RU102172U1 - DEVICE FOR PRE-SEED TREATMENT OF SEEDS IN ELECTRIC FIELD - Google Patents

Abstract

 1. A device for pre-sowing seed treatment in an electric field, including a loading hopper, an output tray, a feed conveyor, a field source located above the upper branch of the feed conveyor a stationary flat grounded electrode, characterized in that the field source is made in the form of a system of three cylindrical potential electrodes interconnected through insulating racks with the lower frame of the rhombic jack rigidly connected to its lower plane, and the upper frame of the rhombic jack is rigidly connected to its upper her plane and fixed through insulators on the frame of the device, while the conveyor belt is equipped with sides. ! 2. The device according to claim 1, characterized in that the device is equipped with a control unit including a frequency drive speed controller, a frequency converter for supplying a system of potential electrodes and a voltage regulator.

Description

The utility model relates to agriculture, in particular to pre-sowing seed treatment.

A device is known for pre-sowing treatment of potato tubers in an electromagnetic field, including a loading container, a feeding conveyor, an exposure system consisting of bipolar electrodes mounted on a U-shaped dielectric plate above the inlet and outlet openings of the stator housing of a three-phase electric motor, which is the source of the electromagnetic field, while the working section of the load-bearing tape is placed in the stator cavity, and bipolar electrodes are located above the load-carrying tape (RF Patent No. 2088066, IPC A01C 1/00, published May 20, 2002).

However, this installation cannot be used for seed treatment of cereals, vegetables and fodder crops. So the electric field inside the stator of a three-phase electric motor has a radial distribution, and therefore the field across the width of the conveyor belt will not be the same, which requires additional mixing, and due to the fact that the geometric characteristics of the radiator in this technical solution cannot be changed, therefore, unchanged the field parameters remain, which reduces the range of processed seeds and the types of processing. In addition, the low productivity of the installation is due to the insignificant cross-sectional dimensions of most motor stators not exceeding 300 mm in diameter for most motors. Dust and high humidity, which are a concomitant of the pre-sowing process, lead to premature aging of the stator winding insulation, resulting in inter-turn short circuits, resulting in the installation inoperative.

A known machine for pre-sowing treatment of wheat seeds in an electric field, including a loading hopper, a feed conveyor with sides, an exposure system consisting of a flat grounded electrode and a field source - a flat potential electrode located above the carrier tape at a distance of 6.5 cm and connected to the negative potential of the high-voltage power supply (RF Patent No. 2181234, IPC А01С 1/00, published on April 20, 2002 - prototype).

However, in this setup it is impossible to obtain a rotating elliptically polarized field that provides uniform field effects on the seeds randomly oriented in the layer.

The presence of boards mounted on the conveyor leads to wear of the edges of the belt moving along the sides, to wear of the sides themselves, which reduces the maintenance-free life of the installation, as well as additional friction, which increases energy consumption and grain loss. The disadvantages of this setup include the inconstancy of the parameters of the generated corona discharge field, due to the presence of process dust, which, deposited on the potential electrode, leads to the appearance of regions on it in which a lower potential value is required to create the corona discharge field, which in turn, leads to a redistribution of the electric charge on the surface of the electrode, hence to a distortion of the electric field. In addition, since the biological effect of the electric field, and as a consequence of the current, depends on its parameters: field strength, amplitude value of current density, frequency, current shape, exposure time, the effect is a complex fiction of these factors, and for each object you will need to use your own parameters of the electric field and exposure modes, and if you consider that the seed can be considered as a dipole, then, respectively, when processing with a constant electric field to obtain optimal results visible need seed orientation in the electric field, which is technically a given installation is unattainable.

The claimed utility model of a device for pre-sowing seed treatment in an electric field solves the problem of improving the quality of processing and making it possible to process various types of seeds and types of treatment while increasing the useful life of the device.

The technical result is achieved by the fact that in the device for pre-sowing seed treatment in an electric field, including a feed hopper, an outlet tray, a feed conveyor, a field source located above the upper branch of the feed conveyor, a stationary flat grounded electrode, the field source is made in the form of a system of three cylindrical potential electrodes interconnected through insulating racks with the lower frame of the rhombic jack rigidly connected to its lower plane, and the upper frame of the rhombic jack is rigidly connected with its upper plane and through insulators mounted on the installation frame, while the conveyor belt is equipped with sides. The installation is equipped with a control unit including a frequency regulator of the drive speed, a frequency converter for powering the system of potential electrodes and a voltage regulator. This device allows the processing of seeds in both alternating and constant electric fields. By controlling the speed of the asynchronous motor with a frequency controller, the speed of the conveyor belt is changed, accordingly, the time spent by the seeds in the field of exposure to the electromagnetic field is changed. As a device for frequency regulation of engine speed, for example, a frequency converter of the EI-7011 series is used. Engine speed is selected in accordance with the processing time: where V is the speed of the conveyor belt, l is the length of the electrodes (in the proposed installation, l = 1.2 m), t is the time of seed treatment.

Switching of direct and alternating current circuits is carried out by means of a switch on the control unit. The possibility of supplying both alternating and direct voltage to the electrodes provides the implementation of various types of processing using one installation. The electrodes are connected to the terminals of the control unit. The unit is powered from a three-phase network with a voltage of 380 V.

