MD989Z - Drill with grooved cylinder - Google Patents

Abstract

The invention relates to agriculture, namely to reel-type grain crop seed-sowing devices.The reel-type seed-sowing device comprises a seedbox, in which there are installed the reel with grooves (1), fixed on a drive shaft (3), and a rosette (2). In the lower part of the box, underneath the reel (1), is mounted a movable valve (4) with adjusting screw (5). To the box, at the free end of the valve (4), is rigidly fixed a seed guide device (9), consisting of two parts: in the shape of a truncated cone and in the shape of a cylinder, which communicate with each other. To the base of the cylindrical part of the device (9) is fixed a vertical cylinder, equipped with a fan for the supply of a forced air flow.

Description

The invention relates to agriculture, namely to sowing devices with grooved cylinder for sowing cereal crops.

A grooved cylinder sowing device is known, which is mounted on a seeder for cereal crops and contains a seed box, in which a shaft with grooved cylinders is placed. Each grooved cylinder is composed of two parts, forming a fixed helical groove and a movable one, moving in the axial direction together with the shaft, for sowing different sowing norms [1].

The disadvantages of this device are the uneven distribution of seeds on the scattering surface, since the angle of inclination of the helical groove of the grooved cylinder is not adjusted, the working mode of the device causes free leakage of seeds from the box, at the same time the device is complex in construction and use, and its reliability is low. All this leads to a decrease in crop productivity.

A sowing device with a grooved cylinder is also known, consisting of a housing with a grooved cylinder, on the outer cylindrical surface of which 14…18 edges are made, forming inclined oblique grooves, located at an acute angle of 12…17° to the axial line of the cylinder, with a volume of the grooves made multiple of the dimensions of the sown seeds, with a cross-sectional area of 5…7.5 mm, and the diameter of the protrusions of the grooves smaller than the outer diameter of the collar at the ends of the grooved cylinder. The grooves of the cylinder are made according to the radius, equal to 0.5…0.7 of the diameter of the distributed seeds. The housing is made removable, consisting of two parts, and the grooved cylinder is mounted with a clearance of 0.2…0.3 mm between its teeth and the surface of the removable housing [2].

The disadvantages of this sowing device consist in the uneven distribution of seeds on the sowing surface, because the angle of inclination of the helical groove of the grooved cylinder is not adjusted, which leads to a pulsating-portioned evacuation of seeds, at the same time the width of the seed flow at the evacuation from the sowing device to the guide tube is approximately equal to the width of the sowing device, and the axis of the seed flow distribution is perpendicular, in the horizontal plane, to the axis of the gutter and not along it, thus a larger distribution surface is formed on the width of the gutter, uneven and Z-shaped along the gutter. All this contributes to the decrease in crop productivity.

The closest solution is the grooved cylinder seeder, which contains a seed box with a rosette installed on the grooved cylinder shaft, a device for guiding seeds to the lower part of the seed box and a flap. The edges of the grooves of the grooved cylinder are made helically at an angle of 18…22° to the axial line. The edge of the free end of the flap is made rectangular. The cutting line of the edge of the free end of the flap is located below the axis of the grooved cylinder by (0.6-0.7)R, where R is the radius of the cylinder. The end of one edge of the grooved cylinder in the direction of rotation of the cylinder coincides with the upper right tip of the flap, and the beginning of the next edge of the grooved cylinder coincides with the upper left tip of the flap. The rosette cuts are made according to the shape of the edges of the grooved cylinder at an angle of 18…22° to the axial line of the cylinder [3].

