A faucet includes a mixing chamber, a bypass chamber, a hot water actuator, a cold water actuator, and a valve assembly. The mixing chamber is in fluid communication with a spout. The bypass chamber is operably coupled to a source of cold water. The cold water actuator is operably coupled to provide, upon actuation, cold water to the mixing chamber. The hot water actuator is operably coupled to provide, upon actuation, hot water to the mixing chamber. The valve assembly has a seal configured to move in a direction away from the spout responsive to a temperature of water in the mixing chamber exceeding a threshold, such that fluid connection is provided between the bypass chamber and the mixing chamber.

A single waterway valve core structure comprises a valve housing, a valve cover, a temperature regulating valve rod, a water stop piece, and a hollow water stop pad. A bottom of the valve housing comprises a water inlet cavity, and a side wall of the valve housing comprises a water outlet. The water stop piece is integrally formed on a bottom end of the temperature regulating valve rod, and the bottom end of the temperature regulating valve rod comprises one or more water passing holes. A side wall of the temperature regulating valve rod comprises a side outlet hole in communication with the water outlet. The hollow water stop pad is disposed in the water inlet cavity, the temperature regulating valve rod is disposed in the valve housing, and the water stop piece contacts the hollow water stop pad.

A water heater appliance and methods for operating the same, as provided herein, may include a casing, a tank, an inlet conduit, an electric heating system, a mixing valve, and a controller. The electric heating system may be in thermal communication with the tank. The mixing valve may be mounted to the casing downstream from the tank. The controller may be operably coupled to the electric heating system and the mixing valve. The controller may be configured to initiate a mixing cycle. The mixing cycle may include detecting a flow demand at the water heater appliance, directing the mixing valve to a programmed park position in response to detecting the flow demand, determining expiration of a park period following directing the mixing valve to the programmed park position, and releasing the mixing valve from the programmed park position in response to determining expiration of the park period.

The present invention relates to a screen. The screen a) is annular, b) is designed to filter water in a thermostatic valve, c) can be transferred from a first state into an additional state, d) has a first circumference in the first state, and e) has an additional circumference in the additional state. The screen is characterized in that the additional circumference is greater than the first circumference. The invention also relates to a thermostatic valve comprising the screen; to a thermostat fitting comprising the thermostatic valve; to a method comprising connecting the screen to a thermostatic valve body; and to a use of the screen in a thermostatic valve or in a thermostat fitting or in both.

A method adjusts a regulated temperature in a faucet that includes a spout, a faucet body, a hot water valve and a cold water valve. The method includes regulating a maximum water temperature of water provided to the spout using a thermostatic valve cartridge to add cold water that bypasses the cold water valve to the water provided to the spout as a function of water temperature inside the thermostatic valve cartridge. The thermostatic valve cartridge is affixed to the faucet body and external access to the thermostatic valve cartridge is inhibited by at least one element. The method also includes removing the at least one element to expose at least a portion of a thermostatic valve cartridge, and rotating a rotatable portion of the thermostatic valve cartridge to adjust the regulated maximum water temperature.

Fuel recirculation methods, fuel supply circuits and fuel recirculation valves for selectively mixing hot return fuel from a diesel engine with fuel from a tank before providing it to back to the engine. In exemplary disclosed embodiments of fuel recirculation valves, the valves are configured to selectively mix the fuel in a controlled manner using a temperature sensitive actuator within the valve such that, when the temperature of the fuel reaches a certain point, the valve restricts flow pathways to reduce heated fuel being mixed with fuel from the fuel tank, and eventually closes to prevent any heated fuel from being mixed and overheating the fuel provided to a fuel filter, a fuel pump and the engine. Disclosed fuel circulation valves are separate from the fuel filter and are placed upstream of the filter.

A water heater appliance includes a cold water conduit and a hot water conduit. The water heater appliance also includes a mixing valve and a controller. The controller may be configured for and/or methods of operating the water heater appliance may include detecting a start of a flow event from the water heater appliance and detecting a water temperature in the mixed water conduit of the water heater that is outside of tolerance limits after detecting the start of the flow event. The controller may be further configured for and/or the method may further include verifying that the flow event has not ended after detecting the water temperature in the mixed water conduit is outside of the tolerance limits. After verifying that the flow event has not ended, a count is added to a fault counter.

A water heater appliance and methods for operating the same, as provided herein, may include a casing, a tank, an inlet conduit, an electric heating system, a mixing valve, and a controller. The electric heating system may be in thermal communication with the tank. The mixing valve may be mounted to the casing downstream from the tank. The controller may be operably coupled to the electric heating system and the mixing valve. The controller may be configured to initiate a mixing cycle. The mixing cycle may include detecting a flow demand at the water heater appliance, directing the mixing valve to a programmed park position in response to detecting the flow demand, determining expiration of a park period following directing the mixing valve to the programmed park position, and releasing the mixing valve from the programmed park position in response to determining expiration of the park period.

A thermostatic assembly comprises a casing in which are delimited a chamber where hot and cold fluids mix to form a mixed fluid, a hot fluid inlet, a cold fluid inlet and a mixed fluid outlet. This assembly also comprises a thermostatic element including a thermosensitive body and a piston which move relative to one another along a central axis (X-X) of the chamber as a function of the temperature of the mixed fluid. A spool regulates the temperature of the mixed fluid, being connected to the thermosensitive body to be moved along the central axis in the chamber so as to close, in respective inverse proportions, hot and cold fluid passages which are each delimited, along the central axis, between the spool and the casing. In order to make this assembly more adaptable to various geometries of the installation environment, the spool has a profile that is non-circular.

A system and a method for reducing a risk of bacterial contamination in a water heater are disclosed. A bypass conduit is connected to cold water supply and hot water outlet conduits of the water heater with T-shaped fittings, the bypass conduit generally extending in a same horizontal plane as the fittings and running alongside a top surface of the water heater. A thermostatic mixing valve is integrated to the bypass conduit close to the fitting with the hot water outlet so that its mixed water outlet is connected to the fitting with the hot water and its cold water inlet is connected to the fitting with the cold water, its hot water inlet being blocked. The thermostatic mixing valve is adjusted to regulate the hot water temperature at the outlet of the system and to produce a thermosiphon loop in the system depending on whether there is extraction or no extraction of hot water from the water heater.