KR880002478B1 - Sharp-pencil - Google Patents

Abstract

The slider (16) moves forward by the resilience of spring (13) to pull forward the lead core (14) by the frictional force of a friction member (20). When interrupting a writing or freeing the tip of the slider pipe (18) from the paper. The holding force of lead chuck (6) given by spring (12) for engaging the lead core (14) is arranged to be weaker than that of the spring (13) so as to allow the advancement of the core by spring (13) with suppression of the spring (12). The lead core keeps projecting at a given distance from the tip of the pencil.

Description

Shaaf Pencil

1 is a longitudinal sectional view of one embodiment of the present invention.

2 (a)-(h) are longitudinal cross-sectional views of various embodiments showing engagement of the sleeve with the front cylindrical portion.

3 is a partial side cross-sectional view of the lead chuck.

4 is a plan view of FIG.

5 is a cross-sectional view taken along the line X-X of FIG.

6 is a cross-sectional view taken along the line Y-Y of FIG.

7 is a plan view of the fitting portion for the core fitting.

8 is a cross-sectional view of the core portion.

9 (a) and 9 (b) are plan views of another embodiment of the fitting portion.

10 is a longitudinal sectional view of another embodiment of the lead chuck and front cylindrical portion.

11 is a longitudinal cross-sectional view of the buffer third spring.

12 is a front view of another embodiment of the front cylindrical portion.

13 is a cross-sectional view of the friction material.

14 to 17 are explanatory diagrams of the heart-feeding operation.

* Explanation of symbols for main parts of the drawings

1: outer cylinder 2: tip cap

3: lead pipe 4: front cylindrical portion

5: lead delivery mechanism 6: lead chuck

7: sleeve 9: front tube

10: bowl support portion 11: bowl

12: first spring 13: second spring

14: heart 15: intermediate body

16: slider 17: third spring

18: slider pipe 19: slider body

20: frictional imparting member 21: receiving part

60: penetrating hole 614, 62: chuck member

63, 64: gum teeth 71, 72: lumbar region

70, 73, 74, 75: iron section

The present invention relates to a mechanical pencil that is automatically sent out when writing stops when writing on a paper, the writing pressure received by the slider at the time of writing is canceled.

Recently, a so-called automatic mechanical pencil has been proposed, in which a slider that is able to slide within the tip cap and a plurality of springs are combined to automatically send the core as the slider releases the force from the ground. . However, all of the proposals had a problem that the internal structure with the core delivery mechanism is so complicated that assembly efficiency is poor and the number of parts increases, resulting in high manufacturing costs.

Accordingly, the present invention has been invented to solve the above problems, and in addition to simplifying the internal structure, even though the structure is simple, the pen core sending operation is also made of three, press the tip end to send the pen core The purpose of this operation is to provide a mechanical pencil so that only a certain amount of protrusion is always protruded, even if the core is not protruded, and even if it is overextruded more than a predetermined amount.

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

As shown in FIG. 1, the outer cylinder 1 has a tip cap 2 disposed at the tip thereof, and a pen core pipe 3 having a sliding reciprocating movement in the front axial direction is disposed therein. The front cylindrical portion 4 is fitted to the tip of the pen core pipe 3 while the pen core sending mechanism 5 is arranged on the front end shaft of the front cylindrical portion 4 while maintaining a predetermined distance of contact distance a. It is done. In addition, the front cylindrical portion 4 is formed with a tip holder 4a which is pressed into the rear end of the lead chuck 6, which will be described later, while the front cylindrical portion 4 is movable with the sleeve 7. Is hanging. here. The jamming of the front cylindrical portion 4 and the sleeve 7 causes the jamming of the sleeve 7 to move together integrally until the sleeve 7 contacts the front barrel 9. From this, as long as the front cylindrical portion 4 is fitted so that it can move forward, it is good. As a specific example, the example shown in FIG.

In the embodiment of Fig. 2 (a), a foot-shaped convex portion 4b is formed to protrude from the front cylindrical portion 4 so as to be movably hooked with the recessed portion 7a of the sleeve 7.

