JP2022098909A - fountain pen - Google Patents

Abstract

To provide a fountain pen capable of supplying a sufficient amount of ink, not allowing occurrence of ink shortage, to a writing region, as well as, capable of inhibiting occurrence of ink dripping.SOLUTION: The fountain pen comprises: a pen core 10; a first ink groove 12A communicating with a rear ink groove 12C and extending to a front end; a second ink groove 12B communicating with the rear ink groove through an ink groove 12D and extending to the front end alongside the first ink groove; a rear ink groove communicating with an ink storage region 30 and communicating with the second ink groove; and a gas-liquid groove 14 communicating with the ink storage region and communicating with the outside. The first and second ink grooves merge with each other on the front end side, the rear ink groove is open at a bottom of the gas-liquid groove in a longitudinal direction of the groove. Capillary forces have a relation of F1>F2>F3>F4, where F1 is a capillary force of the first ink groove; F2 is a capillary force of the second ink groove; F3 is a capillary force of the rear ink groove; F4 is a capillary force of an opening of the rear ink groove provided at the bottom of the gas-liquid groove.SELECTED DRAWING: Figure 2

Description

The present invention relates to a fountain pen provided with an ink groove that supplies ink to the writing area by capillary force.

A fountain pen provided with an ink groove that supplies ink to the writing area by capillary force is widely used. Among them, a writing tool provided with three ink grooves instead of the usual one ink groove has been proposed (see, for example, Patent Document 1). Since this writing tool can supply more ink to the writing area than when it has one ink groove, it is possible to prevent the ink from running out even when a pen tip for writing bold characters is used. Can be done.

Square root extraction No. 9-95083

In the writing tool described in Patent Document 1, the size of the cross section of the ink grooves on both sides of the three ink grooves is almost the same as the size of the cross section of a normal ink groove. The size of the cross section of the ink groove in the center is further increased because it communicates with the comb groove. Therefore, the time for the ink to reach the writing area by the capillary force from the state where there is no ink in the ink groove is the same as the case where the ink has only one conventional ink groove. Therefore, it may take a certain period of time from the state where there is no ink in the ink groove to the state where the writing tool can be used, such as when the writing tool is started to be used or after the writing tool is washed.
Further, since the gas-liquid groove communicating with the three ink grooves penetrates through the center of the pen core of the writing tool described in Cited Document 1, a large amount of ink is supplied to the writing area from the three ink grooves. In that case, there is a risk that so-called ink dripping may occur.

Therefore, an object of the present invention is to solve the above-mentioned problems, and it is possible to promptly supply ink to the writing area from a state where there is no ink in the ink groove to make it usable. It is intended to provide a fountain pen capable of supplying a sufficient amount of ink that does not sometimes run out of ink to the writing area and suppressing so-called ink dripping.

The fountain pen according to one embodiment of the present invention
A pen core partially covered with a pen tip,
A shaft cylinder that fits into the pen core at the neck and has an ink storage area inside.
A first ink groove formed in the pen core, communicating with the rear ink groove at the rear end, and extending to the front end in the axial direction.
A second ink groove formed in the pen core, communicating with the rear ink groove through a connecting ink groove at the rear end, and extending to the front end in the axial direction along with the first ink groove.
The rear, which is formed in the pen core and communicates with the ink storage area at the rear end, communicates with the first ink groove at the front end, and also communicates with the second ink groove through the connecting ink groove. Ink groove and
A gas-liquid groove formed in the pen core, communicating with the ink storage area at the rear end and communicating with the outside at the front end,
Equipped with
The first ink groove and the second ink groove merge with each other on the front end side.
The rear ink groove is opened at the bottom of the gas-liquid groove over a predetermined length in the longitudinal direction of the groove.
Let F1 be the capillary force per unit area in the cross section of the first ink groove at the rear end.
Let F2 be the capillary force per unit area in the cross section of the second ink groove at the rear end.
Let F3 be the capillary force per unit area in the cross section of the rear ink groove at the rear end.
Assuming that the capillary force per unit area at the opening of the rear ink groove provided at the bottom of the gas-liquid groove is F4.
F1 ＞ F2 ＞ F3 ＞ F4
It has come to have a relationship of.

According to the present invention, ink can be quickly supplied to the writing area from a state where there is no ink in the ink groove to make it usable, and a sufficient amount of ink that does not run out of ink during use can be supplied to the writing area. It is possible to provide a fountain pen that can be supplied to the ink and can suppress so-called ink dripping.