The disadvantages of this sowing device consist in the uneven distribution of seeds on the sowing surface at low sowing rates by moving the grooved cylinder and the drive shaft in the axial direction towards the inside or outside of the seed box, at the same time the angle of inclination of the grooves is oriented opposite to the direction of seed evacuation, thus causing the seeds to slide from the grooves of the grooved cylinder back into the sowing device at low sowing rates. Also, the angle of inclination of the grooves of the grooved cylinder relative to its axial line is not adjusted with the plane described by the cutting line of the edge of the free end of the movable flap, which leads to a pulsating-portioned evacuation of seeds and complicates the installation of the sowing device at low sowing rates due to the loss of the effect of the angle of inclination of the grooves of the grooved cylinder relative to its axial line. Another drawback is the width of the seed flow when it is discharged from the sowing machine to the funnel of the seed guide device, which is approximately equal to the width of the movable flap, in this case 33 mm, even if the furrow, depending on the coulter used, is made with a width of 20…60 mm, and the diameter of the seed guide device is 40 mm. At the same time, the axis of the seed flow distribution is perpendicular, in the horizontal plane, to the axis of the furrow and not along it, thus a larger distribution surface is formed across the width of the furrow, uneven and Z-shaped along the furrow. All this contributes to reducing the yield of agricultural crops.

The technical problem solved by the invention is to improve the uniformity of seed distribution on the sowing surface by eliminating the pulsating-portioned evacuation of seeds, regardless of the sowing rates, excluding the sliding of seeds from the grooves back into the sowing device at low sowing rates or high speeds of the grooved cylinder, reducing the diameter of the cross-section of the seed flow at the evacuation from the seed guiding device, and the seed distribution axis is oriented along the gutter.

The grooved cylinder sowing device according to the invention eliminates the above-mentioned disadvantages by containing a seed box, in which the grooved cylinder, fixed on a drive shaft, and a rosette are placed. At the bottom of the box, under the cylinder, a movable flap with an adjustment screw is mounted with one end. The cylinder grooves are made inclined with a twist angle of 1…37° perpendicular to its longitudinal axis, and the free end of the flap is made straight or inclined with a working angle of up to 20°, and correlated so that the absolute amplitude Aasl of the area of the working surface of the seeds Sli, equal to the difference between the areas of the maximum working surfaces Slmax and minimum Slmin, is selected less than or equal to 20Ss, where Ss - the area of the master section of the seed, and the area of the working surface Sli is equal to the sum of the areas of the working surfaces of the cylinder groove Slci and the active layer of the seeds Slsai, formed by the plane τ described by the cutting line of the edge of the free end of the flap and a point on the axial line of the cylinder. A device for guiding seeds is rigidly fixed to the box, at the free end of the flap, inclined in the vertical plane at an angle of 1...45°, opposite to the direction of movement of the sowing device and consisting of two parts: frustoconical and cylindrical. The frustoconical part is located at the level of the free end of the flap and made with a rectangular internal profile in cross-section with the side opposite the flap bent. The length of the side Ld next to the flap is equal to the working length of the cylinder Llc, the area of the rectangular section SD being greater than or equal to the area of the cross-section of the seed flow Sf. The cylindrical part is joined to the frustoconical part and made with an internal profile in ovoid shape in cross-section with a small radius Rj greater than or equal to the radius of the master section of the seed Ss, the area of the ovoid section SE being greater than or equal to the area of the cross-section of the seed flow Sf. A vertical cylinder is fixed to the base of the cylindrical part of the device for directing the seeds.

The vertical cylinder can be equipped with a fan to deliver a forced air flow.

The particularities of the invention allow obtaining the best results with the sowing device, in which the grooved cylinder is located, the grooves of which are made under a twist angle αrc = 22°, approximately equal to the angle αhelic = 13.65°, formed by the helical line and the axial line of the cylinder, the angles being inclined towards the rosette towards the direction of seed evacuation from the seed box, and the working length of the grooved cylinder is Llc = 33 mm. The absolute amplitude Aasl of the area of the working surface of the seeds Sli, equal to the difference between the areas of the maximum working surfaces Slmax and minimum Slmin, is selected less than or equal to 20Ss, where Ss is the area of the master section of the seed, and the area of the working surface Sli is equal to the sum of the areas of the working surfaces of the cylinder groove Slci and the active layer of the seeds Slsai, formed by the plane τ described by the cutting line of the free end edge of the movable flap and a point on the axial line of the grooved cylinder, which intersects the grooves in i = 0…12 points, located radially at equal distances along the length of the arc, formed by a groove of the cylinder (Aasl = Slmax - Slmin ≤ 20Ss), which corresponds to the working angle δlcl = 8°.

