ES2284324B1 - MARINE WATER FILTER SYSTEM FOR DESALATORS. - Google Patents

Abstract

Marine water filtering system for desalination plants, for applying filtered water to desalination plants (1) floating, by means of a single pumping and a single filtering, with filtering elements (3) submerged in the seawater itself at a depth of at least 30-40 meters, where the water mass has the necessary pressure for filtering through said filtering elements (3), which have a filter body around a tubular core and on the outside a mobile housing that It is susceptible to axial displacement between a filtering position and an automatic cleaning position of the filtering body.

Description

Marine water filtering system for desalination plants

Technical sector

The present invention is related to the desalinated water production from seawater, proposing a filtering system that improves the conditions of the contribution of water destined for desalination.

State of the art

Population growth and improvement of  quality of life are determining an exponential increase in demand for water for consumption, so that in many places the use of water from rivers and wells is reaching the limit, while demand continues to grow.

Therefore, for water supply necessary for consumption has chosen to resort to desalination of sea water, since this is a source of supply inexhaustible, being the best known technique for such desalination the reverse osmosis, for which a conditioning of the water to desalinate, in order to preserve the membranes desalination plants of the deterioration that dirt can cause in them contained in the water.

Conventional desalination systems take usually seawater, storing it in large deposits built for it, from where the water is subsequently taken for desalination, three pumps being carried out throughout this process of water, which in turn passes through three respective filtrates for the necessary cleaning conditioning, resulting in a Very expensive process

Object of the invention

According to the invention, an application filtering system is proposed within the seawater itself and preferably intended for desalination plants floating in the sea itself, so that with a single filtration and a single pumping the supply of the water required, under the conditions due, to the desalination plant
tion.

This filtering system object of the invention it is based on arranging the filtering elements for water intake at a depth of at least 30-40 meters in the seawater, using filtering elements that comprise a filter body arranged around a tubular core externally provided with longitudinal cavities that are communicate with a lower chamber where a shutter is housed mobile capable of establishing different opening states and closing depending on its position, with which camera shutter housing communicates a supply line of pressurized water, while outside the filter body an axially movable housing is arranged that allows closing and open external communication with said filter body.

According to one embodiment the filter elements they comprise a piston that plays axially inside the tubular core depending on the supply of a hydraulic pressure accessory that communicates through the camera in which it is hosted the mobile shutter, leaving the mobile outer shell associated with said  piston, in displacement unit with it.

This is a provision with which through the supply of an injection of pressurized water through the camera in which the shutter is housed the elevation of the outer shell, leaving the filter body uncovered, to through which the water from the outside environment passes, so that water is filtered, discharging into a water tank desalted

Cutting the water supply under pressure, by effect of external pressure of the aquatic environment and the difference of surface between the upper base of the outer shell and the base of the inner plunger, said outer shell assembly and the Plunger descends, causing an exit of water from inside to through the filter body, resulting in a cleaning of this one in countercurrent with respect to the direction of filtering, reaching a closed arrangement at the end, in which the housing external closes the environment of the filter body.

According to a variant embodiment the housing external surrounding the filter body is arranged suspended so floating by means of support springs, which keep said housing in an open position to allow the passage of water from the outside aquatic environment through the body filtering, in the filtering activity, the aforementioned outer housing arranged in a piston-like assembly, so that by providing an injection of pressurized water, causes the lowering of said housing to close the environment of the filter body, at the same time as a circulation takes place countercurrent cleaning through the filter body.

This filtering system object of the invention take the water from the sea to a depth in which the medium itself aquatic has the necessary pressure for water to enter the filters through their filter body, with the advantage that at that depth the water contains a minimum of dirt and also due to the lack of light, certain microorganisms that could damage filters and damage Reverse osmosis membranes in desalination application.

Thus, a very filtering is achieved. effective and in very favorable conditions for the duration of the filters, which are also cleaned automatically, allowing to maintain the effectiveness of the filtered, while during the resting state the body Filter filtering can be kept immersed in treated water,  favoring conservation.

The arrangement of the filtering system in the within the marine aquatic environment, it also allows the application to desalination directly to floating desalination plants, by a single pump and a single filtering, simplifying the process and reducing the necessary energy cost with respect to conventional desalination systems.

