1. Field of the Invention
The present invention is related to the field of folding knives, and in particular to folding knives having sealed pivot and locking mechanisms.
2. Description of the Related Art
Folding knives have been popular for centuries because of their relative safety and convenience. They have found use in an extremely wide range of applications, and are especially popular among sportsmen and individuals who work outdoors. Many folding knives, especially larger knives or those subjected to strenuous use, are provided with a lock that must be released before the blade can be closed. This enhances the safety of such knives, and further reduces the likelihood of injury.
One difficulty that has been encountered is that the pivot mechanism of many folding knives is prone to fouling due to the introduction into the mechanism of contaminants such as mud, sand, fine grit, organic matter, etc. The contaminants can interfere with opening or closing of the blade, and, in cases where the knives are not easily disassembleable, can be very difficult to clean. This can also damage the knife if not removed.
According to various embodiments, a pivot mechanism of a folding knife is effectively sealed from contaminants. According to one embodiment, the folding knife has a handle having first and second handle elements and a blade coupled to the handle and configured to rotate around a pivot axis between an open position and a closed position. An annular blade seal is positioned between the blade and the first handle element and contacting an inner surface of the first handle element so as to substantially seal a space between the blade and the first handle element and circumscribed by the blade seal.
First and second control pins are coupled to the blade within the circumference of the blade seal so as to extend toward the first handle element. A lock plate is movably coupled to the first handle element and configured to engage the first and second control pins when the blade is in the open and closed positions, respectively, such that the lock plate resists movement of the blade away from the open and closed positions when engaged, respectively, with the first and second control pins.
A release knob coupled to the lock plate permits a user to move the lock plate to release engagement with the blade. A seal is positioned between the release knob and the first handle element to seal a space between the release knob and the first handle element.
For the purposes of clarity and ease of comprehension, directional terms such as, for example, top, bottom, right, and left may be used in describing embodiments, and will be with reference to elements as they appear on the figures. Where elements are described using terms such as inner or outer, this is with respect to a central plane of the knife, i.e., a plane that lies parallel to, and substantially centered between, the first and second frame members. Thus, a side of an element that lies closer to that center plane than another side of the element may be described as the inner side of the element. Additionally, an element or feature that lies closer to the axis of rotation of the blade than another element or feature may be described as being inside the other feature.
Elements that are, in the illustrated embodiment, substantially identical will be identified by identical reference numbers. Where it is necessary to distinguish between such identical elements in the description, letters will be used. Fasteners, which may be screws, rivets, pins, or other suitable devices such as are well known in the art, and which may or may not be identical, are indicated generically by reference number 140.
An embodiment will be described with reference to
The knife 100 includes a handle 102 and a blade 104. The handle 102 includes first and second frame members 106, 108 arranged in a spaced-apart relationship, with a space, or blade channel 105, between them. First and second handle overlays 110, 112 are affixed to outer faces of the first and second frame members 106, 108, respectively, by fasteners 140. A spacer 105 is positioned between the first and second frame members 106, 108 at a rear end of the handle 102, and a pocket clip 170 with a decorative knob 172 is coupled to the first frame member 106 by a fastener 140.
The blade 104 is coupled to the handle 102 so as to rotate around a pivot axis A with respect to the handle 102, between an open position, as shown in
The blade 104 includes a blade pivot aperture 126 formed coaxially with the pivot axis A, and control apertures 130a, 130b positioned some distance from the pivot axis A. The blade pivot aperture 126 and the control apertures 130a, 130b traverse the blade 104. Annular blade seal grooves 128 are formed in opposite faces of the blade 104, positioned coaxially with the pivot axis A. Thumb studs 137 are positioned on the blade 104 for access by a user, to assist in moving the blade 104 from the closed position to the open position.
In one embodiment, the thumb studs 140 are in the form of knurled discs coupled to the blade 104 by fasteners 140 that threadingly engage a splined sleeve that is pressed into a stud aperture formed in the blade 104. Other structures for thumb studs that serve a similar function are well known in the art, and are within the scope of the invention.
Frame pivot apertures 132 are provided in each of the first and second handle frame members 106, 108, and each of the first and second handle overlays 110, 112 is provided with an overlay pivot aperture 134. The pivot apertures 132 and 134 are positioned so as to be substantially coaxial with the pivot axis A when the knife 100 is properly assembled.
The blade 104 is pivotably coupled to the handle 102 by a blade pivot 114. The blade pivot 114 includes an internally threaded pivot tube 122 and pivot screws 116. The pivot screws 116 have enlarged heads 118, and shafts 120 that are threaded to engage the inside wall of the respective ends of the pivot tube 122. The pivot tube 122 has a central region 121 that has a first diameter, and end regions 123 that have a smaller, second diameter. A ridge or shoulder 125 is thereby formed near each end where the diameter of the pivot tube 122 changes from the first diameter to the second diameter. The first diameter of the pivot tube 122 is greater than a diameter of the frame pivot apertures 132, while the second diameter is smaller.
