A method for programming a water delivery device having a first optical communications interface is provided. The method includes physically coupling a communications bridge to the water delivery device. The communications bridge includes a second optical communications interface and a separate data communications interface. The method further includes transmitting information from a user device to the communications bridge using electronic data communications between the user device and the data communications interface; generating, by the communications bridge, an optical signal comprising the information received from the user device; and transmitting the optical signal from the communications bridge to the water delivery device using optical communications between the first and second optical communications interfaces.

A valve arrangement includes various improvements useable in the context of a fluid additive system, such as a water softener. For example, the valve assembly may include a seal assembly engaged by a reciprocating piston, in which the seal assembly includes a minimal number of parts, is easily assembled, and can be easily inserted in the bore of the valve body without jeopardizing the integrity of the seals. The valve assembly may further include a quick-disconnect system which allows a control head including a valve actuation system and electronic controls to be disconnected from the rest of the valve arrangement with only a partial rotation of the control head. The valve assembly may also include a venturi used for drawing regeneration fluid into the system, and an associated venturi cleaner system which allows a user to unclog the fluid-flow orifice of the venturi without any disassembly of parts of the valve arrangement.

A control system includes a water delivery device and a communications bridge. The water delivery device includes a mixing valve, a controller configured to control the mixing valve, and a first optical communications interface coupled to the controller. The communications bridge includes a second optical communications interface and a separate data communications interface. The communications bridge is configured to exchange information with the water delivery device using optical communications via the first and second optical communications interfaces, and to exchange information with a user device using electronic data communications between the user via and the data communications interface.

A system includes a regional blending facility having a number of bulk receiving facilities, where each bulk facility receives and stores a particle type having a distinct size modality, a bulk moving device that transfers particles between the bulk receiving facilities and of a blending/continuously receiving vessel and/or a mixer, and a carrying medium vessel. The mixer receives particles from the blending/continuously receiving vessel and/or the bulk moving device, receives a carrying medium from the carrying medium vessel, mixes the particles with the carrying medium, and provides a mixed treatment fluid. The system includes a fluid conduit that fluidly couples a wellsite location with the regional blending facility, where the fluid conduit delivers the mixed treatment fluid to the wellsite and/or delivers produced fluid from a wellbore positioned at the wellsite to the regional blending facility.

A mixing system is disclosed in which the system comprises a source of bone-graft or bone-graft-substitute material, a liquid source, and a vacuum source, at least one of the source of bone-graft or bone-graft-substitute material and the liquid source being in communication with the vacuum source. A valve assembly also forms part of the system, the valve assembly having a valve movable between a first position in which a first fluid passageway is created between the source of bone-graft or bone-graft-substitute material and the vacuum, and a second position in which a second fluid passageway is created between the source of bone-graft or bone-graft-substitute material and the liquid source, wherein, in the second position, the valve seals off the first fluid passageway, the vacuum source being adapted to generate a negative-pressure environment, relative to atmospheric pressure, within the valve assembly while the valve is in the first position. Methods of utilizing the aforementioned system are also disclosed.

A water delivery system is disclosed. The water delivery system may have an electronic user interface. The electronic user interface may be a portable device. The electronic user interface may include inputs to select water temperature, water flow rates, water flow patterns, and/or task based presets. A mixing valve for use with either manual faucets or electronic faucets is disclosed.

A mixing system is disclosed in which the system comprises a source of bone-graft or bone-graft-substitute material, a liquid source, and a vacuum source, at least one of the source of bone-graft or bone-graft-substitute material and the liquid source being in communication with the vacuum source. A valve assembly also forms part of the system, the valve assembly having a valve movable between a first position in which a first fluid passageway is created between the source of bone-graft or bone-graft-substitute material and the vacuum, and a second position in which a second fluid passageway is created between the source of bone-graft or bone-graft-substitute material and the liquid source, wherein, in the second position, the valve seals off the first fluid passageway, the vacuum source being adapted to generate a negative-pressure environment, relative to atmospheric pressure, within the valve assembly while the valve is in the first position. Methods of utilizing the aforementioned system are also disclosed.

A water delivery system is disclosed. The water delivery system may have an electronic user interface. The electronic user interface may be a portable device. The electronic user interface may include inputs to select water temperature, water flow rates, water flow patterns, and/or task based presets. A mixing valve for use with either manual faucets or electronic faucets is disclosed.

Apparatus and systems are disclosed for improved set-up of multi-ingredient compounders. An improved apparatus includes a manifold and a plurality of valve members disposed for movement relative to different corresponding ones of a plurality of inlet ports of the manifold. The valve members are moveable to open and close a corresponding fluid passageway between the corresponding inlet port and an internal passageway of the manifold. A plurality of caps are locatable on different corresponding ones of the inlet ports, with each of the caps being engageable with the corresponding valve member for co-movement from a locked position at which the cap is restricted from removal to an unlocked position at which the cap is removable, e.g. by manual, axial retraction of the cap. An improved system includes a compounder controller operable to control valve actuators of the compounder so as to sequentially move the valve members and corresponding caps from locked to unlocked positions in a predetermined sequence, thereby reducing the potential for undesired cross-connections.

A technology, when forming a film by supplying TiCl.sub.4 gas and NH.sub.3 gas a plurality of times in alternation to a substrate, can increase the amount of gas flow while suppressing cooling of a valve device, and contribute to an increase in throughput. In the formation of the film, the gas for atmosphere replacement supplied into a processing vessel between supplying one processing gas and supplying the other processing gas is heated ahead of time. Thus, the flow rate of gas can be increased while suppressing cooling of the gas-contacting sites such as a wafer and the inner wall of the processing vessel, and so it is possible to reduce the time necessary to replace the atmosphere, resulting in being able to contribute to increased throughput, and problems such as adhesion of reaction products due to cooling at the valve device are suppressed.