RU224428U1 - Device for growing mini potato tubers - Google Patents

Abstract

The utility model relates to plant growing systems using hydroponic, aerohydroponic and other production methods and can be used in elite seed production of potatoes and other tuber-forming crops. The device for growing mini-tubers of potatoes consists of a support frame 1 having an upper 4 and lower 5 frames, a growth table 6 with holes is placed on the upper 4 frame, a tray 12 for a growth container 10 is placed on the lower 5 frame, the internal cavity of the latter is connected to nutrient solution supply system 9. The tray 12 is equipped with a drain neck 13 for the spent nutrient solution. The growth container 10 is made disposable and is a bag made of light-opaque flexible material, the bottom of the bag is made moisture-permeable with the possibility of the spent nutrient solution flowing into the tray 12, on the side of the bag there is a window 11 with a folding light-opaque screen, and the upper edges of the bag are in contact with the base of the growth table 6 along its perimeter and removably fixed to the top 4 frame. The technical result is to increase the efficiency of primary seed production by eliminating the risk of spread and transmission of viral and bacterial infections through the growth container with the aerohydroponic method of growing potato mini-tubers while reducing labor costs for sanitizing the device for substrate-free cultivation of mini-tubers at the end of the plant's growing season. 9 salary f-ly, 5 ill.

Description

The utility model relates to hydroponic, aerohydroponic and other production methods of growing plants and can be used in elite potato seed production, including for year-round cultivation and propagation in controlled conditions of virus-free planting material during laboratory cultivation of seed material of potato mini-tubers, Jerusalem artichoke, stachys and other tuber-forming crops.

To accommodate the root part of vegetative plants when growing plants using the aerohydroponic method, containers made of materials based on plastic, composite and other materials that are resistant to contact with the nutrient solution, its media and capable of bearing loads are traditionally used to accommodate the developed root system of plants of various biological species, including potatoes.

Methods and installations for aerohydroponic growing of plants have long been known in science and technology.

One of the necessary elements of the aerohydroponic process of growing plants is the cleaning of the growth container from biological residues of the root system, deposits of salts of the nutrient solution, as well as the biological background formed during the growing season of the plant in the form of bacterial, fungal or mixed plaque, which negatively affect generations of plants grown in subsequent revolutions at the same settings. Proper cleaning of growing containers at the end of the growing season is a critical element in seed production.

For example, an installation for growing plants is known, containing a frame on which plants, lamps and a nutrient solution supply system are mounted (RU N 1806359, A01G 31/02, 1993).

A known cultivation unit (phytotron) is designed for growing plants in an artificial climate for collecting root and tuber crops. The installation is a housing that limits the cultivation room, a device for managing and monitoring the growth of the plant and is equipped with a light-heat-tight partition that divides the cultivation room into two zones isolated from each other and accessible for observation for the root and stem parts of the plant. The light-heat-proof partition is made with holes for placing plants in them. The roots of the plant, hanging from the ceiling of the root zone, are located in a vessel made in the form of a translucent trench, which allows you to visually observe the development of the root system and fruiting. The gutter is connected to the nutrient solution supply system and attached to the ceiling of the root zone on removable hinges (RU 2038747, A01G 9/24, 1995).

The known installation can be used for growing potato mini-tubers, because dividing the cultivation unit into two volumes makes it possible to create different temperature and humidity cultivation conditions in the stem and root zones of plants to intensify the outflow of assimilates into tubers and increase productivity. However, constant light exposure to potato roots located in a translucent trench cannot ensure its high productivity. In addition, the design of the root zone does not provide the possibility of collecting potato tubers, and at the end of the growing season, the known installation requires labor-intensive sanitary treatment, including gutters, which does not guarantee the absence of a biological background for the next generation of grown mini-potato tubers.

A similar technique for dividing a cultivation installation into two volumes is widely known, for example RU 2157064 (2000), RU 2715604 (2020), CN104429853 (2015), KR20060129986 (2006), CN108207601 (2018), UZ 0000004602 (2012).

