CZ309929B6 - Multi-functional mobile modular container monobloc for water treatment - Google Patents

Abstract

The multi-functional mobile modular container monobloc (1) of water treatment technology consists of a mobile container (2) formed by structural framework (3) where the supporting frame (4) of the structural framework contains the water treatment plant technology (7) and a service retractable module (6) and a structural framework superstructure (5). The structural framework (3) with the supporting frame (4) of the structural framework and the structural framework superstructure (5) is insertable in/removable from the mobile container (2). The service retractable module (6) is insertable in/removable from the structural framework (3). The supporting frame (4) of the structural framework holds the water treatment plant technology (7) consisting of the modular system of interconnected tanks, dosing system, containers, pumps, filtration and sorption technologies, including the superior automated control (27) and electric switch cabinet (28). The inputs and outputs of the water treatment plant technology (7) pass through the supporting frame (4) of the structural framework.

Description

Multifunctional mobile modular container monoblock for water treatment

Field of technology

The solution concerns a multifunctional mobile modular container monoblock of a surface and groundwater treatment plant, with the effect of containerized and stationary use of complex technology by pulling it out of the container, simultaneously with the ability to cascade connection of separate technological blocks to obtain treated water media in large volumes with an efficiency of 99% of treated drinking water .

Current state of the art

There are a large number of water treatment technologies for drinking water in the world, always with an orientation to the type of incoming raw water.

A thorough analysis of the incoming raw water is always necessary, which, together with the conditions and the environment, determines the type and parameters of the treatment technology used.

Purpose-built solutions for systems of combined drinking water treatment plants must meet a number of different legislative standards for the intended destination of use. At the same time, all negatives and positives must be determined when choosing a technology from its individual manufacturers to achieve an optimal finishing process.

For example, Lenntech B.V. (https://www.lenntech.com) deals with the production of water treatment plants for almost all types of applications. It also uses a modular system that enables different technological settings according to the type of customers and sources of raw water - including seawater treatment. In the case of a container solution, front and side door exits, a roof hatch and a floor drain are used. The area with chemical technology is separated from the basic technology of the treatment plant.

The company ASIO TECH, spol. s.r.o. (https://www.asio.cz) has products with wide application in the field of water management, where, in addition to the technology of water treatment plants, it also deals with the development and supply of wastewater treatment plants. In its portfolio, it has small and large water treatment plants for both emergency and permanent use, in both mobile and stationary versions. The filtration technology for treating raw water into drinking water is multi-stage with a fully automated control system. Filtration stages are optional and include pre-filters and mechanical filters, coagulation with flocculation, ultrafiltration or nanofiltration, sand filter, activated carbon filter, UV sterilization and final chlorination. Container equipment is supplied in standard warehouse or ISO containers. The construction of water treatment plants is always made to order and is subject to changes depending on the quality of the water.

Neither the above-mentioned manufacturers, nor other significant companies that develop and produce similar treatment technologies (for example EUROWATER, WATEX and AQUAREX) use the positives and effects of the technological solutions presented by us. For example, highly progressive filter ceramic membranes with their automated physical and chemical flushing, with the advantage of filtering more polluted waters with 99% efficiency of treated water - i.e. almost without the production of waste water.

Their design does not allow multifunctional use both in a mobile container and when extending the technology for stationary installation. It does not allow the operative cascade connection of multiple treatment plant blocks via frontal inputs and outputs. In the case of requirements for the treatment of large volumes of water, a retractable service module expanding the loading area with supporting accessories and operating the control system is not used, ensuring continuous internal air conditioning,

- 1 CZ 309929 B6 with an automated process of replacing activated carbon from a gau-filter, using a multi-chamber mixing flocculator for the treatment of more polluted water, in combination with the use of a linear tube flocculator due to the multifunctionality of the system, optimization management with a control system to continuously ensure the required output quality water independently of changes in turbidity and some other changes in the chemical composition of the input raw water.

Therefore, there is no known design solution with the effect of replacing the tubular flocculator, with a new spatial solution, for a multi-chamber mixing flocculator for the treatment of more polluted raw water in symbiosis with a system that enables continuous maintenance of the quality of the output water even when the quality of the raw water changes. In addition, none of the listed manufacturers achieves the effect of placing treatment technology in the space of a 20-foot ISO container while ensuring the necessary output water quality with an output of 10 m ³ /hour.

The company ENVI-PUR, s.r.o. (https://www.envi-pur.cz) produces mobile water treatment plant technology for independent and mobile locations. The produced water treatment plants are also oriented for emergency drinking water supply, crisis situations and integrated rescue systems - with operative provision of drinking water from almost any surface and underground water. The modular system solution offer enables different settings of the water treatment plant technology according to the types of customers and different sources of raw water from surface or underground water. The filtration technology for treating raw water into drinking water is three or more stages with an automated control system. This manufacturer is almost the only one that uses highly efficient ceramic membranes with the advantage of 99% efficiency at the output of the treated water.

In the mobile version of the treatment plant technology, however, it does not use a separate retractable support frame with a completely built-in technological block of the treatment plant with the possibility of combining a mobile and a stationary version at the same time. It does not include the connection of one input/output (end point at the head of a separate supporting frame or container), including the advantage of the cascade connection of several treatment plant technological blocks precisely through the mentioned front inputs and outputs. Furthermore, it does not contain a modular partition for the security of technology and easy operation, service, and also does not contain a retractable service module for hygienic security of service workers with secondary security and a number of other technological and structural elements mentioned above according to the proposed solution.

The company Aqua Global s.r.o. (https://www.aquaglobal.cz) offers products and solutions in the field of water filtration and treatment. Container mobile water treatment plants are designed to quickly obtain drinking water from wells, open sources, shore wells, sea and brackish water. They provide and ensure clean drinking water for permanent and emergency provision of drinking water according to hygiene standards. Container water treatment plants can also be used for water treatment in industrial applications (tertiary wastewater treatment, production of ultra-pure water, etc.). Water treatment systems are built into 10', 20' and 40' ISO containers equipped with internal insulation with permanently installed water treatment plant technology using anchoring elements. Another option is to place the complex technology of the water treatment plant in a special frame with a plug & play connection system for quick installation and immediate start-up. The container is insulated as standard with a platform plate on the floor and one connecting inlet and outlet. Each container treatment plant is a unique system designed and manufactured according to the specific specifications and requirements of the customer and is subject to changes depending on the quality of the water. The company manufactures mobile water treatment plant technologies for both stationary and mobile locations. The filtration technology for treating raw water into drinking water is three or more stages with a fully automated control system. Filtration stages are optional and include pre-filters and mechanical filters, coagulation with flocculation, ultrafiltration or nanofiltration, sand filter, activated carbon filter, UV sterilization and final chlorination.

The technological solution for flushing sorption filters is ensured by using treated water and air.

Aqua Global's product offering does not include a container solution of a mobile water treatment plant with a modular partition for the safety of the technology and easy operation, service and

- 2 CZ 309929 B6 also does not contain a retractable service module for hygienic security of service workers with secondary security. The solution offer does not include microfiltration ceramic membranes, which have a higher lifetime and mechanical resistance compared to nanofiltration or ultrafiltration membranes, and does not include technology for operative flushing of membranes using air. At the same time, it does not use the effect of frontal inputs and outputs with the advantage of cascading multiple technological blocks through these frontal outputs, nor the effect of combining the container mobile version and the stationary version of using complex technology with an operative pull-out mechanism outside the container and a number of other advantageous technological elements mentioned above, according to the proposed solution.

