JP2013107263A - Mechanical pencil - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a mechanical pencil which can perform maintenance for the breakage of a writing lead in a slider, and achieves normalization even though the fitting degree of the slider is insufficient after the maintenance.SOLUTION: A stepped part 8a formed in the slider 8 is abutted with an inner wall surface 2a of a barrel tip member 2 between the first moving position to the second moving position of a knock rod 31 accompanying a knocking operation. Thus, the fitted state of the slider 8 to a relay pipe 7 can be normalized at this time even though the fitting degree of the slider to the relay pipe 7 is insufficient in reloading the slider. The tip end of a chuck moves to be projected from a ring-shaped fastening tool to the front side at the second moving position of the knock rod. Accordingly, the delivering operation of the writing lead is performed.

Description

  The present invention relates to a knock-type mechanical pencil, and more particularly, to a mechanical pencil in which maintenance is easily performed when the writing core is broken at a chuck portion that holds the writing core (replacement core).

The knock-type mechanical pencil includes a chuck that holds the writing core in the shaft cylinder. For example, by performing a knocking operation on a knock portion arranged at the rear end of the shaft cylinder, the chuck moves back and forth, By the action of a ring-shaped fastener or the like disposed outside the chuck, the writing core operates so as to be sequentially fed out from the front end portion of the shaft tube.
In the mechanical pencil equipped with such a chuck, the writing core may be broken immediately before the chuck in the shaft cylinder due to some factors, and the broken remaining core may adversely affect the inside of the mechanism by the knocking operation. Will occur.

  On the other hand, this type of mechanical pencil has a problem that the thickness of the drawn line changes because the writing core is unevenly reduced as the writing progresses, and the present applicant uses the writing pressure applied to the writing core. A mechanical pencil provided with a rotation drive mechanism that can gradually rotate the writing core in one direction has been previously proposed, and this is disclosed in Patent Documents 1 and 2, for example.

International Publication No. WO2007 / 142135 JP 2011-1116028 A

By the way, even if it is the above-mentioned conventional knock type mechanical pencil or the mechanical pencil provided with the rotation driving mechanism of the writing core mentioned in Patent Documents 1 and 2, the writing core is in front of the chuck although the frequency is low. The problem that breaks.
As described above, the broken remaining core adversely affects the inside of the mechanism by the knocking operation, so that maintenance for removing this is required.

In order to enable this maintenance, it is preferable that a part called a slider disposed immediately before the chuck can be removed, and an operation for remounting the part is necessary after the maintenance.
When remounting the slider, the slider can be attached to the shaft body by fitting, but the user does not perform a reliable fitting operation, but a mouthpiece member that covers the slider or a mouthpiece member made of resin. There are cases where an operation of screwing into the shaft cylinder is performed.
In this state, when an operation of drawing out the writing core by a knocking operation is performed, the core hits a part of the slider, and the problem of breaking the writing core again immediately before the chuck is repeated.

  The present invention has been made paying attention to the above-mentioned problems, and adopts a configuration in which a slider disposed immediately before the chuck is detachably fitted to the shaft main body, and after maintenance, to the shaft main body. It is an object of the present invention to provide a mechanical pencil that can normalize the fitted state of the slider by a knocking operation even if the degree of fitting of the slider is insufficient.

  In addition, the present invention can be suitably employed in a mechanical pencil equipped with a unitized rotational drive mechanism that can rotationally drive the writing core by writing pressure as disclosed in Patent Document 2, Similarly, an object of the present invention is to provide a mechanical pencil capable of normalizing the slider fitting state by a knocking operation.

  The mechanical pencil according to the present invention, which has been made to solve the above-described problems, includes a knock bar that moves forward in the axial direction by a knock operation, and a relay member that moves forward as the knock bar moves forward in the axial direction. And a slider that is detachably fitted to and attached to the front end portion of the relay member, and a tip member that covers the slider and is detachably attached to the front end portion of the shaft cylinder. As the relay member moves forward, the step formed on the slider is configured to come into contact with the inner wall surface of the tip member.

