CS252012B1 - Method of seeds' presowing treatment and equipment for realization of this method - Google Patents

Description

The present invention relates to a pre-seed treatment of seeds and to an apparatus for carrying out such treatment.

The seed treatment of the present invention solves the problem of improving seed quality and producing crops and other crop and ornamental plant species by an intensifying biophysical method based on the stimulatory interaction of the electromagnetic field with the biological material.

In the field of physical stimulation of plant seeds, methods using combined action are already known and used:

- ultraviolet radiation (further UV radiation) with infrared radiation (hereinafter IR radiation) and magnetic radiation, - laser radiation with red light, - gamma or X-ray radiation (hereinafter X-ray radiation) with laser radiation, red light and corona discharge.

The disadvantages of the first combined method are insufficient and also inappropriate photoregulatory effects, the second insufficient photochemical, bactericidal and fungicidal effects, the third mutagenic effects, the high weight and cost of the devices, as well as the increased risk to the operating personnel in the use of hard radiation.

Known devices employing the second method of seed treatment only expose a portion of the seed due to the thick layers of irradiated seeds, the irradiated seeds being exposed only on one side, causing only a small portion of the seeds to be affected by the embryos by direct laser radiation. Therefore, multiple treatment cycles are required when using them. This increases the technological demands, costs and degree of mechanical damage to the seeds.

The above-mentioned drawbacks are overcome by the solution according to the invention. The principle of the present invention is that a continuous seed layer of one grain thickness is cyclically staggered one to five times for a period of 0.5 to 10 with combined electromagnetic radiation in spaced apart zones while being electrostatically treated at a rate of 100 up to 1000 kV / m. In the first phase of the cycle, the seed layer shall be irradiated with ultraviolet radiation at an intensity of 10 to 1000 W / m ² and infrared radiation at an intensity of 10 to 3 000 W / m ² and in a second phase of the cycle the seed layer shall be irradiated with red light of 600 to 680 nm and an intensity of 1 to 400 W / m ² and finally irradiated with a laser beam with a wavelength of 600 to 680 nm and an intensity of 1 to 100 kW / m ² , the last cycle of irradiation of the seed layer being 5 to 28 days before sowing. Irradiation of the seed layer with a laser beam of frequency! 50 to 500 Hz is multiplied by first irradiating the scanned laser beam, the scanning range of which is at the level of the conveyor plane exceeding its width, and then irradiated by the reflective reflection of the laser beam from the lateral, respectively. the bottom reflective surface for 10 ~ ³ to 10 ^-2 s. The electrostatic field is generated by moving the seed layer over the dielectric surface of the conveyor, preferably of polyvinyl chloride.

The principle of the device according to the invention is that the common axis of the laser, the divergent optics and the fixed or movable mirror, which are located above the dielectric surface of the conveyor, are at an acute angle with the longitudinal axis of the conveyor. the obtuse angle through the conveyor axis. The inclination of the conveyor is controllable in the range of 10 to 40 ° and the conveyor surface is of dielectric material, preferably in the zone of the laser beam's propagation zone it is formed as a reflective layer.

The main advantage of the seed treatment according to the invention is to achieve a higher synergistic effect, which results as a result of a suitable combination of the interaction of biologically active spectra of incoherent and coherent electromagnetic radiation and electrostatic field on the seeds of plants and their microflora.

In the first phase of the treatment cycle, the photochemical, bactericidal and fungicidal effects of UV and IR radiation on seeds and their microflora are exploited while simultaneously affecting the electrostatic field, which positively affects the functional state of biological membranes and at the same time generates an electric charge on the surface of seeds. generated by UV radiation in atmospheric! environment to seed material. This positively affects the level of oxidation processes in mitochondria and accelerates their development. The surface protection of the seed structure undergoes partial denaturation and provides greater permeability to water and oxygen, and allows early onset of active germination processes. The bactericidal and fungicidal effects of the treatment also increase.

In the second phase of the treatment cycle, the photoregulatory effect of shortwave red light and laser radiation on the phytochrome system is used, the effect of which is increased by generating a positive electric charge of the seeds (electrostatic field due to triboelectric effect). laser radiation and electrostatic pole are more likely to develop radicals and excited states of biostructures, and the second treatment stage also ensures photoconversion of protochlorophyll seeds containing it.

It has been experimentally confirmed that the treatment of the seeds of the invention increases the resorption of acid and water over the control samples, with an increased concentration of unstable free radicals and the presence of manganese ion radicals in dry seeds (approximately 10-14% relative humidity). and the fungicidal effect of the treatment on the pathogenic seed microflora in which the second phase of the treatment cycle of the invention is also involved.

