Abstract: An oxidation oven with a heated chamber for treating fibers, the heated chamber having two opposing sides, each side with a plurality of gaps to allow the fibers to pass to and from the heated chamber. Embodiments of the invention provide capture ducts, which are configured to be under negative pressure, the capture ducts draw-in heated chamber air that would otherwise flow through the gaps. Embodiments of the invention provide supply ducts, which are configured to be under positive pressure and provide heated air near the gaps. Embodiments of the invention provide louvers positioned near the gaps, the louvers are configured to reduce the flow of heated chamber air that would otherwise pass through the gaps.

Abstract: One embodiment is directed to an oven for heating fibers. The oven comprises a plurality of walls forming a chamber and a supply structure disposed within the chamber between first and second ends of the chamber. The supply structure is in communication with a first heating system and is configured to direct heated gas from the first heating system into a first portion of the chamber. The supply structure is in communication with a second heating system and is configured to direct heated gas from the second heating system into a second portion of the chamber.

Abstract: Protective enclosure and method for protecting heat sensitive, data recording devices in high temperature environments. The protective enclosure has a housing having at least one compartment for containing a heat sensitive, data recording device, e.g., a temperature recording device, and a jacket configured to contain a phase change material. The jacket may be vented and configured to at least partially surround the compartment. The housing may be sealed with an endcap. The recording device and a heat absorbing element are disposed within the same or within adjoining or adjacent sub-compartments within the enclosure. In a method, the enclosure with heat absorbing element and temperature recording device is placed within a heated environment or environment to be heated, e.g., a furnace. The recording device is connected to a thermal couple.

Abstract: A dryer comprising an enclosure and a transporter for transporting one or more components therethrough between a first and a second opening. The dryer includes one or more heating elements and a first and a second duct within the enclosure. The first and said second duct each include a plurality of openings configured for discharging heated air towards the one or more components. An exhaust stack in fluid communication with an interior of the enclosure includes an exhaust blower for extracting fluid from within the enclosure, and one or more heating elements for oxidizing the vaporized compounds. The supply and the exhaust blowers cooperatively operate to induce infiltration of air through the first and the second opening. A method for operating the dryer is also provided.

Abstract: An oxidation oven with a heated chamber for treating fibers, the heated chamber having two opposing sides, each side with a plurality of gaps to allow the fibers to pass to and from the heated chamber. Embodiments of the invention provide capture ducts, which are configured to be under negative pressure, the capture ducts draw-in heated chamber air that would otherwise flow through the gaps. Embodiments of the invention provide supply ducts, which are configured to be under positive pressure and provide heated air near the gaps. Embodiments of the invention provide louvers positioned near the gaps, the louvers are configured to reduce the flow of heated chamber air that would otherwise pass through the gaps.

Abstract: A thermal processing system for processing work pieces such as silicon wafers for photovoltaic cells. The system include a firing furnace comprised of upper and lower banks for microzones having infrared lamps in each microzone. The microzone are lined with or formed of a reflective insulative material. Some embodiments of the system of the invention can be used as or in a continuous infrared furnace of oven having a drying, burn-off and firing zone.

Abstract: A thermal oxidizer assembly is adapted for mounting onto a furnace, such that a heating chamber of the assembly is in direct flow-through communication with an interior of the furnace and defines a flow path for volatile organic compounds that are released from workpieces being processed within the furnace. A heating module is mounted within the heating chamber of the assembly and is located within the flow path to create turbulent flow therethrough. The assembly is configured to allow a natural draft to pull the volatile organic compounds from the furnace and through the flow path, and the heating module heats the volatile organic compounds, within the heating chamber, to a temperature necessary to destroy greater than approximately 99% of the volatile organic compounds. A flow rate of the volatile organic compounds being pulled along the flow path is, preferably, between approximately five and thirty standard cubic feet per minute.

