SU806830A1 - Three-dimensional roof - Google Patents

Description

The invention relates to the construction and is intended to cover civil buildings and structures in the form of hyperbolic paraboloids. _

Closest to the proposed ³ in technical essence and the achieved result is spatial coverage, including shells in the form of hyperbolic paraboloids, interconnected, with free vertices and vertices supported on columns at the same height above the reference plane [1].

The disadvantage of this coating is the presence of powerful buttresses, taking 1 large spacer or diagonal puffs, to eliminate a plate break in the middle of the span, since the surface of the coating has a horizontal straight line in the middle of the span along the large side of the plan, which leads to cost overruns and complicates installation .

The aim of the invention is to increase the bearing capacity and a stable * 5 ty coating with reduced material consumption and simplified installation.

This goal is achieved in that in the spatial coverage, including connected shells in the form of hyperbolic paraboloids with free vertices and vertices supported on columns, one of the free vertices along the “conjugation line of the shells is set down by 0.15-0, 30 boom lift relative to the reference plane.

Figure 1 - coating, General view; figure 2 is a plan of coverage; on Fig.3 section aa in Fig.2.

The spatial coating includes two identical shells 1 and 2 in the form of a hyperbolic paraboloid with peaks 3,4 and 5, resting on racks 6, with an average free vertex 7, located below the reference plane by 0.15-0.30 lifting boom, and external free peaks 8 and 9. located above the reference plane at a height of 4-15-4.30 boom lift. The surface of the coating does not contain a horizontal straight line. All sections parallel to the large side of the plan have an L ‘-shaped shape, which eliminates the possibility of a slab fracture, which makes it possible to simplify the design by excluding auxiliary elements (buttresses, tightenings).

Depending on the geometric dimensions and reinforcement of the structures, each case has its own value for lowering the average free vertex relative to the reference plane. It is calculated from the condition that the bearing capacity at a kink along a line parallel to the large side of the plan is equal to the bearing capacity according to the console ”scheme, ie maximum bearing capacity.

The decrease in the average free vertex relative to the reference plane reaches its maximum value with a minimum span, a minimum percentage of reinforcement, a maximum boom lift and the ratio R _M / ba, where R ^ is the concrete compressive strength under bending) θα is the yield strength of the reinforcement The proposed coating eliminates the need for buttresses and simplifies the construction, consumption

reinforcing steel is reduced by 30 • 50 ".

Claims (2)

The invention relates to construction and is intended to cover civilian buildings and structures in military, hyperbolic paraboloids. The closest to the proposed technical essence and the achieved result is a spatial coverage, including shells in the form of hyperbolic paraboloids connected to each other, with free vertices and vertices supported on columns at the same height above the supporting plane 1. The disadvantage of this coating is the presence of powerful buttresses, susceptible, large spreading or diagonal stubs, in order to exclude a plate fracture in the middle of the span, since the surface of the coating has a horizontal straight line in the middle of the span along the large side of the plan, which leads to cost overruns and complicates installation. The aim of the invention is to increase the bearing capacity and stability of the coating with reduced material consumption and simplified installation. This goal is achieved by the fact that in G1 spatial coverage, which includes interconnected shells in the form of hyperbaptic paraboloids with free vertices and vertices supported on columns, one of the free vertices along. the sheathing line is set with a 0.15-0.30 decrease in the boom of the boom relative to the reference plane. figure 1 - coating, general view; FIG. 2 is a plan; in FIG. 3, section A-A in FIG. 2. The spatial coverage includes two identical shells 1 and 2 in the form of a hyperbolic paraboloid with vertices 3,4 and 5, supported by pillars b, with an average free vertex 7 located below the reference plane by 0.15-0.30 lifting jib , and external free peaks 8 and 9., located above the reference plane at a height of 4-15-4.30 jib arrows. The surface of the pokralti does not contain a horizontal straight line. All sections, parallel to the large side of the plan, have a 1-Fold form, and therefore the possibility of a plate fracture is artificial, which makes it possible to simplify the design by means of ancillary elements (buttresses, tapers). Depending on the geometric dimensions and the reinforcement of the structure, the specific value of lowering the average free vertex relative to the reference plane corresponds to each specific case. It is calculated from the fact that the carrying capacity at fracture along the line parallel to the larger side of the plan is equal to the carrying capacity of the abilities according to the console scheme, i.e. maximum bearing capacity The value of the decrease in the average free top with respect to the reference plane reaches a maximum value with a minimum span, a minimum centrifugal reinforcement, a maximum lift arm and a ratio of RH / ba. where is the compressive flexural strength of concrete / (50 is the yield strength of reinforcement The proposed coating eliminates the need for buttresses and simplifies the construction of the structure, the consumption of reinforcing steel is reduced by 3050%. Invention formula Spatial coating including interconnected shells in the form of hyperbolic paraboloids with free vertices and vertices, supported on columns, of which it is so that, in order to increase the holding capacity and stability of the coating with reduced material consumption and simpler installation, one of the free vertices along the line of shell mating is set down by 0.15-0.30 boom of lift relative to the reference plane. Sources of information taken into account during the examination 1. Rüle G. Spatial Coverage M., Stroyizdat, 1974, v.2, p.237, fig.6.3.