RU2364075C1 - Method of grain crops storage - Google Patents

Abstract

FIELD: agriculture.

SUBSTANCE: method involves cyclic treatment of grain crops by a sinusoidal electromagnetic field using a low frequency generator in places of the constant storage continuously within the whole storage period. The treatment is carried out in successive continuous cycles, each of which involves two stages, on the first one the treatment is carried out with a frequency in the range of 7-9 Hz within not more than 40 minutes, and on the second stage the treatment is carried out with a frequency in the range 13-15 Hz within not more than 25 minutes. Moreover, the low frequency generator with the range of frequency equalled 1×10^-5÷30 Hz and output capacity less than 140 mW is used. Inductance coil with active resistance in the range of 2.0-8.00 Ohm and inductance equalled 2.0-5.0 mHz is used as a radiator. Inductance coil can have conical, cylindrical or toric shape, it also has a dielectric coreless frame and is placed in the distance from the treated products.

EFFECT: high safety of grain crops properties during the whole storage period due to improved storability.

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Description

The invention relates to agriculture, and in particular to methods for storing agricultural products, in particular to a method for storing crops.

The prior art it is known the impact of various physical methods on the processes taking place in agricultural production. The use of electrical, electromagnetic and magnetic effects, as well as their various combinations with sound and optical effects, allows you to adjust the functional state of biological objects of plant origin. So, for example, in order to grow plants, mushrooms and seaweeds, it is widely known that electromagnetic radiation is applied by applying modulated energy pulses of a certain sequence and amplitude to biological objects of plant origin themselves, as well as to water in which seeds of crops are soaked, water and spray plants . The amplitude parameters of the pulses of electromagnetic radiation are selected depending on the type of plants and phase of development [RU 2090053, 1997].

A known method of storing biological and food products, including sterilization or pasteurization using devices emitting radio waves in the high frequency range, preferably from 6 MHz to 1 MHz with preheating of the treated object, the device is a pair of facing one another emitting surfaces associated with the generator Microwave fields [RU 2067400, 1996]. The disadvantage of this method is that it allows you to suppress pathogenic and spore-bearing bacteria, however, leads to a loss of sowing qualities.

A similar method of storing agricultural products for the same purposes is known using a microwave device with a magnetron and a waveguide [Japanese Application No. 2-211855, 1989].

The disadvantage of such methods is the following. It is known from the prior art that the use of microwave radiation for processing biological objects of plant origin is quite effective, but leads to rapid heating of objects, requires special measures to protect personnel, and there is usually a negative effect on the taste of the object. In addition, there is no data on the effect of these physical methods on the preservation of the properties of agricultural products for a long time.

A known method using a block of lasers with a wavelength of 670 and 730 nm as a stimulator of seed germination. To create bulk optical radiation, a system of waveguides and splitters ending in optical glass rods for their location inside a heap of seeds is connected to the laser units [RU 2132119, 1996].

The disadvantage is that seed treatment is carried out only in a through mode, which requires additional production areas, while data on the impact of such an impact on the safety of agricultural products is not available.

These disadvantages are partially eliminated by a known method of processing agricultural products using compact devices, which are a source of modulated optical study of low power, the spectral components of which are in the range 3 × 104-3 × 1015 Hz. Opto-acoustic radiation is generated using spatial modulation with a low surface power and wavelength of the original optical radiation from the visible, red or infrared spectra. As emitters use LEDs or laser diodes, the modulation is carried out by sound waves using an acoustic resonator [RU 2192728, 2002]. Due to the fact that optical-acoustic radiation of low surface power is used to process agricultural products, the crop cell is not damaged, and a targeted effect is achieved - accelerating the metabolism, which manifests itself in an increase in the yield of grain crops. Data on the preservation of crops is not available.

A known method of influencing biological objects in agriculture, which is irradiated with modulated optical radiation at an average density of the incident power of 10 ^-6 -2 × 10 ^-1 / cm ² . Modulation is carried out by irregular analog vibrations, the spectral components of which are in the range of 10 ^-4 -10 ^-6 Hz. As irregular analog oscillations in special cases, use voltage or transient currents in electrical circuits or, for example, flicker noise. This enhances the biostimulating effect, determines the growth of plant productivity. Lasers or LEDs of the visible and / or infrared ranges are used as the source of optical radiation, a linearly increasing, exponentially increasing sinusoidal voltage generator, flicker noise generator, etc. are used as an irregular oscillation generator. [RU 2116089, 1996].

However, the known method does not give a stable positive effect and data on the preservation of the properties of crops is not available.

The objective of the present invention is to provide a method for storing crops that provides a technical result - high preservation of their properties during the entire storage period by improving keeping quality.

The problem is solved in that the method of storing crops is characterized in that it includes cyclic treatment with a sinusoidal electromagnetic field using a low frequency generator in places of constant storage continuously throughout the entire storage period, and the processing is carried out in sequential continuous cycles, each of which includes two stages , in the first of which processing is carried out with a frequency range of 7-9 Hz for no more than 40 minutes, and in the second stage, with a frequency range of 13-15 Hz for no more than 25 minutes

In addition, the method is characterized in that they use a low-frequency generator with a frequency range of 1 × 10 ^-5 ÷ 30 Hz, use the output power of a low-frequency generator less than 140 mW, use an inductor as an emitter. Moreover, an inductor with an active resistance in the range of 2.0-8.0 Ohms and an inductance of 2.0-5.0 mH, which can have a cone-shaped or cylindrical or toroidal shape, and also made with a dielectric frame without a core and placed at a distance, is used. from processed products.

