Patent Grant
11162768
The present invention relates to a bullet, hereinafter referred to also as a “Nemesis Bullet” or simply “Nemesis” (trademark expression(s) used by the Applicant(s)). More particularly, the present invention relates to a new and improved bullet for use with various types of weapons, such as riffles and the like, and also relates to a weapon provided with at least one of such bullet, as well as to a kit for assembling the same (ex. bullet, corresponding weapon, associated accessory(ies), etc.), and to corresponding methods of manufacturing, operating and/or use associated thereto.
Weapons, such as rifles and the like, and the various types of ammunitions used therewith (ex. bullets, etc.), are well known in the art, and have been used for many years. It is also well known that these have evolved over the years, and have been the object of various patent applications.
For example, known to the Applicant(s) are the following documents: U.S. Pat. Nos. 2,941,469; 3,345,948; 3,754,507; 3,988,990; 3,995,558; 4,003,313; 4,091,732; 4,108,073; 4,213,393; 4,528,911; 4,742,774; 5,353,711; 6,186,072 B1; 6,581,522 B1; 7,171,905 B2; 7,823,510 B1; 8,122,833 B2; 8,291,828 B2; 8,511,233 B2; US 2008/0035008 A1; EP 2,811,256 A1; and WO 1991/011676 A2.
Despite these known improvements over the years, there is a need to continue innovating and finding better and/or different ways of firing projectiles (ex. bullets, etc.) in a more efficient, more precise, more accurate, more reliable, more adjustable, more versatile, more adaptable, more impactful, more strategic, more powerful, more lethal and/or more desirable manner (ex. depending on the circumstances, and the intended results, etc.).
Indeed, in regards to conventional bullets, it is known that they are affected by a pressure difference that occurs on the rearward face. This drop in pressure causes drag and can generate flight instability. These factors will reduce the precision and accuracy of a bullet grouping.
Thus, it would be particularly useful to be able to provide an improved bullet which, by virtue of its design and components, would be able to overcome or at least minimize some of these known drawbacks associated with conventional bullets.
An object of the present invention is to provide a new bullet which, by virtue of its design and components, is intended to satisfy the above-mentioned need and which is thus an improvement over other related bullets, corresponding weapons, associated accessories and/or firing devices, systems, assemblies and/or methods known in the prior art.
In accordance with the present invention, the above main object is achieved, as will be easily understood, with a bullet (and/or a corresponding weapon and/or associated accessory provided with at least one such bullet, as well as corresponding kits for assembling the same (ex. bullet, weapon, etc.), and corresponding methods of manufacturing, assembling, operating, use, etc.) such as the one(s) briefly described herein and such as the ones exemplified in the accompanying drawings.
More particularly, according to one aspect of the present invention, there is provided a bullet for use with a cartridge for propulsion out of a barrel of a weapon, the bullet comprising a main body acting as a projectile and a drag-reducing assembly provided about the main body. The drag-reducing assembly is configured for being triggered upon a blast from the cartridge, in order to reduce a resulting drag of the projectile during flight trajectory, thereby improving resulting ballistic performance of the bullet.
As will be explained in greater detail hereinbelow, the present system is particularly advantageous in that, due to its components and features, the bullet is capable of considerably increased ballistic performances (ex. more precise trajectory, much longer range, greater travelling speed, more powerful impact, etc.).
According to another aspect, there is provided a bullet configured to be propelled by a blast of a cartridge. The bullet comprises a main body provided with an internal body cavity and has a frontward section and a rearward section provided with an opening in fluid communication with the internal body cavity. The internal body cavity by means of the opening is capable of recovering a portion of gun gas resulting from the blast of the cartridge.
According to another aspect, there is provided a kit with corresponding components for assembling a bullet according to the present disclosure.
According to another aspect of the present invention, there is provided a corresponding weapon (ex. riffle, etc.) and/or an associated accessory (ex. loader, etc.) provided with at least one of the above-mentioned bullet(s), and preferably, with a plurality of such bullets.
According to another aspect, there is provided a weapon system comprising a weapon and at least one bullet according to the present disclosure.
According to another aspect, there is provided a kit with corresponding components for assembling a weapon system according to the present disclosure.
