RU2078490C1 - Method and apparatus for presowing treatment of seed material - Google Patents

Abstract

FIELD: agriculture. SUBSTANCE: method involves exposing seed material to electromagnetic field with frequency corresponding to resonance frequency causing intralobular transformations in seed material at conformance oscillations (in particular, 8-19 Hz frequency range). Apparatus has low- frequency electromagnetic oscillation source and emitter electrically connected with mentioned source. Emitter is positioned so that radiation is directed to seed material. Frequency may be regulated within the range of 8-17 Hz. Radiated signal shape may be regulated to correspond intralobular transformations in seed material. EFFECT: increased efficiency and improved quality of treated seed material. 13 cl, 1 dwg

Description

 The invention relates to agriculture, and more specifically relates to a method for pre-treatment of seed and device for its implementation.

 It is known that the acceleration of ripening, increasing yield directly depends on the quality of the seed. Widespread use of electromagnetic radiation of various spectra and ranges to improve the quality of seed.

 So, for example, a known method of processing seed by irradiating it with electromagnetic radiation in the optical range (US, A, 4041642).

 This method is characterized by low productivity, since processing can only be carried out in a very thin layer of seed due to the strong absorption of optical radiation by the processed seed.

 A device for processing seed is known that implements this method and contains a source of electromagnetic radiation in the optical range (see the same patent).

 The specified device has poor performance for the reason described above.

 There is a method of pre-sowing treatment of seeds, which consists in the magnetic activation of seeds based on the interaction of the gradient magnetic field with moving charged particles located in the volumes of various plants (SU, A, 1253445).

 In this method, to create a magnetic field gradient, it is necessary to move a large volume of seed, which leads to significant energy costs.

 A device is known for pre-sowing treatment of seed material, implementing the specified method and containing permanent magnets located at certain distances along the conveyor moving the seed (see the same copyright certificate).

 In the specified device, the seed is treated with a magnetic field with a frequency that is close, but not equal to the frequency of conformational vibrations, since it is very difficult to establish the distance between the poles of the magnets corresponding to the unstable speed of movement of the seed material along the conveyor belt, since the speed of the belt in existing conveyors depends from the load and is in a certain range of speeds.

 Thus, the specified device is cumbersome, and to implement the specified method requires large areas and a lot of time.

 Attempts have been made to use low-frequency electromagnetic radiation.

 So, there is a known method of pre-sowing treatment of seed material, which consists in acting on the material with a low-frequency electromagnetic field (collection "The influence of natural and weak artificial magnetic fields on biological objects", 1973, Belgorod, p. 22).

 In this method, low-frequency radiation with a frequency of 20 Hz and above is used to treat millet seeds.

 However, this method did not find wide application because of the extremely low efficiency and instability of the results, since the increase in yield was either extremely low or there was no increase in yield at all.

Thus, this method is inherent in the instability of obtaining the result: 8-10% increase in yield. The probability of the event is about 52%
A device is known for pre-sowing treatment of seed material, implementing the specified method and containing a source of low-frequency electromagnetic waves and an electrically connected emitter source, the electromagnetic radiation of which is directed to the seed (see the same collection).

 In the specified device, the source of electromagnetic waves is a standard low-frequency generator of sinusoidal waves. The impact of such a low-frequency electromagnetic field on the seed is extremely inefficient, since the increase in yield is extremely low and reaches only 8-10%. As a result, this device that implements the above method has not been widely used.

 The aim of the invention is to develop a method for pre-sowing treatment of seeds with a low-frequency electromagnetic field, which provides a tangible and stable increase in crop yields by 20-25% with simultaneous improvement of product quality, and the creation of a device for pre-sowing processing of seeds using this method.

 This is achieved by the fact that in the method of pre-sowing treatment of seed, which consists in exposing the seed to a low-frequency electromagnetic field, according to the invention, a low-frequency electromagnetic field is used having a frequency corresponding to the resonant frequency of the intriglobular transformations in the seed during conformational vibrations.

 It is advisable to use a low-frequency electromagnetic field having an energy below the energy of breaking hydrogen bonds in the seed.

