1. Technical Field
The present invention relates to a pressurizing-type pen in which the ink contained in an ink refill is pressurized by the user at the time of writing to assist in writing.
2. Related Art
Pressurizing-type pens such as ball point pens have been known in which, when the front end of a refill accommodated in a pen barrel is protruded to a writing position by a knocking operation, the ink supplied to the writing tip at the front end of the refill can be pressurized by applying air pressure to a rear space of the refill filled with the ink. For example, JP-A-2005-246648 and JP-A-2005-138356 describe such pressurizing-type pens.
In pressurizing-type pens, generally, when the front end of a refill is fed from a barrel by a knocking operation, the periphery of a rear portion of the refill is closed to form a closed space and air in the closed space is compressed to pressurize the rear space of the refill. In many cases, as a sealing member for forming the closed space, an elastic member which is in sliding contact with the periphery of the refill is used. For example, the pressurizing-type pen described in JP-A-2005-246648 uses an O-ring having such an inner diameter that makes it possible to slidably move in sealing contact with the periphery of an outer face of an ink reservoir. In the ball point pen described in JP-A-2005-138356, an annular elastic member formed by an O-ring is constituted such that the elastic member sealingly and slidingly contacts with and detachs from the inner face of a cylinder.
Accordingly, in conventional pressurizing-type pens, when the refill moves in an axial direction, the sealing member is rubbed against the outer periphery face of the refill or against the inner face of the cylinder, and therefore the sealing member is apt to abrade. Further, since the O-ring itself is required to expand or shrink, the O-ring is likely damaged and it sometimes becomes impossible to retain an adequate sealing condition. In addition, since the air compressed by the pressurizing mechanism does not always properly act on the ink, the pressurization of the ink sometimes becomes uncertain. Further, in some cases, the pressurizing mechanism is retracted in such a condition that sealing is maintained without sufficient pressure reduction, and the ink is sucked out of the refill by suction.
Further, in conventional pressurizing-type pens, many pens employ a so-called rotating cam-type feeding mechanism as a mechanism for feeding a refill by a knocking operation, but such pens have the above pressurizing mechanism incorporated therein, and therefore the entire mechanism becomes complicated making it difficult to feed the refill securely.
It is an object of the present invention to provide a pressurizing-type pen having a pressurizing mechanism, in which a rear space of an ink refill can be pressurized when the refill is advanced and in which a sealing body in sealing contact with the outer face of the refill does not slidably move along the outer face of the refill.
It is another object of the present invention to provide a pressurizing-type pen in which the ink in the refill can be securely pressurized with no risk of backward suction of the ink by the pressurizing mechanism.
The above and other objects of the present invention are carried out by a pressurizing type pen comprising a refill movably accommodated in a barrel to undergo movement in an axial direction between a writing position and a retracted position, and a pressurizing mechanism to pressurize air in a rear space of the refill when the refill is moved to the writing position. The pressurizing mechanism comprises a refill holder which holds a rear portion of the refill in an aeration-allowed condition and which has an opening at its rear end. An elastic airtight member surrounds a periphery of the refill while providing an air vent path between the airtight member and the refill. A return spring holder holds the airtight member and is connected to a front portion of the refill holder to undergo slight movement in an axial direction within a predetermined range, and the return spring holder is urged by a return spring backwardly to a position abutting on a stopper disposed in the barrel.
A compression cylinder is fitted to a rear portion of the refill holder and has a compression chamber at its inside. A knocking-type feeding mechanism is disposed in the barrel to move the compression cylinder back and forth. An inner face of the refill holder faces the airtight member so that when the refill holder advances, the inner face of the refill holder presses and elastically deforms the airtight member to bring an inner face of the airtight member into close contact with an outer periphery face of the refill thereby closing the vent path.
The compression cylinder and the refill holder are connected by a releasable connecting means for connecting the compression cylinder and the refill holder so that when the compression cylinder advances, the compression cylinder and the refill holder advance together to a position where the refill holder presses and deforms the airtight member to close the vent path, and then the connection of the compression cylinder and the refill holder is released so that the compression cylinder can move closer to the refill holder. The refill holder with the refill and the return spring holder with the airtight member are moved forward by the compression cylinder against the return spring.
In the present invention, the front part or front portion means a front end side of the barrel at which the refill advances and from which its front end protrudes, and the rear part or rear portion means a rear end side of the barrel in which the refill retracts.
