RU2132611C1 - Superlow volume sprayer - Google Patents

Abstract

FIELD: agricultural engineering. SUBSTANCE: sprayer has frame carrying reservoir with working fluid solution, pipelines, leveling vessel with valve, airduct with pressure reducer and valve, sprinkler, feeding pipeline with injector nozzles. Sprinkler has jet forming device with slit-type air nozzle having two interconnected plates with layer between them. Layer has lemniscate-shaped portion positioned at circular inlet slit and rectangular outlet opening junction place. Inlet pipe is welded to upper plate at an angle exceeding 90 deg relative to nozzle axis and oriented in the direction of air flow. Such construction allows field crops and perennial plantations to be treated at low flow rate of solution. EFFECT: reduced consumption of power for operation of sprayer, reduced usage of solution and improved dispersity of spray beam. 2 dwg

Description

 The invention relates to agricultural machinery, mainly to sprayers for processing field crops and perennial plantings with small doses of the drug and the rate of flow of the working fluid.

 There are various designs of small (MO) and ultra-small (ULV) sprayers. So, for example, fan UMO OM-320, OM-630, OP-2000, etc. (analogues, see "Mechanization of plant protection". Reference / m 55 I.N. Veletsky, A.K. Lysov, N.S. Lepekhin et al. - M .: Agropromizdat, 1992, p. 71) have a complex and not sufficiently reliable design with a hydraulic drive of the spray heads. A more reliable design has a pneumatic-mechanical type ULV, for example a small-droplet knapsack sprayer ОМР-2 (analogue, see Danube NF and other Mechanization of plant protection. - M .: Kolos, 1979, p. 83).

 Even better quality indicators and simplicity of design are provided by an ultra-low-volume sprayer (UMO) (RU 2058740 C1, 04/27/96, prototype), which consists of a frame, an equalization tank, pipelines, an air duct and a jet-forming device with an ejector type sprayer connected to the tank.

 The disadvantage of the prototype is the insufficient laminarization of the air flow from the slotted nozzle in a pear-shaped form, which leads to different flow rates along the jet of the jet, which adversely affects the dispersion of the working fluid flowing through the nozzle.

In addition, when air is supplied through the air duct to the slotted nozzle, unnecessarily large local energy losses are observed, since air is introduced into the slotted nozzle at an angle of 90 ^° and the air flow rate decreases sharply.

 The disadvantages of the prototype are proposed to eliminate a new technical solution.

 The technical solution is to expand the technical capabilities of the sprayer by reducing energy consumption for the operation of the sprayer and improving the dispersion of the spray.

The technical problem is solved in that in a sprayer including a frame, a reservoir, an equalizing tank, an air duct with a pressure reducer and a crane; feed pipe with interchangeable nozzles; a sprayer having a jet-forming device with a slotted type air nozzle consisting of two fastened plates with a gasket placed between them, the upper plate of which has an inlet pipe installed at an angle greater than 90 ^o relative to the axis of the nozzle in the direction of air flow (V.V. Smyslov "Hydraulics, aerodynamics. - Kiev: Vishka Shkola, 1979, p. 194); and the gasket has a lemniscate profile of the transition from a circular inlet slit to a rectangular outlet of an air nozzle (Deutsch M.E." Technical gas dynamics ". - M. : "Ene Gia "1974, p. 281).

 Thus, in comparison with the prototype, the air flow through the sprayer is reduced to obtain the output characteristics of the air flow from the slot nozzle, similar to the prototype (speed, jet length).

 According to scientific, technical and patent information, the claimed combination of features has not been identified, which clearly follows from the existing level of technology, which allows us to conclude about the selective level of the invention.

 The invention is illustrated in the drawing, where in FIG. 1 is a flow chart of a sprayer; FIG. 2 is a sectional view A-A of the inkjet element.

 The sprayer includes a frame (not shown in the diagram) on which a tank 1 (see Fig. 1) with a working fluid solution is mounted, pipelines 2, equalization tank 3 with a valve 4, air duct 5 with a valve 6 and a gear 7 in communication with the spray gun 8 comprising a jet element 9 with a slotted type nozzle 10, consisting of two bonded plates 11 and 12, forming an oblique section.

The upper plate 12 has an inlet pipe 14 welded to it at an angle greater than 90 ^° relative to the axis of the nozzle to reduce local resistance when the airflow enters the slotted nozzle 10.

 Between the plates 11 and 12, a gasket 13 is placed to form an air chamber. The gasket profile is made in the form of a lemniscate or according to the Vitoshinsky type at the transition from a circular inlet cavity to a rectangular outlet slit.

 The working fluid flows to the nozzle 15 through the feed line 16 from the surge tank 3 to the mixing chamber 17 and then in the form of an airborne stream to the processing object.

 The sprayer works as follows.

 Air from a compressor or other source (not shown) enters the receiver, and from it into the constant pressure reducer 7 (Fig. 1). The compressed air outlet under a certain constant pressure is connected via air ducts 5 to the air nozzle of the jet element 9 of the overpressure of the atomizer 8. When air leaves the slotted nozzle 10 of the jet element 9, a vacuum is created in the mixing chamber 17. In this regard, from the reservoir 1 through the suction line 2 through the equalization tank 3 with the valve 4, the working fluid is ejected into the feed pipe 16 to the nozzle 15, mounted in the housing of the spray gun 8, and mixed with the air stream sucked by the jet element 9. The incoming air stream from a slit nozzle transports the working fluid in the form of small drops to the object being processed. Turn off the supply of working fluid is a plug valve 6 of the air duct.

 The rate of flow of the working fluid and the dispersion of the spray is controlled by changing the nozzles 15 of the feed pipe 16, by changing the air pressure using the gearbox 7 and by changing the angle of inclination of the pipe 16.

 The versatility of spraying is determined by the possibility of its use for the processing of field crops and perennial plantings with various working fluid flow rates.

Claims (1)

The ultra-low-volume sprayer, including a frame, a reservoir, equalizing capacity, an air duct with a pressure reducer and a tap, a feed pipe with replaceable jets, a spray gun having a jet-forming device with a slotted air nozzle consisting of two bonded plates with a gasket placed between them, characterized in that the upper plate has an inlet tube mounted at an angle greater than 90 ^o, relative to the nozzle axis in the direction of air flow, and lemniskatny gasket has the profile of a transition ugovoy entrance slit to a rectangular air outlet nozzle.

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