JP6968695B2 - Writing implements - Google Patents

Description

The present invention relates to a writing instrument.

Conventionally, the shaft cylinder, the core feeding unit including a chuck that is supported by the shaft cylinder and holds the writing core forward so that it can be fed forward, and the shaft cylinder or the front end of the base (the end on the paper surface side) are supported by the writing core. A writing instrument (for example, a mechanical pencil) is known that includes a guide pipe that surrounds a front end region, and the guide pipe sneaks into the inside of a barrel or a base in synchronization with the wear of the writing core (for example, Patent Document 1). ). In such a writing instrument, when the guide pipe is pressed against the paper surface during writing, the guide pipe is pressed to the rear of the shaft cylinder by the reaction force from the paper surface, so that the guide pipe is partially inside the shaft cylinder or the mouthpiece. It is stored in.

In such a writing instrument, for example, the guide pipe is exposed from the front end of the barrel as follows. That is, the guide pipe is arranged immediately in front of the chuck, and is pressed forward by the chuck when the chuck advances with respect to the barrel when the writing core is extended and operated. As a result, the guide pipe is exposed to the outside from the front end of the barrel.

In this case, the length at which the guide pipe is exposed to the outside from the front end of the barrel depends on the length at which the chuck advances during the feeding operation of the writing core. Normally, the length that the chuck advances is about several mm, so that the length that the guide pipe can slip into the inside of the barrel or the base in synchronization with the wear of the writing core is relatively short. Therefore, the user of such a writing instrument needs to frequently perform the writing operation (knocking operation). Therefore, if the guide pipe can be exposed from the front end of the barrel longer than before, the frequency of the writing core feeding operation can be reduced, which is convenient.

Jikkenhei 7-40186 Gazette

The present invention has been devised in view of the above problems. That is, an object of the present invention is to provide a writing tool capable of exposing the guide pipe surrounding the front end of the writing core from the front end of the barrel longer than before.

The present invention includes a shaft tube and
A core feeding unit that holds the writing core forward so that it can be fed forward,
It is provided with a guide pipe provided at the front end of the shaft cylinder so as to be relatively movable in the axial direction of the shaft cylinder with respect to the shaft cylinder and the core feeding unit, and is located on the writing core.
The core feeding unit is
A chuck support unit supported by the shaft cylinder so as to be relatively movable in the axial direction with respect to the shaft cylinder.
It has a chuck unit that is supported by the chuck support unit so as to be relatively movable in the axial direction with respect to the chuck support unit, and holds the writing core so as to be sent forward.
The guide pipe moves forward relative to the shaft cylinder as the core feeding unit moves forward relative to the shaft cylinder.
A writing tool that limits the relative movement of the chuck unit in the axial direction with respect to the chuck support unit when the chuck support unit is relatively moving backward with respect to the barrel.

The chuck support unit is supported by the chuck support unit main body that supports the chuck unit and the chuck support unit main body, and has a first phase and a second phase with respect to the chuck support unit main body around the axis of the barrel. With a rotating body that can rotate between,
The chuck unit rotates the rotating body from the second phase to the first phase when moving forward relative to the chuck support unit.
The chuck unit may be restricted from moving relative to the chuck support unit in the axial direction when the rotating body is in the first phase.

In the above writing instrument, when the writing core is pressed backward with respect to the shaft cylinder, the chuck unit may move rearward with respect to the shaft cylinder.

The rotating body supports the chuck support unit main body so as to be relatively movable in the axial direction.
Further, a urging means for urging the chuck unit or the chuck support unit main body forward with respect to the rotating body or the shaft cylinder may be provided.

The chuck unit is urged backward by the first urging force with respect to the chuck support unit.
The chuck support unit may be urged rearward with respect to the shaft cylinder by a second urging force larger than the first urging force.

Even with such a writing instrument, when the writing core is pressed backward with respect to the shaft cylinder, the chuck unit may move rearward with respect to the shaft cylinder.

The chuck support unit has a chuck support unit main body that supports the chuck unit, and a support that is supported by the chuck support unit main body and can move relative to the chuck support unit main body in the axial direction.
The chuck unit is urged forward with respect to the barrel or the support.
The support may be urged rearward with respect to the barrel.

Further, in a writing tool of a type in which the chuck unit moves rearward with respect to the shaft cylinder, when the chuck unit moves relative to the shaft cylinder in the axial direction, the chuck unit with respect to the shaft cylinder Further, a damping means for applying a damping force according to the relative speed to the chuck unit may be provided.

The maximum static friction force acting between the guide pipe and the shaft cylinder may be larger than the maximum static friction force acting between the guide pipe and the writing core.

Alternatively, the present invention includes a shaft tube and
A chuck support unit supported by the shaft cylinder so as to be relatively movable in the axial direction of the shaft cylinder,
A chuck unit that is supported by the chuck support unit so as to be relatively movable in the axial direction with respect to the chuck support unit and holds the writing core so as to be sent forward.
The shaft cylinder, the chuck support unit, and a guide pipe provided at the front end of the shaft cylinder so as to be relatively movable in the axial direction with respect to the chuck unit and located on the writing core are provided.
When the chuck unit is moved forward relative to the barrel,
First, the chuck unit moves forward relative to the chuck support unit, and then
Next, it is a writing tool in which the chuck unit, the chuck support unit, and the guide pipe move forward relative to the barrel.

According to the present invention, it is possible to provide a writing tool capable of exposing a guide pipe surrounding the front end of a cursive from the front end of a barrel longer than before.