2 (b) and 2 (c) show another embodiment of the sleeve 7, the groove being movably hung with the convex portion 4c of the front cylindrical portion 4 ( 7b) is formed, and the projection 7c is formed in the groove 7b, and the groove width A of this portion is formed to be narrower than the width B of the convex portion 4C, so that the sleeve 7 is formed. The convex part 4c is caught by the synchronous 7c of the groove | channel 7b until it contacts the front cylinder 9, and both will move together integrally. Subsequently, the convex portion 4c is pushed forward by pushing the projection 7c so that only the front cylindrical portion 4 can move forward to the tip of the groove 7b.

In addition, in the case of FIG. 2 (c), the convex portion 4c pushes the inclined portion 7d even after the convex portion 4c crosses the convex portion 7c while being connected to the protrusion 7c of the groove 7b. Go forward.

In addition, the second (d) also shows another embodiment of the sleeve (7), by forming a rough surface (7e) to give a predetermined resistance force to the convex portion (4c) in a portion of the groove (7) I put it. By this rough surface 7e, as in the above-described embodiment, the front cylindrical portion 4 and the sleeve 7 are provided with resistance to the convex portion 4c until the sleeve 7 touches the front cylinder 9. It moves integrally, and only the front cylinder part 4 can move forward after that.

Both the second (e) and the second (f) show yet another embodiment of the sleeve 7, in which a groove 7b having a bent shape is formed so that the sleeve 7 and the front cylinder are formed. The portion 4 is formed to be movable as in the above embodiment.

In particular, the width A of the groove 7b in FIG. 2 (e) is narrower than the width B of the convex portion 4c to give the concave portion 4c a predetermined resistance, while the width C is the width of the convex portion 4c. It was made wider than B) so that the sleeve 7 and the front cylindrical portion 4 could move as in the above embodiment.

Moreover, the rough surface 7e which gives predetermined resistance to the convex part 4c was also formed in the groove 7b of FIG. 2 (f).

On the other hand, the second (g) also shows another embodiment of the sleeve 7, which is formed in the bent groove 7, where the width A of the groove 7b is the convex portion 4c. It is formed narrower than the width (B) of) so that as in the above-described embodiment, the sleeve 7 is moved together until the sleeve 7 touches the front cylinder 9, and only the front cylindrical portion 4 thereafter. It is formed to move forward.

In FIG. 2 (h), the protrusion 7c and the locking inclined surfaces 7f ₁ and 7f ₂ are formed in the bent groove 7b to have the same effects as in the above embodiments. However, in the embodiment up to FIG. 2 (h), the convex portions 4c and the grooves 7b form a pair facing each other, and as shown in FIG. 1, the rear end and the front cylindrical portion of the sleeve 7 are formed. An interval equal to the distance b was provided between the engaging portions 4b of (4).

In addition, the pen core feeding mechanism 5 has the rear end of the bowl 11 and the lead chuck 6 supported by the bowl supporting portion 10 of the head of the lead chuck 6 formed in two parts, and the rear end thereof. The first spring 12 for tightening the chuck is elastically fitted between the sleeve 7 engaged with the front cylindrical portion 4 and the engaging jaw 6a of the sleeve 7 and the lead chuck 6. Has

The lead chuck 6 is formed of a metal molded product formed by forging or press working, a small alloy, a cutting work, or a synthetic resin molded by injection molding or extrusion molding.

The lead chuck 6 is divided into two along the axis of the penetrating through hole 60, as shown in FIGS. Consists of a pair of chuck members (61, 62) formed in a semicircular shape, the retaining portion (10) and the locking jaw (6a) at the rear, extending from the rear end of the locking jaw (6a) to the rear The rear tapered barrel portion 6b, whose rear end side is gradually reduced in diameter, the penetrating through hole 60 of the shaft portion, the engagement recesses 71 and 72, the engagement recesses 70 and 73, and the opening and closing point recess 74 , 75).