It is a top sectional view schematically showing the whole structure of the fountain pen which concerns on one Embodiment of this invention. FIG. 3 is an enlarged plan view showing a pen core portion of the fountain pen shown in FIG. 1. It is a figure which shows the outline of the 1st ink groove, the 2nd ink groove, the rear ink groove, and the gas-liquid groove schematically. It is a figure which shows typically the flow of the fluid in the 1st ink groove, the 2nd ink groove, the rear ink groove, and the gas-liquid groove in a pen core. It is a figure which shows typically the flow of the fluid in the 1st ink groove, the 2nd ink groove, the rear ink groove, and the gas-liquid groove, and is the figure which shows the place where the ink started to flow in the rear ink groove. It is a figure which shows typically the flow of the fluid in the 1st ink groove, the 2nd ink groove, the rear ink groove, and the gas-liquid groove, and is the figure which shows the place where the ink started to flow through the 1st ink groove. .. It is a figure which shows typically the flow of the fluid in the 1st ink groove, the 2nd ink groove, the rear ink groove, and the gas-liquid groove, and shows the place where the ink reaches the front end of the 1st ink groove. be. It is a figure which shows typically the flow of the fluid in the 1st ink groove, the 2nd ink groove, the rear ink groove, and the gas-liquid groove, and is the figure which shows the place where the ink started to flow also in the 2nd ink groove. be. It is a figure which shows typically the flow of the fluid in the 1st ink groove, the 2nd ink groove, the rear ink groove, and the gas-liquid groove, and shows the place where the ink reaches the front end of the 2nd ink groove. Is. It is a figure which shows typically the flow of the fluid in the 1st ink groove, the 2nd ink groove, the rear ink groove, and the gas-liquid groove, and the ink also flowed into the gas-liquid groove, and the air flow was blocked. It is a figure which shows the place.

Hereinafter, embodiments for carrying out the present invention will be described with reference to the drawings. The writing tools described below are for embodying the technical idea of the present invention, and the present invention is not limited to the following unless there is a specific description.
In each drawing, members having the same function may be designated by the same reference numeral. The size and positional relationship of the members shown in each drawing may be exaggerated for the sake of clarity. In the present specification, "front" refers to the tip end side of the writing instrument, and "rear" refers to the opposite side.

(Fountain pen according to one embodiment of the present invention)
First, the outline of the fountain pen according to one embodiment of the present invention will be described with reference to FIGS. 1 and 2. FIG. 1 is a plan sectional view schematically showing the entire structure of a fountain pen according to one embodiment of the present invention. FIG. 2 is an enlarged plan view showing a pen core portion of the fountain pen shown in FIG. 1.
The fountain pen 2 according to the present embodiment has a pen tip 4, a pen core 10 partially covered with the pen tip 4, and a shaft cylinder 20 having an ink storage area 30 inside, which is fitted with the pen core 10 at the neck portion 22. And.

The pen tip 4 has a pen point which is a front end portion that comes into contact with paper at the time of writing, a slit extending rearward from the pen point by a predetermined length, and a hole portion provided substantially in the center of the pen tip 4. The writing area is near the pen point. Since the pen tip 4 requires elasticity and corrosion resistance, the main body is made of gold alloy or special steel, and a wear-resistant alloy is used for the pen point portion in contact with the paper.
The shaft cylinder 20 is composed of, for example, a neck portion 22 located on the front side, a barrel shaft 24 located in the center, and a tail plug 26 located on the rear side. The neck portion 22 and the barrel shaft 24 are attached to each other in a detachable state by screwing or the like. An ink storage region 30 in which ink is stored is arranged mainly in the region of the barrel shaft 24 inside the barrel 20. The ink storage area 30 corresponds to an ink cartridge in the case of a cartridge-type fountain pen as shown in FIG. 1, and corresponds to a storage portion in which bottle ink sucked by the converter is stored in the case of a converter type. The shaft cylinder 20 can be formed of, for example, a resin material.

The pen tip 4 and the pen core 10 are overlapped with each other and fitted to the tubular neck portion 22. At this time, the pen tip 4 is arranged so as to extend to the front side from the region overlapping the pen core 10. The pen core 10 is arranged so as to extend to the rear side from the area overlapping the pen tip 4. That is, a part of the pen core 10 is covered with the pen tip 4. Since the region where the pen tip 4 and the pen core 10 overlap is fitted to the neck portion 22, a structure is obtained in which the pen tip 4 and the pen core 10 are firmly fixed to the front end portion of the barrel 20.

The pen core 10 is provided with an ink groove 12 for allowing the ink in the ink storage region 30 located on the rear end side to flow into the writing region at the front end of the pen tip 4. In the present embodiment, the first ink groove 12A, the second ink groove 12B, the rear ink groove 12C, the connecting ink groove 12D, the further connecting ink groove 12D', and the merging ink groove 12E are formed as the ink groove 12. ing.

