A fire suppression nozzle assembly includes a spray-type nozzle for spraying a fire suppression fluid. The spray-type nozzle includes a body portion defining a passage extending longitudinally through the body portion for conveying the fire suppression fluid. The spray-type nozzle also includes a deflector portion coupled to the body portion and configured to spray the fire suppression fluid onto a fire suppression target area using a radial spray pattern.

The present disclosure discloses a water outlet mechanism and a shower head comprising the water outlet mechanism. The water outlet mechanism comprises an inlet, an air intake chamber, an air intake passage, and a water outlet passage. The water outlet passage is in communication with the air intake chamber, and the air intake chamber is disposed with a wall connected to an entrance of the water outlet passage. The water outlet passage gradually increases in a downward direction, and a plurality of rectifying ribs protrude from an inner wall of the water outlet passage and are arranged in a circumferential direction at intervals. When the water flows through the inlet and enters the air intake chamber, a flowing cross sectional area of the water changes suddenly, an air pressure surrounding the water is less than the external air pressure, and a negative pressure is generated in the air intake chamber.

Provided is an aerosol product which has a simple configuration and enables spraying in the form of a mist at the time of use even when a stock liquid is stored in a high-viscosity state in an aerosol container. An aerosol product (100) has a plurality of partitioned housing spaces and a valve unit (120) provided with an inflow port (122) corresponding to the housing space, wherein at least one among the plurality of housing spaces is a main stock liquid housing section (142) that houses a main stock liquid (M), at least one other of the plurality of housing spaces is a viscosity lowering agent housing section (143) that houses a viscosity lowering agent (S), and the main stock liquid (M) discharged from the inflow port (122) and the viscosity lowering agent (S) discharged from the inflow port (122A) are mixed in an actuator (130).

The present invention provides a showerhead, and a water jet for a showerhead, that is specifically configured to aerate at least some of the water passing through the showerhead. This is achieved by a water jet configuration that may require less precision in manufacturing tolerances and may be a more cost-effective solution for producing a softer flow of water compared to prior art arrangements. The invention has particular application for handheld showerheads which have multiple spray arrays.

An aspirating spray nozzle assembly includes a nozzle body and a distributor removably attached to one another. The nozzle body includes a first inlet, a first chamber, an orifice disc and an annular catchment. The first inlet has a first end and a second end. The first chamber facilitates diffusion of the liquid jet. The first chamber has a third end in communication with the second end of the first inlet and a fourth end in communication with the distributor. The orifice disc is received within the first inlet. The orifice disc has a dispersing means adapted to cause the liquid jet to spread. The annular catchment encircles the fourth end of the first chamber. The annular catchment is configured to catch and deflect a portion of liquid splashback by the interfering means such that the portion of deflected liquid splashback is redirected downstream into the distributor.

A faucet includes a base, an outlet pipe, and an ultrasonic generator. The base has a receiving groove, wherein the receiving groove has an opening formed on an outer surface of the base. The outlet pipe is engaged with the base, and the outlet pipe has an inlet end and an outlet end. The ultrasonic generator is detachably disposed in the receiving groove and could be taken out via the opening. The engaging structure of the ultrasonic generator and the base of the faucet of the present invention could facilitate the storage of the ultrasonic generator and increase the convenience of using the ultrasonic generator.

The present invention provides a water discharging device, including: a housing; a dispenser disposed at an upper portion of the housing or embedded at an upper end of the housing, water flow entering the interior of the housing through the dispenser; a filter provided at an inlet end of the housing, the water flow entering the dispenser first passing through the filter to remove impurities in the water entering the dispenser; the dispenser includes a plurality of dispensing holes each having an inlet section and an outlet section along a water flow direction, the inlet section including a water outlet having a diameter smaller than a diameter of the outlet section.

An exemplary foam dispenser includes a housing, a reservoir for holding a foamable liquid, and a pump located below the reservoir. The pump includes a liquid pump chamber, two or more air pump chamber and a manifold. The manifold includes a liquid outlet port, a liquid outlet valve and an air outlet port. An elongated liquid dispensing conduit in fluid communication with the liquid outlet port and an elongated air dispensing conduit in fluid communication with the air outlet port are also included. A mixing chamber having a mixing chamber liquid inlet, a mixing chamber air inlet, and a foam outlet is provided. The mixing chamber is located remotely from the sequentially operated multi-diaphragm pump. The elongated liquid dispensing conduit is in fluid communication with the mixing chamber liquid inlet and the elongated air dispensing conduit is in fluid communication with the mixing chamber air inlet.

A fan-shaped air suction spray nozzle automatically adjusting an air suction speed is provided in the present invention, which includes a spray nozzle body and a liquid channel, the spray nozzle body being provided with a liquid channel in communication with a nozzle hole, and further includes a pressure groove and an air intake channel, wherein an inlet section of the liquid channel is in communication with the pressure groove, and the air intake channel is in communication with the liquid channel after penetrating through the pressure groove; an air intake orifice plate is installed in the pressure groove through an elastic damping apparatus, and a change of the pressure at an inlet of the liquid channel causes the air intake orifice plate to move between the pressure groove and the air intake channel; the air intake orifice plate is provided with several through holes of the same or different sizes, which are configured to change the air intake volume in the liquid channel as the air intake orifice plate moves in the pressure groove.

A device for mixing a first fluid and a second fluid may include a primary conduit that may extend along a longitudinal axis of the primary conduit between a primary inlet port and a primary outlet port. The primary conduit may have a constant primary inner diameter for an entire length of the primary conduit. The primary inlet port may be connected to a pressurized source of the first fluid. The device may further include at least one secondary conduit that may extend parallel with the primary conduit. The secondary conduit may include a secondary inlet port and a secondary outlet port. The secondary conduit may have a constant secondary inner diameter. The secondary inner diameter may be smaller than the primary inner diameter. The primary conduit may encompass at least a portion of the secondary conduit. The secondary outlet portion may be disposed within the primary conduit. The secondary inlet port may be connected in fluid communication with a source of the second fluid.