 When processing seeds affects two well-known factors: the high sorption activity of protein enzymes (D.E. Koshland J. "Teor. Biol". V. 2, 1962, p. 75), leading to the formation of a non-specific enzyme-substrate complex, excluding an enzyme from work, and the existence of vibrational processes leading to intramolecular (intraglobular) transformations of a chemical nature, destroying a non-specific enzyme-substrate complex and including the enzyme in active work with the formation of a specific enzyme-substrate complex (Chetv Rikov EP "Biophysics", Vol. 13, 1968, Moscow, p. 864).

 The formation of a nonspecific enzyme complex, contributing to the stabilization of the system, at the same time, in some way "takes out" a certain proportion of enzymes from the game and reduces the efficiency of the catalysis process. Under natural conditions, conformational vibrations of a relaxation nature arise in the system. The formation and relaxation of a stabilizing nonspecific enzyme complex will have rather slow vibrations, and the resulting complex will have weak bonds. This allows the enzyme to periodically free itself from the non-specific substrate and form a specific enzyme-substrate complex, that is, to participate in the metabolic processes of the system.

 This can easily be done if the discrete free energy levels of the complex lie close enough (which is likely for a non-specifically linked enzyme complex, since in this case the total vibrational energy of the sorbent molecule is greater than or equal to the activation barrier) and separated by a relatively low energy or entropy barrier, at which for the transition of one state to another, it is required to change successively a relatively small number of weak bonds. Such a condition turns out to be sufficient because, at a low collision frequency, a fluctuation of vibrational energy can be realized in an “energized” molecule.

 The relaxation process of the complex described above can be accelerated by external influences if additional energy is supplied in the form of low-frequency electromagnetic oscillations in the resonant mode.

где ω частота интраглобулярного переноса;
w_o частота соударений электронов;
m масса электрона;
Е_o энергия перехода с одного уровня на другой;
L высота барьера;
U ширина барьера;
ℏ постоянная Планка.This resonant frequency can be calculated according to the well-known formula for calculating the frequency of tunnel transport (Blumenfeld L. A. Problems of biological physics. M. Nauka, 1974, p. 229):

where ω is the frequency of intraglobular transport;
w _{o the} frequency of collisions of electrons;
m is the mass of the electron;
E _o energy transition from one level to another;
L barrier height;
U is the width of the barrier;
ℏ Planck constant.

 The frequency obtained from this calculation can practically be used for processing.

 At this frequency, as mentioned above, at least one of the weak bonds of the enzyme complex contained in the seed being processed breaks, the electron density redistributes in the enzyme molecule, which leads to a noticeable increase in the enzymatic activity and, as a result, accelerated development of the seeded material after patentable processing. The energy of this radiation should not exceed the energy of the breaking of hydrogen bonds, comprising 4-4.5 kcal / mol.

 In the general case, the required effect for almost seeds and tubers of all plant species is achieved by using the frequency of electromagnetic oscillations from 8 to 19 Hz. Such processing should be carried out no later than 10 days before sowing.

 Frequencies below 8 Hz and above 19 Hz are outside the resonant frequencies of intraglobular transformations in plants used in experiments. It is possible that outside this range there are types of organic substances with resonant frequencies of intraglobular transformations corresponding to frequencies up to 8 Hz and more than 19 Hz, but they have not been established.

 The goal is also solved by the fact that in the device for pre-sowing processing of seed material, implementing the above method and containing a source of low-frequency electromagnetic waves and an electrically connected source emitter, the electromagnetic radiation of which is directed to the seed, according to the invention, the source of low-frequency electromagnetic waves is made adjustable in frequency in the range from 8 to 19 Hz and in the form of the emitted signal corresponding to intraglobular transformations in d the seed being processed.

 It is desirable that the source of low-frequency electromagnetic waves was made additionally adjustable in terms of radiation power.

 It is advisable to provide in the device a means of controlling the operation of an adjustable source of low-frequency electromagnetic waves, the output of which is electrically connected to an adjustable source.

 The source of low-frequency electromagnetic waves may contain means for generating a radiated signal in frequency and its shape, electrically connected with the output of the control means and the emitter.

 The source of low-frequency electromagnetic waves may further comprise means for controlling the radiation time and its power, electrically connected to the output of the control means and connected to the emitter.

 In the device, it is advisable to provide a computer whose output is connected to the input of the control means.

 The means of generating the emitted signal in frequency and shape may include a reference generator having first and second outputs, a synthesizer of samples of the phase of the emitted signal, having first and second inputs and output and connected with its first input to the first output of the reference generator and its second input to the output of the control and a synthesizer of the shape of the emitted signal, having first, second and third inputs and an output connected by its first input to the second output of the reference generator, by its second input with the output of the synthesizer samples of the phase of the emitted signal and its third input with the output of the control means and electrically connected with its output to the emitter.

