The following U.S. Patents are incorporated by reference:
Attached hereto is a document entitled “Appendix A: Background Information” (16 pages) with the following subsections:
Also attached hereto is a document entitled “Novel Low-Temperature CVD Process for Silicon Carbide MEMS,” by C. R. Stoldt, C. Carraro, W. R. Ashurst, M. C. Fritz, D. Gao, and R. Maboudian, Department of Chemical Engineering, University of California, Berkeley, Calif. 94720 USA (4 pages). This document is also to be considered a part of this application and is hereby incorporated by reference.
The present invention relates in general to firearms, and in particular to a firearm made from a molded diamond material.
From shotguns to rifles to handguns, firearms have proven to be a valuable tool for law enforcement and self defense. Sadly, however, firearms have also proven to be a valuable tool for criminals, who use them to threaten, injure, or murder their victims. Too often, the criminals cannot be identified, either because the weapon that fired a bullet cannot be reliably identified or because the weapon was stolen from its owner and the shooter cannot be reliably connected to the weapon. In addition, many people are injured or killed each year through accidental discharge of firearms, including children playing with a parent's gun.
Attempts to solve these problems include trigger locks and ballistic fingerprinting. While they are of some help, both solutions are imperfect. Trigger locks, for example, keep unauthorized users (particularly children) from operating a firearm, but they can also interfere with legitimate users' ability to respond quickly to a deadly threat. Further, because a criminal can steal a firearm and remove the lock at his or her leisure, trigger locks do little to prevent stolen firearms from being used in further crimes.
Ballistic fingerprinting attempts to match grooves imparted to a bullet by a gun barrel to the barrel of a particular firearm. The technique is sometimes successful; however, it has been demonstrated that over time, the grooves imparted by a particular barrel can change (e.g., due to wear and tear if the gun is repeatedly fired); moreover, firearms manufacturers generally do not design their barrels to provide a unique signature, so differences are largely accidental, making ballistic fingerprinting, at best, an inexact science.
Therefore, it would be desirable to provide firearms with improved protection against unauthorized use and improved ability to identify a particular firearm as the source of a bullet.
Embodiments of the present invention provide firearms in which all or some of the component parts are made of synthetic diamond materials. In some embodiments, the firearm includes a specially designed trigger capable of verifying a user's identity so that only an authorized user can discharge the firearm. For example, the firearm can be programmed with a time sequence of pressures (which may vary or remain constant) that a user exerts on the trigger to activate the firearm.
In some embodiments, the firearm also includes a diamond barrel designed to impart a unique pattern of grooves to any bullet leaving the barrel, thereby facilitating reliable identification of the firearm that fired a particular bullet.
In still further embodiments, numerous other features are provided. For instance, in one embodiment, the firearm is held in the user's palm with the barrel extending between the user's second and third fingers. In another embodiment, the firearm has a cylinder with radially oriented chambers that can be loaded with a powder charge and a bullet (or shot wad or other type of ammunition) as the chamber rotates past a powder aperture and a bullet tube. The amount of powder in the charge can be regulated by regulating the speed at which the chamber rotates; piezoelectric or other suitable motors can be used to control rotation of the chamber.
In still other embodiments, the powder (or other propellant) charge is ignited by passage of a current through an electrically sensitive material at the base of the bullet (or other ammunition). An insulating diamond member that is made conductive through application of an ultraviolet light pulse can be used to gate or switch the current in response to operation of the firearm's trigger, initiating combustion of the propellant charge. In conjunction with the user recognition mechanisms described herein, this technique provides a reliable safety for the firearm.
The following detailed description together with the accompanying drawings will provide a better understanding of the nature and advantages of the present invention.
The related patent applications incorporated by reference above describe, inter alia:
In embodiments of the present invention, such techniques can be used to fabricate a firearm with all or some parts being made of synthetic diamond materials. In some embodiments, the firearm includes a specially designed trigger capable of verifying a user's identity, e.g., via a pressure-sensitive trigger coupled to computing and logic circuitry capable of recognizing a preprogrammed pattern of pressures on the trigger, so that only an authorized user can discharge the firearm. In some embodiments, the firearm also includes a diamond barrel designed to impart a unique pattern of grooves to any bullet leaving the barrel, thereby facilitating reliable identification of the firearm that fired a particular bullet.
As used herein, the term “diamond” or “diamond material” refers generally to any material having a diamond lattice structure on at least a local scale (e.g., a few nanometers), and the material may be based on carbon atoms, silicon atoms, boron atoms, silicon carbide, silicon nitride, boron carbide, boron nitride, or any other atoms or combination of atoms capable of forming a diamond lattice.