  In this case, in a preferred embodiment, at the first movement position in the axial direction of the knock bar by a knocking operation, it is movable in the axial direction in which the rear end part comes into contact with the first contact part formed on the knock bar. A rear end portion of the relay member is provided at a second abutting portion formed on the knock bar at a second movement position further forward than the first movement position of the knock bar in the axial direction by a knock operation. A chuck for gripping the writing core is disposed at the front end of the lead case, and a ring-shaped fastener covering the periphery of the chuck is disposed at the front end of the relay member. A part of the slider abuts a part of the tip member between the first movement position and the second movement position of the knock bar, and the tip of the chuck is moved at the second movement position of the knock bar. Part is configured so as to project forwardly from the ring-shaped fasteners.

  Further, it is desirable that an arrow mark directed forward of the slider is formed on a part of the slider that is detachably fitted to the front end portion of the relay member.

  Furthermore, the present invention can be suitably used for a mechanical pencil in which the relay member is constituted by a relay pipe and a rotary drive mechanism connected to the rear end of the relay pipe, and the inner peripheral surface of the front end of the relay pipe The ring-shaped fastener is disposed on the outer peripheral surface of the relay pipe, and the slider is detachably fitted to the outer peripheral surface of the relay pipe. The rotational drive mechanism is based on the writing pressure applied to the writing core. The forward / backward movement of the relay pipe is converted into a rotational motion, and the writing core is rotationally driven in one direction via the relay pipe.

According to the mechanical pencil according to the present invention described above, since the slider is removably fitted to the front end portion of the relay member, the remaining core is removed even when the writing core breaks immediately before the chuck. Maintenance work to be removed can be easily performed.
When the slider is remounted on the front end portion of the relay member, the relay member is moved forward in conjunction with the forward movement of the knock bar by the knock operation even when a reliable fitting operation is not performed. Therefore, the step part formed in the slider contacts the inner wall surface of the tip member, and the fitting state of the slider with respect to the relay member can be normalized.

  In addition, since the tip of the chuck moves forward from the ring-shaped fastener in conjunction with the further forward movement of the knock bar by the knocking operation, the writing core held by the chuck is normally fed out. Operation can be guaranteed.

It is the perspective view which showed the external appearance structure of the mechanical pencil concerning this invention. It is sectional drawing which showed the first half part of the mechanical pencil shown in FIG. It is sectional drawing which showed the latter half part similarly. It is sectional drawing explaining the internal motion based on knock operation later on. FIG. 5 is a cross-sectional view for explaining the internal movement based on the knock operation following FIG. 4. It is sectional drawing which expanded and showed each edge part before and behind in the state of FIG.5 (C). It is sectional drawing which expanded and showed each edge part before and behind in the state of FIG. 5 (D). It is the perspective view which expanded and showed the structure of the slider part in the state which removed the tip member.

  A mechanical pencil according to the present invention will be described based on an embodiment shown in the drawings. In the following drawings, the same parts are denoted by the same reference numerals. However, in some drawings, representative parts are denoted by reference numerals for convenience of the paper, and the detailed configuration is attached to the other drawings. In some cases, the reference numerals are quoted for explanation.

  First, FIGS. 1 to 3 illustrate the overall configuration of a mechanical pencil. A tip member 2 is screwed to a tip portion of a tip shaft 1 that constitutes a shaft tube. And is detachably attached. A cylindrical core case 3 is accommodated along the front shaft 1 and the axis of the rear shaft described later, and a short-axis core case joint 4 is attached to the tip of the core case 3. A brass chuck 5 is connected through a core case joint 4.

A writing hole (not shown) is formed in the chuck 5 along its axis, and the tip is divided into a plurality of pieces, and the divided tip is formed into a ring shape by brass. It is loosely fitted in the tool 6. Further, the ring-shaped fastener 6 is attached to the inner surface of the distal end portion of the relay pipe 7 disposed so as to cover the periphery of the chuck 5.
The rear end portion of the relay pipe 7 is connected to a rotation drive mechanism (described later) that rotates the writing core (replacement core) using the writing pressure.