Abstract: Protective enclosure and method for protecting heat sensitive, data recording devices in high temperature environments. The protective enclosure has a housing having at least one compartment for containing a heat sensitive, data recording device, e.g., a temperature recording device, and a jacket configured to contain a phase change material. The jacket may be vented and configured to at least partially surround the compartment. The housing may be sealed with an endcap. The recording device and a heat absorbing element are disposed within the same or within adjoining or adjacent sub-compartments within the enclosure. In a method, the enclosure with heat absorbing element and temperature recording device is placed within a heated environment or environment to be heated, e.g., a furnace. The recording device is connected to a thermal couple.

Abstract: A furnace of controlled heating and treatment of material using infrared radiation. The furnace is capable of continuous infrared treating of material with consistent radiation being applied to the material, ease of access to the furnace for maintenance cleaning and repair, excellent control of radiant cooling of the material to be treated, and ease of maintenance of a volatile component condenser.

Abstract: A vacuum oven with heat transfer fluid conduits. The oven of the invention generally includes a shell into which a removable rack may be placed. The rack has at least one plate which may be heated or cooled by a plate fluid conduit in contact with the plate and through which a heating or cooling fluid may be passed. Work pieces may be loaded in the rack, the rack placed in the shell, the shell sealed, and a vacuum drawn within the shell. The work pieces loaded on the rack are primarily heated and cooled by conductive and radiant heat transfer because of the limited amount of thermally conductive gases within the shell.

Abstract: The present invention provides a method of heat-treating an oxygen-sensitive workpiece to minimize any oxidation of the workpiece, as well as an improved door seal specially suited for use with oxygen-sensitive products. In the method, an oven has an oven chamber and an outer housing, with an enclosure being defined therebetween. The workpiece is placed in the oven chamber and the chamber is sealed. Heated inert gas is circulated within the enclosure to heat the oven chamber and to hold it at a desired treatment temperature. The oven chamber is then cooled to a threshold temperature of the workpiece using inert gas. The chamber is then cooled further by circulating aerobic gas, preferably ambient air, within the enclosure. Another embodiment of the invention provides an oven with a housing forming an oven chamber, the oven chamber having a door opening in one of said walls.

Abstract: The invention provides an oven which can be used to rapidly heat and cool a workpiece. In one embodiment, the oven includes a first duct which defines an initial leg of an enclosed air flow path and which has an inner panel and a heat exchanger. This first duct has an inlet end and an outlet end, the inlet end of which is connected to a temperature-controlled air supply. The oven also includes a second duct which defines a final leg of the enclosed air flow path and which has an inner panel spaced from the first duct's inner panel to define an oven cavity. The oven also has a connecting conduit connecting the outlet end of the first duct to the second duct and which defines an intermediate leg of the enclosed air flow path. In a preferred embodiment, the first duct is the lower of the two ducts and includes a plurality of holes through at least the inner panel of the duct.

Abstract: A microbial barrier isolation system for enclosing and decontaminating equipment so that the equipment may be used in handling or otherwise contacting biologically-sensitive materials such as parenteral solutions and solids. The barrier system is formed with a lower cavity, an upper chamber separated from the inner cavity by filters, an air return conduit, means for supplying dry, heated air to heat the system and means for using steam and hydrogen peroxide to decontaminate the internal parts of the system. The decontamination process involves using dry air to heat the internal equipment of the system to reduce water condensation and then introducing saturated steam and peroxide at a positive pressure slightly above atmospheric pressure. The internal equipment, including all surfaces, is exposed to the steam and peroxide sterilant for a sufficient time to decontaminate the equipment and the system is cooled down with cool, sterile air.

Abstract: An ultraviolet sterilization and decontamination system which is particularly useful in ultraviolet passthrough applications. The system includes a shell having a reflective inner surface and a barrier positioned within the shell and spaced inwardly of the inner surface of the shell, the barrier being formed of a material which will transmit at least about 70% of the desired wavelength of ultraviolet light. The space between the shell and the barrier defines a lamp cell for holding one or more ultraviolet lamps and the interior of the barrier defines a sterilization cell wherein items can be sterilized or decontaminated. The barrier is supported within the shell by supports and reflective endwalls substantially seal the lamp cell from the sterilization cell, as well as substantially sealing the sterilization cell and lamp cell from communication with the external environment.