UA82156C2 - Method and device for growing plants - Google Patents

Abstract

The invention provides a method of growing plants comprising supplying water to the plants so that the plant roots contact a body of water and drawing water through a suction device provided in contact with the body of water and into a first conduit (4) connected at one end to the suction device and through the first conduit (4) into a second conduit (5) connected to the other end of the first conduit (4), and the second conduit (5) is at least partially filled with air and the water is released from the first conduit (4) into air space in the second conduit (5), characterized in that the suction device is formed from a foam formed from a polymer selected from phenol urea formaldehyde; urea melamine formaldehyde polymer; polyurethane; furanic polymers; and homopolymers, copolymers and terpolymers of ethylene, propylene and butylene, provided that methods in which the plants are grown in a phenol urea formaldehyde foam growth substrate and the suction device is formed from phenol urea formaldehyde foam are excluded. The invention also provides an apparatus suitable for carrying out the method.

Description

Description of the invention

The invention relates to methods for growing plants, in which the rate of flow of irrigation water 2 through the environment that surrounds the roots of plants is controlled. In particular, it refers to the ways in which plants are grown in nutrient soil, for example, mineral wool-based nutrient soil. It also relates to a device for implementing this method.

Cultivation of plants on natural or artificial nutrient soil, in particular on the basis of mineral wool, such as basalt wool or glass wool, is well known. Water and, if necessary, fertilizers and other impurities 70 are supplied to the nutrient soil, usually by injection with water, which optionally contains fertilizers and other impurities and flows through the soil. It is important that plants receive sufficient water, oxygen, and other substances such as water-borne fertilizers.

Water is one of the means by which oxygen enters the nutrient soil (although oxygen enters the nutrient soil in other ways, such as directly from the air). In particular, if water is supplied from a dropper 12 located above the nutrient soil, based on mineral wool, the drops that fall on the soil are highly enriched with oxygen. This oxygen is transferred to the soil and absorbed by plant roots.

Similar considerations apply to other impurities dissolved in water, such as fertilizer. A higher rate of water flow in the soil increases the rate of supply of water-borne impurities. It is beneficial to have an appropriate water flow rate for the following reasons: an increased water flow rate leads to increased turbulence around the roots, which increases the rate of transport of essential components such as water and fertilizer in the root. The flow of water also removes unwanted by-products that are released into the nutrient soil by plants.

However, increasing the rate of water supply to the nutrient soil can cause problems. In particular, the maximum flow rate is usually determined by the maximum rate of water flow through the nutrient c 29 soil under the influence of gravity. If the water supply rate exceeds the flow rate, then the excess water (he) will simply overflow.

It is possible to modify the nutrient soil so as to obtain a higher maximum transmission rate.

However, this, as a rule, requires a decrease in the density of the nutrient soil, especially in the case of mineral wool. This in itself leads to a worse distribution of water in the soil. The level of water content in the upper part of the nutrient soil is significantly lower than in the lower part of the nutrient soil. The upper part can become very dry, and the lower mm part - saturated.

It would be desirable to actively control the rate of water flow through the soil. In our previous publications (7