None of the manufacturers take advantage of the modular interchangeability of the linear tube flocculator with the stirring multi-chamber flocculator. At the same time, there is no known technological monoblock that enables such a high level of performance intensification in a small space as the solution presented by us.

In the field of patents, CN 103086543 A, CZ 15277 U1, US 8486275 B2 and US 20140091041 A1 appear to be the closest to our proposed solution.

The proposed solution according to the invention CN 103086543 A contains a wide portfolio of partial technologies such as tube flocculators, ultrafiltration membranes and other types of filters, disinfection and other technological components. This is a specific arrangement of classic technological elements of finishing technologies, where several classic finishing blocks of the above solution are included as variants. However, it does not have the vast majority of advantageous technological arrangements of the solution presented by us.

The solution within CZ 15277 U1 specifies a water treatment plant operating on the basis of a system of pressure filters and a GAU pressure sorption filter, supplemented by water disinfection with UV radiation and sodium hypochlorite. The device is placed in a frame that can be inserted into a standard shipping container. However, the structural solution and spatial arrangement does not allow for the full use of this technology in the shipping container and lacks a large part of the technological solutions and advantages of our proposed solution.

The solution presented in US 8486275 B2 is based on several sub-technologies of water purification using ozone, oil-water separation, mixed filter, membrane filter, activated carbon, reverse osmosis and oxidation. According to the water quality parameters, the control system itself selects partial cleaning technologies so that the water is cleaned efficiently, quickly and without some unnecessary cleaning phases. This technological system uses several technological blocks identical to the proposed technology, but in diametrically different connections from the proposed solution, it does not contain the vast majority of synchronizing technological elements, and for the purpose of the treatment process, this technology is directed to a different area of the chemical composition of raw water.

US 20140091041 A1 mainly deals with the internal architecture of a container with a retractable frame enabling the installation of various water treatment technologies in a modular manner according to the quality of the incoming water and the customer's demands for the quality of the treated water. First of all, it is a robust construction of an air-conditioned container, and secondly, it is about modularity, where, according to the requirements for the quality of the treated water, partial treatment technologies can be implemented into it, and it is also possible to monitor the function of the entire system remotely. This technology is diametrically different from the proposed solution (apart from a few chronically known technological links), both technologically and in terms of focus.

On the world market, there is a complete lack of a container solution for a mobile water treatment plant with a separate extendable support frame containing the complete technology of a water treatment plant for a separate static location or for the application of placing it in/out of a container, both for transport purposes or as a complex modular solution, as well as the possibility of connecting one input/output ( end point) v

- 3 CZ 309929 B6 fronts of a separate supporting frame or container with a combination of an implemented modular partition to ensure the safety of the technology and easy operation, service and a retractable service module ensuring, first of all, the expansion of the technological part by an additional service space and, secondly, for the hygienic security of service workers with secondary security and at the same time a technological solution for flushing ceramic membranes and sorption filters using treated water and air, and further in a combination of hydraulic and mechanical system enabling the emptying and filling of regenerated reactivated granular activated carbon for reuse in sorption filters.

The essence of the invention

The aforementioned disadvantages are eliminated by the multifunctional mobile modular container monoblock of water treatment technology, the essence of which is that it consists of a mobile container formed by a supporting skeleton with a supporting frame of the skeleton containing the technology of the water treatment plant and an operating pull-out module and superstructure of the supporting skeleton, while the supporting skeleton with a supporting frame of the skeleton and the superstructure of the supporting frame is insertable/extendable into/from the mobile container, while the service extendable module is insertable/extendable into/from the support frame, while the mobile container is equipped with an adjustable base system on the lower surfaces of the corners, while in the front part of the floor it is further equipped with front with adjustable traveling rollers and in the rear part of its floor it is equipped with rear adjustable traveling rollers, while vertical rollers are placed on the outer structure of the supporting frame for rolling on the inner side surfaces of the mobile container, while the front face of the supporting frame is formed by a modular entrance partition, with an entrance door and a door electric power distribution box and superior automated control, while a mixing chamber flocculator containing a flocculation chamber divided by partitions into chambers is placed on the support frame, while the mixing chamber flocculator is fitted with an electric motor, a multiple agitator equipped with turbine agitators with blades and a dividing disc, while the operating pull-out module is equipped with a pull-out in its lower part and guide rolls in its upper part, while the guide rolls are attached to the upper corner parts of the structure of the service pull-out module, while the inputs and outputs of the water treatment plant technology pass through the front of the supporting frame of the skeleton, which are formed by the input pipe of the raw water source , the drinking water outlet pipe, the uncontaminated water outlet waste pipe, the waste pipe and the drain channel, while the supporting frame of the skeleton holds the technology of the water treatment plant, which is made up of a modular system of interconnected tanks, a dosing system, vessels, pumps, filtration and sorption technologies, disinfection device, including the superior automated control and electrical power distribution box, while the raw water storage tank is located in the front part of the support frame of the skeleton, which is connected on one side to the inlet pipe of the source of raw water, located on the front side of the support skeleton and woven into its bottom the part connected to the pump, while it is further connected to the raw water storage tank equipped with a level sensor through a pipe, also connected to the submersible abrasive pump, while a turbidity meter and flow meter are connected to the raw water source inlet pipe, while part of the route between the modular inlet partition and the storage tank of raw water is a regulating diaphragm valve and a pressure gauge, when on the other side it is connected to the first pump, which is further connected to a mechanical basket filter, equipped with a basket with bag filters, located on a separate supporting element with mounting to the foot of the support frame of the skeleton, while on the mechanical bag filters of the mechanical basket filter, a homogenizer is connected, which is connected to the dosing pump of the pH regulator and the coagulant dosing pump and is located on the storage barrel of the sodium hypochlorite dosing pump, while it is further connected to the tubular flocculator located on the side and under the ceiling part of the support frame of the skeleton, whereas microfiltration ceramic membranes are located near the tubular flocculator, which are connected to it, while the microfiltration ceramic membranes are located between the flushing pressure vessel and the treated water tank, while the microfiltration ceramic membranes are fitted in their upper part with a pipe connected to the compressed air-compressor circuit unit with an air reservoir for the use of the dryer and further fitted with a pipe connected to