Two pivot seal members 136 are positioned on the blade pivot screws 116. As shown in
When the knife 100 is assembled, as shown in detail in
In one embodiment, the minimum distance between the first and second handle frame members is fixed by the length of the central region 121 of the pivot tube 122, i.e., the distance between the shoulders 125 of the pivot tube 122. Accordingly, this distance can be selected to be slightly greater than the sum of the thicknesses of the blade 104 and the flat bushings 138, such that, regardless of the degree to which the pivot screws 116 are tightened, the blade 104 will retain a selected minimum amount of freedom of movement. On the other hand, if the length of the central region 121 is equal to, or less than the sum of the thicknesses of the blade 104 and the flat bushings 138, the degree of freedom of movement of the blade 104 will be more directly controlled by the degree to which the pivot screws 116 are tightened.
According to an alternate embodiment of the invention, the pivot tube 122 has only one outer diameter, equal to the second diameter of the pictured embodiment, such that there are no shoulders. Other embodiments employ more conventional pivots such as are well known in the art. In these embodiments, as well, the degree of tension applied to the pivot controls the degree of freedom of movement of the blade.
Controlling the freedom of movement of the blade by providing more or less tension on the pivot is well known in the art, and is a feature of many folding knives currently available. However, a problem with this method is that, frequently, a knife pivot cannot be tightened to a degree sufficient to lock a pivot screw in place, without exerting excessive pressure and drag on the blade, and making it difficult to move the blade between the open and closed positions. As a result, the pivot screw will tend to loosen over time. According to the present embodiment and other embodiments that employ pivot seals, this problem is substantially overcome. The pivot seal members 136 are O-rings formed of an elastomeric material, and dimensioned such that, when the enlarged heads 118 of the pivot screws 116 are positioned in overlay pivot apertures 134 with the pivot seal members 136 therebetween, the pivot seal members 136 resiliently press against the outer rims of the enlarged heads 118 of the pivot screws 116 and the inner rims of the overlay pivot apertures 134, exerting a degree of friction between the pivot screws 116 and the respective handle overlays 110, 112 sufficient to prevent the pivot screws 116 from spontaneously loosening.
Annular blade seal members 142 are positioned in the blade seal grooves 128, and are dimensioned so as to make contact with the inner surfaces of the first and second frame members 106, 108. As shown in
Because the blade seal members 142 are annular, and are positioned coaxially with the pivot axis A, the sweep rims 143 follow a continuous circular path around the pivot axis A on the inner surfaces of the frame members 106, 108 as the blade 104 rotates between the open and closed positions. As a result, not only do the blade seal members 142 prevent contaminants from being introduced into the pivot mechanism of the knife, but the sweep rims 143 move continually on a clean surface, and so are not required to move contaminating particles away. They are therefore not subject to a high degree of abrasion or wear while the blade moves, even in environments that would tend to introduce very abrasive particles into the knife.
In tests performed by the inventors, a folding knife that included blade seal members similar to those described above was moved through repeated cycles between the open and closed positions while immersed in extremely fine sand and grit. The knife was then disassembled and examined. No contaminating grit was found inside the mechanism, and no appreciable wear to the blade seal members was detected. The seals are also liquid tight. Tests were also conducted underwater and no water was found to have entered the inside of the mechanism. In high grit environments, such as the desert, or under messy conditions, such as cleaning a game animal or fish, mud, grit, blood, fur, or other contaminants are kept out of the moving mechanism of the knife and it is easy to clean.
According to an alternate embodiment, the blade seal groves are formed in the inner faces of the first and second frame members, and the blade seal members are positioned in the blade seal grooves so as to make resilient contact with opposing faces of the blade.
In one embodiment, a locking mechanism 150 is provided to retain the blade 104 in the open and closed positions. The locking mechanism includes a lock plate 154 having a notch 153, with first and second sides 155, 157, and positioned, in the pictured embodiment, in a cavity 152 formed in the first frame member 106. The cavity 152 is sized to permit translational movement of the lock plate 154, and biasing means are provided to bias the lock plate 154 substantially toward the pivot axis A. In the pictured embodiment, the bias means comprises springs 162 and guide rods 160, but a wide variety of mechanisms may be employed as biasing means, and substituted for the springs, such as, for example, flexible rods, leaf springs, torsion springs, etc. The locking mechanism also includes first and second control pins 144a, 144b positioned in the control apertures 130a, 130b, respectively, and a release knob 156 coupled to the lock plate 154 by fasteners 148, and accessible to a user via a knob aperture 143 formed in the first handle overlay 110.
Operation of the locking mechanism 150 will be described with reference, in particular, to
As previously described, the blade 104 is provided with control apertures 130a, 130b. The first and second control pins 144a, 144b are positioned in respective control apertures 130a, 130b, and extend from the blade 104 into the pin race 146. As the blade rotates between the open and closed position, the control pins 144a, 144b slide within the pin race 146 in an arc around the pivot axis A. One or both of the first and second ends 147, 149 of the pin race 146 may be configured to serve as rotation stops for the blade 104, to limit movement of the blade 104 to an arc of travel between the open and closed positions.
