 FILTERING DEVICE
专利摘要:
The invention describes a filtering device (10) configured to be arranged inside a fluid to be filtered and comprising at least one main filter (14) and a filter holder (100) supporting the main filter (14). , characterized in that: - the filtering device (10) is configured to be moved inside the fluid, so that when the filtering device (10) is moved in a first direction of movement (4) at least a portion of the fluid passes through the main filter (14) in a first filtering direction (200); the filtering device (10) is configured to prevent the fluid from passing through the main filter (14) in a second filtering direction (201) opposite to the first filtering direction (200) when the filtering device (10) is moved in a second displacement opposite to the first direction of movement (4). The invention also relates to a system incorporating such a device and to methods using such a device. 公开号:FR3018459A1 申请号:FR1452056 申请日:2014-03-12 公开日:2015-09-18 发明作者:Jocelyn Pierre 申请人:Commissariat a lEnergie Atomique CEA;Commissariat a lEnergie Atomique et aux Energies Alternatives CEA; IPC主号:
专利说明:
[0001] TECHNICAL FIELD OF THE INVENTION The present invention relates generally to the filtration of fluids. It receives for advantageous application the filtration of fluids that it is difficult to extract from their environment for reasons of contamination, dangerousness or simply accessibility. The invention is particularly advantageous for the filtration of fluids used in nuclear research or irradiation reactors. In this type of application, the invention makes it possible to easily recover precipitates of fluid metal, for example alkaline, resulting from pollution with hydrogen and oxygen, in particular for irradiated devices. STATE OF THE ART A number of experiments in a nuclear irradiation reactor (such as the OSIRIS reactor for example) are carried out on samples in a bath of fluid metal, sodium or a sodium / potassium mixture (commonly called NaK). . The advantage of these experimental conditions is to be able to reach the temperature levels desired by the experiment (usually between 280 ° C and 400 ° C), with a good homogeneity of temperatures that provides a fluid and without the constraints of water which would suppose a pressurized enclosure. Thus, many irradiations of samples of nuclear materials (primarily zirconium alloys) are bathed in NaK for reactor times of up to a few years. However, like any alkaline compound, NaK is very hungry for oxygen and hydrogen in any form. It is therefore important to constantly manipulate this fluid under a neutral gas. Despite all the precautions implemented, the withdrawal and the introduction of the samples in particular introduce impurities (for example water in the form of moisture in the air) which react in the fluid metal forming hydroxide and hydride compounds. These precipitates, very slightly soluble cold, dissolve considerably at the temperature conditions of the irradiation reactor. Thus, hydrogen gas present in significant amounts in the NaK can then diffuse into the samples after their adsorption. Since zirconium compounds have a higher affinity for hydrogen than alkalis, hydrogen penetrates easily and deeply into experimental samples, to such concentrations that the mechanical properties of these samples are largely modified, which can lead to their weakening. [0002] These modifications thus distort the experiments and can even render their results unusable. The solution currently used to avoid these problems is to very slightly oxidize the samples to obtain by this surface treatment a layer that prevents the adsorption of hydrogen. [0003] This solution is only valid for new samples and assuming that the oxide thickness does not create any change in the mechanical properties of the sample. The scope of this solution is therefore limited. For an already irradiated sample or in the case of an express prohibition of the sample owner, it is not possible to pre-oxidize these samples. So you have to remove the source of pollution. One could thus be tempted to look for solutions to purify this type of fluid. In the general field of filtration of conventional fluids, that is to say non-hazardous, several solutions have been proposed. [0004] These solutions provide for equipping the fluid circulation circuit with a loop dedicated to the filtration function. This loop generally includes a filter, a pump, hot and / or cold traps with correlatively temperature control. Indeed, the solubilities of the pollutants that have precipitated are often a function of the temperatures. The use of these circuits then requires increasing the temperature to solubilize the precipitated chemical compounds and then abruptly lower the temperature below the desired solubility limit downstream of the circuit, while remaining above the solidification temperature. fluid. The filter placed immediately after this cooling stage traps the precipitates. The cooling temperature level controls the residual pollutant concentration according to its precipitation limit. These solutions are relatively effective for fluids that do not present any particular danger. On the other hand, for dangerous fluids, typically fluids presenting a danger of the radiological and / or chemical type, the installation for moving the fluid through the filtering loop is very complex to implement. The technical and financial impacts of these solutions are often prohibitive. [0005] Finally, there is another type of solution, for example for very large volumes and even without the fluids are particularly dangerous, which are not based on a circuit dedicated to filtration but based on passive filtration, consisting of recovering by gravity precipitates and other residues. This type of solution nevertheless has the disadvantage of not allowing a filtering satisfactory in terms of filtering speed and not be suitable for fluids that are not immobile, for example, which may undergo a planned or unexpected brewing. [0006] There is therefore a need to provide a solution for effectively filtering a fluid, for example a hazardous fluid, while reducing the technical or financial constraints of the known solutions. This is the object of the present invention. [0007] SUMMARY OF THE INVENTION To achieve this objective, one aspect of the present invention relates to a filtering device configured to be disposed within a fluid to be filtered, for example within the fluid container and having at least one filter and a filter holder supporting the filter. The filter device is configured to be moved within the fluid, for example within the fluid container, so that when the filter device is moved in a first direction of movement, at least a portion of the fluid crosses the filter in a first filtering direction. Thus the filtering is ensured by a displacement of the filtering device with respect to the fluid and the container of this fluid, such as a pipe, a tank or a tank. The filter device thus forms a piston in the container. The fluid can be left immobile or be moved in the container. The invention thus makes it possible to avoid numerous disadvantages induced by the known solutions mentioned above. In particular, the invention makes it possible to dispense with a circuit dedicated to filtration with a circulating pump and temperature management equipment for controlling the formation of the precipitates to be filtered. [0008] The invention thus proposes a simple, reliable and economical solution for filtering a possibly static fluid, and this, within the equipment in which it is used. In particular, it is particularly advantageous for filtering fluids that are very difficult to transfer to a circuit exclusively dedicated to cleaning for example for reasons of contamination, danger or exploitation. This is particularly the case for circuits equipping nuclear research or irradiation reactors such as the OSIRIS reactor. Applied to these reactors, the invention makes it possible to avoid the transmission of pollution to the samples immersed in the fluid, pollution which could be detrimental to the experiment. The invention is nevertheless not limited to the application to the nuclear field and extends to any type of fluid, in particular any fluid that can be loaded with solid particles in its conditions of use. According to an advantageous embodiment, the filtering device is configured to prevent the fluid from passing through the filter in a second filtering direction opposite to the first filtering direction when the filtering device is moved in a second displacement opposite the first filtering direction. direction of movement. The invention thus makes it possible to ensure particularly effective filtering. Indeed, when the filter device is moved in a first direction, the fluid is filtered through the filter and accumulates in the latter residues. When the filter device is moved in the opposite direction, the fluid can not pass through the filter in the opposite direction, thus preventing the release of part of the residues accumulated therein and their dispersion in the fluid. [0009] Other optional features of the invention, which can be implemented in combination in any combination or alternatively, are indicated below: Advantageously, the filtering device is configured to be moved in translation to the inside a container in which the fluid is contained. Alternatively, the filtering device is configured to be rotated inside the container. - The container is typically a circuit or a circuit portion. It can also be a tank or a tank. According to one embodiment, the filtering device is configured to force a portion of the fluid at least to pass through said filter in the first filtering direction when the filtering device is moved in the second direction of movement. Thus, particularly advantageously, the fluid always passes through the filter in the first filtering direction regardless of the direction of movement of the filtering device. Advantageously, the device can thus comprise a single filter which is traversed in the same direction regardless of the direction of movement of the filter holder. According to one embodiment, the filtering device forms at least one filtering chamber comprising the filter and comprises: at least one first valve configured to allow the fluid to pass from the outside of the filtering chamber to a first portion of the filter chamber located opposite a first wall of the filter when the filtering