Soft density and med/fine/very fine abrasive grades produce brushed surfaces without compounds
Provides more surface contact than bristle-type brushes
Continuously supplies fresh abrasives for consistent, uniform finishes
Non-woven web is load and heat resistant, enabling fine finishing results on a variety of materials
Achieves decorative finishes on metal, wood, and composites
Scotch-Brite™ Finishing Flap Brush is constructed from sections of non-woven material slit lengthwise and bonded to a cylindrical core. Our long-lasting brush provides improved consistency and greater control over a number of critical prep and finishing tasks, to include polishing and aesthetic finishing, such as brushed finishes on copper, brass, stainless steel, aluminum, and other metals.
Scotch-Brite™ Finishing Flap Brush requires no chemical compounds to achieve fine finishes and is ideal for all aesthetic finishing applications, smoothing wood fibers, defuzzing wood, plastic, and composite surfaces, and sealer scuffing.
This brush is available with aluminum oxide abrasive mineral. Aluminum oxide is a popular choice among industrial professionals because of its cut-rate and long life. This mineral is a tough, durable abrasive that self-fractures to expose fresh cutting edges in use, whereas traditional abrasives, such as garnet, quickly wear down with use. Due to its high cut-rate, hardness, strength, and low heat retention, aluminum oxide mineral is widely used in grinding applications in addition to sanding and finishing use. Aluminum oxide is suitable on a wide variety of substrates in both woodworking and metalworking, including ferrous alloys.
Our Scotch-Brite™ abrasives are unique surface conditioning products with abrasives incorporated into non-woven fiber matrix. Combining abrasives and non-woven material creates an abrasive system that delivers consistent results for the life of the product. The open-web material runs cool and is load resistant, which keeps the abrasive minerals cutting at high performance by limiting clogging of the fibers.