According to another aspect, there is provided a method of reducing drag from a bullet propelled out of a barrel of a weapon via a cartridge, the bullet having a main body, the method comprising the steps of:
providing at least one internal body cavity about the main body of the bullet;
recovering a portion of gun gas resulting from a blast of the cartridge during firing of the weapon, and conveying said portion of gun gas into said at least one internal body cavity of the bullet via a corresponding fluid passage; and
allowing gun gas present inside said at least one internal body cavity of the bullet to exit as the bullet exits the barrel of the weapon, thereby fluidly filling a void behind the bullet during flight trajectory, in order to reduce a resulting drag of the bullet, for an improved overall ballistic performance of the bullet.
According to another aspect, there is provided a method of reducing drag from a bullet propelled by a blast of a cartridge. The method comprises the step of providing a bullet having a main body provided with an internal body cavity and comprising a frontward section, a rearward section and an opening. The opening is formed in the rearward portion and in fluid communication with the internal body cavity. The method further comprises the steps of recovering a portion of gun gas resulting from the blast of the cartridge in the internal body cavity via the opening, and allowing gun gas present inside the internal body cavity to exit via the opening as the bullet is propelled.
According to another aspect, there is provided a method for manufacturing a drag-reducing assembly configured to be assembled with a main body of a bullet and to reduce a resulting drag of the bullet during flight trajectory, the method comprising the steps of:
manufacturing a nozzle component having an inlet face and an outlet face, and a through opening extending between the inlet and outlet faces;
manufacturing a body portion having at least one internal body cavity, said at least one internal body cavity being in fluid communication with the through opening of the nozzle component;
at least one of the nozzle component and the body portion being manufactured by additive manufacturing.
According to another aspect, there is provided a method for manufacturing a nozzle component for a bullet. The method comprises the step of manufacturing the nozzle component with an inlet face, an outlet face, and a through opening that extends between the inlet and outlet faces.
According to another aspect of the present invention, there is provided a method of manufacturing (ex. making, assembling, etc.) the above-mentioned bullet, weapon and/or associated accessory.
According to another aspect of the present invention, there is provided a method of operating and/or using the above-mentioned bullet, weapon and/or associated accessory.
According to another aspect of the present invention, there is provided an assembly, a system, a station and/or a machine for carrying out the above-mentioned method(s).
According to another aspect of the present invention, there is provided a processing plant provided with any one and/or at least one of the above-mentioned assembly, system, station, machine and/or components thereof.
According to another aspect of the present invention, there is provided a method of manufacturing (ex. producing, assembling, etc.) the above-mentioned bullet, weapon, accessory, assembly, system, station, machine, processing plant and/or components thereof.
According to another aspect of the present invention, there is provided a method of operating the above-mentioned assembly, system, station, machine, processing plant and/or components thereof.
According to another aspect of the present invention, there is provided a kit with corresponding components for assembling the above-mentioned bullet, weapon, associated accessory and/or components thereof.
According to yet another aspect of the present invention, there is also provided a set of components for interchanging with components of the above-mentioned kit.
According to yet another aspect of the present invention, there is also provided a method of assembling components of the above-mentioned kit and/or set.
According to yet another aspect of the present invention, there is also provided a method of doing business with the above-mentioned bullet, weapon, associated accessory, method(s), kit, set, assembly, system, station, machine, processing plant and/or components thereof.
According to yet another aspect of the present invention, there is also provided a bullet (ex. a blank and/or body with hollowed portions) having been obtained and/or processed (modified, altered, etc.) with the above-mentioned method(s), kit, set, assembly, system, station, machine, processing plant and/or components thereof.
The objects, advantages and other features of the present invention will become more apparent upon reading of the following non-restrictive description of preferred embodiments thereof, given for the purpose of exemplification only, with reference to the accompanying drawings.
In the following description, the same numerical references refer to similar elements. Furthermore, for sake of simplicity and clarity, namely so as to not unduly burden the figures with several reference numbers, only some figures have been provided with reference numbers, and components and features of the present invention illustrated in other figures can be easily inferred therefrom. The embodiments, geometrical configurations, materials mentioned and/or dimensions (expressed in inches, for example) shown in the figures are preferred, for exemplification purposes only.
