RU131569U1 - HYDROPONIC INSTALLATION DEVICE - Google Patents

Abstract

1. Installation for growing plants using the methods of aero and hydroponics, consisting of stem and root zones, characterized in that it includes the following functional blocks: 1) made with the ability to retain liquid and fixation in its upper part of the plants or holders with them chamber , designed to accommodate roots in it; 2) the upper part of the lateral surface of the chamber, which determines the position of the stem zone space, external to the chamber, which is illuminated, the volume of which exceeds the volume of the chamber intended to accommodate the stems; 3) the supporting surface or surfaces limiting the external space; 4) block for attaching the camera to the supporting surface; 5) a container with a nutrient solution connected to 6) a liquid compressor connected to 7) a device located in the chamber for feeding the nutrient solution in the direction of the roots; 8) a node for the drainage of the nutrient solution after its possible contact with the roots, connected to the container; 9) artificial stem illuminator with 10) attachment to the supporting surface; 11) stem aerator; 12) a unit for thermostating the external space, given that the chamber is made in the form of a pipe plugged at the ends with through holes in the upper part of the lateral surface and with a door extending along the pipe located in the lower part of the lateral surface, while the pipe is located by means of the fastening unit in such a way in such a way that the deviation of its axis from the horizontal does not exceed ± 15 °. 2. Installation according to claim 1, characterized in that it additionally includes devices selected from the list: 13) a liquid filter; 14) CO and / or equivalent injector

Description

The utility model relates to the field of preferably non-impartial (in the presented materials water and air are not referred to as substrates) growing plants by feeding their root system with liquid solutions (hereinafter referred to as solutions) or aerosols.

Known installation for growing plants using the methods of aero- and hydroponics (application No. 2009121203 from 06/04/2009, authors Martirosyan Y. Ts., Harchenko PN), consisting of root and stem zones.

Such an installation can be used for growing virus-free root crops, in particular potato minicubers.

Its peculiarity is that it is made of racks interconnected by transverse crossbars-ties, on which are installed tray-growths with hinged side walls, covered with landing panels equipped with holes for planting material.

This installation is selected as a prototype.

The main disadvantage of the prototype should be attributed to the difficulty of using commercially available plastic products in it, such as sewer pipes, bends, tees, revisions, etc., etc., which significantly reduces its maintainability.

The technical result from the use of the distinctive features of the presented utility model consists in the possibility of using commercially available highly reliable plastic products in its construction and modernization (building).

In addition, the use of a utility model reduces the complexity of a) access to the root zone, which is carried out when caring for plants and collecting mini-tubers, and b) maintenance of the installation (repair, replacement of nozzles, etc.).

But the most important purpose of the presented utility model is to increase plant productivity, increase the number of vegetation to 4 or more per year, reduce the specific area of the plant - the ratio of the area occupied by the plant to the number of plants grown.

To achieve the claimed technical result, the following main distinguishing features are introduced into the well-known installation for growing root, tuber-forming plants using aero- and hydroponic methods, consisting of stem and root zones:

- it includes the following set of functional blocks 1) made with the possibility of holding fluid and fixing in its upper part of the plants or holders with them a camera (one or more), designed to accommodate the roots in it, 2) the upper part of the side surface of the camera, determining the position external to the camera periodically illuminated space of the stem zone, the volume of which exceeds the volume of the chamber, designed to accommodate the stems, 3) a supporting surface or surfaces that bound outside back space (top and / or bottom, and / or sides - left, right, front, back), 4) a unit for attaching the camera to the supporting surface, 5) a container with a nutrient solution connected to 6) a liquid compressor (pump), connected to 7) a device located in the chamber for supplying the nutrient solution in the direction of the roots, 8) a drainage unit of the nutrient solution after its possible contact with the roots, connected to the container, 9) an artificial stalk illuminator with 10) attachment to the supporting surface, 11) stalk aerator , 12) thermostatic unit anija external space;

- the chamber is made in the form of a solid (for example, sewer) or composite (with or without screed) pipe muffled at the ends with through holes in the upper part of the lateral (in the particular case, cylindrical) surface (it is assumed here that the pipe is horizontal);

- in this case, in the lower part of its lateral surface, the pipe has an extended (along its axis) tightly closing door;