According to one aspect of the present invention, the releasable connecting means comprises locking projections formed on a front end face of the compression cylinder and outward projections disposed on an outer periphery face of the compression cylinder, inward projections formed in the barrel and on which the outward projections abut when the compression cylinder is located at the retracted position, and an engagement groove formed on an outer periphery face of the refill holder and with which the locking projections of the compression cylinder engages. The front end of the compression cylinder is elastically deformable in the radial direction of the compression cylinder so that when the outward projections engage with the inward projections of the barrel, the front end of the compression cylinder is radially contracted and the locking projection of the compression cylinder engage with the engagement groove of the refill holder. When the outward projections are detached from the inward projections of the barrel, the front end radially expands and the engagement between the locking projections of the compression cylinder and the engagement groove of the refill holder is released.
According to another aspect of the present invention, the inner face of the elastic airtight member is spaced from the outer periphery face of the refill at the non-writing time to form a vent path which communicates to the compression chamber of the compression cylinder through a gap between the outer periphery face of the refill and the inner periphery face of the refill holder via the opening at the rear end of the refill holder. When the compression cylinder is located at the retracted position and is made to advance by a knocking-type feeding mechanism, the compression cylinder and the refill holder advance together in a state in which the refill holder and the compression cylinder are releasably connected by a connecting means. As the refill holder advances, the inner face thereof abuts on the airtight member and elastically deforms the inner face of the airtight member into tight contact with the outer periphery face of the refill to close the vent path communicating from the outer periphery face of refill to the compression chamber. When the compression cylinder further advances, the connection between the refill holder and the compression cylinder by the connecting means is released and only the compression chamber advances. As a result, the air in the compression chamber of the compression cylinder is compressed and enters the inside of the refill through the opening at the rear end and pressurizes the ink.
Since the refill holder and the compression cylinder are connected until they reach the position where the vent path around the refill is closed by the airtight member, the rear space of the refill is not unfavorably pressurized before the vent path is closed and can securely be pressurized after the vent path is closed. Further, after the compression cylinder abuts on the refill holder, the refill holder with the refill and the return spring holder with the airtight member advance together against the return spring, and the refill can be held at the writing position. During this advancement, the airtight member is pressed by the refill holder and elastically clamped onto the refill so that the airtight member is not in slidable contact with the outer periphery face of the refill and will not be abraded as in the case of the sealing members of conventional pressurizing-type pens.
Further, when the above knocking-type feeding mechanism is knocked so that the refill is retracted to the non-writing position, the compression cylinder retracts by the action of the knocking mechanism, and following this action, the return spring holder with the airtight member and the refill holder with the refill retract by the action of the return spring. When the return spring holder abuts on a stopper in the barrel, the retraction of the return spring holder and the airtight member is stopped. Since the compression cylinder continues to further retract, the refill holder connected to the return spring holder in slightly movable fashion also retracts, and the deforming pressure exerted on the airtight member by the refill holder is released and the inner face of the airtight member detachs from the outer periphery face of the refill. As a result, the vent path between the outer periphery face of the refill and the inner periphery face of the refill holder is allowed to open to the outside air, and the compression chamber of the compression cylinder is connected to the vent path.
Since the movement of the return spring holder is within a predetermined limited range, it is constrained by the return spring holder within the limitation of movement and the retraction of the refill holder is stopped. Then, since only the compression cylinder retracts, the compression cylinder and the refill holder are connected by the connecting means at the retracted position, and the compression cylinder returns to the non-writing position. At this stage, in accordance with the present invention, since the compression cylinder is designed to further retract after the vent path is opened as mentioned above, no suction is exerted on the compression chamber of the compression cylinder and the ink in the refill will not be sucked backwardly.
As the knocking-type feeding mechanism, various known feeding mechanisms, such as a so-called rotating cam type feeding mechanism or a heart cam type feeding mechanism, may be employed. In the example shown in
As well known, by the above structure, in the non-writing state, the projecting members 11 of the rotating cam 12 enter the deep cam grooves 8 of the stationary cam 7 to make the rotating cam retract. When the knocking part 15 is knocked, the rotating cam 12 advances via the knocking cam 14, and when the knocking is stopped, the knocking cam 14 retracts by the knock spring 16. The rotating cam 12 rotates and the projecting members 11 engage with the shallow cam grooves 9 of the stationary cam 7, and the refill 2 is held in the writing state where the writing front end projects from the barrel 1. In the writing state, when the knocking part 15 is knocked, the rotating cam 12 moves ahead of the stationary cam 7 via the knocking cam 14, and the projecting members 11 come out of the shallow cam grooves 9. When the knocking is stopped, the knocking cam 14 and the rotating cam 12 retract, the rotating cam 12 rotates and the projecting members 11 engage with the deep cam grooves 8 of the stationary cam 7, the refill 2 retracts, and the writing front end is accommodated in the barrel 1. The stationary cam 7 may be formed integrally inside the barrel 1 (not shown).
