A water sprinkler includes a housing and an ejection head. An impeller is assembled in the housing, pushed by water, and connected to a cam. A water-hit target is pivoted with the housing via a compression spring, and an impacted portion of the water-hit target is extending outside of the housing. The water-hit target repeatedly impacts the housing because of the pivoting motion caused by the pushing of water flow and by the pulling of the compression spring, so that the housing is pivoted to change the ejection direction of the ejection head. A water baffling cover is pivoted with the housing. A abutted member is assembled on the water baffling cover and abutted against the cam. The cam can push the abutted member to drive the pivoting motion of the water baffling cover, so that the water baffling cover shields the ejection head by different extents.

The sprinkler has a drive motor with a gear assembly with a drive gear that is engaged with the sun gear of the flow adapter. A motor housing has a gear train chamber for the gear assembly, and a first chamber and a second chamber each providing for a path of flow. A switching mechanism has a valve block for alternatingly blocking and establishing the path of flow through one of the first chamber and the second chamber of the motor housing. A water wheel alternating in rotation between a clockwise direction and a counter clockwise direction based on the path of flow from one of the first chamber and the second chamber of the motor housing and engaging the gear assembly to rotate the gear assembly back and forth around the sun gear of the flow adapter and simultaneously moving the oscillating nozzle.

Rotational speed of a spray arm is regulated based on centrifugal force and a liquid jet to create a variable angle corner spray nozzle. The regulator includes a weight on a pivot and a fluid jet, the weight having a curved surface to produce a variable angle corner spray nozzle depending on the weight angle. Centrifugal force created during rotation pushes the weight outward, which increases as the spray arm rotation speed increases. The liquid jet is located out from a pivot point and tends to push the weight inward. The pushing force of the liquid jet is maximum when the weight is most inward and minimum when the weight is most outward. The regulator stabilizes the arm speed at a specific speed independent from center pivot friction and the spray arm nozzle's orientation tolerance. Speed stabilizes when centrifugal force on the weight is equal to the pushing force of the fluid jet.

Various embodiments include a fogging sprayer nozzle that includes a nozzle base and an outer cap. The nozzle base includes an inner passage extending along an axial extent of the nozzle base. The inner passage may be configured to allow a first fluid to pass through the nozzle base from a proximal base aperture in a proximal end of the nozzle base to a distal base aperture in a distal end of the nozzle base. The nozzle base may include a plurality of fins radially extending outwardly and spiraling along the axial extent of the nozzle base. The outer cap includes an inner chamber configured to receive and surround at least a portion of the nozzle base seated therein. The outer cap includes a proximal cap aperture in a proximal end of the outer cap and a distal cap aperture in a distal end of the outer cap. The nozzle base may be received through the proximal cap aperture. A second fluid may be configured to flow inside the inner chamber and between the plurality of fins from the proximal cap aperture toward the distal cap aperture.

Rotary jet nozzle assembly (1) for pressure cleaning devices, comprising: a housing (2) extended along a first longitudinal axis (X) between an inlet (3) and an outlet (4) of a washing liquid, defining therein a containment chamber (5) of the washing liquid in fluid communication with the inlet (3); a support (10) rotatable within said containment chamber (5) and about the first longitudinal axis (X) due to the effect of the washing liquid coming from the inlet (3); a nozzle body (20) extended along a second longitudinal axis (Y) inclined with respect to the first longitudinal axis (X) and traversed by a delivery duct (28), the nozzle body (20) being associated with the support (10) and driven in rotation thereby; and a counterweight, integral with the support (10) and arranged in a position that is eccentric and opposite the nozzle body (20) with respect to the first longitudinal axis (X).

A sprinkler assembly with a nutating distribution plate that tilts and/or rotates upon water impinging the distribution plate. A deflector assembly includes the distribution plate and a base. A body of the sprinkler assembly includes a base retainer surface and a flanged bolt which combine to create a portion of a confinement structure. A portion of the deflector assembly is located within the confinement structure to limit a range of movement of the distribution plate. A nozzle subassembly includes a nozzle and retainer supporting a seal. The nozzle alone or in combination with the retainer can be removed from the sprinkler assembly. The sprinkler assembly can be disassembled and reassembled with minimal tools and effort for servicing. The distribution plate and the base can have mass properties optimized to improve sprinkler performance by reducing vibration, improving uniform water distribution, and reducing fine water droplet generation upon water stream impingement on the distribution plate.

Described are riser assemblies suitable for use with fluid dispensers. The assemblies include a container partially circumscribing a reservoir configured to contain a pressurized fluid, the container having a fluid inlet and a fluid outlet disposed therethrough. The assemblies may further include a signal processor situateable outside the container that is configured to receive a signal. The signal processor may be operatively connectable to a control valve that is operatively connectable to the fluid dispenser. The control valve may be configured to selectively control expulsion of the fluid through the fluid dispenser in response to the signal received by the signal processor. Embodiments of the riser assemblies include a utility conduit disposed at least partially within the reservoir and configured to enable secondary use of a resource from within the riser assembly and/or to accommodate transport and securing of the riser assemblies for use.

A short stress path-type electrode sheet rolling machine and an integrated machine equipment for manufacturing lithium battery electrode sheets, whereby the rolling machine comprises: an upper roller mechanism, a lower roller mechanism, an upper bearing base, a lower bearing base and a roller-gap adjusting mechanism; the upper roller mechanism is connected to the upper bearing base, and the lower roller mechanism is connected to the lower bearing base; the upper bearing base and the lower bearing base are connected by means of a guide shaft; the roller-gap adjusting mechanism is connected to the upper roller mechanism so as to adjust a roller gap between the upper roller mechanism and the lower roller mechanism. The rolling machine has a simpler and more reliable structure, has a shorter stress return path when performing electrode sheet rolling, and may improve rolling precision and rolling quality.

The present invention discloses a water-saving dynamic water outlet device, which comprising a base, an inclined water body, a swinging water assembly, an impeller assembly and a driving assembly, the inclined water body is connected with the base to form a cavity, the cavity is provided with a water outlet, the impeller assembly is arranged in the cavity, and the driving assembly can drive the swinging water assembly to swing in a reciprocating manner under the driving of the impeller assembly; the swinging water assembly is installed on the base and can swing in the base, a water passing chamber is formed in the swinging assembly, and a water passing port is formed in the side face of the swinging assembly, the water outlet is communicated with the water passing port through a communicating channel, and the plane where the water outlet is located and the plane where the water outlet is located are arranged non-parallel. The water-saving dynamic water outlet device has a good water-saving effect, and enables the user to have a sweeping impact massage feeling when using it and with strong comfort.

The present invention discloses a water-saving dynamic water outlet device, which comprising a base, an inclined water body, a swinging water assembly, an impeller assembly and a driving assembly, the inclined water body is connected with the base to form a cavity, the cavity is provided with a water outlet, the impeller assembly is arranged in the cavity, and the driving assembly can drive the swinging water assembly to swing in a reciprocating manner under the driving of the impeller assembly; the swinging water assembly is installed on the base and can swing in the base, a water passing chamber is formed in the swinging assembly, and a water passing port is formed in the side face of the swinging assembly, the water outlet is communicated with the water passing port through a communicating channel, and the plane where the water outlet is located and the plane where the water outlet is located are arranged non-parallel. The water-saving dynamic water outlet device has a good water-saving effect, and enables the user to have a sweeping impact massage feeling when using it and with strong comfort.