- the door is made of a fragment of the chamber with an area approximately equal to half the area of the lateral surface of the latter (in the manufacture of the door, the pipe can be cut in half lengthwise, after which overlays can be attached to the inner surface of one of the resulting halves) and the door is made swing open - opening and simultaneously moving away from the camera (but not to the end - the camera may have a special emphasis) for which the door is attached to the camera (or rather, to the upper half of the camera, since the game door itself a role of the lower half of the chamber) by a hinge (e.g., grand piano type), whereas in a tightly closed state it holds the at least one latch (e.g., locking lever presser bill);

- by means of the mounting unit, the pipe is positioned so that the deviation of its axis from the horizontal does not exceed ± 15 ° (in general, the permissible deviation α should be selected based on the length of the chamber L taking into account its height D (in the particular case, taking into account its diameter) so that guaranteed the spillage of the nutrient solution through the holes for the stems in the upper part of the chamber was excluded, which will be ensured when the condition - L · sinα <D) is met;

- the mounting unit is a system for suspending the camera to a surface external to the camera (optimal from the point of view of arranging the passage and placement of other equipment - to the ceiling, but through brackets to the walls and even to the floor) and it is made with the possibility of temporarily changing the position camera - its displacement when applying little effort or otherwise - deviations with the possibility of independent restoration of the original position of the camera in space (for this they can use flexible suspension, hinged mounting of the camera to the suspension, and other structural elements).

The suspension is configured to adjust the height of the camera and its deviation from the horizontal.

At the same time, it is advisable to use pipes up to 12 m in length (optimally from the point of view of inertia - the longer the chamber, the heavier it is, the greater the moments of inertia - the more difficult it is to deviate it from its current position - 3-5 m) with two attachment points located near the ends .

In addition, a number of particular distinguishing features may be used in the presented utility model:

- in addition, it may include at least one of the following devices 13) a liquid filter (mainly performing a disinfecting function), 14) a CO ₂ injector and / or associated gas equipment, 15) a CO ₂ trap, 16) an ozonizer, 17) gas equipment A ₂ , 18) an injector of O ₃ or an ozone-air mixture, 19) a source of metal ions (silver), 20) an air compressor, 21) a water heater, 22) an insolation system, 23) a sheet feeding and humidification circuit; 24) an ultrasound source (in particular an ultrasonic steam generator);

- it is preferable to make the mounting unit with the possibility of a) periodically changing the deviation of the camera axis from the horizontal (for which, for example, at least one of the suspensions can be attached to a rotating eccentric cam that raises or lowers one end of the chamber) with a frequency of from one cycle to several seconds to one cycle per day - two (which ensures the creation of approximately the same conditions from the point of view of washing the roots with a nutrient solution for various plants planted in the chamber) and b) changes in the station If the camera’s position is set to its new stationary position (for this, it can include, for example, rails or other guides, for example, translational motion, and the suspension can be attached to the rollers) - when working with the camera it is more convenient to place it in open space, whereas for reducing the space occupied by the settings of the camera is preferably grouped with each other;

- a pressure pipe can be connected to the liquid compressor, to which a distribution pipe is attached, located in the chamber (not outside - to avoid emergency leaks into the external space);

- nozzles can be connected to the distribution tube (preferably the number of nozzles should be equal to or greater than the number of “good” plants — the number of plants to be harvested from which to be harvested, and not the number of holes for the plants and not the number of all plants planted — practice shows that even if defective plants are replaced (of which up to 200-300% can be detected at the initial stage), 10-15% of the abandoned plants will be useless at the finish already) and at the same time, a hundred or so nozzles can be located in the chambers horns (for example, made of wire) in such a way that one part gets a solution or an aerosol emerging from the nozzles during their operation, while the other part (being, for example, rigidly connected to the first one) is located outside the chamber (as a result of oscillation or the vibration of the gatekeepers will confirm the performance of certain nozzles, which will facilitate the search for clogged or damaged);

- nozzles in the chamber (in order to prevent splashing of the nutrient solution outside) should be directed towards the door hinges (and not towards the latch), thus, the distribution tube should be carried out from the latch side (in the upper part of the chamber from the side of the doorway formation);

- the installation may include O ₂ gas-balloon equipment (cylinders themselves, protective boxes, piping, ball valves, electromechanical valves, etc.) or an air compressor (with hoses, etc.), while the device for feeding the nutrient solution in the direction of the roots should turn on the nozzles and at the same time the latter should be fed in which you can serve? both the equipment and / or compressor mentioned here and the liquid compressor mentioned above simultaneously with the aim of producing a finely dispersed aerosol with a relatively large diameter of the hole through which liquid is supplied to the nozzle (forming an insoluble sediment clogging the nozzles);