The first ink groove 12A is formed so as to communicate with the rear ink groove 12C at the rear end (see P in FIG. 2) and extend to the front end in the axial direction. The second ink groove 12B communicates with the rear ink groove 12C at the rear end via the connecting ink groove 12D, and is formed so as to extend to the front end in the axial direction along with the first ink groove 12A. At the rear end opposite to the front end connected to the second ink groove 12B of the connecting ink groove 12D (see P in FIG. 2), it is connected to the rear ink groove 12C. The rear ink groove 12C communicates with the ink storage area 30 at the rear end, extends axially forward by a predetermined distance, and communicates with and communicates with the first ink groove 12A at the front end (see P in FIG. 2). It is formed so as to communicate with the second ink groove 12B via the ink groove 12D.
In the present embodiment, the rear ink groove 12C and the first ink groove 12A are connected and extended in a substantially linear shape. However, the present invention is not limited to this, and the rear ink groove 12C and the first ink groove 12A may be connected so as to bend at a predetermined angle.

The first ink groove 12A and the second ink groove 12B extending side by side merge with each other on the front end side, and the ink flows forward in the merged ink groove 12E. The merged ink groove 12E where the first ink groove 12A and the second ink groove 12B merge is terminated at the writing region at the front end of the pen core 10.
Further, in addition to the connecting ink groove 12D connected to the rear end of the second ink groove 12B, two additional connecting ink grooves connecting between the first ink groove 12A and the second ink groove arranged side by side. 12D'is formed. The connecting ink groove 12D connecting between the second ink groove 12B and the rear ink groove 12C, and the further connecting ink groove 12D'connecting between the second ink groove 12B and the first ink groove 12A are abbreviated as axial directions. It extends in the orthogonal direction. However, the present invention is not limited to this, and the connecting ink grooves 12D and 12D'may extend diagonally with respect to the axial direction, or may extend in a curved shape. Further, the number of additional contact ink grooves 12D'is not limited to 2, and any number of one or more additional contact ink grooves 12D'can be provided.

Further, a gas-liquid groove 14 is provided at the rear end to communicate with the ink storage area 30 and at the front end to communicate with the outside. When ink flows out from the ink storage region 30 through the rear ink groove 12C, the first ink groove 12A, and the second ink groove 12B, the inside of the ink storage region 30 becomes a negative pressure as it is, and the ink is charged. The flow cannot be continued. Therefore, by performing gas-liquid exchange that takes in the atmosphere by the amount of the outflow ink by the gas-liquid groove 14, it is possible to prevent the ink storage region 30 from becoming a negative pressure and continuously use the ink in the ink storage region 30. Can be supplied to the writing area.

The rear end of the rear ink groove 12C coincides with the rear end of the pen core 10, but the rear end of the gas-liquid groove 14 is located slightly in front of the rear end of the pen core 10. The pen core 10 has a notch portion from the rear end of the pen core 10 to the position of the rear end of the gas / liquid groove 14. Since the ink in the ink storage area 30 is also filled in the space provided by the notch portion, it can be said that the space created by the notch is also a part of the ink storage area 30. Therefore, it can be said that the gas-liquid groove 14 communicates with the ink storage region 30 at the rear end.
Further, a comb groove 16 for temporarily storing the ink drawn from the ink storage area 30 is also provided. The pen core 10 can be formed of a resin material, and when integrally formed, it can be easily washed.

(1st ink groove, 2nd ink groove, rear ink groove and gas / liquid groove)
Next, with reference to FIG. 3, the structures of the first ink groove 12A, the second ink groove 12B, the rear ink groove, and the gas / liquid groove 14 provided in the pen core 10 will be described. FIG. 3 is a diagram schematically showing an outline of a first ink groove, a second ink groove, a rear ink groove, and a gas / liquid groove.

As shown in FIG. 3A, the first ink groove 12A, the second ink groove 12B, the rear ink groove 12C, and the gas / liquid groove 14 each have a substantially rectangular cross-sectional shape. The cross section referred to here means a cross section orthogonal to the direction in which the groove extends. In FIG. 3A, the width at the rear end of the first ink groove 12A is indicated by W1 and the depth is indicated by D1, the width at the rear end of the second ink groove 12B is indicated by W2, and the depth is indicated by D2. The width at the rear end of the rear ink groove 12C is indicated by W3 and the depth is indicated by D3, and the width at the rear end of the gas / liquid groove 14 is indicated by W4 and the depth is indicated by D4.

In the present embodiment, at each rear end, the peripheral length and the cross-sectional area of the cross section of the rear ink groove 12C are larger than the peripheral length and the cross-sectional area of the first ink groove 12A and the second ink groove 12B. In that case, both the width W3 and the depth D3 of the rear ink groove 12C may be larger than the first and second ink grooves 12A and 12B, and either the width W3 or the depth D3 may be larger. However, it may be larger than the first and second ink grooves 12A and 12B.
In either case, the rear ink groove 12C having a larger cross-sectional area can supply a larger amount of ink from the ink storage region 30 to the first ink groove 12A and the second ink groove 12B.

