RU2373328C1 - Wave breaker - Google Patents

Abstract

FIELD: construction, hydrotechnical engineering.

SUBSTANCE: invention is related to hydrotechnical structures intended for suppression of waves energy. Wave breaker is made in the form of volumetrical structure including perforated front wall. Volume structure is made of a row of sections, every of which is made in the form of triangular prism with support side frames. One of sides represents a lateral wing suspended on axis of rotation. Each subsequent section in row relative to the previous one is turned by 180°. Lateral wing is made with perforation, and axis of rotation passes along upper edge of lateral wing.

EFFECT: invention makes it possible to provide for efficient suppression of wave energy, to reduce height of wave splash, to lengthen period of wave rolling, to increase prefabricability of structure.

2 cl, 4 dwg

Description

The invention relates to the field of hydraulic engineering and can be used to absorb wave energy.

Known wave attenuator, which is a rigid lattice support mounted on the bottom with an inclined wall located on it. The disadvantage of the wave suppressor is that the upper part of the wall rises above the water level and the waves, rolling on the wall, without overflow through it roll back. The bulkiness of the structure, low damping efficiency of the wave flow reduce the scope of this waveguard (US patent No. 2967398; Breakwaters, annotated review of inventions. L .: Energy, 1969, p. 15. Fig.19).

Closest to the invention is a pier of box construction with a perforated front wall. The disadvantage of this technical solution is cumbersome, the inability to change position (French patent No. 1289872; Mounting slopes of hydraulic structures. L.: Energy, 1968, p. 39, Fig. 39).

The technical result achieved by the present invention is to increase the efficiency of damping the wave flow, increasing the integrity of the structure.

This technical result is achieved by the fact that the waveguard is composed of a number of sections, each of which is made in the form of a triangular prism with supporting side frames, one of the sides is a sloping wall suspended on the axis of rotation, with each subsequent section in a row relative to the previous one deployed 180 °, in addition to the fact that the sloping wall is made with perforation, and the axis of rotation passes along the upper edge of the sloping wall.

Figure 1 shows a General view of the waveguard, consisting of a number of sections; figure 2 - one section in the closed position; figure 3 is the same in the open position; figure 4 is a part of a section without a sloping wall.

The suppressor consists of sections 1, including triangular support frames 3 located on the base 2, having an axis 4 in the upper part, to which the upper edge of the sloping wall 5 is attached with perforation 6. The supports 3 have connecting nodes 7, which allow the section to join with the section, and the base 2 - fasteners 8, allowing to fix section 1 on the bottom of the reservoir or on the slope of the dam.

The suppressor works as follows. Part of the section, including the base 2 and side support frames 3, with the help of fasteners 8 is installed in the wave zone on the gentle bottom of the reservoir (on the sea coast) or on the slope of the dam. Using the connecting nodes 7 sections are joined together in a row, growing to the required length and configuration. Using the axis 4, a sloping wall 5 is hung so that each subsequent section with respect to the previous one is turned 180 °.

At the time of wave run-up and impact, part of the flow is restrained by the slope wall 5 facing the wave, part passes through the perforation 6, and part flows into the adjacent section open to the wave, and if there is enough energy, it turns and raises the slope wall 5 around axis 4 and passes into the resulting gap and through the hole of the triangular support frames 3 (figure 3).

During the rollback, the wave bumps onto the sloping wall 5, facing the wave, and slams it, while opening the wall 5, facing the reservoir in the adjacent section.

Such operation of the wave attenuator allows to reduce the height of the wave run-up to the slope, to lengthen the period of wave rolling, which in turn allows to slow down the run-down time to the slope of the next wave due to the occurrence of the oncoming flow, and ultimately allows to increase the efficiency of wave energy quenching.

Claims (2)

1. The suppressor, made in the form of a three-dimensional structure, including a perforated front wall, characterized in that the three-dimensional structure is composed of a number of sections, each of which is made in the form of a triangular prism with supporting side frames, and one of the sides is a sloping wall suspended on axis of rotation, with each subsequent section in a row in relation to the previous one rotated 180 °. 2. The suppressor according to claim 1, characterized in that the sloping wall is made with perforation, and the axis of rotation passes along the upper edge of the sloping wall.

Images