Metal Fabricating - Tube Fabricating - Rubber Fabricating

Fabricating

Aluminum Fabricating Fabricating involves building, forming, welding and assembly of structures with sections to 10 ft x 12 ft, narrow structures up to 150 ft long or 2000 sq ft display booths. Materials used are tube, bar, rod, plate and sheet stock made from stainless steel, mild steel, aluminum, alloys and exotic metals.
A complete facility should include a CNC machine shop and a welding shop in addition to the fabrication capability, all under one roof. The combination of these functions gives the manufacturer control over the precision-machined components that become part of larger weldment assemblies. Frames, manifolds, bracket panels, flanges, clamps, tanks, housings, beams, structures, towers and displays are made for semiconductor, medical, telecommunication, electronic, marine, aerospace, construction and retail businesses.

Electrical Panel Fabricating
Electrical Panels: Design & engineering of electrical panels provides system assemblies completely wired and interconnected per the customer's specific design requirements. Components are mounted and wired to terminal strips in specified enclosures to meet all applicable industry standards. Panel assemblies range from small junction boxes to multiple enclosure systems.

Foam Fabricating Foam fabricating involves the production of parts and components from foam materials: polyurethane foam, polyethylene foam, foam cushions, acoustic foams, closed cell foams, and cushion foam.

Lead Fabricating Lead Fabricating: The process of lead fabrication can include shearing, cutting, forming, bending, trimming, laminating to provide components used in radiation shielding. Components can range from lead-lined panels for protecting a radiation source in an airport baggage scanner to lead-lined gypsum board to be used in a medical or dental office to isolate radiation from x-rays.

Tube Fabricating Tube Fabricating Designing parts to permit manufacture from tubing, or tubing in conjunction with other material forms, can provide dramatic cost reductions. At the same time, quality and function of parts can be improved. Tubular parts can provide structural integrity superior to that achievable with solid cylindrical and most shaped sectional elements. There is virtually no fabrication operation that cannot be performed on small diameter metal tubing while maintaining rigid tolerances. In addition, tubular parts can simultaneously provide functional utility for transmission of liquids, gases, wiring and other functions.
Generally speaking, tubular components should be seriously considered where: difficult miniature shapes are required; close tolerances are essential; reduced size or weight is desirable; maximum electrical and mechanical properties are required; smooth, burr-free surface finishes are needed; reducing materials waste would significantly reduce costs; alternate production methods require expensive machining or finishing operations; and a specific alloy is essential because of the particular application.

Rubber Fabricating Rubber Fabricating: Fabrication methods include homogeneous molding, die cutting, rubber to metal and rubber to plastic vulcanizing. Parts can be produced in various colors, durometers and textures from the following materials: Silicone, Flourosilicone, Viton, EPDM, Neoprene, Butyl, Isoprene, Buna-N/Nitrile, Natural Rubber, SBR, Millable Urethanes, AFLAS, and others. Many materials can be compounded to be Self-lubricating for ease of installation or to reduce drag in dynamic applications. Common uses are seals, bellows, vacuum suction cups, strain relief's, grommets, duckbill and umbrella valves, bushings, boots, diaphragms, connector insulators, interfacial seals, and die-cut gaskets (with or without pressure sensitive adhesives). Applications can include conductive materials for applications such as EMI/RFI shielding, and keyboard/keypad devices.

Wire Fabricating Wire Fabricating: The process of making products out of wire has progressed from loose tolerance everyday items to high precision products, including wireform/sheetmetal hybrids, for high technology applications. In these applications, hybrids can mean lower cost, lighter parts that are easier to work with and which provide more flexible solutions to design engineering parameters that cannot be met by sheet metal alone. The hybrids also allow for flexibility in production that blends well with users on just-in-time manufacturing systems or ship-to-stock programs.
Precision wireforms and especially wireform/sheetmetal hybrid products are particularly suitable for use as chassis within enclosures or other master assemblies. The hybrid chassis provides secure, precise alignment and location of the various components while maximizing design flexibilities and minimizing product weight and cost.