Further, when the first ink groove 12A and the second ink groove 12B are compared, the peripheral length and the cross-sectional area of the cross section of the second ink groove 12B at the rear end are the peripheral length of the cross section of the first ink groove 12A. And it is larger than the cross-sectional area. More specifically, the width W1 of the first ink groove 12A and the width W2 of the second ink groove 12B are the same. On the other hand, regarding the depth, the depth D2 of the second ink groove 12B is larger (deeper) than the depth D1 of the first ink groove 12A.

The width W1 and the depth D1 of the first ink groove 12A, the width W2 and the depth D2 of the second ink groove 12B, and the width W3 and the depth D3 of the rear ink groove 12C are changed as they move forward (for example,). It can be narrower and shallower toward the tip). The depth D2 of the second ink groove 12B is the same as the depth D1 of the first ink groove 12A at the front end portion where the ink groove 12A merges with the first ink groove 12A.

However, the present invention is not limited to this, and for example, the width W1 and the depth D1 of the first ink groove 12A and the width W3 and the depth D3 of the rear ink groove 12C are substantially the same over the entire length, and the second ink is used. For the groove 12B, the width W2 is the same over the entire length, but the depth D2 can be made smaller (shallow) toward the front side. As a result, the depth D2 of the second ink groove 12B can be made the same as the depth D1 of the first ink groove 12A at the front end portion where the ink groove 12A merges with the first ink groove 12A.

In any case, at the rear end, the cross-sectional area of the second ink groove 12B is larger than that of the first ink groove 12A, and at least the cross-sectional area of the second ink groove 12B decreases as the cross-sectional area of the second ink groove 12B advances to the front side. The cross-sectional areas of the first ink groove 12A and the second ink groove 12B can be made to be substantially the same at the front end portion that joins the ink groove 12A.
As a result, at the rear end connected to the rear ink groove 12C, the first ink groove 12A having a stronger pulling force F1 can quickly guide the ink to the writing area on the front end side, and at the confluence portion, the first, Since the cross-sectional areas of the second ink grooves 12A and 12B are the same, flow resistance due to the difference in flow is unlikely to occur, and sufficient ink can be efficiently supplied to the writing area.

The rear ink groove 12C extends axially forward by a predetermined length from the rear end portion of the pen core 10 communicating with the ink storage region 30 to the position P connected to the first and second ink grooves 12A and 12B. There is. Among them, there is a region where the gas-liquid groove 14 is arranged on the upper side (the side where the pen tip 4 is arranged) of the rear ink groove 12C over the length L in the direction in which the groove extends. In that region, the rear ink groove 12C and the gas-liquid groove 14 communicate with each other. In other words, the rear ink groove 12C is opened at the bottom of the gas-liquid groove 14 over the length L in the longitudinal direction of the groove. The front end side of the gas-liquid groove 14 having a length L communicates with the atmosphere. For example, on the front end side of the gas-liquid groove 14, the upper side of the gas-liquid groove 14 may be open to the atmosphere, or the gas-liquid groove 14 may be separated from the position on the upper side of the first ink groove 12A. It may extend in the direction intersecting the axial direction and open to the atmosphere at the side of the pen core 10.

As shown in FIG. 3B, the capillary force per unit length generated on the surfaces of the first ink groove 12A, the second ink groove 12B, the rear ink groove 12C, and the gas / liquid groove 14 is T, and the capillary tube is formed. Assuming that the angle of the force T with respect to the inner surface of the groove is θ, the force per unit length for drawing ink into the groove per unit length is T × cos θ.
Assuming that the capillary force per unit area, which corresponds to the pressure for drawing the ink in the rear ink groove 12C into the first ink groove 12A, is F1.
F1 = T × cos θ × (W1 + 2 × D1) / (W1 × D1).

Similarly, assuming that the capillary force per unit area, which corresponds to the pressure for drawing the ink in the rear ink groove 12C into the second ink groove 12B via the connecting ink groove 12D, is F2.
F2 = T × cos θ × (W2 + 2 × D2) / (W2 × D2).
Further, assuming that the capillary force per unit area, which corresponds to the pressure for drawing the ink in the ink storage area 30 into the rear ink groove 12C, is F3.
F3 = T × cos θ × (W3 + 2 × D3) / (W3 × D3).
Further, assuming that the capillary force per unit area, which corresponds to the pressure for drawing the ink in the rear ink groove 12C into the gas-liquid groove 14 through the opening at the bottom of the gas-liquid groove 14 over the length L, is F4.
F4 = T × cos θ × (2 × L) / (W4 × L). The capillary force F4 that draws the ink in the rear ink groove 12C into the gas-liquid groove 14 is due to the surface tension generated on the inner walls on both sides of the gas-liquid groove 14 over the length L, so that the above equation is obtained.