IER-A-300,536 and EP-A-409,348) active water supply systems are described. si

IER-A-300,536)| reveals a system in which the flow of water through the nutrient soil is controlled by a capillary system. Water pipes are laid in the nutrient soil and connected to a water pump. This device is set to a predetermined speed of pumping water from the ground. The pipe system is completely filled with water, and the flow rate is essentially determined by the set performance of the water pump. This publication discusses "suction pressure," but in this context it represents the force that must be exerted on a plant to pull water "out of the soil." A high "suction pressure" in this sense correlates with a low soil water content, and the purpose of this 50 publication is to increase the corresponding soil water content and thus the corresponding suction pressure. ts IER-A-409,438) refers to the water pump system. In addition, it ensures the connection of system elements with pipelines and nutrient soil. The purpose of this is to prevent plant roots from growing into the piping system. It is claimed that the advantage of combining elements is that they remain more moist than the surrounding nutrient soil and prevent air from entering the pipeline system from the side of the nutrient soil layer. with IMO 95/31094)| describes the drainage system for active and passive liquid drainage of nutrient soils. There are rows of nutrient soils, each of which has a "suction plug" connected to a siphon hose that leads to the riser. There is no indication of the material from which the "suction plug" is made. - Although all these systems are effective and useful, there is room for some improvements. In particular, the previously described sl 20 systems require that the surface on which the plants grow, for example, the floor in a greenhouse, be almost exactly horizontal. Otherwise, the pressure in the system and the flow rate change depending on the height at which the 0th layer of nutrient soil (for example, mineral wool) is located. An additional possible complication is the fact that the pipeline system is largely filled with water. Thus, in such a system there is a continuous path for water from one plant to another. This allows the transfer of plant viruses and other 29 infections between all plantings. about MO 94/03046) reveals another system of growing plants in mineral wool. In this system, the water content in mineral wool is kept constant by supplying water to the nutrient soil based on mineral wool through irrigation pipes and removing it through drainage pipes. A conventional system of pipelines was used for water supply and drainage. In this system, as in the systems (EP-A-300,536 and EP-A-409,346), described 60 above, there is a continuous connection between the water in the nutrient soil and the water in the drainage system.

Another well-known plant growing system is known as the nutrient layer technique (MET) system. In this system, the plants grow in small germination boxes or even no soil at all, the plants and boxes, if used, are placed in a plastic container, such as a plastic wrap container. Water drips into the container and into the grow boxes, if used, and is removed from the plastic container 62 through the opening. Such systems have a disadvantage, which is that the drainage process depends significantly on the smoothness of the surface on which the plants grow. A rough surface leads to uneven drainage, and different plants are moistened to a different extent.

MO 03/005808) describes a system that effectively addresses all of these issues. It describes a system that

Includes a liquid drain and an air plug device that are connected to the growth system and that are part of a piping system that uses a cavity partially filled with liquid and partially filled with air to cause a controlled release of liquid from the soil. More specifically, it discloses a method of growing plants that includes providing plants, supplying water so that the roots of the plants are in contact with the body of water, and directing the water through a suction device embedded in the body of water into a first 7/0 conduit, directing the water through the first conduit into a second pipeline, and the second pipeline is at least partially filled with air, and the first and second pipelines are connected so that the first pipeline exits into the air space of the second pipeline. In preferred embodiments, the plants are placed in the nutrient soil, water is fed into the nutrient soil and removed from the nutrient soil through a suction device located in the nutrient soil. This system has numerous advantages compared to 75. 3 earlier systems such as (EP-A-300,536 and EP-A-409,348 and MO 95/31094 and UMO 94/030461.

It is shown that the suction device is suitable for removing water from the nutrient soil under the action of capillary forces. Said suction device can be made of porous materials, including stone (especially volcanic stone), ceramics, mineral wool or porous glass. Organic polymeric foam and organic polymeric fibers are also described as possible materials for the suction device. In practice, stone, especially volcanic stone, is considered suitable.

The preferred suction device materials in this publication have been found to have some disadvantages.

In particular, after some time of use, nutrients in the water that irrigates the system tend to settle on the surface of the stone or ceramic suction device. Due to the small pore size of the suction device, this can lead to clogging of the suction device. high school

This invention is aimed at solving this problem and it is done by selecting special materials for the suction device. at

According to the present invention, a method of growing plants is proposed, which includes providing plants, supplying water so that the roots of the plants are in contact with the body of water, and draining the water through a suction device placed in the body of water into the first pipeline, draining the water through the first pipeline into the second " o zo pipeline, where the second pipeline is at least partially filled with air, and the first and second pipelines are connected so that the first pipeline exits into the air space of the second pipeline, which is characterized by io) in that the suction device is made of foam plastic obtained from a polymer selected with "- phenol urea formaldehyde polymers, urea melamino formaldehyde polymers, polyurethanes, furan polymers, and homopolymers, copolymers and terpolymers of ethylene, propylene and butylene. with

Thus, the foam can be made, for example, from polyethylene, polypropylene or polybutylene, and ethylene-propylene-butylene terpolymers can be used in the same way as ethylene-propylene, ethylene-butylene and propylene-butylene copolymers.

