RU128450U1 - HYDROPONIC DEVICE FOR AUTONOMOUS IRRIGATION OF PLANTS - Google Patents

Abstract

1. A device for watering plants by periodic flooding with a nutrient solution, including a flooded tray, a working container for a nutrient solution, connected to the specified flooded tray by means of supplying a solution for periodic flooding of the tray, and associated with means for periodic air injection, characterized in that for a stable level of periodic flooding of plants, the device includes an additional container for the nutrient solution installed in the device body or next to the device, the said container has a neck at the bottom in the form of at least one hole and / or tube. 2. The device according to claim 1, characterized in that the additional container is located in the device body in height between the tray and the working container, the working container is located at the bottom of the device body. The device according to claim 2, characterized in that the working container is made in the form of an inverted bowl, in the upper part of which there is an opening for connecting the air injection channel and a tube for supplying the solution to the tray and exiting excess air, the additional container is made in the form of an upper inverted bowl with the formation of a neck by the lower edge of the bowl and installed above the working container with the formation of a gap between the container neck and the working container, while the air injection channel and the tube for supplying the solution to the tray and outgoing excess air are installed outside the container, the tray is formed by the side walls of the upper part of the device body, the bottom the tray is the top of the container. 4. The device according to claim 2, characterized in that the working capacity is made

Description

The utility model relates to devices for watering plants grown on artificial nutrient media in special conditions.

A number of hydroponic devices are known in which watering of plants is carried out by periodically flooding the roots of plants by increasing the level of nutrient solution in a container with plants, followed by lowering the level of the solution. In the method of periodic flooding, the roots of the plant are provided with an increase in the level of the solution with water and nutrients, and with a decrease in the level of the solution with oxygen.

Various devices are known that use a system of two containers for periodic flooding: a container with a solution, from where, using air, a nutrient solution is squeezed through channels of various configurations into a container with plants. When air is injected into the device, the level of the solution rises, when turned off, the solution displaces air from the device under the action of gravity, the level of the solution decreases.

A number of hydroponic installations are known, including reservoirs for a nutrient solution containing a compressor for pumping air into the installation (ed. St. USSR 1727719, US 20090313894, patent US 3451162).

The hydroponic plant (ed. St. USSR 1727719, IPC A01G 31/02, published April 23, 1992) has a reservoir 1 for the nutrient solution connected to the system of channels 6 through pipeline 4 and tubes 5. In the lids of 7 channels, vessels 8 are fixed with plants. At the bottom of the channels laid inflatable containers 10. connected to the compressor 12 and equipped with vertical movement limiters. The nutrient solution from the tank fill the channels to a certain level. Periodically turned on compressor supplies air to inflatable tanks, which, increasing in volume, raise the level of the solution in the channels up. In this case, the root system of plants is periodically wetted.

The disadvantage of this device is the design complexity and complex control system, which is difficult to implement in a device for home use.

A hydroponic device is known (US 20090313894, IPC A01J 31/00, published December 24, 2009), which includes a hydroponic pot with a plant connected to a sealed container of nutrient solution by means of fluid supply, and an air pump connected to the container of nutrient solution through air supply channels . When the air pump is turned on, pressure is created in the container of the nutrient solution, and the nutrient solution is displaced into the pot with plants. After the level of the nutrient solution in the container decreases significantly, air enters through the fluid supply channel into the hydroponic pot, thus saturating the nutrient solution in the hydroponic pot with oxygen. After the time interval set by the timer, the air pump is switched off and the solution returns from the hydroponic pot to the container under the action of gravity.

The disadvantage of this device is that when the solution is consumed by plants, the level of flooding of the plant roots in the hydroponic pot changes. Thus, the battery life of the device is limited.

The closest technical solution is a hydroponic device according to patent US 3451162 (IPC A01G31 / 02; A01G 27/00; A01G 31/00, publ. 1967.02.14).

The hydroponic device includes a housing, a base, an upper part, a central part, and the central part is partially transparent. The parts forming the container for the nutrient solution are located at the base of the housing. The tray with plants has a device for fixing plants. Between the tray and the container for nutrient made means for supplying liquid. In the upper part of the device, a pumping device is installed with means for ensuring the movement of gas along the line for pumping air into a container with a nutrient solution.

This device is designed to work at home, but it, like other devices, does not provide a stable level of flooding in the device, so the battery life of the device is limited.

The objective of the proposed utility model is to develop a device for watering plants that provides a long autonomous automatic operation with stable parameters of periodic flooding of plant roots, with the possibility of implementing the utility model in a compact device for home use.

