DE3023558A1 - Siphon weir continuous flow regulation - involves automatic float controlled venting mechanism varying air intake opening - Google Patents

Abstract

Continuous regulation of through-flow in siphon weirs is provided by an automatic venting device with a float control. An air intake aperture (D) is continuously varied in area, with float (F) regulation, in accordance with upstream conditions. This permits a set supply of air into a siphon weir (H) enabling a volume of water carried to it to be carried away in a stationary condition. A float may rise and fall, depending on upstream conditions, with movement via a rod linkage system causing the area of the air intake aperture to change.

Description

Title: Automatic, float-controlled ventilation controls

direction for continuous flow control in siphon weirs area of application: The invention can defend in all habits with different weir widths and drop heights be applied.

Purpose: The purpose of this invention is to run through a continuously variable addition of air at the top of the siphon to ventilate the siphon weir so that at only slightly fluctuating headwater levels any amount of water within the performance limits of the siphon weir can be removed in a stationary manner.

Prior art, criticism: It is known that a break in the water flow in a full siphon weir by adding air at the siphon apex on the one hand a certain structural arrangement of the inlet trumpet on the other hand by the Arrangement of funnel-shaped or otherwise shaped end cross-sections of the air duct can be effected depending on the surface water level.

But these arrangements have not yet emerged, a continuous one steady state of flow between free raid, partial siphon and full To achieve siphon flow.

All previous controls work discontinuously more or less strong upstream Fluctuations; she only cause a repeated break-off of a full siphon flow.

Task: There is now the task of a siphon flow through an automatic, continuously variable ventilation at the top of the lifter control that any amount of jasser approaching the siphon weir is stationary (without abrupt change between the flow states, full siphon flow - tear the siphon flow) is discharged. The task should be as low as possible on the upstream side Fluctuations can be coped with with the invention described below.

Solution of the task and examples: (without claim to the correctness the geometric relationships in the attached sketch) The invention is based on a Example shown in Fig. 1 and Fig. 2 explained.

If the upper water level exceeds the siphon crown G of the siphon weir H, how does the amount of water flow Q? Q1 at the headwater level A over the siphon weir away. An air evacuation in the top of the siphon and an associated full of the Hebers cannot take place, however, because a certain amount of air QL1 via the air line C is fed to the siphon weir. Air is supplied through the air inlet opening with the area D1, which can be changed by a height-adjustable plate E. The change in the area D1 and the associated reduction in the amount of air Li success depends on the surface water level, since the height-adjustable Flatte is firmly connected to the float F. Increases the approaching the lifting contact If the amount of water at Q2 (Fig. 2) is reached, the upper water level rises by the amount #H the water level B. This change in water level causes a shift in altitude of the float F and thus also of the plate E, and the air inlet opening becomes reduced to area 2. This means that the siphon weir can handle the increased oil quantity Q2 discharge stationary.

Within a given headwater level difference, the Air inlet opening in its area from a maximum to the amount zero accordingly the SchwZmrilerssellun9 changes and thus the amount of air that the siphon apex flows in, regulated. This metered air supply enables a stationary siphon weir flow for various siphon weir inflows.

Another example of the upper water level-dependent area regulation the air inlet opening is shown in Fig. 3 and Fig. 4.

Two discs I and 3 have air inlets and give depending on mutual rotation, the surface D3 free. The disk I is firmly mounted and the disk D is mounted above the disk I so that it can rotate freely at the pivot point K. If the headwater level changes from A to B by the amount H, then it changes the position of the float F, which is firmly connected to the disk 3 and causes a rotation of the disk B by the angle α. By twisting the disc 3, the area D3 becomes the area D4 and the air volume QL1 becomes the air volume qL2 decreased. In this example, too, is therefore within a given headwater difference the air inlet opening in its area from a maximum to the amount zero accordingly the float position changed.

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Claims (2)

Claims: 1) Generic term: Automatic, float-controlled Ventilation device for continuous flow control in lift contacts Part: characterized in that an air inlet opening is dependent on the surface water level, Float-controlled continuously changes in its area and thus a Enables a certain air supply to a siphon weir, so that one approaches the siphon weir amount of water can be discharged stationary. 2) Generic term like 1y characterizing part: characterized, that a swimmer rises and falls depending on the surface level, and this bending A linkage is used to translate the area of the air inlet opening or to change it by turning.