A cylindrical slider 8 which is accommodated in the above-described tip member 2 and protrudes from the tip member 2 is fitted to the relay pipe 7 at the front end portion of the relay pipe 7 so as to be attached and detached. Further, a tip pipe 9 for guiding the writing core is attached to the front end portion of the slider 8 via a pipe holder 10.
Further, immediately after the pipe holder 10 on the inner peripheral surface of the slider 8, a rubber holding chuck 12 having a through hole formed in the shaft core portion is accommodated.

  With the above-described configuration, a linear core insertion hole reaching the tip pipe 9 through a through hole formed in the chuck 5 following the core case 3 and a through hole formed in the shaft core of the holding chuck 12 is provided. A writing core (not shown) is inserted into the linear core insertion hole. A coiled chuck spring 13 is disposed between the relay pipe 7 and the core case joint 4.

  That is, the front end portion of the chuck spring 13 abuts on an annular step formed on the inner peripheral surface of the relay pipe 7, and the rear end portion of the chuck spring 13 abuts on the front end surface of the core case joint 4. It is housed in the state. Therefore, due to the action of the chuck spring 13, the chuck 5 is urged in the direction in which the relay pipe 7 is retracted and the tip end is accommodated in the ring-shaped fastener 6, that is, in the direction in which the writing core is gripped. Has been.

A grip member 14 made of an elastic material such as rubber is mounted on the above-described front shaft 2 constituting the shaft cylinder so as to surround the front shaft 2. When the grip member 14 is mounted on the front shaft 2, a transparent ring 15 formed of a transparent resin material that functions as a decorative ring is mounted from the front end side of the front shaft 2.
The transparent ring 15 is positioned by an annular flange 1a formed integrally with the front shaft, and then the grip member 14 is mounted so as to surround the front shaft 2 from the same direction. Thereafter, the tip member 2 is screwed into the front end portion of the front shaft 1 so that the transparent ring 15 and the grip member 14 are attached to the front shaft 1 without coming out in the axial direction.

The transparent ring 15 functioning as the decorative ring described above is configured so as to cover the decorative seal 16 that is pasted so as to be wound around the front shaft 1 in advance so that the peripheral surface of the seal 16 can be visually recognized. Yes.
The decorative seal 16 is printed with a glossy color such as gold or silver, and a transparent portion that is not printed is formed at an appropriate position. And it is comprised so that a part of internal relay pipe 7 can be visually recognized through the said front axis | shaft 1 shape | molded by this transparent part and the transparent resin raw material.
Thereby, it is possible to confirm through the transparent ring 15 how the relay pipe 7 is rotationally driven by a rotational drive mechanism described later.

An inner surface of a front end portion of a rear shaft 18 constituting a shaft cylinder is fitted and attached to the rear end portion of the front shaft 1 described above, and the front half portion of the rear shaft 18 is shown in FIG. Thus, the unitized rotation drive mechanism 21 is accommodated.
As described above, the rear end portion of the relay pipe 7 is connected to the rotation drive mechanism 21, and the relay pipe 7 performs the retraction and forward movement (cushion movement) of the writing core based on the writing movement via the chuck 5. In response to this, it is transmitted to the rotational drive mechanism 21 and acts to transmit the rotational movement caused by the cushion operation by the rotational drive mechanism 21 to the chuck 5 via the relay pipe 7.
As a result, a writing core (not shown) gripped by the chuck 5 is subjected to a rotational motion by the rotational drive mechanism 21 in accordance with the writing operation.

The rotary drive mechanism 21 is urged rearward by a shaft spring 22 interposed between the front shaft 1 and the front shaft 1. The rear end portion of the rotary drive mechanism 21 is in contact with the step portion 18 a formed by the reduced diameter in the rear shaft 18 by the biasing force of the shaft spring 22.
That is, in this embodiment, the rotation drive mechanism 21 that is unitized is restricted from rotating by friction due to contact with the step portion 18a in the rear shaft 18, and the rotation drive mechanism generated by the cushion operation described above. It acts to transmit the rotational motion by 21 to the chuck 5 side.

  The rotary drive mechanism 21 includes a rotor 24 formed in a cylindrical shape, and the relay pipe 7 is fitted to the inner peripheral surface of the rotor 24 at the front end portion of the rotary drive mechanism 21. Are combined.

