RU2014119588A - METHOD FOR PLANT GROWING AND DESIGN FOR ITS IMPLEMENTATION - Google Patents

Abstract

1. A method of growing plants (43) in a building (1) having a greenhouse (2), comprising the following steps: sowing seeds in a nutrient medium in sterilized pots (17) using a sowing apparatus (7), where the sowing apparatus (7) is also provides watering, adding nutrients and / or fertilizers to the nutrient medium, germinating seeds in pots (17) in a germination device (8), controlling germination of seeds in pots (17), arranging only pots (17) with sprouted seeds on trays ( 9) with the axis of the length (16) using a device for moving pots (25) , moving the trays (9) to a section (14) of one of several parallel tapes 3, 3 ′ using a lift (4), where the trays (9) move from the bottom of the building to the beginning of the tape section (14) at the top of the building (1), automatic movement pots in the greenhouse (2) for the growth of sprouted seeds in seedlings (43), where the greenhouse consists of at least two parallel strips 3, 3 ′ for moving the trays (9) from the beginning, at the top of the building (1), down, moving trays (9) supported by the first beam (51) and the second beam (52), through the greenhouse (2) using a conveyor belt characterized by with an import device (53) with a tray moving device (55), which moves along the first beam (51) and moves the tray (9) one step along the tape section (14) after passing the tray (9), the transport device (53) moves the trays (9) gradually along the section of the tape (14) while passing along the tape (14), the trays slide off from one section of the tape (14) to another section of the tape (14) down by means of the tape connection (18) installed diagonally inclined channels with an axis of length (19), where the specified means of connecting tapes (18)

Claims (19)