By the term "styrofoam" we understand materials that at the micro level are sieves.

In preferred embodiments, the pressure in the pipelines is regulated by an air pump. "

It was established that the use of the above-mentioned types of organic foams alleviates complications with the deposition of nutrients in the pores of the suction device and allows smoothing and prolonging the course of the process.

Although in (MO 03/005808) organic foams are mentioned in general, the specific material is not mentioned. In particular, there is no mention of the fact that these particular materials can solve the problem of nutrient deposition in the pores of the suction device.

The invention includes an air-locked liquid discharge device which is connected to the oo growing system and which is part of a piping system in which a cavity, partly filled with liquid and partly filled with air, is used to cause a controlled release of soil liquid. A device for draining liquid with an air lock usually takes the form of a suction device, such as a suction plug inserted into the nutrient soil. The suction device is made of one of the specified materials and can form an air lock when the pressure in the piping system causes 1 air to be sucked into it. As the pressure of the discharged water increases in the system, it increases

Fo the flow of water, usually before the traction force is at least ZOcm of the water column.

The pressure can build up before the thrust reaches a value where the suction device releases air into the first pipe instead of water, so the force tending to remove the water from the system is greater than the force that holds the water in the suction device.

In a particularly preferred embodiment of the invention, the plants are placed in the nutrient soil, water is supplied to (F) the nutrient soil and removed from the nutrient soil through the suction device, which is placed in the nutrient soil

F soil. Thus, the liquid discharge device with an air valve is preferably connected to the nutrient soil. 60 There is no need to provide a horizontal surface and thus the system can be simply and directly applied in greenhouses without prior leveling of the floor.

The first pipeline goes into the air space of the second pipeline. In a preferred embodiment, at least two, and preferably a large number of pipelines are provided, each of which is connected to a suction device in contact with the mass of water that comes into contact with the roots of the plants. When plants grow in 65 nutrient soil, a large number of blocks are usually provided, each containing one or a small number of plants. In this case, each suction device usually corresponds to one block, and in some cases there is one suction device for each plant. Thus, although viruses and other infectious disease agents of one plant may be transferred from the nutrient soil to the first pipeline and then discharged to the second pipeline, there is no water connection between the second pipeline and other first pipelines corresponding to other plants. Thus, the risk of transmission of viruses and other pathogens of infectious diseases is significantly reduced.

The flow of water through the space surrounding the roots of plants, that is, the nutrient soil, can be regulated simply by changing the pressure in the pipeline system with an air pump and obtaining the following advantages mentioned above, such as regulation of the oxygen supply rate, regulation of the impurity supply rate, regulation of water content, pH, EP 7 /0 (electrical conductivity), nutrients such as nitrogen and trace elements, and removal of unwanted by-products. It is also possible to achieve this with a high density of nutrient soil, which ensures good water distribution.

It is also possible to easily and quickly change the composition of the atmosphere in the pipeline system and thus change the flow rates and water content without complications.

If nutrient soil is used and the suction device is placed in the lower part of the nutrient soil, then the water is removed from the lower part of the soil and the water saturation of the lower part of the soil decreases.

The invention also provides a device suitable for growing plants. It includes a cultivation system to hold the plants and water so that the roots of the plants are in contact with the mass of water, a cultivation system provided by a suction device made of foam obtained from

Of a polymer selected from phenol urea formaldehyde polymers, urea melamine formaldehyde polymers, polyurethanes, furan polymers, and homopolymers, copolymers, and terpolymers of ethylene, propylene, and butylene, and mounted to drain water from the cultivation system, and connected to the first conduit at one end of the first conduit. The first pipeline is connected at its second end to the second pipeline, and the device includes means for draining water from the second pipeline. The size of the device c is chosen so that the second pipeline is at least partially filled with air during use. Preferably, the device also includes an air pump mounted to regulate the air pressure in the piping system. at

Since in the method of the invention the cultivation system is preferably a nutrient soil, the suction device is preferably located in the nutrient soil.