The problem is solved using a device for watering plants by periodically flooding with a nutrient solution, including a flooded tray, a working container for a nutrient solution connected to the specified flooded tray using means for supplying a solution for periodically flooding the tray, and associated with means for periodically pumping air. For a stable level of periodic flooding of plants, the device includes an additional container for the nutrient solution installed in the device body or next to the device, the specified container has a neck at the bottom in the form of at least one hole and / or tube.

Preferably, the additional container is located in the device body in height between the tray and the working capacity, the working capacity is located at the bottom of the device body.

Preferably, the working container is made in the form of an inverted bowl, in the upper part of which there is a hole for connecting the air injection channel and a tube for supplying the solution to the tray and the excess air outlet, the additional container is made in the form of an upper inverted bowl with a neck at the bottom edge of the bowl and installed above the working capacity with the formation of a gap between the neck of the container and the working capacity, while the air discharge channel and the tube for supplying the solution to the tray and the excess air outlet Lena outside the container, the tray is formed by the upper side walls of the machine, the tray bottom is the upper part of the container.

Preferably, the working container is made in the form of an inverted bowl, in the upper part of which there is an opening for connecting the air injection channel and a tube for supplying the solution to the tray and the excess air is released, the additional container is made in the form of an upper inverted bowl with a gap with the working capacity, in the upper part of the bowl forming the container, a tube is installed with a gap relative to the working capacity, an air injection channel and a tube for supplying solution to the tray and exit ytka air, the container neck is formed by the lower edges of the inverted cup and said tube, the tray formed by the upper side walls of the machine, the tray bottom is the upper part of the container.

Preferably, the tube for supplying the solution to the tray and venting excess air is installed so that the upper end of the tube is higher than the neck of the container and the lower end of the tube is higher than the lower edge of the bowl of the working container.

Preferably, the working capacity is formed between the bottom of the device’s body and the bowl, hermetically inserted into the device’s body, with an opening for connecting the air injection channel, a tube for supplying the solution to the tray and the excess air outlet, a tube for topping the working capacity, the upper bowl is hermetically inserted with the formation an additional container between the bowls, at the same time a tube is made in the bottom of the upper bowl through which an air injection channel and a tube are installed to supply the solution to the tray and to release excess air, etc. and this tray is formed by the upper bowl.

Preferably, the excess air outlet pipe is installed so that the upper end of the tube is higher than the container neck and the lower end of the excess air pipe is above the lower edge of the topping tank.

Preferably, plants are mounted in the flooded tray.

Preferably, the container has an opening on top with attached means for venting and filling the solution.

Preferably, as a means for periodically pumping air into the container, it has a tube, a compressor, a timer and an exhaust device.

Preferably, a transparent tube is installed outside the device body to control the level of the solution and drain the solution.

Preferably, in order to adjust the volume of the displaced solution, the tube for supplying the solution to the tray and the outlet of excess air is configured to move relative to the working capacity.

Preferably, in order to adjust the volume of the displaced solution, the lower part of the tube for the exit of excess air is made with the possibility of changing the length.

Preferably, the tube is telescopic or corrugated. Preferably, the container is removable.

Preferably, the neck of the container is provided with a plug and a valve opening when the container is placed in the device.

Preferably, the neck of the container is located at a level corresponding to the minimum level of nutrient solution in the device.

The level of the solution in the container with plants is determined by the volume of the solution displaced by air and the minimum level of solution that was in the device before the air supply.

When the solution is consumed by plants, or by evaporation, the minimum level of solution in the device decreases. Therefore, without taking special measures, the level of flooding changes, which essentially disrupts the automatic operation of the device.

The constancy of the volume displaced by the air of the solution is ensured by the supply of air in an amount exceeding the volume of the displaced solution. Excess air escapes.

To stabilize the minimum level of the solution, an additional container 3 was added to the device with a stock of solution with a neck 19, in the form of holes and / or tubes, located at the level corresponding to the minimum level of solution in the device. When the level of the solution in the device is higher than the neck 19, it is blocked by a water shutter preventing the passage of air into the container 3, and the solution is held inside the container 3 by external atmospheric pressure. When lowering the level of the solution below the level of the neck 19, ambient air enters into it, and the solution flows out until its level in the device is equal to the level of the neck 19 and does not block the air supply.

The outflow of the solution from the additional container 3 occurs according to the principle of an auto-drinker. This principle is widely used in agriculture (for example, patent RU No. 2268585).

In the proposed utility model, sensors and other actuators used in known solutions are not required, therefore, the proposed solution allows the production of compact and inexpensive devices.