Moreover, although the present invention was primarily designed as a bullet for use with various types of weapons, such as riffles and the like, it may be used with other types of objects, and in other fields, as apparent to a person skilled in the art. For this reason, expressions such as “bullet”, “weapon”, “riffle”, etc., used herein should not be taken as to limit the scope of the present invention and include all other kinds of objects or fields with which the present invention could be used and may be useful, as apparent to a person skilled in the art.
Moreover, in the context of the present invention, the expressions “bullet”, “projectile”, “device”, “product”, “system”, “method”, “kit” and “assembly”, as well as any other equivalent expressions and/or compounds word thereof known in the art will be used interchangeably, as apparent to a person skilled in the art. This applies also for any other mutually equivalent expressions, such as, for example: a) “bullet”, “Nemesis”, “system”, “product”, “assembly”, “device”, “apparatus”, “unit”, “component”, “equipment”, “projectile”, etc.; b) “producing”, “manufacturing”, “assembling”, “making”, “processing”, “altering”, “modifying”, “changing”, etc.; c) “body”, “shell”, “chassis”, “support”, “frame”, etc.; d) “removing”, “reducing”, “diminishing”, etc. e) “drag”, “resistance”, “friction”, etc.; f) “hollow”, “cavity”, “hole”, “recess”, “grove”, etc.; g) “cartridge”, “propellant”, “fuel”, “explosive”, etc.; h) “blast”, “explosion”, “ignition”, “propulsion”, etc.; i) “gun gas”, “combustion gas”, etc.; j) “cutting”, “detaching”, “separating”, etc.; as well as for any other mutually equivalent expressions, pertaining to the aforementioned expressions and/or to any other structural and/or functional aspects of the present invention, as also apparent to a person skilled in the art.
Furthermore, in the context of the present description, it will be considered that all elongated objects will have an implicit “longitudinal axis” or “centerline”, such as the longitudinal axis of an elongated bullet, or the centerline of a hole, for example (and as a result, there is a “transversal axis” being substantially “perpendicular” for each longitudinal axis, etc.), and that expressions such as “connected” and “connectable”, or “mounted” and “mountable”, may be interchangeable, in that the present invention also relates to a kit with corresponding components for assembling a resulting fully assembled and operational bullet, for use with various types of weapons, such as riffles and the like (and/or the present invention also relates to a weapon provided with at least one of such bullet(s), to a kit for assembling the same (ex. bullet, weapon, associated accessory, etc.), and to corresponding methods of manufacturing, operating and/or use associated thereto, etc.).
Moreover, components of the bullet(s), weapon(s), associated accessory(ies) and/or steps of the method(s) described herein could be modified, simplified, altered, omitted and/or interchanged, without departing from the scope of the present invention, depending on the particular applications which the present invention is intended for, and the desired end results, as briefly exemplified herein and as also apparent to a person skilled in the art.
In addition, although the preferred embodiment of the present invention as illustrated in the accompanying drawings may comprise various components, and although the preferred embodiments of the bullet, weapon, accessory and/or associated method(s) (ex. of manufacturing, assembling, operating, use, etc.) may consist of certain preferred steps and components as explained herein, not all of these steps and components are essential to the invention and thus should not be taken in their restrictive sense, i.e. should not be taken as to limit the scope of the present invention. It is to be understood, as also apparent to a person skilled in the art, that other suitable steps, components and cooperation thereinbetween, may be used for the present drag-reducing method of a bullet and corresponding bullet (as well as corresponding components thereof) according to the present invention, as will be briefly explained hereinafter and as can be easily inferred herefrom by a person skilled in the art, without departing from the scope of the invention.
Broadly described, the present invention, as illustrated in the accompanying drawings, relates to a new and improved bullet, typically for use with a cartridge for propulsion out of a barrel of a weapon, such as riffles and the like, the bullet comprising a) a main body acting as a projectile, and b) a drag-reducing assembly provided about the main body, and configured for being triggered upon a blast from the cartridge, in order to reduce a resulting drag of the projectile during flight trajectory, thereby improving resulting ballistic performance of the bullet.