- 4 CZ 309929 B6 a tank of treated water, while in the lower part the microfiltration ceramic membranes are connected to a tubular flocculator and a waste pipe, which further connects to the output waste pipe of uncontaminated water, while a level sensor is located in the upper part of the tank of treated water, while the tank of treated water is connected in its lower part on one side to the second flushing pump, which is further connected by a pipe to the flushing pressure vessel and to the third pump, which is further connected by a pipe to the sorption pressure vessels, and is further connected in its lower part on the other side to the waste pipe, which is connected to the outlet waste pipe of uncontaminated water, while the treated water tank is simultaneously connected via the pipe to the fourth potable water distribution pump, which is connected to the treated potable water tank equipped with a level gauge, while the treated potable water tank is via the second flushing pump connected by a pipeline to the upper part of the microfiltration ceramic membranes, while the pipelines of the sulfuric acid dosing pump, the sodium hypochlorite dosing pump and the sodium hydroxide dosing pump are connected to the hydrostatic mixer located in this pipeline, while the sorption pressure vessels are fitted with a pipeline through which they are connected to the inlet of the UV reactor , while in their lower part they are connected to an air pipe, which is further connected to an air compressor with an air reservoir, in their upper part they are connected to a waste pipe connected to the output waste pipe of uncontaminated water, while the UV reactor is located above the tank of treated drinking water and by connecting the dosing nozzle of the sodium hypochlorite dosing pump for drinking water to the pipe route leading to the treated drinking water tank, while it is fitted with a pipe connected to the sorption pressure vessels at its inlet and connected to the treated drinking water tank equipped with a level gauge connected to a third pump at the outlet via a pipe and further with a connection to the outlet pipe, whereby the treated drinking water tank is connected to the fourth potable water distribution pump via the pipe, while the fourth potable water distribution pump is simultaneously connected to the potable water outlet pipe via the pipe.

Furthermore, it is advantageous if there are two front adjustable travel rollers and two rear adjustable travel rollers.

Furthermore, it is advantageous if there are two microfiltration ceramic membranes.

Furthermore, it is advantageous if four pieces of electrodes are placed in the flushing pressure vessel and there is a tubular level indicator on the side of the flushing pressure vessel.

Advantages of the solution:

• High filtration efficiency - up to 99% - 0.5 to 1% waste water - effect from the use of ceramic membranes.

• Modular interchangeability of tubular linear flocculator (less polluted water) for multi-chamber mixing flocculator (more polluted water).

• High intensification - great performance in a small space - there are no finishing technologies with a performance of 10 m ³ /hour. located only in the space of a 20-foot container, an analog level of technology only in the space of a 40-foot ISO-container.

• Multifunctional solution - separate stationary placement inside technical and technological buildings - at the same time after being inserted into standard ISO-containers for permanent use of technology as well as temporary transport purposes.

• Modularity by modifying the cascading arrangement of the mobile modular container block even when it is placed in a separate stationary building.

- 5 CZ 309929 B6 • The ability to deploy in highly different temperatures of the external climate - with the advantage of controlling the system from the outside - ensuring full air conditioning of the interior space.

• The modifiability of assembly procedures of individual technological elements - modules using the quick assembly system of the supporting frame.

• The extendable service module significantly expands the storage area of the monobloc - it increases the placeability of supporting accessories.

• The system of generalization of all pipe inputs and outputs in one frontal module of the basic supporting frame with the advantage of providing external engineering - the effect of multiples of the performance of cascaded individual monoblocks of treatment plant technology, unlimited increase in the output of drinking water production.

• Modular intermediate partitions with the possibility of connecting technologies and a control panel.

• An innovative solution for access to the interior spaces of the technology through a modular partition providing primary security and assurance of the air-conditioned space compared to the outside environment (the interior air-conditioned space is thus separated from the outside space even when the container door is open).

• Retractable module from the support frame to ensure technology management and operation, including secondary security.

• Operative extension and insertion of a complex container monobloc into the inner spaces of the container by means of transport rollers.

• New layout solution for inserting the drainage channel in the floor of the supporting skeleton.

• Mechanical and simultaneously electronic security.

• Air conditioning of the interior space with the effect of using interspace modular partitions even when the container doors are open.

• Connection to external engineering in one place.

• Connection to a secondary or redundant power supply from renewable sources.

• High ability to deploy in different climatic conditions of the external or internal environment while maintaining constant climatic parameters of the internal space of the technology.

• Due to the location of the tubular flocculator on the sides and ceiling of the supporting frame, a significant saving of space is achieved compared to other devices for performing flocculation and coagulation while achieving comparable results.

Clarification of drawings

Figures and legend are shown on the attached sheets.

Giant. 1 General axonometric view of a mobile modular container monoblock of water treatment technology.

- 6 CZ 309929 B6

Giant. 2 View of the internal arrangement of the technological elements of the container monoblock.

Giant. 3 Detailed view of a partial part of the internal technology of the water treatment plant with a link to the mobile container.

Giant. 4 A detailed view of part of the internal technology of the water treatment plant with the capture of the flushing pressure vessel and microfiltration ceramic membranes.

Giant. 5 A detailed view of part of the internal technology of the water treatment plant with the capture of the tube flocculator, the air reservoir and the treated water tank.

Giant. 6 View of part of the internal technology of the water treatment plant with links to the mobile container.

Giant. 7 Detailed view of a partial part of the internal technology of the water treatment plant with reference to the elements of the mobile container.

Giant. 8 A detailed view of a partial part of the internal technology of the water treatment plant with the capture of the sorption pressure vessel.

Giant. 9 A detailed view of a partial part of the internal technology of the water treatment plant with the capture of the sorption pressure vessel.

Giant. 10 Top view of a partial part of the internal technology of the water treatment plant with connection to the mobile container.

Giant. 11 Top view of a partial part of the internal technology of the water treatment plant with a link to a mobile container.

Giant. 12 Axonometric view of the construction of the mobile container with the capture of the service extendable module in the extended position.

Giant. 13 View of the structure of the supporting skeleton of the mobile container, including the capture of the tubular flocculator.

Giant. 14 Longitudinal section of the supporting skeleton of a mobile container with the capture of a tubular flocculator and the technology of anchoring and handling elements.

Giant. 15 General axonometric view of a mobile modular container monoblock of water treatment technology.

Giant. 16 Axonometric view of the basic elements of the internal technology of the water treatment plant.

Giant. 17 Detailed axonometric view of a partial part of the internal technology of the water treatment plant with capture of the flocculation chamber.

Giant. 18 Top axonometric view of a partial part of the internal technology of the water treatment plant with connection to a mobile container.

Giant. 19 Top axonometric view of water treatment plant technology.

Giant. 20 Axonometric view of a partial part of the supporting skeleton of a mobile container with capture of the technology of anchoring and handling elements.

Giant. 21 General axonometric view of the supporting skeleton of a mobile container with capture of the technology of anchoring and handling elements.

- 7 CZ 309929 B6

Giant. 22 Longitudinal section of the structure of the supporting skeleton of a mobile container.

An example of the implementation of the invention

The multifunctional modular container monobloc 1 of the water treatment technology consists of a mobile container 2 sized for the insertion/extension of the support skeleton 3 with the support frame 4 of the skeleton and the superstructure 5 of the support skeleton, with the fact that it is dimensioned for the insertion/extension of the service retractable module 6, while it is in technology 7 of the water treatment plant is placed in the inner space of the supporting frame 3.

The mobile container 2 is equipped with an adjustable pedestal system 20 on the lower surfaces of its corners, in the front part of the floor it is further equipped with a pair of front adjustable travel rollers 15 and in the rear part of its floor it is equipped with a pair of rear adjustable travel rollers 15' for sliding in/out of the supporting frame 3, with the fact that on the outer structure of the support skeleton 3, the guide side vertical rollers 16 of the support frame of the skeleton are placed. The mobile container 2 is equipped on all its internal surfaces with insulating panels 11 of the inner side walls of the mobile container 8 and insulating filling 12 of the floor of the block of the mobile container 8.