- the installation may include a CO ₂ trap located above the upper part of the chamber (around the green mass of plants) and representing a tray with high translucent walls (and with "overflows" for the flow of carbon dioxide when the chambers are located one below the other), the bottom of which is located stems aerator fan, made with the possibility of periodic on / off (for example, connected to a timer);

- the installation may include a source of metal ions (electrochemical), which is autonomous from the point of view of power supply, immersed and placed inside the working volume of the tank directly in a nutrient solution (such a source is supposed to be used for disinfection of the latter);

- the installation may include several chambers similar to each other, located side by side at different levels vertically and offset from each other horizontally by a distance commensurate with the width of the green mass of plants (to reduce the specific area of the installation);

- a plastic cylindrical pipe with local profile deviations within 10% of the diameter can be used as a camera (with large deviations, stagnation of the nutrient solution is likely), in another design the camera can be assembled (composed) of tees, revisions, etc .;

- a pipe and so on can be used. diameter from 110 to 476 mm (numbers from a row are indicated);

- the through holes in the upper part of the chamber along their perimeter can include elastically deformable gaskets-inserts (which should compress the stem of the plant), so that shallow glasses (with plants) of elastically deformable material can be inserted into them (this should allow easy replacement of glasses);

- the tank can be installed under the camera - below the level of the latter, while it may include and / or measuring tanks, level, mixer, piping system with nozzles, consumables, valves and so on .;

- the installation may include a localized or distributed (with the controls distributed in space in accordance with the location of certain blocks) a manual control unit for the operation modes of its blocks;

- the installation may also include sensors (for example, СО ₂ , О ₃ , humidity, temperature) connected to the device for automatically controlling the operating modes of its units (however, manual control is preferable from the point of view of all factors);

- the drainage unit may include a siphon drain, preferably with a multi-stage replaceable filter installed inside, cutting off mechanical impurities;

- the drainage unit can be attached to the camera in two places (from the front and rear ends - thus, with one tilt of the camera during its periodic swing, the drain will be carried out in one place, and with another in another);

- the chamber may include partitions (preventing weaving of the roots of various plants) by at least one less number of through holes (partitions are designed to facilitate the removal of glasses with defective plants);

- the partitions can be made removable (there is no need for partitions in the finishing stages of cultivation, while it is advisable to provide the root system with maximum freedom), as well as of mesh material (which should facilitate the flow of nutrient solution through the partitions).

Besides.

The installation may include additional circuits for feeding the nutrient solution into the chamber (for example, when using different solutions in the "day" and "night" time).

The illuminator may include an infrared filter and / or cooler.

Mounting the illuminator may provide the ability to change the position of the latter vertically.

The installation may have a backup tank with shut-off equipment located above the camera. This capacity is designed to power plants in the event of an emergency power outage.

The chambers can be made of opaque material. The pressure pipe can approach the end of the chamber, in the cap of which a corresponding fitting can be located.

The utility model is illustrated by 4 figures.

Figure 1 shows a block diagram of the presented installation.

Figure 2 shows the camera (rear view).

Figure 3 - shows the camera (front view).

Figure 4 - shows the installation, composed of several cameras.

Figure 1 is provided to illustrate the relationship between the installation units.

Figure 2 - 4 are shown to illustrate the design of the installation units.

In FIG. The following notation is accepted:

1 - camera.

2 - illuminated space.

3 - supporting surface.

4 - camera mount unit.

5 - capacity with a nutrient solution.

6 - liquid compressor.

7 - a device for supplying a nutrient solution.

8 - node drain of nutrient solution.

9 - artificial light.

10 - fastening the illuminator to the supporting surface.

11 - aerator stems.

12 - thermostatic control unit.

13 - liquid filter.

14 - CO ₂ injector.

15 - CO ₂ catcher.

16 - ozonizer.

17 - gas equipment O ₂ .

18 - injector O ₃ or ozone-air mixture.

19 is a source of metal ions.

20 - air compressor.

21 - water heater.

22 - insolation system.

23 - contour of sheet top dressing and moisturizing.

24 is a source of ultrasound.

25 - camera door.

26 - door hinge.

27 - door latch.

28 - cam.

29 - rail.

30 - movie.

31 - pressure pipe.

32 - distribution tube.

33 - nozzle.

34 - the gatehouse.

35 - aerator fan.

36 - gasket.

37 - a glass.

38 - a partition.

39 - fitting.

h is the horizontal.

α is the angle of the camera.

A - direction of rotation of the cam.