For example, a diamond material may include crystalline diamond. As is well known in the art, a crystal is a solid material consisting of atoms arranged in a lattice, i.e., a repeating three-dimensional pattern. In crystalline diamond, the lattice is a diamond lattice 100 as shown in
In other embodiments, the diamond material is an imperfect crystal. For example, the diamond lattice may include defects, such as extra atoms, missing atoms, or dopant or impurity atoms of a non-majority type at lattice sites; these dopant or impurity atoms may introduce non-sp3 bond sites in the lattice, as is known in the art. Dopants, impurities, or other defects may be naturally occurring or deliberately introduced during fabrication of a diamond part.
In still other embodiments, the diamond material is made of polycrystalline diamond. As is known in the art, polycrystalline diamond includes multiple crystal grains, where each grain has a relatively uniform diamond lattice, but the grains do not align with each other such that a continuous lattice is preserved across the boundary. The grains of a polycrystalline diamond material might or might not have a generally preferred orientation relative to each other, depending on the conditions under which the material is fabricated. In some embodiments, the size of the crystal grains can be controlled so as to form nanoscale crystal grains; this form of diamond is referred to as “nanocrystalline diamond.” For example, the average value of a major axis of the crystal grains in nanocrystalline diamond can be made to be about 100 nm or less.
In still other embodiments, the diamond material is made of amorphous diamond. Amorphous diamond does not have a large-scale diamond lattice structure but does have local (e.g., on the order of 10 nm or less) diamond structure around individual atoms. In amorphous diamond, a majority of the atoms have sp3-like bonds to four neighboring atoms, and minority of the atoms are bonded to three other atoms in a sp2-like bonding geometry, similar to that of graphite;
Thus, it is to be understood that the terms “diamond material” and “diamond” as used herein include single-crystal diamond, polycrystalline diamond (with ordered or disordered grains), nanocrystalline diamond, and amorphous diamond, and that any of these materials may include defects and/or dopants and/or impurities. Further, the distinctions between different forms of diamond material are somewhat arbitrary not always sharp; for example, polycrystalline diamond with average grain size below about 100 nm can be labeled nanocrystalline, and nanocrystalline diamond with grain size below about 10 nm can be labeled amorphous.
A diamond part may include multiple layers or components made of diamond material, and different layers or components may have different composition. For example, some but not all layers might include a dopant; different polycrystalline oriented layers might have a different preferred orientation for their crystal grains or a different average grain size; some layers might be polycrystalline oriented diamond while others are polycrystalline disoriented, and so on. In addition, coatings or implantations of atoms that do not form diamond lattices may be included in a diamond material.
A diamond part, such as the firearm described herein, may be fabricated as a unitary diamond structure, which may include crystalline, polycrystalline or amorphous diamond. Alternatively, the part may be fabricated in sections, each of which is a unitary diamond structure, with the sections being joined together after fabrication.
In operation, a force sensing trigger 201, which may include a piezoelectric or piezo resistive element (not shown but well known to those skilled in the art), is pressed one or more times in an activation sequence. The activation sequence includes a specific pattern of pressures or pulses on the trigger 201, and the pattern may be defined by reference to a relative duration of the pulses and/or relative force on the trigger as a function of time. The activation sequence is advantageously preprogrammed by the user, e.g., upon purchasing the firearm, and stored in memory in control and battery circuit 214. When trigger 201 is operated, signals representing the force as a function of time are transmitted to control and battery unit 214, which compares them to the activation sequence, with the firearm becoming usable only when the trigger operations match the preprogrammed activation sequence. This sequence acts as a “password” to prevent the firearm from being used by anyone other than an authorized user. In other embodiments, other user identification techniques, such as fingerprint or DNA matching, could be used instead of or in addition to the activation sequence described herein.
When the activation sequence is recognized by control and battery unit 214, a force and time pattern LED 204 is turned on, signifying that the user has been recognized and that the arm is ready for use. If there is no bullet or shot wad aligned with the barrel 205, then a portion of the light from LED 204 will be visible at 218. In some embodiments, light from LED 204 may also be visible at the muzzle end of barrel 205.
Targeting laser diodes 202, 203 may also be turned on at this time. In one embodiment, laser diodes 202 and 203 provide laser beams of different colors to guide the user's aim, compensating for trajectory, at two different distances. In another embodiment, laser diodes 202 and 203 may be distinguished by the projected shapes of their light beams (e.g., one might be round while the other is rectangular).
Pressing the trigger 201 again with a user-selected “loading” force will cause control and battery system 214 to load the firearm. Specifically, control and battery system 214 activates a rotation mechanism 210 (e.g., a piezoelectric motor that acts on a boss 211 on a surface of cylinder 209) to rotate the cylinder 209 at a predetermined speed past a powder column 208. As cylinder 209 rotates past column opening 208, an empty chamber 219 in cylinder 209 is charged with powder; the charge can be controlled by regulating the rotation speed of cylinder 209. A bullet 220 is then loaded on top of the powder charge in chamber 219. Further rotation puts the bullet in contact with a first set of bumps 213a at the inner end of barrel 205, which further seat the bullet until a bump 213b on the chamber comes into electrical contact with a third (center) bump on barrel 205 or with another electrical contact element, which may be located in barrel 205 or chamber 219 or on the surface of cylinder 209. In other embodiments, bumps and/or other contact elements are advantageously arranged on surfaces of barrel 205, cylinder 209, and/or chamber 219 such that a circuit is completed only when a bullet in a chamber 219 is properly aligned with barrel 205. When the circuit is completed, the weapon is ready to fire.
