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General Filters Oil Filter Cartridge, 10 gph, Filter Rating: 10, Filter Media Type: Wool Felt, Suitable for: 77B, 1A-25B, 1A-25A Fuel Oil Filters
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General Filters Oil Filter Cartridge, Filter Media Type: Microfiber, Suitable for: 77B, 1A-25B, 1A-25A Fuel Oil Filters
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10-micron wool felt. Center core bonded to prevent media migration.
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10-micron wool felt. Center core bonded to prevent media migration.
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Mainly used on burners with a hollow cone air pattern and for throughputs up to 2.00 GPH. The droplet distribution is concentrated on the outside of the cone and results in good ignition and low-noise combustion.
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Produce a spray that distributes droplets fairly uniformly throughout the complete pattern. The spray pattern becomes progressively more hollow at higher flow rates. Provides smooth ignition and efficient combustion, particularly in larger burners.
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Mainly used on burners with a hollow cone air pattern and for throughputs up to 2 GPH. The droplet distribution is concentrated on the outside of the cone and results in good ignition and low-noise combustion.
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Produce a spray that distributes droplets fairly uniformly throughout the complete pattern. The spray pattern becomes progressively more hollow at higher flow rates. Provides smooth ignition and efficient combustion, particularly in larger burners.
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Mainly used on burners with a hollow cone air pattern and for throughputs up to 2 GPH. The droplet distribution is concentrated on the outside of the cone and results in good ignition and low-noise combustion.
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Produce a spray that distributes droplets fairly uniformly throughout the complete pattern. The spray pattern becomes progressively more hollow at higher flow rates. Provides smooth ignition and efficient combustion, particularly in larger burners.
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Mainly used on burners with a hollow cone air pattern and for throughputs up to 2.00 GPH. The droplet distribution is concentrated on the outside of the cone and results in good ignition and low-noise combustion.
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Mainly used on burners with a hollow cone air pattern and for throughputs up to 2 GPH. The droplet distribution is concentrated on the outside of the cone and results in good ignition and low-noise combustion.
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Produce a spray that distributes droplets fairly uniformly throughout the complete pattern. The spray pattern becomes progressively more hollow at higher flow rates. Provides smooth ignition and efficient combustion, particularly in larger burners.
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Mainly used on burners with a hollow cone air pattern and for throughputs up to 2 GPH. The droplet distribution is concentrated on the outside of the cone and results in good ignition and low-noise combustion.
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Mainly used on burners with a hollow cone air pattern and for throughputs up to 2 GPH. The droplet distribution is concentrated on the outside of the cone and results in good ignition and low-noise combustion.
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Produce a spray that distributes droplets fairly uniformly throughout the complete pattern. The spray pattern becomes progressively more hollow at higher flow rates. Provides smooth ignition and efficient combustion, particularly in larger burners.
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Produce a spray that distributes droplets fairly uniformly throughout the complete pattern. The spray pattern becomes progressively more hollow at higher flow rates. Provides smooth ignition and efficient combustion, particularly in larger burners.
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Mainly used on burners with a hollow cone air pattern and for throughputs up to 2.00 GPH. The droplet distribution is concentrated on the outside of the cone and results in good ignition and low-noise combustion.
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Produce a spray that distributes droplets fairly uniformly throughout the complete pattern. The spray pattern becomes progressively more hollow at higher flow rates. Provides smooth ignition and efficient combustion, particularly in larger burners.
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Mainly used on burners with a hollow cone air pattern and for throughputs up to 2 GPH. The droplet distribution is concentrated on the outside of the cone and results in good ignition and low-noise combustion.
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Mainly used on burners with a hollow cone air pattern and for throughputs up to 2 GPH. The droplet distribution is concentrated on the outside of the cone and results in good ignition and low-noise combustion.
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Mainly used on burners with a hollow cone air pattern and for throughputs up to 2.00 GPH. The droplet distribution is concentrated on the outside of the cone and results in good ignition and low-noise combustion.
