A water filtration apparatus comprises a housing having a housing outlet and a housing inlet, the housing outlet configured to allow filtered water to exit therefrom, the housing inlet includes a valve stem, where the housing has latch arms disposed adjacent to the valve stem. At least one filter is disposed in the interior portion of the housing, and the at least one filter is in fluid communication with the housing outlet and the housing inlet. A valve assembly includes a valve body releasably coupled with the valve stem, where the valve body has a faucet interface component, and the valve body configured to fluidly couple with a faucet via the faucet interface component. The valve assembly has a valve body release coupled with the valve body, and the valve body release is slidable relative to the valve body and the one or more latch arms.

A chemical solution supply system including: a first tank that stores a first chemical solution; a first pipe that is connected to the first tank and conveys the first chemical solution; a first filter unit that is connected to the first pipe and has a first filter through which the first chemical solution is filtered; a first valve that is provided in the first pipe between the first tank and the first filter unit; a second tank that stores a second chemical solution; and a second pipe that is connected to the second tank and the first pipe between the first filter unit and the first valve.

A multi-bank cooking system includes multiple discrete cooking systems sharing common plumbing and integrated safety features. The multi-bank cooking system may include two or more rack-fryer systems, each with discrete frypots, operating mechanisms and cooking controllers. Each of the discrete cooking systems, may share a common plumbing system with integrated valves and controls receiving coordinated safety signals to facilitate safe and efficient operation of the system.

An interconnection scheme between a filter cartridge and its corresponding manifold whereby a magnetic shear force is introduced to remove a blocking mechanism that would otherwise prohibit attachment. The magnetic shear force may also be employed to activate or deactivate a switch or valve, or engage or disengage an engagement mechanism relative to other components upon interconnection. The magnetic shear force is generated by complementary correlated magnet structures moved into close proximity to one another. The interconnection scheme may be a linear or rotational attachment of the filter cartridge with respect to the manifold. A valve assembly utilizing magnetic shear force may be employed to activate a bypass action between a manifold ingress port and egress port, thereby allowing water to flow when a filter cartridge is removed from the manifold and directing water to the filter cartridge when the valve assembly is activated.

A filter assembly includes a filter element, and a mount having at least one port, each of the filter element and mount having inter-engaging connection formations where the filter element and mount can be detachably connected to one another, with the mount defining a flow path for fluid to flow between the port and the filter element. The mount includes a valve with a valve member which can move between an open position and a closed position. One of the filter element and the mount has at least one lug and the other of the filter element and mount has a ramp surface, the lug engaging the ramp surface when the filter element and mount are brought together along an axis and a cam action between the lug and the ramp surface causes axial movement of the valve member when the filter element is then rotated relative to the mount.

A filter arrangement for an aquarium is disclosed. The filter arrangement can include a housing assembly, a pump assembly, a transfer tube assembly, and a valve assembly for controlling water flow through the transfer tube assembly. The transfer tube assembly can include a tube structure within which a valve body of the valve assembly is rotatably disposed. The tube structure can be formed from a first tube half mated to a second tube half to permanently secure the valve body within the tube structure. A valve operator can be connected to the valve body to advantageously allow a user to manipulate the flow of water through the transfer tube assembly. Control of water flow through the filter arrangement is beneficial for obtaining a desired water flow for a certain aquarium size and application and for reducing flow during certain periods, such as during feeding.

A filtration system interconnection structure having manifold with a rotatable manifold magnet of correlated magnets, a shroud with alignment tracks, an actuating valve for water ingress, and a filter cartridge having a rotatable filter magnet of correlated magnets, where the manifold magnet and the filter magnet are in magnetic communication with one another when the filter cartridge is inserted with the shroud, and are at least partially rotatably compatible, where the manifold magnet rotates with the filter magnet until the manifold magnet experiences a rotational stop beyond a predetermined rotation of the filter magnet, thus allowing the filter magnet to shift polarity with respect to the manifold magnet and present a repulsion force for removal of the filter cartridge from the shroud.

A filtering apparatus (100) having a filtering mode and a self-cleaning mode, the apparatus provided for filtering an upstream flowing fluid with filtering elements (20) in the form of a plurality of stackable discs during filtering mode utilizing a first flow direction, apparatus (100) also configured to self-clean the filtering elements (20) the apparatus (100) including an internal fluid diverter (110,210, 310) that is internal to the filter housing. The position of the internal fluid diverter determines the direction of fluid flow through the filter housing and the filter phase. The position of the internal fluid diverter is controlled with a controller disposed external to the filter housing that may be manipulated either manually or by automated means.

A capacitive sensor and control system is configured to detect the presence (or absence) of a filter pan and of fluid within a filter pan. Configured in a filter pan of a deep fryer, the sensor determines when a level of liquid within the filter pan is at or above the level of the. The sensor is in communication with the control system and the sensor sends a signal to the control system representative of the presence of liquid within the filter pan and at the level of the sensor. The controller receives the signal from the sensor, and allows operation of a fluid management system and its associated plumbing to completely and safely move oil into and out of the filter pan.

A water purifier includes a water supply tube into which water is introduced, a filter member purifying water passing through the water supply tube, a water discharge tube supplying water to the outside of the water purifier, a hot water tube branched from the water discharge tube, a hot water module including a hot water tank provided on the hot water tube to accommodate purified water and a heat generation unit heating the water accommodated in the hot water tank, a controller spaced apart from the hot water tank or the heat generation unit to control the heat generation unit, and a water discharge nozzle supplying the water passing through the water discharge tube and the hot water tube to the outside of the water purifier. At least a portion of the hot water tube or the water discharge tube passes through the controller and is heat-exchanged with the controller.