When trigger 201 is pressed again, a feedback signal (e.g., a vibration, acoustic wave, electrical signal, thermal change or any or all of the above) is advantageously passed through the trigger 201; where trigger 201 includes a piezoelectric element, the feedback signal can be driven electrically by the controller/battery 214. At this time the controller 214 also sends a high voltage pulse through the rotatable cylindrical section 209 that now contains bullet(s) 220 and powder in the radial chambers 219 along its circumference. Only the bullet aligned with the barrel 205 can complete the electrical circuit and ignite the powder, which drives the bullet 220 down the barrel 205.
In preferred embodiments, barrel 205 is rifled with a pattern unique to an individual firearm 200. An example rifling pattern 212 using grooves of two different widths is shown in
After a bullet is fired, the process can be repeated, with control and battery unit 214 operating piezoelectric rotator 210 in response to trigger 201 to rotate cylinder 209, thereby loading and positioning the next round. To unload firearm 200, operating trigger 201 by applying an “unload” sequence of pressures causes bottom flap 215 to open. Cylinder 209 is then rotated such that bullets 220 are passed down an ejection path 217 and ejected as shown.
The main body and other components of firearm 200 are advantageously made of a diamond material such as carbon-based diamond or silicon carbide. In some embodiments, the components are made of carbon-based diamond materials coated with silicon carbide. Various fabrication techniques can be used, including fabrication on sacrificial (e.g., barrel forms 205a, 205b, 205c) or reusable (e.g., half-cylinder form 205d) substrates formed to the desired shape of the component. The barrel is evenly coated with diamond to a sufficient depth (typically 150 microns) to provide adequate burst strength, machined at one end to match the curvature of the cylinder form, then put in place with other components that can be made by similar techniques. A final diamond coating may be grown to integrate and fix the various parts in position.
While all components of firearm 200 can be made of diamond material, this is not required. Barrel 205 and firing mechanism 209 are advantageously made of diamond materials; other components can be made of other materials, including steel and other metals conventionally used in firearms. Bullets 220 may be of generally conventional design and materials. In preferred embodiments, the body of firearm 200 includes at least some metal elements large enough to be readily detected by conventional metal detectors (e.g., as used in airports); such elements help to deter unauthorized concealed carrying of firearm 200.
In another embodiment, a spiral bullet feed tube may be placed around a central powder column 208. If the dimensions of the spiral are about 1.75 inches by 4 inches for a typical arm of .5 caliber, the total tube length is about 20 inches. If there are 10 inches of spring or 20 bullets, a constant force spring would produce a capacity of about 40 rounds.
While the invention has been described with respect to specific embodiments, one skilled in the art will recognize that numerous modifications are possible. One skilled in the art will also recognize that the present invention provides a number of advantageous techniques, tools, and products, usable individually or in various combinations. These techniques, tools, and products include but are not limited to:
It should be noted that several of the features of firearms described herein do not require that any part of the firearm be made of diamond material or any other particular material. Such features can be applied to firearms made of other materials, including conventional materials.
Thus, although the invention has been described with respect to specific embodiments, it will be appreciated that the invention is intended to cover all modifications and equivalents within the scope of the following claims.
This application claims the benefit of U.S. Provisional Application No. 60/557,470, filed Mar. 29, 2004, entitled “Diamond and/or Silicon Carbide Molding of Small and Microscale or Nanoscale Capsules and Other Objects Including Firearms,” which disclosure is incorporated herein by reference for all purposes. The present disclosure is related to the following commonly-assigned co-pending U.S. Patent Applications: application Ser. No. 11/046,526, filed Jan. 28, 2005, entitled “Angle Control of Multi-Cavity Molded Components for MEMS and NEMS Group Assembly”;application Ser. No. 11/067,517, filed Feb. 25, 2005, entitled “Diamond Capsules and Methods of Manufacture;”application Ser. No. 11/067,609, filed Feb. 25, 2005, entitled “Apparatus for Modifying and Measuring Diamond and Other Workpiece Surfaces with Nanoscale Precision”; andapplication Ser. No. 11/079,019 filed Mar. 11, 2005, entitled “Silicon Carbide Stabilizing of Solid Diamond and Stabilized Molded and Formed Diamond Structures.” The respective disclosures of these applications are incorporated herein by reference for all purposes.
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