CS255633B1 - Sprinkler - Google Patents

Abstract

The solution relates to a sprayer with a rotor, especially for irrigation of non-circular areas which uses fluid pressure to drive the rotor. The essence of the solution is that in the body of the sprayer is a conical chamber and in it is freely a rotatably mounted tapered portion of the rotor, which with its jacket follows the shape of the chamber. Flowing the liquid between the conical part of the rotor and the wall of the chamber utilizes hydrodynamic paradox, allowing contactless the rotor housing in the sprayer body. According to other character points, they are conical part of the rotor or head helical grooves. Alternatively, it is sprayer body solved as split, which allows variable surface spraying function different shape.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a sprayer which uses the energy of the pressurized water supplied to rotate the rotor.

In irrigation technology, different types of impact sprayers are used for irrigation, the orifice of which is provided with a nozzle or nozzles and is supported by an axial and radial bearing and is sealed by a mechanical seal. This production-intensive and complex design is replaced by fixed spray nozzles for the smallest sprayers, the disadvantage of which is uneven spraying. To ensure uniform spraying, sprayers are used in which spraying of distant surfaces is provided by nozzles in a rotating rotor.

Closer surfaces are then covered by conical spraying of liquid over the annulus formed between the sprayer body and the rotor shaft passing therethrough and extending above the sprayer body into the header. The head is formed by spraying and rotating the liquid while the rotary movement of the rotor is achieved by the pressure liquid supplied by tangentially drilled holes into the stream formed in the body, possibly by deflecting the head from the vertical axis. The disadvantage of this embodiment is the bearing of the rotor in the thrust bearing and unreliable operation in different positions.

The above-mentioned disadvantages are eliminated by the sprayer according to the invention, which uses the energy of the pressurized liquid supplied to rotate the rotor, consisting of a body housed and sealed in the lance and a rotor housed in its cavity. a widening conical chamber in which the inner conical portion of the rotor is freely received, the shape of which corresponds to the shape of the cavity.

Another object of the invention is that the body is divided and consists of a cap nut, a sealing washer, a flexible collar and an insert, the cavity being formed by the liner and the elastic collar.

It is a further object of the invention that helical grooves are formed on the rotor head.

Finally, it is an object of the invention that helical grooves are formed on the conical part of the rotor.

Compared to the sprayers used hitherto, the construction according to the invention achieves a higher effect in that the production-intensive mounting of the rotor in the thrust bearing is eliminated and a space for easier mounting of the filter is created. During operation of the sprayer, the rotor does not come into contact with the housing in the thrust bearing, so that wear is minimized.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS OF THE INVENTION are schematically illustrated in the accompanying drawings, wherein FIG. 1 is a vertical axial section through a sprayer, the right half of which shows the grooves in the conical part of the rotor and the left half shows the grooves in the rotor head. Giant. Fig. 2 is a cross-sectional view of the sprinkler of Fig. 1 taken on the line A-A; and Fig. 3 shows an alternative embodiment of the split body and groove sprayer in meridial section.

According to the invention the sprayer is formed by a body 2 which is mounted, for example screwed, in pipe 1 ^ on whose free end for sealing the inner chamber from the surroundings sealing gasket 2 · ^axis of the body 2 is a cavity 5 formed by the upwardly widening conical a chamber 51 terminated at the bottom by a blinded cylindrical bore 52 into which radial inlets 6 are introduced, the number and angular spacing of which is determined by the shape of the irrigated surface.

In the upper part, the cavity 5 is provided with supporting ribs 53 and terminates in the neck 54. In the cavity 5 of the body 2, the rotor 7 is loosely mounted, the shape of which follows the surface of the conical chamber 51 and the cylindrical bore 52. a shank 71 that continuously passes into the extended head 72. ^{in the axis of the} rotor 7 a channel is formed with a radial inlet 81 at the bottom.

The header 72 of the rotor T_ j ^e channel 2 is provided with two radial pins 82 on the rotor surface J7, either on the inside of the conical part 73, or on the head 72 are formed in the groove 2 · Size and shape of the cross section of the helical grooves 2 ^{and the} width of the joints between the body 2 and rotor 2 are chosen differently according to the flow rate and the pressure of the supplied liquid. A filter 4 is then attached to the lower part of the body 2,

In the alternative embodiment of the sprinkler of Fig. 3, the sprinkler body 2 is split and consists of a cap nut 22, a sealing washer 21, a flexible cuff 24, and an insert.

The conical chamber 51 is formed in the liner 22 'and the radial inlets 2 extend into this conical chamber 51. The support ribs 53 are then formed on the base of the conical part 73 of the rotor T and the neck 54 is formed in the flexible collar 24.

When the supply of pressurized fluid from the supply pipe ³ and 2 passed this gap between the body 2 and the rotor 2 ^and flows through the spray annulus formed between the portion 54 of the body 2 ^{and the} shank 71. In the embodiment according to FIG. 3, the width of the throat 54 formed in the elastic cuff 24 variable according to the quantity and pressure of the liquid supplied. It is then sprayed onto the rotor head 22 ^and irrigates the nearer part of the irrigated area. At the same time, at the moment of the radial inlet 81 of the channel 2 to the outlet 61 of the body 2, the pressurized liquid is guided through the channel 2 into the head 72 of the rotor 2 ^and irrigates the distal parts of the surface with maximum spray.

Rotational movement of the rotor 2 is achieved by utilizing the liquid pressure in the helical grooves 2 on the rotor 2. During start-up, before reaching the required velocity of liquid flow through the gap, clogging of the neck 54 is prevented by the inner conical portion 73 of the rotor T by supporting ribs 53 the fluid of the desired velocity, the hydrodynamic paradox is utilized, and the rotor 2 does not touch the sprayer body 2 with any part.

The described embodiments of the invention are not exhaustive. The radial outlets 82 of the channel 2 ^on the rotor head 72 can be made tangential to support the rotational movement of the rotor 2. Likewise, the radial inlets 2, outlets 61 and radial inlet 81 may be in various numbers and designs according to the requirements of the irrigated area, and the lower part of the body 2 with radial inlets 81 may be of a replaceable design. The radial inlet 21 can also be completely replaced by the axial outlet of the duct 2. In order to achieve suitable pressure conditions, the blind hole of the cylindrical bore 52 can also be omitted.

Claims (4)

SUBJECT OF THE INVENTION Sprayer, which uses the energy of the pressurized fluid to rotate the rotor, comprising a body housed and sealed in a supply tube and a rotor housed in its cavity, characterized in that the cavity (5) of the body (2) is formed in the fluid flow direction. an expanding conical chamber (51) in which the inner conical portion (73) of the rotor (7) is freely received, the shape of which corresponds to the shape of the cavity. Sprayer according to claim 1, characterized in that the body (2) is divided and consists of a union nut (22), a sealing washer (21), a flexible collar (24) and an insert (23), the cavity (5) being formed by an insert (23) and a flexible collar (24). Sprayer according to claim 1, characterized in that helical grooves (9) are formed on the head (72) of the rotor (7). Sprayer according to claim 1, characterized in that helical grooves (9) are formed on the conical part (73) of the rotor (7).