device is moved in the first direction of movement and configured to prevent the entry and exit of the fluid respectively in and out of said first portion when the filtering device is moved in the second direction of movement; at least one second valve configured to allow fluid to flow from outside the filter chamber to said first portion of the filter chamber when the filter device is moved in the second direction of movement and configured to prevent the inlet and the outlet of the fluid respectively in and out of said first portion when the filtering device is moved in the first direction of displacement. According to one embodiment, the first valve is arranged upstream of the second valve with respect to the direction of flow of the fluid in the filter device when the latter is displaced in the first direction of displacement. According to one embodiment, the filtering device comprises at least two outlet openings configured to allow the fluid to pass from a portion of the filtering chamber situated opposite a second wall of the filter opposite to the first wall up to outside the filter chamber downstream of the filtering device, one of the two openings for the outlet of the fluid downstream of the filtering device when the latter is moved in the first direction and the other of the two openings allowing the fluid outlet downstream of the filter device when the latter is moved in the second direction. According to one embodiment, the filtering device comprises at least two outlet valves, each respectively associated with one of the at least two outlet openings. Each outlet valve is configured to allow the passage of fluid from the second portion downstream of the filter device and to prevent the passage of fluid from the upstream of the filter device to the second portion of the filter chamber . According to one embodiment, each outlet valve prevents the passage of fluid to the outlet opening associated therewith when it is plated on a valve seat and comprises a light arranged in line with an orifice of inlet allowing the fluid located upstream of the filtering device to access the first and second valves. According to one embodiment, the filtering device is configured to be displaced in translation inside the container and the filter has a cylinder shape extending in the direction of translation of the filtering device. According to another embodiment, the filtering device is configured to prevent the fluid from passing through the filter when the filtering device is moved in the second direction of displacement. - Preferably, the filtering device comprises at least a first valve disposed downstream of the filter, relative to the direction of movement of the fluid relative to the filter device when the latter is moved in the first direction of movement and disposed upstream of the filter relative to the direction of movement of the fluid with respect to the filter device when the latter is displaced in the second direction of movement, said first valve being configured: to open under the pressure of the fluid having passed through the filter when the filtering is moved in the first direction of movement so as to allow the fluid having passed through the filter to leave the filtering device; - To remain closed otherwise, that is to say when the filter device is stationary or is moved in the second direction of movement so as to prevent the fluid from passing through the filter. According to one embodiment, the filtering device comprises at least a second valve arranged upstream of the filter, relative to the direction of movement of the fluid with respect to the filtering device when the latter is displaced in the first direction of movement and disposed downstream. of the filter, relative to the direction of displacement of the fluid with respect to the filtering device when the latter is displaced in the second direction of movement, said second valve being configured: to open under the pressure of the fluid when the filtering device is moved in the first direction of movement so as to allow the fluid to reach the filter; - To keep closed otherwise, that is to say when the filter device is stationary or is moved in the second direction of movement so as to prevent fluid having passed through the filter leaving the filter device. According to one embodiment, the filtering device is configured to form, when the filtering device is moved in the first direction of movement, at least one filter path passing through the filter and configured to form, when the filtering device is moved in the second direction of movement, at least one leakage path through which the fluid bypasses the filter. According to one embodiment, the filtering device is configured to be placed facing an inner wall of a container in which the fluid is contained and the leakage path is formed, at least in part, by a portion of space between said inner wall of the container and an outer wall of the filter device. According to one embodiment, the filtering device has an outer envelope complementary to an inner wall carried by the container, the leakage path being formed by a portion of space located between said inner wall of the container and the outer casing of the container. filtering device. According to one embodiment, the filtering device is configured so that, when the filtering device is moved in the first direction of movement, all the fluid traversed by the filtering device passes through the filtering path. Alternatively, the filtering device is configured so that, when the filtering device is moved in the first direction of movement, a portion of the fluid traversed by the filtering device passes through the filter path and another part of the fluid. crossed by the filtering device goes through the escape route. According to one embodiment, the minimum passage section of the escape path is less than 1/3, or even 1/5 and preferably less than 1/8 of the minimum section of the filter path. According to one embodiment, the filtering device comprises two filtration stages, each stage comprising a filter, the filtering device being configured so that: when the filtering device is displaced in the first direction of movement, at least a portion of the fluid passes through the filter of the first stage and does not pass through the filter of the second stage, - when the filtering device is displaced in the second direction of movement, at least part of the fluid passes through the filter of the second stage and does not pass through the filter of the first stage. [0010] Thus, the filter path formed by one stage opens into or extends the leak path of the other stage. The filtering device thus has a symmetrical operation. According to one embodiment, the first and second filters are successively arranged in the direction of movement of the filtering device. Each stage is equipped with at least one valve and preferably two valves. The valves of the two stages are mounted in opposition so as to open only one stage in the direction of movement of the filtering device. According to one embodiment, the shape of the filter defines a cavity having at least one opening and at least one filtering wall having an internal face facing towards the inside of the cavity and an external face facing the cavity towards the outside. The filtering device is configured so that the fluid enters the cavity through the opening and escapes through the filter wall from the inner face to the outer face when the filtering device is moved into the cavity. the first meaning. Thus, the fluid passes through the filter from the inside to the outside of the cavity. The residues accumulate on the inside of the cavity and are not exposed to the outside. Thus, in the event of withdrawal and / or manipulation of a used filter, the residues remain trapped inside the cavity, which reduces the risks of stall and dispersion of the residues as well as contamination of the surrounding environment. - Preferably, the filtering wall is continuous and has a bottom opposite to the opening. Thus the residues can accumulate in the bottom. According to one embodiment, the device is configured to be moved in translation inside a container. The cavity extends in the direction of translation of the filtering device and preferably has a cone portion shape extending in the direction of translation of the filtering device. In a more general way, the cavity extends in the direction of displacement of the filtering device. According to one embodiment, the filtering device comprises a draining device configured to allow a flow of the fluid under the effect of gravity as soon as the filtering device is sufficiently far from an inner wall of the container to be able to flow freely on the periphery of the filtering device. According to one embodiment, the draining device comprises at least one drain hole allowing the fluid it contains to flow outwardly bypassing the valve controlling the outlet of the fluid out of the filter chamber. Thus, even if the valve (s) and / or the valve (s) are (are) closed, the filtering device automatically empties. According to one embodiment, the emptying device comprising a drain filter is arranged in such a way that fluid passing through the drain hole necessarily passes through the drain filter. According to one embodiment, the filter is fixed removably relative to the filter holder. The maximum section of the filter, taken in a plane perpendicular to said direction of displacement, is greater than 60% of the section of the inner wall of the container and preferably greater than 70% and preferably greater than 90%. According to one embodiment, the filter holder is made of metal and the filter is preferably made of metal. According to one embodiment, all the parts constituting the valves are made of metal. Preferably, the fluid is a liquid. According to one embodiment, the liquid comprises or is formed of liquid metal. According to another embodiment, the filtering device comprises a device for diverting the fluid, comprising at least one valve and preferably openings, orifices and conduits, and configured so that when part of the fluid contained in the container passes through the filter in the first traversing direction, the fluid passes through the filter from a first wall to a second wall of the filter. The bypass device is further configured to prevent fluid from passing through the filter from said second wall to the first wall of the filter when the filter device