Plastic Fabricating
Other Fabricating materials: Aluminum, Aluminum Extrustions, Felt/Cork/Rubber, Heavy Steel & Plate, Non-metallic, Plastic, Stainless Steel, and Steel.

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		Fabricating involves building, forming, welding and assembly of structures with sections to 10 ft x 12 ft, narrow structures up to 150 ft long or 2000 sq ft display booths. Materials used are tube, bar, rod, plate and sheet stock made from stainless steel, mild steel, aluminum, alloys and exotic metals. A complete facility should include a CNC machine shop and a welding shop in addition to the fabrication capability, all under one roof. The combination of these functions gives the manufacturer control over the precision-machined components that become part of larger weldment assemblies. Frames, manifolds, bracket panels, flanges, clamps, tanks, housings, beams, structures, towers and displays are made for semiconductor, medical, telecommunication, electronic, marine, aerospace, construction and retail businesses.
		Electrical Panels: Design & engineering of electrical panels provides system assemblies completely wired and interconnected per the customer's specific design requirements. Components are mounted and wired to terminal strips in specified enclosures to meet all applicable industry standards. Panel assemblies range from small junction boxes to multiple enclosure systems.
		Foam fabricating involves the production of parts and components from foam materials: polyurethane foam, polyethylene foam, foam cushions, acoustic foams, closed cell foams, and cushion foam.
		Lead Fabricating: The process of lead fabrication can include shearing, cutting, forming, bending, trimming, laminating to provide components used in radiation shielding. Components can range from lead-lined panels for protecting a radiation source in an airport baggage scanner to lead-lined gypsum board to be used in a medical or dental office to isolate radiation from x-rays.
		Tube Fabricating Designing parts to permit manufacture from tubing, or tubing in conjunction with other material forms, can provide dramatic cost reductions. At the same time, quality and function of parts can be improved. Tubular parts can provide structural integrity superior to that achievable with solid cylindrical and most shaped sectional elements. There is virtually no fabrication operation that cannot be performed on small diameter metal tubing while maintaining rigid tolerances. In addition, tubular parts can simultaneously provide functional utility for transmission of liquids, gases, wiring and other functions. Generally speaking, tubular components should be seriously considered where: difficult miniature shapes are required; close tolerances are essential; reduced size or weight is desirable; maximum electrical and mechanical properties are required; smooth, burr-free surface finishes are needed; reducing materials waste would significantly reduce costs; alternate production methods require expensive machining or finishing operations; and a specific alloy is essential because of the particular application.
		Rubber Fabricating: Fabrication methods include homogeneous molding, die cutting, rubber to metal and rubber to plastic vulcanizing. Parts can be produced in various colors, durometers and textures from the following materials: Silicone, Flourosilicone, Viton, EPDM, Neoprene, Butyl, Isoprene, Buna-N/Nitrile, Natural Rubber, SBR, Millable Urethanes, AFLAS, and others. Many materials can be compounded to be Self-lubricating for ease of installation or to reduce drag in dynamic applications. Common uses are seals, bellows, vacuum suction cups, strain relief's, grommets, duckbill and umbrella valves, bushings, boots, diaphragms, connector insulators, interfacial seals, and die-cut gaskets (with or without pressure sensitive adhesives). Applications can include conductive materials for applications such as EMI/RFI shielding, and keyboard/keypad devices.
		Wire Fabricating: The process of making products out of wire has progressed from loose tolerance everyday items to high precision products, including wireform/sheetmetal hybrids, for high technology applications. In these applications, hybrids can mean lower cost, lighter parts that are easier to work with and which provide more flexible solutions to design engineering parameters that cannot be met by sheet metal alone. The hybrids also allow for flexibility in production that blends well with users on just-in-time manufacturing systems or ship-to-stock programs. Precision wireforms and especially wireform/sheetmetal hybrid products are particularly suitable for use as chassis within enclosures or other master assemblies. The hybrid chassis provides secure, precise alignment and location of the various components while maximizing design flexibilities and minimizing product weight and cost.
		Other Fabricating materials: Aluminum, Aluminum Extrustions, Felt/Cork/Rubber, Heavy Steel & Plate, Non-metallic, Plastic, Stainless Steel, and Steel. Brought to you by: