A system for preventing hydrate formation in a pipeline includes a heater housing. The heater housing has an outer diameter sized to travel within the pipeline. A turbine assembly is located within the heater housing. The turbine assembly has a blade that is rotatable by a flow of fluid within the pipeline. An electric heater is located within the heater housing and is electrically connected to the turbine assembly. The electric heater is selectively contacted by the flow of fluid within the pipeline.

A diaphragm valve is disclosed. The diaphragm valve may include, a valve body comprising a valve channel, the valve channel including an inlet channel and an outlet channel. The diaphragm valve may also include, a valve seat adjacent to the valve channel and a flexible diaphragm comprising a wetted surface and an opposing non-wetted surface, the flexible diaphragm being disposed adjacent to the valve channel. The diaphragm valve may also include, a flexible heater disposed over the non-wetted surface of the flexible diaphragm, and a valve actuator that is operable to operable to move the wetted surface of the flexible diaphragm into and out of contact with the valve seat. Valve components including a flexible heater and methods for forming such valve components are also disclosed.

A washer tank according to an embodiment includes: a first container which stores a washer fluid and retains a temperature of the washer fluid; an inflow pipe through which the washer fluid flows into a storage space in the first container; an outflow pipe through which the washer fluid flows out of the first container from the storage space; and a heating portion which heats the washer fluid, in which all the inflow pipe, the outflow pipe, and the heating portion are disposed in a lower portion of the first container.

Methods and apparatuses for additively manufactured tubular passages, additively manufactured manifolds, and additively manufactured heaters are provided.

Provided is a vacuum bellows hot valve with durability and drivability not impaired by increased temperature and voltage of heating means while having a simple, compact structure, the valve also allowing valve's temperature control with high accuracy. In the vacuum bellows hot valve, a stern is provided inside a valve box with an inflow port and an outflow port so as to freely ascend and descend, a bellows is elastically provided to a valve body provided at a lower end of the stem and on an outer circumferential side, of the stem, a cylindrical ceramic heater is arranged between an inner circumference of the bellows and an outer circumference of the stem, and a temperature measuring part of a thermocouple for control is arranged at a position close to the valve body.

A diaphragm valve is disclosed. The diaphragm valve may include, a valve body comprising a valve channel, the valve channel including an inlet channel and an outlet channel. The diaphragm valve may also include, a valve seat adjacent to the valve channel and a flexible diaphragm comprising a wetted surface and an opposing non-wetted surface, the flexible diaphragm being disposed adjacent to the valve channel. The diaphragm valve may also include, a flexible heater disposed over the non-wetted surface of the flexible diaphragm, and a valve actuator that is operable to operable to move the wetted surface of the flexible diaphragm into and out of contact with the valve seat. Valve components including a flexible heater and methods for forming such valve components are also disclosed.

A heated water valve provides electrical resistance heaters placed within flange connections of the valve to provide for an integrated heater valve assembly with good heat conduction and spreading capabilities that can prevent water valve freezing at low temperatures.

In order to appropriately control temperatures of fluid heating sections that are maintained at different temperatures, the fluid control device (100) comprises a plurality of fluid heating sections (1) connected to each other and each having a flow path or a fluid accommodating portion inside, heaters (10) configured to heat each of the plurality of fluid heating sections to different temperatures, and heat insulating members (13, 13) disposed between adjacent fluid heating sections.

A plumbing component includes a valve provided within a portion of the plumbing component and configured to control the flow of water through the plumbing component. The valve includes a body and at least one waterway within the body. An electric heater extends through at least a portion of the body of the valve and is configured to heat at least a portion of the body to an elevated temperature sufficient to kill organisms within the waterway.

A shower head having a stem; a spray head coupled to the stem; a mixing valve located within the stem or the spray head, the mixing valve having a first valve member assembly for controlling a first fluid flow to a mixing chamber and a second valve member assembly for controlling a second fluid flow to the mixing chamber. Each valve member assembly includes a spool, a first valve member on the spool that engages with a first valve seat in a closed position and a second valve member on the spool that engages with a second, separate, valve seat in the closed position. An electrically powered first motor is located within the stem or the spray head. The first motor is coupled to the first valve member assembly to control movement of the first valve member assembly to control the flow of the first fluid to the mixing chamber.