In this case, the locking convex portion is configured to hook the convex portion 70 of one chuck member 61 to the concave portion 72 of the other chuck member 62 so that the chuck members 61 and 62 do not deviate from each other in the axial direction. Doing. In addition, the opening and closing point convex portions 74 and 75 of the chuck members 61 and 62 are brought into contact with each other to enable the chuck members 61 and 62 as support points for levering the chuck members 61 and 62 in the opening and closing direction, and are also sufficient for smooth lever movement. It serves as a spacer so that a gap K (see FIG. 1) is formed.

However, in the present embodiment, in order to prevent the axial shift of the chuck members (61, 62) to install the locking projections (71, 72, 70, 73) and to open and close the branch openings 74 for the lever movement in the opening and closing direction 74 , 75) were installed respectively. In the chuck members 61 and 62 of each of the grips, a convex portion longer than the concave portion may be formed at the latching position so that both of the convex and convex portions may be combined, or the saw blade may be formed to prevent misalignment at the mutual contact portion.

And teeth teeth 63, 64 are formed on the inner wall of the head of the lead chuck 6, which teeth teeth 63, 64, as shown in Figs. 61 and 62, alternately arranged at regular intervals between the plurality of central tooth teeth 63 and the central tooth teeth 63 which are arranged at regular intervals along the center line of the inner circumferential surface of the penetrating penetrating hole 60 divided in half at 61 and 62). It is made of a side tooth red 64 that is displaced to both sides thereof.

In these gum teeth 63 and 64, the central tooth teeth 63 have a tapered surface 63a at their front and rear surfaces and a vertical surface 63b at both ends thereof, while the side teeth 64 have a tapered front and rear surfaces. Face 64a, the inner end side is a vertical surface 64b, the outer end side is a tapered surface 64c, and the side teeth 64 are divided into half penetrating holes 60 between the central teeth 63. The inner circumferential surface is arranged while overlapping with the central tooth red 63 and arranged at regular intervals. Accordingly, each of the teeth 63 and 64 is sharply formed at its tip, and the bottoms 63c and 64f of the grooves formed between the teeth are formed in a planar shape.

Since the teeth teeth 63 and 64 are arranged to be different from each other at a predetermined interval, the same thing as the chisel residue does not remain, and the groove bottoms 63c and 64d formed between the teeth are in a plane. Since it is formed, the core waste etc. do not remain from this advantage.

모양이나

모양으로 배열해 놓는등 어떤 형태로 배열시켜도 좋다.In addition, if the arrangement structure of each gum teeth 63 and 64 can effectively remove the remaining of the core and the residue of the core, for example, as shown in FIG.

Shape

You can arrange them in any shape, such as in a shape.

In addition, each tooth teeth 63 and 64 may be provided in the form of a space | interval or continuous form in the front, back, left, and right of each other.

The bowl 11 supported by the head of the lead chuck 6 has a metal barrel 7h such as stainless on the inner tapered wall 7g of the tip of the sleeve 7 as shown in FIG. ) Is fitted as needed.The metal barrel (7h) makes contact firmly while rolling stably and durably. Furthermore, the lead chuck (6) can securely hold the core and its durability. Will increase.

The metal cylinder 7h is not necessarily required, and in normal use, the metal cylinder 7h may be omitted by forming the bowl 11 in contact with the inner tapered wall 7g while rolling. In addition, at the tip of the inner tapered wall 7g of the sleeve 7 or the tip of the metal barrel 7g, a ring-shaped protrusion 71 may be formed only when necessary, as shown by a dotted line in FIG. Accordingly, dropping of the bowl 11 is effectively prevented.

In the embodiment of FIG. 1, the front end portion of the sleeve 7 is formed as a tapered wall 7g. However, the present invention is not limited to this, but may be a parallel wall that is substantially parallel to the axial direction.

