EP0533676B1 - Writing unit for a cartridge fountain pen - Google Patents

Abstract

The invention concerns a writing unit for a cartridge fountain pen, with a nib (1), a gripping-piece (2) and an ink-feed unit (3). The ink-feed unit (3) has lamella-like ink-holding chambers (3e). A capillary channel (3a) passes longitudinally along the whole length of the ink-feed unit (3) on the nib side of the ink-feed unit (3). An air channel (3c) extends out radially from the capillary channel (3a). So that ink does not drip out of the slit in the nib, particularly when the ambient temperature varies considerably, and to ensure that the ink-feed unit is suitable for broad-lettered writing, the writing unit is designed so that the air channel (3c) extends longitudinally over the whole length of the ink-holding chambers (3e) up to a control line (3g) which is formed at the end of the chambers (3e) nearest the nib (1) and which acts as a liquid valve. The air channel (3c) is delimited in the radial direction by a surface opposite the capillary channel (3a), and the air channel (3c) extends, on the side opposite the capillary channel (3a), up to overflow capillaries (3d) linked to the ink-holding chambers (3e) so that liquid can flow between the two.

Description

The invention relates to a writing unit for a cartridge fountain pen, in particular a writing unit for a cartridge fountain pen with a nib, a handle and an ink feeder, the ink feeder having lamella-like collecting chambers, the side of the ink feeder facing the nib extending over the entire length of the ink feeder from one Capillary longitudinal gap is drawn through and an air channel extends from the longitudinal gap in the radial direction to the outside.

Cartridge fountain pens with writing units of the type in question have been known for decades, see e.g. DE-B 1 230 331. Cartridges filled by the manufacturer and sealed with a ball are pierced for use by means of a push-through pin of the writing unit, the ball serving to close the cartridge being pressed into the interior of the cartridge to pierce the cartridge. Even after decades of introducing the cartridge fountain pen in question, writing a new or cleaned cartridge fountain pen is still extremely problematic. On the one hand, it takes minutes for the conventional writing units or the ink guide systems used there, and therefore too long, until the ink reaches the nib after the cartridge is pierced and all the capillaries important for proper functioning are filled with ink.

On the other hand, there is a risk of ink leakage after the piercing, since the capillary longitudinal gap of the ink guidance system is filled with ink immediately after the piercing, i.e. supplies the spring with ink, but the control path that is important for regulating the ink flow and serves as a liquid valve is not filled with ink, causing air can constantly flow into the cartridge and thus ink reaches the nib unregulated or undosed. The ink drips from the pen when the cartridge fountain pen is placed in a desk stand after piercing or placed in a box for shipping.

To remedy the above-mentioned problems, leading manufacturers of cartridge fountain pens have so far offered that they have already fitted their fountain pens with cartridges at the factory and thus the cartridge fountain pens are sold to specialist retailers. The long-lasting writing process is often abbreviated by the manufacturer by treating the cartridge fountain pen with the pierced cartridge in a centrifuge. This takes the time-consuming piercing of the cartridge and the letter from the fountain pen away from the dealer, but the risk of leakage is particularly great when the transport is not usually vibration-free.

In particular, when choosing the air transport path, pressure and temperature differences that occur, in particular when the ink feeder is designed for large font widths, lead to the inevitable escape of ink due to expanding ink or air, which can cause considerable damage.

Finally, the previously known writing units are problematic in particular when using an ink feeder for large font widths insofar as they offer little protection against blobs with a high ink throughput.

The invention is therefore based on the object of designing and developing the writing unit for cartridge fountain pens of the type mentioned at the outset such that, in particular, in the case of ink feeders dimensioned for large font widths Dripping or leakage of the ink after piercing the cartridge is prevented and the work process is accelerated, on the other hand blotches are largely prevented in the event of pressure and temperature fluctuations.

The writing unit according to the invention achieves the above object by means of the features of patent claim 1. The air duct then extends in the longitudinal direction over the entire area of the collecting chambers up to a control section which is designed at the end of the collecting chambers facing the writing pen and serves as a liquid valve. The air duct is delimited in the radial direction by a surface opposite the longitudinal gap. Furthermore, the air duct on the side opposite the longitudinal gap extends to the overflow capillary that connects the flow chambers with the flow chamber.

According to the invention it was first recognized that the problem of dripping after piercing a cartridge is caused by the fact that the capillary longitudinal gap is filled with ink immediately after the cartridge has been pierced, but that the air channel is only gradually filled with ink. Consequently, immediately after the cartridge has been pierced, neither the control section nor the overflow capillary are filled with ink, so that air can flow into the cartridge through the control section which is not yet filled or not yet closed, which in turn causes more or too much ink - uncontrolled - to Pen arrives and drips there.