In the present embodiment, the capillary force F1 per unit area in the cross section of the first ink groove 12A, the capillary force F2 per unit area in the cross section of the second ink groove 12B, and the capillary force F2 per unit area in the cross section of the rear ink groove 12C. Between the capillary force F3 and the capillary force F4 per unit area at the opening of the rear ink groove 12C provided at the bottom of the gas-liquid groove 14.
F1 ＞ F2 ＞ F3 ＞ F4
Have a relationship of.

Expressing this in terms of the groove dimensions above,
T × cos θ × (W1 + 2 × D1) / (W1 × D1) ＞ T × cos θ × (W1 + 2 × D1) / (W1 × D1) ＞ T × cos θ × (W3 + 2 × D3) / (W3 × D3) ＞ T × It has a relationship of cosθ × (2 × L) / (W4 × L).
Divide by T × cos θ
(W1 + 2 × D1) / W1 × D1> (W2 + 2 × D2) / W2 × D2
> (W3 + 2 x D3) / (W3 x D3)> (2 x L) / (W4 x L)
Have a relationship of.

Further, assuming that the capillary force per unit area, which corresponds to the pressure for drawing the ink in the ink storage region 30 into the gas-liquid groove 14, is F5.
F4 = T × cos θ × (W4-W3 + 2 × D4) / (W4 × D4).
Also for F5
F1 ＞ F2 ＞ F3 ＞ F5
It has come to have a relationship of.
in short,
(W1 + 2 × D1) / W1 × D1 ＞ (W2 + 2 × D2) / W2 × D2 ＞ (W3 + 2 × D3) / (W3 × D3) ＞ (W4-W3 + 2 × D4) / (W4 × D4)
Have a relationship of.

Comparing the cross-sectional areas of the first ink groove 12A, the second ink groove 12B, the rear ink groove 12C, and the gas / liquid groove 14, basically, the first ink groove 12A, the second ink groove 12B, and the rear ink The size increases in the order of the groove 12C and the gas-liquid groove 14. in short,
W1 x D1 <W2 x D2 <W3 x D3 <W4 x D4
Have a relationship of.
Since the ink groove and the gas-liquid groove have a narrow and deep rectangular cross section, the peripheral length becomes long, so that the above inequality regarding the cross-sectional area may not apply, but even in that case, the ink groove 12A, By appropriately determining the dimensions of 12B, the rear ink groove 12C, and the gas-liquid groove 14, it is possible to have a relationship of F1>F2>F3> F4.

The cross-sectional area of the further connecting ink groove 12D'connecting between the first ink groove 12A and the second ink groove 12B arranged side by side is from the cross-sectional area of the first ink groove 12A and the second ink groove 12B. Is also formed to be large. Further, the cross-sectional area of the connecting ink groove 12D'is formed to be the same or smaller as it progresses from the first ink groove 12A side to the second ink groove 12B.
As described above, the cross-sectional area of the second ink groove 12B may decrease as it advances to the front side, and may match the cross-sectional area of the first ink groove 12A at the front end portion where it joins the first ink groove 12A. be. Even in that case, for example, the cross-sectional area of the second ink groove is 25% to 50% or more of that of the first ink groove at the connection position of the further connecting ink groove 12D'arranged on the front side. It is preferable that it is large.

(Ink, air flow)
Next, with reference to FIGS. 4 and 5A to 5E, the flow of ink and air in the first ink groove 12A, the second ink groove 12B, the rear ink groove 12C, and the gas / liquid groove 14 having the above relationship. To explain. FIG. 4 is a diagram schematically showing the flow of fluid in the first ink groove, the second ink groove, the rear ink groove, and the gas / liquid groove in the pen core. FIG. 5A is a diagram schematically showing the flow of fluid in the first ink groove, the second ink groove, the rear ink groove, and the gas / liquid groove, and is a diagram showing where the ink starts to flow in the rear ink groove. 5B is a diagram showing where the ink has started to flow through the first ink groove, FIG. 5C is a diagram showing where the ink has reached the front end of the first ink groove, and FIG. 5D. Is a diagram showing a place where the ink has started to flow into the second ink groove, FIG. 5E is a diagram showing a place where the ink has reached the front end of the second ink groove, and FIG. 5F is a diagram showing the ink. It is a figure which shows the place where the ink flowed into the gas-liquid groove and blocked the flow of air.