In addition, as shown in FIG. 10, the rear end of the lead chuck 6 may be provided with the locking recess 6c of the front cylindrical portion 4 and the locking convex portion 6c to be engaged. Although the knock is released by these uneven parts 4e and 6c, the lead chuck 6 and the front cylindrical part 4 are temporarily detached from each other to prevent an insufficient pen core feeding operation. That is, during the knock operation, the lead chuck 6 is pushed forward by the front cylindrical portion 4 to reach the front cylinder 9, and then the front end hole 4a of the front cylindrical portion 4 and the lead chuck ( As the rear end of 6) is caught, the lead chuck 7b opens and moves forward to send the lead. Herein, immediately after the knock is released, the recessed portion 4e and the convex portion 6c are caught until the outer locking jaw 7j of the sleeve 7 retreats and contacts the inner locking jaw 15a of the intermediate cylinder 15. In the meantime, the lead chuck 6 is opened, and the lead is smoothly sent out.

In this embodiment, the lead chuck 6 is shown to be split into two sides, but may be formed to be split into three or more pages. On the other hand, in order to prevent such a phenomenon as the axial shift of this lead chuck 6, you may form a concave-convex part or a tooth | piece for a misalignment prevention in the mutual contact part. In addition, a part of the diameter of the lead chuck 6 is almost the same as the inner diameter of the sleeve 7, and the rear end of the first spring 12 is reliably caught by the locking jaw 6a of the lead chuck 6. Therefore, the shape of the lead chuck 6 in the up, down, left and right directions can be reliably prevented from being skewed or misaligned.

In addition, although the bowl support part 10 of the lead chuck 6 may be used as the hole holding the bowl 11 only, you may accommodate it so that the bowl 11 may not come out. In addition, the bowl 11 is free to rotate in the bowl support 10.

On the other hand, the first spring 12 has a smaller resilience force than the second spring described later. The first spring 12 is smaller than the usual elastic modulus, and the resilience force is, for example, about 10 g. The value of 10 g is simply an example and can be used as needed.

In addition, the pen core delivery mechanism 5 described above is housed in the intermediate cylinder 15, and the intermediate cylinder 15 is arranged in the outer cylinder 1 so as to slide reciprocally in the axial direction. It is pushed forward by 17). And the front cylinder 9 is provided in the front-end | tip of this intermediate | middle cylinder 15, and the inner locking jaw 15a is formed in the inner wall, and the outer locking jaw 15b is formed in the outer periphery, respectively.

A certain distance (C) is maintained between the tip (9a) and the end of the sleeve (7) of the front tube (9) of the penis, this distance (C) is to be sent out by the end nose as described later It is equivalent to the amount of stroke sent out.

Wherein the front cylinder (9) is fitted to the tip of the intermediate cylinder (15) to reach the front end of the lead chuck (6) as described later ① stop the lead chuck (6), ② inner wall slope At 9b, the lid chuck 6 is opened and the rear end of the slider 16 is pressed. Any material having these functions may be used.

In addition, the inner locking jaw (15a) of the intermediate cylinder 15 is caught with the outer locking jaw (7j) of the sleeve (7) when writing, the sleeve (7) is the third against the writing pressure It is pushed forward by the spring 17 and pushed forward by the intermediate cylinder 15.

The third spring 17 has three functions as follows. That is, first, the anti-shake function of the pen core pipe 3, and second, the elasticity of the third spring 17 is stronger than the normal writing pressure, but if the excessive pen pressure acts on the pen core 14 during writing The buffer function to push the cylinder 15 to the rear, and, thirdly, when the eraser rubber (not shown) is installed at the rear end of the pen core pipe 3, it is a support function when using the eraser rubber.

Further, in the case of the pen core feeding operation described below, the third spring 17 has a force in the compression direction by the intermediate cylinder 15 which is moved back to the tip knock. Here, the eraser rubber for pushing the pen core pipe 3 in the rear direction is supported by a predetermined strong elastic force. In addition, in order to make the tip knock smoothly with a small force, it is required that the force pushing the intermediate cylinder 15 forward is made with a predetermined weak elastic force. Thus, as shown in FIG. 11, the number of turns of the third spring 17 is changed in the front direction and the rear direction so that the approximate center portion is brought into contact with the inner wall of the outer cylinder 1. In addition to weakening, resilience in the backward direction is strengthened.

