A tank has two substantially parallel side surfaces, a tank first side surface and a tank second side surface, and the return filter is provided in the tank via an insertion hole formed in the tank first side surface. The strainer has one end provided on an outflow portion provided on a bottom surface of a filter case and the other end provided on the tank second side surface.

Disclosed herein is a method, system, and apparatus, for filtering liquid, which uses negative air pressure to draw liquid stream through a filter screen and which cleans that filter screen by periodically modulating the negative air pressure to allow the liquid stream to wash any contaminants from the surface of the filter screen.

A nozzle apparatus is configured to distribute a primary fluid. The nozzle apparatus includes a support plate; a fluid manifold; a fluid nozzle element; an actuator gear assembly; and a pincher gear assembly having a first pincher gear and a second pincher gear mounted on the support plate. The actuator gear assembly is configured to drive the pincher gear assembly between a first position in which the first and second pinchers are positioned relative to each other and relative to the fluid nozzle element such that the fluid nozzle element has a first cross-sectional shape and a second position in which the first and second pinchers are positioned relative to each other and relative to the fluid nozzle element such that the fluid nozzle element has a second cross-sectional shape. The first cross-sectional shape is different than the second cross-sectional shape.

A filter element is provided and includes a filter medium having an axial channel, end plates each sealingly covering one axial end of the filter medium, one end plate having an opening in fluid communication with the channel, a hole arranged on the liquid path, not on the filter medium, and a closing member which is arranged in the hole and which is configured: to prevent liquid from flowing through the hole when the liquid pressure upstream the closing member is below a predetermined threshold to open at the threshold, to allow liquid to flow through the hole, and, after it has been opened, to remain open. A method is provided for checking the suitability of a filter element, at first use after a filter element change. The method includes monitoring the liquid pressure at a point of the liquid circuit located outside of and near a port of a filter housing receiving the filter element, when an electrical pump of the liquid circuit is restarted for the first time, comparing the evolution of the monitored liquid pressure over time with a predetermined evolution over time of the liquid pressure at the point for a new reference filter element.

A differential pressure measurement range is widened and differential pressure can be measured particularly during low differential pressure. A first spool facing a space in a high pressure side is lighter than a second spool facing a space in a low pressure side in a state where a magnet is provided. Urging force of a first elastic member that urges the first spool toward the space in the high pressure side is smaller than urging force of a second elastic member that urges the second spool toward the space in the high pressure side, and the first elastic member and the second elastic member are disposed in series.

Self-cleaning inline filters that utilize sensors to measure pressure differential and activate a self-cleaning mode are disclosed. In the self-cleaning mode, the self-cleaning inline filters of the present disclosure utilize back, reverse, and/or counter-current fluid flow to separate two filter elements. The back, reverse, and/or counter-current fluid flow also flushes particulates out of the filter, such that the particulates are captured by a mechanical trap.

A method is disclosed for maintaining a filtration device of a system for extracting a liquid from a tank of a motor vehicle. The method is based on risk criteria for detecting (301) the choking of the device and on application criteria for identifying (302) a context favorable to the cleaning of the filtration device. The cleaning of the filtration device, based on generating (303) a reverse stream in the extraction system, is thus only triggered when specific, configurable conditions are identified.

A pressure measuring device configured as a multi-function device operable as a differential pressure switch (DPS); a differential pressure transducer (DPT); a pressure switch (PS); a pressure transducer (PT) providing readings of high and low pressure zones; a data recording logger; and a backwashing controller. The pressure measuring device may use at least two piezoelectric sensors operable to measure pressure attributes. The associated electronic hardware, processing unit, cables and pressure tubing are retrofittable and packaged in a molded case, with no moving parts with the electronic hardware fully coated to make the device reliable and resistant to extreme environmental conditions. The device is configured for remote access, enabling remote device configuration, maintenance and servicing. The device is further operable to communicate with various external devices: a tablet, a smartphone and the like as a user interface and further provides wired interface with a programmable logic controller (PLC) via RS-485 interface.

A first differential pressure that is a differential pressure as a pressure difference between a high pressure side and a low pressure side in a filtration device is detected at a first time as a time while the filtration device filters a liquid. A remaining life that indicates how long the filtration member is usable from the first time is obtained based on the first differential pressure and differential pressure characteristics.

A method for predicating a service life of a fuel filter includes causing a fuel pump of a fuel system to direct fuel through a fuel filter of a fuel system. The method also includes receiving work cycle data from machines that implement a same or similar fuel system. The method further includes receiving, via sensors of the fuel system, fuel system data and determining, from the fuel system data, a pressure difference across the fuel filter. The method further includes determining, based on the work cycle data, predicted load cycle data for the fuel system and determining, via a filter life model, a filter service interval representing an amount of time the fuel filter is operable in the fuel system prior to the pressure difference reaching a predetermined value.