5A to 5F each figure (a) shows a side surface along the direction in which the groove extends, and FIG. 5B shows a cross section orthogonal to the direction in which the groove extends. The front ends of the first ink groove 12A and the second ink groove 12B shown in FIGS. 5A to 5F indicate positions where the two ink grooves meet.
FIG. 4A is a diagram showing a state before the ink flows out from the ink storage region 30, and FIG. 4B is a diagram showing the front end of the first ink groove 12A in the same manner as in FIG. 5C. FIG. 4 (c) is a diagram showing a place where the ink reaches the front end of the second ink groove 12B, as in FIG. 5E, and is a diagram showing a place where the ink reaches the front end of the second ink groove 12B. FIG. 5F is a diagram showing a place where ink flows into the gas-liquid groove 14 and blocks the flow of air, as in FIG. 5F.

As described above, the pulling force F3 per unit area for drawing ink from the ink storage area 30 into the rear ink groove 12C, the pulling force F1 per unit area for drawing ink from the rear ink groove 12C to the first ink groove 12A, and the rear ink groove. The pulling force F2 per unit area for drawing ink from 12C to the second ink groove 12B via the connecting ink groove 12D, and the unit area for drawing ink from the rear ink groove 12C to the gas / liquid groove 14 through the upper opening. Since there is a relationship of F1> F2> F3> F4 between the pulling forces F4, ink and air flow in the groove as follows.

From the initial state in which ink does not exist in the ink groove 12 as shown in FIG. 4A, first, the ink in the ink storage region 30 flows into the rear ink groove 12C by the pulling force F3 (see FIG. 5A). Subsequently, the pulling force F1 showing the highest value causes the ink to flow from the rear ink groove 12C into the first ink groove 12A and flow to the front side (see FIG. 5B). In this case, a part of the ink also flows into the connecting ink groove 12D, but the pulling force F1 of the first ink groove is higher than the pulling force F2 per unit area of the second ink groove 12B. It does not continue to flow into the ink groove 12B of 2.

Then, the ink flowing through the first ink groove 12A reaches the front end. The first ink groove 12A having a strong pulling force can quickly form a usable state in which the ink is filled from the state where the ink does not exist in the ink groove to the front end region of the ink groove 12 (FIG. 4). (B), see FIG. 5C). When the ink reaches the front end of the first ink groove 12A, the direction of the surface tension of the ink becomes blunt and the capillary force weakens, so that the force of drawing from the rear ink groove 12C into the first ink groove 12A weakens, and the first It is less than the force F2 that pulls into the ink groove 12B of 2.

As a result, the ink begins to flow into the second ink groove 12B through the connecting ink groove 12D, and flows forward in the second ink groove 12B (see FIG. 5D). Then, the ink flowing through the second ink groove 12B reaches the front end. (See FIG. 4 (c), FIG. 5E). When the ink flowing through the second ink groove 12B reaches the front end, the direction of the surface tension of the ink becomes blunt and the capillary force weakens, so that the force drawn into the second ink groove weakens and the first ink groove It is lower than the force F4 that draws ink from 12A into the gas-liquid groove 14.
The pulling force F4 draws ink from the rear ink groove 12C into the gas / liquid groove 14 through the upper opening. At the same time, the ink flows from the ink storage region 30 into the gas-liquid groove 14 by the pulling force F5 that draws the ink from the storage region 30 into the gas-liquid groove 14. Since the gas-liquid groove 14 is filled with ink, the flow of air into the ink storage region 30 is blocked, and the flow of ink is stopped (see FIG. 4D and FIG. 5F). As a result, it is possible to prevent so-called drop-off when the writing area of the pen tip 4 is not in contact with paper or the like in an unused state.

When the rear ink groove 12C, the first ink groove 12A, and the second ink groove 12B are filled with ink, when writing, the paper surface is evenly distributed to both the first ink groove 12A and the second ink groove 12B. Under the suction pressure, ink is supplied from both the first ink groove 12A and the second ink groove 12B. At that time, the second ink groove having a wide cross-sectional area supplies more ink. Since a large amount of ink can be supplied to the writing area by the second ink groove 12B, the ink does not run out even when a pen tip for writing bold characters is used.

When the ink flows in the first ink groove, the ink also flows into the further connecting ink groove 12D'connected to the second ink groove, but the second ink groove 12B has a second pulling force F2. Since the pulling force F1 of the ink groove 1 is higher, the ink does not flow into the second ink groove 12B. As described above, the cross-sectional area of the second ink groove 12B is larger than the cross-sectional area of the first ink groove 12A even at the position where the further contact ink groove 12D'arranged in the frontmost position is connected. The pulling force F1 of the first ink groove is higher than the pulling force F2 of the second ink groove 12B.
On the other hand, when the ink reaches the front end of the first ink groove 12A, the force for drawing into the first ink groove 12A weakens and is lower than the force F2 for drawing into the second ink groove 12B. The ink flowing in the ink groove 12A flows into the second ink groove 12B through the further connecting ink groove 12D.