The front face of the supporting skeleton 3 is made up of a modular insulated entrance partition 9, with an entrance security door 10 and a door of the distribution box 28 of electrical power and superior automated control 27 of the complete technology of the multifunctional modular container monoblock 1, while the modular insulated entrance partition 9 is equipped with technology 25 from the outside sanitation, electric sockets with switches 26 and motion sensor 24.

A mixing chamber flocculator 72 containing a flocculation chamber 71 divided into chambers by partitions is placed on the support frame 3, while the mixing chamber flocculator 72 is equipped with an electric motor 73 with a frequency converter and a gearbox with a shaft seal, a multiple mixer equipped with turbine agitators with blades and a dividing disc 74.

The service pull-out module 6 is equipped with a modular floor 13, and the structure of its walls and ceilings is fitted with insulation panels 14 of the pull-out module, while the service pull-out module 6 is fitted in its lower part with a ball multi-element slide 17 and in its upper part with guide rolls 18. At the same time, on the outer on the lower side, in the front corners, it is equipped with manually adjustable support brackets 21 and on the outer front side, it is equipped with mobile entrance steps 22. Guide rolls 18 are attached to the upper corner parts of the structure of the service pull-out module 6. The front face of the service pull-out module 6 is equipped with revolving lattice doors or other doors .

The inputs and outputs of the raw water source input pipe 29, drinking water output pipe 30, uncontaminated water output pipe 31, waste pipe 47 and drain channel 32 are brought into the front of the supporting frame 4_skeletu from the technology 7 of the water treatment plant.

In the supporting frame 4 of the skeleton, through a combination of anchoring elements 19 and anchoring feet 23 with damping, the technology 7 of the water treatment plant is attached, which consists of a modular system of interconnected tanks, a dosing system, vessels, pumps, filtration and sorption technologies, disinfection equipment, pipe systems, and other technologies, including the superior automated control 27 and the distribution cabinet 28 of electrical power.

In the front part of the supporting frame 4 of the skeleton, there is a storage tank 36 of raw water, which is connected on one side to the inlet pipe 29 located on the front side of the supporting skeleton 3 woven into its lower part and connected by fire hoses to an external submersible abrasive pump 33 and using the pipe it is connected to a raw water storage tank 36 equipped with a continuous ultrasonic level sensor 37, mounted in a cantilever lid holder

- 8 CZ 309929 B6 storage tank 36 also connected by communication with a submersible abrasive pump 33, while a turbidity meter 40 and a flow meter 41 are connected to the inlet pipe 29 of the raw water source.

Part of the route between the modular insulated inlet bulkhead 9 and the raw water storage tank 36 is a regulating membrane valve 34 and a pressure gauge 35, when on the other side it is connected to the first pump 38 with a frequency converter, which is further connected to a mechanical basket filter 39, equipped with a stainless steel basket with bag filters, located on a separate support element with assembly to the prepared base of the support frame 4 of the skeleton.

A homogenizer 42 is connected to the mechanical bag filters of the mechanical basket filter 39 via a fitting line, which is connected from the side to the dosing pump 44 of the pH regulator and the dosing pump 45 of the coagulant and is located on the storage barrel of the sodium hypochlorite dosing pump 50 and is further connected to the tube flocculator 43 suspended using anchoring elements 19 on the side and under the ceiling part of the supporting frame 4_skeletu. A pair of microfiltration ceramic membranes 46 is located in the immediate vicinity of the tubular flocculator 43, with the possible application of a device for CIP 66 with a circulation pump 68 and a collection tank 67, while the pair of microfiltration ceramic membranes 46 is connected to the tubular flocculator 43 via a fitting line and anchored to the floor of the carrier frame 4 skeleton.

A pair of microfiltration ceramic membranes 46 is located between the flushing pressure vessel 48 and the tank 52 of treated water. The pair of microfiltration ceramic membranes 46 is fitted in its upper part with a pipe connected to the compressed air circuit-compressor unit 64 with an air reservoir 65 with the possibility of using a dryer 70 and further fitted with another pipe connected to the treated water tank 52. In the lower part, a pair of microfiltration ceramic membranes 46 is connected to a tubular flocculator 43 and a waste pipe 47, which further connects to the outlet waste pipe 31 of uncontaminated water.

4 electrodes are placed in the flushing pressure vessel 48 and there is an additional tubular level indicator on the side of the flushing pressure vessel 48. An ultrasonic level sensor 53 is located in the upper part of the treated water tank 52.

The treated water tank 52 is connected in its lower part on one side to the second flushing pump 54, which is further connected by a pipe to the flushing pressure vessel 48 and to the third pump 55, which is further connected by a pipe to a pair of sorption pressure vessels 56, and is further in its lower part, on the other side, it is connected to the waste pipe 47, which connects to the outlet waste pipe 31 of uncontaminated water. At the same time, the treated water tank 52 is connected via a pipe to the fourth drinking water distribution pump 61, which is connected to the treated drinking water tank 58, equipped with an ultrasonic continuous level meter 59.

The tank 58 of treated water is connected via the second flushing pump 54 by a pipeline to the upper part of a pair of microfiltration ceramic membranes 46, while the pipelines of the sulfuric acid dosing pump 49, the sodium hypochlorite dosing pump 50 and the sodium hydroxide dosing pump 51 are connected to the hydrostatic mixer 69 located in this pipeline .

The sorption pressure vessels 56 are attached to the anchoring elements 19 and are fitted with a pipe through which they are connected to the inlet of the UV reactor 57, while in their lower part they are connected to the air pipe 63, which is further connected to the air compressor 64 with the air reservoir and in its the upper parts are connected to the waste pipe 47 connected to the outlet waste pipe 31 of uncontaminated water.

The sorption pressure vessels 56, located in the rear right part of the machine part (from the perspective of the main entrance) on the support feet, are at the same time a partial modular technological assembly, consisting of the mentioned sorption tanks and an assembly of fittings, while the placement of the fittings is divided by placing them on the support system between these tanks and suspended in the front part on the bodies of sorption pressure vessels 56

- 9 CZ 309929 B6 whereby the technology is adapted for easy handling and access to individual control elements.

The UV reactor 57 is located on the anchoring elements 19 in the upper part above the treated drinking water tank 58, and the connection of the dosing nozzle of the sodium hypochlorite dosing pump 60 for drinking water to the pipe route leading to the treated drinking water tank 58 is fitted at its entrance with a pipe connected to the sorption pressure vessel 56 and at the outlet via a pipeline connected to a tank 58 of treated drinking water equipped with an ultrasonic continuous level gauge 59 connected to a third pump 55 and further to a connection to the outlet pipe 10, while a tank 58 of treated drinking water is connected to the fourth pump 61 of drinking water distribution via a pipeline , while the fourth potable water distribution pump 61 is simultaneously connected via a pipe to the potable water outlet pipe 30 connected to the supply pipe of the water treatment plant operator. From the fourth potable water distribution pump 61, the pipe leads to the automatic pressure vessel 62, which is connected to the potable water outlet pipe 30 directly into the distribution system.

