Embodiments relate generally to a self-cleaning filter. A filter may include a tube comprising perforations. The tube may be configured to receive a flow of a liquid from a first direction or a flow of a gas from a second direction opposite to the first direction. The filter may also include a filter media positioned concentrically around the tube, and spacers positioned between the tube and the filter media to create a space between the tube and the filter media. A portion of the filter media is configured to flex inward into the space during the flow of liquid into the filter, and flex outward from the space during the flow of gas exiting the filter.

Embodiments relate generally to a self-cleaning filter. A filter may include a tube comprising perforations. The tube may be configured to receive a flow of a liquid from a first direction or a flow of a gas from a second direction opposite to the first direction. The filter may also include a filter media positioned concentrically around the tube, and spacers positioned between the tube and the filter media to create a space between the tube and the filter media. A portion of the filter media is configured to flex inward into the space during the flow of liquid into the filter, and flex outward from the space during the flow of gas exiting the filter.

A portable fluid filtering apparatus includes a debris chamber having an exhaust port; a rotor that draws in a fluid from outside the debris chamber to the exhaust port; a filter positioned between the exhaust port and the rest of the debris chamber; an intake port in fluid communication with the debris chamber and wherein the rotor draws the fluid into the debris chamber through the intake port; and a drive system configured to rotate the rotor that includes a drive shaft connected to the rotor, a motor to rotate the drive shaft, and a power source for the motor.

A portable fluid filtering apparatus includes a debris chamber having an exhaust port; a rotor that draws in a fluid from outside the debris chamber to the exhaust port; a filter positioned between the exhaust port and the rest of the debris chamber; an intake port in fluid communication with the debris chamber and wherein the rotor draws the fluid into the debris chamber through the intake port; and a drive system configured to rotate the rotor that includes a drive shaft connected to the rotor, a motor to rotate the drive shaft, and a power source for the motor.

The invention is a gray water reclaiming container and system. It is comprised of two containers, an inner container which captures liquids destined for drainage and an outer liquid container for reclaiming water. There is a screen on the top of the inner container allowing ice to be filtered from liquid drinks as ice is fresh water which usually gets thrown away in cups into the trash can. The ice goes to the outer liquid container where it is melted into usable water.

Methods of operating candle filter systems for removing solids from MEG recovered from drilling fluids include passing an MEG rich stream to a candle filter system comprising a plurality of candle filter units in parallel, determining a concentration of TDS in the MEG rich stream, determining whether to operate the candle filter system in a low TDS mode or a high TDS mode based on the concentration of TDS the MEG rich stream, filtering the MEG rich stream in the plurality of candle filter units to produce a filtrate and a filter cake, determining to conduct a cleaning cycle of the candle filter units based on a pressure differential, and conducting a cleaning cycle to remove the filter cake from the outer surfaces of the filter candles. The cleaning cycle is modified to improve removal of solids from the filter candles of the candle filter units.

Methods of operating candle filter systems for removing solids from MEG recovered from drilling fluids include passing an MEG rich stream to a candle filter system comprising a plurality of candle filter units in parallel, determining a concentration of TDS in the MEG rich stream, determining whether to operate the candle filter system in a low TDS mode or a high TDS mode based on the concentration of TDS the MEG rich stream, filtering the MEG rich stream in the plurality of candle filter units to produce a filtrate and a filter cake, determining to conduct a cleaning cycle of the candle filter units based on a pressure differential, and conducting a cleaning cycle to remove the filter cake from the outer surfaces of the filter candles. The cleaning cycle is modified to improve removal of solids from the filter candles of the candle filter units.

A water treatment method used in a water treatment device including a filter for filtering untreated water and a housing that houses the filter includes a step of putting the untreated water into the housing to obtain filtered water that has permeated through the filter, and a step of replacing the untreated water in the housing by storage water. The storage water is water having less favorable survival conditions for microbes than the untreated water.

A water treatment method used in a water treatment device including a filter for filtering untreated water and a housing that houses the filter includes a step of putting the untreated water into the housing to obtain filtered water that has permeated through the filter, and a step of replacing the untreated water in the housing by storage water. The storage water is water having less favorable survival conditions for microbes than the untreated water.

The instant disclosure relates to liquid salts such as but not limiting to ionic liquids; and method for recovering liquid salts including ionic liquids. Ionic liquids get deactivated due to presence of various contaminants or impurities. The present disclosure deals with recovery and regeneration of ionic liquids using compounds containing at least one coordinating agent to form adduct with metal compounds. The instant disclosure also includes an assembly for carrying out the recovery and regeneration of the ionic liquids.