The method is as follows.

The use of a standard low-frequency generator loaded on an inductor is proposed as a means of physical impact on crops. The latter is used as a radiator.

Using the proposed tool allows you to provide exposure to a weak electromagnetic field in the frequency range from 1 × 10 ^-5 ÷ 30 Hz. The impact is carried out by continuous cyclic processing of crops in places of their constant storage, both in collars (heaps, heels), and in the passing mode, for example, through the use of conveyors.

As a low-frequency generator, any standard device can be used, for example, a “BIO-EM resonator” with a frequency range of 1 × 10 ^-5 ÷ 30 Hz with a sinusoidal shape of the output signal and an output power of less than 140 mW. A standard low-frequency generator GZ-122, G6-36 or other technical analogues of these generators can also be used as a generator.

The low-frequency generator operates on an inductor, which acts as a radiator. As an emitter, an inductor of any shape can be used, for example, cone-shaped, toroidal or cylindrical, preferably with an active resistance of 2.0 Ohms to 8.0 Ohms, an inductance of 2.0 to 5.0 mH and a frame made of dielectric material with an air core or other similar core.

An inductor can be placed above the workpiece at a distance of up to 50 m from the low-frequency generator.

The low-frequency generator allows for a gentle effect on the cell of a biological object with an electromagnetic field. Such an effect ensures the preservation of the physiological rest of the cell, while the activity of pathogenic bacteria is significantly reduced and the influence of the adverse temperature and humidity storage conditions is minimized. The claimed solution allows you to implement a new approach to solving problems associated with the preservation of the target properties of a biological object in the storage process.

It is known from the prior art that exposure to an electromagnetic and / or magnetic field with certain characteristics leads to an increase in crop yields, while the effect achieved is traditionally associated with the procedure of cell awakening and increase its metabolism by forcibly withdrawing from a state of physiological rest. It is also known that electromagnetic exposure allows you to ensure the safety of agricultural products, however, increasing the safety of a biological object is achieved due to the strong impact of, for example, a microwave field, which leads to partial processing and, consequently, to the loss of sowing qualities and other useful properties of the crop processed in this way .

The claimed invention provides qualitative and quantitative safety of the beneficial properties of a bioobject during the entire storage period. The achieved effect of the preservation of properties is ensured mainly by reducing the activity of pathogens. The sowing properties of grain crops after the period of their storage with the use of the effects we have claimed also do not lose their quality.

The drawing shows a schematic diagram of the claimed impact, where 1 is a low-frequency generator; 2 - connecting cable; 3 - inductor; 4 - processed agricultural products.

The claimed method of storing crops is illustrated by examples of specific implementation, from which the positive effect of processing with low-frequency fields on the preservation of the grain crop obviously follows.

Example 1

The harvested barley grain of the AChA variety (delivered to the grain mill of PSK Bobrovsky on August 22, 2005 at a moisture content of 26.0%) was stored in a heap processed by a low-frequency generator throughout the entire storage period. Storage conditions: ordinary granary with outdoor temperature, asphalt flooring, without forced ventilation, embankment height 1.6 m, lot size 87 t.

For processing, a low-frequency generator of the brand “BIO-EM resonator” was used with a frequency range of 1 × 10 ^-5 ÷ 30 Hz; the form of the output signal is a sinusoid, the amplitude of the signal is 0.10-4.0 V; the number of frequencies in the cycle 1-30; signal duration of one frequency 1 min - 24 hours the duration of the pause between signals is not more than 18 hours; maximum power consumption - 3 W (external power supply 12.0 V), signal amplitude 4.0 V at a load of 8.0 Ohms, maximum output power - less than 0.75 W, mass-dimensional characteristics, mm 195 × 105 × 58 , weight - 0.6 kg.

Processing conditions by the low-frequency generator: cyclical effects, with each cycle consisting of 2 stages.

1st stage: the generated frequency on the generator within the range of 7 Hz, the processing time is 30 min, a cone-shaped coil with an inductance of 2.0 mH is used, the resistance is 8.0 Ohms, the voltage amplitude on the coil is 1.5 V, which corresponds to P _{max out} less than 140 mW. Other exposure parameters in accordance with the technical characteristics of the used low-frequency generator;

Stage 2 - similar to the first, at a frequency of 13 Hz and a time of 20 minutes.

Processing cycles are sequentially alternated throughout the entire shelf life.

Example 2

The same as in Example 1, the grain of barley varieties "AChA" (humidity 26.0%) was stored in a heap processed by a low-frequency generator throughout the entire shelf life. Storage conditions as in Example 1.

For processing, a similar low-frequency generator was used. Processing conditions by the low-frequency generator: cyclical effects, with each cycle consisting of 2 stages.

