RU2278922C1 - Automatic hydraulic gate - Google Patents

Abstract

FIELD: hydraulic engineering, particularly means to close water-discharge weir or dam orifices and to regulate water level in water storage pond.

SUBSTANCE: automatic hydraulic gate comprises counterweight and rotary sheet performing rotation about horizontal axis and having working chamber located over the axis of sheet rotation. The working chamber comprises adjustable water intake means. Drainage orifices are created in working chamber from lower pool side. In closed state the sheet may be supported by weir still and by spillway piers so that the sheet is inclined towards lower pool. In opened state the sheet may be supported by spillway piers. Water intake means may be filled with water from upper pool and has inlet orifice located over axis of sheet rotation. Inlet water intake means orifice may be arranged above overflow ridge of the sheet.

EFFECT: increased operational reliability and prevention of water level elevation in upper pool over predetermined mark.

2 cl, 5 dwg

Description

The invention relates to hydraulic engineering and can be used to block spillways in the body of dams and dams and regulate the water level in the reservoir.

A device for regulating the water level in a reservoir is known, which is a blocking element mounted on the crest of one of the weirs, formed by at least one solid block, which is made easily breakable or tilting with a design water pressure corresponding to the maximum level of the upper pool (UVB _max ) during emergency high water (RU 2080433, 1997).

A disadvantage of the known device is the complexity of its recovery.

It is known to use valve closures for closing the aperture of retaining structures, including a panel with a horizontal axis of rotation mounted on the flute of the structure (Handbook of Hydrotechnics, M., Selkhozizdat, 1955, p. 699, Fig. 26-29). The control of such a shutter is carried out by means of additional devices: winches, manual drives, levers, etc., which is very laborious.

An automatic shutter is known in the form of a flat shield rotating around a horizontal axis and laying on a flatbet at a certain level of the upper pool (SU 18291, 1930).

The disadvantage of this shutter is the presence of a large number of levers, rods, props and hinges that are in a damp state, which determines the short life and unreliability of its service. In addition, the calculations show that such a shutter cannot automatically return to the closed state and in the closed position it is unstable due to the fact that the support included in its design and having a hinge in the middle works to compress and the slightest violation of its straightness leads to actuation shutter. The disadvantage of this shutter is also that it can only be set to one level of the upstream and cannot be adjusted to another level.

A hydraulic shutter is known, including a span with a horizontal axis of rotation located on the flatbut, while the span is made in the form of a hollow trihedral prism, the two smaller faces of which face the flatbet towards the upstream, and there are two holes on the larger side (SU 636321, 1978). The shutter works like a float, flooded when filling the cavity inside the prism.

The above shutter allows you to automatically provide a given water level, however, it is unstable in the open position in the stream. In addition, its response depends on the level of the downstream, which, as a rule, is not determining. The location of the holes through which water enters the shutter on the bottom casing may cause the shutter to operate in off-design conditions due to water overflowing through the comb of the prism.

The technical result achieved by the invention is to ensure the reliability of the shutter and prevent the rise of the upstream level above the set mark.

The essence of the invention is to achieve the specified technical result in an automatic water shutter containing a shield mounted with the possibility of rotation on the horizontal axis and mounted on the gobies of the dam with internal cavities and a water intake chamber and having an overflow ridge, while the upper chamber is working and has drainage holes, made from the downstream side and is connected to the lower chamber having an adjusting flap with a water intake chamber located on the overflow crest of the shield It is adapted to support on the threshold dam shield at oblique position toward downstream and has a counterweight, and the upper edge of the water intake regulating valve chamber is located above the overflow crest shield.

In a preferred embodiment, the intake chamber is located on 1 / 10-1 / 20 of the overflow crest of the shield.

The invention is illustrated by drawings, where in Fig.1 shows the shutter sideways in the closed state, Fig.2 is the same in the open state, Fig.3 is a shutter from the upstream side, Fig.4 is a shutter operation stage, where I - the shutter is closed, there is no overflow, II - the shutter is stably closed, the flow is overflowing through the shutter ridge, III- the filling of the working chamber has begun, overflow is in progress, IV - the working chamber is full, the shutter has opened, is stable in the horizontal position, V - there is no overflow from above, there is emptying the working chamber, after which the shutter is automatically set tsya in the closed position, figure 5 - the principle of operation of the shutter.