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Produce a spray that distributes droplets fairly uniformly throughout the complete pattern. The spray pattern becomes progressively more hollow at higher flow rates. Provides smooth ignition and efficient combustion, particularly in larger burners.
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Mainly used on burners with a hollow cone air pattern and for throughputs up to 2 GPH. The droplet distribution is concentrated on the outside of the cone and results in good ignition and low-noise combustion.
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Mainly used on burners with a hollow cone air pattern and for throughputs up to 2.00 GPH. The droplet distribution is concentrated on the outside of the cone and results in good ignition and low-noise combustion.
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Produce a spray that distributes droplets fairly uniformly throughout the complete pattern. The spray pattern becomes progressively more hollow at higher flow rates. Provides smooth ignition and efficient combustion, particularly in larger burners.
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Mainly used on burners with a hollow cone air pattern and for throughputs up to 2 GPH. The droplet distribution is concentrated on the outside of the cone and results in good ignition and low-noise combustion.
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Produce a spray that distributes droplets fairly uniformly throughout the complete pattern. The spray pattern becomes progressively more hollow at higher flow rates. Provides smooth ignition and efficient combustion, particularly in larger burners.
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Produce a spray that distributes droplets fairly uniformly throughout the complete pattern. The spray pattern becomes progressively more hollow at higher flow rates. Provides smooth ignition and efficient combustion, particularly in larger burners.
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Mainly used on burners with a hollow cone air pattern and for throughputs up to 2 GPH. The droplet distribution is concentrated on the outside of the cone and results in good ignition and low-noise combustion.
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Produce a spray that distributes droplets fairly uniformly throughout the complete pattern. The spray pattern becomes progressively more hollow at higher flow rates. Provides smooth ignition and efficient combustion, particularly in larger burners.
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Mainly used on burners with a hollow cone air pattern and for throughputs up to 2 GPH. The droplet distribution is concentrated on the outside of the cone and results in good ignition and low-noise combustion.
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Neither truly a hollow or solid nozzle. The nozzles frequently can be used in place of either solid or hollow cone nozzles between 0.4 and 8 GPH, regardless of the burner's air pattern. The lower flow rates tend to be more hollow. Higher flow rates tend to be more solid.
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Mainly used on burners with a hollow cone air pattern and for throughputs up to 2 GPH. The droplet distribution is concentrated on the outside of the cone and results in good ignition and low-noise combustion.
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Produce a spray that distributes droplets fairly uniformly throughout the complete pattern. The spray pattern becomes progressively more hollow at higher flow rates. Provides smooth ignition and efficient combustion, particularly in larger burners.
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Produce a spray that distributes droplets fairly uniformly throughout the complete pattern. The spray pattern becomes progressively more hollow at higher flow rates. Provides smooth ignition and efficient combustion, particularly in larger burners.
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Produce a spray that distributes droplets fairly uniformly throughout the complete pattern. The spray pattern becomes progressively more hollow at higher flow rates. Provides smooth ignition and efficient combustion, particularly in larger burners.
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Mainly used on burners with a hollow cone air pattern and for throughputs up to 2.00 GPH. The droplet distribution is concentrated on the outside of the cone and results in good ignition and low-noise combustion.
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Mainly used on burners with a hollow cone air pattern and for throughputs up to 2 GPH. The droplet distribution is concentrated on the outside of the cone and results in good ignition and low-noise combustion.
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Mainly used on burners with a hollow cone air pattern and for throughputs up to 2 GPH. The droplet distribution is concentrated on the outside of the cone and results in good ignition and low-noise combustion.
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Produce a spray that distributes droplets fairly uniformly throughout the complete pattern. The spray pattern becomes progressively more hollow at higher flow rates. Provides smooth ignition and efficient combustion, particularly in larger burners.
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Produce a spray that distributes droplets fairly uniformly throughout the complete pattern. The spray pattern becomes progressively more hollow at higher flow rates. Provides smooth ignition and efficient combustion, particularly in larger burners.