The seed guiding device is inclined vertically at an angle ɛ = 30°, opposite to the direction of movement of the sowing machine.

The main constructive parameters are described by the seed guiding device consisting of two parts: frustoconical and cylindrical, which ensures the change of the seed flow Lconv ≥ , where is the diameter of the master section of the seed Ss. The first frustoconical part is made with a rectangular inner profile in cross-section with the length of the side Ld next to the flap equal to the working length of the cylinder Llc or with the distance between the side walls of the seed box and the side, opposite the flap, bent, at the same time the area of the rectangular section SD is greater than or equal to the area of the cross-section of the seed flow Sf. The second cylindrical part is made with an ovoid inner profile in cross-section, with the small radius Rj greater than or equal to the radius of the master section of the seed Ss, and the area of the ovoid section SE is greater than or equal to the area of the cross-section of the seed flow Sf.

The technical result of the invention consists in improving the uniformity of seed distribution on the sowing surface. The coefficient of variation of seed distribution of the proposed sowing device is ν = 13…26%, and for the cylinder grooves, from the close solution, executed at an angle of 18…22° to the axial line of the cylinder, the coefficient of variation is ν = 44%, while for the cylinder grooves, from the close solutions, this coefficient is ν = 65…70%.

The quality of seed distribution on the sowing surface at low sowing rates is not lost, due to the fact that the adjustment on the sowing surface is carried out by reducing the rotations of the grooved cylinder, not by moving it and the drive shaft in the axial direction towards the inside or outside of the seed box.

The diameter of the cross-sectional area of the seed flow at the exit from the seed guiding device is reduced, due to the way it is made, the diameter being less than or equal to 20 mm, and the axis of the seed flow distribution is oriented along the gutter, which forms a smaller and more uniform seed distribution surface along the gutter.

All of this improves the quality of sowing and leads to increased productivity, reduced costs and production losses in cereal crops.

The invention is explained by the drawings in Fig. 1-10, which show:

- Fig. 1, diagram of the sowing device with grooved cylinder;

- Fig. 2, section A-A of Fig. 1;

- Fig. 3, the sowing machine in axonometric view;

- Fig. 4, side view of the seed guiding device;

- Fig. 5, section A-A of Fig. 4;

- Fig. 6, section B-B of Fig. 4;

- Fig. 7, the device for guiding seeds in axonometry;

- Fig. 8, rear view of the grooved cylinder and the method of calculating the working angle;

- Fig. 9, side view of the grooved cylinder with its calculation method and twist angle;

- Fig. 10, axonometric view of the grooved cylinder and the method of calculating the grooves.

The seed drill with a grooved cylinder (fig. 1, 2, 3) contains the seed box 6, in which the grooved cylinder 1, fixed on the drive shaft 3, and the rosette 2 are located. In the cylinder 1, fixed on the shaft 3, the cylindrical shank 8 is mounted, on which the bushing 7 with centering protrusions is located (fig. 3), fixed in the wall of the box 6 to prevent the bushing 7 from rotating. In the lower part of the box 6, under the cylinder 1, the movable flap 4 with the adjustment screw 5 is mounted with one end. The grooves of the cylinder 1 are made inclined with the twist angle αrc = 1…37° (fig. 9), which is approximately equal to the angle αhelic = 1…22°, formed by the helical and axial lines of the cylinder 1, the angles being inclined with respect to the rosette 2 towards the direction of seed evacuation from the box 6 (fig. 2, 3). The working length of the cylinder 1 is Llc = 33 mm, and the edges of the grooves of the cylinder 1 are not made with brush frames. The absolute amplitude Aasl of the area of the working surface of the seeds Sli (Fig. 9, 10), equal to the difference between the areas of the maximum working surfaces Slmax and minimum Slmin, must be selected less than or equal to 20Ss (Aasl = Slmax - Slmin ≤ 20Ss, where Ss is the area of the master section of the seed). The area of the working surface Sli is equal to the sum of the areas of the working surfaces of the groove of the cylinder 1 Slci and the active layer of the seeds Slsai, formed by the plane τ described by the cutting line of the edge of the free end of the flap 4 (Fig. 8, 9, 10) and a point on the axial line of the cylinder 1, which intersects the grooves in i = 12 points (Fig. 10), located radially at equal distances along the length of the arc, formed by a groove of the cylinder 1.