Also widely known is the industrial universal aeroponic installation "Harvest", consisting of a support frame, 5 separate planting trays for growing plants, a plant lighting unit, a nutrient solution supply system, including containers for the nutrient solution, a pump, polypropylene pipelines connecting the pump with high-pressure nozzles installed in the side walls of the planting trays opposite each plant [Electronic resource] Access mode - http://www.aeroponica.su/odnoyapucnie/odnoyapucnie.

An aerohydroponic installation for growing plants is known, which contains a frame of a collapsible structure with upper and lower frames, an aerohydroponic box located in the middle part of the frame, independent aerosol, aeroponic and hydroponic nutrition systems located inside the aerohydroponic box, a transplanting panel located in the upper part of the aerohydroponic box and consisting of a series-connected plastic grid, black opaque film and foil foam, a net for fixing plants located above the transplanting panel, a lighting installation attached to the upper frame frame, a filtration and ultraviolet purification system and a water pump attached to the lower frame of the frame, rollers attached to the frame to provide mobility, an aerosol nutrient system includes air tubes and water tubes arranged perpendicularly to provide mixing of air flow and liquid flow, respectively, and separators configured to provide foliar treatment of plants during the process. growing season, while the hydroponic nutrition system is a passive form of nutrition and includes a hydraulic reservoir with a nutrient solution, built into the aerohydroponic box and located with the ability to ensure constant contact of the lower part of the plant roots with the nutrient solution, and a lift platform mounted inside the aerohydroponic box, made with the ability to move in a vertical plane and having holes and recesses in the form of cells for holding the nutrient solution. (RU 2693721, A01G 31/02, 2019).

The known installation is difficult to manufacture and maintain, and also does not guarantee the absence of a biological background for the next generation of grown mini-potato tubers after sanitary treatment of the aerohydroponic box.

The closest is an installation for growing mini-tubers of potatoes, consisting of a lightweight support frame, planting trays for plant cultivation with front plastic doors, a plant lighting unit, a nutrient solution supply system, which consists of a container for the nutrient solution, an ultrasonic fog generator, polypropylene pipelines connecting the nutrient solution container to the ultrasonic fog generator, and the latter to the planting trays. The frame contains two closed planting trays for cultivating plants no more than 30 cm high and two LED lighting units. (RU 188109 A01G 31/02, 2019)

The known installation has light-opaque plastic trays that serve as reusable growth containers with front plastic doors that provide access to the root system for monitoring and collecting potato tubers. At the end of the growing season, sanitary treatment of trays and doors is required, and due to the high penetrating ability of the potato root system, removing biological residues from such containers is quite labor-intensive work, the poor performance of which is a direct risk of transmitting viral and bacterial infections from one growth cycle to another , which is unacceptable in the processes of primary seed production. At the same time, sanitary treatment of plastic trays with doors and their subsequent repeated use does not guarantee the absence of a biological background for the next generations of grown potato mini-tubers.

The technical objective of the proposed device for growing potato mini-tubers is to increase the efficiency of primary seed production during year-round cultivation and propagation of virus-free potato planting material by eliminating the risk of transmission of viral and bacterial infections through the growth container from one growth cycle to another.

The technical result is increasing the efficiency of primary seed production by eliminating the risk of spread and transmission of viral and bacterial infections through the growing container with the aerohydroponic method of growing potato mini-tubers while reducing labor costs for sanitizing the device for substrate-free cultivation of mini-tubers at the end of the plant's growing season.

The problem is solved by the fact that a device is claimed for growing mini-tubers of potatoes, consisting of a support frame having an upper and lower frame, a growth table with holes is placed on the upper frame, a tray for a growth container is placed on the lower frame, the internal cavity of which is connected to system for supplying a nutrient solution, the tray is equipped with a drain neck for the spent nutrient solution, characterized in that the growth container is a bag made of a light-opaque flexible material, the bottom of the bag is made moisture-permeable with the possibility of the spent nutrient solution flowing into the pan, on the side of the bag there is a window with a folding, light-opaque screen, and the upper edges of the bag are in contact with the base of the growth table along its perimeter and are removably fixed to the upper frame.

