RU2537919C2 - Method of presowing treatment of seeds of agricultural crops - Google Patents

Abstract

FIELD: agriculture.

SUBSTANCE: method consists in seed treatment during five cycles. In the first cycle the seeds are treated with hot air with the temperature of 70°C. In the second and third cycles - with pulsed infrared radiation with a wavelength of 3.0-4.0 microns and the flux density of 5-10 kW/m². In the fourth cycle - with the infrared radiation with a wavelength of 1-1.4 microns and the flux density of 25-30 kW/m². In the fifth cycle - with the ultraviolet radiation with the wavelength of 0.25-0.3 microns. The interval of each cycle separately from each other is 1-2 sec. The speed of the temperature regime ranges from 1 to 5°C/sec.

EFFECT: invention enables to improve the quality parameters of seeds - germination capacity and germination power.

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Description

The invention relates to agriculture and can be used for seed treatment of any crops at the pre-sowing stage to improve quality indicators, such as germination and germination energy.

To activate the vital processes of each crop, taking into account its initial state, it is important to choose the type of electromagnetic effect, the type of spectrum, the intensity that would be most suitable for it.

To replace the methods of processing crops, in which each crop was treated with one of the most suitable (selected) types of radiation with hard-set exposure parameters (wavelength, pulse frequency, time and frequency of exposure), came the methods of complex (mixed) exposure.

So, the “Method for presowing seed treatment” is known (RF Patent 2090031, IPC ⁶ А01С 1/00, 07.25.95), which provides for simultaneous exposure of seeds to radiation in the infrared and red spectral regions with a certain ratio, volumetric density of radiation and time exposure. Moreover, the radiation flux is formed by means of LEDs or diode lasers.

However, this method, as well as its predecessors, is applicable only to a limited type of crops. In this method, the cells of irradiated objects, which are original resonators, under the action of irradiation with a given wavelength and direction of radiation, enter into resonance with waves whose wavelength is comparable to or a multiple of the size of the cell. At the same time, “standing waves” are formed in the cells, blocking the intercellular metabolic processes.

The closest analogue to the method proposed in the invention is the "Method for pre-sowing processing of leguminous crops" (RF Patent 2433584, IPC A01C 1/00, 11/20/11), including the simultaneous exposure of a seed layer to several types of radiation, including infrared radiation spectral region. In this case, the seed layer with a thickness within 1-2 average grain size simultaneously with infrared laser radiation with a wavelength of 890 nm and a dose density level of 6-7 J / cm ^{2 is} affected by pulsed ultraviolet radiation with a wavelength of 255 nm and a power of 6 J / cm, as well as a pulsed magnetic field with a frequency of 1-2 Hz and the amplitude of the magnetic induction of the field, equal to 20 MT. The impact on the seed layer is carried out in such a way that the amplitudes of the frequency-phase modulations of ultraviolet and infrared laser radiation change synchronously with the amplitude of the pulsed magnetic field in all time intervals.

Closest to the invention in technical essence is an apparatus for processing grain and cereals, containing a table for placing a processed grain product on it, over which blocks of infrared radiation sources are installed, according to the invention, the table is equipped with a vibrator (Patent 2004969, IPC A23K 1/14, 12.30.1993 ) The table and blocks are equipped with a single mechanism for changing the angle of inclination relative to the horizontal, and each block of infrared radiation sources has a fixed radiation wavelength and a control circuit independent of other blocks. The described device allows only drying and disinfection of the product, but not provide presowing treatment.

The essence of the proposed method is as follows: according to the invention, the seed treatment is carried out for five cycles, the first of which is carried out with hot air at a temperature t _air = 70 ^° C for 1-2 s, the second and third cycles are pulsed infrared radiation with a wavelength of λ ₁ = 3.0-4.0 microns and a flux density of P ₁ = 5-10 kW per 1 m ² for 1-2 s, the fourth cycle - infrared radiation with a wavelength of λ ₂ = 1-1.4 microns and a flux density of P ₂ = 25-30 kW per 1 m ² for 1-2 s, and the fifth with ultraviolet radiation with a wavelength of λ ₃ = 0.25-0.3 μm for 1-2 s. For seeds of agricultural crops during the stimulation of sowing qualities, the speed of the temperature regime should vary from 1 to 5 ^° C / s.

The essence of the proposed installation is that in a plant for pre-sowing treatment of crops containing an inclined trough for transporting the treated seeds on it, above which sources of infrared radiation and UV radiation are installed, according to the invention, an air duct is installed at the seed outlet from the hopper hot air is supplied. The inclined trough is equipped with a regulator for changing the angle of inclination with respect to the horizontal, and each source of infrared radiation and UV radiation has a fixed radiation wavelength and a control circuit independent of other sources. The principle of operation of the inclined trough is based on the property of flowability of seeds of agricultural crops moving along the trough tray in a continuous stream in one layer under the influence of gravitational forces.

The figure schematically depicts the proposed installation. It contains an inclined groove 1 for transporting seeds (not shown in FIG.). Above the chute 1, sources of infrared radiation 2-3 and ultraviolet radiation 4 are installed, equipped with reflectors designed to increase the uniform distribution of the radiant flux throughout the chute 1. The radiation sources 2-4 are installed with the possibility of changing the distance from the chute to the radiation sources. For this, each radiation source is equipped with a screw mechanism. The gutter 1 and the radiation sources 2-4 are rigidly interconnected using a common frame 6. On the frame there is a regulator 10 for changing the angle of inclination with respect to the horizontal in the form of a screw mechanism. The controller 10 changes the angle of inclination of the gutter 1 and the radiation sources 2-4 together with respect to the base plane. Sources of infrared radiation 2 are infrared generators of the ESC-1 type, the maximum emissivity of which falls on a wavelength of λ ₁ = 3.6 μm, the source of infrared radiation 3 is an infrared generator KG500, the maximum emissivity of which falls on a wavelength of λ ₂ = 1,2. The source of ultraviolet radiation 4 is an irradiator brand DB15, the maximum radiation of which occurs at a wavelength of λ ₃ = 0.256 μm. Each radiation source 2-4 has an independent electrical control circuit located in the control panel 11. The installation is equipped with a heater 5 for supplying hot air with a temperature of 70 ^° C through the duct 7. The installation has a loading hopper 9 from which the seeds are fed to the groove 1. The dose seed is provided by a shutter 8.