The free end of the flap 4 (fig. 1, 2, 3) is made straight or inclined with the working angle δlcl = 0…20° (fig. 8), formed by the cutting line of the edge of the free end of the flap 4 to the intersection of the plane τ (fig. 8), having as a common point the uppermost tip of the flap 4.

On the seed evacuation side of the flap 4, at its free end, the seed guiding device 9 (fig. 4, 5, 6, 7) is rigidly fixed to the box 6, inclined in the vertical plane at an angle ɛ = 1…45°, opposite to the direction of movement of the sowing device.

The device 9 consists of two parts: frustoconical (fig. 5) and cylindrical (fig. 6), which allows changing the seed flow Lconv ≥ (fig. 4), where is the diameter of the master section of the seed Ss. The first frustoconical part is made with a rectangular internal profile in cross-section with the length of the side next to the flap 4 Ld = Llc, where Llc is the working length of the cylinder 1, and with the side opposite the flap 4 bent, and the area of the rectangular section SD (fig. 5) is greater than or equal to the area of the cross-section of the seed flow Sf. The second cylindrical part is made with an internal profile in ovoid shape in cross-section, with a small radius Rj (fig. 6) greater than or equal to the radius of the master section of the seed Ss, and the area of the ovoid section SE is greater than or equal to the area of the cross-section of the seed flow Sf.

The diameter of the cross-sectional area of the seed flow at the outlet from the device 9 must be less than or equal to 20 mm.

The device 9 (fig. 1, 3, 4, 7) can be adapted to transport seeds both under the action of gravitational force and forced with the fan by delivering an overpressure air flow.

Cylinder 1 is inserted into rosette 2, its inner contour (fig. 1, 3) is made according to the shape of the edges of cylinder 1, and the twist angle αrr of the contour is correlated to the twist angle αrc (fig. 9) of cylinder 1.

The grooved cylinder seeder operates in the following way.

The seeds from the box under the action of gravitational force flow into the box 6 (fig. 1, 2) and fill the space around the cylinder 1. The latter, rotating, moves the seeds, some of them fall into the grooves, and some of the active layer of seeds (fig. 9), which did not fall into the grooves, but are located near the edges of the cylinder 1, move to the bottom of the box 6, towards the free end of the flap 4, into the device 9, but not pulsating-portioned, but smoothly and continuously, due to the fact that the angle of rotation αrc of the grooves of the cylinder 1 and the working angle δlcl (fig. 8), formed by the cutting line of the edge of the free end of the flap 4, are correlated so that the absolute amplitude Aasl of the areas of the working surfaces Aasl = Slmax - Slmin ≤ 20SS (fig. 10). The area of the working surface of the seeds Sli is equal to the sum of the areas of the working surfaces of the groove of cylinder 1 Slci and of the active layer of the seeds Slsai, formed by the plane τ (fig. 9, 10) described by the cutting line of the edge of the free end of the flap 4 and a point on the axial line of cylinder 1, which intersects the grooves in i = 0…12 points, located radially at equal distances along the length of the arc, formed by a groove of cylinder 1.

Due to the fact that the edges of the grooves of the cylinder 1 are inclined relative to the rosette 2 towards the direction of seed evacuation from the box 6 (Fig. 2, 3), sliding off the groove back inside the box 6 and the appearance of non-uniformity when adjusting the sowing device to small sowing rates by moving the cylinder 1 and the shaft 3 in the axial direction towards the inside or outside of the box 6 is excluded.

The sowing rate is adjusted by changing the speed of cylinder 1. For low sowing rates, the sowing device is set by reducing the speed of shaft 3, without losing the quality of seed distribution on the sowing area.