The inventive device, in contrast to previously known cultivation installations (phytotrons) for growing potato tubers, contains a disposable growth container in the form of a bag, which provides light-opaque conditions for growing mini-potato tubers and drainage of the waste nutrient solution through the bottom into a drain neck placed on a pallet, window with a folding opaque screen on the side of the growth container. The growth capacity differs from previously known ones and ensures phytosanitary safety throughout the entire growth cycle, as well as periodic monitoring of tuber growth and periodic collection of mini-tubers without disrupting the technological process of plant growth and minimizing the risk of the spread of viral and/or bacterial infection. Contacting the upper edges of the growth container with the base of the growth table along its perimeter prevents the nutrient solution from splashing beyond the boundaries of the growth container, prevents the evaporation of moisture from the growth container during the growth cycle, and prevents the penetration of air and light to the root system, i.e. eliminates the negative impact of external factors on the potato root system, ensuring the production of high-quality seed material. The removable fastening of the growth container to the upper frame makes it possible to install and dismantle the growth container with minimal labor costs and without the risk of spreading viral and bacterial infections in the next growth cycle on the same device or to plants grown in adjacent devices located in the same working room. The claimed set of features of the disposable growth container and its location on the support frame provides the possibility of effectively growing high-quality potato seed material using the aerohydroponic method and eliminates the need to sanitize the disposable growth container at the end of the growing season, eliminates the risk of transmitting viral and bacterial infections when growing subsequent generations of mini-tubers potatoes in the same installation or in the same room on similar devices.

In the inventive device, the support frame is a power frame, the side posts of which form a U-shaped frame; the lower edges of the side posts of the frame can be equipped with adjustable support elements. Between the right and left side posts of the support frame, there are upper and lower frames installed, which act as load-bearing elements for the growth table and a metal lattice with a tray and growth container, respectively. The support frame is made of aluminum profile, the lower and upper frames are formed by guides or cradle, the ends of which are rigidly connected to the aluminum profile of the side posts of the support frame. The guides or cradle correspond to the supporting surfaces of the growth table and the pallet placed on the lower frame of the support frame. The base of the growth table is in contact along the perimeter with the upper edges of the growth container; the growth table is placed in the guides of the upper frame. The tray is in contact with the bottom of the growth container. The distance between the upper and lower frames determines the overall dimensions of the growth container.

The support frame can be configured to be installed in the upper part of artificial lighting, for example, on brackets attached to the supports of the support frame.

The growth table is a rigid plastic cover made by casting or molding HDPE plastic or any other suitable plastic. On the surface of the plastic roof there are through holes for placing plants in seedling cells, cassettes or any other type. In some cases, technological elements of growth equipment - pipelines, sprayers, plant clamps and other elements required by production - can be placed on the plastic cover. Additionally, the plastic cover is made with stiffening ribs, because It is the growth table that bears the physical load from the vegetative stem and leaf mass of the grown plant.

The nutrient solution supply system is made in the form of a plastic pipeline with nozzles. The pipelines can be secured by any known methods, for example, with brackets, on the base of the growth table, allowing the nutrient solution to flow directly to the root system located in the growth container.

The main physical load, including weight, is borne by the lower part of the growth capacity, because it houses the root system and nutrient solution. The bottom of the growth container is in contact with a tray mounted on a metal grid in the guides of the lower frame. The pan is made with side walls and grooves for collecting and redistributing the remaining nutrient solution in the pan, leaking or flowing from the moisture-permeable bottom of the growth container, moving to the drain neck of the pan for subsequent disposal or recycling. The tray can be made of hard plastic or any other material that can bear the load created by the growth container and is chemically inert to the flowing spent nutrient solution. The pallet is placed on a metal grid mounted on the lower frame of the support frame.

The support frame can be additionally equipped with front panels, pipeline fastening elements with nozzles for spraying the nutrient solution. Any known nutrient solution suitable for growing potato mini-tubers using the aerohydroponic method can be used as a nutrient solution.