Brief description of the drawings Fig. 1 shows a diagram of the device according to the invention.

Figure 2 shows a section of a part of the device according to the invention. io)

Figure 3 shows another section of a part of the device according to the invention. "-

Fig. 4 shows an additional diagram of the device according to the invention.

It is essential for the invention that the mass of water that comes into contact with the roots of the plants is in contact with the specified suction device. The suction device can remove water from the nutrient soil. That is, it can collect water against the pressure. Thus, although the invention may include a system for pumping or pumping, the suction device is such that it can receive water without it. In particular, it can first remove water from the nutrient soil under the action of capillary forces.

Styrofoam mainly consists of Kk) phenol urea formaldehyde polymers, linoleic melamine formaldehyde polymers, polyurethanes, furan polymers. In other variants of the implementation of c, it consists of homopolymers, copolymers and terpolymers of ethylene, propylene and butylene, for example, from polyethylene, polypropylene and polybutylene. z The suction device is preferably made of phenol urea formaldehyde foam or polyethylene foam. One variety of such foam is sold under the name Oaviz m, which has a three-dimensional cellular (or mesh) structure.

Go! Alternatively, the suction device is made of urea-melamine-formaldehyde polymer.

Corresponding polymers are sold under the trade mark Euioseii (TM) by the Eruiodgeep company. It is obtained from co-aminoplast resins and has an open cellular structure. Similar products that can be used are sold under the Euuisat (TM) and Nuagosei trademarks! (TM) by the same company.

A grid in which there are cells is essentially formed by square or rectangular cells in which the distance between

Ge) at the intersection points is from about 20 to about 100 micrometers, especially preferably from about n 40 to about 60 micrometers. The walls that form the cell are preferably in the range of 2 to 20 micrometers, but particularly preferred are walls that have a greater thickness in this range, for example, from 4 to 20 micrometers. The thickness is preferably from 1/10 to 1/5 of the distance between the intersection points of the cell, preferably from 1/8 to 1/5.

The material used to make the suction device must be sufficiently hydrophilic (F) to perform the required capillary action. Some special foams are formed from t polymers which are themselves sufficiently hydrophilic to ensure this, otherwise the foam must preferably contain a surfactant. 60 Absorbent devices having a density of at least bOkg/m?, especially when the absorbent device is made of phenol urea formaldehyde foam, are preferred. The density of the suction device can be high, for example up to 9UOOkg/m?, especially when the suction device is made of phenol urea formaldehyde foam. In particular, for suction devices made of polyethylene, the density can be from 600 to 820 kg/m3. Ureamelaminoformaldehyde materials can have a density/content of dry matter from 14 to 2Okg/m 3.

Foams, as a rule, have an open foam structure.

The suction device must hold water more strongly than air. Preferably it holds water against a force of at least 10cm of water column, preferably at least 133cm of water column, more preferably at least 20cm of water column, most preferably at least 30cm of water column. Some can hold water against the force of up to 200 cm of water column.

The capacity of the suction device to hold water can be greater or less according to the nature of the nutrient soil (when it is used). For example, when the nutrient soil is basalt wool, suction devices capable of holding water against the force of at least 5 cm of water column give 7/o satisfactory results. However, where the nutrient soil is earth, the best results are achieved when the suction device holds the water against the force of at least 50 cm of water column.

When the pressure in the second pipeline is lower than atmospheric (which is preferable), as a rule, the suction device holds water more firmly than air at the value of the water column, which is determined by: the rise of the second pipeline above the suction device, which was subtracted from how much the pressure in the second 7/ 5 pipeline below atmospheric pressure (which is often called rarefaction). In practice, the suction device can hold water against a force that is essentially equal to the vacuum in the second conduit.