Furthermore, it has been recognized that sufficient space must be created in which the ink can escape due to temperature fluctuations when the air expands, corresponding flow paths having to be specified.

Furthermore, it has been recognized according to the invention that rapid filling of the controlled system with ink by manipulation of the air duct is possible.

According to the invention, it was finally achieved by combining various features relating to the design of the ink feed that the controlled system fills with ink as quickly as possible. If underpressure arises during writing, the controlled system empties, ie tears open, and allows air to flow through the air duct to the cartridge. The controlled system is then closed again by the ink flowing in as long as there is no longer a negative pressure, that is to say no more ink is removed.

According to the invention, the collecting chambers take over the expanding air or the ink located in the ink feeder. As a result, in the event of air expansion, for example due to temperature fluctuations, the ink is not pressed out of the ink feeder towards the spring, but instead passes through the overflow capillary into the collecting chambers, which are only connected to one another via the overflow capillary and on the other hand to the longitudinal gap or the air duct.

Consequently, the measures according to the invention on the one hand prevent ink from dripping, in particular when the ink feeder is designed for large font widths and thus for a considerable ink delivery volume.

Furthermore, it is advantageous if a separate overflow capillary is provided for each collecting chamber. The collecting chambers are connected to one another on the one hand only via the overflow capillary, on the other hand to the longitudinal gap or the air duct. Such an embodiment of the ink feeder has the consequence that even with dimensioning of the capillary longitudinal gap for realizing large font widths, ie when realizing a large ink throughput, the ink in the ink feeder is not then pushed out of the ink feeder when the gas in the ink feeder or the air there expands due to temperature fluctuations. This is because the ink reaches the collecting chambers, which then serve as ink stores, via defined flow paths, which in this case have the function of a buffer.

Since the collecting chambers compensate for the expansion of the air due to temperature fluctuations, the above features ensure reliable control of the ink, which prevents leakage and in particular also increases the resistance to shaking. Significant insensitivity to temperature fluctuations is guaranteed.

With regard to rapid filling of the air duct with ink - if possible immediately after the cartridge has been pierced - it is of further advantage if the air duct widens with stair-shaped walls up to the side opposite the longitudinal gap. The ink fills the air channel from the capillary longitudinal gap from level to level, whereby the air channel is quickly filled with ink as a whole with sufficient wetting behavior between the ink feeder and the ink. So the ink quickly gets into the overflow capillary and finally into the controlled system.

It is also possible that the air duct with wavy walls extends up to the side opposite the longitudinal gap, with sharp edges as "obstacles" for the spreading of the ink being avoided in comparison with the above-mentioned configuration and the refilling process thereby being repeated accelerates.

According to a further advantageous embodiment, the air duct is expanded with concave or convex walls up to the side opposite the longitudinal gap. Here too, the air duct is quickly filled with ink. It would also be possible that the side of the air duct opposite the longitudinal gap is delimited by a likewise concave or convex wall. Finally, it is particularly advantageous both in terms of a short filling time of the air duct and in terms of a simple constructional or manufacturing design of the air duct if the air duct expands up to the surface opposite the longitudinal gap in such a way that the air duct has a triangular cross section. The triangular cross section of the air duct could either have the shape of an isosceles triangle or the shape of an equilateral triangle.

Fig. 1

in schematischer Darstellung, geschnitten, eine erfindungsgemäße Schreibeinheit für einen Patronenfüllhalter in Seitenansicht,

Fig. 2

in schematischer Darstellung, geschnitten, den Gegenstand aus Fig. 1 in Draufsicht,

Fig. 3

in schematischer Darstellung, vergrößert und ausschnittsweise den Gegenstand aus Fig. 2 im Schnitt entlang der Linie A-B,

Fig. 4

in schematischer Darstellung, vergrößert und ausschnittsweise den Gegenstand aus Fig. 2 im Schnitt entlang der Linie C-D und

Fig. 5

in schematischer Darstellung, vergrößert und ausschnittsweise den Gegenstand aus Fig. 2 im Schnitt entlang der Linie E-F.

