SU975101A1 - Sprinkling nozzle - Google Patents

Description

(54) RAINBOW

The invention relates to the spraying of liquids and can be used in agriculture for irrigation by ordinary sprinkling and finely dispersed spraying of the earth.

Known spray liquid, which is provided with a control valve in the form of a cylinder rigidly connected with a screw rod with a beveled end surface located at an angle of 15-45 ° to its axis 1.

However, such a nebulizer does not provide an unaccented spray of liquid, it irrigates a limited area, since the output channel is a regular tube that does not change its parameters.

The closest to the proposed i by technical essence and the achieved effect is a sprinkling nozzle, including a housing with an outlet channel and racks, on which a screw deflector 12 is attached to the screw POM01CH.

A disadvantage of the design of this pre-docking attachment is the difficulty of adjusting to a given mode of operation in view of specific conditions.

The aim of the invention is to simplify the operation of the sprinkler.

This goal is achieved by the fact that in the sprinkler nozzle, including a housing with an outlet channel and racks on which a deflector is fixed with a screw, the latter is made in the form of a polyhedron fixed on the screw so that it can rotate around the axis of the screw and fix its position.

10 is mounted in a rack perpendicular to the axis of the outlet channel, and each face of the deflector is made with different shaped profiles.

15

FIG. 1 shows a sprinkler attachment, general view; in fig. 2 shows section A-A in FIG. one; in fig. 3 is a view B in FIG. 4 1.

Sprinkler head includes

20 housing 1 with an outlet channel 2 and columns 3 on which the deflector 5 is fastened with a screw 4 in the form of a polyhedron with shaped profiles a, b, c, d (straight cone, flat surface, figured surface and reverse cone) . A screw 6 with calibrated holes 7 is located in the housing 1. The deflector 5 can be rotated around the axis of the screw 4 and fixed in

30 certain position, and screw 4 in

The racks 3 are installed perpendicular to the axis of the output channel 2.

The device works as follows.

The liquid, the passage through the corresponding calibrated orifice 7 along the output channel 2, falls on a certain shaped profile of the deflector 5, comes off it and receives co. proper direction of movement.

Depending on the specific conditions, the shaped profile a, b c and d is positioned against the output channel 2, for which screws 4 are first loosened, the deflector 5 is re-turned and secured from spontaneous turning by the same screws 4. So, in windy weather the deflector 5 with a shaped profile a (straight cone), which allows you to direct the ra: spraying liquid- at an angle to the irrigated surface and thereby drastically reduce its demolition by the wind. When the wind is weak, use a flat surface b. At first, the liquid flows around the conical protrusion, then continues to move along the flat part of the deflector 5, comes off it, and, striking air, splits off into drops, which subsequently change the horizontal movement to a curvilinear one and fall on the irrigated surface under its own weight, moistening significantly square.

In calm weather, when, as a rule, the air temperature is highest, it is necessary to moisten not only the soil and plants, but also the surface air layer in order to create the most favorable conditions for the growth and development of plants. In this case, use the surface with. The liquid flows around the cone first, then the profile part of the deflector 5 and smoothly reverses its direction to a certain angle. To the horizon, it leaves and disintegrates into droplets, which under their own weight of the parabolic curve descend onto the irrigated surface. When irrigating high-stem cultivated agricultural crops such as maize, the d-surface is a reverse cone, which also provides a low head in the system and the location of the nozzles near the plants after the flow and the subsequent dropwise liquid distribution according to the type of operation of hose outlets when irrigated, for example, vegetables.

Thus, the proposed nozzle provides the ability to adjust to a given mode of operation, taking into account

specific conditions. The nozzle is easy to handle and reliable in operation. Low cost, ease and anti-corrosion due to the possibility of stamping from polymeric materials favorably distinguishes the proposed nozzle from known ones.

Claims (2)

1. USSR author's certificate No. 621384, cl. B 05 B 1/34, 1978. 2. USSR Author's Certificate for Application No. 2929495 / 23-05, cl. B 0.5 B 1/26, 1980 (prototype).