According to a first possible embodiment of the present invention (referred to as “passive boost bullet” or “generation 1”, for example, in the context of the present description), and as can be easily understood when referring to
The bullet 1 has a longitudinal axis 17, and opposed forward 2 and rearward 4 ends. The bullet 1 further comprises a main body 3 acting as a projectile, the main body 3 being substantially ogive-shaped towards the forward end 2. The main body 3 comprises a length l, a frontward section 3a at the forward end 2 of the bullet 1, a rearward section 3b at the rearward end 4 of the bullet 1, and a central section 3c arranged between the frontward and rearward sections 3a, 3b. The bullet 1 further comprises a drag-reducing assembly 5.
The drag-reducing assembly 5 comprises an internal body cavity 7 provided in the shown embodiment in the rearward section 3b of the main body 3; the internal body cavity 7 has an open face 8 at the rearward end 4 of the bullet 1. In other words, the internal body cavity 7 opens outwardly at the rearward end 4 of the bullet 1. In the shown embodiment, the internal body cavity 7 is substantially cylindrical and has an outer diameter d1 and a length 11. The main body 3 has an outer diameter d2, the outer diameter d1 of the internal body cavity 7 being smaller than the outer diameter d2 of the main body 3. The drag-reducing assembly 5 further comprises a choking annulus 11 (or nozzle component) comprising an inner diameter d3, an outer diameter d4 and a length 12. In the shown embodiment, the inner diameter d3 of the choking annulus 11 is smaller than the outer diameter diameter d1 of the internal body cavity 7, and the choking annulus 11 is at least partially arranged in the internal body cavity 7. The choking annulus 11 comprises an inner volume that is in fluid communication with the internal body cavity 7. The choking annulus 11 is mounted to the rearward section 3b of the main body 3, for instance in the internal body cavity 7 at least partially formed in the rearward section 3b of the main body 3. For instance, the choking annulus 11 and the internal body cavity 7 cooperate together using a screw thread. For instance, a threading 13 is formed on an outer surface of the choking annulus 11 and is configured to cooperate with a threading formed on an inner surface of the internal body cavity 7. For instance, the threading is formed in a direction opposite of rotational direction of the bullet 1 during its flight. In other embodiments, the choking annulus 11 is press-fitted into the internal body cavity 7 or the choking annulus 11 is bonded to the inner surface of the internal body cavity 7. In these embodiments, for instance, the outer diameter d4 of the choking annulus 11 is greater than the outer diameter d1 of the internal body cavity 7, for the choking annulus 11 to be snugly fitted in the internal body cavity 7.
As represented on
It is clear from the present description that the drag-reducing assembly 5 is not necessarily distinct from the main body 3 of the bullet 1. In other words, the drag-reducing assembly 5 can comprise elements from the main body 3. For instance, it is understood that the internal body cavity 7 is provided in the main body 3. In the shown embodiment, the internal body cavity 7 is formed in the rearward section 3b of the main body 3, and is in fluid communication with the orifice or opening 9 that is also provided in the rearward section 3b. The choking annulus 11 (or nozzle component) is mounted at least partially in the opening 9, and has a through opening in fluid communication with the internal body cavity 7 provided in the main body 3.
It is understood that the bullet 1 as represented in
Indeed, the present invention relates to performance enhancements of a bullet. As previously explained, conventional bullets are affected by a pressure difference that occurs on the rearward face. This drop in pressure causes drag and can generate flight instability. These factors will reduce the precision and accuracy of a bullet grouping. The present first embodiment of the present invention is particularly advantageous in that it does not use secondary combustion methods to mitigate the pressure difference, and the rearward face can still maintain perpendicularity of a conventional bullet geometry.