In order to move the blade 104 away from the open position, it is necessary that the lock plate be manually moved out of engagement with the first control pin 144a. A user does this by sliding the release knob 156 in a direction away from the pivot axis A while moving the blade 104 away from the open position. On the other hand, when the blade 104 is moved into the open position, the first control pin 144a approaches engagement with the lock plate 154, and pushes against an end face of the lock plate 154, applying force at a vector that easily moves the lock plate 154 rightward a distance sufficient to permit passage of the first control pin 144a. Thus, as configured in the present embodiment, the blade 104 moves easily into the open position and is automatically locked there until it is manually released for movement toward the closed position.
In the illustrated embodiment, the first end 147 of the pin race 146 defines the limit of travel of the blade 104 in the clockwise direction. When the blade is moved to the open position, the second control pin 144b makes contact with the first end 147 of the pin race 146, which prevents further movement. The notch 153 of the lock plate 154 has a shape such that the first side 155 of the notch 153 engages the first control pin 144a before the lock plate 154 reaches the leftmost end of the cavity 152. This allows the lock plate 154, in engagement with the first pin 144a, to cooperate with the first end 147 of the pin race 146, in engagement with the second control pin 144b, to provide a solid lock to the blade 104, substantially without play.
According to an alternate embodiment, an additional pin race is provided in the inner face of the second frame member 108. The additional pin race may be configured to receive only one, or both of the first and second control pins 144a, 144b, and provide additional rotation stops, to reduce asymmetrical forces acting on the blade 104.
According to one embodiment, the required biasing force is selected such that, in normal operation, when a user applies a force sufficient to overcome the resistance of the lock plate 154, the same force is sufficient to move the blade 104 all the way to the open position. The force applied to start movement of the blade from the closed position toward the open position will cause the blade to complete the movement without further effort. Thus, a user may press against a thumb stud or some other feature of the blade until the blade begins to move, and the blade will thereafter complete the movement independently.
An example of a suitable blade feature against which a user may press to open the blade is an element sometimes referred to as a flipper. This is an enlarged portion of the blade that extends from a back part of the handle when the blade is in the closed position, such that pressure against the enlarged portion will move the blade away from the closed position. A number of terms are used in the art to refer to this enlarged portion, including flipper, trigger, kicker, ridge, etc. One example of such a feature is described in U.S. Pat. No. 6,338,431, which is incorporated herein by reference, in its entirety.
According to an alternative embodiment, the second side 157 is shaped such that the blade 104 cannot be moved toward the open position without manual movement of the lock plate 154, in a manner similar to that described above with reference to first side 155. The first side 155 of the notch lock plate may also be configured to act as a detent, allowing the blade to be moved away from the open position when sufficient force toward the closed position is applied to the blade. In the case of an embodiment in which the knife 100 is provided with an automatic opening mechanism, the locking mechanism may be configured to provide a manual release for automatic opening of the blade, as well as a lock to prevent the blade from inadvertent closure.
A bellows seal 158 is provided around the release knob 156, as shown in
According to the illustrated embodiment, the first and second handle overlays 110, 112 are affixed to the first and second frame members 106, 108 by fasteners 140 such that substantially planar inner surfaces of the handle overlays are in direct and firm contact with substantially planar outer surfaces of the frame members. The inventors have determined that such a configuration is sufficient to provide a reliable seal between the overlays and the frame members. According to an alternate embodiment, a thin gasket seal is provided between the overlays and the frame members. Such an arrangement may be desirable where the knife is intended for use where it will be under water for long periods, or under increased pressure, such as in diving, to prevent water from working between the overlays and frame members. In that embodiment, the bellows seal may be formed as an integral portion of the gasket seal.
Many variations on the disclosed embodiments can be made within the present invention. Some embodiments do not include all the elements of the disclosed embodiments, and some combine elements disclosed here with more conventional aspects. For example, in the embodiment shown, the blade channel extends through the knife, from the top side to the bottom, with only the pivot and the spacer extending between the first and second frame members. This arrangement is advantageous because it minimizes the places where foreign matter can gather. Nevertheless, such an arrangement is not essential to the invention. Other embodiments may include a channel that is open only at the bottom of the knife. Furthermore, the locking mechanism described here can be used in a knife that does not employ the seals, and, conversely, various ones of the disclosed sealing mechanisms may be employed in knives that use more conventional locks.
Some of the features of the embodiments disclosed above are grouped into elements and sub-elements for convenience. For example, a locking mechanism is described as including a number of individual components. Where claims recite similar elements, such claims should not be construed as including the same sub elements unless the sub-elements are explicitly recited as members of the recited elements.
The abstract of the present disclosure is provided as a brief outline of some of the principles of the invention, according to one embodiment, as an aid to searching. The abstract is not intended as a complete or definitive description of any embodiment thereof, nor should it be relied upon to define terms used in the specification or claims. The abstract does not limit the scope of the claims.
From the foregoing it will be appreciated that, although specific embodiments of the invention have been described herein for purposes of illustration, various modifications may be made without deviating from the spirit and scope of the invention. Accordingly, the invention is not limited except as by the appended claims.
This application claims the benefit of U.S. Provisional Patent Application No. 60/765,754 filed Feb. 6, 2006, where this provisional application is incorporated herein by reference in its entirety.
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