Function

Description of the function in the tubular flocculator variant

The multifunctional modular container monobloc 1 of water treatment technology is a complex technology, consisting of a mobile container 2, into which the support skeleton 3 is inserted, formed by the support frame of the skeleton 4 and the superstructure of the support skeleton 5, into which the complex technology of the water treatment plant 7 is implemented, with the , that from the front of the supporting frame 3, the operating pull-out module 6 extends in its walls with implemented insulation panels of the pull-out module 14, which in its upper part is equipped with guide rolls 18 and in its lower part with ball multi-element pull-out technology 17 to ensure its extension from of the supporting skeleton 3, after its extension, then in its front lower part it is fitted with a manually adjustable support bracket 21, equipped with anchoring feet with damping 23 and mobile entrance steps 22, when the mobile container 2 is previously set in height in the field using the adjusting pedestal system 20. module 6 serves as a pre-entrance space to the interior space of the complex technology of the water treatment plant 7, implemented in the superstructure of the supporting skeleton 5, while between the retractable service module 6 and the interior space of the complex technology of the water treatment plant 7, a modular insulated entrance partition 9 is implemented, fitted with integrated entrance safety devices through the door 10, on which a motion sensor 24, sanitation technology 25 and electric sockets with switches 26 are implemented, while in the inner space of the water treatment plant technology 7 on the right side of the entrance, behind the modular insulated entrance partition 9, an electrical power distribution box 28 with superior automated control is located 27. The modular insulated entrance partition 9 ensures the isolation of the interior space of the complex technology of the water treatment plant 7 from the external environment, including the air conditioning of the interior space of the technology of the water treatment plant 7, simultaneously with the use of insulating panels of the inner walls of the container 11, on the side inner walls 8 and insulating filling of the floor of the mobile block container 12, as a modular floor 13, with the advantage of the possibility of open doors of the mobile container 2, without a negative effect on the insulation of the inner space of the technology of the water treatment plant 7, during its operating process. This system enables the use of a complex modular container monobloc 1 for a mobile variant. In the case of using the second variant without the mobile container 2, i.e. the stationary variant, then the mobile container 2 will only be used for the transport of the complex technology of the multifunctional modular container monoblock 1 · From the mobile container 2, the complex technology of the water treatment plant 7, implemented in the supporting skeleton 3, will be pushed out. into the designated space by means of front and rear adjustable traveling rollers 15 and 15' and by means of guiding lateral vertical rollers 16, anchored in the supporting frame 4 of the skeleton.

The multifunctionality of the use of this system of two variants is due to the high degree of intensification of the technology of the 7 water treatment plant - a maximum of technological elements in a minimum space. Furthermore, it is given by the ability of cascade assemblies of individual blocks of water treatment plant technology to higher multiple treatment plant outputs, using the advantage that there are 4 skeletons to the front of the supporting frame

- 10 CZ 309929 B6 from technology 7 water treatment plant derived inputs and outputs - input pipe 29 source of raw water, output pipe 30 drinking water, output waste pipe 31 uncontaminated water, waste pipe 47 and drain channel 32. This centralization of inputs and outputs of the water medium into the frontal profile of the block of the supporting skeleton enables the general connection of individual inputs and outputs from multiple blocks of technology 7 of the water treatment plant and thus obtaining the advantage of increasing multiple treatment plant outputs with output to one output center and thus also the advantage of replacing a large-capacity water treatment plant with this technological cascade.

In the case of using the first mobile variant, in which the mobile container 2 with the implemented technology 7 of the water treatment plant remains in an isolated container, an advantage arises through the covered service and at the same time safety spaces inside the service pull-out module 6, in the upper part of which the guide rolls 18 and control are fixed by the functions of the treatment plant through the superior automated control 27 and the distribution box 28, built into the modular insulated entrance partition 9, equipped from the outside with sanitation technology 25, electrical sockets with switches 26 and motion sensor 24 and at the same time and at the same time through the entrance security door 10 allows entry into the technology area 7 water treatment plants. The inner space of the supporting skeleton 3, in which the technology 7 of the water treatment plant is implemented, thus remains isolated from the external environment while maintaining the required climatic conditions in the inner space of the supporting skeleton 3, in contrast to the vast majority of container solutions of water treatment plants, where when the container door is opened, the inner space of the technology water treatment plants 7 open compared to the external environment.

When using the second alternative, when the technology 7 of the water treatment plant is used as a stationary block outside the mobile container 2, implemented in the extendable support frame 3, it is unloaded from the mobile container 2 by being pushed out of its space by means of a pair of front and rear adjustable travel rollers 15 and 15', built into the front and back of the support frame of the skeleton 4 and through the first system of vertical guide side rollers 16 of the support frame of the skeleton, built in an optimal location on the side structure of the superstructure of the support skeleton 5 with the alternative of simultaneous use of the second system of vertical guide side rollers built directly into the side walls of the mobile container 2.

A high degree of intensification of the complex technology of the water treatment plant 7 in the limited space of, for example, a 20-foot mobile container 2, with an output of 10 m ³ of water treatment per hour, is achieved by a new spatial arrangement of the technology of the water treatment plant 7 in the supporting retractable skeleton 3, a new design solution of the tubular flocculator, which it uses the remaining spaces in the walls and ceiling of the support frame 3, with a similar effect when using the alternative design solution of the mixing chamber flocculator 72. When ensuring analogous requirements for the quantity and quality of the output water, other manufacturers use containers with multiple spaces compared to the solution presented by us. Another effect of the technology of the water treatment plant 7 is its ability to cascade - that is, the use of a number of these technologies for multiple outputs with one output of treated water. This effect is due to the technological solution of the support frame of the skeleton 4, in the inner spaces of which a complex output system of media inputs and outputs is located, which is then generalized to the face of the support frame of the skeleton 4. The subsequent connection of these front outputs of the given cascade using the technology of water treatment plants 7 enables their efficient connection to one outlet and to the treated water tank. Through the sophisticated automation of treatment plant processes and the use of new technologies to analyze and measure the quality and chemical composition of the treated media, the same quality of the output water is ensured even when the quality of the input raw water changes.

Tubular flocculator 43 with the combined solution of its spatial layout - wall and ceiling solution - effectively uses the unbuilt spaces in the support frame of the skeleton 4 and is at the same time interchangeable, in case of higher demands on coagulation processes of more polluted input media, for the mixing chamber flocculator 72 with blade segments, while maintaining the existing technology of the water treatment plant 7. The used sorption pressure vessel 56 with a filling of granulated activated carbon - gau, into which the third pump 55 with a frequency converter continuously supplies treated water, is

- 11 CZ 309929 B6 is characterized by a new design solution enabling pressurized exchange of granular activated carbon when its activation is lost, compared to current technological solutions of sorption filters, which require manual removal of granular activated carbon from the sorption pressure vessel 56.

The structure of the walls and ceilings of the service extension module 6 is fitted with insulation panels 14 of the extension module, and on the outer lower side in the front corners there are manually adjustable support brackets 21 and on the outside also mobile entrance steps 22. The mobile container itself 2 is extended from the support frame 3 /retracts via ball multi-element slide 17.