1st stage: the generated frequency on the generator within the range of 9 Hz, the processing time is 40 min, a cone-shaped coil with an inductance of 5.0 mH is used, the resistance is 2.0 Ohms, the amplitude of the voltage across the coil is 1.5 V, which corresponds to P _{max out} less than 140 mW. Other exposure parameters in accordance with the technical characteristics of the used low-frequency generator;

Stage 2 - similar to the first, at a frequency of 15 Hz and a time of 25 minutes

Processing cycles are sequentially alternated throughout the entire shelf life.

Example 3

The ACHA barley grain (humidity 26.0%) was stored in a heap processed by a low-frequency generator throughout the entire storage period. Storage conditions as in Example 1.

For processing, a similar low-frequency generator was used. Processing conditions by the low-frequency generator: cyclical effects, with each cycle consisting of 2 stages.

Stage 1: the generated frequency on the generator within the range of 8 Hz, the processing time is 35 min, a cone-shaped coil with an inductance of 3.0 mH is used, resistance is 4.0 Ohms, the amplitude of the voltage across the coil is 1.5 V, which corresponds to P _{max out} less than 140 mW. Other exposure parameters in accordance with the technical characteristics of the used low-frequency generator;

2nd stage - similar to the first, at a frequency of 14 Hz and a time of 23 minutes

Processing cycles are sequentially alternated throughout the entire shelf life.

Example 4 (control).

The barley grain was stored in a heap without electromagnetic processing. Storage conditions are similar to Example 1, the batch volume is 1.3 tons

The first analyzes were carried out 4 days after loading the grain. As a result of the analysis, the total grain contamination (24-26%) and laboratory germination (62-63%) were determined. Reduced laboratory germination of grain due to incomplete period of post-harvest ripening of barley. Subsequent analyzes were performed on 09.09.2006 and 20.10.2005. Microorganisms were present in the test grain:

Helmintosporum, Fusarium, Muccor, Altemarium, Pennicilium. The research results are shown in the table.

As can be seen from the above examples, with the same initial data on infection and laboratory germination, after 2 weeks the laboratory germination of seeds in the control variant decreased to 7-8%, while the laboratory germination of grain treated according to the invention increased from 62% to 87 %, which is most likely due to the acceleration of the process of post-harvest ripening of seeds. After 2 months, the treated grain had a laboratory germination rate of 90% and a total infection rate of 26%, with 78% in the control variant. An analysis of the species composition of microorganisms during storage of grain with high humidity indicates that it varies depending on the temperature factor in the heap and under the influence of tuning a low-frequency generator for certain types of microorganisms. In the present example, in the first grain storage period (September-early October) Helmintosporum prevailed (control example - 21-26%, according to the invention - 23-27%), when adjusting the treatment regime, the percentage of Helmintosporum lesions decreased to 19-26%.

Date of sampling for analysis Control experience Experience according to the invention (Examples 1, 2, 3) Total infection,% Laboratory germination,% Total infection,% Laboratory germination,% 08/26/2005 24.0 63.0 26.0 62.0 09.09.2005 29.5 7.5 29.0 87.0 10/20/2005 78.0 8.5 26.0 90.2

The results of the comparison show that the use of a low frequency generator for storing crops allows not only to reduce the activity of pathogens, but also to maintain and even increase the laboratory germination rate of grain. The increase in laboratory germination rates is probably associated with maintaining the integrity of the shell, accelerating the post-harvest ripening of grain during its storage.

Thus, the claimed method using a low-frequency generator for processing grain crops allows not only to reduce product losses during storage, but also to preserve the qualitative and quantitative characteristics of their beneficial properties. The invention can be used in agriculture by both large and small agricultural producers without additional capital costs for equipping granaries. In addition, the invention eliminates the consequences of adverse storage conditions of agricultural products and ensures the environmental cleanliness of the storage process, without significant costs for the organization of the process.

Claims (8)

1. A method of storing crops, characterized in that it includes cyclic processing with a sinusoidal electromagnetic field using a low frequency generator in places of constant storage continuously for the entire storage period, moreover, the processing is carried out in sequential continuous cycles, each of which includes two stages, in the first of which processing is carried out with a frequency range of 7-9 Hz for no more than 40 minutes, and in the second stage, with a frequency range of 13-15 Hz for no more than 25 minutes. 2. The method of storing crops according to claim 1, characterized in that they use a low-frequency generator with a frequency range of 1 · 10 ^-5 ÷ 30 Hz. 3. The method of storing crops according to claim 1, characterized in that the output power of the low-frequency generator is less than 140 mW. 4. The method of storing crops according to claim 1, characterized in that an inductance coil is used as an emitter. 5. The method of storing crops according to claim 1, characterized in that they use an inductor with an active resistance in the range of 2.0-8.0 Ohms and an inductance of 2.0-5.0 mH. 6. The method of storing crops according to claim 1, characterized in that they use an inductor having a conical, or cylindrical, or toroidal shape. 7. The method of storing crops according to claim 1, characterized in that they use an inductor with a dielectric frame without a core. 8. The method of storing crops according to claim 1, characterized in that the inductor is placed at a distance from the processed products.

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