RU2760752C1 - Liquid spraying device - Google Patents

Abstract

FIELD: agriculture.

SUBSTANCE: invention relates to agriculture, in particular to devices for spraying liquid mineral fertilizers, pesticides and other agrochemicals. The device contains a housing 1, a cylindrical chamber 2 with a channel 3 for supplying a working fluid and an air chamber 4 with a tangential channel 5 for supplying air. The device also contains a linear actuator 6 with a vertical rod 7, a deflector 8 in the form of a body of revolution with a deflecting surface 9 and a cylindrical shank 10, a nozzle channel 11 for supplying air to a deflector 8, a nozzle chamber 12 for a working fluid, a liquid fairing 13 connected to the rod 7 of the actuator 6, insert 14, nozzle 15 with an elliptical outlet for spraying liquid, vertical channels 16 for supplying the working fluid to the nozzle chamber 12. The air chamber 4 is made toroidal, coupled with the nozzle channel 11 with an annular hole for air supply to the deflector 8. The deflector rotation body is made along the generatrix in the form of an arc 20 of an ellipse 21. The end part of the deflector 8 is provided with a linear circular surface 22 of air escape. The liquid nozzle 15 is made in the end face 23 of the deflector 8 and is associated with the nozzle chamber 12 in the form of an ellipsoid of revolution. The liquid fairing 13 is located inside the nozzle chamber 12 and is made in the form of an ellipsoid of rotation coaxially and equidistantly to the ellipsoid of rotation of the nozzle chamber 12. The maximum spray angle β of the liquid nozzle 15 is at least less than the minimum spray angle of the air flow α of the deflector 9.

EFFECT: use of the invention will improve the quality of liquid atomization.

1 cl, 4 dwg

Description

The invention relates to agriculture, in particular to a device for spraying liquid mineral fertilizers, pesticides and other agrochemicals with a controlled consumption and a given quality for their differentiated application.

Known is a pneumohydraulic spray of pesticide solutions containing an air duct in the form of a cone-shaped diffuser, a cone-shaped air flow divider, two slotted spray nozzles of the working fluid made with a truncated secant plane, installed in such a way that drops are introduced into the air flow in the form of a sector (Patent RU 194076, IPC A01M 7 / 00, 2019).

The disadvantage of the known device is the inability to regulate the flow rate and the degree of dispersion of the sprayed liquid, which does not allow the use of the known device for differential application, when using the known device, droplets are deposited on the treated surface under the action of gravitational forces, and due to the low sedimentation rate, drift takes place small drops outside the treated area by wind and oncoming air flow when the sprayer is moving. This causes pollution of the environment, leading to burns to other crops and plants near the processing area.

A device for spraying a liquid is known, comprising a housing with a collecting cavity with an opening for supplying a working gas, a branch pipe installed in the housing, covered by a collecting cavity with channels for supplying liquid, while at least two nozzles connected to the collecting cavity are located in the lower part of the housing along a circle about the axis of symmetry of the branch pipe; a fairing is installed coaxially to the axis of symmetry of the branch pipe;

The disadvantage of the known device is the lack of the possibility of automatic stepless regulation of the flow rate of the working fluid in accordance with the program for the processing of the agricultural field, which makes it difficult to use it on machines for differentiated application; air flow when the sprayer is moving. This leads to pollution of the environment with agrochemicals above the maximum permissible concentrations.

The technical objective of the invention is to improve the quality and efficiency of the application of mineral fertilizers, pesticides and other agrochemicals, to reduce their application rates, to reduce the risks of environmental pollution by creating a device for spraying liquid mineral fertilizers, pesticides and other agrochemicals with automatic flow control, providing.

The technical problem posed is achieved by the fact that in a device for spraying a liquid containing a body, a cylindrical chamber made in it with a channel for supplying a working fluid and an air chamber with a tangential channel for supplying air, a linear actuator with a vertical rod, a deflector in the form of a body connected to the body rotation with a deflecting surface and a cylindrical shank, a nozzle channel for supplying air to the deflector, a nozzle chamber for a working fluid, a liquid fairing connected to the actuator rod, an insert, a nozzle with an elliptical outlet for spraying a liquid, vertical channels for supplying a working fluid to the nozzle chamber According to the invention, the air chamber made torus-like with the surface of the open torus and tangential air supply is equipped with a nozzle channel made conoidal, conjugated with one fourth of the lower surface of the torus, the outlet part of the nozzle channel and the surface of the cylindrical xv the deflector frame is made with the formation of an annular hole for supplying air to the deflecting surface, the deflector rotation body with an elliptical arc-shaped generatrix bounded by adjacent vertices of an ellipse with a long axis parallel to the longitudinal axis of symmetry of the device, while the end part of the deflector is equipped with a linear circular surface of air outlet, and the liquid nozzle is made at the end of the deflector and is coupled with the nozzle chamber, the nozzle chamber is made in the form of an ellipsoid of revolution with a long axis perpendicular to the longitudinal axis of symmetry of the device, parallel to the longitudinal axis of the liquid nozzle and a vertical axis coinciding with the longitudinal axis of symmetry of the device, the liquid fairing is placed inside the nozzle chamber and is made in the form of an ellipsoid of rotation coaxially and equidistantly to the ellipsoid of rotation of the nozzle chamber, the difference in the lengths of the vertical semiaxes of the ellipsoid of rotation of the nozzle chamber and the ellipsoid of rotation of the liquid fairing is at least not less than the depth of the slot, determining the depth of opening of the liquid nozzle, while the maximum spray angle of the liquid nozzle is at least less than the minimum spray angle of the air flow of the deflector.