The advantage of the device according to the invention is the multiple irradiation of the seeds with a laser beam, which is achieved by the conveyor side mirror system and the reflective surface of the conveyor bulk surface. These allow the seed to be exposed 2 to 3 times at normal positions to the incident beam of laser radiation, while irradiating the side of the seed facing the conveyor with a laser beam reflected from its reflective surface, which in turn increases the probability of irradiating the seed embryo. This increases the efficiency of the treatment and makes it possible to reduce the number of cycles thereof and the degree of mechanical damage to the seeds compared to the prior art laser seed treatment devices. The advantage of the device is also the simplicity of the solution, the possibility of using the modular structure and the relatively low costs for its implementation.

The seed repair according to the invention increases! their qualitative parameters such as metabolism levels, germination, germination energy, growth strength and the pathogenic microflora content are reduced. As a result, plants develop better, are more resistant to negative environmental impacts, and yield higher yields (5 to 30%). Significant results can be achieved especially in seeds and seeds of lower quality, which is more pronounced in worse agrotechnical and climatic conditions. Repairs can partially replace seed dressings (reduce heavy metal dressings) and thus prevent them from being negatively affected. ecological impact, which is currently particularly the case in areas with groundwater sources of drinking water. The seed repair according to the invention is suitable for cereals, grains, vegetable seeds, sugar beet, flower and wood seeds, e.g. pine.

In the accompanying drawings, FIG. 1 is a side view of FIG. 2 shows a plan view and FIG. 3 shows a cross-section of a device according to the invention with a divergent optic and a fixed mirror, FIG. 4 is a side view and FIG. 5 is a bottom view of an exemplary embodiment of a moving mirror apparatus for scanning a laser beam.

Example 1

A method of pre-sowing a wheat seed according to the invention, wherein the seeds are irradiated while moving on the downcomer simultaneously by ultraviolet and visible mercury lamp light and by infrared radiation of ceramic infrared heaters with individual intensities of 200 W / m ^and 60 000 lx and 2 000 W / m ² seconds. After 24 hours, it is irradiated separately with monochromatic polarized light of neon lamps with a wavelength of 640 nm and an intensity of 10 W / m ² for 1 second using polarizing filters. Then, the seeds are individually irradiated with a He-Ne laser scan beam having a wavelength of 632.8 nm and an intensity of 10 kW / ra ³ at a scanning frequency of 300 Hz.

During the irradiation to the seed, the electrostatic field generated by friction against the dielectric surface of the PVC conveyor will be provided.

Example 2

A method of superhanging seed treatment according to the invention, wherein irradiate corn seed on a downstream conveyor simultaneously with ultraviolet radiation, visible light of metal halide lamps and infrared radiation with individual intensities of 250 W / m ² , 100 000 lx and 500 W / m ³ for 5 s. They are then irradiated by the light of 610 and 670 nm lithium halide lamps at 300 W / m ² for 2 seconds using absorption filters while moving on the downcomer. Finally, it is independently irradiated with a He-Ne laser scan beam of 632.8 nm and an intensity of 20 kW / m ² at a scanning frequency of 500 Hz. During the irradiation to the seed, the electrostatic field generated by friction on the dielectric surface of the conveyor, in our case of PVC, is protected.

In a first embodiment with a divergent optic and a fixed mirror, the inlet portion for the irradiated seed hopper 14 is provided at the bottom with a turnstile 13. The turnstile 13 is followed by a gravity conveyor 12, the inclination of which is changeable by screw 16 and electrostatic and reflective properties of the laser.

Above the conveyor 12 are mounted on the supporting structure 11 electromagnetic radiation sources in the order of infrared radiation source 6, ultraviolet and visible light source 5 and red light source 4, followed by laser radiation source 1. The laser beam is treated with divergent optics 2 and The mirror surface 9 is located on both sides of the conveyor 12 in the laser beam zone (area), correcting mirrors 9 which form an obtuse angle a with the conveyor plane. The sources of electromagnetic radiation and the zones of their action on the conveyor are separated by opaque baffles 10. Between the source 4 and the conveyor 12 is placed a filter 7, which transmits bright red light and possibly ensures its polarization, between the source 5 and the conveyor 12 is placed a filter 8 ultraviolet radiation, blue and lived light. For the separate application of the pr252012 and the second phase of the treatment cycle, it is advantageous to use interchangeable conveyors 12 and the supporting structure of the sources 11, i. j. one conveyor with a supporting structure with sources 5, 6 and the other with a source 4 and a laser irradiation area 1.