is moved in the second direction of travel. According to another embodiment, the invention relates to a system comprising a container adapted to contain a fluid to be filtered and a filtering device according to the invention, disposed inside the container and configured to be moved manually or mechanically to the interior of the container so as to filter the fluid at least when moved in a first direction. Other optional features of the invention, which can be implemented in combination in any combination or alternatively, are indicated below: Advantageously, the container is fixed. According to one embodiment, the container is a pipe or a tank. According to one embodiment, the system is configured so that the filtering device can be moved freely in the container. Thus, the filtering device is not articulated on the container. Furthermore, the filtering device is not geometrically constrained by the container. According to one embodiment, the container has an inner wall and the filtering device comprises at least one longitudinal scraper configured to scrape the inner wall of the container and suspend the glued residues on the walls of the container. According to one embodiment, the longitudinal scraper protrudes with respect to an outer casing of the filtering device. According to one embodiment, the filtering device is configured to be displaced in translation inside the container and the longitudinal scraper 25 extends mainly in a plane perpendicular to the translation device filtering direction. Alternatively, if the filtering device is configured to be rotated inside the container then the scraper extends mainly in a direction parallel to the axis of rotation of the filtering device. According to one embodiment, the filtering device comprises, at at least one of its ends, at least one end scraper protruding beyond an outer envelope of the filtering device for scraping a wall of bottom of the container and suspend the residues deposited on the bottom. [0011] According to another embodiment, the invention relates to a process for the depollution of a fluid, the method comprising the displacement within a fluid to be filtered of a filtering device according to the invention immersed at least partly in the fluid. [0012] According to a non-limiting embodiment, the fluid is contained in a pipe or tank fitted to a nuclear reactor or a plant and the displacement of the filtering device is carried out manually or mechanically. According to another non-limiting embodiment, the fluid is water contained in the sea or in a lake and the displacement of the filtering device is caused by waves or waves. In this case the filtering device comprises a flotation device allowing it to remain on the surface or at a desired depth. In this embodiment, the filtering device does not evolve in a container, except to consider that the shoreline and the bottom bordering the body of water form a container. The filter device is configured to be moved in water by waves and waves. Thus, the filtering device is driven in motion, for example in a pendulum movement, relative to the sea floor. Other objects, features, and advantages of the present invention will be apparent from the following description and accompanying drawings. It is understood that other benefits may be incorporated. BRIEF DESCRIPTION OF THE FIGURES The accompanying drawings are given by way of example and are not limiting of the invention. These drawings are schematic representations and are not necessarily at the scale of the practical application. The objects, objects, as well as the features and advantages of the invention will become more apparent from the detailed description of an embodiment thereof which is illustrated by the following accompanying drawings in which: FIG. diagram of a longitudinal sectional view of a first embodiment of the invention, the filtering device being moved in a first direction of movement relative to a pipe in which it is arranged. FIG. 2 is a diagram of a sectional view of the embodiment illustrated in FIG. 1 in which the filtering device is moved in a second direction of displacement opposite to the first direction of movement. FIG. 3 is a sectional view of the embodiment illustrated in FIG. 1 in which the filtering device is removed from the pipe or is placed in a wider section of the pipe to automatically ensure the emptying of the filtering device; . FIG. 4 is a diagram of a longitudinal sectional view of a second embodiment of the invention comprising two filtration stages and allowing filtering by one of these two stages in each of the filtering directions. FIG. 5 is a diagram of a longitudinal sectional view of a third embodiment permitting a filtration of the fluid by the same filter whatever the direction of movement of the filtering device, this figure shows the flow of the fluid when the filtering device is moved in a first direction. FIG. 6 shows FIG. 5 and shows the flow of the fluid when the filtering device is moved in a first direction. - Figure 7 shows the filter device of the embodiment of Figure 5 in a longitudinal section offset by 90 ° with respect to the section of Figure 5 and during a drain. FIG. 8 is a perspective view of the embodiment of FIG. 8. A first embodiment will now be described with reference to FIGS. 1 to 3. In this embodiment, the filtering system comprises a device 30. filter 10 inserted in a container 1. The container 1 is typically a conduit for the passage of fluid. It can also be a tank or a tank. The filtering device 10 comprises a main filter 14, a filter holder 100 and a device for moving the filter holder. Typically, this displacement device is a perch 11 secured to the filter holder 100 and operable by an operator or operable motorized manner. Under the actuation of the displacement device, the filtering device 10 slides along the pipe and thus acts as a piston inside the latter. [0013] The filter device 10 forms, in this embodiment, a single filtration stage. The filtration stage comprises the main filter 14 and a filtering chamber inside which the main filter 14 is arranged, the filtering chamber being delimited by a body 101 of the filter holder 100 extending substantially longitudinally and by two transverse walls each forming a valve block 103, 107. The filter chamber is also equipped with at least one valve 102, 106 as will be detailed later. Preferably, the filtering chamber has two ends and comprises at least one valve 102, 106 at each of its ends. With the exception of drain openings 19, 19 'which will be detailed later, the filter chamber defines a sealed chamber whose access is controlled by the valves 102, 106. The main filter 14 defines in the chamber of filtering, two portions 115, 116 located on either side of the inner and outer walls 16 of the main filter 14. The filtration stage comprises at least a first exhaust valve 102 also referred to as a valve cooperating with a valve block 103 integral with the body 101 of the filter holder 100 and having at least one outlet opening 114. This first exhaust valve 102 is configured to pass the fluid through the outlet openings 114 only when the filter device 10 is moved in a first direction of movement 4. Thus, when the filtering device 10 is moved in a second direction of displacement opposite to the first direction of movement 4 or when the filtering 10 is stationary relative to the fluid, the first exhaust valve 102 blocks the passage of fluid and prevents access to the filter chamber. Typically, the first exhaust valve 102 is formed by a valve slidably mounted on the valve block 103 forming a valve seat. A biasing element such as the spring 104 applies a force on the valve to maintain the latter in contact with the seat when the fluid does not exert sufficient reverse pressure. This first exhaust valve 102 is disposed downstream of the main filter 14 when the filtering device is moved in the first direction of displacement 4. Thus, this first exhaust valve 102 prevents the filtered fluid from escaping out of the filtering chamber when the filtering device 10 is actuated in the second direction of displacement 5. The filtration stage comprises another valve said first intake valve 106 cooperating with the valve block 107 and being pressed against the latter by an element as the spring 109. This first intake valve 106 is configured to allow the entry of fluid into the portion 115 of the filter chamber when the filter device 10 is moved in the first direction of movement 4 and for to prevent it otherwise. Preferably, the filtering device 10 comprises a ferrule 112 integral with the body 101 via the valve block 107 and on which is fixed the pole 11. This ferrule 112 comprises orifices 113 allowing the fluid to reach the first intake valve 106 In this embodiment, the first direction of movement 4 thus corresponds to a movement generated by traction exerted on the pole 11. Preferably, a second ring 112 'is provided to form the other end of the filter device 10. This other ferrule 112 'is preferably also provided with at least one orifice 113'. The filtering device 10 also comprises a seal 110 which prevents or limits the passage of the fluid between an inner wall 2 of the container 1 and the filtering device 10. The filter holder 100 comprises at least one outlet opening 105 arranged downstream of the first exhaust valve 102 when filtering device 10 is moved in the first direction 4 and for communicating the fluid escaping from the first exhaust valve 102 with a space portion downstream of the 110. Preferably, a liner 111 forms with the valve block 103 an outlet chamber 118 and carries the outlet opening 105. The shell 112 'is fixed on the liner 111. [0014] The path of the fluid will now be described during a displacement of the filtering device 10 in the first direction 4 with reference to FIG. 1. When the filtering device 10 is moved upwards with reference to FIG. through the filter device 10 from top to bottom as indicated by the arrows 401 to 406. The upstream and downstream of the filter device 10 are located at the top and bottom in this figure 1. The fluid through 401 the orifices 113 of the ferrule 112 and reaches the valve block 103. Under the effect of the fluid pressure, the valve of the second intake valve 106 opens and lets the fluid pass through the inlet opening 108 The fluid thus reaches the portion 115 of the filter chamber facing the inner wall 15 of the main filter 14. This portion 115 of the filter chamber is