B - direction of camera displacement.

In - direction of camera deflection.

Given the accepted notation, the presented utility model can be described as follows.

The installation should consist of stem and root zones. At the same time, it should include a chamber 1 made with the possibility of retaining liquid and fixing in its upper part of the plants or holders with them, intended for placement of roots in it, an illuminated space 2 of the stem zone located relative to it above the chamber, the volume of which exceeds the volume of the chamber 1, supporting surface 3 or surfaces that limit the external space (above and / or below, and / or from the sides - left, right, front, rear), mounting unit 4 of the camera to the supporting surface, capacity 5 with a feed a barrel connected to a liquid compressor 6 (pump) connected to a device 7 for supplying a nutrient solution in the direction of the roots located in the chamber, a drain solution node 8 of the nutrient solution after its possible contact with the roots, connected to the tank, an artificial illuminator 9 stems with a fastening of 10 to supporting surface, aerator stems 11, thermostatic unit 12 of the outer space of the chamber.

The camera should be made in the form of a pipe muffled at the ends with through holes in the upper part of the side surface, while in the lower part of the side surface the pipe should have a tightly closing door 25 extended along its axis.

The said door should be made of a fragment of the chamber with an area approximately equal to half the area of the lateral surface of the latter and at the same time it should be swing open (but not to the end - the camera should have a special emphasis), for which it should be attached to the camera using hinges 26 (for example , such as grand pianos), while in a tightly closed state it must be held by at least one latch 27 (for example, a lever clamping patch latch fixing).

By means of the mounting unit, the pipe must be positioned so that the deviation of its axis from the horizontal h does not exceed ± 15 ° (angle α).

The attachment unit must be a system of suspending the camera to the surface and at the same time it must be capable of temporarily changing the position of the camera — its displacement or, in other words, deviation (arrow B), while ensuring the possibility of independent restoration of the camera’s initial position in space (for this flexible suspension, hinged mounting of the camera to the suspension, and other structural elements).

Additionally, the installation may include at least one of the following devices: a liquid filter 13 (mainly performing a disinfecting function), a CO ₂ 14 injector and / or associated gas equipment, CO ₂ 15 trap, ozonizer 16, O ₂ 17 gas equipment, 18 O injector ₃ or ozone-air mixture, a source of metal ions (silver) 19, an air compressor 20, a water heater 21, an insolation system 22, a sheet feeding and humidification circuit 23; ultrasound source 24.

The fastening unit can be made with the possibility of a) periodically changing the deviation of the camera axis from the horizontal in the direction of arrow B (for which, for example, at least one of the suspensions can be attached to the eccentric cam 28 rotating in the direction of arrow A) with a frequency from one cycle of several seconds to one cycle per day - two and b) changes in the stationary position of the camera to its new stationary position (for this it can include, for example, rails 29 or other guides, for example, translational motion, and the suspension can be attached to the roller am 30).

A pressure pipe 31 can be connected to the liquid compressor with a distribution pipe 32 connected to it located in the chamber (to prevent leakage into the external space).

Nozzles 33 may be connected to the distribution tube (preferably, the number of nozzles should be equal to or greater than the number of plants) and at the same time, the guards 34 (for example, made of wire) are located in front of the nozzles in such a way that one part of them comes out of the nozzles when their work is a solution or aerosol, while the other part (being, for example, rigidly connected to the first one) is located outside the chamber.

The nozzles in the chamber (in order to prevent splashing of the nutrient solution outside) should preferably be directed towards the hinges of the door (not towards the latch).

The installation may also include gas equipment O ₂ 17 or an air compressor 20, while the device 7 for supplying a nutrient solution should include nozzles 33 and the latter should be powered by both the equipment and / or compressor mentioned here and the liquid compressor 6.

The installation may include a CO ₂ 15 trap located in the upper part of the chamber and representing a tray with high translucent walls, in the lower part of which there is a fan of the aerator of stems 35, configured to periodically turn on / off (for example, connected to a timer).

The installation may further include a source of metal ions 19, which is made submersible and placed inside the working volume of the tank 5.

The installation may also include several similar to each other cameras located side by side at different levels vertically and offset from each other horizontally (figure 4).

As a camera, a plastic cylindrical pipe with local profile deviations within 10% of the diameter can be used; in another design, the camera can be assembled (composed) of tees, revisions, etc. In this case, the value of the diameter of the pipe can lie in the range from 110 to 476 mm.

