RU2084602C1 - Shelter - Google Patents

Abstract

FIELD: construction engineering. SUBSTANCE: this ground surface protective structure relates to special-purpose objects to be built at various enterprises. Shelter is made of prefabricated reinforced concrete trough-like components ensuring high impact-proofing and fire-safety properties. Shelter has internal box assembled from fiber-reinforced concrete trough-like components installed on base and surrounded at three sides with pliable layer on which placed with their flanges down are respectively horizontal and vertical trough-like components of outer contour. Installed on walls of horizontal trough-like components are pliable tubular devices which function as supports for one end of incline trough-like components which by their other end rest on walls of vertical trough-like components of outer contour. Installed atop of incline trough-like components in horizontal position are two upper trough-like components which are interconnected by their walls through pliable interlayer placed between walls and by means of connecting bolts inserted through holes made in walls of trough-like components. Trough-like components of internal box are connected by bolts at corners, and vertical trough-like components of outer contour are fixed in design position by means of thrust member at base. Efficiency of shelter directly depends on energy-absorbing capacity of its structural components under action of dynamic loads and shock waves. Shelter can be disassembled and again assembled at required site close to enterprises or other objects. Assembly and disassembly of shelter are simple and require no special and powerful load-lifting facilities or other machinery. EFFECT: high efficiency. 1 dwg

Description

 The invention relates to the field of construction of special structures and can be used in the construction of shelters in various enterprises.

Known shelters with enclosing and supporting structures of special elements of the typical series U-01-01 / 80 and U-01-02 / 80 [1]
The disadvantage of these shelters is that their use is effective with a building capacity of more than 150 people. In addition, for the production of elements of the indicated series, special technological lines are required at the precast concrete plants.

 At the same time, the number of the largest working shift at most facilities does not exceed 100 people, and the facilities themselves are located throughout the republic, which makes it difficult to deliver special building structures to the place of construction of the shelter.

However, there are shelters made of structures of industrial and civil construction. These shelters are erected from planar elements and volumetric blocks of various shapes [2]
Closest to the proposed invention is a shelter, including an inner box mounted on the base and bordered on three sides by a compliant layer, and elements of the external contour, some of which are vertically mounted on the sides of the compliant layer, and the others are horizontally laid on top of it (German application No. 1803558 , CL E 04 H 9/12, 1974) [3]
This shelter is taken as a prototype, the prototype is the base object.

 The disadvantages of such shelters is that this technical solution, being made only of structures of industrial and civil construction, can not provide an effective reduction in the impact of dynamic loads from an air shock wave, increased shockproof protective properties from falling debris, individual structural elements and equipment, as well as increased fire protective properties when exposed to fires.

 At the same time, in industrial and civil construction, tray elements, as well as building material fiber reinforced concrete, are quite widespread.

 Using these structures and fiber-reinforced concrete, it seems possible to easily mount the necessary shelters and avoid the disadvantages characteristic of the prototype.

 The aim of the invention is to provide the possibility of building shelters from prefabricated reinforced concrete tray elements and increasing their shockproof and fire protective properties.

 This goal is achieved by the fact that in the proposed shelter the inner box is made of fiber-reinforced concrete chute elements, and the outer contour elements of chute elements supported by shelves on a pliable layer, this shelter is equipped with tubular malleable elements laid on the walls of horizontal chute elements, inclined chute elements, one ends supported by tubular ductile elements, and the other by the walls of the vertical channel elements of the outer contour, and by additional upper horizontal tray elements connected by walls to each other through a compliant gasket by means of connecting bolts passed through the holes in the walls. The tray elements of the inner box are fastened in the corners with connecting bolts, and the vertical channel elements of the outer contour are fixed in the design position by the stop elements placed at the base.

 The proposed shelter is presented in the drawing and consists of fiber-reinforced concrete chute elements of the inner box 1, ductile layer 2, chute elements of the outer contour 3, tubular ductile elements 4, inclined chute elements 5, additional upper horizontal chute elements 6, ductile gasket 7, connecting bolts 8, thrust elements 9. The shelter is installed on the base 10.

 The shelter operates as follows. The dynamic shock load from the falling debris, individual structural elements and equipment is perceived by the additional upper horizontal chute elements 6, causing them to move and deform due to compression deformation of the flexible strip 7 at the junction and transferred to the inclined chute elements 5. At the same time, the elements 5 themselves receive displacement and deformation, thereby causing deformation of the tubular ductile elements 4. From the inclined chute elements 5 and tubular ductile elements 4 shock Wie transmitted into horizontal and vertical elements are external contour chute 3, which, in turn, moved and deformed, compressed compliant layer 2. Thereafter, exposure by a compliant layer 2 fibrozhelezobetonnymi perceived inner box gutter elements 1, which are also subjected to deformation.

 Thus, the energy of influence on the shelter is spent in the general case on the deformation and destruction of the additional upper horizontal chute elements 6, deformation when compressing the flexible strip 7, the movement, deformation and destruction of the inclined chute elements 5, the deformation of the tubular flexible elements 4, the movement and deformation of the chute elements external contour 3, deformation under compression of the compliant layer 2, deformation of the tray elements of the inner box 1.

 At the same time, the tray elements of the inner box 1 are made of fiber reinforced concrete in order to prevent spallation during dynamic impacts.

 The effect of exposure depends on the energy intensity of these structural elements of the shelter. The higher the energy intensity of the proposed shelter, the greater the impact it is able to perceive, thereby providing an increase in the protective properties from the effects of both shock and dynamic loads from shock waves (air).

 The proposed shelter allows you to provide the necessary protection for the largest working shift facilities. In addition, such a shelter can be dismantled and installed in a new place suitable for these purposes, which will allow creating a more flexible protection system at facilities, bringing it as close as possible to workplaces.

 The assembly and disassembly of such structures is quite simple and does not require special powerful lifting mechanisms and other devices.

Claims (1)

 A shelter, including an inner box installed on the base and bordered on three sides by a compliant layer, and elements of the outer contour, some of which are vertically mounted on the sides of the compliant layer, and the others are horizontal laid on top of it, characterized in that the inner box is made of fiber-reinforced concrete tray elements, and the elements of the outer contour of the tray elements, supported by shelves on a compliant layer, while the shelter is equipped with tubular compliant elements laid on the walls of the horizontal tray elements, inclined chute elements, supported at one end by tubular pliable elements, and others on the walls of vertical chute elements of the outer contour, and additional upper horizontal chute elements connected by walls to each other through a flexible gasket by connecting bolts passed through the holes in the walls, moreover, chute the elements of the inner box are fastened in the corners with connecting bolts, and the vertical tray elements of the outer contour are fixed in the design th position placed at the base of the thrust elements.