RU89067U1 - REVERSE OSMOTIC DESCRIPTION PLANT FOR UNDERWATER HABITATED OBJECTS - Google Patents

Abstract

Reverse osmosis desalination plant for underwater habitable objects, containing coarse and fine filters for sea water, a high pressure pump, diaphragm apparatus, hydraulic connections and fittings, characterized in that the installation is made in the form of at least three separately located at different levels and functionally combined interconnected by hydraulic connections of blocks: a pump block fixed through shock absorbers on horizontal and vertical foundations and including a high-pressure plunger pump electric drive, a pneumatic accumulator mounted on the discharge pipe of the pump, and flexible hoses; desalination unit, fixed through shock absorbers on a vertical foundation and including a coarse filter, fine filter and membrane devices; and a block of boron-selective filters rigidly fixed to a horizontal foundation, moreover, the coarse filter is filled with a mixed charge of metal particles heterogeneous with respect to the electrochemical potential made of wire with an aspect ratio of L: D = 2 to 5, where L is the length of the wire and D is the diameter of the wire, the fine filter is equipped with a replaceable cartridge of elastic fibers, and the boron-selective filters are loaded with a boron-selective sorbent, while the hydraulic connections and fittings are made with providing the possibility of two-stage desalination of water in membrane units, utilizing the brine by dosing it in desalinated and in source sea water with the subsequent discharge of desalinated water and brine into autonomous prefabricated containers and increasing the volume

Description

This technical solution relates to the field of desalination of natural waters and can be used mainly on underwater inhabited objects (hereinafter referred to as objects): deep-sea vehicles for oceanological studies of the shelf, flora and fauna; tourist aquaplanes; bathyscaphe; pop-up cameras; submarines of civilian and military purposes, etc.

Known reverse osmosis desalination plant in the ship (magazine "Sudostroenie" No. 1, 1997, p.25-26), including a high pressure pump, filters for rough and fine purification of sea water, reverse osmosis desalination elements (membrane devices), pipelines, fittings, tools management and control. The installation implements a single-stage desalination scheme and is made in the form of an automated unit mounted on a single frame. A disadvantage of the known installation is its bulkiness and unsatisfactory vibration and noise characteristics (VHS), since the installation has powerful sources of noise and vibration, and there is no means of suppressing them. In addition, the quality of water in a single-stage desalination scheme does not meet modern hygiene requirements.

Also known is a more advanced reverse osmosis desalination plant in ship design (patent No. 2186709), containing coarse and fine filters for sea water, a high pressure pump, diaphragm devices, hydraulic connections and fittings. Filters for coarse and fine purification of sea water contain filter elements (replaceable cartridges) made of an elastic filter material, which provides some improvement in the VSH installation.

This installation is adopted as a prototype of the proposed technical solution.

The main disadvantages inherent in the installation according to patent No. 2186709:

- bulky design, due to the rigid aggregation of the installation nodes, requires a significant amount of space for its placement to the detriment of the living space of the crew,

- unacceptable HF installations due to the presence of vibroactive components in the unit and the possibility of resonant effects, which interferes with the secrecy of the object and negatively affects the health of the crew,

- unsatisfactory quality of desalinated water, due to a single-stage desalination scheme and the absence of a final treatment unit for water from toxic elements - boron and bromine, which is harmful to human health, especially with prolonged use of desalinated water,

- insufficient life of the membrane apparatus due to the possibility of their biological fouling by marine microorganisms in long voyages can lead to an emergency in which the crew will be left without drinking water,

- An unacceptable ratio of the amount of desalinated water to brine - about 90% of the total amount of sea water goes to the brine, and only 10% is desalinated water. This ratio is due to the single-stage desalination scheme used in the installation without brine disposal. Since the discharge of brine overboard is not possible for reasons of secrecy of the object, for the collection and storage of brine inside a solid hull, additional tanks will be required to the detriment of the living space of the crew.

The listed disadvantages of the desalination plant according to patent No. 2186709 create harmful living conditions for the human underwater object, especially during its long-term autonomous (offshore) swimming.

The technical result when using the proposed utility model is to provide a crew-friendly living environment in long-term autonomous (offshore) navigation of an object by preparing drinking water from sea using a reverse osmosis desalination plant.