Automatic water shutter contains a shield mounted rotatably on the axes 1, which are fixed in the bulls 2 of the dam. The shield has an upper skin 3 and a lower skin 4, between which the cameras are located. The upper part of the shield is an overflow ridge. The working chamber 5 is located above the axis of rotation of the shield and consists of separate sections communicating with each other through holes 6, and has drainage holes 7 made in each of the sections in the lower casing 4, i.e. from the downstream side. The working chamber 5 through the hole 8 communicates with an adjustable water intake means, which is a water intake chamber 9 having a shutter 10 installed with the ability to control the size and height of the water intake hole 11, i.e. inlet. The inlet of the intake means is located above the axis of rotation of the shield, and structurally the intake means can be located both on the shield and on the overflow crest of the shield. In a specific embodiment (FIG. 1), the intake is located on the overflow ridge of the shield, occupies 1 / 10-1 / 20 of its part, while the upper edge of the adjustment flap 10 of the intake chamber 9 (i.e., the inlet) is located above the overflow ridge shield. The inlet of the damper is configured to fill with water from the upstream, i.e. located on the side of the shield, which, when installed on the dam, will face the upstream.

The shield along the length is made possible to support in the closed state the lower chamber 12 on the dam threshold 13 with an inclination towards the downstream, and in the closed state, the shutter is stable in position by supporting it not only on the dam threshold, but also on the gobies 2 by means of axes 1. B a counterweight is installed in the lower chamber 14. Structurally, the lower chamber can have as many sections as in the working chamber, and in each of them a counterweight can be installed. The angle of the shield is calculated by the sum of the moments.

The area of the drainage holes 7 is an order of magnitude smaller than the area of the water inlet 11. The volume of the working chamber and the weight of the counterweight are determined by calculation based on the specific dimensions of the shield, the maximum pressure and the span to be blocked.

The shutter works as follows (for the case of the location of the intake on the overflow crest of the shield, and the inlet of the shutter is located above the overflow crest).

In the closed state (when the shield rests on the threshold of the dam and the bulls), the shutter stability is ensured by the fact that the resultant R of all hydrostatic forces, the counterweight and the shutter weight creates a moment M + that keeps the shutter in the closed position (Fig. 5) (I and II in Fig. .four). This state is maintained even when the flow overflows through the overflow ridge of the shutter until water begins to be poured into the working chamber of the shutter through the hole 11 in the intake chamber and then through the hole 8 in the working chamber (III in Fig. 4). The installation of the shutter 10 of the intake chamber corresponds to a predetermined maximum mark of water in the reservoir.

After filling the working chamber with water, the sum of the moments of hydrostatic forces and the weight of the gate with the counterweight becomes negative, i.e. the overturning moment M- (shown by the dotted line in Fig. 5) exceeds the holding one, the shutter rotates on the axes and fits horizontally with the support of the bulls, opening the hole of the dam for the flow both under and over the shutter (IV in Fig. 4). In Figs. 3 and 4, BWF _max is the maximum level of the upper pool, and NPU is the normal retaining level.

A layer of water overflowing from the dam and the weight of water in the working chamber keep the shutter pressed against the gobies in a horizontal open position.

As a result, the water level in the reservoir decreases, and the overflow of water over the shutter stops, the working chamber is emptied through the drainage holes (V in Fig. 4), and the sum of the moments of force becomes positive, which causes the shutter shield to return to the closed position.

In specific operating conditions, the shutter is installed in the necessary position for the shutter to operate.

When the inlet of the intake means is located above the overflow crest of the shield, the shutter operates with overflow until the level of the upper pool of the inlet of the inlet means is reached.

The described design features of the shutter automatically prevent the rise of water in the reservoir above a predetermined maximum level of the upstream, and the absence of any kinematic relationships in it and its complete automatism and the ability to operate only from the water stream makes the structure extremely reliable, which is important due to the fact that the latter time due to changes in climatic and environmental conditions, breakthroughs of dams, accidents with spillways and floods became more frequent.

In addition, conventional valves require the supply of electricity, lifting mechanisms, personnel to bring them into action. In extreme flood conditions, blackouts, malfunctions of lifting mechanisms, negligence and lack of discipline of personnel, lack of access to gates, etc. are possible.

The shutter according to the invention can be installed at remote sites that do not have access to electricity, far from populated areas, since it does not require maintenance and operates automatically. Any number of gates can be installed on the dam, and the sequence of their operation and the number of triggered gates at any level can be selected in accordance with the predicted flood and restrictions on the levels of flooding and discharged discharge.

Claims (2)

1. Automatic water shutter, characterized in that it comprises a shield mounted rotatably about a horizontal axis with a working chamber located above the turning axis and having an adjustable intake, and a counterweight, drainage holes are made in the working chamber from the downstream side, the shield being made with the possibility of support in the closed state on the threshold of the dam and the gobies with an inclination towards the downstream and support in the open state - on the gobies, and the intake means is made with the possibility of water filling from the upper pool and its inlet is located above the axis of rotation of the shield. 2. The shutter according to claim 1, characterized in that the inlet of the intake means is located above the overflow crest of the shield.

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