As can be easily understood when referring to
According to this particular first embodiment of the present system, during a firing of the bullet, the following events and/or associated advantages can occur:
As described above with reference to
As represented in particular in
As mentioned above, the open face 8 of the internal body cavity 7 forms an orifice or opening 9 at the rearward end 4 of the bullet 1. In the embodiment represented in
According to a second possible embodiment of the present invention (referred to as “active boost bullet” or “generation 2”, for example, in the context of the present description), and as can be easily understood when referring to
The bullet 1 comprises a main body 3 and a drag-reducing assembly 5. The drag-reducing assembly 5 comprises a substantially cylindrical internal body cavity 7 and a nozzle component 11. The same structural, arrangement and dimensional considerations as the ones detailed above with reference to
As for the embodiment described with reference to
It is clear from the present description that the drag-reducing assembly 5 can comprise elements from the main body 3. For instance, it is understood that the internal body cavity 7 is provided in the main body 3. In the shown embodiment in
It is understood that the bullet 1 as represented in
Indeed, the present invention relates to performance enhancements of a bullet. As previously explained, conventional bullets are affected by a pressure difference that occurs on the rearward face. This drop in pressure causes drag and can generate flight instability. These factors will reduce the precision and accuracy of a bullet grouping. This present second embodiment of the present invention is particularly advantageous in that it does not use secondary combustion methods to mitigate the pressure difference. Also, there are at least three main advantages resulting from the features detailed in regards this particular second embodiment of the present invention. Firstly, to increase the muzzle velocity of the projectile by burning propellant located in the internal body cavity of the projectile, in addition to the propellant that is in the cartridge case of the round. The burning of the propellant in the projectile will extend the pressure in the barrel resulting in higher muzzle velocity of the projectile. Secondly, the base drag reduction will be more effective as the differential of pressure between internal body cavity and outside of the projectile will be higher than in case of absence of propellant in the cavity. Thirdly, thrust upon exit from the muzzle will result in higher velocity of the projectile. Furthermore, the rearward face of this particular embodiment can still maintain perpendicularity of a conventional bullet geometry.
As can be easily understood when referring to
According to this particular second embodiment of the present system, during a firing of the bullet, the following events and/or associated advantages can occur:
The second embodiment of the present bullet system may come in the form of a bullet including one and/or several of the following optional components and features (and/or different possible combination(s) and/or permutation(s) thereof):
According to a third possible embodiment of the present invention (referred to as “phase change boost bullet” or “generation 3”, for example, in the context of the present description), and as can be easily understood when referring to
The drag-reducing assembly 5 of the bullet 1 comprises an internal body cavity 7 formed in the main body 3. For instance, the internal body cavity 7 has a substantially cylindrical shape and is formed between the forward and rearward ends 2, 4 of the bullet 1. The drag-reducing assembly 5 further comprises an axial cavity 15a extending substantially along the longitudinal axis 17 of the bullet 1. As represented in
It is understood that the bullet 1 as represented in
Indeed, the present invention relates to performance enhancements of a bullet. As previously explained, conventional bullets are affected by a pressure difference that occurs on the rearward face. This drop in pressure causes drag and can generate flight instability. These factors will reduce the precision and accuracy of a bullet grouping. The present third embodiment of the present invention, namely the “phase change boost bullet”, uses the gun gases of the burning propellant as a catalyst to change the state of a substance from “liquid” to “vapour” (for example, although “solid” to “vapour” could also be contemplated, etc.). The change of state of a substance will substantially increase the volume of the substance and the pressure in which the substance is contained. The vapour generated by change of state is then released outside of the projectile—as the vapour has a lesser density and viscosity than the surrounding air, the aerodynamic drag will decrease as compared to a drag generated by a projectile flying through the air.
As can be easily understood when referring to
It is clear from the present description that the drag-reducing assembly 5 is not necessarily distinct from the main body 3 of the bullet 1. In other words, the drag-reducing assembly 5 can comprise elements from the main body 3. For instance, it is understood that the internal body cavity 7 and the axial cavity 15a are provided in the main body 3. In the shown embodiment, the internal body cavity 7 is formed in the rearward and central sections 3b, 3c of the main body 3, and is in fluid communication with the orifice or opening 9 that is provided in the rearward section 3b. The axial cavity 15a is formed in the main body 3 and extends in the rearward, central and forward sections 3b, 3c, 3a. The nozzle component 11 is mounted at least partially in the opening 9 that is in fluid communication with the axial cavity 15a and the internal body cavity 3. The nozzle component 11 has a through opening in fluid communication with the internal body cavity 7 and with the axial cavity 15a.
