An electronic showerhead device for automatically controlling water flow includes a showerhead body, a presence detector located within the showerhead body, a first water channel providing a primary water stream exiting the showerhead body, and a second water channel providing a secondary water stream exiting the showerhead body. Turning on a main water valve turns on the second water channel, while the first water channel remains off. Interruption of the presence interrogation beam area by a person or an object turns on the first water channel.

A coating device for applying a coating agent to the surface of a workpiece. The coating device includes a frame with a workpiece receptacle, a coating agent source and a rotary unit which is rotatable in relation to the frame. The rotary unit has a pump and a plurality of spray units, with the pump on the suction side being connected to the coating agent source by a fluid-conducting rotary joint connection. The rotary unit has a pneumatic valve device, and the spray units have in each case one compressed air controlled valve for controlling the delivery of coating agent. The inlet side of the valve is connected to the compressed air source by a fluid-conducting rotary feedthrough, which simplifies the overall construction of the coating device by providing a pneumatic connection between the compressed air source and the rotary unit that is independent of the rotation angle.

A coating device for applying a coating agent to the surface of a workpiece. The coating device includes a frame with a workpiece receptacle, a coating agent source and a rotary unit which is rotatable in relation to the frame. The rotary unit has a pump and a plurality of spray units, with the pump on the suction side being connected to the coating agent source by a fluid-conducting rotary joint connection. The rotary unit has a pneumatic valve device, and the spray units have in each case one compressed air controlled valve for controlling the delivery of coating agent. The inlet side of the valve is connected to the compressed air source by a fluid-conducting rotary feedthrough, which simplifies the overall construction of the coating device by providing a pneumatic connection between the compressed air source and the rotary unit that is independent of the rotation angle.

A method and coating system are provided that use a temperature controlled gas flow to smooth a surface of a ceramic, like a thermal barrier coating (TBC). Thermal spray coating unit coats a ceramic on a surface. The thermal spray coating unit creates a flow of ceramic material towards the surface. A layer of at least partially molten ceramic material on the surface is smoothed by transmitting a flow of temperature controlled gas across the at least partially molten ceramic material on the surface after the thermal spray coating of the ceramic on the surface. The solidified ceramic has a smoother surface that requires much less polishing to attain a desired surface roughness.

A method and coating system are provided that use a temperature controlled gas flow to smooth a surface of a ceramic, like a thermal barrier coating (TBC). Thermal spray coating unit coats a ceramic on a surface. The thermal spray coating unit creates a flow of ceramic material towards the surface. A layer of at least partially molten ceramic material on the surface is smoothed by transmitting a flow of temperature controlled gas across the at least partially molten ceramic material on the surface after the thermal spray coating of the ceramic on the surface. The solidified ceramic has a smoother surface that requires much less polishing to attain a desired surface roughness.

A substrate processing apparatus includes a processing liquid supply mechanism 70 configured to supply a SPM liquid to a substrate; a temperature adjusting unit (heater) 303 configured to adjust a temperature of the SPM liquid at a time when the SPM liquid is supplied to the substrate from the processing liquid supply mechanism 70; an acquisition unit (temperature sensor) 80 configured to acquire temperature information of the SPM liquid on a surface of the substrate; and a control unit 18 configured to set an adjustment amount of the temperature adjusting unit (heater) 303 based on the temperature information of the SPM liquid acquired by the acquisition unit (temperature sensor) 80. The temperature adjusting unit (heater) 303 adjusts, based on the adjustment amount set by the control unit 18, the temperature of the SPM liquid at the time when the SPM liquid is supplied to the substrate.

A substrate processing apparatus includes a processing liquid supply mechanism 70 configured to supply a SPM liquid to a substrate; a temperature adjusting unit (heater) 303 configured to adjust a temperature of the SPM liquid at a time when the SPM liquid is supplied to the substrate from the processing liquid supply mechanism 70; an acquisition unit (temperature sensor) 80 configured to acquire temperature information of the SPM liquid on a surface of the substrate; and a control unit 18 configured to set an adjustment amount of the temperature adjusting unit (heater) 303 based on the temperature information of the SPM liquid acquired by the acquisition unit (temperature sensor) 80. The temperature adjusting unit (heater) 303 adjusts, based on the adjustment amount set by the control unit 18, the temperature of the SPM liquid at the time when the SPM liquid is supplied to the substrate.

A shower head water collecting device includes a water collecting hanging component, a temperature sensing element, an assembling component, a solar panel, and a temperature displaying element. The water collecting hanging component is provided for a shower head to be hung thereon and collects the water spraying from the shower head. The temperature sensing element is disposed inside the water collecting hanging component to sense the temperature of water spraying from the shower head. The assembling component is mounted on top of the water collecting hanging component. The solar panel and the temperature displaying element are disposed in the assembling component. The solar panel is electrically connected to the temperature sensing element and the temperature displaying element, wherein the solar panel harvests the light energy from the outside and converts it into electrical energy to supply power to the temperature sensing element and the temperature displaying element.

An apparatus and method for removing support material from and/or smoothing surfaces of an additively manufactured part (the AM part) is disclosed. The apparatus may include a chamber, a support surface within the chamber, and one or more nozzles within the chamber. The nozzles may be the same size or different sizes. The support surface may be configured to support the AM part. The support surface may have one or more openings sized and configured to allow the fluid to pass through the opening(s). The nozzles may be configured to spray a fluid at the AM part, and the spray may be an atomized or semi-atomized spray of the fluid.

Disclosed is a fumigation vaporizer capable of quickly vaporizing a fumigant, which is widely used in agriculture or quarantine to control insects or weeds, thereby safely and effectively carrying out fumigation, as compared to a conventional process. The fumigation vaporizer includes a housing, a fumigant supply pipe, a heater, a non-explosive gas supply member, a gas supply pipe, a vessel-type heater, a gas discharge pipe, and a controller. The housing is provided with a heating hollow portion at the lower portion of the inner cavity, in which the non-explosive gas heated and supplied by the vessel-type heater heats a bottom surface of the inner cavity while passing through the heating hollow portion. A bottom surface of the heating hollow portion is provided with an inlet port through which the non-explosive gas passes, and a top surface of the heating hollow portion opposite to the inlet portion is provided with an outlet port through which the non-explosive gas passing the heating hollow portion is supplied to the gas discharge pipe installed to the inner cavity.