 It is desirable that the means for controlling the radiation time and its power contain a timer, the input of which is connected to the output of the control means, and an adjustable power amplifier having first and second inputs and output and connected by its first input to the output of the timer, its second input to the output of the form synthesizer means for generating the emitted signal and output with the emitter.

 This embodiment of the patented device that implements the method according to the invention provides a tangible and stable increase in crop yields while improving product quality, since it allows you to increase the yield without the use of chemical fertilizers and herbicides, when used, in particular, the latter are harmful admixtures in food products, which reduces their quality.

 The invention is illustrated by the description of a specific example of its implementation with reference to the accompanying drawing, which shows a block diagram of a device implementing the method according to the invention.

 A method for pre-sowing treatment of seed according to the invention consists in exposing the seed to a low-frequency electromagnetic field.

 A low-frequency electromagnetic field is used having a frequency corresponding to the resonant frequency of the intraglobular transformations in the seed material under conformational vibrations, and an energy lower than the energy of breaking of hydrogen bonds in the seed material.

 Use a low-frequency electromagnetic field with a frequency in the range from 8 to 15 Hz.

 Processing of seed is carried out no later than 10 days before sowing.

 The device contains a source 1 of low-frequency electromagnetic waves and an electrically connected emitter 2, the electromagnetic radiation of which is directed to the seed (not shown in the drawing).

 Source 1 of low-frequency electromagnetic waves is made adjustable in frequency in the range from 8 to 19 Hz, in the form of the emitted signal, corresponding to the intraglobular transformations in this processed seed and the radiation power.

 The device according to the invention also comprises means 3 for controlling the operation of the regulated source 1, the output of which is electrically connected via the bus 4 to the adjustable source 1, and a computer 5, the output of which is connected via the bus 6 to the input of the means 3.

 The source 1 of low-frequency electromagnetic waves contains means 7 for generating the emitted signal in frequency and its shape and means 8 for controlling the radiation time and its power.

 The means 7 for generating the emitted signal in frequency and shape contain a reference crystal oscillator 9 having first 10 and second 11 outputs, a synthesizer 12 of the phase samples of the emitted signal having first 13 and second 14 inputs and output and connected with its first input 13 to the first output 10 of the reference generator 9, with its second input 14 to the output of control means 3 via bus 4, and a synthesized waveform synthesizer 15 having first 16, second 17 and third 18 inputs and an output connected by its first input 16 to second output 11 of the reference generator 9 torus, its second input 17 to the output synthesizer 12 via bus 19 and its third input 18 with the output control means 3 via the bus 4.

 The means 8 for controlling the radiation time and its power comprises a timer 20, the input of which is connected to the output of the control means 3 via a bus 4, and an adjustable power amplifier 21 having first 22 and second 23 inputs and an output and connected by its first input 22 to the output 24 of the timer 20 , its second input 23 with the output of the form synthesizer 15 and the output with the emitter 2.

 The control means 3 comprises a unit 25 for storing information about the operating mode of the source 1, the input of which serves as the input of the means 3, is connected via a bus 6 to a computer 5, and the output 26 is connected to the input 27 directly of the control unit 28, the output 29 of which is connected to the input 30 of the block 25 The output of block 28, which serves as the output of means 3, is connected, as described above, with the inputs 14 and 18 of synthesizers 12 and 15, respectively, and the input of the timer 20 via bus 4.

 A device for implementing the method according to the invention comprises a pulsed power supply unit 31, electrically connected by its outputs to the above blocks and connected by one of its inputs to the output of the timer 20.

 In the described embodiment of the device according to the invention, it is possible to use well-known units that meet the set goals and objectives.

 So, for example, the source 1 of low-frequency electromagnetic waves and control means 3 can be performed on known microcircuits.

 As computer 5, a well-known computer 1BM can also be used.

 The emitter 2 may be a solenoid.

 As a switching power supply unit 31, a known switching power supply with input and output voltages indicated in the drawing can be used.

 The principle of operation of the device implementing the method is as follows.

To obtain a stable low-frequency electromagnetic field with a relative frequency error of the order of 10 ^-6, generator 1 must be stabilized in frequency. A reference crystal oscillator 9 with high frequency stability is best suited for these purposes.