Even if some ink may flow from the rear ink groove 12C into the gas-liquid groove 14 through the upper opening until the ink reaches the front ends of the first ink groove 12A and the second ink groove 12B. , The pulling force F1 and F2 of the first ink groove 12A and the inner second ink groove 12B are larger than the pulling force F4 of the gas / liquid groove 14, so that the gas flow path is blocked, the inside of the gas / liquid groove 14 is blocked. Ink does not flow into.
The relationship of F1>F2>F3> F4 is as follows: the first ink groove 12A and the second ink groove 12B, and the first ink groove 12A and the second ink from the state where there is no ink in the rear ink groove. It is a relational expression to be filled until the ink is filled up to the front end of the groove 12B and merged.

As described above, the cross-sectional area of the further connecting ink groove 12D'is larger than the cross-sectional area of the first ink groove 12A and the second ink groove 12B, and the second from the first ink groove 12A side. The cross-sectional area may become smaller toward the ink groove 12B side of the ink groove. When the ink reaches the tip of the first ink groove 12A in a state where there is no ink in the further contact ink groove 12D', the force F1'to pull into the first ink groove 12A weakens, and the second ink groove 12B It is lower than the force F2 that pulls in. Assuming that the capillary force per unit area of the further connecting ink groove 12D'at this time is F6, it is preferable to have a relationship of F2> F6> F1'. As a result, the ink can be quickly flowed from the first ink groove 12A to the second ink groove 12B through the further connecting ink groove 12D'. Therefore, the function of the contact ink groove 12D'can be further enhanced. In order to realize this, it is preferable that the cross-sectional area of the further connecting ink groove 12D'becomes smaller from the first ink groove 12A to the second ink groove 12B.

As described above, the fountain pen 2 according to this embodiment is
A pen core 10 partially covered with a pen tip 4 and
A shaft cylinder 20 having an ink storage area 30 inside, which is fitted with a pen core 10 at the neck portion 22,
A first ink groove 12A formed in the pen core 10 that communicates with the rear ink groove 12C at the rear end and extends to the front end in the axial direction.
A second ink groove 12B formed in the pen core 10, communicating with the rear ink groove 12C via the connecting ink groove 12D at the rear end, and extending to the front end in the axial direction along with the first ink groove 12A.
Rear ink formed in the pen core 10 and communicates with the ink storage area 30 at the rear end, with the first ink groove 12A at the front end, and also with the second ink groove 12B via the communication ink groove 12D. Groove 12C and
A gas-liquid groove 14 formed in the pen core 10, communicating with the ink storage area 30 at the rear end and communicating with the outside at the front end, and
Equipped with
The first ink groove 12A and the second ink groove merge with each other on the front end side, and the first ink groove 12A and the second ink groove merge with each other.
A rear ink groove 12C is opened at the bottom of the gas-liquid groove 14 over a predetermined length L in the longitudinal direction of the groove.
Let F1 be the capillary force per unit area in the cross section of the first ink groove 12A at the rear end.
Let F2 be the capillary force per unit area in the cross section of the second ink groove 12B at the rear end.
Let F3 be the capillary force per unit area in the cross section of the rear ink groove 12C at the rear end.
Assuming that the capillary force per unit area at the opening of the rear ink groove 12C provided at the bottom of the gas-liquid groove 14 is F4,
F1 ＞ F2 ＞ F3 ＞ F4
It has come to have a relationship of.

With F1, the strongest capillary force can be quickly supplied to the writing area on the front end side of the pen core 10 from the state where there is no ink in the ink groove 12. After the ink is filled up to the front ends of the first ink groove 12A and the second ink groove 12B, the gas-liquid groove 14 is closed with the ink, so that so-called ink dripping can be suppressed. After the ink is filled up to the front ends of the first ink groove 12A and the second ink groove 12B, a sufficient amount of ink that does not run out of ink during use can be supplied to the writing area.
As described above, in the present embodiment, the ink can be promptly supplied to the writing area from the state where there is no ink in the ink groove 12 such as at the start of use or after cleaning, and the ink can be made usable. It is possible to provide a fountain pen 2 capable of supplying a sufficient amount of ink that does not cause ink shortage during use to the writing area and suppressing so-called ink dripping.

In order to realize this, when the first ink groove 12A, the second ink groove 12B, the rear ink groove 12C, and the gas / liquid groove 14 each have a substantially rectangular cross-sectional shape,
The width of the cross section of the first ink groove 12A is W1, and the depth is D1.
The width of the cross section of the second ink groove 12B is W2, and the depth is D2.
The width of the cross section of the rear ink groove 12C is W3, and the depth is D3.
Assuming that the width of the cross section of the gas-liquid groove 14 is W4 and the predetermined length of the opening of the rear ink groove 12C provided at the bottom of the gas-liquid groove 14 is L, it is assumed.
(W1 + 2 × D1) / W1 × D1> (W2 + 2 × D2) / W2 × D2
> (W3 + 2 x D3) / W3 x D3> (2 x L) / (W4 x L)
Have a relationship of.
As a result, it is possible to surely have the relationship of F1>F2>F3> F4.