It is a schematic vertical sectional view which shows the writing instrument by one Embodiment of this invention. It is a schematic cross-sectional perspective view which shows the rotating body of the writing instrument of FIG. It is a schematic perspective view which shows the rotation operation part of the writing instrument of FIG. It is an IV-IV line cross section of the shaft cylinder of the writing instrument of FIG. It is a schematic plan view which shows the rotation stop member of the writing instrument of FIG. It is a figure for demonstrating the operation of the writing instrument of FIG. 1, and is a schematic vertical sectional view of the front area of a writing instrument in a state where a guide pipe is embedded in a barrel, and the relative positional relationship of a rotating body and a rotation operation part at this time. And. It is a figure for demonstrating the operation of the writing instrument of FIG. 1, and is a schematic vertical sectional view of the front area of the writing instrument in a state where the writing core is extended, and the relative position of a rotating body and a rotation operation part at this time. It shows the relationship and. It is a figure for demonstrating the operation of the writing instrument of FIG. 1, and is a schematic vertical sectional view of the front area of the writing instrument in a state where the chuck unit is moving forward relative to the chuck support unit, and the rotating body and rotation at this time. The relative positional relationship of the operation unit is shown. It is a figure for demonstrating the operation of the writing instrument of FIG. The relative positional relationship of is shown. It is a figure for demonstrating the operation of the writing instrument of FIG. The relative positional relationship of is shown. It is a schematic vertical sectional view which shows the writing tool by another Example of this invention. It is a schematic vertical sectional view which shows the writing tool by still another Example of this invention. It is a schematic vertical sectional view which shows the writing tool by still another Example of this invention.

Hereinafter, an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 is a schematic vertical sectional view showing a writing tool 100 according to an embodiment of the present invention. Here, a mechanical pencil is exemplified as the writing instrument 100. 2 is a schematic cross-sectional perspective view showing the rotating body 42 of the writing tool 100 of FIG. 1, and FIG. 3 is a schematic perspective view showing the rotation operation unit 41 of the writing tool 100 of FIG. 4 is an IV-IV cross section of the shaft cylinder 10 of the writing tool 100 of FIG. 1, and FIG. 5 is a schematic plan view showing a rotation stop member 60 of the writing tool 100 of FIG.

As shown in FIG. 1, the writing instrument 100 includes a shaft cylinder 10, a core feeding unit 20 supported by the shaft cylinder 10 and holding the writing core 21 forward (left in FIG. 1) so as to be able to be fed forward, and a shaft cylinder 10. A guide pipe 30 provided at the front end 11 of the writing core 21 and located on the writing core 21 is provided. The core feeding unit 20 is supported by the shaft cylinder 10 so as to be relatively movable in the axial direction da of the shaft cylinder 10. Further, the guide pipe 30 is supported so as to be relatively movable with respect to the shaft cylinder 10 and the core feeding unit 20 in the axial direction da of the shaft cylinder 10.

The core feeding unit 20 of the present embodiment is movable relative to the axle cylinder 10 in the axial direction da, and the chuck support unit 27 supported by the axle cylinder 10 is movable relative to the chuck support unit 27 in the axial direction da. It has a chuck unit 28 which is supported by the chuck support unit 27 and holds the writing core 21 so as to be sent forward. The guide pipe 30 is adapted to move forward relative to the axle cylinder 10 as the core feeding unit 20 moves forward relative to the axle cylinder 10.

As shown in FIG. 1, the chuck support unit 27 is supported by a chuck support unit main body 29 that supports the chuck unit 28 and the chuck support unit main body 29, and the axis L of the shaft cylinder 10 is supported with respect to the chuck support unit main body 29. It has a rotating body 42 that can rotate between the first phase and the second phase. The first phase and the second phase will be described later. The chuck support unit main body 29 of the present embodiment is supported by the outer cylinder 29p and the front end region of the outer cylinder 29p, and the tightening ring 25 for tightening the chuck 24 described later and the chuck unit 28 are attached to the rear of the outer cylinder 29p. It has a return spring 26 and a force.

Further, the writing tool 100 has an urging means 44 for urging the chuck support unit 27 rearward with respect to the shaft cylinder 10. The urging means 44 of the present embodiment is a coil spring, and is arranged as follows. That is, the outer cylinder 29p of the chuck support unit 27 has a flange portion 27f on the outer surface. Further, the shaft cylinder 10 has an inner flange 10p in front of the flange portion 27f. The urging means 44 is arranged between the flange portion 27f and the inner flange 10p. The chuck support unit 27 of the present embodiment is restricted from moving backward with respect to the shaft cylinder 10 by the small diameter portion 10s provided on the inner surface of the shaft cylinder 10. In this state, the flange portion 27f and the inner flange 10p are provided with each other in a positional relationship in which the separation distance in the axial direction da is smaller than the natural length of the urging means 44. Therefore, the urging means 44 is arranged in a compressed state between the flange portion 27f and the inner flange 10p. The urging means may urge the chuck unit 28 or the chuck support unit main body 29 forward with respect to the rotating body 42.

The outer cylinder 29p has a reduced diameter portion 27p on the front inner peripheral surface. The chuck 24 is arranged so as to penetrate the opening defined by the reduced diameter portion 27p in the axial direction da, and is movable relative to the outer cylinder 29p in the axial direction da. Further, the return spring 26 is arranged in a compressed state between the reduced diameter portion 27p of the outer cylinder 29p and the front end of the rotation operation portion 41. With such a configuration, the return spring 26 urges the chuck unit 28 rearward with respect to the outer cylinder 29p. When the chuck unit 28 is not moved forward relative to the chuck support unit 27, the chuck 24 holds the writing core 21 so that the front end region is tightened by the tightening ring 25 and the writing core 21 is not retracted.

As shown in FIG. 1, the chuck unit 28 has a chuck 24 for holding the writing core 21, and a core pipe 23 connected to the rear end of the chuck 24 and accommodating the writing core 21. The chuck 24 is made of, for example, brass, and the core pipe 23 is made of, for example, polypropylene. Further, the chuck unit 28 rotates the rotating body 42 from the second phase to the first phase when the chuck unit 28 moves forward relative to the chuck support unit 27 in the rear region of the chuck 24 (FIG. 3). See). In the present embodiment, as shown in FIGS. 1 and 3, the chuck 24 and the rotation operation unit 41 are configured as separate members, but the present embodiment is not limited to such a form. For example, in another example, the rotation operation unit 41 may be integrally provided on the chuck 24 and / or the core pipe 23.

Further, as shown in FIGS. 1 and 4, the shaft cylinder 10 is formed with a groove 13 extending in the axial direction da on the inner surface of the portion surrounding the rotating body 42. Four grooves 13 of the present embodiment are provided at equal intervals along the circumferential direction ds of the shaft cylinder 10. The groove 13 is for allowing the rotating body 42 to move forward relative to the axle cylinder 10 only when the rotating body 42 is in a specific phase (first phase). Further, as shown in FIG. 4, in the portion of the shaft cylinder 10 in which the groove 13 is formed, the inner diameter d1 in the rear region is larger than the inner diameter d2 in the front region.

