SU1109091A1 - Drip feed - Google Patents

Abstract

DROPPER, containing a housing with inlet and outlet and a membrane, characterized in that, in order to increase reliability in operation when the pressure in the network changes and there is mechanical impurities in irrigation water, the inlet and outlet are located in the supermembrane cavity, while the dropper inlet is made in The shape of a curved nozzle, the inner end of which is installed perpendicular to the membrane and concentric with it, and provided with a cap associated with the membrane that has a side slot. (L

Description

11 The invention relates to agriculture and is intended for use on drip irrigation systems. A known dropper comprising a housing with inlet and outlet nozzles and an elastic membrane in the dropper cavity mounted rotatably in the horizontal plane TI 3 However, the dropper does not provide self-regulation of flow in a wide range of pressure variations in the network. A dropper is also known, containing an inlet and outlet body and a C 2 membrane. The disadvantage of the known dropper is that the water in it passes successively through a small gap into the submembrane cavity, the presence of a spring in which contributes to the accumulation of mechanical inclusions and then through small holes into the cavity of the rod and from the cavity of the rod. The dropper then becomes clogged. The use of a spring in the submembrane cavity in combination with a membrane device that includes two membranes limits the ability of flow to self-regulate when the pressure in the network varies over a wide range. The purpose of the invention is to increase the reliability of the dropper. When the pressure in the network changes and there are mechanical impurities in the water, this goal is achieved by the fact that in the dropper comprising a housing with inlet and outlet and a membrane located between the housing and the lid, the inlet and outlet are located in at the same time, the outlet of the dropper is made in the form of a curved bend nozzle, the inner end of which is perpendicular to the membrane and concentric with it and supplied with a cap connected to the membrane having a lateral right cut The drawing shows the proposed dropper. The dropper comprises a housing 1, a crush 2 and a membrane 3. The housing 1 in the supermembrane cavity 4 is provided with an inlet in the form of a curved nozzle 5 and an outlet 6. The inner end of the stem 5 is deployed relative to the membrane 3 perpendicular to its plane and is located concentric with it. On 1. 2, an inner end of the curved pipe 5 is provided with a cap 7 with a side slot 8 and connected via a flexible connection 9 to the center of the membrane. The width of the side slot 8 can be variable or constant in height. The cap 7 can be fixed rigidly on the membrane 3. In the bridge 2 of the dropper there is a drain hole 10 with access to the atmosphere. During operation, water is pushed into the dropper through the inlet 5. The network pressure of the cap 7 is pressed from the end of the curvilinear nozzle 5, the water through the gap formed enters the supermembrane cavity 4 of the dropper, from where it passes through the opening 6 to irrigation. Self-regulation of flow is provided as follows. With increasing pressure in the network, the cap 7 is pressed by a large amount, which leads to a decrease in the losses in the gap and, accordingly, to a certain increase in pressure in the drip cavity. An increase in pressure in the dropper cavity results in c. turn to increase the force acting from the membrane to cover the exit slit. Due to the fact that the area of the membrane is much larger than the area of the outlet of the nozzle, the pressure in the dropper cavity will vary slightly, which ultimately causes a slight change in the dropper flow rate with significant changes in the pressure in the network. Throttling the pressure in the gap between the cap 7 and the outlet end of the nozzle 5 provides in the dropper outlet 6 a low pressure mode, which allows its relatively large diameter (about 1-2 mm) and significantly reduces the likelihood of clogging. The clogging between the cap 7 and the loose end of the nozzle 5 during the operation of the gap leads to a decrease in pressure in the overmembrane cavity 4, the deflection of the membrane 3 decreases, the cap 7 rises, the flow area increases and the blockage of the plug closes. Each time the dropper is turned on, it will automatically work.

31109091

prophylactic washing due to the proposed dropper it is reasonable that, at the time of inclusion, it is different for use as

the dropper's bones pressure is absent from water outlets of the irrigation network with

e.-automatic hydraulic system. The design of the proposed control, the dropper, virtually eliminates the possibility of clogging, as well.

the likelihood of her failing to work from zapiv, ensured by

clogging is minimized. The proposed dropper, under conditions

Lagam dropper Provides large irrigated areas to ensure stable fluid flow with significant savings in pressure, network and self-flushing.

Claims (1)

A DROPPER containing a housing with an inlet and an outlet and a membrane, characterized in that, in order to increase operational reliability when the pressure in the network changes and mechanical impurities are present in the irrigation water, the inlet and outlet are located in the supmembrane cavity, while the inlet of the dropper is made in the form a cranked nozzle, the inner end of which is installed perpendicular to the membrane and concentric with it and equipped with a cap with a membrane, a new slot. bound having side 1 1109091