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Mainly used on burners with a hollow cone air pattern and for throughputs up to 2 GPH. The droplet distribution is concentrated on the outside of the cone and results in good ignition and low-noise combustion.
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Produce a spray that distributes droplets fairly uniformly throughout the complete pattern. The spray pattern becomes progressively more hollow at higher flow rates. Provides smooth ignition and efficient combustion, particularly in larger burners.
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Mainly used on burners with a hollow cone air pattern and for throughputs up to 2 GPH. The droplet distribution is concentrated on the outside of the cone and results in good ignition and low-noise combustion.
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Produce a spray that distributes droplets fairly uniformly throughout the complete pattern. The spray pattern becomes progressively more hollow at higher flow rates. Provides smooth ignition and efficient combustion, particularly in larger burners.
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Produce a spray that distributes droplets fairly uniformly throughout the complete pattern. The spray pattern becomes progressively more hollow at higher flow rates. Provides smooth ignition and efficient combustion, particularly in larger burners.
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Mainly used on burners with a hollow cone air pattern and for throughputs up to 2 GPH. The droplet distribution is concentrated on the outside of the cone and results in good ignition and low-noise combustion.
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Mainly used on burners with a hollow cone air pattern and for throughputs up to 2 GPH. The droplet distribution is concentrated on the outside of the cone and results in good ignition and low-noise combustion.
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Mainly used on burners with a hollow cone air pattern and for throughputs up to 2 GPH. The droplet distribution is concentrated on the outside of the cone and results in good ignition and low-noise combustion.
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Mainly used on burners with a hollow cone air pattern and for throughputs up to 2 GPH. The droplet distribution is concentrated on the outside of the cone and results in good ignition and low-noise combustion.
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Delavan Type A Hollow Cone Oil Nozzle, Brass, 3/4 in Width, 1-5/8 in Height, Specifications: 1.25 GPH Capacity, 70 deg Spray Angle, Hollow Cone Spray
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At the forefront of nozzle development, Delavan created its nozzle using bi-metal construction. The brass body and stainless steel metering parts permit machining to close tolerances for precision and consistently high performance. Brass transmits heat fast from the nozzle face to reduce the possibility of varnish and oil residue buildup. Stainless steel provides that extra durability for metering parts where wear is a factor.
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At the forefront of nozzle development, Delavan created its nozzle using bi-metal construction. The brass body and stainless steel metering parts permit machining to close tolerances for precision and consistently high performance. Brass transmits heat fast from the nozzle face to reduce the possibility of varnish and oil residue buildup. Stainless steel provides that extra durability for metering parts where wear is a factor.
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Low-capacity nozzles designed to minimize the plugging problems associated with very low flow rates. The special interior design of the Del-O-Flo flushes contaminants through, limiting build-up. These nozzles will interchange whenever standard A or B nozzles are called for.
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General Filters Oil Filter Cartridge, 45 gph, 15 psi, 3-3/4 in Dia, 5-1/2 in H
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General Filters Gar-Ber Spin-On Fuel Filter, 3/8 in Connection, NPT Connection, 45 gph Flow Rate, 15 psi Pressure, 10 um Filter, Aluminum Head, Dimensions: 3-3/4 in W x 7-1/2 in H
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For oil-fired heating appliances used in small to average sized homes and commercial buildings. Used for final filtration in central fuel oil distribution systems. May be used in one or two-pipe systems. Working pressure of 12 psi. UL listed. 3/8 in NPT standard.
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For oil-fired heating appliances used in small to average sized homes and commercial buildings. Used for final filtration in central fuel oil distribution systems. May be used in one or two-pipe systems. Working pressure of 12 psi. UL listed. 3/8 in NPT standard.
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A black plastic display and storage rack. Holds up to 120 nozzles (12 vials in 10 slots). Lightweight and easily mounts when using the pre-drilled holes. Comes packaged two to a carton.
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Honeywell Oil Burner Control, Specifications: 120 V
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