  The rotor 24 has a large-diameter portion with a slightly larger diameter near the front end, and a first cam surface 24a is formed on one end surface (rear end surface) of the large-diameter portion. A second cam surface 24b is formed on the other end surface (front end surface). On the other hand, a cylindrical upper cam forming member 25 is disposed so as to cover the rear end side of the rotor 24 so as to rotatably support the rotor 24, and the upper cam forming member 25. A cylindrical lower cam forming member 26 is fitted and attached to the upper cam forming member 25 on the outer periphery of the front end portion.

  A first fixed cam surface 25a is formed on the front end surface of the upper cam forming member 25 facing the first cam surface 24a of the rotor 24. Further, a second fixed cam surface 26a is formed on the inner surface of the front end portion of the lower cam forming member 26 facing the second cam surface 24b of the rotor 24.

A cylinder member 27 is fitted to the upper cam forming member 25 on the rear end side of the upper cam forming member 25. The cylinder member 27 is formed in a cylindrical shape and is movable in the axial direction. A torque canceller 28 is disposed, and a coiled cushion spring 29 is mounted between the front end portion of the inner peripheral surface of the torque canceller 28 and the rear end portion of the inner peripheral surface of the cylinder member 27.
The cushion spring 29 acts to urge the torque canceller 28 forward, and is pushed by the torque canceller 28 that has received this urging force so that the rotor 24 acts forward.

  As described above, the rotation drive mechanism 21 is separated from the core case 3 by the central portion of the rotation drive mechanism 21 passing through the core case 3, and the rotation drive mechanism 21 is indicated by the reference numerals 25 to 29 described above. It is unitized by members.

A knock bar 31 is slidably mounted in the axial direction on the rear half of the rear shaft 18, that is, on the rear side of the rotary drive mechanism 21. A front end portion of the knock bar 31 is formed as an annular wedge-shaped protrusion 31a, and the wedge-shaped protrusion 31a is mounted so as to ride over an annular protrusion 18b formed in the rear shaft 18.
A coiled knock bar spring 32 is disposed between the annular protrusion 18b and the knock bar 31, and the spring 32 urges the knock bar 31 toward the rear end of the rear shaft 18. It is configured.

  Further, an abutting portion 31b having a writing core replenishing hole 31c is formed slightly closer to the rear end than the center of the knock rod 31, and an eraser 33 is provided at the rear end of the knock rod 31. Is attached detachably, and a knock cover 34 covering the eraser 33 is detachably attached to the peripheral surface of the rear end portion of the knock bar 31.

  The contact portion 31b of the knock bar 31 and the rear end portion of the core case 3 are opposed to each other with a predetermined interval. According to this structure, even if the chuck 5 and the lead case 3 are slightly retracted by the cushioning operation described above, the rear end portion of the lead case 3 does not collide with the contact portion 31b of the knock bar 31. It is possible to prevent the rotation operation by the rotation drive mechanism 21 from being obstructed.

The knock cover 34 detachably attached to the knock bar 31 is integrally formed with a disk-shaped protrusion 34 a on the side wall surface of the knock cover 34. The disk surface of the disk-shaped projection 34a is circular and has a central portion that is slightly convex, and a resin fill seal 35 that is different from the knock cover 34 is mounted. A notch groove 18c is formed in the axial direction at a part of the rear end portion of the rear shaft 18, and the disc-shaped protrusion 34a is disposed along the notch groove 18c. Thus, the knock cover 34 can be knocked.
The disk-shaped protrusion 34a formed on the knock cover 34 functions as a decoration by the resin pile seal 35 and also functions as a mechanical pencil to prevent rolling.

  According to the rotary drive mechanism 21 in the mechanical pencil configured as described above, the rotor 24 is centered on the shaft core together with the chuck 5 via the relay pipe 7 in a state where the chuck 5 holds the writing core. It is made rotatable. When the mechanical pencil is in a state other than the writing state, the rotor 24 is biased forward via the torque canceller 28 by the action of the cushion spring 29 arranged in the rotation drive mechanism 21.

  On the other hand, when a mechanical pencil is used, that is, when a writing pressure is applied to the writing core protruding from the tip pipe 9, the chuck 5 moves backward against the urging force of the cushion spring 29. Thus, the rotor 24 is also slightly retracted in the axial direction. Therefore, the first cam surface 24a formed on the rotor 24 is brought into mesh with the first fixed cam surface 25a.

