Saint-Gobain Surface Conditioning's natural diamond micron combines mechanical strength with high thermal stability. Crushed and processed from boart, natural diamond micron is typically free of cracks and inclusions and contains less metal impurities.
Available in sizes ranging from 0-1 micron to 40-60 micron, Saint-Gobain natural diamond micron is processed using state-of-the-art grading equipment to ensure well-controlled particle size distribution and surface cleanliness in your most demanding applications. It’s ideal for gemstone polishing and lapping.
Natural Blocky: 16 / 18 to 50 / 60
Natural Blocky: 60 / 70 to 325 / 400
Natural Blocky: 400 / 500 to 500 / 600
Natural EP: 20 / 30 to 50 / 60
Natural EP: 60 / 70 to 325 / 400
Natural Diamond: Micron 0 - 1 to 40 - 60
|Natural Blocky||12 thru
|Strong, uniform particles. Recommended for saw blades, rotary dressing tools, bonded wheels and electroplated products.|
|A lightly processed, well shaped diamond for strength and longer life. Recommended for rotary and form dressing tools, saw blades and impregnated bits. Also available in 10 SPC thru 200 SPC and in Christensen sizes.|
|Semi-blocky particles for use in free cutting tools and where good bond retention is required.|
|Fully processed and chemically polished for resistance to severe impact and high temperature. Recommended for petroleum bits, mining bits and form dressing tools. Also available in Christensen sizes.|
|DR-FP||10 SPC thru
|Fully processed and machine polished to resist wear, high impact and premature breakdown. Recommended for impregnated bits, mining bits and form dressing tools. Also available in US mesh sizes 14 thru 80 and in Christensen sizes.|
A: MICRON refers to abrasive particle sizes typically 40 µm (1 µm = 40 microinches) or less.
A: A very hard abrasive, usually natural or synthetic diamond and cubic boron nitride (CBN). Hardness is measured on the Knoop Scale in megapascals (1 Mpa = 145 lb / in2 ) and diamond is 7000 Mpa with CBN following at 5000. Conventional abrasives such as silicon carbide and aluminum oxide have much lower Knoop values of 2500 and 2200 respectively.
A: Size, shape, color, surface (extrinsic) chemistry, internal (intrinsic) chemistry, mechanical properties -- Ti and TTi (toughness index / impact strength and thermal toughness index), zeta potential (surface charge) and microstructure.
A: Most individual grains of a superabrasive powder batch are not the same size (or shape). The powder consists of a distribution of particles of different sizes represented as a frequency distribution curve.
A: Electroless nickel plating (EN) is an auto-catalytic chemical technique used to deposit a layer of nickel-phosphorus on a solid workpiece, such as metal or plastic. The process relies on the presence of a reducing agent, for example hydrated sodium hypophosphite (NaPO2H2·H2O) which reacts with the metal ions to deposit metal. Alloys with different percentages of phosphorus, ranging from 2 - 5 (low phosphorus) to up to 11 - 14 (high phosphorus) are possible. The metallurgical properties of alloys depend on the percentage of phosphorus.
A: Essentially the same process as electroless nickel, but copper is the coating element.
A: To improve the adhesion of the superabrasive in the bond matrix of the grinding wheel and to aid removal of heat from the grinding zone.
A: Ti and TTi stand for Toughness Index and Thermal Toughness Index. This is a measurement of the impact strength of the superabrasive and its ability to resist mechanical breakdown (friability).
The Ti test is performed on a superabrasive at room temperature. The TTi test is run at room temperature on a superabrasive previously raised to an elevated temperature and allowed to cool down – this mimics the performance of the superabrasive in a grinding wheel in “real world” conditions.
The Ti and TTi test is performed to ANSI (American National Standards Institute).
A: A measure of the ability of a superabrasive to be pulverized, crumbled or otherwise reduced to a powder. Ti and TTi testing are employed to measure friability in superabrasives.
A: Diamond is an allotrope of carbon, where the atoms are arranged in a variation of the face-centered cubic crystal structure called an atomic diamond lattice. It is this atomic structure which defines diamond's hardness. Diamond is well-known as a material with excellent physical qualities, most of which depend on strong covalent bonds between its atoms. Diamond has the highest hardness and thermal conductivity of any material and those properties make it the abrasive of choice in many industrial drilling, grinding, lapping and polishing applications.