An active strainer contains a housing with a cover, a base and side surfaces made in the form of filtering elements, pipes with channels fixed at one end at the central vertical axis of the strainer and configured to supply purified fluid from the central part of the strainer to the filtering elements from the other end of the pipe through channels, wherein the strainer housing is made of two parts, an upper and a lower one, each part is equipped with at least one filtering element, the turbine is installed between the upper and lower part and configured to rotate during the fluid flow passage through it, the turbine shaft is connected with the pipes, which are capable of sampling the purified fluid from the strainer housing during rotation of the turbine.

The invention relates to a liquid recovery system for a motor vehicle and to a vehicle including such a recovery system that that includes at least one liquid intake that communicates with a tank and is referred to as the first tank, which is designed to store liquid from the liquid intake and where the liquid intake is arrangeably designed below the vehicle's beltline.

The invention relates to a liquid recovery system for a motor vehicle and to a vehicle including such a recovery system that that includes at least one liquid intake that communicates with a tank and is referred to as the first tank, which is designed to store liquid from the liquid intake and where the liquid intake is arrangeably designed below the vehicle's beltline.

A filter includes a filter assembly deployed within a pressure vessel. The filter includes a series of filter configurations arranged along a central flow path connected to an outlet. Each filter configuration has filter screens overlying at least one filtrate channel which directs filtered fluid to the central flow path, A partition is deployed within the pressure vessel so as to subdivide the pressure vessel into a first filter chamber and a second filter chamber, each containing a number of the filter assemblies. A flow diverter is deployed in the central flow path for diverting a flow of filtered liquid passing along the central flow path from the first filter chamber so as to flow outwards from the central flow path to undergo a second filtering in the second filter chamber. Also disclosed is an outlet flow throttling arrangement to avoid overload of a backwash cleaning system.

A filter includes a filter assembly deployed within a pressure vessel. The filter includes a series of filter configurations arranged along a central flow path connected to an outlet. Each filter configuration has filter screens overlying at least one filtrate channel which directs filtered fluid to the central flow path, A partition is deployed within the pressure vessel so as to subdivide the pressure vessel into a first filter chamber and a second filter chamber, each containing a number of the filter assemblies. A flow diverter is deployed in the central flow path for diverting a flow of filtered liquid passing along the central flow path from the first filter chamber so as to flow outwards from the central flow path to undergo a second filtering in the second filter chamber. Also disclosed is an outlet flow throttling arrangement to avoid overload of a backwash cleaning system.

A method and apparatus for passive self-cleaning filtration of a liquid containing suspended solids is disclosed. A filter assembly of upright cylindrical filter tubes having open, downwardly-facing ends is placed within a tank of unfiltered liquid. The filter assembly is positioned in the flow of liquid through the tank such that the unfiltered liquid must pass through the filter tubes prior to discharge from the tank. The inner walls of the filter tubes are smooth with small filtering holes. Unfiltered liquid is passes up into the filter tubes and the solids are collected in the tubes and on the smooth walls. Filtered liquid that has passed through the filter tubes is kept separated from the unfiltered liquid by a barrier that functionally prevents passage of unfiltered liquid. The filtered liquid is passed out of the tank. A filter housing protects the filtered liquid and the outside surface of the filter tubes from unfiltered liquid. The solids that have collected in the filter tubes and on the smooth inner walls of the filter fall out of the open, downwardly-facing ends of the filter tubes. The filter housing has a lower chamber below the filter assembly with a sloping floor and an opening for unfiltered liquid to enter the filter housing and accumulated solids to leave the housing. The sloping floor encourages solids that fall out of the filter tubes to move down the slope and out of the housing. The filter assembly may be raised at least partially out of the tank and cleaned by washing the solids down the inside walls of the filter tubes, onto the sloping floor, and back into the unfiltered liquid. The filter assembly may be associated with a pump which pumps filtered liquid from the tank.

A method and apparatus for passive self-cleaning filtration of a liquid containing suspended solids is disclosed. A filter assembly of upright cylindrical filter tubes having open, downwardly-facing ends is placed within a tank of unfiltered liquid. The filter assembly is positioned in the flow of liquid through the tank such that the unfiltered liquid must pass through the filter tubes prior to discharge from the tank. The inner walls of the filter tubes are smooth with small filtering holes. Unfiltered liquid is passes up into the filter tubes and the solids are collected in the tubes and on the smooth walls. Filtered liquid that has passed through the filter tubes is kept separated from the unfiltered liquid by a barrier that functionally prevents passage of unfiltered liquid. The filtered liquid is passed out of the tank. A filter housing protects the filtered liquid and the outside surface of the filter tubes from unfiltered liquid. The solids that have collected in the filter tubes and on the smooth inner walls of the filter fall out of the open, downwardly-facing ends of the filter tubes. The filter housing has a lower chamber below the filter assembly with a sloping floor and an opening for unfiltered liquid to enter the filter housing and accumulated solids to leave the housing. The sloping floor encourages solids that fall out of the filter tubes to move down the slope and out of the housing. The filter assembly may be raised at least partially out of the tank and cleaned by washing the solids down the inside walls of the filter tubes, onto the sloping floor, and back into the unfiltered liquid. The filter assembly may be associated with a pump which pumps filtered liquid from the tank.

A device for separating the constituents of a fluid medium includes an element for separating the constituents, helping to define, upstream and/or downstream from the separation element, a closed chamber, to which at least one conduit is connected. The conduit includes at least one activatable sealing device, the activation of which is capable of at least partially closing and opening the conduit. The device also includes a controller for the activation of the sealing device, controlling the closing and opening, at least partially, of the conduit cyclically, at a frequency greater than 0.008 Hz.

A filtration system with a filter out of which filtered medium exits are provided. The system includes a control panel that receives pressure and flow rate information of the medium and uses the pressure information to send a first signal to prevent a pressure differential of the medium from exceeding a first set point yet maintain filtration of the medium. The control panel uses the flow rate information to send a second signal to prevent the flow rate of the medium from exceeding a second set point yet maintain filtration of the medium. An actuated flow control valve is present that opens at different amounts, and the medium flows through the actuated flow control valve.

A filtration system with a filter out of which filtered medium exits are provided. The system includes a control panel that receives pressure and flow rate information of the medium and uses the pressure information to send a first signal to prevent a pressure differential of the medium from exceeding a first set point yet maintain filtration of the medium. The control panel uses the flow rate information to send a second signal to prevent the flow rate of the medium from exceeding a second set point yet maintain filtration of the medium. An actuated flow control valve is present that opens at different amounts, and the medium flows through the actuated flow control valve.