In the writing tool 100 according to the present embodiment, when the chuck support unit 27 is relatively moving backward with respect to the shaft cylinder 10, the relative movement of the chuck unit 28 in the axial direction da with respect to the chuck support unit 27 is restricted. It has become. Such a limitation is realized in cooperation with the rotating body 42, the rotating operation unit 41, and the shaft cylinder 10. Hereinafter, a specific configuration of these components will be described.

The rotating body 42 has a substantially tubular shape. However, FIG. 2 shows only the inner portion of the rotating body 42 as a vertical cross-sectional view. As shown in FIG. 2, the rotating body 42 has a guided portion 42g configured as a convex portion on the outer surface. The guided portion 42g is provided in a total of four, two in the back portion shown in FIG. 2 and two in the front portion not shown in FIG. 2. In another embodiment, the guided portion 42g may be provided with three or less, or five or more. The four guided portions 42g have the same shape as each other, and have dimensions that can be accommodated in the groove 13 provided in the barrel 10. These four guided portions 42g are arranged at equal intervals in the circumferential direction ds of the rotating body 42. The outer diameter of the rotating body 42 becomes maximum in the phase in which the guided portion 42g is provided. This maximum outer diameter is larger than d2 and smaller than d1. On the other hand, the outer diameter of the rotating body 42 in the phase in which the guided portion 42g is not provided is smaller than d2.

Further, the rotating body 42 has a raised portion 42e on the inner surface. The raised portions 42e are provided in a total of two, one in the back portion shown in FIG. 2 and one in the front portion not shown in FIG. 2. These two raised portions 42e are arranged with a phase difference of 180 ° in the circumferential direction ds of the barrel 10. Each raised portion 42e has a first inclined edge portion 42e1 at an edge portion on the side that advances clockwise when viewed from the rear, and a second inclined edge portion 42e2 at an edge portion on the opposite side thereof. As shown in FIG. 2, the first inclined edge portion 42e1 is an edge portion inclined with respect to the axial direction da of the barrel 10 so as to face rearward, and the second inclined edge portion 42e2 is an axis so as to face forward. It is an edge portion inclined with respect to the axial direction da of the cylinder 10.

Next, the rotation operation unit 41 will be described. As shown in FIG. 3, the rotation operation unit 41 has a substantially tubular shape. A chuck fitting portion (not shown) that fits outside the rear end of the chuck 24 is provided at the front end (lower left end in FIG. 3) of the rotation operation unit 41. Further, a core pipe fitting portion 41s that is internally fitted into the core pipe 23 is provided at the rear end (upper right end in FIG. 3) of the rotation operation portion 41. Further, as shown in FIG. 3, a protrusion for applying a force in the circumferential direction ds to the rotating body 42 is formed on the outer surface of the rotation operation unit 41. This protrusion has a first protrusion 41a in which a first tapered portion 41at corresponding to a first inclined edge portion 42e1 of the rotating body 42 is formed at the front end, and a second taper corresponding to a second inclined edge portion 42e2 of the rotating body 42. The portion 41bt has a second protrusion 41b formed at the rear end thereof. In the present embodiment, the first protrusions 41a and the second protrusions 41b are alternately arranged at equal intervals, two each in the circumferential direction ds, corresponding to the raised portion 42e of the rotating body 42.

Further, the writing tool 100 has a rotation stop member 60 for preventing the relative rotation of the rotation operation unit 41 around the axis L with respect to the shaft cylinder 10. As shown in FIG. 5, the rotation stop member 60 has a substantially ring shape, and four engaging protrusions 63 corresponding to the groove 13 of the barrel 10 are formed on the outer surface. Further, the rotation stop member 60 has four engaging recesses 62 formed on the inner surface at a position where the engaging convex portion 63 is formed on the outer surface. Two of these engaging recesses 62 facing each other engage with the first protrusion 41a of the rotation operation unit.

As shown in FIG. 1, the rotating body 42 and the rotation stopping member 60 are arranged in the shaft cylinder 10 so as to surround the rotation operating portion 41. The rotating body 42 is arranged in a second phase in which the guided portion 42g is located at a position different from the position of the groove 13 of the shaft cylinder 10 when viewed from the axial direction da. Further, the rotation stop member 60 is arranged in the first phase in which the four engaging convex portions 63 are at the same positions as the positions of the grooves 13 of the shaft cylinder 10. More specifically, the guided portion 42g of the rotating body 42 is positioned in the rear region having the inner diameter d1 in the portion of the shaft cylinder 10 in which the groove 13 is formed. As described above, since the inner diameter d1 is larger than the maximum value of the outer diameter of the rotating body 42, the rotating body 42 can rotate relative to the shaft cylinder 10 around the axis L of the shaft cylinder 10. On the other hand, as described above, the maximum value of the outer diameter of the rotating body 42 is larger than the inner diameter d2 of the rear region in the portion of the shaft cylinder 10 in which the groove 13 is formed. Therefore, the rotating body 42 is prohibited from moving forward relative to the barrel 10. Further, in the rotation stop member 60, four engaging protrusions 63 are fitted in the groove 13 of the shaft cylinder 10 behind the rotating body 42, and relative rotation around the axis L with respect to the shaft cylinder 10 is prohibited. ing. Then, the rotating body 42 and the rotation stopping member 60 press the small diameter portion 10s of the shaft cylinder 10 backward by the urging force of the urging means 44.

Returning to FIG. 1, the guide pipe 30 of the present embodiment will be described. The guide pipe 30 is supported by the front end 11 of the shaft cylinder 10, supports the guide pipe main body 31 and the guide pipe main body 31 in the rear end region, and slides on the inner surface of the shaft cylinder 10 in the axial direction da. It has a support portion 32 and. Further, the shaft cylinder 10 defines an accommodation space 33 for accommodating the sliding support portion 32. The accommodation space 33 has a predetermined length in the axial direction da, and the sliding support portion 32 slides in the accommodation space 33 in the axial direction da within the range of this length. ..