The growth container is a quick-removable disposable container with flexible walls in the form of a bag with an open top and bottom, designed to allow the spent nutrient solution to pass into the pan. After completion of the growth cycle, the growth capacity is removed along with the remnants of the root system after cutting it off from the plant stem apparatus, which is located above the growth table and is removed separately from the root system.

A bag made of dense, opaque flexible plastic, such as black polyethylene film with a thickness of 0.1 mm or more, is used as a growth container. The growth container can be made of dense opaque non-woven material, for example spunbond, with a density of 100 g/ ^{m2 or more} . The choice of specific material for making a bag depends on the varietal specifics of the potato. If the bag is made of dense opaque flexible plastic (film), perforations are made in its bottom to drain the spent nutrient solution from the growth container into the tray. If the bag is made of dense spunbond, the waste nutrient solution is removed through the bottom of the spunbond, which can be done without additional perforation of the bottom. The overall dimensions of the bag correspond to the overall dimensions of the space formed between the lower and upper frames.

The upper edge of the bag is removably secured to the guides of the upper frame, for example, by bending around the upper edges of the bag by the guides or by engaging pre-formed technological holes in the upper edge of the bag by protrusions or grooves made on the guides of the upper frame. Any known method of removably fastening the upper edge of the bag to the upper frame of the support frame can be used.

On the side surface of the growth container there is a through window, which is equipped with a folding, light-opaque screen, preferably made of the same material as the growth container of dense opaque flexible plastic in the form of a film or dense opaque spunbond.

The inventive device is illustrated by the following figures.

In FIG. 1 schematically shows the components of the proposed device

In FIG. Figure 2 shows the inventive device assembled with the side and lower front front panels removed and the growth container window open;

In FIG. Figure 3 shows the inventive device assembled in a section from the side of the support frame;

In FIG. Figure 4 shows a growth container in the form of a bag with an open window on the side wall;

In FIG. Figure 5 shows a general assembled view of the claimed device.

The inventive device for growing mini-potato tubers consists of:

1 - support frame, the side posts of which form a U-shape, made of aluminum profile;

2 - front panels attached to the support frame on the sides of the support frame, front and back on the upper and lower frames;

3 - adjustable supports installed in the bases of the side posts to adjust the horizontal position of the support frame 1;

4 - upper frame formed by guides rigidly attached to the side posts of the support frame 1;

5 - lower frame formed by guides rigidly attached to the side posts of the support frame 1;

6 - growth table, made in the form of a rigid plastic cover, installed in the guides of the upper frame 4;

7 - holes in the growth table 6 for placing plants;

8 - stiffening ribs of growth table 6;

9 - nutrient solution supply system in the form of pipelines attached to the support frame 1 and the base of the growth table 6, which are equipped with nozzles for spraying the nutrient solution;

10 - growth container in the form of a bag with perforations on the bottom (not shown), made of light-opaque flexible material, the upper edges of which are removably attached to the upper frame 4;

11 - window on the side wall of the growth container 10, closed by a folding screen (not shown), which is made of light-opaque material;

12 - tray for growth container 10, made of hard plastic with grooves for accumulation and distribution of waste nutrient solution;

13 - drain neck of tray 12 for discharging spent nutrient solution;

14 - a metal grid installed in the guides of the lower frame 5, on which a pallet 12 is placed, which serves as the basis for the bottom of the growth container 10.

The inventive device operates as follows.

The device is assembled according to the diagram shown in Fig. 1, inserting a growth table 6 into the guides of the upper frame 4, placing the pallet 12 on a metal grid 14 inserted into the guides of the lower frame 5. Artificial lighting sources (not shown), for example LEDs, are attached to the support frame 1 in the upper part on brackets. To the surface of the base of the growth trunk 6, facing the growth container, a nutrient solution supply system 9 is attached in the form of two pipelines from a HDPE pipe with nozzles for spraying the nutrient solution into the growth container 10. The nutrient solution supply system 9 is connected to a pump (not shown) for injection of nutrient solution. A growth container 10 is removably attached to the upper frame 4 by the upper edges, and the bottom is placed on a tray 12. Potato plants are placed in the holes 7 of the growth table 6, artificial lighting is turned on, and through the nozzles of the nutrient solution supply system 9 it is supplied to the growth container 10.