The above structure is not essentially different from the usual rotating cam type feeding mechanism. In the present invention, at an intermediate part of the inside of the stationary cam 7, a plurality of inward projections 17 extending in an axial direction are disposed at circumferentially spaced intervals, and at the front part of the stationary cam, a long hole 18 is formed. When the refill 2 retracts from the writing state to the non-writing state, the rotating cam 12 is connected to the knocking cam 14 so that it retracts together with the knocking cam 14. Namely, the rear part of the rotating cam 12 is formed into a small diameter part 19 that can be inserted into the inside of the knocking cam 14, and on the outer face of the small diameter part 19, an outward projection 20 is disposed. On the inner face of the knocking cam 14, an inward projection 21 is formed. The small diameter part 19 of the rotating cam 12 is inserted in the knocking cam 14 from the front side of the knocking cam, and inserted to the position where the outward projection 20 goes beyond the inward projection 21 of the knocking cam 14. Since a recess 22 is formed in front of the outward projection 20 of the rotating cam 12, the knocking cam 14 can move ahead of the outward projection 20, but when it moves rearward, it retracts together with the rotating cam 12 from the position where the inward projection 21 engages with the outward projection 20.
By the above structure, after the rotating cam 12 is advanced by the knocking operation to move the refill 2 to the writing position, when the knocking cam 14 retracts, only the knocking cam 14 retracts. However, when the rotating cam 12 is moved rearward by the knocking operation to retract the refill 2 to the non-writing position, the outward projection 20 and the inward projection 21 engage with each other and the rotating cam 12 moves rearward together with the knocking cam 14.
The pressurizing mechanism is mainly constituted by a refill holder 23, an elastic airtight member 24, a return spring holder 25 and a compression cylinder 26. The refill holder 23 (
At the inner end part of the small diameter part 28, projections 29 extending in a radial direction are disposed so as to allow contact with the rear end edge of the refill, but preventing close contact and allowing ventilation. The small diameter part 28 opens backward through an opening part 30, and at its rear end, an elastic member 31 made of a soft material such as elastomer is integrally disposed in a two-color (double mold) molding fashion, and the elastic member 31 is designed to slidably contact with the inner face of the compression cylinder 26. This structure provides an air vent path 32 running between the outer periphery face of the refill 2 and the inner periphery face of the refill holder 23 from the opening 30 (
Further, on the periphery of the small diameter part 28 of the refill holder 23, an engagement groove 33 is formed in an annular shape, a raised part 34 is formed at the forward portion of the engagement groove 33, and a locking click 35 is provided as a protrusion. Here, the elastic member 31 may be produced separately from the refill holder 23. In this instance, a substantially cylindrical-shape elastic member (not shown) is produced and this elastic member is installed at and connected to the rear end of the refill holder.
At the forward portion of the small diameter part 28 of the refill holder 23, a large diameter part 37 is formed via a shoulder part 36, and a slant face 38 is formed on a corner part of an inner portion of the large diameter part 37 which communicates to the small diameter part 28. On the rearward periphery of the large diameter part 37, a locking click 39 is formed and slidably engages with the long hole 18 of the stationary cam 7 to permit back and forth movement of the refill holder 23 and prevent detachment of the refill holder 23. At the circumference of the large diameter part 37, a control hole 40 is formed for connection to the return spring holder 25, and on the inner face of its forward end, a raised part 41 is disposed to hold the return spring holder 25 in a stable state.
Into the front part of the refill holder 23, the return spring holder 25 having the airtight member 24 is inserted (
In the state where the return spring holder 25 is inserted into the refill holder 23, the slant face 43 of the airtight member 24 faces the slant face 38 formed on the refill holder 23. The return spring holder 25 is movable backward and forward and is urged backward by a return spring 48 to the position where a flange 46 of the return spring holder 25 abuts on a stopper 47 in the barrel as shown in
Since the locking click 49 is loosely fitted to the control hole 40, when the return spring holder 25 abuts on the stopper 47 at the front end of the stationary cam, the refill holder 23 can slightly move in an axial direction (back and forth directions) in a predetermined range up to the position where the end edge of the control hole 40 formed on the refill holder 23 abuts on the locking click 49 (
The compression cylinder 26 has, as shown in
At the inner face end part of the large diameter part 50, an annular projection 54 is disposed so that the elastic member 31 disposed at the rear end of the refill holder 23 can be closely contacted with the annular projection 54 to further securely keep the airtight condition. At the outer periphery face of the rear portion of the large diameter part 50, rotation-preventing projections 55 extending in an axial direction are disposed so that the projections 55 can enter between inward projections 17 extending in an axial direction of the stationary cam 7 to prevent rotation of the compression cylinder 26. At the intermediate part of the large diameter part 50, long holes 56 are formed into which the locking clicks 35 disposed at the periphery of the refill holder 23 can enter for preventing detachment. On the periphery of the small diameter part 52, an annular locking click 57 is formed, and when it is inserted into the rotating cam 12, although the rotation of the rotating cam 12 is not transferred, the compression cylinder 26 and the rotating cam 12 are connected so that they can move axially back and forth in unison (