The first cam surface 24a is continuously serrated along the circumferential direction, and the first fixed cam surface 25a is also continuously serrated along the circumferential direction. Are formed to be identical to each other.
The opposed first cam surface 24a and fixed cam surface 25a are set so as to have a half-phase (half-pitch) offset in the axial direction with respect to one tooth of the cam, as described above. The first cam surface 24a is joined to the first fixed cam surface 25a so as to mesh with each other, so that the rotor 24 is driven to rotate corresponding to a half phase (half pitch) of one tooth of the first cam surface 24a. Receive.

On the other hand, the second cam surface 24b is also continuously serrated along the circumferential direction, and the second fixed cam surface 26a is also continuously serrated along the circumferential direction, The pitches are formed to be the same.
As described above, in the state where the first cam surface 24a is joined to the first fixed cam surface 25a so as to be engaged with each other, the second cam surface 24b and the second fixed cam surface 26a facing each other. Is set so as to have a half-phase (half-pitch) offset with respect to one tooth of the cam in the axial direction.

  Accordingly, when the writing of one stroke is completed and the writing pressure on the writing core is released, the rotor 24 advances slightly in the axial direction by the action of the cushion spring 29 described above, and the second formed on the rotor 24. The cam surface 24b meshes with the second fixed cam surface 26a. As a result, the rotor 24 again receives the rotational drive in the same direction corresponding to the half phase (half pitch) of one tooth of the second cam surface 24b.

As described above, according to the above-described mechanical pencil, the rotor 24 has one tooth (the first cam surface 24a and one second cam surface 24b) along with the reciprocating motion of the rotor 24 in the axial direction by receiving the writing pressure. The writing core gripped by the above-described relay pipe 7 and chuck 5 is also rotationally driven in one direction in the same manner.
Therefore, the tip of the writing core is always conical due to the rotational movement received by itself and the wear caused by writing. Therefore, it is possible to prevent the writing core from being unevenly worn as the writing progresses, and writing with a stable line width is possible.

  In the rotary drive mechanism 21 described above, a torque canceller 28 is interposed between the rotor 24 and the cushion spring 29. The torque canceller 28 acts to prevent the rotational motion of the rotor 26 from being transmitted to the cushion spring 29 side by generating a slip between the rear end portion of the rotor 24. As a result, the problem that the rotating operation of the rotor 24 is obstructed by the twisted return (spring torque) of the spring 29 can be solved.

  Further, in the mechanical pencil having this configuration, when the knock cover 34 is knocked, the knock bar contact portion 31b pushes the lead case 3 forward, and a part of the slider 8 attached to the relay pipe 7 has a lip. Advancing in the member 2 is prevented. For this reason, the front-end | tip part of the chuck | zipper 5 protrudes relatively from the fastener 6, and the holding state of the writing core by the chuck | zipper 5 is cancelled | released. When the knocking operation is released, the lead case 3 and the chuck 5 are retracted in the shaft cylinder by the action of the chuck spring 13.

  At this time, the writing core is held by friction in a through hole formed in the holding chuck 12, and in this state, the chuck 5 is retracted and its tip is accommodated in the fastener 6. The core is again held. That is, the chuck 5 is moved back and forth by repeating the knocking operation of the knock cover 34, whereby the writing core is released and gripped, and the writing core acts so as to be sequentially advanced forward from the chuck 5.

  By the way, in the mechanical pencil having the above-described structure, as described at the beginning, there is a problem that the writing core breaks immediately before the chuck 5, and maintenance for removing the remaining core due to the breaking is required. In order to enable this maintenance, in this embodiment, as described above, the slider 8 arranged immediately before the chuck 5 is attached to the relay pipe 7 so as to be detachably fitted.

Therefore, when performing maintenance to remove the remaining core due to breakage, first the tip member 2 screwed to the tip shaft 1 is removed, and then the slider 8 fitted to the tip of the relay pipe 7 is removed. Thus, the remaining core in the slider 8 can be easily removed.
After this maintenance operation, the slider 8 is fitted to the tip of the relay pipe 7 and reattached, and then the tip member 2 is screwed to the front shaft 1.

