An insulated solution injector may include an outer tube and an inner tube arranged within the outer tube. The outer tube and the inner tube may define an annular space therebetween, and the inner tube may define a solution space within. The annular space may be configured so as to insulate the solution within the solution space. As a result, the solution may be kept to a temperature below its decomposition temperature prior to injection. Accordingly, the decomposition of the solution and the resulting deposition of its constituents within the solution space may be reduced or prevented, thereby decreasing or precluding the occurrence of a blockage.

An insulated solution injector may include an outer tube and an inner tube arranged within the outer tube. The outer tube and the inner tube may define an annular space therebetween, and the inner tube may define a solution space within. The annular space may be configured so as to insulate the solution within the solution space. As a result, the solution may be kept to a temperature below its decomposition temperature prior to injection. Accordingly, the decomposition of the solution and the resulting deposition of its constituents within the solution space may be reduced or prevented, thereby decreasing or precluding the occurrence of a blockage.

A method of generating a building assembly that includes spraying a coating material onto a plurality of pieces of substrate disposed on a first assembly face. The spraying includes spraying the coating material onto the plurality of pieces of substrate via a sprayer configured to apply the coating material to a target surface via a nozzle coupled with a mobile storage container storing the coating material, the coating material impregnating voids of the substrate. The method also includes allowing the coating material impregnating the voids to dry and harden and become rigid to generate the building assembly.

A shroud for a sprinkler head having a series of removable tabs to allow for configuring a shield-to-shield water distribution from the sprinkler head. The shield has removeable tabs of which allow for water to be sprayed past the shield. The shroud is utilized to configure the distribution of water from a sprinkler head so as, for example, to limit water distribution on unintended or undesired areas. Embodiments of the shroud can be configured to attach by a clip to a sprinkler head, by engagement with a weight threadingly engaged with the sprinkler head, by friction engagement with the sprinkler head, or by alternate attachment. The shroud can be configured in different embodiments to attach to a specific sprinkler head in the industry or configured to attach to different varieties of sprinkler head.

A nozzle member (14) of a personal care device (10) comprising: a nozzle head (16) positioned at an end of the nozzle member; and an orifice (40) formed in a surface (30) of the nozzle head, wherein the orifice comprises at least one liquid jet orifice (42) configured to allow the liquid and/or air to exit the nozzle head in the form of a jet, and at least one liquid sheet orifice (40a-d) configured to allow the liquid and/or air to exit the nozzle head in the form of a sheet.

An example of a device (100) may include a valve body (108). The device (100) may include a printing substance transfer aperture (122) through the valve body (108). The device (100) may include a hood (138), fixed to the valve body (108), encompassing the printing substance transfer aperture (122) within a cavity between an external face (137) of the valve body (108) and the hood (138). The device (100) may include a printing substance dispensing nozzle (110) movable between a first position with an orifice (126) of the printing substance dispensing nozzle (110) facing an internal face of the valve body (108) and a second position with the orifice (126) of the printing substance dispensing nozzle (110) facing the printing substance transfer aperture (122). The device (100) may include a dispensing-side gasket material (132) slide-able through the printing substance transfer aperture (122) when moving the printing substance dispensing nozzle (110) between the first position and the second position.

A substrate processing apparatus includes a substrate processing unit, a partition wall, a first gas supply, and a second gas supply. The substrate processing unit performs a liquid processing on a substrate. The partition wall separates a first space defined from a carry-in/out port through which the substrate is loaded to the substrate processing unit, and a second space other than the first space. The first gas supply is connected to the partition wall, and supplies an atmosphere adjusting gas to the first space. The second gas supply is connected to a place different from the first gas supply in the partition wall, and supplies an atmosphere adjusting gas to the first space.

A substrate processing apparatus includes a substrate processing unit, a partition wall, a first gas supply, and a second gas supply. The substrate processing unit performs a liquid processing on a substrate. The partition wall separates a first space defined from a carry-in/out port through which the substrate is loaded to the substrate processing unit, and a second space other than the first space. The first gas supply is connected to the partition wall, and supplies an atmosphere adjusting gas to the first space. The second gas supply is connected to a place different from the first gas supply in the partition wall, and supplies an atmosphere adjusting gas to the first space.

An overcap assembly configured to attach to a container. The overcap assembly includes a body, an actuator, a first nozzle, and a second nozzle. The actuator is integrally attached with the body and defines a longitudinal axis. The actuator further comprises a fluid passageway that extends therein. The first nozzle and the second nozzle extend laterally from the actuator, and the first nozzle and the second nozzle define a portion of the fluid passageway. The first nozzle comprises a first angled exit aperture and the second nozzle comprises a second angled exit aperture. The first nozzle and the second nozzle each comprises an inner cylindrical wall and an outer cylindrical wall surrounding and spaced apart from the inner cylindrical wall. The first angled exit aperture and the second angled exit aperture are non-parallel to the longitudinal axis.

Pendent vertical sidewall fire protection sprinklers, systems and methods for the protection of windows are provided. The sprinklers include a fluid deflection member with an impact surface and an adjacent retention surface having one or more arcuate surface profiles to define a fluid throw channel. The sprinklers and their system installation provide for a maximum sprinkler-to-sprinkler spacing that ranges from over eight feet to fifteen feet (8+ ft. to 15 ft.).