The proposed device differs from the known ones by the addition of a container 3, which works as an automatic drinker, and the organization of topping up a solution from it. The air in the proposed device is pumped in excess.

The proposed device is shown in Fig.1-4.

The device includes a flooded tray 1, a working container 2 for a nutrient solution and an additional container 3 for a nutrient solution, which are located outside of the housing 4 or in the housing 4 in various embodiments of the device.

The working container 2 and the additional container 3 can be formed in the device case 4 by various elements, for example, by using bowls 5, 6 inserted in different ways (an inverted bowl installed with a gap relative to the walls of the housing 4, relative to each other, hermetically inserted bowl in the housing 4 devices).

On top of the working tank 2 through the hole 10 is connected by a channel for pumping air 11 with a compressor 7 with a control device 8, for example a timer. On the air injection channel 11 there is a hole or branch with a device for discharging air 9, for example, in the form of a crane or a small hole.

The working tank 2 as a means of supplying the solution to the tray contains tubes and / or holes.

The working tank 2 is equipped with a tube 12 for supplying a solution to the tray 1 and air outlet. The container 3 on top may have a tube 14 with an opening 13. The tube 14 at the end has a tap or stopper 15 for discharging excess air and pouring the nutrient solution through the tube 14.

One or more plants 16 with one or more pots 18 with an inert substrate 17 is installed in the flooded tray 1. The pot 18 is made mesh or with holes for the solution.

The device may have a transparent tube 20 for draining and monitoring the level of the solution.

Figure 1 shows one of the variants of the device, the capacity of which 2 is formed by the inner surface of the inverted bowl 5, installed with a gap 23 relative to the walls of the housing 4.

As fastenings, any devices known from the prior art can be used, for example, threaded connections or latches.

The additional container 3 is formed by the inner surface of the inverted bowl 6, mounted in the housing 4 above the working capacity 2 with a gap 24 (the fastening in Fig.1-2 is not shown). Mounts are similar to those described above.

The flooded tray 1 is formed by the inner surface of the side walls of the housing 4 and the upper surface of the bowl 6.

The fluid supply channels are formed by: gaps, gaps 23 between the outer surface of the bowl 5 and the inner surface of the housing 4, gaps, gaps between the outer surface of the bowl 6 and the inner surface of the housing 4, tube 12.

The lower end of the tube 12 is higher than the lower edge of the bowl 5, the upper end of the tube 12 is higher than the lower edge of the bowl 6. This embodiment is preferable so that excess air exits the container 2 without entering the container 3, and exits through the tray 1.

At the top of the working tank 2 there is an opening 10 connected to air injection means. As a means of pumping air, the device comprises an air compressor 7 connected via a control device 8 to an electricity source (not shown). The air compressor 7 is connected to the opening 10 by means of an air injection channel 11, on which there is an exhaust device 9 for discharging air in the form of a valve, valve or hole. The exhaust device 9 is configured so that when the compressor 7 is running, the air flow through the exhaust device 9 was less than the capacity of the compressor 7, which allows filling the working capacity 2 with air for a time shorter than the time set by the control device for the compressor 7. When the compressor 7 is turned off, the air leaves capacity 2 through the exhaust device in a time shorter than that set by the control device until the next turn on. At the top of the additional container 3 there are means for discharging air and pouring the solution into the container in the form of an opening 13 and a tube 14 connected to the subject connected to the valve / plug / faucet 15.

The tube 12 may be rigid or semi-rigid with a fixed position, or with a variable position of the lower end, for example, corrugated or telescopic movable relative to the cup 5 or below. The variable position of the lower end of the tube is necessary to change the volume of fluid displaced from the tank 2.

In this case, the air injection channel 11 and the tube 12 for supplying the solution to the tray 1 are installed outside the bowl 6 close to the side wall of the device 4, the tray 1 is formed by the side walls of the upper part of the device 4, and the bottom of the tray 1 is the top of the container 3.

Figure 2 shows a device that differs from the device shown in Figure 1 in that a tube 21 is made in the upper part of the bowl 6, through which an air injection channel 11 and a tube 12 are installed, while the tray 1 is formed by the side walls of the upper part of the housing 4 and the bottom of the tray is the top of the container 3.

The container 3 is formed by the inner surface of the inverted bowl 6, mounted in the housing 4 above the container 2 (mount not shown) and the outer side of the tube 21, hermetically fixed in the hole in the upper part of the bowl 6. The flooded tray 1 is formed by the inner surface of the housing 4 and the upper surface of the bowl 6 .