Installation works as follows. Seeds (wheat, barley, rye, etc.) enter the hopper 9. Using the regulator 10 sets the angle of inclination of the groove 1 and radiation sources 2-4 in relation to the base plane. The angle of inclination is selected approximately 21-24 degrees relative to the floor surface. The average speed of the flow of seeds for a given value of the angle of inclination is 0.45 ... 0.55 m / s. The shutter 8 is designed so that it can gradually increase or decrease the number of seeds that are fed for heat treatment. Infrared emitters 2 and 3, ultraviolet emitter 4 and air heater 5 are turned on.

After warming up all the heat sources to the optimum parameters, the shutter 8 of the loading hopper 9 opens. The seeds are fed to the trough in one layer. When seeds are swollen from the loading hopper, the first cycle of treatment with heated air 1 _air = 70 ^° C occurs, the so-called “awakening” process occurs. This air temperature allows the process of waking up the seeds without causing a thermal burn. The thermal threshold of seeds is t _mp = 90 ^° C. This cycle is necessary because the non-awakened grain is not processed well in the future, which will ultimately lead to negative results.

After treatment with hot air, the seeds flow in one layer along the trough, falling into the zone of action of the emitters 2, in which the source of radiation is ESC-1 generators, the maximum emissivity of which falls on a wavelength of λ ₁ = 3.6 μm. The main process of stimulating the sowing qualities of seeds occurs. At this wavelength, the seeds of grain crops have the lowest reflectivity of 15-18%, which helps to penetrate the radiation deep into the seeds and activate the internal potential of the seed.

A generator of the KG500 type is installed in the emitter 3, the maximum emissivity of which falls on the wavelength λ ₂ = 1.2. At a given wavelength, the reflectivity of seeds doubles. Seed shells are stimulated, which for the first time days after planting actively absorb moisture, thereby accelerating the development of the plant.

The final seed treatment cycle is carried out by an ultraviolet emitter 4. When exposed to ultraviolet radiation 4, the seeds are disinfected from pathogenic fungi, pores, etc., which adversely affect the further development of the plant as a whole.

As a result of the interaction of the flow of hot air, IR radiation and UV radiation and the flow of seed material, a biostimulation process is carried out. After biostimulation is completed, the seeds are laid on the curing process, which is 5-10 days.

The method was carried out as follows. Seeds were passed through the gutter in a single layer, which was subsequently subjected to heat treatment. First, for processing in the first cycle, the seeds were treated with hot air at a temperature of 70 ^° C, then in the second and third cycle they were irradiated with an infrared radiation generator (type ESC-1) with a wavelength of λ ₁ = 3.0-4.0 μm and a flux density P ₁ = 5-10 kW per 1 m ² , then in the fourth cycle the irradiation was carried out by an infrared radiation generator (type KG500) with a wavelength of λ ₂ = 1-1.4 μm and a flux density of P ₂ = 25-30 kW per 1 m ² and the fifth cycle was carried out in the area equipped with an ultraviolet emitter (type DB15) λ ₃ = 0.25-0.3 μm. In the process, the seed flow rate was controlled by changing the angle of inclination of the gutter relative to the floor surface.

To verify the effectiveness of the proposed method, the treatment of wheat seeds "Tulunskaya 12" was carried out in comparison with the control. As a control, seeds that were not subjected to pre-sowing treatment were taken.

Processed by the proposed method and control seeds were sown on plots in the field. Throughout the growing season, they were monitored. The observation results are shown in tables 1, 2 and 3.

Table 1 Laboratory germination of wheat seeds "Tulunskaya 12", pcs.,% No. Options Repetition total number one 2 3 four Average value one The control one hundred 28 34 78 83 55.75 four The proposed method one hundred 71 72 81 81 76.25

table 2 The growth power of wheat seeds "Tulunskaya 12", gr. No. Options Repetition total number one 2 3 four Average value one The control one hundred 3.31 3.65 7.28 5.52 4.94 2 The proposed method one hundred 5.63 6.13 7.13 7.41 6,575

Table 3 Yield of wheat seeds "Tulunskaya 12", t / ha No. Options Productivity, t / ha one The control twenty 2 The proposed method 53,4

Claims (2)

1. The method of pre-sowing treatment of leguminous crops, including the simultaneous exposure of the seed layer to infrared laser radiation and pulsed radiation of the ultraviolet range, as well as pulsed magnetic field, characterized in that the effect is carried out for five consecutive stages, the first of which is carried out with hot air at 70 ° C, second and third - pulsed infrared wavelength of 3.0-4.0 microns, the flow density of 5-10 kW / m ² and 1-2 with the exposure, the fourth - infrared and radiation wavelength 1-1.4 microns, the flux density of 25-30 kW / m ² and 1-2 with the exposure, the fifth - UV 0.25-0.3 micron wavelength exposure and 1-2. 2. A device for processing grain and cereals, containing a table for placing a processed grain product on it, above which blocks of infrared radiation sources are installed, equipped with a vibrator, characterized in that infrared and ultraviolet radiation sources are installed above the inclined trough for transporting seeds, an air duct installed on exit from the hopper through which hot air with a temperature of 70 ° C is supplied.

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