RU2057862C1 - Wall panel - Google Patents

Abstract

FIELD: civil engineering. SUBSTANCE: internal and external firm facing are made in the form of internal panel of wood boards with facing of boards and external panel of wood boards with facing of sheets. Spacing between the panels are filled with vertically installed polyethylene tubes overlapped from above and below with polyethylene tubes laid horizontally. Tube ends are bolted to external and internal panels, and cavities of the tubes and intertube spacing are filled with foam plastic packed with polyethylene. EFFECT: improved protective ability of humans, improved tightness as compared to known engineering solutions concerning blast effects. 3 dwg

Description

 The invention relates to the construction of land-based buildings and can be used in the construction of these buildings in areas where the effects of explosions in accidents and disasters are possible.

Known wooden wall panel containing a wooden frame, sheathed on both sides with a lining of solid fiberboard, between which is placed a heater made of mineral wool panels, and on the inside on the wooden slats attached asbestos-cement sheet [1]
Three-layer wall panels are also known: a panel with a bearing frame: a panel with a ribbed center; solid center panel [2]
These panels are rigid framing of wooden bars, sheathed on both sides with sheathing or sheathing with a layer of foam, and the interior has either an air gap or is filled with a continuous layer of foam.

 The disadvantages of these panels are that when exposed to an air shock wave on a building, these panels are destroyed with the formation of fragments and fragments.

 Closest to the invention is a three-layer wall panel with a ribbed center.

The three-layer wall panel contains the inner and outer layers of hard skin, the space between which is filled with a protective frame in the form of a honeycomb structure, and the voids of the cells include an air gap and a foam layer [2]
This wall panel is taken as a prototype, the prototype is the basic object.

 The disadvantage of such wall panels is their destruction and violation of the tightness of the premises when exposed to an air shock wave. In addition, when these panels are destroyed, fragments and fragments are formed that can have a damaging effect on people inside the building. To eliminate the consequences of explosions in relation to a building containing such panels, significant manpower and expense will be required.

 The aim of the invention is to increase the security of people inside the building and the tightness of the premises when exposed to explosions, as well as reducing the cost of restoration work.

 This goal is achieved by the fact that the inner and outer layers of the hard skin are made in the form of an inner board made of boards with a finishing layer of boards and an outer board made of boards with a finishing layer of sheet material, the space between the boards is filled with vertically installed polyethylene pipes overlapping horizontally from above and from below. stacked polyethylene pipes.

 The pipes are connected at the ends with the outer and inner shields by means of bolts, and the cavities of the pipes themselves and between the pipes are filled with foam in a plastic bag.

 Figure 1-3 presents the proposed wall panel.

 It consists of an inner shield of boards with a finishing layer of boards 1, an outer shield of boards with a finishing layer of sheet material 2, vertical polyethylene pipes 3, horizontal polyethylene pipes 4, polystyrene in polyethylene packaging 5 and bolts 6.

 Wall panel operates as follows.

 An air shock wave, acting on the wall panel, causes the outer shield 2 to move due to the compliance of the polyethylene pipes 3, 4 and foam 5. The polyethylene pipes 3, 4 and the foam layer 5 undergo compression deformation. Next, there is a movement of the inner shield 1.

 The high deformability of the wall panel reduces the amplitude of the acting excess reflection pressure due to the violation of diffraction and flow patterns, which does not allow the formation of a dynamic reflection load on the walls of the building. The highest excess reflection pressure is observed during diffraction by fixed rigid obstacles mounted vertically.

 With an increase in the dynamic load on the building, the movement of the panels of panels 1, 2 occurs until the polyethylene pipes 3, 4 and polystyrene 5 reach ultimate compressive strains.

 The time of the onset of ultimate deformations of pipes 3, 4 and foam 5 is selected theoretically or experimentally so that it is less than the time of the dynamic load. Such a solution will not allow pipes 3, 4 and foam 5 to reach ultimate compressive strain during the dynamic load.

 When restoring the building after explosive action, the wall panel is dismantled, the inner or outer shield is removed from the boards 1, 2, the polyethylene pipes 3, 4 and the foam layer 5 are aligned. Then the panel is assembled and hung on the building frame.

 This technical solution avoids the destruction of the wall panels of the building, which does not lead to the formation of debris and fragments, and therefore to the defeat of people inside the building. In addition, in this case, the necessary tightness of the premises of the building is provided.

 Based on the foregoing, a significant increase in the security of people and the tightness of the premises is ensured in comparison with the well-known technical solutions of buildings under the influence of these damaging factors.

Claims (1)

 WALL PANEL containing the inner and outer layers of hard skin, the space between which is filled with a protective honeycomb structure, and the voids of the honeycomb include an air gap and a foam layer, characterized in that the inner skin is made in the form of a shield of boards with a finishing layer of boards, and the outer skin in the form of a shield made of boards with a finishing layer of sheet material, the honeycomb structure is formed by vertically installed polyethylene pipes overlapped by horizontally laid polyethylene pipes on top and bottom rubami, wherein the tubes are connected at the ends of the outer and inner shields by means of bolts, and the cavities of the pipes themselves and between the pipes are filled with foam plastic in the plastic package.

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