closed except for the inlet openings 108. The fluid is then forced to cross the filter pr incipal 14 in the filtering direction 200, that is to say from the inner wall 15 to the outer wall 16 of the main filter 14. The fluid thus reaches the filter chamber portion 116 with respect to the wall external filter 16 of the main filter 14. This filter chamber portion 116 is closed with the exception of the drain openings 19 and the outlet openings 114. The section of the latter being significantly greater than that of the drain holes 19, the fluid exerts pressure on the first exhaust valve 102 and moves it away from its seat. The fluid passes 403 through the outlet openings 114 to reach the outlet chamber 118, at least the outlet opening 105 of which opens out 405 from the filter device 10 and downstream of the seal 110 to escape towards the outlet. downstream 406 of the filter device 10. It will be noted that preferably a drain filter 18 is provided for filtering the fluid flowing from the filter chamber portion 116 towards the openings 114 and the drain holes 19. [0015] The fluid has thus traveled a filter path illustrated by the arrows 401 to 406 during which it has passed through the main filter 14 to leave in the latter the residues it contains. It will be noted that a portion of the fluid may also engage in a leakage path 500 defined by the space between the inner wall 2 of the container 1 and the outer casing of the filter device 10. More precisely, the fluid engages 501 in the escape path 500 and enters the filter device 10 through a leakage opening 119 carried by the liner 111 and located upstream of the seal 110. Preferably, the fluid thus enters 502 into a defined leakage chamber 120 by the liner 111 and leaves 503 of the ferrule 112 'downstream of the filter device 10 through the orifice 113'. The section of the escape path 500 is defined by the relative dimensions of the inner wall 2 of the container 1 and the maximum section of the filtering device 10 upstream of the seal 110. This section is determined as a function of the desired filtration rate, the resistance applied to the filter device 10 and the number of back and forth movements that it is desired to perform to obtain a satisfactory filtering. A zero section for the escape path 500 leads to filter in one pass all the fluid. A large section requires a large number of passes to obtain a satisfactory filtering. The path of the fluid will now be described during a displacement of the filtering device 10 in the second direction 5 and with reference to FIG. 2. [0016] When the filtering device 10 translates, with reference to FIG. 2 downwards, the fluid passes through the filtering device 10 from the bottom to the top as indicated by the arrows 601 to 606. The upstream and the downstream of the filtering device 10 are in this case located respectively at the bottom and at the top in FIG. [0017] The fluid enters 601 into the leakage chamber 120 through the orifice 113 'of the ferrule 112'. The leak opening 119 allows the fluid to pass 602 in the escape path 500 downstream of the seal 110 and to travel the escape path 500 to exit downstream 603 of the filter device 10. The portion of fluid that passes upstream of the seal 110 between the inner wall 2 of the container 1 and the filtering device 10 enters 605 through the outlet opening 105 in the outlet chamber 118. The fluid is then blocked 606 by the first exhaust valve 102 remains pressed against its seat under the effect of the fluid pressure and its spring 104. The fluid does not penetrate the filter chamber. If a portion of fluid enters from the leakage path 500 into the filter chamber portion 116 through the drain hole 19, then this fluid can not escape downstream of the filter chamber since the second valve intake 106 blocks it. As will be detailed with reference to the embodiment illustrated in FIG. 4, it is possible to provide a drain valve configured to prevent the fluid from passing from the leakage path to the filter chamber via the orifice 19. [0018] Thus, whatever the path taken by the fluid, it does not cross the filter chamber. Depending on the efficiency of the drain valve, it may not even enter the filter chamber. One can provide a valve 1002 having seat valve block 107. Preferably, the functionality of the valve 1002 is not the same as that of the valve 106. Advantageously, the function of the valve 1002 is double. It allows a drain function by ensuring in the open position at rest, as illustrated in FIG. 4, an opening of the chamber 115 and an equipressure (inside / outside) of the fluid present in the chambers 115 and 116 in order to allow a free flow to the outside of the fluid possibly still present in these chambers. This valve 1002 must be closed in the same way as 106 when the fluid pushes in the direction of displacement 5. In the direction of displacement 4, this valve 1002 contributes as 106 to the passage of the fluid but does not constitute the privileged passage of this fluid. this. [0019] According to the embodiment illustrated in FIGS. 1 to 4, the intake valve has a ring shape. The valve 1002 is located inside the ring, preferably at its center. Thus, the filtration stage is unidirectional. The main filter 14 is traversed in only one direction 200 by the fluid and this regardless of the direction of movement of the filter device 10. This prevents the residues accumulated in the filter are released under the effect of A reverse flow 201. The invention thus greatly improves the filtering and safety during the manipulation of the filter. [0020] Thus, in this embodiment illustrated in FIGS. 1 and 2, the derivation device which makes it possible to control the flow of the fluid through the filtering device comprises in particular the valves 102, 106, the inlet openings 108, the openings of output 105, 114. [0021] Moreover, it will be noted that the main filter 14 forms a cavity. As described above, the main filter 14 is traversed only in the direction 200, that is to say from its inner wall 15 to its outer wall 16. Thus, the residues are trapped inside the cavity. This avoids the dispersion of residues when handling a used filter. [0022] Preferably, the cavity has an opening accessible from the openings 108 of the valve block 107 and also has a bottom 17. Outside its opening, the main filter 14 is preferably continuous. Manipulated with its bottom turned downwards, the main filter 14 thus prevents the residues from escaping by gravity, which further enhances safety. [0023] Preferably, the main filter 14 is thus removable to be replaced or cleaned. It is for example mounted tight between the body 101 and the valve block 107 by crushing the filter gasket 123 between these two parts. More specifically, the valve block 107 has an inner section that corresponds to the outer section of the base of the main filter 14 on which it rests, which allows easy positioning of the main filter 14 relative to the valve block 107. The body 101 has meanwhile a shoulder 121 configured to come into contact with the filter gasket 123, itself in contact with the base of the main filter 14 on a face opposite to that which bears on the valve block 107. [0024] The valve block 107 is assembled on the body 101 for example by being screwed on the latter. The filter gasket 123, made of a filtering material, ensures the locking of the filter 14. In order to remove the main filter 14, it is sufficient to disassemble the valve block 107 and the body 101 which allows access to the main filter 14 and to to seize it easily. The invention thus allows a particularly simple, fast and reliable replacement of the main filter 14. [0025] Preferably, at least one circumferential scraper 150 mounted on the periphery of the filtering device 10 protrudes beyond the outer envelope of the latter in order to scrape the inner wall 2 of the container 1 during the displacement of the filtering device 10. impurities that can be deposited on the walls 2 are thus unhooked and suspended. Preferably, the scraper 150 has a discontinuous section to allow the passage of the fluid. Advantageously, in the direction of translation of the filter device 10, a plurality of circumferential scrapers 150 are disposed with an angular offset around this direction, so that the superposition of the circumferential scrapers 150 in a projection perpendicular to the direction of translation, presents a continuous profile all around the filter device 10, thus allowing to scrape the entire surface of the inner wall 2, even though the filter device 10 performs only translational movements. [0026] According to alternative embodiment or combined with the circumferential scrapers 150, the seal 110 may be configured to act as scraper. The filtering device 10 also comprises end wipers 151, configured to scrape a wall of the container 1 disposed substantially perpendicular to the direction of translation of the filtering device 10. Such a wall may for example constitute an elbow, a pipe or the bottom of a tank. FIG. 3 illustrates the automatic emptying of the filtering device 10 when it is removed from the fluid or when it is brought into a section of the container 1 which is large enough so that the seal 110 does not apply to the inside wall 2 of the container 1. The fluid 3 accumulated in the filter chamber flows by gravity through the drain filter 18. The fluid 3 is blocked at the outlet openings 114 by the first exhaust valve 102 and flows through the This emptying may be carried out outside the container 1, or even inside the container 1 in a volume of the container containing no fluid. In the latter case, the fluid 3 flowing from the emptying remains in the container 1 and the filtering device 10 can be removed from the container 1 without any fluid flow or with only a few drops. This turns out to be very advantageous in practice, when the fluid presents a radiological and / or chemical or even bacteriological hazard. In the embodiment described with reference to FIGS. 1 to 3, the filter device 10 comprises a single filtration stage. Filtration occurs only when the filtering device 10 is moved in only one direction, that referenced 4. It can thus qualify this filter device 10 unidirectional. The embodiment that will now be described with reference to Figure 4 is bidirectional, that is to say, it filters the fluid in both directions of displacement. For this, the filtering device 10 has two stages 12, 12 'of filtration. Each stage provides filtering in one