In the seed treatment mode with an alternating electric field, a phase voltage is applied to the electrodes. The voltage value is switched by setting the control handle located on the control unit panel in the corresponding position. This achieves a coarse adjustment of the electric field in the working space between the movable and fixed electrodes. The maximum voltage at the output of the voltage regulator is 10 kV. Structurally, the voltage regulator is combined with a frequency converter. To fully adjust the intensity, the dependence of the electric field strength on the distance between the electrodes is used, which in a first approximation is expressed as: where U is the voltage at the electrode, D is the distance between the movable and stationary electrode, which is the sum of the distance from the fixed electrode to the conveyor belt (2 cm) and the adjustable distance from the conveyor belt to the system of movable cylindrical electrodes (6.5-8 cm) . The lower grounded flat electrode is necessary to equalize the magnitude of the electric field in the seed treatment area. The use of the cylindrical shape of smooth electrodes as a source of electric field was chosen in connection with the desire to reduce corona on the surface of the electrodes. One of the conditions for high-quality processing on the claimed model when using conveyor belts of various widths is compliance with the ratio of the distances from the edges of the tape to the extreme electrodes. This distance should be ½ of the distance between the electrodes. Compliance with these ratios ensures uniformity of the electric field.

Figure 1 and 2 shows a General view of the installation. In Fig.1 is a General side view, in Fig.2 is a field source (a system of cylindrical potential electrodes).

The installation consists of a feed hopper 1 and an outlet tray 2, a belt feed conveyor 3 with a drive 4. The upper branch of the conveyor belt 3 is located between the grounded flat electrode 5 and the field source, made in the form of a system of 3 cylindrical potential electrodes 6, rigidly fixed through insulating racks 7 with the lower frame 8 of the diamond jack 9, the upper frame 10 of which through the insulators 11 is rigidly fixed to the frame 12 of the device. In turn, the lower frame 8 is rigidly connected with the lower plane of the rhombic jack, and the upper frame 10 with its upper plane. The conveyor belt 3 has sides 13. The installation is equipped with a control unit 14, including a frequency controller for the speed of the drive 4, a frequency converter for supplying a system of potential electrodes 6 and a voltage regulator.

As studies have shown, for different cultures, the frequency of exposure to an electromagnetic field is different and lies in the low-frequency region. The high sensitivity of seeds to a low-frequency electromagnetic field is associated with a change in pH and the release of proteins that accelerate the release of seeds from dormancy and stimulate the development of restoration processes in them, determined by the restoration of the barrier function of the membranes, which leads to increased germination and the absence of microflora after treatment.

Table 1 shows the optimal parameters of the pre-sowing treatment of seeds of spring and winter wheat, peas, carrots, cotton, barley, corn, sunflower and tomatoes found experimentally.

Type of seed Field frequency Electrode voltage, kV The height of the electrodes above the tape, see Processing time, s Yield increase,% The germination rate,% Spring wheat 14-16 8 7 13 eighteen 35 Winter wheat 15-19 10 6.5 fifteen 27 36 Peas 17-20 7 7.5 10 eighteen 33 Carrot 18-20 5 7.5 12 thirty fifteen Cotton 17-20 3 8 5 thirty 22 Barley 14-16 8 7.5 12 24 46 Corn 7-10 7 7.5 eleven 27 35 Sunflower 7-10 6 7.5 10 eighteen 36 Tomatoes 16-18 5 8 7 24 19

The processing results shown in the table indicate that both germination and productivity are simultaneously increasing.

An example of the use of the installation when processing seeds with an alternating electromagnetic field:

seeds, for example peas, are poured into the hopper 1. Depending on this, the frequency of the electromagnetic field (18 Hz) is set using a frequency converter, then, using the control unit, the voltage value (7 kV) supplied to the system of movable electrodes 6 is set, and then, turning the screw of the diamond jack 9, the height of the electrodes 6 is set above the surface of the carrier belt 3 of the conveyor (7.5 cm) and using the frequency controller to drive the conveyor belt set the time spent by the processed grain in an electromagnetic field (10 s). After setting the parameters, voltage is applied to the electrodes, starting the conveyor belt drive. The sides of the conveyor belt with a height of 6.5 cm are made with the possibility of maintaining and leveling the seed layer with a height of 5 cm. The system of cylindrical potential electrodes in the original version are located above the carrier tape at a height of 6.5 cm.

If it is necessary to treat seeds in an electrostatic field (type of treatment), a constant voltage is applied to potential electrodes.

Thus, the claimed utility model has the ability to adjust the parameters of the electromagnetic field in a wide range, the ability to change exposure, the ability to use both direct and alternating voltage (type of processing), which ultimately determines its versatility and high quality seed treatment in an electric field , and the implementation of the sides directly on the carrier tape prevents friction and wear of the corresponding parts of the installation.

Claims (2)

1. A device for pre-sowing seed treatment in an electric field, including a loading hopper, an output tray, a feed conveyor, a field source located above the upper branch of the feed conveyor a stationary flat grounded electrode, characterized in that the field source is made in the form of a system of three cylindrical potential electrodes interconnected through insulating racks with the lower frame of the rhombic jack rigidly connected to its lower plane, and the upper frame of the rhombic jack is rigidly connected to its upper her plane and fixed through insulators on the frame of the device, while the conveyor belt is equipped with sides. 2. The device according to claim 1, characterized in that the device is equipped with a control unit including a frequency drive speed controller, a frequency converter for supplying a system of potential electrodes and a voltage regulator.