In the supporting frame 4 of the skeleton, through a combination of anchoring elements 19 and anchoring feet 23 with damping, the technology 7 of the water treatment plant is attached, which is formed by a modular system of interconnected tanks - dosing system, filtration and sorption technology, disinfection technology, pipe systems, dosing pumps - for example by the PH regulator dosing pump 44, the coagulant dosing pump 45, the sulfuric acid dosing pump 49, the sodium hypochlorite dosing pump 50, the sodium hydroxide dosing pump 51, the sodium hypochlorite dosing pump 60 for drinking water and other technologies, including the superior automated control 27 and the distribution box 28 electrical energy. In the front part of the supporting frame 4 of the skeleton, there is a storage tank 36 of raw water, which is connected on one side to the inlet pipe 29 of the source of raw water, equipped with a turbidity meter 40 and a flow meter 41 located on the front side of the supporting skeleton 3, woven into its lower part and connected by an adequate by a length of resistant fire hoses with an external submersible abrasive pump 33 and by means of a pipe it is connected to a raw water storage tank 36 fitted with a continuous ultrasonic level sensor 37 mounted in the console holder of the tank lid, also connected by communication with the pump 33. Part of the route between the modular insulated inlet partition 9 and the storage the raw water tank 36 has a regulating membrane valve 34 and a pressure gauge 35, on the other hand, it is connected to the first pump 38 with a frequency converter, which is further connected to a mechanical basket filter, equipped with a stainless steel basket with bag filters 39, located on a separate supporting element with mounting to prepared feet of the support frame of the skeleton 4.

After the raw water has been pre-treated, passing through the mechanical basket filter 39 with bag filters, the pH regulator is injected by the pH regulator dosing pump 44 and the coagulant by the coagulant dosing pump 45 through the injection units together with their electromagnetic dosing pumps. By passing a mixture of chemical agents and treated water through the homogenizer 42, the chemicals will be uniformly dispersed by the effect of the turbulent flow of the liquid, caused by the passage through the defined space of the homogenizer 42, and at the same time, the optimal formation of the seeds of flocculation precipitates in the total volume is enabled. When the mixture passes through the tubular flocculator 43, due to the frictional forces between the wall of the tubular flocculator 43 and the liquid mixture, the formation and growth of flakes occurs, which enables their further mechanical separation.

The mixture prepared in this way is directly fed to a pair of microfiltration ceramic membranes 46, where direct filtration of undissolved substances, bacteria, viruses and microbiological particles is ensured by passing through the membrane. During the filtration cycle, filtered substances and particles separate on the surface of the microfiltration ceramic membrane 46, which is manifested by an increase in the TMP transmembrane pressure. When the defined value is reached, the washing cycles are started, which in their sequence ensure the restoration of the permeability of the microfiltration ceramic membranes 46. The treated water-filtrate in this way is directly drained into the storage tank 52 of the treated water.

The water level in the treated water storage tank 52 is maintained by means of a continuous level sensor 53 and a third tank filling pump 55, which continuously drains the treated water to a pair of series-connected sorption pressure vessels 56 filled with granular activated carbon (GAU). By passing through the sorption pressure vessels 56, separation is ensured

- 12 CZ 309929 B6 of residual dissolved substances and at the same time the sensory properties of water are optimized in the form of sorption of odor, taste, color and turbidity onto activated granular carbon. The water treated in this way is then hygienically ensured by sterilization by passing through a UV reactor 57. The collection of treated drinking water is carried out in the treated drinking water tank 58 equipped with an ultrasonic continuous level meter 59. Sodium hypochlorite is dosed into the treated drinking water tank 58 by an electromagnetic dosing pump 60 so that it is treated water hygienically treated according to the national decree or WHO standards. From the treated drinking water tank 58, the treated drinking water is drained via the fourth drinking water distribution pump 61 into the outlet pipe 30 of the point of consumption, or in cooperation with the automatic pressure vessel 62 through the outlet pipe 30 directly into the distribution system.

Tubular flocculator 43 is adapted to the spatial possibilities of arranging the technology of the water treatment plant with suspension using anchoring elements 19 on the side and under the ceiling part of the supporting frame 4 of the skeleton of a defined length and with the possibility of extending or shortening the total length with regard to the flocculation process. For cleaning and maintenance of the inner walls of the tubular flocculator 43, an inspection member is placed at a defined location of the tubular flocculator 43.

The mixing chamber flocculator 72 contains a flocculation chamber 71, divided by several partitions into several chambers, equipped with an electric motor 73, with a frequency converter and a gearbox with a shaft seal, a multiple stirrer equipped with turbine agitators with blades and a dividing disc 74, while the mixing chamber flocculator 72 is placed on pedestals legs and attached to the supporting frame 3.

The container system has the technology of combined washing of microfiltration ceramic membranes 46, where part of this combined washing with pressurized water and compressed air is a separate technology for the preparation of compressed air.

Compressed air is produced using an air compressor 64 with an air reservoir to cover the disposable sampling tips. To ensure the hygienic parameters of the compressed air, the air compressor 64 is fitted with an antibacterial filter at its inlet, and the compressed air is dehumidified in a separator for subsequent distribution. The treated compressed air is fed to the partial control pneumatic fittings and, after passing through the corresponding reduction valves, also to the backwash storage tank - the backwash pressure vessel 48, ensuring the combined flushing of the microfiltration ceramic membranes 46, and at the same time it is also directly led to the microfiltration ceramic membranes 46.

Phase NBW - Normal Backwash

In the first stage, the cleaning - washing of the microfiltration ceramic membranes 46 is carried out with treated water of a defined pressure, which is supplied from the flushing pressure vessel 48. The filling of the flushing pressure vessel 48 with treated water is realized by means of the second pump 54 of flushing from the tank 52 of treated water. Together with the compressed air supplied from the air compressor 64 with the air reservoir to the microfiltration ceramic membranes 46, this is a combined method of cleaning and washing the microfiltration ceramic membranes 46, the aim of which is to break off the accumulated undesirable impurities, substances and particles trapped on the surface of the microfiltration ceramic membrane 46. In the second phase is followed by flushing only with compressed air, which is performed only on the supply side of the microfiltration ceramic membrane 46 - on the retentate side, the aim of which is to remove residual pollution. In both cases, all water evaporation, including accumulated sediments, are drained from the underside of the microfiltration ceramic membranes 46 into the waste pipe 47, which leads to the outlet waste pipe 31 of uncontaminated water.

- 13 CZ 309929 B6

CEB phase - Chemically Enhanced Backwash

Standard physical backwashes (NBW) with pressurized water and air are implemented based on the pressure loss on the microfiltration ceramic membranes 46 or time. Depending on the specifics of the filtered water and the type of contamination of the raw water, CEB rinses supported by a chemical additive can be applied, facilitating the restoration of the filtration function of the microfiltration ceramic membrane 46. When the treated water is pumped by the second rinse pump 54 from the treated water tank 52, chemical additives are injected through electromagnetic dosing pumps of sulfuric acid sulfuric acid pump 49, sodium hypochlorite by sodium hypochlorite dosing pump 50, and sodium hydroxide by sodium hydroxide dosing pump 51 into the hydrostatic mixer 69, which ensures homogenization of the ingredients in the entire volume. The mixture of chemicals and water is introduced into the microfiltration ceramic membranes 46.