At the shoulder part 51 of the compression cylinder 26, a plurality of rounded raised parts 58 extending in a radial direction are formed to facilitate rotation of the rotating cam 12 which abuts the rear end of the compression cylinder. In this instance, as shown in
The compression cylinder 26 and the refill holder 23 are connected by a releasable connecting means which connects the compression cylinder 26 and the refill holder 23 so that when the compression cylinder 26 advances, the compression cylinder 26 and the refill holder 23 can advance together as a unit until the refill holder 23 engages with and presses on the airtight member 24, and then only the compression cylinder 26 can continue to advance in an axial direction until it engages with the shoulder part 36 of the refill holder 23 following which the compression cylinder and the refill holder can again advance together as a unit. The releasable connecting means may be constituted in various manners. In the example shown in
With reference to
By this structure, the refill holder 23 and the compression cylinder 26 are connected so that they can advance forwardly together. When the compression cylinder 26 advances to the position where the outward projections 62 no longer contact the inward projections 17 of the stationary cam 7, the front end of the compression cylinder 26 radially expands to its normal state, and the locking projections 63 detach from the engagement groove 33. The front end of the compression cylinder 26 is thereby radially expanded beyond the raised part 34 of the refill holder 23, and the connection of the refill holder 23 and the compression cylinder 26 is released. When the compression cylinder 26 further advances, the pressing end 60 abuts on the shoulder part 36 of the refill holder 23 and the refill holder can be advanced again by continued advancement of the compression cylinder.
As the releasable connecting means, other suitable mechanisms may be employed. For example, a mechanism similar to a chuck mechanism of the usual knocking-type mechanical pencil may be used. In this instance, the front end of the compression cylinder is formed elastically in outwardly expandable fashion like a collet chuck, and a clutch ring is fitted like a clutch ring of a chuck mechanism around the front end to enable radial opening and closing so that the compression cylinder can chuck the small diameter part of the refill holder. By radially closing the front end of the compression cylinder by the clutch ring, the refill holder is connected to the compression cylinder and they advance together until the refill holder engages and presses against the airtight member. By constituting this mechanism in such a manner that after the refill holder presses against the airtight member, the clutch ring abuts on a suitable stopper and its movement can thereby be stopped, the chuck is opened and the connection of the refill holder and the compression cylinder is thereby released, and the movement of the refill holder is stopped. Since the compression cylinder further advances thereafter, the pressing end of the compression cylinder can be positioned close to the shoulder part of the refill holder. When the pressing end of the compression cylinder abuts on the shoulder part of the refill holder, the refill holder can be moved again by continued movement of the compression cylinder.
The operation of the pressurizing-type pen will be explained below with reference to
As shown in
When the compression cylinder 26 further advances, as shown in
When the pressing end 60 of the compression cylinder 26 comes into contact with the shoulder part 36 of the refill holder 23 or the elastic member 31 at the rear end of the refill holder 23 abuts on the bottom of the compression chamber 53 (
When the knocking part 15 is knocked in the writing state, the rotating cam 12 retracts via the knocking cam 14 as shown in
After the pressure in the compression chamber 53 is reduced, the compression cylinder 26, refill holder 23 and refill 2 further retract, but when the end edge of the control hole 40 formed at the large diameter part 37 of the refill holder 23 is hooked by the locking click 49 on the return spring holder 25, the retracting movement is stopped, and the refill holder 23 stays at this position (see
In the above example, the inward projections 17 on which the outward projections 62 of the compression cylinder 26 abut are formed on the inner face of the stationary cam 7. However, the inward projections may be directly formed on the inner face of the barrel 1 in such a manner that the outward projections of the compression cylinder 26 abut on the inward projection (not shown). Further, the stopper on which the flange of the return spring holder abuts is formed at the front end of the stationary cam. However, a suitable stopper may be disposed on the inner face of the barrel.
Number | Date | Country | Kind |
---|---|---|---|
2011-193633 | Sep 2011 | JP | national |
Number | Name | Date | Kind |
---|---|---|---|
3075497 | Tate | Jan 1963 | A |
3415603 | Blanchard | Dec 1968 | A |
7128491 | Kobayashi | Oct 2006 | B2 |
7604427 | Taniguchi | Oct 2009 | B2 |
7819601 | Taniguchi | Oct 2010 | B2 |
8511925 | Noguchi | Aug 2013 | B2 |
Number | Date | Country |
---|---|---|
2005138356 | Jun 2005 | JP |
2005246648 | Sep 2005 | JP |
Number | Date | Country | |
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20130058703 A1 | Mar 2013 | US |