In addition, as shown in FIG. 12, the front cylindrical portion 4 has a friction with the inner wall of the outer cylinder 1 by forming a stretchable piece 4f that can be moved outward on a portion of the outer peripheral surface of one cylindrical portion 4. To impart a certain counter force to the backward movement of.

In addition, a distance d is provided between the outer engaging jaw 15b of the intermediate cylinder 15 and the stopping jaw 1a of the outer cylinder 1, so that the maximum retraction distance of the intermediate cylinder 15 is the stopping jaw 1a. Regulated to

Inside the tip cap 2, a slider 16 is arranged to move in the axial direction. The slider 16 has a slider having a slider pipe 18 mounted in the center thereof, as shown in FIG. A main body 19 and a friction imparting member 20 mounted inside the slider body 19 to impart a predetermined friction pressure to the core 14 are provided.

And the slider 16 is pushed forward by the second spring 13, the rear end of which is caught by the receiving portion 21 fixed to the tip cap (2).

Here, the frictional imparting member 20 imparts a predetermined frictional force to the pen core 14 and is larger than the elastic force of the first spring 12 when performing the automatic pen core delivery operation described later. It is slightly larger than the elasticity. In addition, the friction applying portion 20a of the friction applying member 20 is formed in a sawtooth shape inclined toward the front direction as shown in FIG. 1 and FIG. 13, so that the forward lead 14 moves smoothly. However, the retracted lead 14 is formed such that it cannot be easily retracted by the frictional force.

Further, as shown in FIG. 1, as a means for stopping the slider 16 for a while, a projection 19b to be engaged with the inner wall annular projection 21a of the accommodation portion 21 is provided.

Here, the slit S is formed on the side surface of the slider body 19 as shown by the dotted line.

By the way, the distance f is the distance between the rear end of the slider 16 and the front barrel 9 in a state where the slider 16 does not retreat backward as shown in the drawing, which is described later. A distance corresponding to a handwriting transmission amount at the time of performing a handwriting transmission operation by the front end knock, which is the first means, and at the same time as the second hand of the automatic handwriting transmission operation. On the other hand, the distance g is the distance from the inner wall annular projection 21a to the front of the projection 19b, that is, the distance at which both are engaged.

However, there is a relationship of (a)> (d)> (g) between the distances a, d, and g.

Next, the heart-feeding operation of the present invention will be described. The pen core sending operation is made of the following three operations.

(1) The first means is a conventional means which is achieved by knocking the rear end of the lead pipe 3, that is, the sleeve 7 engaged with the front cylindrical portion 4 is subjected to the knock pipe according to the knock operation. (3) It moves forward with the lamp, but stops against the front end of the front barrel (9). However, the front cylindrical portion 4, which is integral with the lead pipe 3, is pushed forward and slides forward while sliding the inner wall of the sleeve 7, so that the rear end of the lead chuck 6 is pushed forward, and thus the normal lead Send operation.

(2) As the second means, when the writing is interrupted, the pen core sending operation is automatically performed, that is, the writing is usually performed in a predetermined amount from the slider pipe 18 by the pen core 14 as shown in FIG. (X) This is achieved in a state of protruding, and the writing 14 gradually wears out by writing, and coincides with the front end of the slider pipe 18 as shown in FIG. Even in this state, the slider 16 moves backward against the resilience force of the second spring 13 with respect to the rearward direction, which can be retracted to the retraction distance f shown in FIGS. 1 and 15 as much as possible. Will be.

However, the amount of wear of the pen lead 14 according to the writing requires a considerably long writing time to reach the retreat distance f. In particular, even with the pressure of a normal adult, the pencil is HB and a pencil diameter of 0.5 mm in diameter. The average amount of wear required when writing a single kanji on good paper is only about 0.01mm, so it is not usual to continue writing until the slider 16 retreats by the retreat distance (f). I think it will stop.

