The present disclosure relates generally to a writing utensil with a writing tip that may be retracted into the body, and more particularly to a valve that stores the writing tip when the tip is retracted into the body.
Various known writing utensils have a fibrous writing tip, or nib, and a reservoir filled with liquid ink in communication with the nib. In general, these writing utensils, e.g., markers and pens, include a separate cap that releasably attaches to the body of the writing utensil to cover and seal the nib in a substantially air-tight manner. In this way, the liquid ink disposed in the nib and the reservoir does not evaporate, and the writing utensil does not dry out. While the cap is successful in keeping a tight seal over the nib and keeping the writing utensil functional, the writing utensil will inevitably dry out and be ruined if the cap is lost.
To address this issue, the so-called “cap-less” maker has been devised. In certain cap-less markers, the nib is retractable from an extended writing position, in which the user can write with the marker, to a retracted or withdrawn position, in which the nib is stored in a valve. The valve generally includes a valve door which substantially seals the nib inside the valve when the marker is in the retracted position. The valve door opens up to allow the nib to extend o of the body of the marker into the writing position so the user can write with the marker.
U.S. Pat. No. 5,048,990 to Hashimoto describes a cap-less marker that has been successfully commercialized. In the commercialized version of this marker, the nib is a large fiber-type tip, and the valve is made entirely from a thermoplastic elastomer, also known as TPE. While a TPE valve can generally provide a good seal between the valve body and the valve door, many TPE's have poor vapor barrier properties. Thus, solvent vapor from the ink is likely to permeate through the walls of the valve so as to dry out the nib/tip. Further, all-TPE valves may exhibit poor structural integrity over time. For example, the commercialized Hashimoto valve is subject to loading applied by a spring and a string when the writing tip/nib is in the retracted (or sealed) position. Over time, the TPE material begins to creep and the valve deforms. This deformation can inhibit the valve's ability to maintain an air-tight seal between the valve body and the valve door.
In the case of a marker including a (relatively) large, fibrous nib, a valve made from TPE generally works adequately. In such markers, the large nib retains a large volume of ink and has a relatively large wick portion in fluid communication with an ink reservoir. The wick portion includes many capillary channels, which allows a large volume of ink to travel from the reservoir to the writing tip. Thus, the nib can generally replenish any ink within the nib/tip that evaporates so that the nib does not dry out, and the writing utensil is not ruined. However, consumers are demanding permanent markers with an ultra-fine tip, instead of a large fiber-type tip, for everyday writing. Such a marker has a much smaller nib/tip made from an extruded plastic, includes very small capillary channels, and has a smaller. wick portion in fluid communication with an ink reservoir.
An all-TPE valve is generally not satisfactory for an ultra-fine tip due to ink vapor permeating through the valve walls. An ultra-fine tip has very small capillary channels where very little ink is present. Because only a small amount of ink permeation or evaporation will clog the tip, this construction is vulnerable to ‘hard starting,’ and susceptible to complete dry-out. Hard start means the marker struggles to write initially with little or no ink being deposited on the paper. Consequently, dry-out is of greater concern for such ultra-fine markers (relative to markers including a large, fibrous nib/tip).
While the devices and methods described herein are susceptible to various modifications and alternative constructions, certain illustrative embodiments have been shown in the drawings and will be described below in detail. It should be understood, however, that there is no intention to limit the invention to the specific forms disclosed. On the contrary, the intention is to cover all modifications, alternative constructions, and equivalents falling within the spirit and scope of the disclosure.
Referring now to
Referring now to
The nib subassembly 46 includes a nib 66, a metal nib adapter 68, and a nib tube 70 surrounding the nib 66. The nib 66 extends from the writing tip 38 back through a hole 74 in the reservoir holder 54 such that it is disposed within the reservoir 56 to permit transport of ink stored in the reservoir 56 to the writing tip 38. The reservoir 56 in this example is a conventional capillary reservoir. A free ink reservoir with a capillary buffer to s ore the excess ink could also be used. The nib 66 can be an extruded plastic tube with a single channel extending the length of the nib 66. The cross section of the channel can be in the shape of a snow flake. Such nibs can be obtained from a variety of sources including Teibow, Ltd. (Japan) and AuBEX Corp. (Japan). Suitable nibs may include Teibow model numbers PN-C, PN1-D, PH-C, PH1-D, PH5-D, PH5, PN1-D, PH2-D, PO, and PH. They can be made from a homopolymer or a copolymer, and more specifically, a polyacetal homopolymer or a polyacetal copolymer. A nib porosity of greater than about 15% has been found to be effective. A nib porosity of greater than about 25% is preferred. Additional suitable extruded nibs manufactured by the AuBEX Corp. may include DH/DB, F type, FX type, HA type, IL type, IX type, JA type, JC/JD type, JH type, JQ type, MA type, MC./MD type, MO type, NZ, PA-X series, PA type, PB type, PD A type, PD type, PF/SK type, PL/PU type, PS type, PW type, PY type, SA type, k VA type, VE type, and VS type. Alternatively, the valve could be used in combination with fibrous nibs comprising nylon, acrylic, or polyester fibers.
