Abstract: Ions for neutralizing electrostatic charge on an object are generated and delivered in a stream of gas flowing through a dielectric channel that surrounds a loop of conductive filament which forms an ionizing electrode. The loop is formed within a single plane, or within multiple planes, and is supported within the channel with a plane of the loop substantially aligned with flow of gas through the channel. A region of minimum field intensity within the bounded region of the loop electrode is oriented in alignment with substantially maximum velocity of gas flow through a cross section of the dielectric channel.

Abstract: Method and apparatus for generating positive and negative ions include electrodes that are spaced apart by a gap and that are supplied alternating ionizing voltage at a frequency which causes the generated ions to move within the gap between electrodes and exhibit a resident time in transit that accumulates the ions substantially within the central region of the gap. An electrostatic field, or a flowing stream of air or other gas passing through the gap, transports the generated ions from within the gap. Self-balancing of generated positive and negative ions is accomplished using capacitive coupling of the ionizing voltage to at least one of the electrodes disposed about the gap.

Abstract: An air ionizing module and method for generating ions of one and opposite polarities within a flowing stream of air or other gas includes a thin-filament electrode mounted within the flowing stream in regions thereof of maximum flow velocity. The thin-filament electrode is mounted in a multi-sided polygonal configuration to receive high ionizing voltage of alternating one and opposite polarities to form an intense stream of ions toward an electrically-isolated reference electrode positioned upstream of the filament electrode. Another reference electrode positioned within the flowing stream downstream of the filament electrode receives a bias voltage of selected polarity to control the quantities of generated ions of positive and negative polarities in an outlet stream of the ions and flowing gas.

Abstract: Method and apparatus for generating positive and negative ions include electrodes that are spaced apart by a gap and that are supplied alternating ionizing voltage at a frequency which causes the generated ions to move within the gap between electrodes and exhibit a resident time in transit that accumulates the ions substantially within the central region of the gap. An electrostatic field, or a flowing stream of air or other gas passing through the gap, transports the generated ions from within the gap. Self-balancing of generated positive and negative ions is accomplished using capacitive coupling of the ionizing voltage to at least one of the electrodes disposed about the gap.

Abstract: Static neutralization of a charged object is provided by generating, in an ionizing cell or module, an ion cloud having a mix of positively and negatively charged ions, and reshaping the ion cloud by redistributing the ions into two regions of opposite polarity by using a second voltage. The second voltage creates an electrical field, which is preferably located in the vicinity of the ion cloud. The redistribution of the ions increases the effective range in which available ions may be displaced or directed towards the charged object. The electrical field redistributes ions that form the ion cloud. Ion redistribution within the ion cloud occurs because ions having a polarity corresponding to the polarity of the second voltage are repelled from the electrical field, and ions having a polarity opposite from that of the electrical field are attracted to electrical field.

Abstract: An ionizer bar includes upper and lower housings having aerodynamically-shaped exterior surfaces to support laminar air flow over the structure. The upper housing forms an upper interior chamber for electrical circuitry isolated from a lower chamber within the lower housing that confines fluid under pressure therein. Outlets spaced along the length of the structure include ionizing electrodes that are disposed within fluid conduits and that are connected to a source of ionizing voltage mounted in the upper chamber. Fluid passages at the outlets release fluid under pressure within the lower chamber around associated ionizing electrodes mounted at the outlets.

Abstract: The present invention relates to ion emitter tip metals and alloys for ionizing the molecules of a gas which concurrently produces small diameter and very low numbers of unwanted particles. Specifically, the invention discloses ion emitter tip materials which, when subjected to normal operating electrical conditions of between about 0.1 and 100 microamperes per emitter tip, produces about 1 particle or less having a diameter of about 0.5 microns or less per cubic foot. Useful ion emitter tip materials include zirconium, titanium, molybdenum, tantalum, rhenium or alloys of these metals. In a specific embodiment, the metal alloys comprise zirconium and rhenium, titanium and rhenium, molybdenum and rhenium, or tantalum and rhenium. Silicon coated metal emitter tips, particularly titanium-silicon coated are disclosed. The emitter tip materials are useful to obtain Class 1 clean room standards in static air or flowing air environments used, for example, in semiconductor manufacture.

Abstract: The present invention relates to ion emitter tip metals and alloys for ionizing the molecules of a gas which concurrently produces small diameter and very low numbers of unwanted particles. Specifically, the invention discloses ion emitter tip materials which, when subjected to normal operating electrical conditions of between about 0.1 and 100 microamperes per emitter tip, produces about 1 particle or less having a diameter of about 0.5 microns or less per cubic foot. Useful ion emitter tip materials include zirconium, titanium, molybdenum, tantalum, rhenium or alloys of these metals. In a specific embodiment, the metal alloys comprise zirconium and rhenium, titanium and rhenium, molybdenum and rhenium, or tantalum and rhenium. Silicon coated metal emitter tips, particularly titanium-silicon coated are disclosed. The emitter tip materials are useful to obtain Class 1 clean room standards in static air or flowing air environments used, for example, in semiconductor manufacture.