An additively manufactured intermediate part includes a body and at least one sacrificial electrode formed within or upon the body. The body includes a plurality of layers and at least one surface having a region to be smoothed in a near-finished state of the additively manufactured intermediate part. The at least one sacrificial electrode is adjacent to the body along the at least one surface, such that at least one of the plurality of layers is adjacent to the at least one sacrificial electrode in the region to be smoothed in the near-finished state of the additively manufactured intermediate part.

The embodiment relates to a hand-held cathode structure and an electrolytic polishing apparatus including the same. The hand-held cathode structure according to the embodiment has a cathode plate structure that is disposed adjacent to an electrolytic polishing target material for an electrolytic polishing, a cathode plate movable with respect to the electrolytic polishing target material, and an insulating fiber coating layer capable of absorbing the electrolyte disposed between the electrolytic polishing target material and the cathode plate.

The embodiment relates to a hand-held cathode structure and an electrolytic polishing apparatus including the same. The hand-held cathode structure according to the embodiment has a cathode plate structure that is disposed adjacent to an electrolytic polishing target material for an electrolytic polishing, a cathode plate movable with respect to the electrolytic polishing target material, and an insulating fiber coating layer capable of absorbing the electrolyte disposed between the electrolytic polishing target material and the cathode plate.

A technique of removing material from metal parts referred to as OPECM and a corresponding OPECM processing machine are disclosed. A tool electrode is manufactured for removing material from a target workpiece, and the workpiece and tool electrode are fixed into a processing machine that imparts an oscillatory motion path or profile and applies a voltage through a flowing electrolyte solution. The disclosed technique and processing machine removes material from the surface of the target workpiece through proximal surface dissolution as the workpiece and tool electrode are brought within proximity of one another.

A technique of removing material from metal parts referred to as OPECM and a corresponding OPECM processing machine are disclosed. A tool electrode is manufactured for removing material from a target workpiece, and the workpiece and tool electrode are fixed into a processing machine that imparts an oscillatory motion path or profile and applies a voltage through a flowing electrolyte solution. The disclosed technique and processing machine removes material from the surface of the target workpiece through proximal surface dissolution as the workpiece and tool electrode are brought within proximity of one another.

An apparatus capable of local polishing and suitable for performing a plasma-electrolytic polishing process on an object is provided. The apparatus capable of local polishing includes a fixing seat, a motion mechanism, and a jet module connected to the motion mechanism and including an electrolyte communication port, a gas communication port, a power connection area, and a jet flow outlet. The jet flow outlet faces the fixing seat and is communicated with the electrolyte communication port and the gas communication port to be suitable for performing the plasma-electrolytic polishing process on the object fixed on the fixing seat. A plasma-electrolytic polishing system including an apparatus capable of local polishing is also provided.

An apparatus capable of local polishing and suitable for performing a plasma-electrolytic polishing process on an object is provided. The apparatus capable of local polishing includes a fixing seat, a motion mechanism, and a jet module connected to the motion mechanism and including an electrolyte communication port, a gas communication port, a power connection area, and a jet flow outlet. The jet flow outlet faces the fixing seat and is communicated with the electrolyte communication port and the gas communication port to be suitable for performing the plasma-electrolytic polishing process on the object fixed on the fixing seat. A plasma-electrolytic polishing system including an apparatus capable of local polishing is also provided.

Endodontic instruments for use in performing root canal therapy on a tooth are disclosed. In one form, the instruments include an elongate shank having a cutting edge extending from a distal end of the shank along an axial length of the shank. The shank comprises a titanium alloy, and the shank is prepared by heat-treating the shank at a temperature above 25° C. in an atmosphere consisting essentially of a gas unreactive with the shank. In another form, the endodontic instruments have an elongate shank having a cutting edge extending from a distal end of the shank along an axial length of the shank. The shank consists essentially of a titanium alloy selected from alpha-titanium alloys, beta-titanium alloys, and alpha-beta-titanium alloys. The instruments solve the problems encountered when cleaning and enlarging a curved root canal.

Endodontic instruments for use in performing root canal therapy on a tooth are disclosed. In one form, the instruments include an elongate shank having a cutting edge extending from a distal end of the shank along an axial length of the shank. The shank comprises a titanium alloy, and the shank is prepared by heat-treating the shank at a temperature above 25° C. in an atmosphere consisting essentially of a gas unreactive with the shank. In another form, the endodontic instruments have an elongate shank having a cutting edge extending from a distal end of the shank along an axial length of the shank. The shank consists essentially of a titanium alloy selected from alpha-titanium alloys, beta-titanium alloys, and alpha-beta-titanium alloys. The instruments solve the problems encountered when cleaning and enlarging a curved root canal.

Provided is a method for manufacturing a solid oxide and a device therefor, capable of manufacturing a solid oxide used as an optical material without introducing damaged layers caused by machining, which does not use any polishing agent or abrasive grains including rare earth elements, or does not use any solution, such as hydrogen fluoride, for which handling is difficult and which imposes a heavy environmental burden. In the presence of water 1, a solid oxide in which one or more kinds of elements are bonded through oxygen is used as an object to be manufactured; a catalyst substance, which cuts a backbond between an oxygen element and another element, forming the solid oxide, by dissociation of a water molecule, and adsorbs it, and helps production of a decomposition product by hydrolysis, is used as a machining reference surface (3); the object (5) to be manufactured and the machining reference surface are disposed so that they are brought into contact with each other or they are brought very close to each other in the presence of water; a potential of the machining reference surface is adjusted to a range where neither H.sub.2 nor O.sub.2 is produced; and the object to be manufactured is moved relative to the machining reference surface thereby to remove a decomposition product from the surface of the object to be manufactured.