The fluid supply channels are formed by: gaps 23 between the outer surface of the bowl 5 and the inner surface of the housing 4, gaps 23 between the outer surface of the bowl 6 and the inner surface of the housing 4, tube 12, tube 21.

The lower end of the tube 12 is higher than the lower edge of the bowl 5, the upper end of the tube 12 is higher than the lower edge of the tube 21. This embodiment is preferable so that excess air leaves the container 2 without entering the container 3, and leaves through the tray 1.

The neck 19 is formed by the lower edge of the bowl 6 and the lower edge of the tube 21, i.e. the solution from the container flows into the gap between the inner side surface of the bowl 6 and the outer surface of the tube 21.

Figure 3 shows a variant of the device in which the cups 5, 6 are inserted into the housing 4 of the device not turned upside down.

The container 2 is formed by the space between the outer surface of the bowl 5, the inner surface of the housing 4, the outer side of the tube 12 and the outer side of the tube 22. The walls of the bowl 5 are hermetically connected to the housing 4. The connection of the bowl 5 to the housing 4 is made detachable, with or without a sealing seal.

The container 3 is formed by the space between the outer surface of the bowl 6 and the inner surface of the bowl 5 and the outer side of the tube 21 hermetically fixed in the hole in the lower part of the bowl 6. The walls of the bowl 6 are hermetically connected to the walls of the bowl 5. The connection of the bowl 6 with the bowl 5 is made detachable through a sealing compaction or without it.

The flooded tray 1 is formed by the inner surface of the bowl 6.

The fluid supply channels are formed by: tube 12, tube 22, tube 21.

The lower end of the tube 12 is higher than the lower edge of the tube 22, the upper end of the tube 12 is higher than the lower edge of the tube 21. This embodiment is preferable so that excess air exits the container 2 without entering the container 3, and exits through the tray 1.

The neck 19 is formed by the lower edge of the tube 21 and the inner surface of the bowl 5, i.e. the solution from the container flows into the gap between the inner side surface of the bowl 5 and the outer surface of the tube 21.

Figure 4 shows a variant of the device in which a container 3 with a supply of nutrient solution is installed above the tray 1. For convenient filling with nutrient solution, the container can be made removable, additionally equipped with plugs and / or valves.

The neck 19 may be short or long, made in the form of a tube, rigid or flexible.

The fluid supply channels are formed by: tube 12, neck 19, lower part of the flooded tray 1.

The tube 12 is installed on the side of the neck 19, so that the air coming out of it does not enter the container 3 through the neck 19.

The proposed hydroponic device shown in Fig.1, 2, 3, works as follows:

1. Filling the device with a solution: To fill the device with a solution, open the valve 15 of the container 3. Pour the solution from above into the tray 1. The air filling the container 2 exits through the exhaust device 9. The air filling the container 3 leaves the pipe 14 through the valve 15. The solution is poured until the device is filled at the top of the container 3. The valve 15 is closed.

2. Flooding phase: When the compressor 7 is turned on using timer 8, air from it is pumped into the container 2 with the nutrient solution, forcing the solution into the tray 1, flooding the roots of the installed pots 18 with plants 16. When the air level in the container 2 reaches the lower edge of the tube 12 excess air exits through tube 12 to the outside.

3. Drainage phase: When the compressor 7 is turned off by the timer 8, the solution, by gravity, displaces the air from the working tank 2 through the channel for pumping air 11 into the atmosphere through the exhaust device 9. In this case, the solution is lowered through the tube 12 and either the tube 22 topping up the tank or the gap 23 between the housing 4 and the working tank 2, and when lowering the level below the upper end of the tube 12 only through the pipe 22 topping up the tank 2 or the gap 23 between the housing 4 and the tank 2.

4. Stabilization of the solution level: During the operation of the device, the solution is partially consumed by plants and evaporates. If in the drainage phase the level of the solution in the body of the device 4 falls below the hole (neck) 19 in the container 3, outside air passes into the container 3. The solution flows from the container 3 into the body of the device 4 until the hole (neck) 19 again falls below the level of the solution in the body of the device 4. From the body, the solution flows into the working tank 2 through the tube 22 topping up the tank or the gap 23 between the body 4 and capacity 2. Thus, as long as there is a solution in container 3, by the end of the drainage phase the working capacity 2 for the nutrient solution is each time filled with the same amount of solution, which ensures a stable level of periodic flooding in the mouth Royce.