There are now various possibilities for designing and developing the teaching of the present invention in an advantageous manner. For this purpose, reference is made on the one hand to the claims subordinate to patent claim 1, and on the other hand to the following explanation of an embodiment of the invention with reference to the drawing. In connection with the explanation of the preferred embodiment of the invention with reference to the drawing, preferred configurations and developments of the teaching are also explained in general. In the drawing shows

Fig. 1

in a schematic representation, sectioned, a writing unit according to the invention for a cartridge fountain pen in side view,

Fig. 2

in a schematic representation, sectioned, the object from FIG. 1 in plan view,

Fig. 3

in a schematic representation, enlarged and in sections, the object from FIG. 2 in section along the line AB,

Fig. 4

in a schematic representation, enlarged and excerpted the object of Fig. 2 in section along the line CD and

Fig. 5

in a schematic representation, enlarged and excerpted the object from FIG. 2 in section along the line EF.

1 and 2 together show an embodiment of a writing unit according to the invention for a cartridge fountain pen. This writing unit, which is only shown here by way of example, has as essential components a pen 1, a handle 2 and an ink feeder 3.

The ink feeder 3 has lamella-like collecting chambers 3e, the side of the ink feeder 3 facing the pen 1 being traversed by a capillary longitudinal gap 3a over the entire length of the ink feeder. The longitudinal gap 3a merges with the outside in the entire area of the collecting chambers 3e into an air channel 3c, which takes up a substantially larger cross-sectional area than the longitudinal gap 3a. The side of the air duct 3c opposite the longitudinal gap 3a extends to the overflow capillary 3d connecting the collecting chambers 3e. In the longitudinal direction, the air duct 3c extends to a control section 3g provided at the spring-side end of the collecting chambers 3e.

According to the invention, the air duct 3c extends in the longitudinal direction over the entire area of the collecting chambers 3e up to a control section 3g formed at the end of the collecting chambers 3e facing the pen and serving as a liquid valve. In the radial direction, the air duct 3c is delimited by a surface opposite the longitudinal gap 3a. The air duct 3c extends on the side opposite the longitudinal gap 3a to an overflow capillary 3d which connects the collecting chambers 3e with flow.

Overall, the figures show that the collecting chambers 3e are connected to one another and to the air channel 3c or the longitudinal gap 3a only via the overflow capillary 3d. Ink and air therefore only get into the collecting chambers or out of the collecting chambers 3e via the overflow capillary 3d.

3, 4 and 5 show particularly clearly that the air duct 3c extends up to the surface opposite the longitudinal gap in such a way that the air duct 3c has a triangular cross section. The triangular cross section of the air duct 3c in the preferred embodiment here has the shape of an isosceles triangle.

1 and 2 show, in addition to the essential features of the present invention discussed above, that the nib 1 has a nib 1a and a nib 1b. The handle 2 has a bore 2a, a recess 2b, a flat stop 2c, a stepped bore 2d, a shoulder 2e, a piercing pin 2f with a rear end 2g and a flange 2h.

The ink feeder 3, which has the capillary gap 3a and the air channel 3c, also includes a stop 3b for the nib 1, the overflow capillary 3d, via the overflow capillary 3d with the air channel 3c or. the capillary gap 3a flow-connected collecting chambers 3e, slats 3f delimiting the collecting chambers 3e, a control section 3g serving as a liquid valve, a transverse rib 3h, a pin 3i and a flange 3k. Furthermore, air grooves 4, 4b and a transverse groove 4a can be seen.

3 clearly shows the handle 2, the ink feeder 3 and the capillary longitudinal gap 3a. As already stated, the air duct 3c is designed in a triangular shape. Furthermore, the lamellae 3f, overflow capillary 3d, the controlled system 3g, the air groove 4 and the air grooves 4c can be seen from the illustration in question.

FIG. 4 shows the object from FIGS. 1 and 2 in a cross section that is placed differently than in FIG. 3, namely along the line C-D. Here too, the handle 2, the ink feeder 3 and a lamella 3f can be seen. Furthermore, this illustration shows the position or configuration of the capillary gap 3a, the air duct 3c which is triangular in cross section, the air groove 4 and the air grooves 4c.

Finally, FIG. 5 again shows the object from FIGS. 1 and 2 in section along the line E-F. Here the handle 2 with the piercing pin 2f and the pin 3i on the ink feeder 3 can be clearly seen. Furthermore, the capillary longitudinal gap 3a in the pin 3i on the ink feeder 3 is shown.

The mode of operation of a writing unit according to the invention is explained below with reference to the figures discussed above.

