Abstract: A valve comprises a housing and at least three ceramic discs in the housing such that at least two fixed ceramic discs are provided and at least one rotatable ceramic disc is provided between the fixed ceramic discs. The ceramic discs comprise through holes such that when the holes are aligned, the valve is open, and turning the rotatable ceramic disc turns the holes to be misaligned in successive ceramic discs, which prevents water flow through the valve. The valve further comprises a handle for rotating a rotatable ceramic disc and the handle comprises a stem extending through the housing, and a curved part, the curved part curving at least partly around the housing along the circumference of the housing.

Abstract: A valve for use in harsh chemical environments which is substantially inert from the predations of the chemicals. At least a valve insert is formed from ceramic. The insert defines potential fluid passageways while a gate determines flow path(s).

Abstract: An element for controlling the fluid flow rate through a fluid valve. The element may include a generally spherical metal housing encasing a cylindrical ceramic insert. The element may also include a cone-shaped metal housing encasing a cylindrical ceramic insert. The cylindrical ceramic insert defines a fluid passageway through the element. The element further includes a coupling mechanism disposed on the metal housing configured for securing a metal actuation shaft to the element. The coupling mechanism provides a high-strength element-to-shaft connection between the metal actuation shaft and a metal portion of the element. The present invention also encompasses a method of manufacturing the element.

Abstract: An element for controlling the fluid flow rate through a fluid valve. The element may include a generally spherical metal housing encasing a cylindrical ceramic insert. The element may also include a cone-shaped metal housing encasing a cylindrical ceramic insert. The cylindrical ceramic insert defines a fluid passageway through the element. The element further includes a coupling mechanism disposed on the metal housing configured for securing a metal actuation shaft to the element. The coupling mechanism provides a high-strength element-to-shaft connection between the metal actuation shaft and a metal portion of the element. The present invention also encompasses a method of manufacturing the element.

Abstract: A valve for controlling the flow of a fluid comprises a housing, a flow-control element disposed within the housing, at least one seat operably engaging the flow-control element, and a biasing device for urging the seat and the flow-control element relative toward each other. In some embodiments, the valve also includes an actuating device operably engaging the flow-control element. The flow-control element, the seat, and the biasing device are comprised of a refractory material, and at least the biasing device is formed of a toughened refractory or ceramic material that is fully annealed so that porosity in the material is substantially eliminated and such that the material is substantially homogenous. In some embodiments, the seat, the flow-control element, the biasing device, and/or other components may be advantageously fabricated together as a unitary structure. An associated fabrication method is also provided.

Abstract: An element for controlling the fluid flow rate through a fluid valve. The element may include a generally spherical metal housing encasing a cylindrical ceramic insert. The element may also include a cone-shaped metal housing encasing a cylindrical ceramic insert. The cylindrical ceramic insert defines a fluid passageway through the element. The element further includes a coupling mechanism disposed on the metal housing configured for securing a metal actuation shaft to the element. The coupling mechanism provides a high-strength element-to-shaft connection between the metal actuation shaft and a metal portion of the element. The present invention also encompasses a method of manufacturing the element.

Abstract: A flow-controlling device is provided for controlling the flow of a fluid. The device comprises a housing, a flow-control element disposed within the housing, at least one seat operably engaging the flow-control element, a biasing device operably engaging each seat for urging the seat into sealing engagement with the flow-control element, and an actuating device operably engaging the flow-control element. The seat operably engages the flow-control element and the biasing device operably engages the seat to urge the seat into a sealing engagement with the flow-control element. The flow-control element, the seat, and the biasing device are comprised of a refractory and/or toughened ceramic material that is fully annealed so that porosity in the material is substantially eliminated and such that the material is substantially homogenous. Components fabricated from such a ceramic are generally heat, corrosion, and wear resistant and are capable of substantial elongation without failure.