A mechanical pencil includes a clamping claw for playing a coordination role in lead output. An abutting member is arranged in front of the clamping claw. The rear end, corresponding to the clamping claw, of the abutting member is provided with an abutting portion. The abutting portion includes a first through hole allowing a lead to move through. The abutting portion can be inserted into the clamping claw in a case where the clamping claw moves forward and simultaneously drives the clamping claw to open outwardly. The mechanical pencil has a better lead output effect.

A mechanical pencil includes a clamping claw for playing a coordination role in lead output. An abutting member is arranged in front of the clamping claw. The rear end, corresponding to the clamping claw, of the abutting member is provided with an abutting portion. The abutting portion includes a first through hole allowing a lead to move through. The abutting portion can be inserted into the clamping claw in a case where the clamping claw moves forward and simultaneously drives the clamping claw to open outwardly. The mechanical pencil has a better lead output effect.

Cam faces 24a and 24b are continuously formed in a circle on upper and lower faces which are perpendicular to an axial direction of a rotatable cam 24 which constitutes a rotational drive mechanism 21. Elastic members 23b are formed integrally with a holder member 23 for rotatably supporting the rotatable cam 24 to extend in the axial direction, and the first fixed cam and second fixed cam 23c and 23d having a small number of cam faces at butts and tips of the elastic members are arranged to face each other via the upper and lower cam faces 24a and 24b of the rotatable cam 24. The rotatable cam 24 is retreated and moved forward in the axial direction by writing pressure applied to a writing lead to be rotationally driven in one direction and rotational motion of the rotatable cam 24 is transmitted to the writing lead.

Cam faces 24a and 24b are continuously formed in a circle on upper and lower faces which are perpendicular to an axial direction of a rotatable cam 24 which constitutes a rotational drive mechanism 21. Elastic members 23b are formed integrally with a holder member 23 for rotatably supporting the rotatable cam 24 to extend in the axial direction, and the first fixed cam and second fixed cam 23c and 23d having a small number of cam faces at butts and tips of the elastic members are arranged to face each other via the upper and lower cam faces 24a and 24b of the rotatable cam 24. The rotatable cam 24 is retreated and moved forward in the axial direction by writing pressure applied to a writing lead to be rotationally driven in one direction and rotational motion of the rotatable cam 24 is transmitted to the writing lead.

The present invention is a chuck body (13) provided with: a hollow, substantially cylindrical fastener (11) having a tapered inner surface (13) in which the diameter of the hole gradually changes along the axial direction; and a chuck (21) having a divided end part (23) divided into two or three, the divided end part (23) having a tapered outer surface (24) that can enter or exit from the fastener (11) and that comes into contact with the tapered inner surface (13) of the fastener (11) when entering the fastener (11). When the divided end part (23) of the chuck (21) closes in the fastener (11) and holds the core (10), the angle of the tapered outer surface (24) of the chuck (21) relative to the center axis line of the chuck (21) is substantially identical to the angle of the tapered inner surface (13) of the fastener (11).

The present invention is a chuck body (13) provided with: a hollow, substantially cylindrical fastener (11) having a tapered inner surface (13) in which the diameter of the hole gradually changes along the axial direction; and a chuck (21) having a divided end part (23) divided into two or three, the divided end part (23) having a tapered outer surface (24) that can enter or exit from the fastener (11) and that comes into contact with the tapered inner surface (13) of the fastener (11) when entering the fastener (11). When the divided end part (23) of the chuck (21) closes in the fastener (11) and holds the core (10), the angle of the tapered outer surface (24) of the chuck (21) relative to the center axis line of the chuck (21) is substantially identical to the angle of the tapered inner surface (13) of the fastener (11).

Provided is a writing instrument or an applicator using resin parts formed, by way of two-color molding, to have an optimal guiding clearance between slide members. A plurality of resin molded parts is included. At least one of the plurality of resin molded parts is formed as a primary molding, and at least another one of the resin molded parts is formed as a secondary molding, by way of two-color molding, using a portion of a surface of the primary molding. The primary molding and the secondary molding are separated to be used as independent members. In this case, the primary molding and the secondary molding are preferably configured to slide against each other by each separating portion.

Provided is a writing instrument or an applicator using resin parts formed, by way of two-color molding, to have an optimal guiding clearance between slide members. A plurality of resin molded parts is included. At least one of the plurality of resin molded parts is formed as a primary molding, and at least another one of the resin molded parts is formed as a secondary molding, by way of two-color molding, using a portion of a surface of the primary molding. The primary molding and the secondary molding are separated to be used as independent members. In this case, the primary molding and the secondary molding are preferably configured to slide against each other by each separating portion.

A mechanical pencil 1 has a first cam surface 140a, a second cam surface 140b, a first fixed cam surface 141a that cooperates with the first cam surface to cause a rotating element to rotate, and a second fixed cam surface that cooperates with the second cam surface to cause a rotating element to rotate. The first cam surface is provided with first cam teeth 140aa, the second cam surface is provided with second cam teeth 140ba, the first fixed cam surface is provided with first fixed cam teeth 141aa that cooperate with the first cam teeth, and the second fixed cam surface is provided with second fixed cam teeth 142aa that cooperate with the second cam teeth. The first cam teeth are configured such that in each first cam tooth, the relationship 0<Y<X is achieved, where, with respect to a perpendicular line drawn from the apex, X is the length of the base on the rear side with respect to the rotating direction of the rotating element 140, and Y is the length of the base on the front side with respect to the rotating direction of the rotating element.

A mechanical pencil 1 has a first cam surface 140a, a second cam surface 140b, a first fixed cam surface 141a that cooperates with the first cam surface to cause a rotating element to rotate, and a second fixed cam surface that cooperates with the second cam surface to cause a rotating element to rotate. The first cam surface is provided with first cam teeth 140aa, the second cam surface is provided with second cam teeth 140ba, the first fixed cam surface is provided with first fixed cam teeth 141aa that cooperate with the first cam teeth, and the second fixed cam surface is provided with second fixed cam teeth 142aa that cooperate with the second cam teeth. The first cam teeth are configured such that in each first cam tooth, the relationship 0<Y<X is achieved, where, with respect to a perpendicular line drawn from the apex, X is the length of the base on the rear side with respect to the rotating direction of the rotating element 140, and Y is the length of the base on the front side with respect to the rotating direction of the rotating element.