A functional polymeric cutting edge structure and methods for manufacturing cutting edge structures using polymeric materials are provided. A razor blade for use in a razor cartridge or a blade box for assembly in a razor cartridge frame may be formed using the present invention.

The present disclosure provides a razor blade coating by a physical vapor deposition method through performing a deposition with a single composite target composed of dissimilar materials with their area ratio defined to be varied in the single composite target in the direction of transferring the razor blade subject to the deposition, thereby forming a single layer in which the composition ratio of the dissimilar materials gradually changes in the thickness direction of the coating layer to improve the durability of the razor blade coating layer.

A razor cartridge comprising a frame, wherein the frame comprises a leading longitudinal member and a trailing longitudinal member and at least one transverse frame member defining a cartridge plane, disposed in between, and joining, the leading longitudinal member and the trailing longitudinal member, in a transverse direction of the razor cartridge. The at least one transverse frame member comprises a plurality of cutting member guides defining a plurality of cutting member support slots, each cutting member support slot configured to accommodate a longitudinal cutting member, and a plurality of longitudinal cutting members, wherein each cutting member is disposed in a respective cutting member support slot.

A shaving head that doubles as breaking mechanism to break a safety razor blade into two pieces to form a 2-blade shaving razor. The shaving head includes a front component having a retention guide, a first position stop and a second position stop at a distance offset from the first position stop. The shaving head further includes a back component having a blade slot configured to receive a first blade portion and a second blade portion formed from breaking a double-edge safety razor blade such that the first blade portion has a different width compared to the second blade portion. The retention guide is configured to retain the first blade portion and the second blade portion in the blade slot responsive to the retention guide being at least partially inserted into the blade slot. The sharp shaving edges once installed form a shaving angle between 5 and 30 degrees, where the shaving angle is determined by where the blade is broken.

A method of assembling a razor cartridge. A housing is injection molded. An elastomer is co-injection molded to the housing forming a pair of laterally spaced apart blade stabilizers. A primary blade member having a cutting edge is mounted to the housing. The cutting edge of the primary blade member is contacted with the laterally spaced apart blade stabilizers. A blade retention member is mounted to a top surface of the housing. A pair of lateral ends of the cutting edge of the primary blade member is constrained between the blade retention member and the pair of laterally spaced apart blade stabilizers.

A razor apparatus including a head having at least one blade member on each of a first and a second opposed side of the head. Each blade member has a straight front cutting edge. The head includes a frame defining an opening through which the cutting edges are accessible. The frame also includes a rotatable mounting element for attachment of the head to a handle. The head is rotatable around a longitudinal axis of the handle at least 180° when the rotatable mounting element is activated.

A novel cutting-edge structure and method and apparatus for manufacturing the cutting-edge structure is provided. The cutting-edge structure is comprised of naturally derived or renewable material at greater than 50% by volume fraction. In one embodiment, the naturally derived material is a cellulose nanostructure such as a cellulose nanocrystal. The cellulose nanocrystal is processed using a base or mold structure to provide a cutting edge of any shape such as linear or circular edge structures. The process includes dual cure steps to produce an optimal cutting-edge structure without shrinkage. The formed cutting-edge structure can be utilized as a razor blade as it is formed with very sharp tip and edge suitable for cutting hair. The base structure can form one or more cutting-edge structures simultaneously.

The present disclosure provides an improvement to razor blade coating by a physical vapor deposition method, by forming a hard coating layer as a thin coating layer in which chromium boride, which is a nanocrystalline structure having high hardness, is dispersed in an amorphous mixture of chromium and boron, thereby improving the strength and hardness of the thin coating layer and securing the bonding force by chromium in the amorphous mixture between the hard coating layer and a blade substrate on which an edge of the razor blade is formed.

A functional polymeric cutting edge structure and methods for the manufacturing of cutting edge structures comprised of polymeric materials are provided. The cutting edge structures may be produced on a substrate having a blade body or blade support type. The polymeric material is produced by curing a precursor material activated by electromagnetic radiation wherein a wavelength of said radiation is about double a wavelength required to activate the precursor material. A razor blade for use in a razor cartridge or a blade box may be formed using the present invention.

A functional polymeric cutting edge structure and methods for the manufacturing of cutting edge structures comprised of polymeric materials are provided. The cutting edge structures may be produced on a substrate having a blade body or blade support type. The polymeric material is produced by curing a precursor material by electromagnetic radiation wherein a wavelength of said radiation is about double a wavelength required to cure the precursor material. A razor blade for use in a razor cartridge or a blade box may be formed using the present invention.