5. Setting the level of flooding in the device: The level of flooding in the device is determined by the amount of solution displaced from the tank 2 with the nutrient solution. By changing the position of the lower end of the tube 12 in the tank 3, you can change the amount of air that fits into the tank 2, and therefore change the amount of solution displaced into the tray 1 and the level of flooding of plants. Changing the position of the lower end of the tube 12 can be realized by making the tube 12 movable relative to the container 2, or make the tube 12 with a variable length, for example corrugated.

The technical result of the proposed utility model is the development of a device that provides a long autonomous automatic operation with stable parameters of periodic flooding of plant roots, with the possibility of implementing a utility model in a compact device for home use.

Claims (17)

1. Device for watering plants by periodically flooding with a nutrient solution, including a flooded tray, a working capacity for a nutrient solution connected to the specified flooded tray using means for supplying a solution for periodically flooding the tray, and associated with means for periodically pumping air, characterized in that for a stable level of periodic flooding of plants, the device includes an additional container for nutrient solution installed in the housing of the device or near the device, said container bottom has a neck, at least one opening and / or tube. 2. The device according to claim 1, characterized in that the additional container is located in the device’s body in height between the tray and the working capacity, the working capacity is located at the bottom of the device. 3. The device according to claim 2, characterized in that the working container is made in the form of an inverted bowl, in the upper part of which there is a hole for connecting the air injection channel and a tube for supplying the solution to the tray and the outlet of excess air, the additional container is made in the form of an upper inverted bowl with the formation of the neck bottom edge of the bowl and installed above the working capacity with the formation of a gap between the neck of the container and the working capacity, while the air channel and the tube for supplying the solution into the tray and exit excess air is installed outside the container, the tray is formed by the side walls of the upper part of the device body, the bottom of the tray is the upper part of the container. 4. The device according to claim 2, characterized in that the working capacity is made in the form of an inverted bowl, in the upper part of which there is a hole for connecting the air injection channel and a tube for supplying the solution to the tray and the outlet of excess air, the additional container is made in the form of an inverted top bowl with the formation of a gap with a working capacity, in the upper part of the bowl forming the container, a tube is installed with a gap relative to the working capacity, an air injection channel and a tube for feeding thief into the tray and the excess air outlet, the neck of the container is formed by the lower edges of the inverted bowl and the specified tube, the tray is formed by the side walls of the upper part of the device, the bottom of the tray is the upper part of the container. 5. The device according to claim 3 or 4, characterized in that the tube for supplying the solution to the tray and the excess air outlet is installed so that the upper end of the tube is higher than the neck of the container, and the lower end of the tube is higher than the lower edge of the bowl of the working container. 6. The device according to claim 2, characterized in that the working capacity is formed between the bottom of the device’s body and the bowl, hermetically inserted into the device’s body, with an opening for connecting the air injection channel, a tube for supplying solution to the tray and outlet of excess air, and a topping-up tube working capacity, the upper bowl is hermetically inserted into the bowl with the formation of an additional container between the tanks, while at the bottom of the upper bowl there is a tube through which an air injection channel and a tube for supplying the solution to the tray are installed and you the course of excess air, while the tray is formed by the upper bowl. 7. The device according to claim 6, characterized in that the tube to exit the excess air is installed so that the upper end of the tube is higher than the neck of the container, and the lower end of the tube to exit the excess air is higher than the lower edge of the tube topping up the working tank. 8. The device according to claim 1, characterized in that in the flooded tray installed means for fixing plants. 9. The device according to claim 1, characterized in that the container has a hole on top with attached means for venting and filling the solution. 10. The device according to claim 1, characterized in that as a means for periodically pumping air into the container has a tube, compressor, timer and exhaust device. 11. The device according to claim 1, characterized in that a transparent tube is installed outside the device body to control the level of the solution and drain the solution. 12. A device according to any one of claims 3, 4, 6, characterized in that, in order to adjust the volume of the displaced solution, the tube for supplying the solution to the tray and the output of excess air is made with the possibility of movement relative to the working capacity. 13. A device according to any one of claims 3, 4, 6, characterized in that, in order to adjust the volume of the displaced solution, the lower part of the tube to exit the excess air is made with the possibility of changing the length. 14. The device according to claim 1, characterized in that the tube is made telescopic or corrugated. 15. The device according to claim 1, characterized in that the container is removable. 16. The device according to clause 15, wherein the neck of the container is equipped with a stopper and a valve that opens when the container is placed in the device. 17. The device according to any one of claims 1 to 4, 6-11, 14-16, characterized in that the neck of the container is located at a level corresponding to the minimum level of nutrient solution in the device.

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