The application of individual additives, their concentration and their combination is dependent on the type of pollutants removed from the surface of the microfiltration ceramic membranes 46, as well as the frequency of performing CEB.

CIP phase - Cleaning In Place

In cases where the adequate permeability of the microfiltration ceramic membranes 46 is not restored and neither standard flushing nor flushing supported by chemical agents - CEB, usually once a year, the CIP 66 flushing device is applied, which consists in the circulation and leaching of a concentrated preparation that dissolves tough and tightly adhering deposits on the microfiltration ceramic membranes 46. The choice of chemical agent depends on the type of deposit of the microfiltration ceramic membrane 46.

Flushing is carried out by a single-purpose external device for CIP 66, consisting of a reservoir of concentrated preparation, a circulation pump 68, a collection tank 67 and the respective connections to microfiltration ceramic membranes 46.

This device is used as an external device of the service organization ensuring the execution of the CIP phase.

The container system also has the technology of combined washing of sorption pressure vessels 56, where part of this combined washing of sorption pressure vessels 56 with pressurized water and compressed air is the technology itself for the preparation of compressed air, which is needed to control pneumatic fittings and at the same time as a supporting means for removing deposits of aggregates of substances adhering to granular activated carbon.

Compressed air is produced using an air compressor 64 with an air reservoir 65 to cover disposable sampling tips. To ensure the hygienic parameters of the compressed air, the air compressor unit with the air reservoir 65 is fitted with an antibacterial filter at its inlet, and the compressed air is dehumidified in a separator for subsequent distribution. Adjusted compressed air is supplied to partial control pneumatic fittings and, after passing through the corresponding reduction valves, it is supplied to the sorption pressure vessels 56 for flushing, ensuring a combined flushing of granular activated carbon.

In the first phase, the washing of the sorption pressure vessels 56 is carried out with compressed air supplied from the air compressor 64 with the air reservoir 65.

In the second phase, washing is carried out with water of a defined pressure, supplied from the storage tank 52 of treated water. Washing of the sorption pressure vessels 56 with treated water is realized by means of a third pump 55 filling the tank from the tank 52 of treated water. Washing the sorption pressure vessels 56 with treated water results in the removal of aggregated undesirables

- 14 CZ 309929 B6 impurities, substances and particles trapped on the surface of granulated activated carbon. In both cases, all waste water, including aggregate deposits, is discharged into the waste pipe 47, which leads to the outlet waste pipe 31 of uncontaminated water.

The components for low and high current are placed in a standard distribution box 28, while the location of the circuit breaker components are on consoles with appropriate cover in accordance with the legislation. The complex energy distribution system is guided by the project electrical diagram, which synchronizes with the complex superior control system.

The distribution of the treated air is realized through the air pipe 63, when it comes from the air generator thanks to the air compressor with the air reservoir 64 and is treated with the help of filters, and then through the air dryer 70 the air reservoir 65 is filled, while these main routes are conducted in PE fittings and they are then led to the individual pneumatic elements in standard hoses terminated with quick couplings. The air is continuously replenished based on the evaluation of the pressure in the storage tank using the transmission of a command from the superior automated control 27.

Description of the function in the variant of the mixing chamber flocculator 72 with the flocculation chamber 71.

The raw water intended for treatment is distributed from the water source through an external submersible abrasive pump 33 with a protective basket using fire hoses of the appropriate length from the raw water source to the inlet pipe 29 of the raw water source located on the front side in the lower part of the supporting frame 4 of the skeleton, with the possibility control of the raw water flow through the diaphragm control valve 34 following the monitoring of the pressure state using the pressure gauge 35, for pre-treatment into the bag filters of the mechanical basket filter 39 for the removal of mechanical impurities. The raw water quality is evaluated using the installed turbidity meter 40. The flow meter 41 with pulse output, which is subsequently included, provides feedback for the control system and in real time ensures the corresponding performance of the external submersible abrasive pump 33. Visual control of the pressure is made possible by the pressure gauge located on the bag filter of the mechanical basket filter 39 .

After the raw water has been pre-treated, passing through the bag filter of the mechanical basket filter 39, the pH regulator is injected by the pH regulator dosing pump 44 and the coagulant by the coagulant dosing pump 45 through the injection units together with their electromagnetic dosing pumps. By passing a mixture of chemical agents and treated water through the homogenizer 42, the chemicals will be uniformly dispersed by the effect of the turbulent flow of the liquid, caused by the passage through the defined space of the homogenizer 42, and at the same time, the optimal formation of the seeds of flocculation precipitates in the total volume is enabled. By passing the mixture through the flocculation chamber 71 of the mixing chamber flocculator 72, based on the controlled flow rate up to a maximum level of, for example, 10 m ³ /hour, optimal continuous adjustments of the revolutions of the mixing chamber flocculator 72 and the liquid mixture, the formation and growth of flakes occurs, which enables their subsequent mechanical separation.

The mixture prepared in this way is directly fed to a pair of microfiltration ceramic membranes 46, where direct filtration of undissolved substances, bacteria, viruses and microbiological particles is ensured by passing through the membrane. During the filtration cycle, filtered substances and particles separate on the surface of the microfiltration ceramic membrane 46, which manifests itself in an increase in the TMP transmembrane pressure. When the defined value is reached, the washing cycles are started, which in their sequence ensure the restoration of the permeability of the microfiltration ceramic membranes 46. The treated water - the filtrate - is directly drained into the treated water storage tank 52.

The water level in the treated water storage tank 52 is maintained by means of a continuous ultrasonic level sensor 53 and a pump 38 with a frequency converter/third pump 55 filling the tank and sorption filtration, which continuously drains the treated water to a pair of series-connected sorption pressure vessels 56 filled with granular activated carbon . Passing through

- 15 CZ 309929 B6 via sorption pressure vessels 56, the separation of residual dissolved substances is ensured and at the same time the sensory properties of water are optimized in the form of sorption of odor, taste, color and turbidity onto activated granular carbon. Water treated in this way is then hygienically protected by sterilization by passing through a UV reactor 57. The collection of treated drinking water is carried out in the treated drinking water tank 58. Sodium hypochlorite is dosed into the treated drinking water tank 58 by an electromagnetic dosing pump 60 so that the drinking water is hygienically treated according to national regulations or WHO standards. From the treated drinking water tank 58, the treated drinking water is drained via the fourth drinking water distribution pump 61 into the drinking water outlet pipe 30 of the point of consumption, or in cooperation with the automatic pressure vessel 62 through the drinking water outlet pipe 30 directly into the distribution system.

Industrial applicability

The solution concerns a highly innovative multifunctional mobile and stationary treatment plant for surface and underground water for drinking water. New design solutions and technological symbioses show high technological, useful and economic added value. Especially for the interchangeability of mobile and stationary use through a sophisticated design system of extendable autonomous complex technology - with the possibility of cascading with multiple outputs, through the generalization of all inputs and outputs at the head of the supporting skeletons. With the advantage of the possibility of deployment in highly different temperatures of the external climate and island use with energy sources based on RES without dependence on distribution networks and with the possibility of flexible transport and variable use in external and internal spaces, including the alternative of using commonly available ISO containers.