In conventional writing units, when the cartridge is pierced, the ink always flows first into the capillary longitudinal gap due to the capillary action and from there to the nib. Only through a backflow from the nib - namely through a backflow in the capillary longitudinal gap - the controlled system, the air duct and the overflow capillary are gradually filled with ink, so that a further inflow of air into the cartridge and thus an outflow of the ink from the cartridge is prevented.

This process usually takes a few minutes and leads to undesired dripping of ink from the nib, especially if the fountain pen is placed immediately after the cartridge has been pierced with the nib down in a designated case or the like in a desk stand. Even when the air in the writing unit expands, there is a drip due to the ink displaced by the expanded air.

In contrast, the following occurs in the writing unit according to the invention: when the cartridge, not shown in the figures, is pierced, the sealing ball of the cartridge is pushed into the cartridge from the front end of the cartridge with the piercing pin 2f on the handle 2 and thereby opened. The ink can thus flow into the ink supply system. The ball volume and the piercing pin 2f cause a compression of the air inside the cartridge, which favors the writing of the writing instrument. The inventive design of the ink feeder 3 ensures that not only the capillary gap 3a, which supplies the pen 1 with ink, but also the two triangular tips of the air channel 3c are almost simultaneously filled with ink due to their capillary action. The ink flowing out of the cartridge fills the capillary-acting corners of the triangle of the air duct almost simultaneously with the capillary longitudinal gap 3a - in both cases by capillary action.

According to the invention, the overflow capillary 3d on the ink feeder 3 and the control path 3g are filled with ink and closed in time so that the ink can no longer flow when it has arrived in the nib 1b due to capillary action. This is because the air can no longer flow into the cartridge through the ink path 3g, which ultimately prevents ink from dripping.

The collecting chambers 3e also serve to receive ink in the event of air expansion in the capillary longitudinal gap 3a or in the air duct 3c and thus compensate for air expansion in the writing instrument caused by temperature fluctuations. This effectively prevents ink from dripping. This measure, based on the connection between the collecting chambers 3e with the capillary longitudinal gap 3a or the air duct 3c, exclusively via individual overflow capillaries 3d, provides this protection against temperature fluctuations, but also a certain resistance to shaking, in particular with ink feeders 3, which are suitable for font widths of up to 2.7 mm are designed approximately.

In conclusion, it should be pointed out that the essence of the present invention - prevention of unwanted dripping in a writing unit even in the course of temperature fluctuations - can also be implemented in other writing instruments which have a previously described or similar writing unit by a special design of the ink feeder.

Claims (9)

1. Writing unit for a cartridge fountain pen, having a nib (1), a gripping part (2) and an ink feed device (3), the ink feed device (3) comprising blade-like collector chambers (3e), the side of the ink feed device (3) facing the nib (1) being penetrated over the entire length of the ink feed device (3) by a capillary longitudinal gap (3a), and an air duct (3c) widening radially outwards from the longitudinal gap (3a), characterised in that the air duct (3c) extends over the entire area of the collector chambers (3e) to a regulating segment (3g) and radially to the surface lying opposite the longitudinal gap (3a), and in that the air duct (3c), on the side opposite the longitudinal gap (3a), extends as far as an overflow capillary (3d) connected to the collector chambers (3e).
2. Writing unit according to Claim 1, characterised in that one overflow capillary (3d) is provided for each collector chamber (3e), and in that the collector chambers (3e) are connected for flow exclusively via the overflow capillaries (3d) firstly to one another and secondly to the longitudinal gap (3a) or to the air duct (3c).
3. Writing unit according to Claim 1 or Claim 2, characterised in that the air duct (3c) widens with step-like walls to the side opposite the longitudinal gap (3a).
4. Writing unit according to Claim 1 or Claim 2, characterised in that the air duct (3c) extends with undulating walls to the side opposite the longitudinal gap (3a).
5. Writing unit according to Claim 1 or Claim 2, characterised in that the air duct (3c) widens with concave or convex walls to the side opposite the longitudinal gap (3a).
6. Writing unit according to Claim 5, characterised in that the side of the air duct (3c) opposite the longitudinal gap (3a) is delimited by a concave or convex wall.
7. Writing unit according to Claim 1 or Claim 2, characterised in that the air duct (3c) widens as far as the surface opposite the longitudinal gap (3a) in such a way that the air duct (3c) has a triangular cross-section.
8. Writing unit according to Claim 7, characterised in that the triangular cross-section of the air duct (3c) is in the shape of an isosceles triangle.
9. Writing unit according to Claim 7, characterised in that the triangular cross-section of the air duct (3c) is in the form of an equilateral triangle.

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