When nutrient soil is used, it is preferred that the material of the suction device has an average pore size smaller than the average pore size of the nutrient soil.

A suction device can be described as essentially airtight. For example, it prevents the significant passage of air through the mass of water that comes into contact with the roots (that is, through the nutrient soil, if it is used), and into the first and second pipelines.

The air pressure in the first and second pipelines, as a rule, is determined in advance, and preferably it should be lower than atmospheric pressure. The introduction of air into the second pipeline through the suction device will affect and change this pressure to some extent. This also leads to different air pressures in the different suction devices in the same system, which must be avoided in the proposed system. However, in systems in which the pressure is significantly lower than atmospheric, for example, by about 20 cm of water column, a small level of air passage into the outlet pipeline through the suction device does not cause problems. Thus, the suction device does not pass air to the extent that prevents the entry of significant amounts of air into the second pipeline, which significantly affects the air pressure in the second pipeline. «о зо In systems that contain an air leak in the air pump, the air pump can be seen.

The suction device usually has a total volume of about 2 to 100 cm3. i am

Suction devices are usually placed as independent units with separate boxes of nutrient soil (each box contains one or a small number of plants) or separately in large boxes (which contain many plants), with each suction device corresponding to one small box or small c

Number of plants in a large box. co

Suction devices of this kind can be described as "suction plugs". Devices can take on different shapes and sizes. As a rule, the suction device has the usual cylindrical or elongated shape.

However, it is not necessarily a separate detail. For example, it can take the form of two or more separate threaded parts. The size of the suction device is usually chosen so that it corresponds to the environment « 70 Plant roots, whether it is a box with nutrient soil or a mass of water. It is also possible that the suction device is not a suction plug, but is provided by a layer of material along the base of the box. For example, a box with nutrient soil can be made of mineral wool, in which the top layer is made of mineral wool and the bottom layer is made of a specified foam, such as phenol urea formaldehyde foam or polyethylene foam. Such a layer can be provided in separate boxes or in to one large box equipped for a large number of plants. o The plants are usually commercial crops grown in greenhouses. These crops can be, for example, tomatoes, cucumbers, sweet peppers, eggplants, roses or mushrooms. de According to the prevailing In an embodiment of the present invention, the plants are grown in a nutrient medium. Any natural or artificial nutrient medium may be used, such as soil, peat, coir, perlite, or man-made fiberglass (MMMURE) and any mixtures thereof. Other suitable nutrient mediums include mixture of polyurethane and granular mineral fibers, as described in (МХО 02/00009). If the suction device iy

Fo is made of phenol urea formaldehyde foam, such as is sold under the name Oaviv m, then the nutrient soil is not made of these materials. The preferred nutrient soil is mineral wool, such as glass wool or, preferably, basalt wool.

Nutrient soil based on mineral wool can be produced by the usual method of obtaining mineral melt and the formation of fibers from the melt. During fiber production or, less preferably,

F) after the production of the fibers, a binding material can be applied to the fibers. When a binder is used, it is preferred that it be a hydrophilic binder.

Nutrient soil mainly contains surface-active substance. It can be used in addition to the binding material. Alternatively, you can use one substance that acts simultaneously as a binder and a surface-active substance.

The nutrient soil may contain other additives known in the art that change and improve properties, such as clay or lignite.

In one embodiment, the nutrient soil is presented in the form of a series of small growing blocks 65, each of which contains one plant, and the growing blocks are contained in a plastic container, such as polymer film. This is one of the options for implementing the MET system discussed above.

In another version of the MET system, no nutrient soil is used at all. Instead, the plants are grown so that their roots are in contact with a mass of water contained in a plastic container such as polyfilm.

In this method, water is supplied to the plants, for example, to the nutrient soil, if it is used. Any usual methods are possible, for example, drip feeding. This method is especially preferable, because the water is enriched with oxygen by the time it reaches the plants, for example, the nutrient soil. Irrigation can be continuous or periodic. The water may contain fertilizers, biologically active impurities such as fungicides where useful for crop growth, and other impurities. 70 The suction device is connected to one end of the first pipeline, which, as a rule, has a small diameter. The inner diameter is preferably from 1 to 1 mm, more preferably from 2 to mm, especially about 4 mm.

