CS229306B1 - Flexible bottom of flexible reinforced concrete tank - Google Patents

Abstract

The invention cuts the expansion joint of a tank with a flexible bottom. A notch is made in the bottom of the tank, provided with a chamber along its entire length on the lower side. The invention can be used in places where "there is a continuous, continuous curvature of the terrain surface, for example due to undermining, unevenness of the subsoil, seismicity, etc.

Description

The invention relates to the provision of a flexible bottom of a pliable reinforced concrete tank.

The construction of reinforced concrete tanks in the world is designed so that it is perfectly rigid or that their geometric shape adapts to the continuous curvature of the terrain, which arises, for example, by its undermining.

The tanks, whose geometric shape adapts to the smooth curvature of the terrain, have so far been designed so that they were divided by continuous expansion joints to the foundation joint. These continuous expansion joints divide the expansion tank, connected to each other by expansion strips of elastic mass, provided with a protrusion in the middle of the width, most often hollow, around which the parts rotate relative to each other. These strips of elastic material fulfill the function of a notched joint as in the case of reinforced concrete notched joints

Freyssinetic, joint function is performed by pressure plasticized layer of concrete. Notched joints with soft metal plates such as lead or a resilient material such as rubber or plastic are also known. Other types of joints are Mesnager's belt joints, created by crossed bars of concrete reinforcement in the place of the supposed joint and artificial metal joints.

These other types of joints are not suitable for shape-compliant reinforced concrete tanks, especially since tensile forces from the friction in the foundation joint may occur in the bottom due to undermining.

The notch depths formed by the sealing strips of continuous expansion joints (down to the foundation joint) are costly due to the high consumption of sealing material.

229 308 is the instability of geometrical dimensions, because the belts, due to their great flexibility, allow mutual displacement of individual parts of the tank due to frictional forces between the soil, shifting effects of undermining and the object. This arrangement is not particularly applicable where the built-in mechanical equipment requires a geometrically stable tank. Continuous expansion joints in the bottom mean an increase in the area of possible leakage of the tank. Conventional Freyssinet notched joints are not suitable for this purpose. In the case of the expansion of the terrain due to undermining, there would be no presumptive plasticization of the concrete layer by pressure, since this layer will in this case be stretched and thus the joint can be damaged by a tensile crack. Notch joints with inserts of soft or resilient material would not provide the desired connection of the divided portions of the tank. Mcsnager's spring joints are unsuitable for the base plate, as steel bars would still be subject to corrosion even after additional concreting. The protective concrete layer would crack by deformation of the bars, resulting from axial forces. In addition, these joints are very laborious. Artificial metal joints are very expensive,

All of these difficulties are overcome by the shape-resistant, non-divided, flexible bottom tanks according to the invention. The essence of the flexible bottom according to the invention is that in the extension of the wall expansion joint, a notch is formed in the part of the bottom ending above the foundation joint and widened above the foundation joint in the chamber (cavity). The notch chamber may be tapered at both ends and may be provided with a cover or seal at both ends. The scaffold according to the invention has the following advantages over the known solutions:

By forming a bottom notch chamber, the bottom thickness in the region of the wall expansion joint is reduced and hence its bending stiffness at these locations is reduced. This makes it possible to adapt the tank flexibly to the curvature of the terrain even in the area of the expansion joints of the wall, where otherwise a crack would be formed in the bottom. At the same time the stability of the ground plan dimensions of the tank is ensured.

229 309

The use of the elasticity of only the base plate leads to a significant reduction of the reinforcement consumption compared to the rigid tanks (without expansion joints) and the possibility of longer expansion units than hitherto. Simultaneously weakening the base plate in the area of the expansion joints of the walls prevents the formation of cracks scientifically, otherwise the wall with its stiffness prevents the smooth curvature of the bottom and there is a fracture.

A considerable advantage is also the applicability of the invention to tanks of other planes than four-rounded, for example circular, polygonal and the like.

Another advantage of this solution is under the stress of hydrostatic pressure acting in horizontal planes, notched or other joints on the day e eliminating the stresses of the walls from the inside by eliminating the frame elimination of the necessity of acquisition in the area of expansion joints of the walls.

Another advantage is also to minimize the area of possible leakage.

A significant advantage is the fact that the sealing of expansion joints in the walls is possible with materials other than elastic strips

Made of plastic, such as corrugated copper sheet; there is no mutual displacement of parts of the tank divided by continuous dilators. joints due to horizontal soil deformation from undermining effects.

Inventions whose shape takes etc.

It can be used for construction of tanks on terrains, changing over time, for example due to undermining. settlement

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT OF THE REINFORCED CONCRETE FLOW CONTAINER ε The present invention is shown in the drawings, wherein FIG. 1 is a plan view of a multi-chamber flexible bottom tank; Fig. 3 is a cross-sectional view of the tank taken along the line II-III of Figs. 1 and 2; and Fig. 4 is a vertical cross-sectional view of a portion of the tank bottom in the vertical notch region. Fig. 6 is a vertical sectional view of another embodiment of the notch taken along a plane perpendicular to the longitudinal axis of the notch; and Fig. 7 is a vertical sectional view of the notch taken along IV-IV. 5.

229 306

The multi-chamber reinforced concrete tank consists of longitudinal peripheral walls 1, transverse peripheral walls 2, inner longitudinal partition walls 3, inner transverse partition walls 4 and a flexible bottom 5 according to the invention. In order to compensate for the subsidence of the subsoil, the longitudinal peripheral walls 1 and the transverse peripheral walls 2 are divided into smaller sections which are connected to one another by vertical expansion joints 6 of conventional construction.

The bottom 5 of the submersible reinforced concrete tank is also divided into smaller sections by vertical slits 7 extending into a part of the thickness of the bottom plate 5 and extending at least in the areas of the bottom 5 adjacent to the perimeter of the individual tank chambers.

In its lower part, each notch 7 extends above the base joint into the enlarged space of the chamber 71; thus, a weakened portion of the bottom plate 5 is provided by the bottom wall of the chamber 71 e by the base joint, which allows adjacent portions of the bottom 5 to pivot relative to each other.

When the bottom of the tank 5 is below the surface of the groundwater, the chambers 71 of the slots 7 at both end ends pass into the constriction 72 (FIG. 5) in which the conventional expansion seals 8 are received.

If the bottom 5 of the tank above the water level takes place in the chamber 71 of the same diameter to the region of the bottom plate ⁿ ^ "clutching where the face wire closed by a moisture and ingress of soil cover plate 9 /obr.7/.

Claims (3)

A flexible bottom of a flexible reinforced concrete tank, characterized in that it is provided with at least one notch (7) formed in the extension of the expansion joint (/) of the tank wall (1, 2, 3, 4) and terminating above the foundation (71) notch / 7 /. The flexible bottom according to claim 1, characterized in that the indentation chamber (71) is terminated at both end ends by a constriction (72). 3. The flexible base according to claim 1, characterized in that the indentation chamber (71) is closed at both ends by a seal (2) or a cover plate (9).