Therefore, said system object of the invention results from certainly advantageous features, acquiring own life and preferential character for the function of application to which it is intended.

Description of the figures

Figure 1 shows an example of the arrangement  practice of the filtering system object of the invention in relationship with a floating desalination plant provided with a system of wind pumping.

Figure 2 is an example in sectional view of  a filtering element according to the invention, in the position of repose.

Figure 3 is a cross-sectional view of  said filtering element of the previous figure.

Figure 4 is a sectional view of the element  of filtering in an intermediate opening position.

Figure 5 is a sectional view of the element  filtering in fully open position.

Figure 6 is an enlarged detail of the area of the mobile shutter of the filter element, in the position of repose.

Figure 7 is a detail like the previous one in the  filtering position, corresponding to zone VII indicated in Figure 5

Figure 8 is a sectional view of the element of filtering at the initial position of the cleaning action of the filter body

Figure 9 is a sectional view of the element  filter in the final position of the body cleaning action filter.

Figures 10 and 11 are details enlarged of the respective zones X and XI indicated in the figures 8 and 9.

Figure 12 is a sectional view of a filter element according to another embodiment, according to the invention, in the resting position.

Figure 13 is a cross-sectional view of  said filter element of the previous figure.

Figure 14 is a sectional view of the filter element of figure 12, in the filtering action.

Figures 15 and 16 are details enlarged zones XV and XVI indicated in figure 14.

Figure 17 is a sectional view thereof. filter element, in the body cleaning action filter.

Figures 18 and 19 are details enlarged areas XVIII and XIX indicated in figure 17.

Figures 20 and 21 are two examples of realization of the tubular core of a filter element according with the invention

Detailed description of the invention

The object of the invention relates to a seawater filtering system for obtaining water desalinated, said system being applied in relation, by example, with a floating desalination plant (1), which can have a wind system (2) to pump the water destined to desalination, without this being a limiting application.

The filtering system comprises the arrangement of the filtering elements (3) at a depth of at least 30-40 meters, where sea water has little dirt and also because of the lack of light do not reproduce certain microorganisms that can damage filter elements (3) and damage the reverse osmosis membranes of the desalination plant (1) of application.

In this depth the aquatic environment itself exerts a pressure that exceeds 3 kg per square centimeter that are required for the passage of water through the elements Filtering (3) in the filtering action.

The filter elements (3) that are used in The system, according to the invention, consists of a core tubular (4), around which a filter body (5) is arranged formed by very thin filaments while surrounding on the outside to said assembly is a cover housing (6), which is capable of moving in axial displacement.

The thickness of the component filaments of the filter body (5) determines the filtering capacity, since The smaller the thickness of these filaments, the smaller the spaces between them and therefore smaller the particles that they are retained in the filtering action.

According to one embodiment (Figures 2 to 11), in the inside the tubular core (4) a plunger (7) is included susceptible to axial displacement, which is established together in solidarity with the outer casing (6), by means of a rod (8).

At the bottom of the filter assembly a camera (9) is defined, with which a conduction communicates external (10) intended for the injection of a water supply to pressure, going in the chamber (9) at least one shutter (11) that allows closing and opening a communication step (12) between the conduction (10) and the chamber (13) inside the tubular core (4) and between said chamber (13) of the tubular core (4) and the chamber (9); while the camera (9) is communicated through a step (14) with the chamber (15) remaining between the tubular core (4) and the filter body (5).

The external conduction (10) has a branch (16), by which the opening of a valve (17) is determined disposed in a conduit (18) leaving the chamber (9) towards a water collection tank, so when driving (10) pressurized water is injected through the bypass (16) the pressure reaches the valve (17), causing its opening, while when no water is injected through the conduit (10) the lack of pressure causes said valve (17) to close cutting the passage through the duct (18).

At the top, between the set of filtered and the housing (6) is a camera (19), which communicates to through a conduit (20) with a tube (21) that goes up to more above the surface of the water body, so that chamber (19) is in free communication with the atmosphere; while that the inner chamber (13) of the tubular core is communicated in the upper part with said camera (19), through a conduit (22), and therefore said chamber (13) is also in Free communication with the atmosphere.