The other end of the first pipeline is connected to the second pipeline. The second pipeline is at least partially filled with air. This allows you to adjust the air pressure in the system with an air pump. The first 7/5 pipeline exits into the air space of the second pipeline so that in the preferred embodiment, where several first pipelines feed into a single second pipeline, there is no continuous water path between the plants. As a rule, the first pipeline is connected to the upper part of the second pipeline. Generally, the first pipeline is mostly filled with water when the water flows during operation.

The relative volumes of air and water in the pipeline system will vary according to the required water flow and the size of the pipelines. However, it is preferred that no more than 8095, more preferably no more than 6095 and especially preferably no more than 4095 of the internal volume of the piping system is occupied by water.

Most preferably, less than 2095, especially preferably less than 1095, of the internal volume of the pipelines is occupied by water.

The pressure in the pipeline system is usually from 3000 Pa below to 3000 Pa above atmospheric pressure, but mostly from 2000 Pa below to 2000 Pa above atmospheric pressure. Preferably, the pressure should be lower than atmospheric pressure, for example from 100 to 2000 Pa below atmospheric pressure. (8)

It is possible to create a system in which the air pressure in the pipelines is higher than atmospheric, provided that the outlet from the first pipeline to the second pipeline is below the level of the suction plug.

This means that gravity causes the water to move from the suction plug to the second pipe. A pressure higher than atmospheric will reduce this tendency, but provided that the overall force forces the water to move in the direction of the second pipeline, then any combination of lift and air pressure is possible. what,

It is preferable that the outlet from the first pipeline to the second pipeline is raised higher than the suction device. Preferably, the entire second pipeline is raised higher than the suction device, and more preferably, raised higher than the entire nutrient soil. In this case, the pressure in the EM pipeline system is lower than atmospheric pressure. The advantage of this is that if an air bubble appears in the first pipeline, it will automatically move into the second pipeline without causing any pressure change in the system.

For the optimal operation of the preferred system, which includes two or more suction devices, each of which is connected to the first pipeline, and the two or more first pipelines exit into a single "second pipeline, the height difference between the suction device and the outlet of the first pipeline u - c the second pipe must be the same for each suction device/first pipe combination. It is not necessary that all the suction devices be at the same height or that all the first of the pipelines be at the same height. However, the relative height of the ends of the first pipeline relative to the suction device should be essentially the same for all pairs.

It is clear that the skilled person can choose the relative heights of the suction device and the outlet opening of the first pipeline to the second pipeline and the air pressure in the pipeline system so as to obtain the force necessary to divert water from the suction device to the second pipeline. It is preferable that the height of the outlet opening of the first pipeline into the second pipeline is not less than the height of any other point of the first pipeline. That is, it is preferable that no part of the first pipeline is located higher than the outlet opening of the first pipeline into the second pipeline. 1 It is preferable that the system includes several boxes with nutrient soil, such as mineral wool, each of

Fo which is equipped with a suction device and a first pipeline, and all the first pipelines lead to a single second pipeline. More preferably, when there are a number of such systems, at least two, in general, several second pipelines are all connected together to a single third pipeline. The water then flows into a third pipe, which contains a siphon that removes water from the system. The siphon is preferably placed at the lowest point of the third pipeline. (F) The second pipe can be placed at any angle provided it allows water to flow from

Ф of the system or, preferably, in the third pipeline. As a rule, it is placed at an angle from 0 to 459 relative to the horizontal. Water pumped out of the system is usually reused, usually after disinfection.

The system may be actuated in a variety of suitable ways to create an initial flow of water through the suction device, such as by an air pump or other suction means, or even gravity alone. In well-sealed systems, no additional means of reducing or increasing the air pressure is required, but in practice it is often convenient to include such means to regulate the pressure in the system over a long period of time.

