RU2222183C2 - Sprinkler device for hydraulic drive discharge system of sprinkler machine - Google Patents

Abstract

FIELD: agricultural engineering. SUBSTANCE: sprinkler device has discharge pipeline and ball-type sprinkling deflector with openings formed circumferentially of and perpendicular to deflector surface. Number of openings is determined from cited formula. Optimized number of openings in sprinkling deflector provides uniform distribution of water discharged from hydraulic drives by means of discharge pipeline and sprinkling ball-type device. EFFECT: improved discharge and uniform distribution of used water in sprinkler machine spans and, accordingly, improved flowage of water. 2 cl, 4 dwg

Description

 The invention relates to spraying and uniform distribution of water drained in the area of carts from hydraulic drives using a drain pipe system and a rain-forming ball, can be used in agriculture.

A device is known for reducing soil erosion by increasing the uniformity of the distribution of water discharged from the hydraulic drive in the form of an airborne suspension, including a standpipe and a sprinkler nozzle connected through an additional tap to an injector, a water tank and a sprinkler (A.S. 1519593, MKI A 01 G 25/09, publ. 11/07/89, bull. 41.)
The disadvantage of this device is the design complexity and high material consumption.

 The use of an additional frame with a waterproof casing in front in order to improve the operating conditions of the multi-support sprinkler by removing water from the track during sprinkling (A.S. 1551287, MKI A 01 G 25/09, publ. 23.03.90, bul. 11) does not protect the rut from the drained water from the hydraulic drives of the bogies and has an additional mechanical effect on the soil with its propellers.

 In order to increase the reliability of the known device, where the drain pipes of the hydraulic drives of the self-propelled supports of each previous span are connected to the water supply pipe at the beginning of the next span (A.S. 1628978, MKI A 01 G 25/09, publ. 23.02.91, bul. 7) , it is economically inexpedient due to the costs of installation, dismantling and maintenance of the structure.

Closest to the proposed device is a device for increasing the uniformity of the distribution of water discharged from the hydraulic drive carts by increasing the drain radius, containing a spray device, the outlet pipe of which is equipped with a tetrahedral expanding socket, mated in a wide part around the perimeter of the socket with a deflector made in the form of a part sphere and provided with a series of tapered holes to the exit, the axes of which are located along the normals to the field at angles between 20 ^o and 40 ^o upward downward from horizontal and ± 30 ^o to the vertical planes along the front of the machine (AS 1664193, IPC A 01 G 25/09, published 07.23.91, Bulletin 27 -.. prototype).

 However, due to the frontal wind, the drained water falls into a rut, because the spray device is located in the immediate vicinity of the truck, and the absence of the numerical parameters of the device confirmed by calculations may affect its performance.

 The technical task of the invention is the removal of waste water from the bogies and its uniform distribution in the spans of the machine by optimizing the number of holes in the rain-forming ball and the length of the jet.

где Q - расход воды через дождеобразующий шар, м³/с;
n - число отверстий, шт.;
μ - коэффициент расхода;
ω_отв - площадь отверстия, м²;
g - ускорение свободного падения, м/с²;
P₁- давление воды на выходе из клапана-распределителя, Па;
γ - удельный вес воды, Н/м³;
z - вертикальное расстояние от верхней крышки гидроцилиндра до нижней точки дождеобразующего шара, м;
ω_тр - площадь поперечного сечения трубопровода, м²;
k_э- коэффициент шероховатости трубопровода, м;
d_тр - диаметр трубопровода, м;
R_e - число Рейнольдса;
l - длина всей сливной магистрали, м;
ζ_вн.c- коэффициент внезапного сужения трубопровода (относится к участку после клапана-распределителя на входе в сливной трубопровод);
ζ₉₀°- коэффициент поворота трубопровода (относится к участкам поворота сливного трубопровода).The problem is achieved in the spraying device of the drainage system of hydraulic drives of the sprinkler machine, comprising a nozzle with a water outlet blocked by a spherical deflector, where according to the invention the nozzle is connected to a drain pipe made in the form of four elbows, leaving the distributor valve, and the deflector is located at the outlet of the drain the pipeline and has the shape of a ball consisting of two hemispheres of radius R = 0.045 m, the holes in which are made in a circle and normal to the surface of the sphere and have diameters of 2 mm, while the third part of the holes is located above the "equator" of the ball, and two third parts of the holes are located below the "equator" of the ball, in addition, one drain hole is made with a diameter of 3 mm in the lower part of the ball, and the number of holes is determined by the flow rate drained water through a rain-forming ball according to the formula:

where Q is the flow rate of water through the rain-forming ball, m ³ / s;
n is the number of holes, pcs .;
μ is the flow coefficient;
ω _resp - hole area, m ² ;
g is the acceleration of gravity, m / s ² ;
P ₁ - water pressure at the outlet of the control valve, Pa;
γ is the specific gravity of water, N / m ³ ;
z is the vertical distance from the upper cover of the hydraulic cylinder to the lower point of the rain-forming ball, m;
ω _Tr - the cross-sectional area of the pipeline, m ² ;
k _e - the roughness coefficient of the pipeline, m;
d _Tr - the diameter of the pipeline, m;
R _e is the Reynolds number;
l is the length of the entire drain line, m;
ζ _int.c - coefficient of sudden narrowing of the pipeline (refers to the area after the distributor valve at the inlet to the drain pipe);
ζ ₉₀ ° - the coefficient of rotation of the pipeline (refers to the areas of rotation of the drain pipe).

 In addition, the task is achieved by the fact that the rain-forming ball has holes in the amount of 150-170 pieces, provided that the flow rate of the drained water is equal to the actual flow rate through the drain system of the hydraulic drives of the sprinkler, with fifty-two holes located 5 mm above the equator of the ball, fifty-two holes are located below the "equator" by 5 mm, thirty-eight holes are located below the "equator" by 23.5 mm, and nineteen holes are located below the "equator" by 47.1 mm. When the number of holes is exceeded, it has been established experimentally that the jet flight length sharply decreases and, therefore, the spray quality decreases, while the number of holes decreases, the idle cycle time of the movement mechanism is delayed, which, in turn, affects its kinematics and the operation of the whole machine .

 The presence in the proposed device of the invention is proved by the fact that there are no such reliable and affordable devices for discharging waste water from the trucks and distributing it evenly in the form of an airborne suspension at a respectful distance from the trucks in the flyover zone and having high versatility compared to existing devices due to expanding capabilities, because this device can work at any high-speed modes of the sprinkler.

 The originality of the proposed technical solution lies in the fact that the length of the drain pipe is coordinated (confirmed by calculation and experimentally) with the maximum outflow of an airborne droplet suspension, this eliminates the possibility of waste water entering the track even with a frontal wind.

 The device is illustrated by drawings.

 Figure 1 shows a General view of the device; figure 2 - dependence of the flow rate of the drained water from the number of holes; figure 3 is a decreasing characterizing the process of reducing the flight length of the jet as the number of holes in the rain-forming ball increases; figure 4 is a spray device with a hydraulic cylinder and a control valve assembly.

The spraying device of the drain system of hydraulic drives of the sprinkler machine contains a pipe 1 with a water outlet and an external thread (Fig. 1), a spherical deflector having the shape of a ball 2 and consisting of two hemispheres of radius R = 0.045 m, holes 3 of which are made in a circle and along normal to the surface of the sphere and have diameters of 2 mm, with fifty-two holes located 5 mm above the "equator" of the ball, fifty-two holes - 5 mm lower (l ₁ ), thirty-eight holes - 23.5 mm lower (1 ₂ ), nineteen holes - 47.1 mm lower (1 ₃ ), in addition, one drain hole is made with a diameter of 3 mm in the lower part of the ball 2, and the distance between the holes is c = 5 mm. Ball 2 is made with a radius of 0.045 m in order to proportionally place holes 3 on its lower hemisphere, and holes 3, made in the upper part, are designed to supply air from the atmosphere in order to obtain an airborne suspension. The holes 3 are made in a circle and normal to the surface so that water at different angles to the vertical and horizontal is sprayed onto the irrigated area, creating a rain spot with an area sufficient for drainless drainage of water. Holes 3 are made with a diameter of 2 mm so that the diameter of the drops does not exceed permissible norms when irrigating crops. The pipe 1 is connected to a drain pipe 4, made in the form of four elbows, extending from the valve-distributor. The diameter of the drain pipe is 0.03 m, the elbows are as follows: L ₁ = 0.3 m, L ₂ = 1 m, L ₃ = 4 m, L ₄ = 0.2 m, the elbow length L _{3 was} obtained by calculation.