1. A method of growing plants (43) in a building (1) having a greenhouse (2), comprising the following steps: sowing seeds in a nutrient medium in sterilized pots (17) using a sowing apparatus (7), where the sowing apparatus (7) also provides watering, the addition of nutrients and / or fertilizers to the nutrient medium, germination of seeds in pots (17) in a germination device (8), control of seed germination in pots (17), arrangement of only pots (17) with sprouted seeds on trays (9) with a length axis (16) using a device for moving pots (25), moving the trays (9) to a section (14) of one of several parallel tapes 3, 3 ′ using a hoist (4), where the trays (9) move from the bottom of the building to the beginning of the tape section (14) at the top of the building (1), automatic movement of pots through the greenhouse (2) for the growth of sprouted seeds in seedlings (43), where the greenhouse consists of at least two parallel tapes 3, 3 ′ for moving the trays (9) from the beginning, at the top of the building (1), down , moving the trays (9) supported by the first beam (51) and the second beam (52) through the greenhouse (2) using a conveyor belt characterized by a transport device (53) with a tray moving device (55) that moves along the first beam (51 ) and moves the tray (9) one step along the portion of the belt (14) after passing the tray (9), the transport device (53) at the same time moves the trays (9) gradually along the portion of the tape (14) while passing through the tape (14) , the trays slide from one section of the tape (14) to another section of the tape (14) down by means of a connection of tapes (18) installed as diagonally inclined channels with an axis of length (19), where these means of connection of tapes (18) connect the end of the upper section of the tape (14) with the initial part of the section of the tape (14) located below, harvesting the grown crop (43) using a harvesting machine (5), and sterilization of pots with a nutrient medium in a sterilizing device (6) after harvesting to obtain sterilized pots (17) with a nutrient medium. 2. The method according to claim 1, in which the seeds are sown on Wednesday in pots (17), which have at least two opposite walls with a slight slope, so that the cross-sectional area of the pots (17) decreases towards the bottom of the pots (17) pots (17) are placed in trays (9) having a tapering width towards the bottom, which will correspond to the width of the pots (17), trays (9) are elongated along the length axis (16) and are designed to place the pots (17) in one row on tray (9) along the axis of length (16), these trays (9) are located on the tape (14) so that their axis of length (16) are perpendicular to the beams (51, 52) of the tape (14). 3. The method according to any one of the preceding paragraphs, comprising the step of intermediate watering the plants (43) by periodically supplying water to the trays (9), where the pots (17) and trays (9) are installed so that the nutrient medium in the pots (17) absorbed water from the trays (9), as well as the step of preventing water accumulation at the bottom of the trays (9), the bottom of which is made with a slope of 0.5-2 ° horizontally, while the remaining water flows from the tray through the hole made in the bottom the edge of the tray. 4. The method of claim 3, comprising the steps of continuously cleaning and recycling excess water that flows from openings in trays where excess water passes through (i) a mechanical filter to separate parts of the plants and nutrient medium from the water, (ii) a biological filter comprising zeolite and pumice for purifying water from pathogens of infections and metabolites, (iii) a second mechanical filter for separating particles of zeolite and nutrient medium from water purified by a biological filter, and / or (iv) a UV filter in which excess water passing through some to filter, collected and then mixed with a nutrient fertilizer and / or fresh water, and then pumped back into the building (1) for irrigation of plants and ensuring nutrient and fertilizer. 5. The method according to any one of paragraphs. 1 or 2, in which the step of verifying that the seeds in the pots (17) have sprouted involves the use of automated controls (24) using a digital camera (23) connected to a computer. 6. The method according to any one of paragraphs. 1 or 2, including the step of collecting the grown crop (43) using a harvesting machine (5) with a harvesting apparatus (46), where three parallel conveyor belts (47) move the trays (9) with plants (43) into the harvesting apparatus (46 ), in which empty trays are removed from the harvester on the second conveyor belt (48), and the harvested crop is transported on the third conveyor belt (49), while the camera (50) connected to the computer serves to check the harvested crop and determine its size and colors. 7. The method according to any one of paragraphs. 1 or 2, in which the organic waste after verification of the crop, including a crop that does not meet the established requirements, are transported to a biogas plant (28), and biological nutrients from biogas production are transported to a metering unit (7). 8. The method according to any one of paragraphs. 1 or 2, including the step of sterilizing the pots with nutrient medium (17) using a sterilizing device (6), in which the trays and pots are exposed to steam, and the trays (9) then pass through a cooling device (30), where the trays (9) ), the pots (17) and the nutrient medium are cooled and transported to a separation device (40), in which the pots (17) are removed from the trays (9) and transferred to the metering unit (7). 9. The method according to any one of paragraphs. 1 or 2, in which sterilization is carried out using microwave radiation to heat the residual water in the pots, and, therefore, heating the nutrient medium and pots. 10. Design (1) for growing plants (43) in the form of a building (1) with a greenhouse (2), characterized in that it is equipped a sowing apparatus (7) for sowing seeds in a nutrient medium in pots (17), where a sowing apparatus (7) is also provided for supplying water, a nutrient and / or fertilizer to the nutrient medium, germination device (8) for seed germination in pots (17), controls (24) for determining seed germination, a device for moving pots (25), placing pots (17) in trays (9) along the length axis (16), a lift (4) to move the trays (9) to sections (14) of parallel tapes 3 and 3 ′, where the lift (4) moves the trays (9) from the bottom of the building to the initial position of the tape section (14) at the top of the building (1), a greenhouse (2) so that the sprouted seeds grow to seedlings (43), where the greenhouse includes two parallel tapes 3 and 3 ′ to move the trays (9) from the initial position to the final, means of transporting the trays (9) through the greenhouse (2), where the means for moving the trays (9) includes a section of tape (14) consisting of the first beam (51) and the second beam (52), the tray (9) is supported by beams, a transport device ( 53), passing along the first beam (51), includes a tray moving device (55), which, after passing through the tray (9), moves the tray (9) one step forward along the section of the belt (14), thus, the transport device ( 53) gradually moves the trays (9) along the portion of the tape (14) during the course along the portion of the tape (14), means for connecting tapes (18) installed as inclined channels with an axis of length (19), where the channels are designed to transport trays (9) along their length axes (16) parallel to the direction of transportation, where these means for connecting tapes (18) are installed for sliding the trays from one section of the tape (14) to another section of the tape (14) below, and where the indicated means for connecting the tapes (18) connect the end part of the upper section of the tape (14) with the initial part of the section of the tape (14) located below, a harvesting machine (5) for collecting the grown crop (43), and, a sterilizing device (6) for sterilizing pots (17) with a nutrient medium after collection to provide sterilized pots (17) with a nutrient medium. 11. The construction according to claim 10, where the pots (17) have at least two opposite walls that are slightly inclined so that the cross-sectional area of the pots (17) decreases to the bottom of the pots (17); the trays (9) have a decreasing width to the bottom, which corresponds to the width of the pots (17); trays (9) are elongated to accommodate one row of pots (17) along the length axis (16); the tape section (14) is designed to accommodate the trays (9) on the tape section (14) along their length axes (16) perpendicular to the beams (51, 52) of the tape section (14). 12. Design (1) according to any one of paragraphs. 10 or 11, in which the irrigation means are installed to periodically provide the trays (9) with water from the highest side, the tape section (14) has an angle of 0.5-2 ° relative horizontal, which prevents water retention at the bottom of the trays (9), and residual water flows from the tray through the hole provided at the bottom of the tray. 13. The construction according to claim 12, in which the irrigation means include pipes (10) located at a distance corresponding to the length of the steps of the gradual movement of the trays (9). 14. The structure of claim 12, comprising means for continuously cleaning and recycling the excess water that flows from openings in the trays where the excess water passes through mechanical filters, biological filters and / or UV filters, the excess water passing through the filters is collected and then mixed with a nutrient, fertilizer and / or fresh water, and then pumped back into building (1) to water and supply plants with a nutrient and fertilizer. 15. Design according to any one of paragraphs. 10 or 11, where the controls (24) to verify that the seeds in the pots (17) have sprouted include an automated system using a digital camera (23) connected to a computer. 16. Design according to any one of paragraphs. 10 or 11, in which the harvesting machine (5) includes a harvesting apparatus (46) for collecting the grown crop (43), where three parallel conveyor belts (47) move the trays (9) with plants (43) into the harvesting apparatus (46), empty trays are removed from the harvester on the second conveyor belt (48), the harvested crop is transported on the third conveyor belt (49), and a camera (50) is provided for checking the harvested crop to determine its size and color. 17. Design according to any one of paragraphs. 10 or 11, where the organic waste after checking the crop, including the crop that does not meet the established requirements, is transported to the biogas plant (28), built-in or connected to the mechanism (1), and the biological nutrients from the biogas production are transported to sowing apparatus (7) for sowing seeds. 18. Design according to any one of paragraphs. 10 or 11, comprising a sterilizing device (6), in which the trays and pots are exposed to steam and a cooling device (30), in which the sterilized trays (9), pots (17) and the nutrient medium are cooled, as well as a separation device (40) by means of which the pots (17) are removed from the trays (9) and transferred to the metering unit (7). 19. Design according to any one of paragraphs. 10 or 11, where the sterilizing device includes a microwave source to use microwave radiation to heat the residual water in the pots, and thus heat the medium and pots.