The air pump is mainly used to regulate the pressure in the system and can be connected at any point of the pipeline system, usually to the second or third pipeline. The air pump is adapted to regulate the pressure in the system within the range of the required pressures within the system.

Water is diverted from the nutrient soil into the pipeline system, adjusting the forces so that the water moves from

Suction device to the second pipeline.

The system described in the invention can be used in any method of growing crops. It is particularly useful for regulating the water flow rate in the oxygen control system discussed in (MO 03/0058071.

The system described in the invention will now be illustrated with reference to the drawings. 70 Figure 1 shows a series of boxes 1 with nutrient soil based on mineral wool. Each box 1 contains a plant 2 for cultivation (see Fig. 2). Each box 1 is provided with a suction plug 3 made of Oavzivtm (phenol urea formaldehyde foam) material, connected to the first pipeline 4. All the first pipelines 4 are connected to a single second pipeline 5, described as a discharge pipeline. In a preferred version of the system, there are a number of outlet pipelines 5, each of which has several first pipelines 75 supplying water. Two outlet pipelines 5 are shown in Fig.1. All outlet pipelines 5 supply water to the third pipeline 6. The third pipeline would be represented as the main pipeline. An air pump 7 is connected to this main pipeline 6. At the lower point of the main pipeline 6 is a siphon 8, which is used to remove water.

It can be seen that the outlet of each first pipeline 4 into the outlet pipeline 5 is at a higher height than the corresponding suction plug 3.

The first pipelines 4, as a rule, have an internal diameter of 1 to 1 mm, preferably about bmm. The second outlet pipelines 5, as a rule, have an internal diameter of 20 to 100 mm, preferably from 40 to 100 mm.

The system is started as follows. Siphon 8 is filled with water. Boxes 1 are filled with water. This allows the suction plugs to be filled with water from boxes 1 under the action of capillary forces. Then the air pump 7 is turned on so that it reduces the air pressure in the pipeline system. Air pressure decreases, for example, by about 10 Pa below atmospheric pressure. Therefore, the water from the suction plugs C is diverted to the first i) pipelines 4 due to a decrease in air pressure in the pipeline system and drips into the outlet pipeline 5 from the upper part of the outlet pipeline 5. In Fig. 2 there is a section of the outlet pipeline 5, which shows the air space and water , which flows along the lower part of the pipeline. Thus, the water that is removed from ("y

Each box is isolated from all other boxes. Water flows along the base of the outlet pipeline 5 into the main pipeline 6. Water is removed from the system using a siphon 8, which allows water to exit regardless of air pressure and without affecting air pressure. "-

In the system shown in the illustration, the place where the first pipelines 4 exit into the discharge pipelines 5 is higher than the suction plugs 3. Thus, in order to drain water through the first se

Зз5 pipeline 4, it is necessary that the air pressure is lower than the atmospheric pressure sufficiently in order to raise the water to the required height. The relative height is the same for all suction plug/first pipe pairs. "Yu

Claims (1)