direction. These two stages 12, 13 are preferably symmetrical. Thus, when the filtering device 10 is moved in the direction 4, the stage 12 provides the filtering and the filter of the stage 13 is not traversed by the fluid. Conversely, when the filtering device 10 is moved in the direction 5, the stage 13 ensures the filtering and the filter of the stage 12 is not traversed by the fluid. The stage 12 corresponds to the filtering device 10 described with reference to FIGS. 1 to 3. The stage 13 also corresponds to the filtering device 10 described with reference to FIGS. 1 to 3 being arranged symmetrically with the stage 12 according to FIG. a plane perpendicular to the direction of movement of the filter device 10 and passing through the seal 110. Thus, when the filtering device 10 is placed in the direction 4, the fluid escapes (see the arrow 405 of Figure 1) outside the chamber 118 through the outlet opening 105, this fluid reaches the volume closed by the outer wall of the filter device 10 downstream of the seal 110 and the inner wall 2 of the container 1, which volume corresponds to the leakage path 500 'for the stage 13. The fluid then no longer enters the filtering device 10 and flows downstream. The fluid has not entered the filter chamber of the stage 13 but having borrowed the escape route 500 opens through the leak aperture 119 in the trailing chamber 120. This trailing chamber 120 corresponds for the floor 13 to an exit room. The fluid reaching this chamber 120 keeps the second exhaust valve 102 'closed, which prevents it from reaching the filter chamber of the stage 13. [0027] As an illustration, in this example, the second exhaust valve 102 'has a different structure the first exhaust valve 102 which is functionally symmetrical. Indeed, while the first exhaust valve 102 rests on a translational valve, the second exhaust valve 102 'rests on a ball valve 1021' with a seat 1022 'of complementary section. A return means such as the spring 104 'exerts on the ball 1021' a holding force on its seat 1022 'to ensure a closing of the outlet opening 114' except when the fluid exerts sufficient pressure on the ball 1021 ' to counter the force of the spring and move the ball 1021 'away from its seat 1022'. Such a force can be exerted only during a displacement of the filtering device 10 in the direction 5. With a displacement in the direction 4, the ball 1021 'remains in contact with the seat 1022' and the fluid can not gain the filter chamber of stage 13. [0028] Thus, the embodiment shown in FIG. 4 illustrates three different types of valves. It will be appreciated that for each of the valves of each of the embodiments of the invention, any of these types of valves, or any other type of valve, may be used. Preferably, as illustrated, a liner 111 is connected at one of its ends to the valve block 103 of the first stage 12 and at the other of its ends to the valve block 103 'of the second stage 13. This liner defines with the valve block 103 the outlet chamber 118 and defines with the valve block 13 the outlet chamber 120 for the second stage 13. This sleeve 111 carries the openings 105 and 119. [0029] Note also that in this embodiment, a drain valve 191 'has been illustrated as an alternative to the embodiment of the stage 12. This drain valve 191' prevents the fluid from accessing the drain filter 18 'when a displacement in the direction 4. This valve can be provided on all or only one of the stages 12 or 12 'and remains optional. [0030] When the filtering device 10 is moved in the direction 5, the fluid rushes, at least in part, into the opening 113 'of the shell 112' of the stage 12 '. The second intake valve 106 ', that the spring 109' tends to press against its seat carried by the valve block 107 ', opens under the effect of the pressure of the fluid entering the portion 115' of the chamber filtering, passes through the wall of the main filter 14 'and reaches the portion 116' of the filter chamber. Preferably, a drain filter 18 'and provided. The fluid then passes through the draining filter 18 'and exerts on the ball 1021' a force making it possible to open the second exhaust valve 102 '. The fluid escapes through the outlet openings 114 'and enters the chamber 120 which it escapes through the opening 119 located downstream of the seal 110. The fluid then takes the escape route 500 to flow along the outer wall of the filter device 10 and pass downstream of the latter. [0031] The portion of fluid passing through the escape route 500 'from the upstream end of the shell 112' engages in the opening 105 before being trapped in the chamber 118 whose first exhaust valve 102 remains closed. Thus, when the filtering device 10 is displaced in the direction 4, the main filter 14 of the first stage 12 filters the fluid and the fluid does not pass through the main filter 14 'of the second stage 13. Conversely, when the filtering device 10 is moved in the direction 5, the main filter 14 'of the second stage 13 filters the fluid and the fluid does not pass through the main filter 14 of the first stage 12. Thus, with each direction of progression of the fluid, the valves mounted in opposition open only one filtration stage. In this embodiment illustrated in FIG. 4, the bypass device which makes it possible to control the flow of the fluid through the filtering device comprises in particular the valves / intake valves 706, 706 ', 106, 106', the openings 108, 108 ', the outlet openings 105, 114, 114', 119. The embodiment of FIG. 4 has the previously mentioned advantages for the embodiment illustrated in FIGS. 1 to 3. advantage of being bidirectional. [0032] Preferably, in each of the embodiments of the invention, each valve block comprises a plurality of valves as shown in the figures. [0033] The embodiment illustrated in FIGS. 5, 6, 7 and 8 has the advantages of the embodiments illustrated in FIGS. 1 to 3. It is also bidirectional. Furthermore, it has the advantage of using a single filter to filter in each direction of movement and while avoiding the filter wall to be traversed in both directions 200, 201. This filter device 10 comprises a body 101 which cooperates at each of its ends with a valve block 800, 800 'so as to form a sealed enclosure with the exception of inlet openings 708, 708' and outlet opening 114, 114 'and gills 19, 19 'optional emptying. A main filter 14 is housed inside the chamber forming the filtering chamber. A bypass device comprising inlet valves / valves 706, 706 'allows to allow or prevent the fluid from accessing the filter chamber. The filtering chamber has an internal portion 115 delimited by the inner wall 15 of the main filter 14 and by the valve blocks 800, 800 'and an outer portion 116 delimited by the outer wall 16 of the main filter 14, by an inner wall. of the body 101 and the valve blocks 800, 800 '. Each of the inlet valves / valves 706, 706 'allows the fluid to access the portion 115 of the filter chamber located inside the main filter 14. These two / intake valves 706, 706' are configured to not be open simultaneously. The portion 115 of the filter chamber is closed except for the openings 708, 708 'controlled by the intake valves / valves 706, 706'. The fluid arriving in the portion 115 of the filter chamber can escape only through the main filter 14 from its inner wall 15 to its outer wall 16. Thus, the fluid passes through the main filter 14 still in the same direction 200. The outlet openings 114, 114 'allow the fluid that has passed through the fluid to leave the portion 116 of the filter chamber and exit the filtering device 10. [0034] This filter device 10 and its derivation device will be detailed with reference to Figure 5 which illustrates an embodiment in which the filter device 10 is moved in the direction 5, that is to say down. This displacement can be generated by a movement applied to a pole attached to the filtering device 10 by a ferrule 112 'and a fixing housing of the pole 122. Preferably, the filtering device 10 is symmetrical with respect to a perpendicular median plane to the direction of displacement of the filter holder 100. In this figure, the filtering device 10 is symmetrical with respect to a vertical plane passing through the middle of the filter holder 100. Thus, in this embodiment also, in each direction fluid progression, the valves mounted in opposition systematically activate the single filtration stage. [0035] The fluid 901 located upstream of the valve block 800 enters 902 into a slot 701 formed in the exhaust valve 702 of a shutter 700. This light 701 is disposed opposite an inlet port 806 carried by the valve block 800 and giving access to an inlet duct 801 which forms at its end an inlet opening 708 opening into the portion 115 of the filter chamber. The end of the inlet duct 801 forms a seat for the intake valve 706 which controls the access of the fluid in the portion 115 of the filter chamber. The fluid that does not pass 903 through the lumen 701 can not enter the filter device. When fluid comes from the inlet conduit 801, it exerts a force 905 to move the intake valve 706 away from the seat 802. The minimum force to move the valve away from its seat is regulated by a spring 705 described in FIG. below and which exerts on the valve a force opposed to that of the fluid. The fluid thus penetrates 906 into the portion 115 of the filter chamber located inside the main filter 14. At the opposite end of this portion 115 of the filter chamber, the ducts 801 are closed off by the flapper. 