The upper frame 4 carries the load of the growth table 6 and the nutrient solution supply system 9, and holds the vegetative mass of plants. The side walls of the inventive cultivation device are formed by the side walls of the growth container 10, which has dimensions corresponding to the dimensions of the space formed between the growth table 6 and the tray 12. In the growth container 10, by cutting through its side wall, a window 11 is made, which is removably closed from the outside with a light-proof folding screen ( not shown) made of the same material as the growth container 10. A folding screen of the growth container 10 can be attached along the upper edge of the window 11 and made with dimensions exceeding the size of the window 11, thus completely covering the window 11 of the growth container 10. Window 11 provides access to the root system for maintenance personnel in order to monitor and carry out technological manipulations with the root system. The bottom of the growth container 10 is equipped with perforations to drain the spent nutrient solution into the tray 12 or is made of spunbond, which has water transmission properties (water permeability). The spent nutrient solution is collected in the grooves of the tray 12 and removed through the drain neck 13 into a collecting container for disposal or recycling, followed by feeding into the circulation system (not shown). The removed residual nutrient solution passes through an ultraviolet sterilizer (not shown) before entering the circulation system.

After the growth cycle is completed, the plants are removed from the surface of the growth table 6 - the stem apparatus is cut off from the root apparatus at the location of the planting nest and removed, the root system falls inside the growth container 10. The growth container 10 is removed from the upper frame 4, freely twisted together with the remains of the root system and removed for subsequent disposal.

Upon completion of the growth cycle, the growth table 6 and the tray 12 are removed from the upper 4 and lower 5 frames of the support frame 1 and can be subjected to a sanitation procedure. The pipelines for supplying, collecting and removing the nutrient solution are easily sanitized by connecting to each other; washing cycles are carried out with the addition of appropriate disinfectants.

The inventive installation allows for the efficient cultivation of potato mini-tubers using the aerohydroponic method, changing growth cycles on the same installation with minimal labor costs, and also eliminating the risk of the spread of viral and/or bacterial diseases.

The tests have shown that when using the inventive installation with a number of seats of 40 units, the process of changing cycles with sanitation between them does not exceed 45 minutes (subject to servicing by one specialist).

Claims (10)

1. A device for growing potato mini-tubers, consisting of a support frame having an upper and lower frame, a growth table with holes is placed on the upper frame, a tray for a growth container is placed on the lower frame, the internal cavity of the latter is connected to the nutrient solution supply system, the tray is equipped with a drain neck for the spent nutrient solution, characterized in that the growth container is disposable and is a bag made of light-opaque flexible material, the bottom of the bag is made moisture-permeable with the possibility of the spent nutrient solution flowing into the pan, on the side of the bag there is a window with a folding light-opaque screen, and the upper edges of the bag are in contact with the base of the growth table along its perimeter and are removably fixed to the upper frame. 2. The device according to claim 1, characterized in that the growth container is made of plastic film with a wall thickness of 0.1 mm and is equipped with perforations on the bottom. 3. The device according to claim 1, characterized in that the growth container is made of dense non-woven material. 4. The device according to claim 1, characterized in that the folding, light-opaque screen is removable. 5. The device according to claim 1, characterized in that the support frame is made of aluminum profile, has a U-shape and is equipped with front panels. 6. The device according to claim 1, characterized in that the lower and upper frames are formed by guides, the ends of which are rigidly connected to the side posts of the support frame. 7. The device according to claim 1, characterized in that the growth table is made of hard plastic and equipped with stiffening ribs. 8. The device according to claim 1, characterized in that the pallet is placed on a metal grid installed in the guides of the lower frame. 9. The device according to claim 1, characterized in that the tray is made of hard plastic and equipped with grooves. 10. The device according to claim 1, characterized in that the nutrient solution supply system is represented by pipelines with nozzles for spraying the nutrient solution into the growth container.