Further, as shown in FIG. 1, the axle tube 10 has a friction portion 14 on the inner surface of the front end 11 that provides a predetermined static friction coefficient with the outer surface of the guide pipe 30. The friction portion 14 of the present embodiment is an O-ring. Of course, if a predetermined coefficient of static friction can be provided, an appropriate means such as controlling the surface roughness of the inner surface of the front end of the barrel 10 can be applied. The guide pipe 30 is configured to be located immediately in front of the chuck 24 in a state of being immersed in the barrel 10.

The maximum static friction force acting on the contact portion A between the sliding support portion 32 of the guide pipe 30 and the shaft cylinder 10 defining the accommodation space 33 is fA, and acts on the contact portion B between the guide pipe main body 31 and the writing core 21. Assuming that the maximum static friction force is fB, the relationship fA> fB is established between these static friction forces fA and fB. Therefore, as will be described later, when the writing core 21 passes through the guide pipe main body 31 in the axial direction da, the sliding support portion 32 maintains a stationary state with respect to the shaft cylinder 10. There is.

The core feeding unit 20 further has a pressing operation unit 18 attached to the rear end of the core pipe 23. By pressing the pressing operation unit 18 (knocking operation), the writing core 21 is extended from the chuck unit 28. The specific mode of feeding will be described later. The pressing operation unit 18 of the present embodiment is made of POM resin. The pressing operation unit 18 is configured as a holder unit 18h whose rear side holds the eraser 80 removable. A dome-shaped knob 81 that covers the rear of the eraser 80 is detachably fitted to the holder portion 18h.

Next, the operation of the writing tool 100 as described above will be described with reference to FIGS. 6A to 6E. FIG. 6A is a diagram showing a writing instrument 100 in a state where the guide pipe 30 is immersed in the shaft cylinder 10, and FIG. 6B is a diagram showing a writing instrument 100 in a state where the writing core 21 is being extended. FIG. 6C is a diagram showing a writing instrument 100 in a state where the chuck unit 28 is relatively moving forward with respect to the chuck support unit 27, and FIG. 6D shows a process in which the chuck unit 28 is returning to the initial position after FIG. 6C. FIG. 6E is a diagram showing a writing instrument 100 in a state where the chuck unit 28 has returned to the initial position after FIG. 6D. In each figure, the left side is a schematic vertical cross-sectional view showing the front region of the writing tool 100, and the right side is a diagram showing the relative positional relationship between the rotating body 42 and the rotation operation unit 41. However, for convenience of explanation, the rotation operating member is shown in the front view in the left figure. In the following description, FIG. 6A in which the guide pipe main body 31 is immersed in the shaft cylinder 10 is used as the initial state.

First, the extension of the writing core 21 by a normal knock operation will be described. Hereinafter, this knock operation is referred to as a primary knock operation. Prior to writing on the paper surface, the pressing operation unit 18 is removed from the core pipe 23, and the writing core 21 is inserted into the core pipe 23, if necessary. After that, the pressing operation unit 18 is reattached to the core pipe 23. In this state, the pressing operation unit 18 (knob 81) is pushed forward (knocked) with respect to the axle cylinder 10 in a posture in which the front end 11 of the axle cylinder 10 is located below the pressing operation portion 18. As a result, the chuck unit 28 is advanced with respect to the chuck support unit 27 against the urging force of the return spring 26. In the process of this advance, the tightening ring 25 is disengaged from the chuck 24, and the chuck 24 is opened. As a result, the writing core 21 is extended forward by a predetermined length from the chuck 24.

At the time of this knock, the chuck 24 advances inside the accommodation space 33, and the sliding support portion 32 of the guide pipe 30 is pressed forward by the chuck 24. As a result, the guide pipe 30 is moved forward relative to the barrel 10. As a result, the guide pipe main body 31 is exposed from the front end 11 of the shaft cylinder 10. Then, this exposed state is maintained by the frictional force acting on the contact portion A (see FIG. 1) between the sliding support portion 32 of the guide pipe 30 and the shaft cylinder 10 defining the accommodation space 33.

Then, when the pushing of the pressing operation unit 18 to the front is released, the chuck unit 28 moves backward relative to the chuck support unit 27 due to the urging force of the return spring 26. Along with this, the chuck 24 is tightened by the tightening ring 25. As a result, the writing core 21 is sandwiched by the chuck 24, and the state in which the writing core 21 is extended is maintained.

The operations of the rotating body 42 and the rotating operation unit 41 in the above primary knock operation are as follows. That is, when the pressing operation unit 18 is pushed forward with respect to the barrel 10, the rotation operation unit 41 moves relative to the rotating body 42. Due to the presence of the rotation stop member 60, the rotation operation unit 41 goes straight in the axial direction da without rotating around the axis L of the shaft cylinder 10. Then, when the chuck unit 28 moves relative to the chuck support unit 27 most forward, the first tapered portion 41at of the first protrusion 41a of the rotation operating portion 41 just hits the first inclined edge portion 42e1 of the rotating body 42. Contact (see FIG. 6B). Then, when the pressing of the pressing operation unit 18 is released, the chuck unit 28 moves backward relative to the chuck support unit 27 by the urging force of the return spring 26, and the initial state is restored (see FIG. 6A).

The above primary knock operation is repeated from the front end of the guide pipe main body 31 until the writing core 21 is slightly exposed (see FIG. 1). As described above, the maximum static friction force fA acting on the contact portion A between the sliding support portion 32 of the guide pipe 30 and the shaft cylinder 10 defining the accommodation space 33 is the guide pipe main body 31 and the writing core. It is larger than the maximum static friction force fB acting on the contact portion B with the 21. Therefore, when the writing core 21 is extended, the guide pipe 30 is not hung by the writing core 21 and further advances from the front end 11 of the barrel 10.

Then, the shaft cylinder 10 is gripped by the user, and the shaft cylinder 10 is desired to be moved while the writing core 21 is brought into contact with the paper surface to perform writing. With writing, the writing core 21 wears, and the length of the writing core 21 exposed from the front end of the guide pipe 30 gradually decreases. When the writing core 21 is further worn, the front end of the guide pipe 30 comes into contact with the paper surface. Even in such a case, the guide pipe 30 slips into the barrel 10 in synchronization with the wear of the writing core 21, so that writing can be continued without further extending the writing core 21.