 The device operates as follows.

 Water enters the drain pipe 4 and fills the cavity of the nozzle 1 and the deflector, the air available in the ball 2 and coming through the upper holes 3 is mixed with water and is sprayed in the form of an air-droplet suspension in all directions in a circle on a section of the field remote from the track.

In FIG. 2 graphically depicts the dependence of the discharge flow rate “Q” on the number of holes in the ball, which allows to determine the optimal number of holes at the actual flow rate “Q _d ” through the drain system of the hydraulic drive of the sprinkler.

In FIG. 3 shows a graph of the dependence of the flight range of the drops "X _floor " on the number of holes in the ball. Thus, by choosing the optimal number of holes in the ball, it is possible to determine the optimal range of the droplets.

 Given the number of holes, based on technological requirements (maximum removal of water from the carts, spray quality), we obtain the water flow rate and the flight length of the jet. Varying the parameters (length of the drain pipe: third elbow; the number of holes in the ball), we obtain their optimal values.

With the number of holes n = 162, the water consumption is 0.0014 m ³ / s (normal), the jet length is 1.6 m. As the test results of the prototype device showed, the maximum number of holes should not exceed 170-200 pieces and not less than 150 pieces .

 In FIG. 4 shows a spray device with a hydraulic cylinder and a control valve assembly: 6 - a control valve; 2 - spherical deflector; 7 - a hydraulic cylinder; 4 - a drain pipe; 5 - the top cover of the hydraulic cylinder.

Thus, the use of the invention allows to achieve the following results:
Due to the revealed analytical dependence of the length of the drain pipe, water flow and jet flight on the number of holes in the ball, the spraying device of the drain system of hydraulic drives of the sprinkler machine ensures the discharge of waste water from the carts and evenly distributes it in the spans of the machine in the form of an air-droplet suspension, which improves its throughput, thereby increasing productivity, and hence the quality of irrigation.

 The proposed design does not violate the kinematics of the hydraulic drive mechanisms with the correct selection of the number of holes in the rain-forming ball.

Claims (2)

The spraying device of the drain system of hydraulic drives of the sprinkler machine, comprising a nozzle with a water outlet blocked by a spherical deflector, characterized in that the nozzle is connected to a drain pipe made in the form of four elbows, which leaves the distributor valve, and the deflector is located at the outlet of the drain pipe and has the shape of a ball consisting of two hemispheres of radius R = 0.045 m, the holes in which are made in a circle and normal to the surface of the sphere and have diameters of 2 mm, while the third h st openings located above the "equator" of the ball, and two thirds of the holes are located below the "equator" of the ball, in addition, one drain hole is formed with a diameter of 3 mm at the bottom of the ball, and the number of holes defined flow of water drained through ball dozhdeobrazuyuschy formula

where Q is the flow rate of water through the rain-forming ball, m ³ / s; n is the number of holes, pcs .; μ is the flow coefficient; ω _resp - hole area, m ² ; g is the acceleration of gravity, m / s ² ; P ₁ - water pressure at the outlet of the control valve, Pa; γ is the specific gravity of water, N / m ³ ; z is the vertical distance from the upper cover of the hydraulic cylinder to the lower point of the rain-forming ball, m; ω _Tr - the cross-sectional area of the pipeline, m ² ; k _e - the roughness coefficient of the pipeline, m; d _Tr - the diameter of the pipeline, m; R _e is the Reynolds number; l is the length of the entire drain line, m; ζ _vn.s - coefficient of sudden narrowing of the pipeline; ζ _90? - the coefficient of rotation of the pipeline. 2. The device according to claim 1, characterized in that the rain-forming ball has holes in an amount of 150-170 pieces, with fifty-two holes located 5 mm above the "equator" of the ball, fifty-two holes are 5 mm lower than the "equator", thirty-eight holes are located below the "equator" by 23.5 mm, and nineteen holes are located below the "equator" by 47.1 mm.

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