The metal nib adapter 68 is disposed on the nib 66 near the writing tip 38. The nib tube 70 is connected to the metal nib adapter 68. The nib tube 70 surrounds the nib 66 and extends from the nib adapter 68 near the writing tip 38 to inside the hole 74 in the reservoir holder 54. The nib tube 70 can be made of metal and provides strength to the nib 66 such that it does not buckle when a user applies pressure on the writing tip 38. The nib tube 70 further seals the ink within the nib 66 between the reservoir 56 and the nib adapter 68.
The collar 50 is disposed on the reservoir holder 54, and the spring 48 is disposed about the nib tube 70 between the collar 50 and the valve 44 such that the spring 48 biases the collar 50 away from the valve 44. The string 52 is at ached to the collar 50 on both its first end 76 and its second end 78. The string 52 can be attached to the collar 50 in any known way, and in this example, the collar 50 includes a first slot 80 and a second slot 82, and the string 52 includes a first knot 84 on the first end 76, and a second knot 86 on the second end 78 wherein the knots 84, 86 each have a diameter that is larger than the width of the slots SO, 82. Thus, when each end 76, 78 of the string 52 is placed in the slots 80, 82, the knots 84, 86 maintain the string in the slots 80, 82. From the first end 76, the string 52 extends toward and through a first string guide 88 on the valve 44, around the door 64 and through a string holder 90 in the door 64, back through a second string guide 92 on the valve 44, and through the second slot 82 on the collar 50 (string guides and string holder are not shown in
The reservoir holder 54 is a concentric tubular member extending back about the circumference of the reservoir 56 toward the actuation end 24 that has an open rear end 94 through which, during manufacture of the marker 20, the reservoir 56 is inserted. A plug 96 is disposed in the open rear end 94 of the reservoir holder 54 to seal the reservoir 56 within the reservoir holder 54. A spring 98 can be disposed between the plug 96 and the reservoir 56 to bias the reservoir 56 to the forward end of the reservoir holder 54 to ensure the greatest amount of contact between the nib 66 and the reservoir 56.
The plug 96 includes a shaft 100 extending toward the actuation end 24, and a plunger 102 is disposed on the shaft 100. A spring 104 is disposed between the plunger 102 and the actuator 28. The plug 96, plunger 102, spring 104, and actuator 28, when coupled as shown in
In the writing position shown in
In a third embodiment, the string 52 itself pushes the door 64 open when the marker 20 is actuated, and the nib 66 does not touch the door 64. In one non-limiting example, a fluorocarbon monofilament string with a diameter of between about 0.20 mm and about 0.35 mm, about 0.22 mm and about 0.32 mm or about 0.25 mm, e.g., 0.27 mm, has sufficient rigidity to push the valve door 64 open. Other combinations of material and diameter can be used in any of the foregoing embodiments. In a further embodiment, the string 52 can be replaced with a cam mechanism to open and close the valve door 64.
While a single embodiment of marker 20 is generally shown herein, the marker 20 can generally be constructed in any of the constructions shown in Hashimoto, U.S. Pat. No. 5,048,990, the description of which is incorporated by reference. In other words, the valve 44, as detailed below, can be incorporated into any of the marker embodiments shown in the '990 patent with only minor modifications as would be seen by one of skill in the art. Accordingly, the valve 44 can be used in combination with larger fibrous nibs in addition to the extruded plastic nib 66 exemplified herein. Additionally, the valve can be used in combination with otherwise conventional ball point pens.
Referring now to
As can best be seen in
As best seen in
The valve 44 is made from a first material 128, generally shown as white in
The second portion 131 of the valve 44 includes the inner seal 122 and the circumferential ridge 124 disposed in the circumferential recess 134 of the first portion 129. The second portion 131 further generally includes a plug 144 disposed in the gate 138, a door seal 146 disposed within the circumferential seat 132, and a runner 148 disposed within the channel 136 and connecting the door seal 146 and the inner seal 122. Finally, the second portion 131 may further include the string holder 90 of the door 64 and a pair of outer hinges 150 connecting the string holder 90 to the door seal 146 and disposed on either side of the inner hinge 142. As exemplified herein, all of the components of the second portion 131 are made of the second material 130. As explained in further detail below, however, the material construction of these components may be varied in accordance with the teachings of the present disclosure.