Thus, for example, when the writing is stopped in the state shown in FIG. 16, or the front end of the slider pipe 18 is removed from the ground, the slider 16 is advanced by the elastic force of the second spring 13, The pen core 14 is also pulled in the forward direction together with the slider 16 by a predetermined frictional force from the friction imparting member 20. On the other hand, since the chucking force of the lead chuck 6 holding the pen core 14 is given by the first spring 12 which is weaker than the second spring 13, the tension in the forward direction of the pen core 14 is explained. It is compressed to allow the entire chuck 6 to move forward.

When the head bowl 11 of the lead chuck 6 moves forward in contact with the rolled tapered inner wall 7g of the sleeve 7, the force of the lead chuck 6 is pushed forward. The pen core 14 is made to be weakened, and the pen core 14 is returned to the state shown in FIG. 15 again by the series of operations. Continuous writing up to the retreat distance f) is achieved.

(3) The third means is to push the front end of the slider 16 to the ground to send the lead in accordance with the end knock. There are two cases of the end knock as follows, and the operation is different. Each case will be described separately.

(A) The first end knock is made when the core 14 is not protruded from the front end of the slider pipe 18, as shown in FIG. 15, and the slider pipe 18 is knocked out by knocking the front end. Is a state of FIG. 14 (X = (f)) in which the pen core 14 protrudes by the length of the distance f. In other words, the lead chuck 6 is retracted while the lead chuck 6 is held by the tip knock, and the slider 16 is also backward. At this time, the amount of retraction of both is equal, and the maximum is shown in FIG. The retraction distance d is possible. In addition, the intermediate cylinder 15 is caught by the stop jaw 1a of the outer cylinder 1.

When the lead chuck 6 is retracted, the rear end of the lead chuck 6 is the front cylindrical part because there is a relationship (a)> (d) described above between the distances a and d shown in FIG. Except in the case of contacting (4), the state of the core 14 is always held. With the retraction of the lead chuck 6, the intermediate cylinder 15 and the front barrel 9 are moved backwards against the resilience of the third spring 17 via the inner and outer locking jaws 15a and 7j. Will move.

On the other hand, when the slider 16 is retracted, the distance (a), (d), and (g) has a relationship of (a)> (d)> (g), so the maximum retraction distance (d) In the process of retreating, the projection 19b of the slider body 19 first passes over the inner wall-shaped protrusion 21a of the accommodation portion 21, and the rear end of the slider body 19 is shown in FIG. As will be protruded to the rear end of the receiving portion (21).

Here, the distance f is maintained between the rear end of the slider main body 19 and the front cylinder 9 in the state of FIG. 1 and FIG.

Next, when the slider 16 is removed from the ground holding the slider 16, the pen core sending mechanism 5 and the intermediate cylinder 15, such as the sleeve 7 and the lead chuck 6, are mainly the elastic force of the third spring 17. By the front barrel (9) is to advance until it comes in contact with the stepped portion (2a) of the tip cap (2), in this way, the lead chuck (6) to keep the core 14 in the state of biting do.

On the other hand, the slider 16 is advanced by the elastic force of the second spring 13, but is temporarily stopped by the projection 19b of the slider body 19 engaged with the inner wall annular projection 21a as shown in FIG. Will be done. Even if the slider 16 is paused, as described above, the pen delivery mechanism 5 has been advanced in the state of holding the pen core 14, so that the front barrel 9 is located at the rear of the slider body 19. The tip 14 is advanced relative to the slider 16 until the end is abutted and the pause is released. The amount of advancement at this time is equal to the distance f.

Accordingly, the first tip knock is in the state of FIG. 15 (X = (f)), and the lead 14 is protruded from the front end of the slider pipe 18 by the length f.

