An apparatus and a method for cleaning glass used in cars or cameras are disclosed. Said cleaning apparatus comprises glass, multiple electrodes placed in series on top of said glass, a dielectric layer stacked on top of said electrodes, and a hydrophobic layer stacked on top of said dielectric layer and on whose surface a droplet forms. Here, said droplet moves towards the outer edge of said glass by application of differing direct current voltages to several of said electrodes.

An apparatus and a method for cleaning glass used in cars or cameras are disclosed. Said cleaning apparatus comprises glass, multiple electrodes placed in series on top of said glass, a dielectric layer stacked on top of said electrodes, and a hydrophobic layer stacked on top of said dielectric layer and on whose surface a droplet forms. Here, said droplet moves towards the outer edge of said glass by application of differing direct current voltages to several of said electrodes.

A portable cleaning device comprising a generally cylindrical container for receiving a fluid to a predetermined level and defining a container axis and having a bottom wall and a top opening at opposing axial ends along said container axis; a basket for supporting items to be cleaned and dimensioned to be removably receivable within said container, said basket defining a basket axis that is substantially coextensive with said container axis when said basket is received within said container and being configured to be rotatably supported for rotation on said bottom wall about said axes when received within said container; and spinning means for spinning said basket on said bottom wall about said axes when said basket is received within said container, whereby spinning said basket within said container on said bottom wall when immersed in fluid below said predetermined level creates turbulence and agitates the fluid in contact with the items to be cleaned to dislodge soil particles and contaminants from the items to be cleaned.

A portable cleaning device comprising a generally cylindrical container for receiving a fluid to a predetermined level and defining a container axis and having a bottom wall and a top opening at opposing axial ends along said container axis; a basket for supporting items to be cleaned and dimensioned to be removably receivable within said container, said basket defining a basket axis that is substantially coextensive with said container axis when said basket is received within said container and being configured to be rotatably supported for rotation on said bottom wall about said axes when received within said container; and spinning means for spinning said basket on said bottom wall about said axes when said basket is received within said container, whereby spinning said basket within said container on said bottom wall when immersed in fluid below said predetermined level creates turbulence and agitates the fluid in contact with the items to be cleaned to dislodge soil particles and contaminants from the items to be cleaned.

A drive system for a net cleaner to produce efficient propulsion without damage to the cage net. The drive system includes flexible engagement stumps protruding from a base of a driving belt with tips or studs mounted on an end of the stumps. The tips or studs engage the net and propel the net cleaner. The stumps flex to insure that, if excessive pressure is applied to a stud, the stump will bend and the net will release without damage. A guard prevents the stump from directly engaging a cage net. A track belt produces efficient propulsion without damage to the cage net. The track belt includes flexible engagement stumps protruding from a base of a driving belt with tips or studs mounted on an end of the stumps.

This invention relates to systems and methods that produce a treatment beam with a controllable beam size. This is accomplished by providing an auxiliary chamber in open fluid communication with the main process chamber. A nozzle is mounted in a recessed manner in the auxiliary chamber. The nozzle dispenses a treatment spray into the auxiliary chamber. The auxiliary chamber shapes and dispenses the treatment material as a treatment beam into the process chamber. In illustrative embodiments, control of process chamber pressure adjusts the beam size of a treatment beam used to treat the surface of one or more microelectronic substrates.

This invention relates to systems and methods that produce a treatment beam with a controllable beam size. This is accomplished by providing an auxiliary chamber in open fluid communication with the main process chamber. A nozzle is mounted in a recessed manner in the auxiliary chamber. The nozzle dispenses a treatment spray into the auxiliary chamber. The auxiliary chamber shapes and dispenses the treatment material as a treatment beam into the process chamber. In illustrative embodiments, control of process chamber pressure adjusts the beam size of a treatment beam used to treat the surface of one or more microelectronic substrates.

A cleaning device (10, 110, 210) may be a card-like member such as a flap (16, 116), integrally formed with a dispenser container (12), or a slotted member (36) mounted on a stand-alone cleaning device (110). A cleaning wipe fabric (22, 122) has a modulus of stiffness which is high enough to bridge a plurality of cleaning slots (26a-26d, 126a-126d) and hold the fabric out of contact with the slot floor surfaces (26a′), and low enough to be deflected by a fiber optic end being cleaned to sag within the cleaning slot to better enclose and clean the tip of the fiber optic end. Used cleaning fabric (22, 122) can easily be advanced or removed as needed to avoid using the same area of fabric for cleaning more than once.

A cleaning device (10, 110, 210) may be a card-like member such as a flap (16, 116), integrally formed with a dispenser container (12), or a slotted member (36) mounted on a stand-alone cleaning device (110). A cleaning wipe fabric (22, 122) has a modulus of stiffness which is high enough to bridge a plurality of cleaning slots (26a-26d, 126a-126d) and hold the fabric out of contact with the slot floor surfaces (26a′), and low enough to be deflected by a fiber optic end being cleaned to sag within the cleaning slot to better enclose and clean the tip of the fiber optic end. Used cleaning fabric (22, 122) can easily be advanced or removed as needed to avoid using the same area of fabric for cleaning more than once.

The present invention provides a refillable container (1) for use with a nebulizer device having an aerosol generator comprising a transducer body and a membrane having pores, the container having an opening being fillable with a cleaning liquid (3), wherein the opening is sized and shaped to fit onto the transducer body, so that the container is held in place on the nebulizer device and the membrane is immersed in the liquid inside the container. The invention also provides a pack comprising a multi-day supply of a drug, one or more cleaning liquids and one or more containers; and a method for cleaning the membrane of a nebulizer device using the container.