The formula of the invention - with ! ! 1. A method of growing plants, in which water is supplied to the plants so that the roots of the plants are in contact with a mass of water, and the water is drained through a suction device placed in the mass of water into a first pipe connected at one end to the suction device, through the first pipeline into the second pipeline, connected to the other end of the first pipeline, and the second pipeline is at least partially filled with air, and the water exits from the first pipeline into the air space of the second pipeline, which is characterized in that the suction device is made of foam plastic obtained from polymer, io) selected from urea melaminoformaldehyde polymers, polyurethanes, furan polymers, and homopolymers, - copolymers and terpolymers of ethylene, propylene, and butylene. 2. The method according to claim 1, which differs in that the pressure in the pipelines is regulated by an air pump. 1 3. The method according to claim 1 or claim 2, which differs in that the plants are grown in nutrient soil so that water is fed into the nutrient soil and removed from the nutrient soil through a suction device located in the nutrient soil. 4. The method according to any of claims 1-3, which is characterized by the fact that the suction device is made of 5B polyethylene foam. 5. The method according to any one of claims 1-4, which differs in that the inner diameter of the first pipeline (GF) is from 6 to 50 95, preferably from 7 to 30 95 from the inner diameter of the first pipeline. t 6. The method according to any of claims 1-5, which is characterized by the fact that the dimensions of the pipelines and the flow rate are adjusted in such a way that no more than 20 95, preferably no more than 10 95, of the internal volume of the pipeline system is occupied by water. 7. The method according to claim 3, which is characterized in that the nutrient soil is contained in at least one box, which has at least two suction devices in the form of suction plugs, each of which is connected to a first pipeline, and at least two first pipelines are connected to one second pipeline. 8. The method according to claim 2, which is characterized in that at least two second pipelines are installed, which lead 65 to one third pipeline, to which the air pump is connected. 9. The method according to any of claims 1-8, which is characterized by the fact that water is removed from the pipeline system through a siphon. 10. The method according to any of claims 1-9, which is characterized by the fact that the air pressure in the pipeline system is maintained below atmospheric pressure, preferably below atmospheric pressure by an amount from 100 to 2500 Pa. 11. The method according to any one of claims 1-10, which is characterized by the fact that the place where the first pipeline exits into the second pipeline is located at a height that exceeds the height of the suction device. 12. The method according to any one of claims 1-10, characterized in that the second pipeline is essentially straight and is located at an angle of 0 to 452 to the horizontal, and all its points are at a height that exceeds the height of the suction device. 70 13. The method according to any one of claims 1-7, characterized in that the second pipeline is essentially straight and is located at an angle of 0 to 4592 to the horizontal, and all its points are below the suction device. 14. The method according to any one of claims 1-13, characterized in that the suction device holds water against a force of at least 5 cm of water column, preferably at least 10 cm of water column, more preferably at least 75 at least 20 cm of water column, most preferably at least 30 cm of the water column. 15. The method according to claim 3, which differs in that a nutrient soil is used, which consists of artificial glass fiber, preferably basalt wool. 16. A device for growing plants, which includes a cultivation system designed to hold the plant and water so that the roots of the plants are in contact with a mass of water, and the cultivation system 2o has a suction device mounted for draining water from the nutrient soil, and a first pipeline, with connected to the suction device and mounted to drain water from the suction device, and a second conduit connected to the end of the first conduit, not connected to the suction device, and means for draining water from the second conduit, the device being sized so that the second pipeline during operation is at least partially filled with air, which is characterized by the fact that the suction device is made of foam plastic obtained from a polymer selected from urea melaminoformaldehyde polymers, polyurethanes, furan polymers, and homopolymers, copolymers and terpolymers of ethylene, propylene and butylene. at 17. The device according to claim 16, which is characterized by the fact that it additionally has an air pump mounted to regulate the air pressure in the first and second pipelines. 18. The device according to claim 16 or claim 17, which is characterized by the fact that the cultivation system is a nutrient soil. (That) 19. The device according to any of claims 16-18, which is characterized by the fact that it additionally has a means for supplying water to the nutrient soil, preferably a drip system. i am 20. The device according to any of claims 16-19, which differs in that the inner diameter of the first pipeline - pr is from 6 to 50 95, preferably from 7 to 30 95 from the diameter of the second pipeline. 21. The device according to any one of claims 16-20, which is characterized by the fact that it additionally has a third pipeline, with 3z5 connected to the second pipeline. co 22. The device according to claim 21, characterized in that the means for removing water from the second pipeline has a siphon located at the lower point of the third pipeline. 23. The device according to claim 18, which is characterized by the fact that the nutrient soil consists of artificial glass fiber, preferably basalt wool. " 24. The device according to any one of claims 16-23, which is characterized in that the place where the first pipeline leaves the second pipeline is located at a higher height than the suction device. and 25. The device according to any one of claims 16-23, characterized in that the second pipeline is essentially straight and is located at an angle of 0 to 4592 to the horizontal, and all its points are at a higher height than the suction device. so ko - 1 (42) F) ko 60 b5