For example, the system is suitable for covering excess and seasonal needs, with industrial application, in the areas of civic amenities, agriculture, livestock industry, for charitable organizations providing drinking water supplies, for example in areas supported by the UN and war zones, in locations suffering from a lack of drinking water, water supply within migration camps, during humanitarian aid in situations of critical threat to the life of the population, in cases of contamination of existing resources caused by a natural disaster or disaster. The technology can also be used for the permanent provision of drinking water to the distribution network, in industrial plants, the food industry, breweries and malt houses.

Claims (4)

PATENT CLAIMS 1. Multifunctional mobile modular container monobloc (1) water treatment technology, characterized by the fact that it consists of a mobile container (2) formed by a supporting skeleton (3) with a supporting frame (4) of the skeleton containing the technology (7) of the water treatment plant and a service retractable module (6) and superstructures (5) of the supporting skeleton, whereby the supporting skeleton (3) with the supporting frame (4) of the skeleton and the superstructure (5) of the supporting skeleton is insertable/extendable into/from the mobile container (2), while the service extendable module (6 ) can be inserted/extended into/from the supporting frame (3), while the mobile container (2) is equipped with an adjustable base system (20) on the lower surfaces of the corners, while in the front part of the floor it is also equipped with front adjustable traveling rollers (15) and in rear part of its floor is equipped with rear adjustable traveling rollers (15)', while vertical rollers (16) are placed on the outer structure of the supporting frame (3) for rolling along the inner side surfaces of the mobile container (2), while the front face of the supporting frame (3 ) forms a modular inlet partition (9), with an inlet door (10) and a door of the distribution box (28) of electrical power and superior automated control (27), while on the support frame (3) a mixing chamber flocculator (72) containing a flocculation chamber is placed (71) divided by partitions into chambers, while the mixing chamber flocculator (72) is equipped with an electric motor (73), a multiple mixer equipped with turbine agitators with blades and a dividing disc (74), while the operating pull-out module (6) is equipped with a pull-out in its lower part (17) and in its upper part by guide rolls (18), while the guide rolls (18) are attached to the upper corner parts of the structure of the service extendable module (6), while the inputs and outputs of the technology (7) pass through the face of the supporting frame (4) of the skeleton ) water treatment plants, which are formed by the inlet pipe (29) of the raw water source, the outlet pipe (30) of drinking water, the outlet waste pipe (31) of uncontaminated water, the waste pipe (47) and the drain channel (32), while in the supporting frame ( 4) the skeleton is attached to the technology (7) of the water treatment plant, which is made up of a modular system of interconnected tanks, a dosing system, vessels, pumps, filtration and sorption technologies, a disinfection device, including a superior automated control (27) and an electric distribution box (28) energy, while a storage tank (36) of raw water is located in the front part of the supporting frame (4) of the skeleton, which is connected on one side to the inlet pipe (29) of the source of raw water, located on the front side of the supporting skeleton (3) woven into its the lower part connected to the pump (33), while it is further connected via a pipe to the raw water storage tank (36) equipped with a level sensor (37) at the same time connected by communication with the submersible abrasive pump (33), while on the inlet pipe (29) sources of raw water a turbidity meter (40) and a flow meter (41) are connected, while part of the route between the modular inlet bulkhead (9) and the raw water storage tank (36) is a regulating diaphragm valve (34) and a pressure gauge (35), when on the other side it is connected to the first pump (38), which is further connected to a mechanical basket filter (39), equipped with a basket with bag filters, located on a separate support element with mounting to the base of the support frame (4) of the skeleton, while on the mechanical bag filters of the mechanical basket filter (39 ) is connected to the homogenizer (42), which is connected to the dosing pump (44) of the pH regulator and the dosing pump (45) of the coagulant and is located on the storage barrel of the sodium hypochlorite dosing pump (50), while it is further connected to the tubular flocculator (43) located on the side and under the ceiling part of the support frame (4) of the skeleton, - 17 CZ 309929 B6 whereby microfiltration ceramic membranes (46) are located near the tubular flocculator (43) and are connected to it, while the microfiltration ceramic membranes (46) are located between the flushing pressure vessel (48) and the tank (52) modified water, while the microfiltration ceramic membranes (46) are fitted in their upper part with a pipe connected to the compressed air circuit - compressor unit (64) with an air reservoir (65) for the use of the dryer (70) and further fitted with a pipe connected to the tank (52) modified water, while in the lower part the microfiltration ceramic membranes (46) are connected to the tubular flocculator (43) and the waste pipe (47), which further connects to the outlet waste pipe (31) of uncontaminated water, while in the upper part of the tank (52) treated water a level sensor (53) is located, while the treated water tank (52) is connected in its lower part on one side to the second flushing pump (54), which is further connected by a pipe to the flushing pressure vessel (48) and to the third pump (55 ), which is further connected by a pipe with sorption pressure vessels (56), and is further connected in its lower part from the other side to the waste pipe (47), which connects to the outlet waste pipe (31) of uncontaminated water, while the tank (52) of treated water is simultaneously connected via a pipe to the fourth pump (61) of potable water distribution, which is connected to the tank (58) of treated drinking water fitted with a level gauge (59), while the tank (58) of treated drinking water is through the second pump (54) of flushing connected by a pipe to the upper part of the microfiltration ceramic membranes (46), while the pipes of the dosing pump (49) of sulfuric acid, the dosing pump (50) of sodium hypochlorite and the dosing pump (51) of sodium hydroxide are connected to the hydrostatic mixer (69) located in this pipe, while the sorption pressure vessels (56) are fitted with a pipe through which they are connected to the inlet of the UV reactor (57), while in their lower part they are connected to an air pipe (63), which is further connected to an air compressor (64) with an air reservoir, in their upper part, they are connected to the waste pipe (47) connected to the outlet waste pipe (31) of uncontaminated water, while the UV reactor (57) is located above the tank (58) of treated drinking water and by connecting the dosing nozzle of the sodium hypochlorite dosing pump (60) for potable water into the pipe route leading to the tank (58) of treated drinking water, while at its entrance it is equipped with a pipe connected to the sorption pressure vessels (56) and at the outlet via a pipe it is connected to the tank (58) of treated drinking water equipped with a level gauge (59) connected to the third pump (55) and further connected to the output pipe (10), while the fourth pump (61) for drinking water distribution is connected to the treated drinking water tank (58) via a pipe, while the fourth pump (61) is for drinking water distribution simultaneously connected to the drinking water outlet pipe (30) through a pipe. 2. Multifunctional mobile modular container monobloc (1) of water treatment technology according to claim 2, characterized in that there are two front adjustable travel rollers (15) and two rear adjustable travel rollers (15). 3. Multifunctional mobile modular container monoblock (1) water treatment technology according to claim 1, characterized in that there are two microfiltration ceramic membranes (46). 4. Multifunctional mobile modular container monobloc (1) water treatment technology according to claim 1, characterized in that four pieces of electrodes are placed in the flushing pressure vessel (48) and there is a tubular level indicator on the side of the flushing pressure vessel (48).