By the way, in the writing tool 100 according to the present embodiment, the guide pipe 30 can be exposed longer from the front end 11 of the barrel 10 by pushing the pressing operation unit 18 harder than in the first knock operation. Such a knock operation is hereinafter referred to as a secondary knock operation. The operation of the writing tool 100 during the second knock operation will be described below.

When the pressing operation unit 18 is strongly pushed forward with respect to the axle cylinder 10, the first protrusion 41a of the rotation operation unit 41 presses the first inclined edge portion 42e1 of the rotating body 42 forward in the state shown in FIG. 6B. do. As a result, due to this pressing, forces in opposite directions act on the axis L between the rotating body 42 and the rotation operating unit 41. By the way, as described above, the rotation operation unit 41 is prohibited from rotating relative to the shaft cylinder 10 around the axis L by the rotation stop member 60. Therefore, the rotation operation unit 41 goes straight along the axial direction da without rotating relative to the shaft cylinder 10. Therefore, as shown in FIG. 6c, the rotating body 42 is rotated counterclockwise with respect to the barrel 10 when viewed from the rear (viewed from the right in FIG. 6C). Due to this relative rotation, the phase of the rotating body 42 changes from the second phase in the initial state to the first phase. That is, the phase of the rotating body 42 around the axis L and the phase of the groove 13 of the shaft cylinder 10 coincide with each other. As a result, the rotating body 42 is allowed to move forward relative to the barrel 10. As a result, the chuck unit 28 and the chuck support unit 27 move forward relative to the barrel 10 while compressing the urging means 44 due to the strong pressing force acting on the pressing operation unit 18.

The pushing operation of the pressing operation portion 18 may be performed until the sliding support portion 32 of the guide pipe 30 comes into contact with the front end in the accommodation space 33. As a result, the guide pipe main body 31 is exposed from the front end 11 of the shaft cylinder 10 beyond the length exposed from the front end 11 of the shaft cylinder 10 by the primary knock operation (see FIG. 6C). At this time, as shown in FIG. 6C, the rotating body 42 is positioned so that the second inclined edge portion 42e2 of the raised portion 42e faces the second tapered portion 41bt of the second projection 41b of the rotation operating portion 41.

Then, when the force for pushing the pressing operation unit 18 is released or weakened, as shown in FIG. 6D, the chuck support unit 27 and the chuck unit 28 are subjected to the urging force of the urging means 44 with respect to the shaft cylinder 10. And move backwards. The rotating body 42 maintains the first phase until the chuck support unit 27 is returned to the initial position due to the presence of the groove 13 of the shaft cylinder 10. During this time, the relative movement of the chuck unit 28 in the axial direction da with respect to the chuck support unit 27, specifically, the relative movement to the rear is restricted.

When the chuck support unit 27 returns to the initial position, the rotating body 42 can rotate relative to the shaft cylinder 10 around the axis L. In this state, when the rotation operation unit 41 that does not rotate relative to the axle cylinder 10 moves rearward with respect to the rotating body 42, the second tapered portion 41bt of the second protrusion 41b of the rotation operation unit 41 becomes the second of the rotating body 42. 2 The inclined edge portion 42e2 is pressed backward. As a result, the rotating body 42 is rotated clockwise around the axis L when viewed from the rear. Then, when the second tapered portion 41bt of the rotation operation unit 41 is separated from the second inclined edge portion 42e2 of the rotating body 42, the rotation of the rotating body 42 is completed, and the rotation operation unit 41 is further rearward with respect to the chuck support unit 27. The initial state is restored by moving relative to each other (see FIG. 6E).

Then, as described above, the barrel 10 is gripped by the user, and writing is performed on the paper surface. When the writing core 21 wears, the front end of the guide pipe 30 eventually comes into contact with the paper surface, but the guide pipe 30 slips into the shaft cylinder 10 in synchronization with the wear. Therefore, writing can be continued without additionally extending the writing core 21 until the sliding support portion 32 of the guide pipe 30 comes into contact with the rear end of the accommodating space 33 of the barrel 10.

In short, when the chuck unit 28 is moved forward relative to the barrel 10, the chuck unit 28 and the guide pipe 30 are moved forward relative to the chuck support unit 27. Next, the chuck unit 28, the chuck support unit 27, and the guide pipe 30 move forward relative to the axle cylinder 10.

According to the present embodiment as described above, it is possible to provide the writing tool 100 capable of exposing the guide pipe 30 surrounding the front end of the writing core 21 from the front end 11 of the barrel 10 longer than the conventional one. Therefore, more writing can be performed by one knock operation (second knock operation).

Further, the writing tool 100 has a difference in inner diameter provided between the rotating body 42 provided in the chuck support unit 27, the groove 13 provided in the shaft cylinder 10, and the portion of the shaft cylinder 10 in which the groove 13 is provided. It has d1> d2) and a rotation operation unit 41 provided on the chuck unit 28 to rotate the rotating body 42 relative to the chuck support unit main body between the first phase and the second phase. These components work together to limit the relative movement of the chuck unit 28 in the axial direction da with respect to the chuck support unit 27 when the rotating body 42 is in first phase. As a result, the chuck support unit 27 does not move relative to the shaft cylinder 10 during the primary knock operation, so that the primary knock operation can be stably performed.

Next, a modification of the above writing tool 100 will be described.

FIG. 7 is a schematic vertical sectional view showing a writing tool 200 according to a modification of FIG. 1. The writing tool 200 is different from the writing tool 100 shown in FIG. 1 in that the chuck unit 228 does not have a rotation operation unit and the chuck support unit 227 does not have a rotating body. Further, the chuck unit 228 of the writing tool 200 is urged backward by the return spring 26 with respect to the chuck support unit 227 by the first urging force. The chuck support unit 227 of the writing tool 200 is urged rearward with respect to the barrel 10 by the urging means 44 with a second urging force larger than the first urging force. In particular, the second urging force is set to be larger than the urging force generated by the return spring 26 when the return spring 26 is most compressed during the knocking operation of the writing tool 200 by the first knock operation. Other configurations are substantially the same as those of the writing tool 100 shown in FIG. Therefore, in FIG. 7, the same components as those in FIG. 1 are designated by the same reference numerals, and detailed description thereof will be omitted.