The invention is illustrated by drawings.

FIG. 1 shows a longitudinal section of a device for spraying a liquid; in fig. 2 shows a cross-section AA of the device in FIG. one; in fig. 3 shows a view B of the device in FIG. one; in fig. 4 is a direct view of the device of FIG. one.

The device for spraying liquid contains a housing 1, made in housing 1, a cylindrical chamber 2 with a channel 3 for supplying a working fluid and an air chamber 4 with a tangential channel 5 for supplying air, a linear actuator 6 with a vertical rod 7, a deflector 8 connected to the housing 1, made in the form of a body of revolution with a deflecting surface 9 and a cylindrical shank 10 connected to the housing 1, a nozzle channel 11 for supplying air to a deflector 8, a nozzle chamber 12 for a working fluid, a liquid fairing 13 connected to the rod 7 of an actuator 6, an insert 14, a nozzle 15 with an elliptical outlet for spraying liquid, vertical channels 16 for supplying the working liquid to the nozzle chamber 12.

The air chamber 4 is made torus-shaped with the surface of the open torus 17 and the tangential air supply through the tangential channel 5. The nozzle channel 11 for supplying air to the deflector 8 is made conoidal and mated with one fourth of the lower surface of the torus 17, while the outlet part 18 of the nozzle channel 11 and the surface of the cylindrical shank 10 forms an annular hole 19 for supplying air to the deflecting surface 9 of the deflector 8, and the body of rotation of the deflector has a generatrix in the form of an arc 20 of an ellipse 21, bounded by adjacent vertices A ₁ B _{1 of an} ellipse 21 with a long axis A ₁ - A ₂ parallel, and the minor axis B ₁ - B ₁ , perpendicular to the longitudinal axis of symmetry Y - Y of the device. The end part of the deflector 8 is made with a linear circular surface 22 of the air outlet. The liquid nozzle 15 is made in the end face 23 of the deflector 8 and is coupled with the nozzle chamber 12, which is made in the form of an ellipsoid of revolution with a long axis c ₁ -c ₁ perpendicular to the longitudinal axis of symmetry Y - Y of the device, parallel to the longitudinal axis dd of the liquid nozzle 15 and the vertical axis n ₁ -n ₁ , coinciding with the longitudinal axis of symmetry Y - Y of the device. The liquid fairing 13 is located inside the nozzle chamber 12 and is made in the form of an ellipsoid of rotation with axes c ₂ -c ₂ and n ₂ -n ₂ coaxially and equidistant to the ellipsoid of rotation of the nozzle chamber 12, and the difference in the lengths of the vertical semiaxes o-n ₁ and on _2, respectively, of the ellipsoid rotation of the nozzle chamber 12 and the ellipsoid of rotation of the liquid fairing 13 not less than the depth h of the slot, which determines the depth of opening of the liquid nozzle 15. The maximum spray angle β of the liquid nozzle 15 is at least less than the minimum spray angle of the air flow α of the deflector 8.

The sum of the depth h of the slot and the value of the difference in the lengths of the vertical semiaxes o-n_oneand o-n₂and determines the stroke of the rod 7 of the linear actuator 6.

The implementation of the deflector 8 in the form of a body of revolution with a generatrix in the form of an arc 20 of the ellipse 21 provides the lowest aerodynamic resistance when the air flow around it.

The execution of the final part of the deflector 8 with a linear circular surface 22 of air discharge allows maintaining a given vector of air flow from the deflector and a hollow circular spray of air with a stable spray angle α.

The execution of the air chamber 4 is torus-shaped with the surface of the open torus 17 and tangential air supply, and the nozzle channel 11 for supplying air to the deflector 8 is conoidal and conjugated with one-fourth of the lower surface of the torus 17 with an annular hole 19 allows air to swirl in the chamber 4, giving it a rotational motion, combined with translational movement in the conoidal channel 11, to focus the air flow when it is supplied to the deflector 8, to ensure good dynamic stability of the flow on the deflector 8, to reduce the loss of flow energy when passing the conoidal nozzle 11.

The annular hole 19 for supplying air to the deflector 8 ensures a uniform supply of air flow with a given density.

