RU187044U1 - Plant for presowing seed stimulation - Google Patents

Abstract

The utility model relates to agriculture and is used to process seeds in a magnetic field.

The installation comprises a housing of racks and shelves, a hopper, a magnetic stimulation unit, a control unit and a box, while the magnetic stimulation unit includes a pipe with a stand, stops and openings with dampers, as well as a core, coils and flexible plastic vibration plates located on them with installed on them with metal plates. Using a plant for presowing seed stimulation allows you to increase the yield of the treated crops, by setting the required time and intensity and frequency of the magnetic field, and also simplifies the design by eliminating additional seed metering equipment and thereby reduce energy costs for driving the metering body.

Description

The utility model relates to agriculture and is used to process seeds in a magnetic field.

A device for presowing treatment of seeds is known, comprising a housing made of diamagnetic material surrounded by a winding supplied by a pulsed current source, while static power supplies from an ozonizer and also an ultraviolet radiation source are installed in the upper part of the housing [1].

The disadvantage of this device is the lack of an element for feeding and dosing seeds. In this case, the seed treatment time is determined only by the time of seed fall through the device, which reduces the processing efficiency.

A known installation for presowing treatment of seeds, containing a cylindrical body made of diamagnetic material surrounded by a winding powered by a current source, while inside the case a screw nozzle made of diamagnetic material is installed [2].

The disadvantage of this device is that the seed treatment time depends only on the time spent on the seeds to overcome the path along the screw nozzle. Moreover, given the different physical and mechanical properties of different seeds of agricultural processing time will be different. The seed treatment time in this device does not change. As a result, the efficiency of stimulation of various cultures by the device is reduced.

The problem the utility model aims to solve is to increase the efficiency of seed treatment in a pulsed magnetic field by a coil created by controlling the frequency of the magnetic field and the processing time, as well as using the energy of the magnetic field for vibration dosing of seeds.

The technical solution is achieved due to the fact that the plant for pre-sowing seed stimulation consists of a housing including racks, lower and upper shelves, as well as a hopper, a magnetic stimulation unit with a box installed under it and a control unit, an opening is made in the upper shelf in which the hopper is installed with its outlet hole, on the lower shelf represented by a transverse beam, a magnetic stimulation unit is installed in the center, including an electromagnet consisting of an inductor placed in two longitudinal grooves w-image heat core made of sheets of electrical steel. At the same time, a vibration dispenser is made above the electromagnet, including a rectangular nozzle, the longitudinal width of which is equal to the width of the electromagnet, in the upper part of the nozzle it is connected to the outlet of the hopper, and in the lower part it is centered on the electromagnet. Rectangular openings are made in the lower part of the longitudinal sides of the nozzle, and in the center of the nozzle along the longitudinal axis there is a distribution rack, which rests on the core with its supporting projections. Also, on both sides of the rack in the nozzle there are limiters made in the form of sloping plates, while two plates are installed symmetrically in the upper part of the distribution rack, and two plates are installed lower on the inner wall of the nozzle. On the support ledges of the rack symmetrically on both sides, vibration plates are made of flexible plastic material, on the lower side of which, perpendicular to the rack at the same distance from each other, are three thin plates made of electrical steel, which are located above the grooves of the core into which the inductance coil is laid. Moreover, since the height of the support projection of the rack is greater than the thickness of the plates, a gap is formed between the plates and the electromagnet. The sides are installed along the upper longitudinal ribs of the electromagnet on the end walls of the nozzle, and along the longitudinal walls above the holes are installed vertical guides with dampers.

The figure 1 shows a diagram of an installation for magnetic seed treatment: 1 - rack; 2 - lower shelf; 3 - upper shelf; 4 - hopper; 5 - box; 6 - block magnetic seed treatment; 7 - control unit; 15 - inductor; 17 - core; 19 - pipe.

The figure 2 shows a block diagram of the magnetic stimulation of seeds: 2 - lower shelf; 6 - block magnetic seed treatment; 8 - limiters; 9 - guide; 10 - shutter; 11 - board; 12 - vibration plate; 13 - plate; 14 - distribution rack; 15 - inductor; 17 - core; 18 - support ledge of the rack; 19 - pipe 20 - hole.

The figure 3 shows a diagram of a vibration plate: 12 - vibration plate; 13 - plate; 16 - mounting area.

Installation for pre-sowing stimulation of seeds consists of a housing, including racks 1 (Fig. 1), lower 2 and upper 3 shelves, as well as a hopper 4, box 5, magnetic stimulation unit 6 and control unit 7. A hole is made in the upper shelf 3, in which is equipped with a hopper 4. An outlet is made in the lower part of the hopper 4. On the lower shelf 2, represented by a transverse beam mounted in the center of them, a magnetic stimulation unit 6 is located in the center (Fig. 2), which includes an electromagnet consisting of an inductor 15, laid in two longitudinal grooves of the w-shaped core 17, which is made of sheets of electrical steel. A vibrating batcher is made above the electromagnet, including a rectangular nozzle 19, the longitudinal width of which is equal to the width of the electromagnet, and the longitudinal axis of the nozzle coincides with the transverse axis of the electromagnet. The pipe 19 in the upper part is connected to the outlet of the hopper 4. In the lower part of the longitudinal sides of the pipe 19, rectangular holes are made 20. In the center of the pipe 19, a distribution column 14 is located along the longitudinal axis, which divides the pipe 19 into two sections. At the same time, in the lower part of the rack 14 with its supporting projections rests on the center of the core 17. On both sides of the rack 14 in the pipe 19 there are labyrinths from stops 8 made in the form of pitched plates along the entire width of the pipe 19. In this case, two plates are installed symmetrically on the upper part distribution racks 14, and two plates are installed below on the inner walls of the nozzle 19. On the supporting projections of the racks 18, on both sides, vibration plates 12 made of flexible plastic material are fixed with their fastening sections 16. On the underside of the vibration plates 12, perpendicular to the rack 14, three thin plates 13 made of electrical steel are installed at the same distance from each other. In this case, the plates 13 are mounted on the vibration plates 12 so that they are located above the grooves of the core 17, in which the inductance coil 15 is laid, and their length is equal to the width of the groove. Moreover, the total width of the plates 13 is 15-20 times less than the width of the vibration plates 12. Since the height of the support protrusion of the rack 18 is greater than the thickness of the plates 13, a gap is formed between them and the electromagnet. The magnetic stimulation unit 6 also includes two sides 11 installed along the upper longitudinal ribs of the electromagnet on the end walls of the pipe 19. In the lower part of the pipe 19, along its two longitudinal walls above the holes 20, there are installed in the vertical guides 9 of the shutter 10, which can be moved in the vertical direction and completely close or open the hole 20.

