Fountain Pen Design

Function, Development, Construction and Fabrication

052-7-1 1934 — Marukin Eyedropper

Most noticeable is the lack of fins of the overflow slits.  To prevent overflow, the fountain pen has a hand operated shut off valve.


The feed is completely machined from Ebonite as you can clearly see in photo 3 where machine marks are visible.  In the following, I address the areas marked with red letters in photo 1.


photo 1 — Marukin Eyedropper – 1934

At A the feed is in contact with the nib, and three capillaries are ending there. A detailed photo is following.  The capillaries arrived there through being cut along the bottom of the air-canal, which is at the top of the feed.

In this case, the breather-hole serves its intended purpose.  Many feeds have their air-canal at the bottom, for reasons I have talked about in the chapter Application to the Feed.  The nibs attached to them still have a “breather” hole.  About the “breather” hole’s other purpose I have written in the chapter Nib Manufacturing.

B shows one of the hollowed out sections, which most probably are intended to absorb surplus ink.  I wonder because there is no actual capillary to assist emptying these chambers.  It could be caused by a tolerance gap between the nib radius and the feed.

At C is a chamfered away section, it allows the air to penetrate from the air-canal into the ink reservoir.

The stub at D sticks into the hole at the end of the section, which opens into the ink reservoir.  It contains two ink capillaries, it is slightly flattened on top, and the larger flattening at the side runs out at C serving as the air inlet into the tank.

Front End


photo 2 — Marukin 1934 – front end

Photo 2 shows the front end at Aphoto 1.  At A1 you see the arrival of the two ink capillaries.  At A2 is a narrow cut, which marks the centre of the feed, used to align the nib with the feed.  At A3 is a third capillary, which runs along the bottom edge of the air-canal, starting at C, photo 1.  This capillary facilitates emptying of the air-canal of surplus ink.  Any ink in the air-canal prevents air entering into the reservoir.  This method is generally used to control ink flow.

It is plausible to assume that when the air-canal is somewhat filled, and all three capillaries supply ink to the nib, the writing will be wetter.

A4 shows the hollowed out section.  With the green line, I marked the length of contact between the ink supplying capillaries and the nib.

Rear End


photo 2 — Marukin 1934 – rear end

Photo 2 shows details of the rear end at D.  D1 shows the two ink capillaries and the flattened top of the stub.  I am not sure what this is for; however, I find the capillaries very shallow.  The cross section of the capillaries determines the amount of ink transported.

D3 shows the start of the third capillary, the air-canal-drainage-capillary.  In German, this would be all one word.  Don’t you love it?  At D2 is the larger flat section of the stub and you can see how it runs out into the curved section at C, shown in photo 1.   Here is the trapdoor, the valve, which controls the air inflow to and the ink outflow from the reservoir, subsequently.


The photos have been generously supplied by Zollinger (username), a member of (… you can select the English version).



sketch 1 — rear view with the feed in the grip-section

Sketch 1 may look a bit daunting, it will make sense in a minute.  The letters and number relate to the photos from above.  G is the grip section.  F is the outer diameter of the feed.

C1 is the cutaway part for the air to enter into the reservoir.  C2 is the bit of C1 which goes through the hole in the section allowing air to pass into the ink reservoir.

D is the stub that reaches into the hole in the section.  D1 are the two ink capillaries.  D2 is the flat part of the stub for the air to enter into the reservoir.  D3 is the capillary in the corner of the air-canal.

And finally, X is the width of the air-canal and Z its depth.  That was not too bad?  Yes, the air-canal is not concentric with the section or the nib.

How it works

When the ink runs into the hole of the section, it arrives at the part of the stub with the two ink capillaries D1 and gets sucked into them.  The air-canal opening C2 is too big for any capillary action and a meniscus forms across the opening, preventing the ink from entering.  If you open diagram 4 on page Application to the Feed would help you follow my explanation.

As the ink gets drained out from the reservoir the vacuum in there increases and fights against the capillary force in the ink capillaries.  The increase of vacuum causes the meniscus at C2 to break, and a small bubble of air enters into the reservoir and reduces the vacuum.  Ink can flow again.

If for whatever reasons the pressure in the reservoir increases (see Temperature and Air-pressure) and surplus ink is pushed into the feed it will be stored in the air-canal.  When ink is needed for writing (or dripping) the ink in the air-canal is used first, and the capillary at D3 helps to empty the air-canal.

That’s what happens at the rear end.  For the front end, I have to draw another sketch, for which I need to scout for more information.

If some information is missing, let me know.  I am learning as I go.


Amadeus W.

20 November 2016

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