706 'admission which remains closed under the effect of the fluid 907. The intake valve 706 is attached to a rod 704. It will be noted that apart from any movement of said filter device 10, the intake valves 706, 706 'remain closed because for the intake valve 706 a spring 705 30 disposed between the exhaust valve 702 and a nut 703 attached to the other end of the rod 704 exerts a force which tends to press the intake valve 706 against its seat 802, and for the intake valve 706 ', the rod 704', the spring 705 'and the nut 703' associated with the valve block 800 '. [0036] The fluid can then escape from the portion 115 of the filter chamber only through 908 the filter in the direction 200. The fluid then reaches 909 in the portion 116 of the filter chamber from which it can escape by penetrating 910, 911 into the outlet duct 805 'accessible through the outlet opening 114'. The fluid exerts on the exhaust valve 702 'a force tending to move the exhaust valve 702' away from its seat 808 'and from the outlet orifice 807' of the duct 805 'thus allowing free evacuation 913. In Indeed, the exhaust valve 702 'does not have any light at the right of the outlet port 807' of the conduit 805 '. It will be noted that this separation of the exhaust valve 702 'contributes to pressing the intake valve 706' on its seat 802 '(when the fluid does not put a force on the valve 706'). The two valves 706 'and 702' being integral or at least interconnected, the sealing of the valve 706 'is enhanced since the fluid exerts both a force on the valve 706' and a force on the valve 702 'and that these two forces tend to press the valve 706 'on its seat 802'. Preferably, each flap block 800, 800 'comprises several inlet ducts 801, 801' and several outlet ducts 805, 805 '. FIG. 6 illustrates the filtering device of FIG. 5, when the latter is displaced in opposite direction, that is to say in the direction 4 (upwards in FIGS. 5 and 6), the fluid 901 'penetrates 902 ', 904' in the inlet duct 801 'passing through the lumens 701' of the exhaust valve 702 'of the fourth valve. At the seat 802 ', the fluid pushes 905' the valve 706 'down and penetrates 906' in the portion 115 of the filter chamber. With the intake valve 706 remaining closed, the fluid passes through 908 'the wall of the main filter 14 and reaches the portion 116 of the filter chamber. If fluid rises through the outlet duct 805 ', it can not escape because the fluid 903' upstream of the exhaust valve 702 'maintains the latter in contact with the valve block 800' and thus closes the ends of the duct 805 'output. [0037] The fluid can then escape 910 ', 911' only through the conduit 805 and its outlet port 807 and thus regains 912 ', 913' downstream of the filter device 10. The fluid can also escape through the Gaps 19, 19 ', preferably as illustrated in FIG. 6, gaskets 110 are disposed upstream and downstream of each drain mouth 19, 19'. Thus, the fluid passing through the hearing 19 or 19 'penetrating into the space between the filter device 10 and the inner wall 2 of the container 1 is confined in this space. Thus, regardless of the direction of movement of the filter device 10, the fluid is filtered and the main filter 14 is traversed in a single direction 200. The residues are not released by a reverse flow. Furthermore, a single filter allows filtering in both directions, which facilitates the assembly of the filter device 10 as well as the storage and manipulation of used filters. [0038] Moreover, all residues are trapped on the inner face of the filter which reduces the risk of pollution during handling. Note that the invention nevertheless extends to the case where the filter is traversed in a single direction opposite to the direction 200. In this embodiment illustrated in FIGS. 5 and 6, the bypass device for controlling the flow of the fluid comprises in particular the exhaust valves 702, 702 ', the intake valves 706, 706', the inlet ducts 801, 801 'and the outlet ducts 805, 805', the outlet openings 114, 114 '. Preferably, the filter device 10 has a simple and robust structure. In the illustrated example, each valve block 800, 800 'refers to the body 101 of generally cylindrical shape to form an enclosure. It is possible to provide fastening by screwing as illustrated by the threads 804, 804 'carried by the valve blocks 800, 800' and the body 101. Prior to this assembly, it is possible to insert the main filter 14 which is then in the form of a filter cartridge. Like the filtering devices illustrated in the previous figures, that of Figures 5 and 6 is completely removable which facilitates its maintenance and cleanup. The sectional view of Figure 7 shows the gills 19, 19 'emptying. These gills 19, 19 'drain are disposed at each end of the portion 116 of the filter chamber. When the device is removed from the container or is brought into a wider section of the container allowing a flow between the seals 110 and the inner wall of the container, the fluid 3 in the portion 116 escapes by gravity outlets 19, as illustrated by the arrows 920 to 922. The gills 19 'equipress the chambers 115 and 116 with the external medium, facilitating gravity flow through the gills 19. This emptying is thus automatic. Preferably, there is provided at each end of the main filter 14, a filter portion with higher filtering power so as to be able to form two drain filters 181, 181 'able to ensure particularly fine filtering of the fluid before being evacuated by the gills 19 emptying. Alternatively or in combination, the elements 181 'and 181' are end ferrules of the filter 14. Preferably, scrapers 150 are also provided, the operation of which has been previously described. It will be noted that the seals 110 preferably do not have a scraper function and will thus be longitudinally located between the scrapers. The scraping residues are thus filtered. According to another embodiment not illustrated, the seals 110 also act as scrapers. In this case, the scrapers 150 can be deleted. Figure 8 illustrates in perspective the filter device forming a filter cartridge. This figure clearly shows the simplicity of manufacture and assembly of the filter holder which mainly comprises three parts: the valve blocks 800, 800 'and the body 101. The following features are common to all the embodiments described above. The boom 11 is manually or mechanically activatable and can be rigid or flexible. In the case where it is flexible, it is radially flexible and longitudinally incompressible. It can be wrapped around a mandrel and can be driven by driving the mandrel. The pole can also be telescopic. The embodiments described above provide a filtering device configured to be displaced in translation in the fluid. The invention also extends to filter devices movable in rotation. The external geometry of the filter holder is completely adjustable: it can be adapted to any driving geometry. The minimum diameter is a function of the possibility of miniaturization of the filter holder and the filter. [0039] Similarly, the length of the filter and the filter holder can be adapted for each use, in particular by the length of the body 101 alone. Advantageously, these adaptations do not require modifying the valve blocks. [0040] Preferably, the valves internal to the filter holder are metal / metal contact, relative sealing, thus better supporting the chemical aggressiveness (corrosion) of the filtered liquids than could do polymer seals. However, the replacement of metal seals scopes by polymer seals is possible without changing the principle of bidirectional valves. [0041] According to one embodiment, the filter holder is entirely made of metal as are the filters. In this way, they are completely compatible with use in liquid metal and in a very irradiating medium. In the illustrated examples, a single filter purifies the liquid for each filtration direction. Nevertheless, the invention extends to cases where several filters are arranged in series, for example to ensure a progressive filtering of the fluid. Moreover, the filter is adapted to the particle size of the residues; it can have several thicknesses of sieve to avoid clogging fine porosity too quickly with coarse residues. It suffices, for example, to arrange the screen thicknesses according to their increasingly fine porosity, from the inside to the outside of the filter cartridge. This filter holder can be adapted to the fluid container either by modifying the seals (to some extent) or by increasing or decreasing the sections of the components. Sealing towards the inner wall of the container is not a strong requirement, a certain leakage rate can be envisaged to promote the ease of handling of the filter holder to its filtration efficiency. Indeed, a strong filter holder / container sealing will lead in a single pass to filter all the fluid, at the risk of prematurely clogging, while a slight leakage rate can ensure the removal of the filter holder, whatever its rate of closure. It will then be necessary to make several round-trip movements to gradually reduce the density of pollution of the filtrate. [0042] In view of the above, it is clear that a device according to the invention offers many advantages. In particular, compared to known filtering solutions, it is distinguished by its great ease of implementation, its compactness, its very low cost of production and operation. It is easy to disassemble, especially for replacing filter cartridges. It is also particularly reliable. Its reliability comes from the fact that it allows to do without any electronic or electrical component. Moreover, apart from the valves and valves, no mechanism with articulated parts is necessary. [0043] Moreover, it makes it possible to do without any external circuit to the filtered equipment since this filter operates in situ. Indeed, most purification means rely on a transfer of the fluid and its forced passage through the filter media, via a pump and an ad-hoc circuit. Conversely, this filter holder is brought into the liquid to be filtered which can remain static, which, in the case of dangerous fluids, considerably reduces the risk and the costs associated with the implementation of a loop dedicated to the filtration. In addition, it can be adapted to very variable pipe sizes, in inaccessible places and especially for liquids that can not be easily removed from their container. This invasive filter holder is therefore especially adapted to fluids that can not be moved. The system can be manual, which guarantees both a great simplicity of implementation and an indication of clogging the filter by excessive pressure drop and difficulty handling (back and forth) the filter holder. This increase in the pressure drop can also be identified by sensors external to the container and associated with mechanical actuation of the filter holder. Its bidirectional efficiency as well as the retention inside the filter cartridge are particularly advantageous for uses in hazardous environments. For example, the filtering device according to the invention is particularly advantageous for use in a nuclear environment, in particular for cold extraction of the NaK precipitates present in certain types of test devices for irradiation reactors (such as OSIRIS). [0044] Nevertheless, the filtering device according to the invention can receive many other uses such as for example the removal of solid particles in a contaminated liquid (Na, NaK, Pb-Bi, water, etc.), such