SU705060A1 - Concrete gravity dam - Google Patents

Description

(54) CONCRETE GRAVITATIONAL DAM

one

The invention relates to hydraulic engineering and can be used in the construction of concrete gravity dams in seismically active regions.

The design of an arched dam is known, which flat hydraulic jacks are placed in temperature-shrinkable seams 1. Longitudinal forces created by jacks increase the stability of the dam.

The disadvantages of this solution are the impossibility of transferring transverse forces (along the stream) through the seam with jacks, which makes this solution unsuitable for ensuring the spatial nature of the deformations of the gravity dam.

In this case, the installation of jacks is required not only in the central but also in other expansion joints.

The aim of the invention is to increase the strength of the structure by ensuring that the dam sections work together under the action of various loads, for example, as a result of seismic effects, temperature deformations of the sections.

This is achieved by the fact that pneumatic accumulators are installed in each seam, and the jacks are placed in pairs and at an angle of 30-45 ° to the longitudinal axis of the seam with the formation of two autonomous systems, each of which is hydraulically connected to the pneumatic accumulator and upstream.

FIG. , 1 shows a dam, a transverse section; in fig. 2 — node 1 in FIG. one; in fig. 3 - node. And in FIG. one; in fig. 4 shows section A-A in FIG. one.

The gravity dam concrete is divided into sections 1 by vertical expansion joints 2 with punches in which at 30–45 ° to each other and to the plane of the axis of the seam there are flat hydraulic jacks 3 and 4 connected by pipelines 5 and 6 in which valves 7 are installed and 8, with the upper reach and pneumatic accumulators 9 and 10, forming two hydraulic independent systems. Sensors 11 and 12 are installed in the pneumatic battery.

The device works as follows.

With the pressure of the jacking systems, the water is swirled with the upper one, after which the valves 7 and 8 are closed. In the case of water level in pneumatic accumulators 9 and 10, due to accidental leaks, the signals from sensors 11 and 12 include the actuators of the valves 7 and 8 and the water level is restored, after which the valves are closed.

When opening I1BOV 2 in the process of temperature deformations or as a result of earthquakes, the jacks 3 and 4 increase their volume under the action of the hydrostatic pressure of the upstream and provide air pressure. reduction of transverse forces (in the direction along the flow) through the seam.

When oscillations of sections I of the dam in the direction along the flow when ground in the close 1 hydraulic systems of jacks 3 and 4 alternately, depending on the direction of the relative movement of sections, the pressure increases. The additional forces that arise in the jacks redistribute the horizontal seismic loads along the direction of flow from the more loaded sections to the less loaded ones, providing the most spatial character of deformations of the npii earthquake structure.

Ensuring the spatial nature of the earthquakes on the dam external loads on the hydraulic system of hydraulic jacks. The workbench with the pressure of the upper substage, allows to reduce the amount of concrete of the gravity dam and preserve the safety margin.

Claims (1)

Invention Formula Concrete gravity dam with deformation seams in which flat hydraulic jacks are installed, characterized in that, in order to increase the strength of the structure by providing joint deformation of its sections under different loads, pneumatic accumulators are installed in each joint in pairs and at an angle of 30–45 ° to the longitudinal axis of the seam with the formation of two autonomous systems, each of which is hydraulically connected to the pnevmoakkumul Q with a torus and upper reach. Sources of information taken into account during the examination 1. The first pre-stressed arch. dam-in usa. Express-Information of the All-Union Institute of Scientific and Technical Information Hydropower, 1976, No. 18, p. 11-16. // z  / five J   FIG. 2 R  Th / I Avl / Ф (/ г.З x6 5 W