The control unit 7 includes a direct current source and a rectified pulse current generator with a current frequency control module.

Installation for presowing stimulation of seeds works as follows. When you turn on the installation of pulsed magnetic current from the control unit 7 is supplied to the induction coil 15 of the electromagnet. As a result, two symmetric magnetic fluxes are formed in the w-shaped core 17, which are closed through the core plates 17 and the air gap above the inductor 15. In this case, the main part of the magnetic flux will go into the area above the vibration plate 12, where the seeds are, and a small part the magnetic flux will be locked on the plates 13. As a result, the seeds located on the vibration plate 13 will be exposed to a magnetic field, and the plates 13 made of electrical steel, together the vibrating plate 12 will be attracted to the core 17 with a frequency equal to the frequency of the magnetic field of the electromagnet, causing the seeds located on the vibrating plate 12 to move from the stand 14 through the hole 20 to the edge of the vibrating plate 12 and pour into the box 5. In this case, under the influence of force of gravity will come the seeds located in the hopper 4, which, passing through the pipe 19, are divided by the stand 14 into two equal flows and through the labyrinths of the pressure limiters of the seeds 8 enter the vibration plates 12. As a result, the barriers pass a straight line from the bottom of the pipe 19 to the edge of the vibration plate 12 in a magnetic field uniform in width of the electromagnet, as a result of which uniform seed stimulation will occur.

Dosing of the seed supply through the magnetic stimulation unit is carried out using the adjustment flap 10. The frequency and intensity of the magnetic field is selected depending on the crop being processed. In this case, partly dosing of seeds can be carried out by adjusting the frequency of vibration of the vibrating plate 12, within the frequency range acceptable for the processed crop. Seed pressure limiters 8 located in the nozzle 19 reduce the pressure of the seeds in the hopper 4 on the seeds located on the vibration plate 12. As a result, when the seeds in the hopper 4 are reduced, the seed pressure on the plate 12 will not change.

Using a plant for presowing seed stimulation allows you to increase the yield of the treated crops, by setting the required time and intensity and frequency of the magnetic field, and also simplifies the design by eliminating additional equipment for metering seeds and thereby reduce the energy consumption for driving the metering body.

Information sources.

1. Patent 2290775 of the Russian Federation, IPC A01C 1/00 Device for pre-sowing seed treatment / Potapenko I.A., Bogdan A.V., Amerkhanov R.A., Strizhkov I.G., Adadurov E.A., Harchenko P .M., Vinnik A.V., Kharkovsky K.A., Chernyshev A.I .; Applicant and patent holder FGBOU VPO Kuban GAU No. 2005123594/13 07/25/2005. - Publ. 01/10/2007. Bull. No. 1.

2. Patent 2457653 of the Russian Federation, IPC А01С 1/00 Installation for pre-sowing seed treatment / Grigorash O.V., Uskov A.E., Bzhevdy S.N., Kharchenko P.M., Potapenko I.A., Pertenko Yu. .M .; Applicant and patent holder FGBOU VPO Kuban GAU No. 201043057/13 10/20/2010. - Publ. 08/10/2012. Bull. Number 22.

Claims (1)

Installation for pre-sowing stimulation of seeds, consisting of a housing including racks, lower and upper shelves, as well as a hopper, a magnetic stimulation unit with a box installed under it and a control unit, a hole is made in the upper shelf, in which the hopper is installed with its outlet, on the bottom a shelf is represented by a transverse beam, a magnetic stimulation unit is installed in the center, including an electromagnet consisting of an inductor placed in two longitudinal grooves of a w-shaped core made of sheets of ele technical steel, characterized in that a vibrating batcher is made over the electromagnet, including a rectangular nozzle, the longitudinal width of which is equal to the width of the electromagnet, while in the upper part the nozzle is connected to the outlet of the hopper, and in the lower part it is centered on the electromagnet, in the lower part of the longitudinal the sides of the pipe are made rectangular holes, also in the center of the pipe along the longitudinal axis there is a distribution rack, which with its supporting protrusions rests on the core, also on both sides of the rack in the pipe there are limiters made in the form of sloping plates, while two plates are installed symmetrically in the upper part of the distribution rack, and two plates are installed lower on the inner wall of the pipe, and vibration plates are symmetrically mounted on both sides of the rack, made of flexible plastic material, on the lower side of which, perpendicular to the rack at the same distance from each other, are three thin plates made of electrical steel, which are located above the grooves of the core in which the inductance coil is laid, while, since the height of the support ledge of the rack is greater than the thickness of the plates, a gap is formed between the plates and the electromagnet, along the upper longitudinal ribs of the electromagnet on the end walls of the nozzle there are beads, and along longitudinal walls above the holes are installed in vertical guides with dampers.

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