as nuclear fuel residues. from breakage of pencil sheaths in its coolant. These situations can be found in circuits that are difficult to access during dismantling, in the remains of test devices that have provided duct failure tests or during a post-accident situation requiring prior decontamination of the most radiating solid particles before reprocessing of effluents (in sumps, for example). Specially designed for the nuclear environment, this filter holder can be extended to uses in fluids with other types of dangerousness, bacteriological or chemical in particular. [0045] The purification of a volume of liquid too important for its passage in a dedicated circuit or a volume very difficult to access even by a pole. For this, the seal of the seals can be lowered or even completely remove by removing the seals including scrapers. In this case, the self-drain function should be reconsidered. This use would then rather involve the introduction of the filter holder in an "open" environment, practicing a significant number of back and forth to extract locally pollutants. We would then rely on the homogenization of pollutants in the medium with a concentration decreasing as the oscillations of the filter. [0046] The extraction of residues especially floating in large bodies of water. For this, it is necessary to adapt the inlet section of the fluid and the filter and possibly shorten the height of the filter. It is also possible to remove the self-drain and provide a keel function to force the filter holder to maintain a vertical position. This type of filter holder, completely passive, could then be used for example for the depollution of the seas of their microparticles (millimeter size) such as the area of the Pacific Ocean commonly referred to as the "sixth continent". The filter holder device would then be perfectly independent of any container but simply immersed in a large volume of liquid. It would be displaced by the waves or the swell and would oscillate passively. The invention is not limited to the only embodiments and embodiments described above, but extends to all embodiments within the scope of the claims. [0047] REFERENCES 113. Hole 1. Container 35 114. Outlet opening 2. Inner wall of container 115. Internal chamber portion 3. Filter medium 4. 1 "direction of movement 116. External chamber portion 5. 2nd direction of movement of filtering 40 10. Filtering device 118. Exit chamber 11. Pole 119. Leakage opening 12. Filtration stage 120. Leakage chamber 13. Filtration stage 121. Shoulder 14. Main filter 45 122. Perch attachment housing 15 Inside wall of filter 123. Filter gasket 16. External filter wall 17. Bottom of the filter 150. Circumferential wiper 18. Drain filter 151. End wiper 19. Drain opening 50 181. Filter end ring 100 Filter holder 14 'Filter 101. Body 15' Internal wall of filter 102. First valve 16 'External wall of exhaust filter 55 17' Bottom of filter 103. Valve block 18 'Drain filter 104 Spring 19 'Drain opening 105. Outlet opening 106. First Valve eligibility 102 'Second valve 107. Valve block 60 exhaust 108. Chamber inlet opening 1021'. Ball 109. Spring 1022 '. Seat 110. Seal 103 '. Valve block 111. Shirt 104 '. Spring 112. Ferrule 65 106 '. Second intake valve 34 705, 705 'Spring 107'. Valve block 35 706, 706 'Valve (or valve) intake 708, 708'. Entrance openings 108 '. Room 109 'entrance opening. Spring 111 '. Ferrule 800. Valve block 112 '. Orifice 801. Inlet conduit 113 '. Outlet opening 40 802. Inlet seat 114 '. Portion of chamber of 803. filter joint 10 filter 804. Thread 115 '. Portion of chamber 805. Filter outlet 806. Inlet port 45 807. Outlet port 151 'End scraper 808. Exhaust seat 15 181. Filter end ferrule 191'. Dump valve 800 '. Valve block 801 '. Entrance duct 500 '. Way of escape 50 802 '. Intake seat 200. Filter direction 803 '. Filter seal 201. Opposite direction 804 '. Filtration thread 805 '. Exit duct 806 '. 401-406 inlet port. Filter path 55 807 '. 500-503 outlet port. Escape route 25 601-603; 605-606: Leakage path 901-913 Filter path 901'-913 'Filter path 700, 700' Shutter 920-922 Drain path 701, 701 'Light 60 1002 Valve 702, 702' Valve (or valve) 1003 Exhaust spring 703, 703 'Nut 704, 704' Rod 65
权利要求:
Claims (29) [0001] REVENDICATIONS1. Filter device (10) configured to be immersed at least partly in a fluid to be filtered and comprising at least one main filter (14) and a filter holder (100) supporting the main filter (14), characterized in that: the filtering device (10) is configured to be moved inside the fluid, so that when the filtering device (10) is moved in a first direction of movement (4), at least a part of the fluid passes through the main filter (14) in a first filtering direction (200); the filtering device (10) is configured to prevent the fluid from passing through the main filter (14) in a second filtering direction (201) opposite to the first filtering direction (200) when the filtering device (10) is moved in a second direction of movement (5) opposite to the first direction of movement (4). [0002] 2. Filtering device according to the preceding claim, wherein the filtering device (10) is configured to be displaced in translation inside a container (1) in which the fluid is contained. [0003] A filter device according to any one of the preceding claims configured to force at least a portion of the fluid to pass through said main filter (14) in the first filtering direction (200) when the filtering device (10) is moved in the second direction of movement (5). [0004] 4. Filtering device according to the preceding claim, wherein the filtering device (10) forms at least one filter chamber comprising the main filter (14) and comprises: - at least a first intake valve (706) configured to allowing the fluid to pass from outside the filter chamber to a first portion (115) of the filter chamber located opposite a first wall (15) of the main filter (14) when the filtering device (10) is moved in the first direction of movement (4) and configured to prevent fluid entry and exit respectively in and out of said first portion (115) when the filter device (10) is moved in the second portion (115). direction of movement (5); at least one second intake valve (706 ') configured to allow fluid to flow from outside the filter chamber to said first portion (115) of the filter chamber when the filter device (10) ) is moved in the second direction of movement (5) and configured to prevent entry and exit of the fluid respectively into and out of said first portion (115) when the filter device (10) is moved in the first direction of displacement (4); the first inlet valve (706) being disposed downstream of the second inlet valve (706 ') with respect to the flow direction of the fluid in the filter device (10) when the latter is displaced in the first direction displacement (4). [0005] 5. Filtering device according to any one of the two preceding claims, comprising at least two outlet openings (114, 114 ') configured to allow the fluid to pass from a portion (116) of the filter chamber located opposite the a second wall (16) of the main filter (14) opposite the first wall (15) to the outside of the filter chamber downstream of the filter device (10), one (114) of the two openings for the outlet of the fluid downstream of the filter device (10) when the latter is displaced in the first direction (4) and the other (114 ') of the two openings for the outlet of the fluid downstream of the filtering device ( 10) when the latter is moved in the second direction (5). [0006] 6. Filtering device according to the preceding claim, comprising at least two exhaust valves (702, 702 '), each respectively associated with one of the at least two outlet openings (114, 114'), each flap of exhaust (702, 702 ') being configured to allow passage of the fluid from the second portion (116) downstream of the filter device (10) and to prevent the passage of fluid from upstream of the filter device (10) to the second portion (116) of the filter chamber. [0007] 7. Filtering device according to the preceding claim, wherein each exhaust valve (702, 702 ') prevents the passage of fluid to the outlet opening (114, 114') associated with it when it is plated on a valve seat (808, 808 ') and includes a lumen (701, 701') disposed at an inlet port (806, 806 ') allowing the fluid upstream of the filter device (10 ) to access the first and second intake valves (706, 706 '). [0008] A filter device as claimed in any one of claims 1 or 2, configured to prevent the fluid from passing through the main filter (14) when the filter device (10) is moved in the second direction of movement (5). . [0009] 9. Filtering device according to the preceding claim comprising at least a first exhaust valve (102) disposed downstream of the main filter (14), relative to the direction of movement of the fluid relative to the filter device (10) when the latter is moved in the first direction of movement (4) and arranged upstream of the main filter (14), relative to the direction of movement of the fluid relative to the filtering device (10) when the latter is displaced in the second direction of movement (5). ), said first exhaust valve (102) being configured: - to open under the pressure of the fluid having passed through the main filter (14) when the filtering device (10) is displaced in the first direction of movement (4) ) so as to allow the fluid having passed through the main filter (14) to leave the filtering device (10); - to stay closed otherwise. [0010] 10. Filtering device according to any one of the two preceding claims comprising at least a first intake valve (106) disposed upstream of the main filter (14), relative to the direction of movement of the fluid with respect to the filtering device ( 10) when the latter is moved in the first direction of movement (4) and disposed downstream of the main filter (14), relative to the direction of movement of the fluid relative to the filter device (10) when the latter is moved in the second displacement direction (5), said first inlet valve (106) being configured: - to open under the pressure of the fluid when the filtering device (10) is moved in the first direction of displacement (4) so as to allowing the fluid to reach the main filter (14); - to stay closed otherwise. [0011] 11. Filtering device according to any one of the three preceding claims, configured so as to form, when the filtering device (10) is moved in the first direction of movement (4), at least one