 The device operates in three modes: A job frequency and waveform without radiation; B radiation signal; In direct assignment and signal emission.

 In mode A, a voltage of 12 V is supplied to block 31 from a constant voltage source (not shown in the drawing). Through the bus 6 from the computer 5 serves information about the frequency, shape, power of the signal and the duration of the radiation of the first and second signals. This information via bus 6 enters the information storage unit 25, where it is stored until new modes are reset. The information storage unit 25 is powered by an autonomous battery source (not shown in the drawing).

 Thus, the device is ready to work on radiation to create the required field.

 In the future, when working, the presence of computer 5 is not necessary. The need for its availability arises only when overriding the signal parameters or when operating in mode B.

 To use the device for the proposed purpose, when the start signal is applied, the control unit 28 is turned on, information on the signal parameters is read and transmitted to the synthesized signal form synthesizer 15, the emitted signal phase synthesizer 12, and a timer 20.

 In the synthesized waveform synthesizer 15, a predetermined waveform is stepwise filled using pulses from a reference crystal oscillator 9, for example, a sinusoidal waveform is given a shape, and the synthesizer 15 implements this shape in steps.

 The invention is further explained in the description of specific, but not limiting the invention, examples of its implementation by means of a patented device.

 Before considering various options for processing seed, briefly consider the general principles of the patented method of pre-sowing treatment using the device according to the invention. The experiments were carried out using source 1 of low-frequency electromagnetic waves, which provides the possibility of smoothly controlling the frequency in the range of 8-19 Hz and obtaining an output power of about 3 watts of radiation. The radiation was supplied to the processed material, which was stored in collars, crayons and metal containers up to 1000 tons, using the emitter 2, which is a solenoid with a diameter of 35 cm and an active resistance of 8 ohms.

 Example 1. On the form T. for a batch of seeds of spring wheat, a frequency of 15 Hz was set.

 These seeds were treated at 15 Hz for 5 minutes. After processing, the samples were sown on the third day to determine germination and seed growth in accordance with existing international standards and to analyze the activity of alpha-amylase enzymes in grains.

The analysis revealed the following: germination, length of coleoptile and root, the number of roots in the treated seeds was significantly greater than the control germination rate was 96.7% (in the control 89.3%), the number of roots 4.7 ± 0.53 (in control 3 , 26 ± 0.40), that is, 44% more. The activity of alpha-amylase enzymes in the treated seeds was 29.59 ± 0.60 relative units against 24.08 ± 0.62 relative units of control, that is, exceeded by 23%
Example 2. For a batch of seeds of winter wheat in the farm M. was set to a frequency of 17 Hz, and for a batch of seeds of peas 18 Hz.

 These lots of seeds were subjected to processing by the proposed method - winter wheat at a frequency of 17 Hz for 5 minutes, and pea seeds during the same time at a frequency of 18 Hz. Sowing of seeds was carried out in rolls of filter paper on the second day. On the fourth day after sowing, measurements were taken of the length of the root and sprout, the germination energy and seed germination were determined.

 It was found that the seeds of winter wheat treated with a device that implements the method according to the invention exceed, compared with the control, the average root length of seedlings by 1.7 cm (40%), the sprout length by 1.3 cm (more than twice); germination energy was 86% against 82% in the control, and germination rate of 97% against 95% in the control.

 The root length of the treated pea seeds was also greater than the control by 1.6 cm (by 40%), the sprout length by 0.4 cm (by 45%) with the same germination energy and germination rate of 96% versus 94% in the control.

 It was noted that an increase in the length of the sprout and root of seedlings of the treated seeds manifests itself in the initial period of germination. After 7 days with heterotrophic nutrition, the stimulating effect of the treatment ceases: there is an equalization of the length of the sprout and root of the seedlings.

 Example 3. At the Institute A. in laboratory and vegetative experiments, the effectiveness of the device for implementing the method according to the invention, for presowing treatment of cotton seeds, was investigated.

 The frequency was set to 19 Hz. Processing the batch of cotton seeds with the electromagnetic field of the device was carried out without breaking the packaging for 5 minutes at a frequency of 19 Hz. The control batch of seeds during processing was at a distance of at least 500 m.