In the writing tool 200 as described above, the chuck unit 228 is advanced with respect to the chuck support unit 227 against the urging force of the return spring 26 during the first knock operation. Similar to the writing tool 100 shown in FIG. 1, in the process of this advancement, the tightening ring 25 is disengaged from the chuck 24, and the chuck 24 is opened. At the same time, the sliding support portion 32 of the guide pipe 30 is pressed forward by the chuck 24, and the guide pipe 30 is exposed from the front end 11 of the barrel 10. During that time, the force acting on the urging means 44 from the chuck support unit 227 does not exceed the urging force of the urging means 44. Therefore, during the first knock operation, the chuck support unit 227 does not move relative to the barrel 10.

At the time of the second knock operation, the pressing operation unit 18 is pressed forward with a force exceeding the resultant force of the urging force by the return spring 26 and the urging force by the urging means 44. As a result, the urging means 44 is compressed, and the chuck support unit 227 and the chuck unit 228 are relatively moved forward with respect to the barrel 10. Then, due to this relative movement, the guide pipe 30 is further exposed from the front end 11 of the barrel 10.

Then, when the pressing of the pressing operation unit 18 is released, the chuck support unit 227 and the chuck unit 228 are relatively moved rearward with respect to the shaft cylinder 10 by the urging force of the urging means 44. Further, the urging force of the return spring 26 causes the chuck unit 228 to move backward relative to the chuck support unit 227.

The action of the writing tool 200 as described above is basically the same as the action of the writing tool 100 shown in FIG. 1. When the chuck unit 228 is moved forward relative to the barrel 10, first, the chuck unit 228 and the guide pipe 30 are operated. Is relatively moved forward with respect to the chuck support unit 227, and then the chuck unit 228, the chuck support unit 227 and the guide pipe 30 are relatively moved forward with respect to the barrel 10.

Also by the present modification as described above, it is possible to provide the writing tool 200 capable of exposing the guide pipe 30 surrounding the front end of the writing core 21 from the front end 11 of the barrel 10 longer than the conventional one. That is, even with this modification, it is possible to provide a writing instrument 200 capable of performing more writing by a single knock operation.

Further, the chuck unit 228 is urged rearward with respect to the chuck support unit 227 by the first urging force, and the chuck support unit 227 has the shaft cylinder 10 with a second urging force larger than the first urging force. Is being urged backwards. As a result, the chuck support unit 227 does not move relative to the shaft cylinder 10 during the primary knock operation, so that the primary knock operation can be stably performed.

Next, a further modification of the writing tool 100 shown in FIG. 1 will be described.

FIG. 8 is a schematic vertical sectional view showing a writing tool 300 according to a further modification of FIG. 1. In this writing instrument 300, when the writing core 21 is pressed backward with respect to the shaft cylinder 10, the chuck unit 328 moves rearward with respect to the shaft cylinder 10. Specifically, the rotating body 342 supports the chuck support unit main body 329 so as to be relatively movable in the axial direction da. Further, the writing tool 300 has a coil spring 340 as a urging means for urging the chuck unit 328 forward with respect to the rotating body 342. Behind the coil spring 340 (on the right side in FIG. 1), a damping means 350 for applying a damping force corresponding to the relative speed of the chuck unit 328 to the barrel 10 is provided on the chuck unit 328. The damping means 350 is fixed to the barrel 10.

As shown in FIG. 8, the chuck unit 328 has a tubular member 322 for limiting the amount of rearward movement of the chuck unit 328 with respect to the rotating body 342. The outer circumference of the tubular member 322 is surrounded by a rotating body 342.

Next, the damping means 350 has a tubular housing 351 that surrounds the core pipe 23 of the chuck unit 328, and two sealing portions 352a and 352b arranged in the gap between the housing 351 and the core pipe 23. There is. The seal portions 352a and 352b of the present embodiment are O-rings, are arranged at intervals in the axial direction da, and seal the gap between the housing 351 and the core pipe 23 over the entire circumference of the core pipe 23. As shown in FIG. 8, a spiral groove is formed on the inner surface 351s of the housing 351 and the distance from the inner surface 351s to the outer surface of the core pipe 23 is a space sealed by two sealing portions 352a and 352b. In, it changes along the axial direction da. Then, the sealed space is filled with grease 353.

The coil spring 340 is arranged in a compressible state so as to be expandable and contractible between the flange portion 27f of the chuck support unit 27 and the contacted portion 345 provided on the rotating body 342. Due to the urging force of the coil spring 340, the chuck unit 328 is positioned at the frontmost position in the range of motion with respect to the rotating body 342. At this time, a gap g of, for example, 0.5 mm is formed between the rear end of the tubular member 322 and the contacted portion 345. The coil spring 340 may be configured to urge the chuck unit 328 forward with respect to the axle cylinder 10. Other configurations are substantially the same as those of the writing tool 100 shown in FIG. Therefore, in FIG. 8, the same reference numerals are given to the components common to the writing tool 100 of FIG. 1, and detailed description thereof will be omitted.

In the writing instrument 300 as described above, by pressing the shaft cylinder 10 toward the paper surface with the front end of the writing core 21 in contact with the paper surface, the writing core 21 is pushed backward with respect to the shaft cylinder 10 and the guide pipe 30. It can be moved relative to each other. That is, this pressing force is transmitted from the writing core 21 to the coil spring 340 via the chuck unit 328. When this transmitted force exceeds the initial load of the coil spring 340, the coil spring 340 is compressed, and the chuck unit 328 and the chuck support unit 327 move rearward with respect to the axle cylinder 10. The moving distance of this relative movement is defined by the gap g between the rear end of the tubular member 322 and the contacted portion 345. Therefore, in the example shown in FIG. 8, it is 0.5 mm.

As can be understood from the relationship between the maximum static friction force fA and the maximum static friction force fB described above, when the writing core 21 moves backward relative to the barrel 10, the guide pipe 30 is hung on the writing core 21 and the shaft. It does not move backward relative to the cylinder 10. However, after the writing core 21 has completely slipped into the guide pipe 30, the guide pipe 30 is also pressed from the paper surface, so that the writing core 21 moves rearward with respect to the barrel 10. That is, the length of the portion of the guide pipe main body 31 exposed from the front end of the shaft cylinder 10 is reduced. In the process of such relative movement, the chuck unit 328 receives a damping force according to the relative movement speed by the damping means 350. This damping force provides the user of the writing instrument 300 with an appropriate sense of resistance.