  In this case, depending on the user, when the slider 8 is fitted to the tip of the relay pipe 7, there is a case where an operation of screwing the tip member 2 covering the slider 8 into the front shaft 1 is performed without performing a reliable fitting operation. is there. For this reason, as described above, when the writing core is drawn out by the knocking operation, the core hits a part of the slider 8 and the problem of breaking the writing core again immediately before the chuck is repeated.

  Therefore, in this embodiment, even if the degree of fitting of the slider 8 to the relay pipe 7 is insufficient, it is configured so that the slider fitting state can be normalized by the first knocking operation. Yes. The normalization operation in the fitted state and the subsequent writing-out operation of the writing core will be described with reference to FIGS.

4 (A), 4 (B) and 5 (C), 5 (D) explain a series of operations by one knock operation of the knock cover 34 step by step, and FIG. 4 (A) shows the knock. The state where the knock operation of the cover 34 is not performed, that is, the state shown in FIGS. 2 and 3 is shown.
FIG. 4B shows an initial state in which the knocking operation of the knock cover 34 has been performed, that is, a state in which the knock bar 31 has reached the first movement position in the axial direction. The abutting portion 31b as the formed first abutting portion abuts on the rear end portion of the core case 3 movable in the axial direction.

FIG. 5C shows a state in which the knocking operation has progressed and the knock bar 31 has pushed the lead case 3 slightly forward. In this state, the spring of the shaft spring 22 is compared with the chuck spring 13 described above. Since the constant (K = P / δ) is small, the shaft spring 22 is slightly reduced and the unitized rotation drive mechanism 21 is slightly advanced.
In this state, as shown in an enlarged view of the front and rear ends of the mechanical pencil in FIG. 6, the slider 8 has a stepped portion 8 a formed by a different outer diameter. It contacts the wall surface 2a.

Therefore, as described above, when the degree of fitting of the slider 8 to the relay pipe 7 is insufficient, the fitting state of the slider 8 to the relay pipe 7 can be normalized at this point.
That is, normalization of the fitting state of the slider 8 to the relay pipe 7 is changed from the first movement position of the knock bar 31 (FIG. 4B) to the second movement position described next (FIG. 5D). Will be executed during the movement of.

  Next, FIG. 5 (D) shows a state in which the knocking operation has further advanced and the knock bar 31 has reached the second movement position in the axial direction. In this state, the second contact formed on the knock bar 31 is shown. The front end of the wedge-shaped protrusion 31a as a part abuts on the rear end of the unitized rotation drive mechanism 21 as a relay member, that is, the rear end of the cylinder member 27.

In this state, as shown in FIG. 7, the abutting portion 31b as the first abutting portion formed on the knock bar 31 pushes the rear end portion of the core case 3 further forward. At this time, since the slider 8 and the relay pipe 7 as the relay member do not move forward, the chuck 5 projects forward from the inside of the fastener 6 and at the same time, the chuck spring 13 is compressed.
Thereby, the writing core held by the chuck 5 is fed forward by the protruding operation of the chuck 5.

In this embodiment, as shown in FIG. 6, a tip pipe 9 for guiding the writing core is attached to the front end portion of the slider 8 via a pipe holder 10. An annular protrusion 8 b concentric with the core insertion hole formed in the tip pipe 9 is formed on the inner surface of the slider 8 immediately after the tip pipe 9.
That is, in the conventional mechanical pencil of this type, the projecting portion 8b is not provided, and the effect described below can be enjoyed by providing the annular projecting portion 8b.

This is because, when the writing core breaks immediately before the chuck 5 and exists as a remaining core in the space 8s in the slider 8, the remaining core is relayed by the forward movement of the chuck 5 by the knocking operation, and the tip pipe 9 In some cases, the pipe holder 10 may be pushed out, and sometimes the tip pipe 9 is pulled out forward and writing becomes impossible.
In order to avoid such a problem, it is very effective to form the annular protrusion 8b in the slider 8 as described above. Due to the presence of the annular protrusion 8b, the remaining core in the space portion 8s is formed. The problem of relaying and extruding the tip pipe 9 to make writing impossible can be solved.