 In laboratory studies, the cotton seeds on the fourth day after treatment for 18 h were kept in tap water at room temperature (as well as the reference and control variants), then 100 seeds were germinated in trays in each variant (four-fold repetition). On the third day after laying the seeds in the baths, the number of germinated seeds was counted.

With heterotrophic nutrition of seedlings after seed treatment, their more active development is observed. Germination energy was 96% compared with 86% in the control. In eight-day-old cotton seedlings, the root elongation increased on average by 15 mm compared to the control, the root mass by 14%, the mass of sprouts by 13%
The contrast is even more contrasted when determining the field germination rate, which on the fourth day amounted to 160% (control was taken as 100%) for the treated seeds, and on the sixth day 180%. The number of days from sowing to seedlings was 3 for the treated seeds; in the control, 8 days . The number of days from sowing to the appearance of the first true leaflets is 15 and 23 days, respectively. At the beginning of budding on plants, the number of buds in treated 3.1 was 1.6, in control 1.6.

 Thus, pre-sowing treatment with a device that implements the method according to the invention has a more favorable effect on the germination energy of cotton seeds, increases field germination and accelerates the initial stages of plant growth.

 Example 4. On farm K. production tests were carried out when growing crops: peas, corn for grain, barley, sunflower and carrots, for which the optimal processing frequencies were selected, namely: barley 15 Hz, peas, corn and sunflower 8 Hz and carrots 19 Hz. Processing was carried out for 10 minutes Phenological observations were not carried out. Separate harvesting results showed a yield increase in relation to the control crops: peas 6 kg / ha (19.3%), corn 8 kg / ha (21.4%), barley 7.5 kg / ha (19.1 %), sunflower 5.2 c / ha (23.0%) and carrots 25 c / ha (18.0%).

 Example 5. On the farm M. production tests were carried out during pre-sowing treatment of seeds of winter wheat with a device that implements the method according to the invention.

 Processing was carried out at a frequency of 17 Hz for 10 min. The control material at the time of processing was taken out by car to a distance of more than 1.5 km.

 Sowing of the control and processed seed was carried out on the day after treatment on an area of 10 ha and 500 ha, respectively.

 Analysis in autumn of the root system of seedlings of control and experimental plants showed their greater weight in plants obtained from treated seeds. When harvesting control crops, the yield was 49.1 kg / ha, and experimental 54.9 kg / ha, that is, the increase as a result of seed treatment was 5.8 kg / ha.

 Example 6. On the farm M. production tests were carried out by a device for implementing the method according to the invention, with pre-sowing treatment of cotton seeds. The experimental batch of seeds was exported to the field camp for 4 km, where it was processed by the patented device at a frequency of 19 Hz for 10 minutes. The control and experimental batch of seeds were sown in one day on the same field and occupied up to 50 hectares of the controlled area.

 The seedlings of the treated seeds appeared on the third day after sowing, in the control on the eighth to ninth day.

 Plants were evaluated in the control and experimental fields: by that time, in control plants, on average, there were 7-8 sympodial shoots, in experimental plants 12-14. Harvesting from the experimental field began two weeks earlier than the control and amounted to 38 kg / ha of raw cotton (33 kg / ha in the control). The fiber from the experimental field was longer, thinner and tighter, had a pure white color.

 Example 7. Pre-sowing treatment was subjected to about 1600 c, which was in bags of barley. Three hundred bags were placed in stacks and a frequency of 10 Hz was set. Processing was carried out at this frequency for 9 minutes. The next day, the control material was sown on an area of 30 hectares and processed on an area of 740 hectares in an ordinary way to a seed placement depth of 6-8 cm.

 When harvesting separately, it was found that the yield in the control was 19.6 c / ha, and the treated 21.5 c / ha.

 Thus, the increase in yield amounted to 1.9 kg / ha.

 Example 8. On the farm K. performed scientific and industrial testing of a device for implementing the method according to the invention.

 A pre-sowing treatment was subjected to a batch of seeds of spring wheat, packaged in 15 bags, for 10 min at a frequency of 15 Hz. The control material (20 bags) was transported to a distance of 5 km in the field for sowing. After seed treatment, the latter were also taken out to the field for sowing. Sowing was carried out on the same day: treated seeds on plots on an area of 3.8 ha, control 4.9 ha.