The valve 44 can be manufactured in a two-step injection molding process, also known as two-shot molding. In a first step, the first material 128 can be injection-molded to form the components of the first portion 129 of the valve 44. The first material 128 can be injected such that it forms the flange 58 first, then the valve body 62, then flows through the inner hinge 142 and forms the door 64. This sequence of the flow of the first material 128 during injection is but one example, and other sequences could also be used. In a second step, the second material 130 can be injection molded onto the first material 128 to form the second portion 131 of the valve 44. The second material 130 can enter through the gate 138, flow into the circumferential recess 134, and form the inner seal 122. The second material 130 can then flow through the channel 136 of the first portion 129 to form the runner 148, and then into the circumferential seat 132 to form the door seal 146. The second material 130 can then flow over the inner hinge 142 of the first material 128 to form the outer hinges 150 and onto the door 64 to form the string holder 90. Again, this sequence of the flow of the second material 130 during injection is but one example, and other sequences could be used. The combination of two materials allows advantageous properties of each material to be used in the valve 44 and, more specifically, in the valve body 62 and door 64.
It has been found that the first material 128 can be a relatively hard thermoplastic material such as polypropylene (PP), and the second material 130 can be a thermoplastic elastomer (TPE). Because both PP and TPE can take many chemical formulations, the two ultimately selected materials should be chemically compatible such that they are able to be molded into a single part on a single molding press. The first material 128 should provide moldability, vapor barrier properties, and low cost. The second material 130 should have compatibility with the first material 128 to ensure a good bond between the two during the molding process, high lubricity to minimize dynamic friction, and a durometer in the range of about 60A-100A, preferably 70A-90A, or more preferably about 80A to provide structural stability while being soft enough to provide effective seals. Both materials should have melt flow rates and other properties to allow molding through a living hinge. Other thermoplastic materials may also be used for the first material 129, including polyethylene, HDPE, Nylon, PVC, etc., provided that they satisfy the necessary moldability, vapor barrier properties, and cost considerations. A variety of TPE's can be used for the second material 131, provided that they satisfy the necessary molding and sealing characteristics. Useful PP's may include Model No. P4C6Z-022 and Model No. P4C6B-024B, both made by Huntsman International (Woodlands, Tex.), Model No. HM35Z2 made by Arco Chemical Company (Newtown Square, Pa.), and Marlex HLN-350 made by Phillips Sumika Polypropylene Company (Woodlands, Tex.). Useful TPE's may include Santoprene 101-73, Santoprene 101-80, Santoprene 101-87, Santoprene 8201-70, Santoprene 8201-80, Santoprene 8201-90, and Santoprene 8211-75, made by Advanced Elastomer Systems, L.P. (Akron, Ohio), Dynaflex G2780-0001, Dynaflex G7980-1001-00, Model No. LC290-105, Model No. LC293-116, and Model No. LC248-045, made by GLS Corp. (McHenry, Ill.), KU2-865 and KU2-8770, made by Bayer Material Science (Pittsburgh, Pa.), Estagrip ST70A and ST80A, made by Noveon, Inc. (Cleveland, Ohio), and Monprene MP-2890M, Monprene MP-2870, Monprene MP-2228, Monprene MP-1885-J, and Monprene MP-2780, made by Teknor Apex Company (Pawtucket, R.I.).
In other embodiments not shown, the hinge 112 can be made from a single material (either the first material 128 or the second material 130), or the outer hinge 150 could be PP (or another suitable first material 128), while the inner hinge)42 could be TPE (or another suitable second material 130). Also, the runner 148 can be placed at different locations on the inner surface 110 of the valve 44, or could be placed on the outer surface 140 of the valve 44, or even multiple runners 148 could be used. If no runner 148 is used, then the inner seal 122 would be separated from the door seal 146, and two injection gates would be required. Further, the valve 44 could be made by injecting the second material 130 at multiple locations. In this case, the channel 136 and the runner 148 may not be necessary, and a second gate similar to the gate 138 would be disposed on the front end 106 on the valve body 62. The string holder 90 could be made of PP, and the door seal 146 could be disposed on the door 64 instead of the valve body 62. As an alternative to the two-shot injection molding process, the valve 44 could be constructed of separate pieces and then assembled. For example, the inner seal 122 could adhere to or otherwise couple to the circumferential recess 134 and the door seal 146 can be similarly coupled to the circumferential seat 132.
Furthermore, the embodiment disclosed herein depicts the valve 44 in use with a marker 20. Those of skill in the art will see that the disclosed valve 44 can be used in other writing utensils, such as ball point pens. Further, the disclosed valve 44 may prove useful in correction fluid dispensers, paint applicators, and other products completely outside of the writing implement field.
Numerous additional modifications and alternative embodiments of the invention will be apparent to those skilled in the art in view of the foregoing description. This description is to be construed as illustrative only, and is for the purpose of teaching those skilled in the art the best mode of carrying out the invention. The details of the structure and method may be varied substantially without departing from the spirit of the invention, and the exclusive use of all modifications which come within the scope of the appended claims is reserved.
This is a continuation of U.S. patent application Ser. No. 11/654,959 (now U.S. Pat. No. 7,850,382), filed Jan. 18, 2007, the entire respective disclosure of which is incorporated by reference in its entirety.
Number | Date | Country | |
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Parent | 11654959 | Jan 2007 | US |
Child | 12968265 | US |