Implementation of the liquid nozzle 15 mated with the nozzle chamber 12 in the form of an ellipsoid of revolution with a long axis c ₁ -c ₁ , perpendicular to the longitudinal axis of symmetry Y - Y of the device, parallel to the longitudinal axis dd of the liquid nozzle 15 and the vertical axis n ₁ -n ₁ , coinciding with the longitudinal the symmetry axis Y - Y of the device, and the placement of the liquid fairing 13 inside the nozzle chamber 12, made in the form of an ellipsoid of revolution with the axes c ₂ -c ₂ and n ₂ -n ₂ coaxially and equidistant to the ellipsoid of rotation of the nozzle chamber 12 with the difference in the lengths of the vertical semiaxes o- n ₁ and on _2, respectively, of the ellipsoid of rotation of the nozzle chamber 12 and the ellipsoid of rotation of the fairing of the liquid 13, not less than the depth of the slot h of the liquid nozzle 15, allows to adequately regulate the flow rate of the working fluid, the dispersion of the spray, the liquid distribution diagram in the automatic mode.

The condition that the maximum spray angle β of the liquid nozzle 15 is at least less than the minimum spray angle of the air flow α determines that the spray of the working fluid during its dispersion will always be inside the air spray, which in turn protects the dispersed liquid from external influences, such as wind, oncoming air flow from a mobile machine. This minimizes the drift of the working fluid outside the treated area and ensures the desired quality of application of pesticides, fertilizers and other agrochemicals.

The device for spraying liquid works as follows.

In the initial position, the fairing of the working fluid 13 is in the lowest position and tightly closes the opening of the liquid nozzle 15. In accordance with the task map, for example, for the differentiated treatment of an agricultural field with pesticides (herbicides, insecticides or fungicides), the on-board computer of a mobile machine (not shown) gives a control electrical signal (impulse) to the controller of the actuator 6 to open the opening of the liquid nozzle 15 by a predetermined value, which determines the flow rate of the pesticide working fluid in an elementary section of the processed field. In accordance with the signal, the motor of the actuator 6 rotates the reduction gear, by means of which the rod 7 of the actuator 6 raises the fairing of the working fluid 13 by a predetermined value h. The working fluid from the injection communication of a mobile machine (not shown) under a predetermined pressure difference enters through channel 3 into the cylindrical chamber 2 and then along the vertical channels 16 into the nozzle chamber 12, flowing around the liquid fairing 13 into the liquid nozzle 15, by means of which it is sprayed onto the treated plants with spray angle β. At the same time, air from the source of compressed air through the air duct of the mobile machine (not shown) is supplied to the tangential channel 5 and swirls on the inner surface of the chamber 4, acquiring the shape of a ring. The swirling annular air flow enters the conoidal nozzle channel 11. Coming out of the channel 11 through the annular opening 19, the circular air flow enters the deflecting surface 9, through which it acquires, when descending from the linear circular surface 22 of the deflector, a hollow circular spray of air with a spray angle α. Inside the circular flame, the working fluid is dispersed with a spray angle β. To change the flow rate and, as a consequence, the rate of application of the working fluid in accordance with the task map, a control signal is sent from the on-board computer of the machine to the controller of the linear actuator 6, the rod 7 with fairing 13 is raised or lowered. increasing or decreasing the flow of liquid through the nozzle 15.

The use of this device provides a differentiated application of liquid mineral fertilizers, pesticides and other agrochemicals with a given dose at each elementary section of the cultivated field, reduces their application rates and reduces environmental pollution.

Claims (1)

A device for spraying a liquid containing a body, a cylindrical chamber made in it with a channel for supplying a working fluid and an air chamber with a tangential channel for supplying air, a linear actuator with a vertical rod, a deflector connected to the body in the form of a body of revolution with a deflecting surface and a cylindrical shank, a nozzle channel for supplying air to a deflector, a nozzle chamber for a working fluid, a liquid fairing connected to the actuator rod, an insert, a nozzle with an elliptical outlet for spraying a liquid, vertical channels for supplying a working fluid to a nozzle chamber, characterized in that the air chamber, made torus-shaped with the surface of the open torus and tangential air supply, equipped with a nozzle channel made conoidal, conjugated with one fourth of the lower surface of the torus, the outlet part of the nozzle channel and the surface of the cylindrical shank of the deflector are made with the formation of an annular holes for air supply to the deflecting surface, and the body of rotation of the deflector with a generatrix in the form of an arc of an ellipse bounded by adjacent vertices of an ellipse with a long axis parallel to the longitudinal axis of symmetry of the device, while the end part of the deflector is equipped with a linear circular surface of air outlet, and the liquid nozzle is made in the end of the deflector and is coupled with a nozzle chamber made in the form of an ellipsoid of revolution with a long axis perpendicular to the longitudinal axis of symmetry of the device, parallel to the longitudinal axis of the liquid nozzle and a vertical axis coinciding with the longitudinal axis of symmetry of the device, in addition, the liquid fairing is located inside the nozzle chamber and is made in in the form of an ellipsoid of rotation coaxially and equidistant to the ellipsoid of rotation of the nozzle chamber, the difference in the lengths of the vertical semiaxes of the ellipsoid of rotation of the nozzle chamber and the ellipsoid of rotation of the liquid fairing is at least not less than the depth of the slot that determines the depth of opening of the liquid nozzle, for this The maximum spray angle of the liquid nozzle is at least less than the minimum spray angle of the deflector air flow.

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