Through holes in the upper part of the chamber along their perimeter may include elastically deformable gaskets 36 - inserts into which shallow glasses 37 of elastically deformable material can be inserted.

Capacity 5 can be installed under the camera - below the level of the latter, while it may include and / or: measuring tanks; level; a stirrer; piping system with nozzles; consumable taps; valves.

The installation may also include a localized or distributed (with spatially distributed controls in accordance with the location of certain blocks) apparatus for manually controlling the operating modes of its blocks.

The installation may include sensors (for example, СО ₂ , О ₃ , humidity, temperature) connected to the apparatus for automatically controlling the operating modes of its units.

The drainage unit 8 may include a siphon drain, preferably with a filter 13 that cuts off mechanical impurities.

The drainage unit can be attached to the camera in two places (from the front and rear ends - thus, with one tilt of the camera during its periodic swing, the drain will be carried out in one place, and with another in another).

The camera may include partitions 38 (preventing the weaving of the roots of various plants) by at least one less number of through holes. In this case, the partitions can be made removable, as well as from mesh material.

The installation may include additional feed circuits into the chamber of the nutrient solution.

The pipes can be made of opaque material.

The pressure pipe may approach the end of the chamber, in the cap of which the fitting 39 can be located.

The operation of the presented model is as follows.

Previously obtained seedlings are placed in the holders of the chamber - one plant in each of the holders.

The components of the nutrient mixture previously dissolved in a small amount of water are loaded into the container, add water to the marked level and mix using a mixer. Then open the feed valve, connect the liquid compressor.

Set the compressor operation mode, for example, 2 minutes of feeding the nutrient solution 2 times per hour throughout the day.

At the same time, the operating mode of the artificial illuminator is adjusted, for example, during the initial growing season (development of the leaf apparatus) for 16 hours, the photoperiod with pulsed illumination of 10 ^-5 s pulse / 10 ^-1 s pause. The suspension height of the artificial illuminator, which is optimal in terms of the green mass of the plants, is also established. During plant growth, this height is changed accordingly.

In the case of an insolation system, an artificial illuminator is used as an additional source of illumination to increase the photoperiod and / or enhance illumination.

They include all the equipment necessary for plant life support.

The nutrient solution begins to flow through the pipe into the chamber through the nozzles, while air may be mixed with it for more intensive atomization. Thus, the nutrient solution washes the roots of plants. Gradually, he begins to accumulate at the bottom of the cell.

To carry out the discharge of the nutrient solution from the chambers, a fastener is used, for example, by means of the cam mechanism, the angle of inclination of the chambers relative to the horizontal is changed. Thus, the nutrient solution that drains into the drainage unit through a siphon drainage enters the pipeline, where the mechanical filter passes and returns to the tank.

The operating mode of the mounting unit is adjusted in accordance with the operating mode of the liquid compressor.

Also, if available, a CO ₂ injector is included during the photoperiod, the use of which is advisable with the simultaneous use of a CO ₂ trap.

The state of the root system, as well as tuberization, is controlled by opening the door. The collection of tubers is also carried out by opening the door.

As already noted, the technical result from the use of the presented installation lies in the possibility of using in its construction and upgrade of commercially available highly reliable plastic products. Indeed, because the wall thickness of the latter (for example, sewer pipes) exceeds 3 mm, which is quite sufficient from the point of view of strength calculation of the presented design of the installation.

Using the door described above allows significantly reduce the laboriousness of the installation maintenance by about four times compared with the prototype.

Using the entire set of distinctive features of the presented utility model also allows us to bring the number of vegetation, for example, potatoes (when growing minicubers) to 4-5 per year (ease of access to the tuberous zone allows you to make higher demands on the different sizes of the minicubers collected and interrupt the vegetation in a timely manner) and reduce the specific installation area to 0.02 m ² / plant (potato) with a single-tier arrangement of chambers.

The specified technical result was confirmed in the course of experimental work at the Exciton OJSC, Pavlovsky Posad in 2010-2012, on a plant with an area of about 1 thousand m ² .