With all of this, starting from a position inoperative, as represented in figures 2 and 6, with the outer shell (6) in closed position, that is to say resting on the bottom of the filter assembly, when introducing a pressure water injection by conduction (10), the pressure is extend by the branch (16) and open the valve (17), while that, on the other hand, the pressure forces the shutter (11) to a position in which the passage (12) is open, so that the water injected enters the chamber (13) inside the tubular core (4), below the plunger (7), as shown in Figure 7.

When the injected water enters the chamber (13), the pressure forces the plunger (7) to rise, dragging the outer shell (6) facing up, as shown in figure 4, with which opens the contour of the filter body (5), so that water from the aquatic environment enters through said filter body (5), the dirt particles and the clean (filtered) water descends through the chamber (15), passing through the communication (14) to the camera (9), from which it leaves through the conduit (18) to the collection tank.

Under normal operating conditions the outer shell (6) reaches a higher position in which leave the contour of the filter body (5) fully open, as represents figure 5, maintaining that situation during the filtering process

When the injection pressure is cut by the conduction (10), the lack of acting pressure causes the valve (17), while the shutter (11) changes position by the action of its thrust spring (23), thereby closing the passage between the conduction (10) and the chamber (13), the  step from this chamber (13) to the lower chamber (9), as see in figures 8 to 11.

Under these conditions, the push down of the outer shell (6), by the pressure of the aquatic environment on it causes the assembly of said housing (6) and the plunger (7) descend, forcing the water in the chamber (13) to exit through the passage (12) to the chamber (9), from which it passes through the conduit (14) to the chamber (15) and from it exits through the filter body (5) outward, detaching from said filter body (5) dirt particles retained on the outside of it in the filtering process, which means an automatic cleaning effect that prevents clogging of the filter.

Each time the process of interrupting filtering therefore automatically cleans the filter body (5), removing dirt particles retained in it, being able to schedule periodic detentions, to that cleaning occurs, in order to keep the filter in Perfect conditions for filtering effectiveness.

The rise and fall of the whole outer shell (6) and plunger (7) in the operational phases corresponding, they occur with absolute freedom, due to the chamber communication (13) above the plunger (7) and the chamber (19), through the ducts (20 and 22), with the tube (21) and through it with the atmosphere, allowing entry and air outlet

The decline of the aforementioned set of outer shell (6) and plunger (7) in the cleaning phase of the filter body (5), is produced thanks to the pressure that the medium exterior aquatic exerts on the housing (6) and the difference of section between the upper base of said housing (6) and the base of the piston (7), so that if the external pressure is for example 4 Kg per square centimeter and the upper base of the housing (6) is double surface than the base of the plunger (7), the force that said Plunger (7) made down by the thrust of the housing (6) is 8 Kg per square centimeter, whereby the water inside projects with a resulting force of 4 Kg per square centimeter through the filter body outwards.

In another embodiment (figures 12 to 19), which does not alter the essential concept of the filtering system, the outer housing (6) of the filter element is arranged in assembly floating resting on springs (24), which keep it in a position that leaves a water inlet opening (25) of the outdoor aquatic environment.

With this, in normal conditions the water of the aquatic environment enters through the opening (25) and passes through the filter body (5), the particles of which are retained therein dirt, as shown in figure 14, so that the clean water (filtered) descends through the chamber (15) defined between the body filter (5) and tubular core (4), leaving through a passage (26) to the lower chamber (9), from which it is evicted by a exit (27) to the water collection tank, as it represents Figure 16

In this embodiment inside the lower chamber  (9) at least one mobile shutter (28) is provided provided with a hole (29) in the upper part and another hole (30) in the part lower, being pushed by a spring (31) that tends to keep you in a position where the top hole (29) matches the step (26) of the camera (15) and where it leaves Open the drain outlet (27) of the filtered water.