In a second embodiment of the device, the fixed mirror 3 is replaced by a movable vibrating plane mirror or a rotating polygon with reflective peripheral surfaces, the common axis of the laser 1 and the optics 2 being an acute angle β with the longitudinal axis of the conveyor 12.

In the operation of the device according to the first example, the seeds from the hopper 14 dispensed by the turnstile 13 on the conveyor 12, where they are simultaneously exposed to the radiation of sources 5, B and separate (separately) source 4 and radiation of laser 1. and in part to the side mirrors 9, which reflect the beam on the conveyor and linearize the irradiation characteristic over its entire width.

In a second embodiment of the apparatus, the laser beam 1 is scanned at an angle β across the surface of the conveyor 12, the portion extending beyond the bulkhead of the conveyor being reflected by the side mirrors 9 onto the conveyor 12. This achieves a laser beam trace extension and multiple folding.

In both embodiments of the apparatus, the treated seeds are removed from the end of the conveyor 12 into the container. The size of the exposure doses can be controlled by the rate of movement of the seeds on the conveyor 12 by varying its inclination angle and the intensity of radiation of the sources, the number of which depends on the power of the device and the type of sources used.

SUBJECT

Claims (6)

252012 in] and the second stage of the treatment cycle, the use of interchangeable annular conveyors 12 is preferred. a carrier with support structure 5, 6 and a second source 4 and laser irradiation areas 1. In the second embodiment, the fixed mirror 3 is replaced by a movable-vibrating planar mirror or rotating polygon with reflective circumference. the common axis of the lasse 1 and the optics 2, with the long axis of the axle 12, the sharp angle β. In the operation of the device according to the first example, the seeds from the hopper 14 dispensed by the turnstile 13 proceed along the conveyor 12, where they are simultaneously exposed to the radiation of the sources 5, 6 and the separate source 4 and the radiation of the laser. Directly with a fixed mirror, it strikes the surface of the conveyor and partially with side mirrors 9, which reflect the beam on the conveyor, and linearize the radiation characteristic at its entire width. In a second embodiment of the device, the laser beam 1 is scanned at an angle β over the conveyor surface 12, with the portion extending over the bulkhead of the conveyor being reflected by the side mirrors 9 to the conveyor 12. This results in a laser beam trace and multiple effects. . The treated seeds are taken from the end of the conveyor 12 to the container in both embodiments of the device. The size of the exposure doses can be controlled by the rate of movement of the seeds on the conveyor 12 by varying its angle of inclination and the radiation intensity of the sources, the number of which depends on the power of the device and the type of sources used. OBJECT 1. A method for pre-sowing seeds for biological stimulation by electro-magnetic irradiation, characterized in that the continuous layer of seeds is crimped one to five times during its movement, cyclically operated for 0.5 to 10 times with combined electromagnetic radiation in separate zones and simultaneously the electrostatic polomo is applied at 100 to 1000 kV / m. 2. A seed pre-treatment method according to claim 1, characterized in that in the first phase of the cycle, the seed layer is irradiated with 10 to 1 000 W // m2 ultraviolet radiation and 10 to 3,000 W / m2 infrared radiation. the second phase of the seed-coating cycle is first irradiated with a red light with a wavelength of 600 to 680 nm and an intensity of 1 to 400 W / m 2 and finally with a laser beam irradiation of 600 to 680 nm and an intensity of 1 to 100 kW / m 2, the last cycle of seed irradiation is pre-sowing at 5 to 28 days. The method of pre-treatment of seeds according to items 1 and 2, characterized in that the radiation of the seed layer by a laser beam of 50 to 500 Hz is multiple such that it is first irradiated by a scanned laser beam whose scanning range is at the level of the conveyor extending beyond its width and then being irradiated bad reflection of this laser beam from the side or bottom reflective surface for 10 to 10 2 seconds. The method of pre-treatment of seeds according to items 1 to 3, characterized in that the electrostatic field is formed by the movement of the seed layer over the dielectric surface of the carrier, preferably polyvinyl chloride. 5. A device according to claim 1, comprising a carrier structure, an electromagnetic radiation source housing, optical filters and optical baffles, characterized in that the common laser axis (1), the divergent optics (2), ) and a fixed or movable mirror (3) are disposed above the dielectric surface of the fall conveyor (12), with an oblique angle (/ 3) forming a sloping axis of the downcomer (12), while fixed mirrors (9) co-located at the edges of the downcomer the conveyor (12) with this oscillating angle (a). 6. Apparatus according to claim 5, characterized in that the slope of the slope conveyor is controllable in the range of 10 to 40 degrees and the surface of the slope conveyor is made of dielectric material, wherein a reflective layer is preferably formed in the laser beam shifting zone. 3 sheets of drawings