During operation, the seeds do not leak from the box 6 through the rosette 2, the contour of which is made according to the shape of the edges of the cylinder 1 and the angle of twist αrr of the contour is correlated with the angle of twist αrc (fig. 8) of the cylinder 1.

The gap between the flap 4 and the cylinder 1 is adjusted by means of the screw 5 (fig. 1, 2), depending on the size of the seeds for sowing. The free flow of the seeds through this gap is excluded due to the fact that the free end of the flap 4 is located below the axis of the cylinder 1 by (0.6-0.7)R.

After the seeds are discharged from the valve 4, under the action of gravitational force, they fall into the device 9 (fig. 1, 3, 4, 7) inclined in a vertical plane at an angle ɛ = 1…45°, opposite to the direction of movement of the sowing device.

When the seeds move through the device 9, due to the constructive parameters of the two parts: frustoconical and cylindrical (fig. 5, 6), the change of the seed flow Lconv ≥ (fig. 4) is ensured, where is the diameter of the master section of the seed Ss. The first frustoconical part (fig. 5) is made with a rectangular internal profile in cross-section with the side length Ld = Llc and with the side opposite the flap 4 bent, and the area of the rectangular section SD is greater than or equal to the area of the cross-section of the seed flow Sf. The second cylindrical part (fig. 6) is made with an internal profile in an ovoid shape in cross-section with a small radius Rj greater than or equal to the radius of the master seed section Ss, and the area of the ovoid section SE is greater than or equal to the area of the cross-section of the seed flow Sf, thus changing the axis of the flow distribution - from perpendicular to the axis of the gutter to horizontal, which leads to a more uniform seed distribution surface along the gutter.

The diameter of the cross-sectional area of the seed flow at the outlet from the device 9 is less than or equal to 20 mm.

The device 9 can be adapted to transport seeds both under the action of gravitational force and forced with the fan by delivering an overpressure air flow.

1. SU 55826 A1 1939.10.31

2. RU 2461171 C2 2012.09.20

3. RU 2384040 C1 2010.03.20

Claims (2)

1. Sowing device with grooved cylinder, which contains a seed box (6), in which the grooved cylinder (1), fixed on a drive shaft (3), and a rosette (2) are placed; in the lower part of the box (6), under the cylinder (1), a movable flap (4) with an adjustment screw (5) is mounted with one end; the grooves of the cylinder (1) are made inclined with a twist angle of 1…37° perpendicular to its longitudinal axis, and the free end of the flap (4) is made straight or inclined with a working angle of up to 20°, and correlated so that the absolute amplitude Aasl of the area of the working surface of the seeds Sli, equal to the difference between the areas of the maximum working surfaces Slmax and minimum Slmin, is selected less than or equal to 20Ss, where Ss - the area of the master section of the seed, and the area of the working surface Sli is equal to the sum of the areas of the working surfaces of the cylinder groove (1) Slci and the active layer of the seeds Slsai, formed by the plane τ described by the cutting line of the edge of the free end of the flap (4) and a point on the axial line of the cylinder (1); of the box (6), at the free end of the flap (4), a device (9) for guiding the seeds is rigidly fixed, inclined in the vertical plane at an angle of 1...45°, opposite to the direction of movement of the sowing device and formed of two parts: frustoconical and cylindrical; the frustoconical part is located at the level of the free end of the flap (4) and made with a rectangular internal profile in cross-section with the side opposite the flap (4), bent, at the same time the length of the side Ld next to the flap (4) is equal to the working length of the cylinder (1) Llc, the area of the rectangular section SD being greater than or equal to the area of the cross-section of the seed flow Sf; the cylindrical part is joined to the truncated conical part and made with an ovoid-shaped internal profile in cross-section with a small radius Rj greater than or equal to the radius of the master section of the seed Ss, the area of the ovoid section SE being greater than or equal to the area of the cross-section of the seed flow Sf; a vertical cylinder is fixed at the base of the cylindrical part of the device (9) for directing the seeds. 2. Seeding apparatus according to claim 1, wherein the vertical cylinder is equipped with a fan for delivering a forced air flow.