DE4242272A1 - Propelling pencil with damping spring - has rotatable inner tube with oblique end face to drive lead forward - Google Patents

Abstract

The propelling pencil has a front outer tube and a rear outer tube which can rotate relative to the front outer tube. The pencil also has a sleeve (11) which can slide axially in the outer tubes (1, 2) and which has an attached chuck (6) to grip the lead. The sleeve (11) has a shoulder which abuts against the oblique end face of a tube (13) which can be rotated by means of the rear outer tube (2) in order to actuate the chuck (6). A spring (14) acts on the sleeve and pressed the lead in the axial direction. This spring also serves as a damping element for the lead propelling mechanism. ADVANTAGE - The damping spring reduces the risk of breaking the lead when a high pressure is applied to the pencil.

Description

The invention relates to a damping device for a mechanical pen that allows a suitable one Damping effect or spring support during the To stop writing.

There are already various mechanical pressure pens with a damping effect has been proposed in which the lead retracts into the writing instrument, when it is subjected to high writing pressure. So far, however, no mechanical pin has been proposed gene, which is provided with a damping device,  which is capable of an engagement position for a Dependent in response to writing pressure from the writing conditions from a solid state a mine.

In the case of a conventional, normal, mechanical Pen is in a writing state in which a mine by pushing from an outer end of the pen protrudes, this fixes, and especially when a high writing pressure is exerted, the mine is vulnerable for breaks as a damping device is not provided hen is. When drawing or the like, when a mine is pushed out to a long line in one The mine is particularly susceptible to drawing Breaks.

In the case of the mechanical pin mentioned above with a dampening effect can be of the order of magnitude No damping or spring support in relation to the mine can be set. That is why when words and sentences be written, or when the writing pressure through a change in the material of the paper surface violently varies, the mine very often from the above Posi tion retracted into the outer tube to start writing to interrupt.

This invention is proposed to the above Overcome problem. An object of this invention is it, a damping device or spring bearing for specify a mechanical pen, at which if high pressure on the mine is possible is to adjust the damping effect, which changes with the current writing conditions, the hardness and the Properties of the lead, the quality of the paper and  similar covers so that the mine does not break, and if damping is not absolutely necessary Withdrawal of the mine can be stopped.

According to a defi in claim 1 of this invention nated damping device or spring bearing for a mechanical pin is opposed to an engaging part an oblique cam in a front outer tube a socket inserted.

According to one defined in claim 2 of this invention Damping device for a mechanical pin, on a front outer tube and opposite one Cam for guiding a shoulder of a bushing into a desired position, an engagement part in a socket molded.

According to a damping device defined in claim 3 For an mechanical pen, an eraser is closed Guiding device at the rear end of the mine tube intended.

The damping device for mechanical pens according to claims 1 and 2 of this invention the damping effect can be adjusted by a required gap or engagement between the one handle part and the cam.

In a damping device for a mechanical Pen according to claim 3 can be supplied to an eraser and be withdrawn.

According to claims 1 and 2 of the invention the gap between the engagement part and the cam  can be adjusted by rotating the front and the rear outer tube to the amount of damping effect very easy to adjust.

Furthermore, according to claim 3, the feed and Withdrawal operation for an eraser in addition to that previously mentioned effect can be performed.

Fig. 1 is a sectional view showing a first embodiment of the invention.

FIG. 2 is a sectional view of a front outer tube shown in FIG. 1.

FIG. 3 is a top view of a bushing shown in FIG. 1.

Fig. 4 is a sectional view of a second embodiment of the invention and shows the state of the maximum damping effect.

Fig. 5 is a sectional view of a second imple mentation form and shows the state of the minimum damping effect.

FIG. 6 is a sectional view taken along the line AA in FIG. 5.

A first embodiment will be described in connection with claim 1 of this invention with reference to the drawings. In Fig. 1, reference numeral 1 denotes a front outer tube and the loading reference symbol 2 denotes a rear outer tube which is mutually rotatably connected to the front outer tube 1 by a fitting piece. 3 A front part 4 is secured at the outer end of the front outer tube 1 by an engagement part 5 .

The reference numeral 6 denotes a mine feed device and a mine chuck 7 is axially slidably mounted. A chuck-clamping ring 8 is arranged at the end of the mines äuße ren chuck 7 to close a chuck portion 7a at the outer end of the lead Spannfut ters. 7

Reference numeral 9 designates an arranged between a lead tube 10 and a bush 11 elastic chuck closing element.

A cam tube 13 with an oblique cam 12 is fastened to the rear part of the front outer tube 1 , as shown in FIGS. 1 and 2. In this embodiment, since the cam tube 13 is formed separately from the front outer tube 1 , it should be noted that these can be integrally formed if necessary. The oblique cam 12 has a shape that the cam tube 13 is given an oblique shape.

The socket 11 is axially slidably and rotatably mounted in the outer tubes 1 and 2 and has a protruding engaging part 11 a, which is opposite the oblique cam 12 and a shoulder 11 b in engagement with a groove 2 a of the rear outer tube 2 , as shown in Figs. 1 and 3. Accordingly, the socket 11 is automatically rotated by the approach 11 b when turning the rear outer tube 2 .

A gap (a) between the engaging part 11 a and the oblique cam 12 (a smallest part 12 a of the oblique cam 12 ) of the cam tube 13 causes the damping effect of the bushing 11 . Fig. 1 shows the state, maximum damping, in which the damping effect is maximum.

This is the case when the rear outer tube 2 is rotated relative to the front outer tube 1 , the bushing 11 rotates accordingly and the gap (a) changes from maximum damping effect to minimal damping effect (= 0) (the state in which the engaging part 11 a comes into contact with the longest part 12 b of the oblique Nok kens 12 ) in Fig. 1st

Numeral 14 denotes a damping elastic member for driving the bush 11 .

The lead tube 10 is axially slidably mounted in the outer tubes 1 and 2 , and an eraser feeder 15 is disposed on the rear part.

The eraser feeder 15 has, as shown in Fig. 1, a fitting 15 a, which is removably arranged on the lead tube 10 and is stopped by the groove 2 a of the rear outer tube 2 , a clutch 15 b, which on the fitting 15 a is stopped, a Ra decoder guide pipe 15 c, which rotatably lung with the Kupp is connected 15 b, a helical groove 15 d, which is formed in the inner wall of the eraser guide tube 15 c, and a movable tube 15 f in a handle with the spiral groove 15 d, to which a radius rer 15 e is attached.

The eraser 15 e is pushed out and retracted by rotating the rear end of the guide tube 15 c relative to the rear outer tube 2 . This rotation causes the rotatable tube 15 f to move along the spiral groove 15 d, whereby the eraser 15 e can be advanced. If it is rotated backwards, the eraser 15 e can be pulled back.

If the outer tubes 1 and 2 are rotated further by 180 ° or rotated back by 180 °, they return to their initial state shown in FIG. 1.

In this embodiment, the setting of the damping effect is not caused by the possible compression of the elastic, damping part 14 , but by the distance of the gap (a). As a result, a useless compression force is not exerted on the elastic element 14 , which results in protection and an error in the manufacture of the elastic element can be permitted to a certain extent.

Next is the assembly of the elastic pin described.

First, the elastic damping member 14 is placed around the lead pipe 10 mounted on the lead feeder 6 ; then it is mounted on the front in the outer tubes 1 and 2 , comprising the front outer tube 1 and the rear outer tube 2 , the through hole 18 and the groove 2 a are advantageously constantly connected to one another, while the spatial relationships between the Approach 11 b and the groove 2 a can be considered. Thereafter, the eraser-to guide device 15 is mounted on the rear end of the mine tube 10 and the assembly is complete.

As described above, the assembly can be carried out simply as long as the engagement part 11 a provided in the socket 11 can be dropped into the outer tubes 1 and 2 for adjusting the damping effect.

Next, the handling will be described.  

The normal mine feed operation is carried out by pressing the guide tube 15 c of the eraser feed direction 15 . Be the front outer tube 1 and the rear tube 2 is rotated relative to each other, the bush 11 is assembled with the rear outer tube 2 by the shoulder 11 of the bushing 11 b rotated. With the rotation of the bush 180 °, the damping effect of changes of the gap (a) from the maximum (a) (the state in Fig. 1) for a minimum of 0 (the state in which the engagement portion 11 a in contact with the longest part 12 b of the oblique cam 12 comes).

Accordingly, in the case where high writing pressure is exerted on the lead 16 , the entire lead feed direction 6 and the lead tube 10 , the bushing is moved from the maximum (a) to the minimum 0 (in this case no damping occurs) . The breaking of the lead caused by the high writing pressure can be prevented and the damping effect can be freely set depending on the writing conditions, the hardness of the lead 16 , etc.

The eraser feeder is mounted rearward on the rear outer tube 2 . Accordingly, the assembly steps can be carried out extremely simply and quickly. In addition, the number of parts is small.

Fig. 4 shows a second embodiment in connection with claim 2.

The second embodiment differs from the first embodiment only in that the construction for adjusting the damping effect, that is, the construction of a bushing 11 and the construction of the front outer tube are different. Although not illustrated, the construction of the parts at the rear portion of the sleeve 11 form exactly the same in the second execution as the first execution form, wherein an elastic damping element 14 and another in the rear part of the lug 11 of the socket b 11 available are.

