Various embodiments for an adjustable flow nozzle system having a manifold with a plurality of adjustable flow nozzles in which the flow rate of each adjustable flow nozzle may be individually adjusted are described herein.

Various embodiments for an adjustable flow nozzle system having a manifold with a plurality of adjustable flow nozzles in which the flow rate of each adjustable flow nozzle may be individually adjusted are described herein.

Various embodiments for an adjustable flow nozzle system having a manifold with a plurality of adjustable flow nozzles in which the flow rate of each adjustable flow nozzle may be individually adjusted are described herein.

The present disclosure is intended to provide a nozzle for a sanitary cleaning device, the nozzle being configured such that the positioning of a channel-forming member can be easily performed in an axial direction of a nozzle cover. The nozzle is for used for a sanitary cleaning device, and includes: a nozzle cover made of ceramic and having a nozzle cover-side water ejection opening; a distal-side channel-forming component disposed in the nozzle cover and having a channel-side water ejection opening which communicates with the nozzle cover-side water ejection opening; and a rear-side channel-forming components connected to a rear portion of the distal-side channel-forming component in an axial direction of the nozzle cover, and capable of being adjusted in position in the axial direction of the nozzle cover with respect to the distal-side channel-forming component.

Disclosed is an adjustable and portable fire protection sprinkler system. The device consists of a sprinkler head mounted on an adjustable height center pole connected to adjustable legs, forming a foldable tripod-like configuration. The legs and center pole have inner and outer tubes arranged for telescopic movement relative to each other, for adjusting the height of the pole and the lengths of the legs. The sprinkler head is connected to a rubber hose which is threaded through the top of the center pole and connected to a water source at the bottom. The tube stretches and retracts inside the pole corresponding to the pole height. A collar around the pole connected to the legs, wherein the legs connected to the end of the pole by metal strips. This allows for sliding up and down; increasing or decreasing the triangular base parameter. The base is also defined by the length of the legs and is adjusted to maintain the tripod stability.

The present invention relates to a digital mist nozzle structure that is connected to a general pipeline and continuously sprays water or a chemical solution in the form of a mist, so that it can be efficiently used for indoor humidification or entrance disease prevention. In order to accomplish the above object, the present invention provides a digital mist nozzle structure including: a pipe connector formed in a T shape and configured to be connected to a pipeline; a nozzle body connected to the pipe connector; an ultrasonic vibration nozzle coupled to one end of the nozzle body; and a nozzle cap fastened to the nozzle body in order to prevent the ultrasonic vibration nozzle from being separated.

Embodiments of the present invention are related to a fluid control device for cleaning elevated channels including a top, a bottom, a first side, a second side, and a pair of angled exterior upper surfaces. The top includes a top aperture structured to receive tubing therein and the first side and second side include a spout respectively. The fluid control device is structured to receive fluid into the device top and direct that fluid out the first side and second side at downward side angles.

Embodiments of the present invention are related to a fluid control device for cleaning elevated channels including a top, a bottom, a first side, a second side, and a pair of angled exterior upper surfaces. The top includes a top aperture structured to receive tubing therein and the first side and second side include a spout respectively. The fluid control device is structured to receive fluid into the device top and direct that fluid out the first side and second side at downward side angles.

A continuously variable nozzle system includes a nozzle body (5) with an inlet and an outlet. A conduit is defined between the inlet and the outlet by a series connection of components which includes a flow meter (10). The flow meter (10) has a chamber (83) with internal helical splines (82) that are configured to interact with a spray liquid passing through the chamber (83) and create a cyclone-like effect. A sphere (52) is located inside the chamber (83) for free movement along a circular path (106). A sensor is located outside of the chamber (83) and configured to detect motion of the sphere (52) and generate an output (9) signal in response to detected motion.

A massage nozzle includes a nozzle housing and a nozzle core detachably attached in the nozzle housing. The nozzle housing is split-type and includes a cover mounted in a hole of a wall of a hot tub, a nozzle seat and a fastener. The cover includes an end ring and a side wall extending from the end ring. The side wall is conformed with the hole. The nozzle seat includes an inlet and a spray end which has a surface conformed with the side wall. The nozzle seat passes through and detachably connects with the cover. The outer circumferential surface of the spray end contacts with an inner surface of the side wall. The fastener is detachably sleeved on the outer circumferential surface of the nozzle seat and cooperates with the cover to fix the nozzle seat to the hot tub. The installation is convenient and the cost is reduced.