 During the growing season, observations were made on the parameters: density, morphological analysis of plants and crop structure. No significant differences in the phases of plant development were detected. However, the height of the plants from the treated seeds was 102.5 cm, the grain weight from one plant was 1.16 g and the weight of 1000 grains 41.4 g; in the control plots, respectively, plant height 97.8 cm, grain weight per plant 1.09 g, weight 1000 grains 39.5 g. Yield in areas sown with treated seeds, 25.1 c / ha, in the control 20.8 c / ha, that is, the yield increase was 4.3 c / ha.

 Example 9. At the farm K., production tests of the device for implementing the method according to the invention were carried out during pre-sowing treatment of soy and buckwheat seeds.

 Soybean seeds were packaged in two on-board vehicles, so the device was powered by a car battery. The emitter 2 was placed on the ground near the cars packed with seed. Processing time 15 min at a frequency of 8 Hz. The control was soybean sown at that time on an area of 100 hectares. The processed material was sown in the same field on the same day on an area of 600 hectares.

 The germination energy of the processed soybean seeds was 90% (88% in the control), and 95% germination (93% in the control).

 Sheaf material was selected and plants measured: the height of plants from the treated seeds was 34.85 cm, control 31.10 cm; the diameter of the stems in the middle part of the plant is 3-5 mm, the control is 3-4 mm.

 Processed buckwheat seeds for sowing on an area of 500 hectares, which were sprinkled with a hill. The emitter 2 was located near the processed material (2-3 m from the slide). Processing time 10 min, the optimal frequency is determined at 19 Hz. The control seeds were transported by car to a field located at a distance of 5 km. The control and experimental material was sown for 4-5 days on the prepared field, where the annual grasses for haylage, and then the chill, were the forerunner.

 Field control showed: the height of plants from the treated seeds was 68.98 cm, control 57.78 cm; the number of flower brushes on one plant is 7.67 pieces, in the control 6.16 pieces.

Laboratory analysis of seeds showed that the germination rate of the treated seeds was 97% of the control 94%, the growth rate was 93% and 68%, respectively, the length of 3 cm of seedlings from the treated seeds was 79.7% in the control 22.5% 2 cm, respectively 18.2% and 46, 2% 1 cm 2.0% and 29.2% less than 1 cm, respectively 0.1% and 2.1%
Undoubtedly, plants from treated seeds will provide the highest productivity. However, the final production result will depend on timely and quality cleaning.

 Example 10. On the farm R. field tests were carried out on the results of pre-treatment of peas, buckwheat and millet with a device for implementing the method according to the invention.

 A small batch of seeds (10 kg each) was processed for 5 min using the device: peas and millet at an optimal frequency of 8 Hz, buckwheat at a frequency of 19 Hz. The control material was located at a distance of not less than 600 m. The control and experimental material were sown simultaneously.

 As a result of the conducted studies, activation of growth processes in the initial period of development was found, exceeding the length of the roots and sprouts of seedlings reached 39.9%; the mass of 100 seedlings also exceeded the control by 6.6%. Field germination of treated seeds was 9-14% higher. up to 4.5 kg / ha (20.3%), buckwheat 3.6-4.7 kg / ha (24.4-31.9%) and millet 4.3 kg / ha (up to 10.9%) .

 The treatment of pea seeds allowed to reduce the susceptibility of plants in the budding-flowering phase to 26.7% in the phase of technical ripeness to 39.3%. The treatment contributed to an increase in protein in green mass to 1.62% and in seeds to 1.92%. To reduce the degree of infection seeds of millet with a smut smut the exposure to the electromagnetic field of these frequencies did not significantly affect.

 Example 11. On the farm O. were processed 100 bags of potatoes (40 bags amounted to the control batch), at a frequency of 16 Hz. Material processing was carried out for 15 minutes

 The treated and control lots were sown on a plot of 10 and 5 ha, respectively. The following yields were obtained: on the control field 281 kg / ha, on the experimental 449 kg / ha.

 Example 12. In the farm K. processed yellow carrot seeds at a frequency of 19 Hz for 5 min and sown on an area of 500 hectares simultaneously with untreated seeds (control field of 10 ha).

 The harvest amounted to 83 c / ha in the control, and 128.6 c / ha of cultivated ones. Root crops differed from the control ones not only in a larger size, but also in a more even, regular form.

 Example 13. On the farm R. were treated tomato seeds at a frequency of 17 Hz for 5 minutes

 As a result of the application of the proposed method of pre-sowing seed treatment, the tomato yield was 110.3 c / ha, and the control batch did not exceed 61.5 c / ha.