거리(d)-거리(g)가 되는 경우에는 항상 슬라이더파이프(18)로부터(f)의 길이만큼 필심이 돌출되어져 있게된다. 여기서 이해를 돕기위해 일예로 구체적인 수치를 대입하여 설명하기로 한다. 예를들어(f)=0.8mm, (g)=1.3mm, (d)=1.7mm, X=0.3mm (<(d)-(g)=0.4mm)로 하고, 이 상태에서 선단을 노크하면 먼저 후퇴거리 X까지는 필심송출기구(5)및 중간통체(15)만이 필심(14)과 함께 후퇴하게되고, 그후에는 첫번째 선단노크때와 마찬가지로 필심송출기구(5), 중간통체(15)와 함께 슬라이더(16)가 후퇴하게 된다. 따라서 리이드척(6)은 슬라이더(16)에 대하여 그 후퇴량이 X=0.3mm 커지게 되는 것이다. 그런데 슬라이더(16)의 후퇴가능 거리는 정지턱(1a)에 후퇴량을 규제받게 되는 중간통체(15)에 의해 나머지(d)-(g)=1.7mm-1.3mm=0.4mm 밖에 후퇴할 수가 없게 된다.(B) The second end knock is the case where the lead 14 is protruded from the front end of the slider pipe 18, as shown in FIG. 14. In this case, the protrusion amount X and the distance d X between distances (g)

In the case of the distance d-distance g, the pen core is always protruded by the length of the slider pipe 18 f. For the sake of clarity, specific values will be substituted as an example. For example, (f) = 0.8 mm, (g) = 1.3 mm, (d) = 1.7 mm, X = 0.3 mm (<(d)-(g) = 0.4 mm), and the tip is knocked in this state. First, only the pen delivery mechanism (5) and the intermediate cylinder (15) retreat together with the pen core (14) until the retraction distance X. Then, the pen delivery mechanism (5) and the intermediate cylinder (15) and the like are retracted after the first tip knock. Together, the slider 16 is retracted. Therefore, the retraction amount of the lead chuck 6 with respect to the slider 16 becomes X = 0.3 mm larger. By the way, the retractable distance of the slider 16 can only be retracted by the remaining cylinder (d)-(g) = 1.7mm-1.3mm = 0.4mm by the intermediate cylinder 15 which is regulated by the stopping jaw 1a. do.

Then, in the retreat process, the inner wall annular protrusion 21a of the accommodating part 21 is crossed over.

Then, when the slider 16 is pushed away from the ground, the pen delivery mechanism 5 moves forward with the pen core 14 in the same state as in the first tip knock described above.

On the other hand, the slider 16 is paused by the inner wall annular projection 21a holding the projection 19b, and after that, the lead 14 is formed in the same shape as when the first tip is knocked. It is projected by the length of (f) from the end.

On the other hand, in the case of X> (d)-(g) = 0.4mm, the slider 16 hangs on the inner wall annular projection 21a by the intermediate cylinder 15 whose rear end is attached to the stop jaw 1a. Since it is not retracted until it fits, the slider 16 is caught by the projection 21a of the accommodating portion 21 so that the pause state does not occur. do. As a result, no matter how much the knock is to the end, only the end knock without repeating the lead is repeated, so that the lead 14 is always protruding in the state of the unchanged protrusion amount X.

As described above, according to the present invention, the lead chuck is fastened to the sleeve, and the slide intermediate cylinder is pushed forward, and the slider is moved to the front cylinder for a predetermined time so that the inside The structure can be simplified, and the pen core feeding operation is also carried out in three ways, and the pen core sending operation by the end knock is not always protruded but also a certain amount even if it overprotrudes more than a predetermined amount. As long as the lead is protruding.

Claims (1)

The pen core pipe (3) housed in the outer cylinder (1) for sliding reciprocating movement, and is arranged on the front end of the pen core pipe (3) to allow the advance of the pen core (14), but to prevent the retraction Lead chuck 6, a sleeve 7 fitted to the outside of the front portion of the lead chuck 6, the first spring for chucking elastically installed between the sleeve 7 and the lead chuck 6 12, a buffered third spring 17, which pushes the sleeve 7 in the forward direction, is arranged to slide reciprocally to the front end of the lead chuck 6, and the first spring 12 A sharp pencil having a slider 16 pushed forward by a second spring 13 having a large modulus of elasticity and a front barrel 9 mounted on the intermediate cylinder 15.

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