Claims (25)

1. Installation for growing plants using the methods of aero- and hydroponics, consisting of stem and root zones, characterized in that it includes the following functional blocks: 1) made with the possibility of fluid retention and fixation in its upper part of the plants or holders with them camera intended for placement of roots in it; 2) the upper part of the lateral surface of the chamber, which determines the position of the illuminated space of the stem zone external to the camera, the volume of which exceeds the volume of the chamber designed to accommodate the stems; 3) a supporting surface or surfaces that limit the external space; 4) a unit for attaching the camera to the supporting surface; 5) a container with a nutrient solution connected to 6) a liquid compressor connected to 7) a device located in the chamber for supplying the nutrient solution in the direction of the roots; 8) the node of the drain of the nutrient solution after its possible contact with the roots, connected to the tank; 9) an artificial illuminator for stems with 10) fastening to a supporting surface; 11) aerator stems; 12) the unit for temperature control of the outer space, while the camera is made in the form of a pipe muffled at the ends with through holes in the upper part of the side surface and with a door extended along the pipe located in the lower part of the side surface, while the pipe is located so so that the deviation of its axis from the horizontal does not exceed ± 15 °. 2. Installation according to claim 1, characterized in that it further includes devices selected from the list: 13) a liquid filter; 14) a CO ₂ injector and / or associated gas equipment; 15) CO ₂ catcher; 16) an ozonizer; 17) gas equipment O ₂ ; 18) an injector of O ₃ or ozone-air mixture; 19) a source of silver ions; 20) air compressor; 21) water heater; 22) insolation system; 23) the contour of leaf feeding and moisturizing; 24) the source of ultrasound. 3. Installation according to claim 1, characterized in that the door is made of a fragment of the chamber with an area approximately equal to half the area of the lateral surface of the latter, while the door is swing open for which it is attached to the chamber by means of hinges, while at least one of them holds it in the closed state latch. 4. The installation according to claim 1, characterized in that the mounting unit is a system of suspending the camera to the surface, while it is configured to temporarily change the position of the camera - its displacement or otherwise deviation, while providing the ability to independently restore the original position. 5. Installation according to claim 1, characterized in that the mounting unit is configured to periodically change the deviation of the camera axis from the horizontal with a frequency of from one cycle in several seconds to one cycle per day. 6. Installation according to claim 1, characterized in that the mounting unit is configured to change the stationary position of the camera. 7. Installation according to claim 1, characterized in that a pressure pipe is connected to a liquid compressor, to which a distribution tube is located located in the chamber. 8. The installation according to claim 7, characterized in that the nozzles are connected to the distribution tube, while the guards are located in front of the nozzles in such a way that one part of the nozzles leaves the nozzles or aerosol leaving the nozzles during their operation, while the other part located outside the camera. 9. Installation according to claim 8, characterized in that the nozzles in the chamber are directed towards the hinges. 10. Installation according to claim 1, characterized in that it includes gas equipment O ₂ or an air compressor, while the device includes nozzles and the latter are powered by the equipment and / or compressor mentioned here, as well as the liquid compressor mentioned earlier. 11. Installation according to claim 1, characterized in that it includes a CO ₂ trap located above the upper part of the chamber and representing a tray with high translucent walls, in the lower part of which there is a fan of stems aerator, made with the possibility of periodic on / off. 12. Installation according to claim 1, characterized in that it includes a source of silver ions, which is immersed and placed inside the working volume of the tank. 13. Installation according to claim 1, characterized in that it includes several chambers similar to each other, located side by side at different levels vertically and offset from each other horizontally by a distance commensurate with the radius of the vegetative mass of plants. 14. Installation according to claim 1, characterized in that a plastic cylindrical pipe with local profile deviations within 10% of the diameter is used as a camera. 15. Installation according to 14, characterized in that the pipe is used with a diameter of 110 to 476 mm. 16. Installation according to claim 1, characterized in that the through holes in the upper part of the chamber along their perimeter include elastically deformable gaskets-inserts. 17. Installation according to claim 1, characterized in that shallow glasses of elastically deformable material are inserted into the through holes in the upper part of the chamber. 18. Installation according to claim 1, characterized in that the tank is installed under the camera - below the level of the latter, while it includes and / or measuring tanks, level, mixer, piping system with pipes, consumables, valves. 19. Installation according to claim 1, characterized in that it includes a localized or distributed apparatus for manual control of the operation modes of its blocks. 20. Installation according to claim 1, characterized in that it includes sensors connected to an apparatus for automatically controlling the operating modes of its units. 21. Installation according to claim 1, characterized in that the drainage unit includes a siphon drain, preferably with a filter of mechanical impurities. 22. Installation according to claim 1, characterized in that the drain assembly is attached to the camera in two places. 23. Installation according to claim 1, characterized in that the camera includes partitions of at least one less number of through holes. 24. Installation according to claim 1, characterized in that the partitions are removable. 25. Installation according to claim 1, characterized in that the partitions are made of mesh material.

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