 Thus, when processing seed with low-frequency electromagnetic fields in the frequency range of 8-19 Hz, it is possible to increase productivity.

 Processing should be carried out no more than 10 days before sowing, since then the effectiveness of such processing is reduced. So, according to farm K., in production conditions, a significant difference with control plants in the number of flower brushes in buckwheat obtained from seeds sown in the first week after processing was 24% (an increase of 26.5% in grain yield), and sown in the second week (on days 9-10) only 5% (grain increase of about 10%).

 And, finally, it is advisable to select the optimal frequency value each time, since it can vary within certain limits depending on the type and type of seed. However, in any case, the frequency range of 8-19 Hz will ensure the achievement of positive results.

 Thus, the proposed device that implements the method according to the invention is intended for synthesizing low-frequency signals of various shapes (mainly square-shaped square wave, saw, sinusoid and their combination) for radiation into the environment when working on an inductive (solenoid or other magnetic field-emitting means ) or capacitive load. This device works in conjunction with software and 1VM computer or compatible with it.

 The invention can be used to process seed when growing grain, nightshade, oilseeds, legumes, melons and root crops. In the production of an option for scientific research, the software allows you to reproduce signals of any geometric shape in the frequency range from 1 to 50 Hz with a duty cycle from 0.001 to 10000, providing a non-linear distortion coefficient of the electrical signal at the output connector with an active load of 8 ohms ranging from 0.01 to 0.001% for a 10-4 signal discrete. Perhaps the industrial production of a device for presowing treatment of seeds according to groups of related enzymes: crops, legumes, tubers, seeds of vegetable crops.

Claims (13)

 1. The method of pre-sowing treatment of seed, which consists in the fact that they act on the seed with a low-frequency electromagnetic field, characterized in that they use a low-frequency electromagnetic field having a frequency corresponding to the resonant frequency of the intraglobular transformations in the seed during conformational vibrations.  2. The method according to p. 1, characterized in that they use a low-frequency electromagnetic field having an energy lower than the energy of breaking of hydrogen bonds in the seed.  3. The method according to p. 1 or 2, characterized in that they use an electromagnetic field with a frequency in the range from 8 to 19 Hz.  4. The method according to claim 1 or 2, characterized in that the processing of seed is carried out no later than 10 days before sowing.  5. The method according to claim 3, characterized in that the processing of seed is carried out no later than 10 days before sowing.  6. A device for pre-sowing processing of seed material containing a source of low-frequency electromagnetic waves and an emitter electrically connected to the source, the electromagnetic radiation of which is directed to the seed, characterized in that the source of low-frequency electromagnetic waves is made adjustable in frequency in the range from 8 to 19 Hz and the shape of the emitted signal corresponding to the intraglobular transformations in this processed seed.  7. The device according to p. 6, characterized in that the source of low-frequency electromagnetic waves is additionally adjustable in terms of radiation power.  8. The device according to claim 6, characterized in that it provides means for controlling the operation of an adjustable source of low-frequency electromagnetic waves, the output of which is electrically connected to an adjustable source.  9. The device according to p. 8, characterized in that the source of low-frequency electromagnetic waves contains means for generating a radiated signal in frequency and its shape, electrically connected with the output of the control means and the emitter.  10. The device according to claim 9, characterized in that the source of low-frequency electromagnetic waves further comprises means for controlling the radiation time and its power, electrically connected to the output of the control means and connected to the emitter.  11. The device according to claim 3, characterized in that it provides a computer, the output of which is connected to the input of the control means.  12. The device according to claim 9 or 11, characterized in that the means for generating the emitted signal in frequency and its form contains a reference generator having first and second outputs, a synthesizer of the phase samples of the emitted signal, having first and second inputs and output and connected with its first an input to the first output of the reference generator and its second input to the output of the control means, and a synthesized waveform synthesizer having first, second and third inputs and an output connected by its first input to the second output of the reference generator, its second input with the output of the synthesizer reports the phase of the emitted signal and its third input with the output of the control means and is electrically connected by its output to the emitter.  13. The device according to claim 10 or 11, characterized in that the means for controlling the radiation time and its power comprises a timer, the input of which is connected to the output of the control means, and an adjustable power amplifier having first and second inputs and an output and connected to its first input with the timer output, its second input with the output of the synthesizer form means the formation of the emitted signal and the output with the emitter.