filtering path (401- 406) passing through the main filter (14) and configured to form, when the filter device (10) is moved in the second direction of travel (5), at least one escape path (500-503) by wherein the fluid bypasses the main filter (14). [0012] 12. Filtering device according to the preceding claim, configured to be placed facing an inner wall (2) of a container (1) in which the fluid is contained and wherein the leakage path (500-503) is formed at least in part by a portion of space between said inner wall (2) of the container (1) and an outer wall of the filter device (10). [0013] 13. Filtering device according to any one of the two preceding claims, configured so that, when the filtering device (10) is moved in the first direction of displacement (4), all the fluid traversed by the device of filtering (10) goes through the filter path (401-406). [0014] 14. Filtering device according to any one of claims 11 or 12, configured so that, when the filter device (10) is moved in the first direction of movement (4), a portion of the fluid traversed by the device filter (10) passes through the filter path (401-406) and another portion of the fluid traversed by the filtering device (10) passes through the leakage path (500-503). [0015] A filter device according to any one of the preceding claims, comprising two filter stages (12, 12 '), each stage (12, 12') comprising a main filter (14, 14 '), the filter device (10) being configured so that: - when the filtering device (10) is displaced in the first direction of movement (4), at least a portion of the fluid passes through the main filter (14) of the first stage (12). ) and does not pass through the main filter (14 ') of the second stage (13), - when the filtering device (10) is displaced in the second direction of movement (5), at least a portion of the fluid passes through the main filter (14 ') of the second stage (12') and does not pass through the main filter (14) of the first stage (12). [0016] A filter device according to any one of the preceding claims, wherein the shape of the main filter (14) defines a cavity having at least one opening and at least one filter wall having an inner face (15) facing the interior of the cavity and an outer face (16) facing outwards the cavity, the filtering device being configured so that the fluid enters the cavity through the opening and escapes through the filtering wall from the inner face (15) to the outer face (16) when the filtering device (10) is moved in the first direction (4). [0017] 17. Filtering device according to the preceding claim, configured to be displaced in translation inside a container (1), wherein the cavity extends in the direction of translation of the filter device (10) and wherein the cavity preferably has a cone-shaped portion extending in the direction of translation of the filter device (10). [0018] 18. Filtering device according to any one of the preceding claims, comprising a drain device configured to allow fluid flow under the effect of gravity as soon as the filtering device (10) is sufficiently far from a wall internal (2) of a container (1) inside which is contained the fluid to be able to flow freely around the filter device (10). [0019] 19. Filtering device according to the preceding claim, wherein the emptying device comprises at least one opening (19, 19 ') drain allowing the fluid it contains to flow outwardly bypassing a valve d' exhaust (102, 102 ', 702, 702') configured to control the outlet of the fluid from a filter chamber containing the main filter (14). [0020] 20. Filtering device according to the preceding claim, comprising a drain filter (18) arranged in such a way that fluid passing through the draining orifice (19, 19 ') necessarily traverses the drain filter (18). [0021] A filter device according to any one of the preceding claims, wherein the main filter (14) is removably attached to the filter holder (100). [0022] 22. Filtering device according to any one of the preceding claims, wherein the filter holder (100) is made of metal and wherein the main filter (14) is preferably metal. [0023] 23. System comprising a container (1) adapted to contain a fluid to be filtered (14) and a filtering device (10) according to any one of the preceding claims, the filtering device (10) being disposed inside the container (1) and being configured to be moved manually or mechanically inside the container (1) so as to filter the fluid at least when moved in a first direction (4). [0024] 24. System according to the preceding claim, wherein the container (1) is a pipe or a tank. [0025] 25. System according to any one of the two preceding claims, wherein the container (1) has an inner wall (2) and the filtering device (10) comprises at least one longitudinal scraper (150) configured to scrape the inner wall. (2) the container (1). [0026] 26. System according to any one of the preceding claims, wherein the filtering device (10) comprises, at at least one of its ends, at least one end wiper (151) projecting beyond an outer casing of the filter device (10). [0027] 27. Process for the depollution of a fluid, the method comprising the displacement of a filtering device (10) according to any one of claims 1 to 22 in a fluid in which at least a portion of the device is immersed. filtering (10). [0028] 28. A method of pollution control according to the preceding claim, wherein the fluid is contained in a pipe or a tank equipping a nuclear reactor or a factory and wherein the displacement of the filtering device (10) is carried out manually or mechanically . [0029] 29. The pollution control method according to claim 27, wherein the fluid is water contained in the sea or in a lake and wherein the displacement of the filter device (10) is caused by swell.
类似技术:
公开号 | 公开日 | 专利标题 EP3116622B1|2018-04-11|Filtering device EP1445024A1|2004-08-11|Magnetic sludge filtering device FR2474330A1|1981-07-31|FILTERING METHOD AND APPARATUS, PARTICULARLY FOR PURIFYING LARGE VOLUMES OF FLUID FR2601182A1|1988-01-08|METHOD FOR THE RADIOACTIVE DECONTAMINATION OF A LUBRICANT EP0923972A1|1999-06-23|Selfwashable device for separating and filtering solid particles in a liquid flow and use in a fuel injection system provided with such a device WO2007132073A1|2007-11-22|System for cleaning an oil tank and method of cleaning an oil tank EP2694442B1|2017-05-03|Device for neutralizing acid condensates CA2283686A1|1998-09-24|Wellhead device for retaining the solid particles carried by the production fluid FR2518892A1|1983-07-01|FUEL POLLUTION DETECTOR WITH RETENTION VALVE EP0819310B1|1999-12-29|Device for retaining ferromagnetic articles contained in a liquid circulating in a pipe network FR2771654A1|1999-06-04|MULTI-FUNCTION METHOD AND APPARATUS FOR THE MAINTENANCE OF METASTABLE LIQUIDS FR2878541A1|2006-06-02|Sewer well for e.g. collection and/or sanitation network, has removable device constituted of cartridge comprising annular stop, core maker and lifting ring permitting to grab cartridge using hook FR3073160A1|2019-05-10|DEVICE AND METHOD FOR FILTERING LIQUID LIQUID EFFLUENT EP3838056A1|2021-06-23|Water filtering cartridge and associated portable filtering device for filling tanks of household appliances EP3389816B1|2020-05-06|Apparatus for filtering a suspension EP2310272B1|2012-01-25|System for injecting mortar into a container WO2015004401A1|2015-01-15|Method for decontaminating a filter CA3086663A1|2019-06-06|Immersed device for swimming pool filtration FR2710632A1|1995-04-07|Device for magnetic sensing with mechanical cleaning and its use for the removal of sludge from heating circuits EP1310716B1|2006-07-26|Deaerator WO2002045829A1|2002-06-13|Backwashing of a hollow fibre filter operating in frontal mode FR3088386A1|2020-05-15|FILTRATION DEVICE FOR A MOTOR-COMPRESSOR GROUP FR3102765A1|2021-05-07|Improved filtration system WO2005002708A1|2005-01-13|Device for the separation of particles contained in a fluid stream and cleaning installation comprising one such separation device EP1310714A1|2003-05-14|Valve, particularly a valve for a deaerator
同族专利:
公开号 | 公开日 EP3116622B1|2018-04-11| EP3116622A1|2017-01-18| WO2015136062A1|2015-09-17| US20170246566A1|2017-08-31| US10532300B2|2020-01-14| FR3018459B1|2018-01-05|
引用文献:
公开号 | 申请日 | 公开日 | 申请人 | 专利标题 EP0920894A1|1997-12-03|1999-06-09|Niro Process Technology B.V.|Installation for separating and purifying solids| US20140008311A1|2012-06-25|2014-01-09|Grayl Inc.|Filtration container assemblies and methods|EP3368183A4|2016-08-16|2018-10-24|Bonvi Water, Inc.|Water container with floatable filter system and method| US11033841B1|2012-05-25|2021-06-15|Plenty Company, LLC|Expandable water filter reservoir|US3595397A|1969-05-23|1971-07-27|Anti Pollution Devices Inc|Filter apparatus| US4280906A|1979-11-21|1981-07-28|Ab Asea-Atom|Filter for separating solid contaminants from a fluid, especially solid contaminants in a reactor cooling water used in nuclear reactor plants| SE0301937D0|2003-07-01|2003-07-01|Blue Air Ab|water Filters| FR2862887B1|2003-12-02|2007-07-27|Novintec|BIDIRECTIONAL FILTER FOR HYDRAULIC CIRCUIT| US7790117B2|2008-03-21|2010-09-07|Scientific Plastic Products, Inc.|Filter vial|RU181860U1|2018-03-05|2018-07-26|Российская Федерация, от имени которой выступает Государственная корпорация по атомной энергии "Росатом"|DEVICE FOR CLEANING THE SURFACE OF A LIQUID METAL HEAT CARRIER OF A FAST NUCLEAR REACTOR FROM MECHANICAL IMPURITIES| RU2724239C1|2020-01-17|2020-06-22|Федеральное автономное учреждение "25 Государственный научно-исследовательский институт химмотологии Министерства обороны Российской Федерации"|Two-component fuel filter mixer| CN112973242A|2021-02-05|2021-06-18|陈吉辉|Weaving sewage treatment plant|
法律状态:
2016-03-24| PLFP| Fee payment|Year of fee payment: 3 | 2017-03-30| PLFP| Fee payment|Year of fee payment: 4 | 2018-03-29| PLFP| Fee payment|Year of fee payment: 5 | 2019-03-29| PLFP| Fee payment|Year of fee payment: 6 | 2020-12-18| ST| Notification of lapse|Effective date: 20201110 |
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申请号 | 申请日 | 专利标题 FR1452056A|FR3018459B1|2014-03-12|2014-03-12|FILTERING DEVICE| FR1452056|2014-03-12|FR1452056A| FR3018459B1|2014-03-12|2014-03-12|FILTERING DEVICE| PCT/EP2015/055249| WO2015136062A1|2014-03-12|2015-03-12|Filtering device| US15/125,093| US10532300B2|2014-03-12|2015-03-12|Filtering device| EP15709682.7A| EP3116622B1|2014-03-12|2015-03-12|Filtering device| 相关专利
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