Next, FIG. 8 is an enlarged view of a portion of the slider 8 with the tip member 2 removed, and the fitting portion of the slider 8 at the rear end portion of the slider 8 with the relay pipe 7 is provided with the slider 8. A forward arrow mark 8c is formed so as to be cut from the rear end of the slider.
This arrow mark 8c actively informs the user that the slider 8 can be pulled forward, whereby the user removes the slider 8 from the relay pipe 7 and leaves the remaining in the slider. The above-described maintenance for eliminating the lead can be performed.

  Further, the arrow mark 8c is formed so as to be cut at the cylindrical rear end portion of the slider 8, whereby elasticity can be given to a fitting portion of the slider 8 to the relay pipe 7, and the relay mark 8c is relayed. It acts so that the fitting operation to the pipe 7 can be performed smoothly.

The embodiment described above is based on a mechanical pencil provided with a rotation drive mechanism 21 that can rotationally drive a writing core in accordance with a writing operation. However, the present invention is a mechanical pencil that does not include the rotation drive mechanism 21. Can also be applied.
In this case, instead of the relay pipe 7 and the rotation drive mechanism 21 described above, for example, a single pipe-shaped relay member is used as the second contact portion formed on the knock bar 31 during the knocking operation. The front end of the wedge-shaped protrusion 31a is configured to abut on the rear end of the relay member.

1 Lead shaft (shaft tube)
2 Portion member 2a Inner wall surface 3 Core case 4 Core case joint 5 Chuck 6 Fastener 7 Relay pipe 8 Slider 8a Step 8b Annular projection 8c Arrow mark 8s Space 9 Tip pipe 10 Pipe holder 12 Holding chuck 13 Chuck spring 14 Grip member 17 Relay pipe 18 Rear shaft (shaft tube)
DESCRIPTION OF SYMBOLS 21 Rotation drive mechanism 22 Shaft spring 24 Rotor 25 Upper cam formation member 26 Lower cam formation member 27 Cylinder member 28 Torque canceller 29 Cushion spring 31 Knock stick 31a Wedge-shaped protrusion part (2nd contact part)
31b Contact portion (first contact portion)
32 Knock bar spring 34 Knock cover 35 Resin pile seal

Claims (4)

A knock bar that moves forward in the axial direction by a knock operation, a relay member that moves forward as the knock bar moves forward in the axial direction, and a front end portion of the relay member that is detachably fitted. An attached slider, and a lip member that covers the slider and is detachably attached to the front end of the shaft cylinder,
The mechanical pencil is configured such that a step formed on the slider comes into contact with an inner wall surface of the tip member as the relay member moves forward by the knocking operation. A core case that is movable in the axial direction in which a rear end abuts against a first abutting portion formed on the knock bar at a first movement position of the knock rod in the axial direction by the knock operation is provided, and The rear end of the relay member is in contact with a second contact portion formed on the knock bar at a second movement position further forward than the first movement position in the axial direction of the knock bar.
A chuck for gripping the writing core is disposed at the front end portion of the core case, and a ring-shaped fastener covering the periphery of the chuck is disposed at the front end portion of the relay member,
Between the first movement position and the second movement position of the knock bar, a part of the slider abuts on a part of the tip member, and at the second movement position of the knock bar, the tip of the chuck The mechanical pencil according to claim 1, wherein the mechanical pencil is operated so as to protrude forward from the ring-shaped fastener.   The arrow mark toward the front of the slider is formed on a part of the slider that is detachably fitted to and attached to the front end portion of the relay member. 2. The mechanical pencil described in 2. The relay member includes a relay pipe and a rotation drive mechanism connected to a rear end portion of the relay pipe. The ring-shaped fastener is disposed on an inner peripheral surface of the front end portion of the relay pipe, and the relay The slider is configured to be detachably fitted to the outer peripheral surface of the front end of the pipe,
The rotational drive mechanism is configured to convert the forward and backward movement of the relay pipe due to the writing pressure applied to the writing core into a rotational motion, and to rotationally drive the writing core in one direction via the relay pipe. The mechanical pencil according to claim 2 or 3, wherein the mechanical pencil is characterized.

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