The specified technical result is achieved due to the fact that the reverse osmosis desalination plant is made in the form of at least three blocks located separately at different levels and functionally interconnected by hydraulic connections: a pump unit fixed through shock absorbers, for example, spiral-cable vibration isolators, on horizontal and vertical foundations and including a high-pressure plunger pump with electric drive, a pneumatic accumulator mounted on the discharge pipe pump, and flexible hoses; a desalination unit fixed through shock absorbers, for example, spiral-cable vibration isolators, on a vertical foundation and including a coarse filter, a fine filter and membrane devices; block boron-selective filters, rigidly fixed to a horizontal foundation. The coarse filter is equipped with a copper ion generator, made, for example, in the form of a mixed charge of metal particles heterogeneous with respect to the electrochemical potential made of wire with a ratio of sizes L: D = 2 to 5, where L is the length of the wire and D is the diameter wire. The fine filter is equipped with a replaceable cartridge made of elastic, for example, polypropylene fibers. Borbromoselective filters are loaded with a boron bromine selective sorbent, for example, a polystyrene-based macroporous anion exchange resin, and hydraulic connections and fittings are made with the possibility of two-stage desalination of water in the membrane apparatus, the disposal of brine by dosing it in desalinated and source sea water, as well as the possibility of subsequent discharge of desalination water and brine in stand-alone prefabricated tanks with bringing the volume ratio of desalinated water and brine to a value of at least 1: 3.

The design of the reverse osmosis desalination plant is shown in the attached drawing as an example of an inhabited object - a submarine (PL). The installation includes blocks: pump unit 1, desalination unit 2 and block of boron selective filters 3. The blocks are located separately from each other and spaced apart in the horizontal direction at distances H ₁ and H ₂ and in the vertical direction at a distance of H ₃ . The blocks are interconnected functionally by means of hydraulic connections (pipelines and flexible hoses) and fittings (taps and throttle devices). The pump unit 1 contains a plunger electric pump with a suction 4 and discharge 5 nozzles, a pneumatic accumulator 6 mounted on the discharge nozzle of the pump, and flexible hoses 7 and 8. The pneumatic accumulator 6 contains a container divided by an elastic membrane into two cavities - a sea water cavity connected to the discharge nozzle 5, and an air cavity filled with compressed air. The pump unit is fixed through shock absorbers 9 to a horizontal foundation and through shock absorber 10 to a vertical foundation. As shock absorbers, for example, spiral-cable vibration isolators can be used.

The desalination unit 2 includes a coarse filter 11 of sea water, a fine filter 12 of sea water and membrane units 13, 14 and 15 equipped with semipermeable membranes 16. The coarse filter 11 contains a cylindrical body with a replaceable cartridge filled with a mixed charge of heterogeneous electrochemical potential of metal particles made, for example, of copper and titanium wire with an aspect ratio of L: D = 2 to 5, where L is the length of the wire and D is the diameter of the wire. The specified mixture in the coarse filter performs the function of a generator of copper ions. The fine filter 12 is equipped with a replaceable cartridge of elastic, for example, polypropylene fibers. Filters 11 and 12 are arranged sequentially one after another, i.e. form a "cascade". The desalination unit is fixed through shock absorbers, for example, spiral-cable vibration isolators 17 and 18, to a vertical foundation.

The block of boron bromselective filters 3 is made in the form of a double-shell apparatus filled with boron bromselective sorbent 19, for example, a polystyrene-based macroporous anion-exchange resin. The filter unit 3 is fixed on a horizontal foundation rigidly, without the use of shock absorbers.

Hydraulic connections (pipelines 20-24) and fittings (valves and throttling devices 25-28) functionally combine among themselves blocks 1, 2, 3, a tank of source sea water 29, a brine tank 30 and a tank of desalinated water 31. At the same time, pipelines and valves made with the possibility of two-stage desalination of water in the membrane apparatus, disposal of brine by dosing it in desalinated and source sea water, as well as the possibility of subsequent discharge of desalinated water and brine into autonomous tanks with a volume of Nogo ratio of desalinated water and the brine to a value of at least 1: 3.