In this case, they communicate with the camera (9) pipes (32), for which a water injection is susceptible under pressure, so that when said water injection is made to pressure, the thrust of it causes the shutter (28) to move against the grinding wheel (31), according to figures 17 and 19, leaving in communication the corresponding conduction (32) with the chamber (15), through the passage (26), while the hole upper (29) of said shutter (28) is then in correspondence with a step (33) of communication with the party outside the filter body (5), while the hole lower (30) corresponds to an outlet (34) of dirty water evacuation while the eviction exit (27) of the filtered water is closed.

In the upper part the outer shell (6) goes attached to a block (35) that acts as a mobile cylinder with respect to a fixed piston (36), so that when injected pressurized water through the pipes (32), it rises through the chamber (15) and at the top passes through a conduit (37) to the inner chamber (38) of the block (35), below the plunger (36), thereby creating a pressure that forces the block (35) with a push down against the springs (24), as it represents Figure 18, producing a descent of said block (35), which brings the housing (6) to a closed position against the assembly lower, as shown in figure 17.

Under such conditions, the injected water passes from the chamber (15) through the filter body (5), peeling off the dirt particles that are stuck in the outside of said filter body, to exit, dragging dirt particles, by step (33) and evacuate for the evacuation exit (34), as represented by the figure 19.

The structural assembly of the filter requires that between the tubular core (4) and the filter body (5) a decisive space of the chamber (15), for which the body filter (5) must be distanced and concentric with respect to the tubular core (4).

For this purpose, the tubular core (4) can be of  different forms of practical realization, without altering the concept, for example in the form of a tubular body (39) provided with radial longitudinal fins (40) on the outside, such as represents figure 20, or in the form of a tubular body (41) provided with longitudinal grooves (42) on the outside, such as represents figure 21.

For hydraulic drive injection of the movement of the outer shell (6) between the positions Functional filtering and cleaning of the filter body (5), you can use any water, but in order to protect in the as far as possible the component elements of the filter and in particular the filter body (5), for its longest duration, in that Water injection function is expected to use water desalted and with a convenient chemical treatment.

Claims (7)

1. Marine water filtering system for desalination plants, to supply filtered water directly to floating desalination plants (1), by means of a single pumping and a single filtering, characterized in that the water filtering is carried out at a depth of at least 30-40 meters, where the water mass itself has the necessary pressure for filtering operability, using filtering elements (3) comprising a tubular core (4) and around it a filter body (5), with an outer casing ( 6) susceptible to axial displacement by the action of a hydraulic injection control, allowing to establish a state of functional behavior of filtering and a state of functional behavior of automatic cleaning of the filter body (5). 2. Marine water filtering system for desalination plants, according to the first claim, characterized in that the filtering elements (3) comprise in the lower part a chamber (9), through which the injection passage is established hydraulic control, incorporating in said chamber (9) a mobile shutter (11, 28) that is capable of positioning to establish the respective states of filtering and cleaning of functional behavior. 3. Seawater filtering system for desalination plants, according to the first and second claims, characterized in that the filtering elements (3) include a piston (7) associated in solidarity with the outer casing (6), determining a lifting assembly by hydraulic pressure on the piston (7) by hydraulic control injection, for filtering, and lowering by external hydraulic pressure on the housing (6) for cleaning when the control injection is cut. 4. Seawater filtering system for desalination plants, according to the first and second claims, characterized in that the filtering elements (3) include an upper block (35) as a mobile cylinder with respect to a fixed piston (36), the outer casing (6) being integrally connected to said upper block (35), determining a floating assembly that rests on springs (24), with the possibility of lowering by the action of the hydraulic control injection to establish the closure of the contour in the functional state of cleaning. 5. Marine water filtering system for desalination plants, according to the first claim, characterized in that the tubular core (4) of the filtering elements (3) consists of a tubular body (39) provided with radial longitudinal fins (40) abroad. 6. Seawater filtration system for desalination plants, according to the first claim, characterized in that the tubular core (4) of the filtering elements (3) consists of a tubular body (41) provided with longitudinal grooves (42) in the outside. 7. Marine water filtering system for dealers, according to the first claim, characterized in that the filtering body (5) of the filtering elements (3) consists of a package of filaments, through which the water that passes Filters, with retention of dirt particles of a size that depends on the thickness of said filaments.