Due to this difference in construction between them, the mine feed device 6 is mounted in the outer tubes 1 and 2 regardless of the spatial relationships between the approach 11 b and the groove 2 a and at the same time the approach 11 b is of course by the cam 17 positively guided into the groove 2 a of the rear outer tube 2 .

For this purpose, the bushing 11 is provided with a damping element 11 c for compensating an error in the manufacturing is provided and has a curved engagement portion 11 a on. In the engaging part: 11 a, an oblique part 11 aa is provided for a damping effect.

A pair of inclined parts 11 aa are integrally formed on the engagement part 11 a offset by 180 °.

On the other hand, the front outer tube 1 is provided on its inner wall with a pair of cams 17 which guide the shoulder 11 b and form a damping effect at the gap (a) with reference to the engagement part 11 a.

For this purpose, a pair of cams 17 is curved to guide the projection 11 b to the through hole 18 , as shown in Figure 6 ; the through hole 18 is connected to the groove 2 a of the rear outer tube 2 .

The handling is described below.

If the front outer tube 1 and the rear outer tube 2 are rotated relative to one another, the socket 11 rotates together with the rear outer tube 2 via the set 11 b of the socket 11 and the groove 2 a of the rear outer tube 2 .

The inclined part 11 aa of the engagement part 11 a moves toward the outer end of the cam 17 , as shown in Fig. 4 by the arrow (b). As a result, the gap (a) between the inclined part 11 aa and the outer end 17 a of the cam 17 changes , that is the damping effect from the maximum (a) (the state in FIG. 4) to the minimum 0 (the state at which the sloping part 11 aa comes into contact with the outer end 17 a).

Accordingly, when the high writing pressure is applied to the lead 16 , the entire lead feeder 6, such as the lead tube 10 , the bushing 11 , etc., is moved backward into the outer tubes 1 and 2 from the maximum (a) to the minimum 0 (in this case there is no damping). As a result, the refraction of the lead 16 caused by high writing pressure can be prevented and the damping effect can be freely set depending on the writing conditions, the hardness of the lead, etc.

Especially in this embodiment, the adjustability of the damping effect is not caused by the possible compression of the elastic, damping part 14 but by the distance of the gap (a). Accordingly, a useless compressive force is not applied to the elastic member 14 , and as a result, its protection is achieved, and a failure in manufacturing an elastic member can be allowed to a certain extent.

Next is the assembly of the mechanical pin described.

First, the elastic damping member 14 is inserted into the lead tube 10 mounted on the lead feeder 6 , and then inserted from the front into the outer tubes 1 and 2 and encompassed by the front outer tube 1 and the rear outer tube 2 , with the through hole 18 and the groove 2 a are preferably continuously connected to each other. At the same time, the approach 11 b of the socket 11 is guided by the cam 17 and posi tively through the through hole 18 to the groove 2 a of the rear ren outer tube 2 out. The assembly is extremely simple and advantageous.

Subsequently, the eraser feeder 15 is mounted on the rear end of the mine tube 10 , and the assembly is completed.

Claims (3)

1. Damping device for a mechanical pin, characterized by a front outer tube ( 1 ) which has an oblique cam ( 12 ), a rear outer tube ( 2 ) which is rotatably connected to the front outer tube ( 1 ), a sleeve ( 11 ) which is slidably received in the front and rear outer tubes ( 1 ), ( 2 ) and rotated together with the rear outer tube ( 2 ) and forms part of a mine feed device ( 6 ), an engaging part ( 11 a), which rises from the bushing ( 1 ) and is spaced apart from the oblique cam ( 12 ), and an elastic damping element ( 14 ) for driving the bushing ( 11 ) forward. 2. Damping device for a mechanical pin, characterized by a front outer tube ( 1 ) which has a cam ( 17 ) which engages as a guide element in a through hole ( 18 ), a rear outer tube ( 2 ) which rotates with the first outer tube ( 1 ), a socket ( 11 ) which is slidably received in the front and rear outer tubes ( 1 ), ( 2 ) and rotated together with the rear outer tube ( 2 ) and part of a mine Feeding device ( 6 ), an engagement part ( 11 a) formed in the bushing ( 11 ), which is arranged at a distance from the oblique cam ( 17 ), forms an extension ( 11 b) which through the cam ( 17 ) into the through hole ( 18 ) and the bushing ( 119 ) is positioned, and by an elastic damping element ( 14 ) for driving the bushing ( 11 ) forward. 3. Damping device for a mechanical pin according to claim 1 or 2, characterized by a Radie rer feed device ( 15 ) which is arranged on a lead tube ( 10 ) which forms part of the lead feed device ( 6 ).