Then, when the pressing force on the writing core 21 is released, or when the pressing force is weakened until the pressing force falls below the initial load of the coil spring 340, the coil spring 340 expands and makes the tubular member 322 forward relative to the shaft cylinder 10. Move it. This relative movement ends when the chuck unit 328 is moved to the rear end of the range of motion with respect to the rotating body 342. As a result, the relative positional relationship between the barrel 10 and the chuck unit 328 is restored to the initial state (see FIG. 8). At this time, the damping means 350 acts on the chuck unit 328 with a damping force corresponding to the relative speed with respect to the barrel 10. Therefore, even if the pressing force is momentarily removed from the writing core 21, the chuck unit 328 slowly advances with respect to the barrel 10. That is, the chuck unit 328 smoothly moves relative to the shaft cylinder 10.

Also at this time, as can be understood from the relationship between the maximum static friction force fA and the maximum static friction force fB described above, the guide pipe 30 is hung on the writing core 21 and moves forward relative to the barrel 10. There is no such thing. That is, the guide pipe 30 maintains a relative position with respect to the shaft cylinder 10 while the chuck unit 328 is relatively moved forward with respect to the shaft cylinder 10. Due to the relative reciprocating movement of the chuck unit 328 with respect to the shaft cylinder 10 as described above, the length of the writing core 21 exposed from the front end of the guide pipe 30 is increased by the amount that the guide pipe 30 is retracted with respect to the shaft cylinder 10. do.

Alternatively, the relative reciprocating movement of the chuck unit 328 with respect to the shaft cylinder 10 as described above also provides a function of reducing breakage of the writing core 21. That is, when an excessive writing pressure acts on the writing core 21 during writing, the writing pressure component (component force) along the axial direction da of the barrel 10 compresses the coil spring 340. As a result, the writing core 21 slips into the guide pipe 30, so that the writing core 21 is effectively prevented from breaking. Then, when the writing pressure is weakened, the relative positional relationship between the writing core 21 and the barrel 10 is restored by the urging force of the coil spring 340.

According to the present modification as described above, the length of the writing core 21 exposed from the front end of the guide pipe 30 can be increased without knocking the pressing operation unit 18. Therefore, since it is possible to realize a state in which the guide pipe 30 does not come into contact with the paper surface during writing without using a knock operation, it is possible to provide a writing tool 300 that is highly convenient and has a smooth writing comfort. Further, when the writing pressure acting on the writing core 21 increases, the writing core 21 is drawn into the guide pipe 30, so that excessive writing pressure on the writing core 21 is suppressed. Thereby, it is possible to provide the writing instrument 300 which can effectively suppress the breakage of the writing core 21.

Further, since it is easy to maintain a state in which the writing core 21 is slightly exposed from the front end of the guide pipe 30, the visibility of the writing core 21 is good. For this reason, it is effectively suppressed that the user of the writing instrument 300 unintentionally extends the writing core 21 excessively from the front end of the guide pipe 30 to perform writing, and thus the breakage of the writing core 21 is effectively suppressed. obtain.

Further, the range of motion of the chuck unit 328 with respect to the rotating body 342 is defined by the gap g between the contacted portion 345 of the rotating body 342 and the tubular member 322. Therefore, the amount of retreat of the chuck unit 328 with respect to the rotating body 342 can be reliably regulated within an appropriate range.

Further, a damping means 350 for exerting a damping force corresponding to the relative speed of the chuck unit 328 with respect to the shaft cylinder 10 on the core pipe 23 is arranged between the shaft cylinder 10 and the chuck unit 328. Therefore, the relative movement of the writing core 21 with respect to the barrel 10 can be smoothed. Further, the operation feeling of the knock operation when the writing core 21 is extended can be improved.

The damping means 350 is arranged in the gap between the cylindrical housing 351 surrounding the core pipe 23 and the housing 351 and the core pipe 23 at an interval in the axial direction da, and seals the gap over the entire circumference of the core pipe 23. It has two seal portions 352a and 352b. Then, the space sealed by the two sealing portions 352a and 352b in the housing 351 is filled with grease 353. Therefore, the effect of the damping means 350 can be maintained for a long period of time, and the surrounding members are not contaminated with grease 353.

Further, since the spiral groove is formed on the inner surface 351s of the housing 351, the grease 353 can be suitably held, and the damping force can be stably provided to the core pipe 23.

Further, since the coil spring 340 and the damping means 350 are arranged in series in the axial direction da of the shaft cylinder 10, the coil spring 340 and the damping means 350 are placed in the shaft cylinder 10 without increasing the diameter of the shaft cylinder 10. Can be placed.

The damping means 350 and the coil spring 340 as described above may be additionally provided in the writing tool 200 shown in FIG. 7. FIG. 9 is a schematic vertical sectional view showing such a writing tool 400. As shown in FIG. 9, in the writing tool 400, the chuck support unit 427 is supported by the chuck support unit main body 429 supporting the chuck unit 428 and the chuck support unit main body 429, and is supported in the axial direction da with respect to the chuck support unit main body 429. It has a relative movable support 427s and. The chuck unit 428 is urged forward with respect to the shaft cylinder 10 and the support 427s by the urging force of the return spring 26, and the support 427s is urged rearward with respect to the shaft cylinder 10 by the urging means 44. There is. Other configurations are the same as those of the writing tool 200 shown in FIG. Therefore, in FIG. 9, the same reference numerals are given to the configurations common to the writing tool 200 of FIG. 7, and detailed description thereof will be omitted.

Such a writing instrument 400 also provides the same operation as the writing instrument 200 shown in FIG. 7, and further, the same drawing of the writing core 21 as the writing instrument 300 shown in FIG. 8 is realized. Therefore, according to the writing instrument 400, the same effect as that of the writing instrument 200 shown in FIG. 7 can be obtained, and the writing instrument 300 shown in FIG. 8 has a good operational feeling when the writing core 21 is extended and retracted by the damping means 450. And the effect of reducing the breakage of the writing core 21 can be provided.

In the writing tools 300 and 400 shown in FIGS. 8 and 9, the damping means 320 and 450 may be removed. In this case, the chuck units 328 and 428 are not subjected to the damping force according to the relative moving speed with respect to the barrel 10. Therefore, rapid operation can be provided during a knock operation or when the chuck units 328 and 428 move relative to the rotating body 342 or the support 427s due to compression and expansion of the coil springs 340 and 440.

