A cutting blade mounting method of sandwiching both side surfaces of an annular cutting blade by a first flange and a second flange, the first flange being mounted on an end of a spindle and having a suction hole sucking and holding a side surface of the cutting blade to a sandwiching surface of the first flange, includes: a cutting blade provisional holding step of sucking and holding the cutting blade to the first flange by making the cutting blade abut against the sandwiching surface of the first flange at a perfect circle position at which a center of the cutting blade coincides with an axis of the spindle, and making a suction force act on the suction hole; and a fixing step of fixing the cutting blade maintaining the perfect circle position in the cutting blade provisional holding step to the first flange by the second flange.

A cutting apparatus includes a cutting unit configured to cut a workpiece held on a chuck table, and a groove detecting unit including a CCD imaging element photographing the workpiece held on the chuck table. The groove detecting unit photographs, by the CCD imaging element, a laser-processed groove and a cut groove illuminated by an oblique illumination set such that a light amount of light in a direction parallel with an extending direction of the laser-processed groove as viewed in plan is higher than a light amount of light in a direction orthogonal to the extending direction of the laser-processed groove.

A gemstone including a scannable indicia, and a uniquely identifiable pattern positioned on a surface of the gemstone.

A spool of saw wire is disclosed. The saw wire is wound on the core of the spool (718). The saw wire is made of steel wire (406) wherein two or more crimp deformations are implemented. Each of said two or more crimp deformations has a crimp direction that is perpendicular to the longitudinal axis. Each of the crimp directions is different from the other crimp directions. The saw wire on the spool comprises a number of elastic rotations per unit length applied in the elastic rotation direction. The spool with saw wire can give excellent processability in the sawing process.

To satisfactorily apply a protective tape to a bump wafer, an application apparatus (1) for applying a protective tape (PT) to a wafer (W) includes: an application table (60) configured to support the wafer (W); a tape holding body (30) capable of holding the protective tape (PT) and configured to supply the protective tape (PT) held by the tape holding body (30) onto the wafer (W); and a pressing member (62) configured to press the protective tape (PT) from above. The pressing member (62) includes a protective layer outer periphery retainer (620) configured to press a peripheral portion of a protective layer (PL), which is laminated on the protective tape (PT) and has an outer diameter smaller than an outer diameter of the wafer (W), to apply the protective tape (PT) to the wafer (W).

A spool of saw wire is disclosed. The saw wire is wound on the core of the spool (718). The saw wire is made of steel wire (406) wherein two or more crimp deformations are implemented. Each of said two or more crimp deformations has a crimp direction that is perpendicular to the longitudinal axis. Each of the crimp directions is different from the other crimp directions. The saw wire on the spool comprises a number of elastic rotations per unit length applied in the elastic rotation direction. The spool with saw wire can give excellent processability in the sawing process.

A method for fabricating MAS NMR rotors and drive caps made of diamond to increase the maximum achievable spinning frequency and enhance MAS NMR sensitivity and resolution. Diamond is an excellent choice for making MAS NMR rotors due to its high tensile and flexural strength, however, micromachining diamond is difficult due to its hardness. Although laser cutting is often employed to cut diamond sheets, this process cannot be used to create the high aspect ratio and small features required for MAS NMR rotors. In the present invention, a laser micromachining process is used to create the desired high aspect ratio while maintaining the small lateral features. In this process, the laser is used to first convert the diamond into graphite followed by a conversion to carbon dioxide in the presence of oxygen. To create a rotor, a rectangular log has a center hole drilled by the laser, and is then micromachined into a hollow cylinder.

A method for obtaining a diameter is provided. The method is to be applied to a multi-roller module system and includes: designating a target linear velocity associated with a wire moving in the multi-roller module system, and a value of a presumed diameter parameter associated with a diameter of a main roller; calculating an initial rotational speed of the main roller; measuring a current rotational speed of the fixed-diameter rotating component; calculating an actual linear velocity of the wire; and determining that the value of the presumed diameter parameter equals an actual diameter of the main roller when it is determined that the ratio of the target linear velocity to the actual linear velocity is equal to one.

A cutting apparatus includes a cutting unit configured to cut a workpiece held on a chuck table, and a groove detecting unit including a CCD imaging element photographing the workpiece held on the chuck table. The groove detecting unit photographs, by the CCD imaging element, a laser-processed groove and a cut groove illuminated by an oblique illumination set such that a light amount of light in a direction parallel with an extending direction of the laser-processed groove as viewed in plan is higher than a light amount of light in a direction orthogonal to the extending direction of the laser-processed groove.

A cutting blade mounting method of sandwiching both side surfaces of an annular cutting blade by a first flange and a second flange, the first flange being mounted on an end of a spindle and having a suction hole sucking and holding a side surface of the cutting blade to a sandwiching surface of the first flange, includes: a cutting blade provisional holding step of sucking and holding the cutting blade to the first flange by making the cutting blade abut against the sandwiching surface of the first flange at a perfect circle position at which a center of the cutting blade coincides with an axis of the spindle, and making a suction force act on the suction hole; and a fixing step of fixing the cutting blade maintaining the perfect circle position in the cutting blade provisional holding step to the first flange by the second flange.