s in a three-link polygonal elements, curved in the plane of the coating [2]
In the specified design of the grating plate, only two supporting elements are connected at the joints, which allows to simplify the design of the joints, reduce the metal consumption of the coating and reduce the complexity of its assembly. In addition, the implementation of the frame elements is continuous so that each element is simultaneously part of four lattice cells, increases the coating assembly and provides a better redistribution of forces throughout the lattice structure, and also increases the rigidity of the structure.

 The disadvantages of this coating are the curvature of the bearing elements along two oppositely directed radii of curvature, which complicates their manufacture, increases cost, and also increases the risk of delamination of glued elements, which negatively affects the operational reliability of the coating; low compactness of the bearing elements, reducing their portability and increasing transportation costs; the need to use additional load-bearing elements in the marginal zone to obtain a regular lattice, which increases the number of element sizes, reduces the collectivity of the coating and increases the complexity of its installation.

 The invention is aimed at improving the operational reliability and prefabrication of the coating, reducing costs for the manufacture, transportation and installation of load-bearing elements.

 This is achieved by the fact that in the lattice plate of the coating, including fencing elements in the form of a flooring and a frame containing rigidly interconnected supporting multi-link elements forming a hexagonal lattice, the supporting elements are formed of four parts bent to the same side. Each non-contouring load-bearing element with its ends is docked to the side surfaces of two different load-bearing elements directly connected to each other. The ends are docked on the convex side of each supporting non-contour element in three places located on its bends. For joining, the supporting elements have reinforcing outlets at the ends installed in the upper and lower zones of the cross section, and openings located at the joints.

 The proposed solution allows to achieve the implementation of the docking on one side of the supporting element; a lattice system in which each non-contour bearing element is simultaneously a side of five cells; docking from the side surface to each non-contour bearing element of three others; the docking of each bearing element with the ends with two other elements directly connected to each other; dividing the load-bearing elements by bending places into four equal parts; the ability to assemble a regular lattice without additional elements; the bending of all sections of the structural bearing element in one direction; the same directivity of the radii of curvature of the bearing element in the places of bends, which, in turn, improves the operational reliability of the structure; reduce the cost of manufacturing and transportation of load-bearing elements; to increase the integrity of the coating and reduce the complexity of its installation.

 In FIG. 1 is a plan view of a grating cover plate; in FIG. 2 connection of the bearing element with the adjacent plan; in FIG. 3, section AA in FIG. 2; in FIG. 4 bearing element, plan.

 The lattice plate of the coating includes a frame containing supporting four-link elements 1, forming a lattice with hexagonal cells, and a fence in the form of flooring 2. Elements 1 are rigidly interconnected using reinforcing rods 3, passed through holes 4 and secured by washers 5 and nuts 6.

 Elements 1 are made glued or plastered in the form of vertically glued elements obtained by preliminary gluing the boards in width with subsequent molding using mechanical mechanical, pneumatic or hydraulic presses. The rods 3 are glued to the ends of the supporting elements in the factory using compositions based on epoxy resins. The most appropriate length of the elements is 5-6 m for glued elements, 3-4 m for glued elements. The cross section of glued elements is accepted as solid rectangular with a vertical arrangement of layers, and glued solid, rectangular, I-shaped or box-shaped. The ratio of the height of the cross section to the width is assigned in the range of 8-10. The number of grid cells along the length or width in the plan is taken from four or more, depending on the span of the coating.

 The fence 2 can be made in the form of a single-layer or three-layer boardwalk.

 The support of the grating plate can be carried out both along the contour and in the nodes of the grating.

 The installation of the grating plate is carried out with an enlarged assembly of the frame and laying of the flooring at ground level, followed by a rise to the design level.

 In comparison with the prototype, the declared grid plate of the coating, due to the bending of the parts of the multi-link elements to one side and dividing the elements by bending into four equal parts, allows to give the elements a more compact shape, which increases their portability and reduces transportation costs.

 The joining of adjacent elements on one side of the bearing element determines the same directivity of the radii of curvature of the bearing elements in the places of bends, which simplifies their manufacture, reduces cost and increases the operational reliability of the coating due to the reduced risk of delamination of glued elements.

 In addition, the lattice system, in which each non-contouring bearing element is simultaneously a side of five cells, makes it possible to more evenly distribute forces and thereby reduce material consumption and increase the operational reliability of the coating, as well as increase its rigidity and integrity due to the fact that each element is a bond between a large number of lattice nodes.

 The possibility of drawing up a regular lattice in the claimed solution without additional elements also contributes to increased teamwork and reduced labor costs for installation of the coating due to the limiting reduction in the number of standard sizes of bearing elements.

Claims (1)

 LATTICE COVERING PLATE, including a fence and frame made of the same type of rigidly connected load-bearing elements with a curved shape in the coating plane with parallel extreme parts that form a lattice with hexagonal cells and joined so that their ends adjoin the lateral surfaces of adjacent elements in the places of bends the fact that the supporting elements are made of four parts, bent to one side, and three other elements are attached to each non-contouring bearing element from its convex side, moreover, any supporting element of the lattice with its ends is docked to two elements directly connected to each other.