The listed components of the installation (blocks) are placed inside the durable housing 32. The installation works as follows. The source sea water from the tank 29, which is under pressure of compressed air, passes through the pipeline 20 to the coarse filter 11, where large suspended impurities are detained in the layer of the filter charge. At the same time, inside the charge due to the contact of metal particles with different electrochemical potential in sea water, anodic dissolution of a more active metal (in this case, copper) occurs with the release (generation) of copper ions. Sea water, enriched with copper ions, enters the fine filter, where it is purified from fine (less than 5 microns) mechanical impurities. Moreover, the presence of copper ions prevents the multiplication and growth of marine microorganisms along the entire further path of water movement: in a coarse filter, in a fine filter, on the surface of semipermeable membranes, in a layer of a boron-selective sorbent. Purified water from the filter 12 through the flexible sleeve 7 enters the suction pipe 4 of the high pressure pump, and then from the discharge pipe 5 under a working pressure of 5.5 to 5 MPa - into the pneumatic accumulator 6, and from it through the flexible sleeve 8 - to the inlet into the membrane apparatus 13. Flexible hoses 7, 8 and the pneumatic accumulator 6 smooth out the pulsation of the water flow and ensure a quiet, without vibration disturbance, fluid flow in the membrane apparatus.

Desalination of water in the membrane apparatus is carried out in two stages: desalinated water at the outlet of the apparatus 13 and 14 is combined and sent to the apparatus 15 as feed water of the second stage. The brine from the apparatus 14 is distributed as follows: one part through the throttle valve 26 is discharged into the brine tank 30, and the other part through the throttle valve 25 is returned to the suction pipe 4 of the pump. The brine from the second stage through the pipe 24 is distributed using the inductors 27 and 28 also into two parts: one part is dosed into the brine pipe 21, and the other part into the desalinated water pipeline 22. The valves and inductors 25-28 are adjusted so that the ratio of the quantity desalinated water discharged into the tank 31 and the amount of brine discharged into the tank 30 would be at least 1: 3, i.e. desalinated water should have an output of at least 33% compared to brine. With a lower value of this parameter (for example, 1: 9, as in the installation - prototype), the yield of desalinated water is only 10%, which is unacceptable for the object. It was also established experimentally that to achieve a desalinated water-distillate ratio higher than 1: 3, it would be necessary to complicate the hydraulic circuit of the installation to the detriment of the positive properties achieved with a ratio of 1: 3.

The use of shock absorbers, for example, spiral-cable vibration isolators, provides effective vibration isolation of the installation by damping noise and vibration separately in the pump and desalination units, i.e. in the sources themselves. At the same time, the pump unit, containing unbalanced masses rotating and moving in several planes, is the most vibroactive assembly unit. The vibration block of the pump unit is provided with shock absorbers mounted on the horizontal and vertical foundations of the submarine.

As for the desalination unit, a weakly pulsating water flow comes from the pumping unit, which is substantially smoothed out due to the pneumatic accumulator 6 and flexible hoses 7 and 8. Water filtration through the “cascade” of coarse filters 11 and fine filters 12, which are elastically deformable porous masses finally dampens the energy of the pulsating flow. Already a completely balanced flow of water enters the membrane units, therefore, for vibration isolation of the desalination unit, the use of shock absorbers mounted only on a vertical foundation is sufficient.

Desalinated water in the form of a continuous laminar flow enters the block of boron-selective filters 3; the filtration in the sorbent layer is carried out at obviously low (less than 1 m / s) speeds. Due to the absence of potential sources of noise and vibration in the filter unit, vibration isolation of the unit is not required, the unit is rigidly attached to the foundation.

Spaced apart in height and remote from each other, the vibration-insulated blocks practically do not transmit vibration and noise disturbances to each other, which eliminates the possibility of resonance effects. The use of shock absorbers eliminates the possibility of transmitting vibration and noise to the robust hull of the submarine and to the crew living inside it.

The resulting desalinated water with an acceptable macroionic composition, however, is not yet suitable for drinking, since it contains toxic trace elements boron and bromine - such is the specificity of the reverse osmosis desalination process itself. Finish filtering water through a layer of a boron bromine selective sorbent, for example, a polystyrene-based macroporous anion exchange resin, removes boron and bromine from the water and obtains drinking water that is full in chemical composition and harmless to human health. The prepared drinking water is discharged through a pipe 23 into a tank 31, from which it is distributed to consumers by submarines (to the galley, to wash basins, to a shower, etc.).