Further, the cross-sectional area at the rear end of the rear ink groove 12C is larger than the cross-sectional area at the rear end of the second ink groove 12B, and the cross-sectional area at the rear end of the second ink groove 12B is that of the first ink groove 12A. It is preferably larger than the cross-sectional area at the rear end.
As a result, a large amount of ink can be supplied from the ink storage region 30 to the first ink groove 12A and the second ink groove 12B by the rear ink groove 12C having the largest cross-sectional area, and the second ink groove 12B having the next largest cross-sectional area can be supplied. The ink groove 12B of 2 can supply ink to the writing area on the front end side. Therefore, even when the pen tip 4 for writing bold characters is used, it is possible to supply a sufficient amount of ink to the writing area so that the ink does not run out during use.

The fountain pen according to the present invention is not limited to the above embodiment, and includes any other cursive pen as long as it has a hollow barrel. Although the embodiments and embodiments of the present invention have been described, the disclosed contents may be changed in the details of the configuration, and the present invention is requested to change the combinations and orders of the elements in the embodiments and embodiments. It can be realized without deviating from the scope and idea of.

20,000 years brush 4 Pen tip 10 Pen core 12 Ink groove 12A First ink groove 12B Second ink groove 12C Rear ink groove 12D Communication ink groove 12D'Further communication ink groove 12E Confluence ink groove 14 Gas-liquid groove 16 Comb groove 20 Shaft cylinder 22 Neck part 24 Body shaft 26 Tail plug 30 Ink storage area

Claims (4)

A pen core partially covered with a pen tip,
A shaft cylinder that fits into the pen core at the neck and has an ink storage area inside.
A first ink groove formed in the pen core, communicating with the rear ink groove at the rear end, and extending to the front end in the axial direction.
A second ink groove formed in the pen core, communicating with the rear ink groove through a connecting ink groove at the rear end, and extending to the front end in the axial direction along with the first ink groove.
The rear, which is formed in the pen core and communicates with the ink storage area at the rear end, communicates with the first ink groove at the front end, and also communicates with the second ink groove through the connecting ink groove. Ink groove and
A gas-liquid groove formed in the pen core, communicating with the ink storage area at the rear end and communicating with the outside at the front end,
Equipped with
The first ink groove and the second ink groove merge with each other on the front end side.
The rear ink groove is opened at the bottom of the gas-liquid groove over a predetermined length in the longitudinal direction of the groove.
Let F1 be the capillary force per unit area in the cross section of the first ink groove at the rear end.
Let F2 be the capillary force per unit area in the cross section of the second ink groove at the rear end.
Let F3 be the capillary force per unit area in the cross section of the rear ink groove at the rear end.
Assuming that the capillary force per unit area at the opening of the rear ink groove provided at the bottom of the gas-liquid groove is F4.
F1 ＞ F2 ＞ F3 ＞ F4
A fountain pen characterized by having a relationship of.
The first ink groove, the second ink groove, the rear ink groove, and the gas-liquid groove each have a substantially rectangular cross-sectional shape.
The width of the cross section of the first ink groove is W1, and the depth is D1.
The width of the cross section of the second ink groove is W2, and the depth is D2.
The width of the cross section of the rear ink groove is W3, and the depth is D3.
Assuming that the width of the cross section of the gas / liquid groove 14 is W4 and the predetermined length of the opening of the first ink groove provided at the bottom of the gas / liquid groove is L.
(W1 + 2 × D1) / W1 × D1> (W2 + 2 × D2) / W2 × D2
> (W3 + 2 x D3) / W3 x D3> (2 x L) / (W4 x L)
The fountain pen according to claim 1, which is characterized by having the relationship of.
The cross-sectional area at the rear end of the rear ink groove is larger than the cross-sectional area at the rear end of the second ink groove, and the cross-sectional area at the rear end of the second ink groove is the rear end of the first ink groove. The fountain pen according to claim 1 or 2, wherein the fountain pen is larger than the cross-sectional area in the above.
At least one additional contact ink groove connecting between the first ink groove and the second ink groove arranged side by side is provided.
The cross-sectional area of the further connecting ink groove is larger than the cross-sectional area of the first ink groove and the second ink groove, and is cut off as it progresses from the first ink groove side to the second ink groove side. The fountain pen according to claim 3, wherein the area is small.

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