To provide a multi-core ferrule polishing material suitable for polishing a multi-core ferrule. A multi-core ferrule polishing material of the present invention addressing the above problem includes a binder formed from a resin material, and abrasive grains dispersed in the binder. The abrasive grains are contained in an amount of not less than 88.5% with respect to a sum of masses of the abrasive grains and the binder, include particles having a particle diameter of not greater than 100 nm, the particles being present in an amount of not less than 70% and less than 100% with respect to the mass of the abrasive grains, and are formed from silica.

A coated abrasive article includes a substrate and a plurality of abrasive particles overlying the substrate, and the plurality of abrasive particles including tapered abrasive particles having a taper fraction standard deviation of at least 0.025 and not greater than 0.090.

A coated abrasive article includes a substrate and a plurality of abrasive particles overlying the substrate, and the plurality of abrasive particles including tapered abrasive particles having a taper fraction standard deviation of at least 0.025 and not greater than 0.090.

The purpose of the present invention is to provide a grinding material which has a superior grinding rate and planarizing accuracy, with the grinding rate being less likely to be reduced over a relatively long period of time. The present invention is directed to a grinding material including a base, a grinding layer overlaid on a front face side of the base and including grinding grains and a binder for the grinding grains, and an adhesion layer overlaid on a back face side of the base, in which the grinding grains are diamond grinding grains, a wear quantity of the grinding layer as determined by a Taber abrasion test is no less than 0.03 g and no greater than 0.18 g, and, an Asker D hardness measured from a front face side of the grinding layer is no less than 80° and no greater than 98°.

The purpose of the present invention is to provide a grinding material which has a superior grinding rate and planarizing accuracy, with the grinding rate being less likely to be reduced over a relatively long period of time. The present invention is directed to a grinding material including a base, a grinding layer overlaid on a front face side of the base and including grinding grains and a binder for the grinding grains, and an adhesion layer overlaid on a back face side of the base, in which the grinding grains are diamond grinding grains, a wear quantity of the grinding layer as determined by a Taber abrasion test is no less than 0.03 g and no greater than 0.18 g, and, an Asker D hardness measured from a front face side of the grinding layer is no less than 80° and no greater than 98°.

The present disclosure relates generally to coated abrasive articles that include a tribological performance enhancing composition in a make coat, a size coat, a supersize coat, or combinations thereof, as well as methods of making coated abrasive articles. The present disclosure also relates to coated abrasive articles including a supersize coating comprising a sulfide scavenging composition and/or a crosslinked zinc acrylic binder, as well as methods for making and using such abrasive articles. The present disclosure also relates generally to abrasive articles that include aggregates having an anti-wear composition or grinding aid disposed on or within the aggregates.

A cleaning material, device, and method for predictably cleaning the contact elements and support hardware of a tester interface, such as a probe card and a test socket, in which the cleaning pad has a predetermined configuration appropriate for the particular pin contact elements and a substrate having a defined functionalized surface topology and geometry which can be introduced into the testing apparatus during the normal testing operations. The cleaning material has a predetermined topography with a plurality of functional 3-dimensional (3D) microstructures that provide performance characteristics which are not possible with a non-functionalized and flat surface.

There are provided spherical porous silica particles that do not disintegrate during production and exhibit high disintegration properties (easily disintegrating properties) during use, so as to be used in an abrasive to perform precise abrading, a scrub material of cosmetics, or the like. There have been achieved porous silica particles that have an average particle diameter of 0.5 to 50 μm, a pore volume of 0.5 to 5.0 cm.sup.3/g, a mode of a pore diameter of 2 to 50 nm, a shape factor of 0.8 to 1.0, an average compression strength of 0.1 to less than 1.0 kgf/mm.sup.2, and a sodium content of 10 ppm or less, and possess a network structure. Also, the porous silica particles were produced by a production method including: a dispersion preparation step of dispersing non-spherical silica particles in water to prepare a dispersion of non-spherical particles; a drying step of pouring, in a spray dryer, the dispersion having a viscosity of 8 to 100 mPa.Math.s maintained by shear force applied continuously or intermittently to the dispersion; and a calcination step of calcining the dried silica particles.

The present inventive subject matter provides an abrasive particle. The abrasive particle can include an elongated body that is defined between opposed first and second ends. Each end defines a substantially planar surface. An axis extends through the first and second ends, and each end has a respective first and second cross-sectional area. At least one of the first and second ends is oriented at an angle relative to the axis that is less than 90 degrees. The elongated body has a variable cross-sectional area centered along the axis. At least one cross-sectional area between the first and second ends represents a local minimum cross-sectional area.

A method for manufacturing a porous metal bonded grindstone with which it is possible to arbitrarily adjust a porosity from a low porosity to a high porosity is provided. This method is intended for manufacturing the porous metal bonded grindstone and comprises: a molding step (P1) for obtaining an unfired molded body including abrasive grains, metal powder, and a pore forming material; a solute removing step (P2) for bringing vapor of a solvent having solubility with respect to the pore forming material into contact with the unfired molded body to remove the pore forming material and to obtain an unfired molded body having pores; and a firing step (P3) for firing the unfired molded body having pores.