Given that prolonged, for example, for 180 days and more autonomous navigation, the submarine is objectively characterized by difficult and sometimes extreme living conditions for the crew inside a solid submarine hull, namely, the negative impact on the person of noise and vibration from operating mechanisms, deficiency and unsatisfactory the quality of desalinated drinking water, the inability to replenish the supply of coastal water, the lack of free space for human habitation, etc., a real technical result when using the proposal aemoy utility model is to ensure the health safety of the crew habitability conditions in the long-term offline (without connection to the shore) of the object by producing potable water from sea water with a reverse osmosis desalination plant.

Between the essential features of the claimed utility model and the achieved technical result, the following cause-effect relationship is manifested:

1. Signs “the installation is made in the form of at least three blocks separately located at different levels and functionally interconnected by hydraulic connections: a pump block fixed through shock absorbers on horizontal and vertical foundations and including a high-pressure plunger pump with electric drive, a pneumatic accumulator installed on the discharge pipe of the pump, and flexible hoses; desalination unit, fixed through shock absorbers on a vertical foundation and including a coarse filter, fine filter and membrane devices; and block boron-selective filters, rigidly mounted on a horizontal foundation "provide:

- separate placement of blocks in niches, for example, in the spacings of a strong submarine hull, and the release due to this additional living space, urgently needed for the crew in conditions of long autonomous navigation,

- Improvement of the HPL of the desalination plant and, thereby, the reduction of the negative impact of noise and vibration on the health of the crew. At the same time, the stealth of the submarine increases and its viability is ensured in conditions of prolonged autonomous navigation,

2. The sign "coarse filter is equipped with a copper ion generator, made, for example, in the form of a mixed charge of metal particles heterogeneous with respect to the electrochemical potential made of wire with a size ratio L: D = 2 to 5, where L is the length of the wire and D is the wire diameter ”provides blocking of biological fouling of the filtering surfaces, prolongs the installation resource due to this, and allows supplying the crew with benign drinking water during the entire period of long autonomous Lavagna submarines,

3. The signs “a fine filter is equipped with an interchangeable cartridge of elastic fibers” and “boron bromse filters are loaded with a boron bromine selective sorbent, and hydraulic connections and fittings are provided with the possibility of two-stage desalination of water in the membrane apparatus” ensure effective purification of sea water and obtaining full-fledged seawater in terms of chemical composition and sufficient amount of drinking water that is harmless to human health, which is vital for the crew in conditions of prolonged av onomnogo (out of communication with the shore) diving.

4. Signs “hydraulic connections and fittings are made with the possibility of two-stage desalination of water in the membrane apparatus, the disposal of brine by dosing it in desalinated and source sea water, followed by discharge of desalinated water and brine into stand-alone collection tanks and bringing the volume ratio of desalinated water to brine to a value of not less than 1: 3 "minimize the amount of waste water and reduce the volume of" dirty "tanks, thereby increasing living space for crew Ms, which is vital in long-term autonomous navigation. At the same time, it is understood that the discharge of "dirty" waters overboard in conditions of prolonged autonomous navigation in order to ensure the secrecy of submarines is impossible.

When studying publicly available and limitedly accessible sources of information, applicants and authors did not identify technical solutions that discredit the novelty and usefulness of the claimed technical solution.

Claims (1)

Reverse osmosis desalination plant for underwater habitable objects, containing coarse and fine filters for sea water, a high pressure pump, diaphragm apparatus, hydraulic connections and fittings, characterized in that the installation is made in the form of at least three separately located at different levels and functionally combined interconnected by hydraulic connections of blocks: a pump block fixed through shock absorbers on horizontal and vertical foundations and including a high-pressure plunger pump electric drives, a pneumatic accumulator mounted on the discharge pipe of the pump, and flexible hoses; desalination unit, fixed through shock absorbers on a vertical foundation and including a coarse filter, fine filter and membrane devices; and a block of boron-selective filters rigidly fixed to a horizontal foundation, moreover, the coarse filter is filled with a mixed charge of metal particles heterogeneous with respect to the electrochemical potential made of wire with an aspect ratio of L: D = 2 to 5, where L is the length of the wire and D is the diameter of the wire, the fine filter is equipped with a replaceable cartridge of elastic fibers, and the boron-selective filters are loaded with a boron-selective sorbent, while the hydraulic connections and fittings are made with providing the possibility of two-stage desalination of water in membrane devices, disposing of the brine by dosing it in desalinated and in source sea water with the subsequent discharge of desalinated water and brine into stand-alone collection tanks and bringing the volume ratio of desalinated water to brine to a value of at least 1: 3.