10 Shaft cylinder 10p Inner flange 10s Small diameter part 11 Front end 13 Groove 14 Friction part 18 Pressing operation part 18h Holder part 20 Core feeding unit 21 Writing core 23 Core pipe 24 Chuck 25 Tightening ring 26 Return spring 27 Chuck support unit 27f Flange part 27p Shrinkage Diameter 28 Chuck unit 29 Chuck support unit body 29p Outer cylinder 30 Guide pipe 31 Guide pipe body 32 Sliding support part 33 Accommodation space 40 Coil spring 41 Rotation operation part 41a 1st protrusion 41at 1st taper part 41b 2nd protrusion 41bt 2nd Tapered part 41s Core pipe fitting part 42 Rotating body 42e Raised part 42e1 First inclined edge part 42e2 Second inclined edge part 42g Guided part 44 Erasing means 60 Rotating stop member 62 Engagement recess 63 Engagement convex part 80 Eraser 81 Knob 100 Writing tool 200 Writing tool 227 Chuck support unit 228 Chuck unit 300 Writing tool 320 Damping means 322 Cylindrical member 322f Locking part 327 Chuck support unit 328 Chuck unit 329 Chuck support unit body 340 Coil spring 342 Rotating body 345 Contacted part 350 Damping means 351 Housing 351s Inner surface 352a Seal part 352b Seal part 353 Gris 400 Writing tool 427 Chuck support unit 427s Support 428 Chuck unit 429 Chuck support unit body 440 Coil spring 450 Damping means

Claims (10)

With the shaft tube
A core feeding unit that holds the writing core forward so that it can be fed forward,
It is provided with a guide pipe provided at the front end of the shaft cylinder so as to be relatively movable in the axial direction of the shaft cylinder with respect to the shaft cylinder and the core feeding unit, and is located on the writing core.
The core feeding unit is
A chuck support unit supported by the shaft cylinder so as to be relatively movable in the axial direction with respect to the shaft cylinder.
It has a chuck unit that is supported by the chuck support unit so as to be relatively movable in the axial direction with respect to the chuck support unit, and holds the writing core so as to be sent forward.
The guide pipe moves forward relative to the shaft cylinder as the core feeding unit moves forward relative to the shaft cylinder.
When the chuck support unit is moving backward relative to the barrel, the relative movement of the chuck unit in the axial direction with respect to the chuck support unit is restricted .
The chuck support unit is supported by the chuck support unit main body that supports the chuck unit and the chuck support unit main body, and has a first phase and a second phase with respect to the chuck support unit main body around the axis of the barrel. With a rotating body that can rotate between,
The chuck unit rotates the rotating body from the second phase to the first phase when moving forward relative to the chuck support unit.
The chuck unit is restricted from moving relative to the chuck support unit in the axial direction when the rotating body is in the first phase.
Writing implements. Said writing lead in time when pressed rearwardly with respect to said barrel, said chuck unit is moved relative to the rear relative to the barrel, a writing instrument according to claim 1. The rotating body supports the chuck support unit main body so as to be relatively movable in the axial direction.
The writing tool according to claim 2 , further comprising an urging means for urging the chuck unit or the chuck support unit main body forward with respect to the rotating body or the shaft cylinder. The chuck unit is urged backward by the first urging force with respect to the chuck support unit.
The writing tool according to claim 1, wherein the chuck support unit is urged rearward with respect to the barrel with a second urging force larger than the first urging force. With the shaft tube
A core feeding unit that holds the writing core forward so that it can be fed forward,
It is provided with a guide pipe provided at the front end of the shaft cylinder so as to be relatively movable in the axial direction of the shaft cylinder with respect to the shaft cylinder and the core feeding unit, and is located on the writing core.
The core feeding unit is
A chuck support unit supported by the shaft cylinder so as to be relatively movable in the axial direction with respect to the shaft cylinder.
It has a chuck unit that is supported by the chuck support unit so as to be relatively movable in the axial direction with respect to the chuck support unit, and holds the writing core so as to be sent forward.
The guide pipe moves forward relative to the shaft cylinder as the core feeding unit moves forward relative to the shaft cylinder.
When the chuck support unit is moving backward relative to the barrel, the relative movement of the chuck unit in the axial direction with respect to the chuck support unit is restricted.
The chuck unit is urged backward by the first urging force with respect to the chuck support unit.
The chuck support unit, wherein at large second biasing force than the first biasing force, that is urged rearwardly relative to the barrel, the brush Kigu. The writing tool according to claim 5, wherein when the writing core is pressed backward with respect to the shaft cylinder, the chuck unit moves rearward with respect to the shaft cylinder. The chuck support unit has a chuck support unit main body that supports the chuck unit, and a support that is supported by the chuck support unit main body and can move relative to the chuck support unit main body in the axial direction.
The chuck unit is urged forward with respect to the barrel or the support.
The writing tool according to claim 6, wherein the support is urged rearward with respect to the barrel. A claim further provided with a damping means for exerting a damping force corresponding to a relative speed of the chuck unit with respect to the shaft cylinder on the chuck unit when the chuck unit moves relative to the shaft cylinder in the axial direction. Item 2. The writing tool according to 2, 3, 6 or 7. One of claims 1 to 8, wherein the maximum static friction force acting between the guide pipe and the shaft cylinder is larger than the maximum static friction force acting between the guide pipe and the writing core. Writing tools described in. With the shaft tube
A chuck support unit supported by the shaft cylinder so as to be relatively movable in the axial direction of the shaft cylinder, and a chuck support unit supported by the chuck support unit so as to be relatively movable in the axial direction with respect to the chuck support unit, and the writing core is moved forward. A chuck unit that holds it so that it can be sent out, and
The shaft cylinder, the chuck support unit, and a guide pipe provided at the front end of the shaft cylinder so as to be relatively movable in the axial direction with respect to the chuck unit and located on the writing core are provided.
When the chuck unit is moved forward relative to the barrel,
First, the chuck unit moves forward relative to the chuck support unit, and then
Next, a writing tool in which the chuck unit, the chuck support unit, and the guide pipe move forward relative to the barrel.

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