According to this particular third embodiment, during a firing of the bullet, the following events and/or associated advantages can occur:
4) the substance ejected outside of a projectile is used to reduce the Magnus forces on a projectile; and
The third embodiment of the present bullet system may come in the form of a bullet including one and/or several of the following optional components and features (and/or different possible combination(s) and/or permutation(s) thereof):
According to a fourth possible embodiment of the present invention (referred to as “additive manufactured bullet nozzle” or “generation 4”, for example, in the context of the present description), and as can be easily understood when referring to
As represented in
It is understood that the drag-reducing assembly 5 as represented in
Indeed, the present invention relates to performance enhancements of a bullet.
As previously explained, conventional bullets are affected by a pressure difference that occurs on the rearward face. This drop in pressure causes drag and can generate flight instability. These factors will reduce the precision and accuracy of a bullet grouping. The present fourth embodiment of the present invention relates to a structure that can increase ballistic performance—namely, by integrating an enclosed cavity and nozzle component as a single structure, a reduction of drag can be achieved. It is not possible to fabricate the additive manufactured bullet nozzle using subtractive methods as there are features in the component that tooling cannot reach. Through the process of additive manufacture, the entire drag-reducing assembly can be fabricated without the use of secondary joining processes such as brazing or welding, for example.
As can be easily understood when referring to
According to this particular fourth embodiment, during a firing of the bullet (and/or prior thereto), the following events and/or associated advantages can occur:
The fourth embodiment of the present bullet system may come in the form of a bullet including one and/or several of the following possible components and features (and/or different possible combination(s) and/or permutation(s) thereof):
As this is apparent from the above description, the bullet 1 according to the different embodiments of the present disclosure consists of more than one component. For instance, all or part of the bullet 1 is manufactured using an additive manufacturing process. Additive manufacturing affords in particular design and fabrication methods which can hardly be achieved via traditional subtractive operations. The accuracy of the shapes and dimensions of the different components of the bullet 1 can be improved via additive manufacturing. Moreover, the mass distribution of the structure of the bullet according to the present disclosure can be improved: it is known that the bullet 1 is subjected to maximum “g” loading and therefore should have material with a high yield point in a strategically engineering location. Optimization can lead to a weight reduction as to minimize the traverse moment of inertia resulting in an increase of the gyroscopic stability. Furthermore, the internal body cavity 7 should be capable of withstanding high internal pressures and centripetal forces to contain hot gases during the flight of the bullet 1. The outer surface of the bullet 1 also has to engrave into the barrel rifling and have high malleable properties and high density to maximize the axial moment of inertia and weight of the bullet 1. To maximize the penetration upon impact high hardness and toughness of material are also required. The additive manufacturing process is particularly well suited for production of bullets with complex geometries without incurring assembly costs. Moreover, additive manufacting makes it possible to use different material, each material having properties that are adapted to the function of the component it forms. In other words, additive manufacturing is particularly well adapted to the manufacturing of the bullet according to the present disclosure. The complexity for assembling the different small components of the bullet is eliminated by using additive manufacturing technology.
Indeed, the present bullet is particularly advantageous in that, by virtue of its design, components and features, as better described and illustrated herein, it enables to fire a projectile (ex. a bullet, etc.) in a more efficient, more precise, more accurate, more reliable, more adjustable, more versatile, more adaptable, more impactful, more strategic, more powerful, more lethal and/or more desirable manner (ex. depending on the circumstances, and the intended results, etc.). As previously explained, and depending on the different possible embodiments, the present system also advantageously enables to: a) improve a bullet's structural integrity; b) improve gyroscopic stability; c) improve cargo carrying capabilities; d) a higher muzzle velocity for the same weight of projectile without an increase in breech pressure; e) a base aerodynamic reduction during flight; f) a shorter time of flight to target; and/or etc.
The present bullet 1 may come in the form of a bullet including one and/or several of the following possible components and features (and/or different possible combination(s) and/or permutation(s) thereof):
1. A bullet for use with a cartridge for propulsion out of a barrel of a weapon, the bullet comprising:
a main body acting as a projectile; and
a drag-reducing assembly provided about the main body, and configured for being triggered upon a blast from the cartridge, in order to reduce a resulting drag of the projectile during flight trajectory, thereby improving resulting ballistic performance of the bullet.
2. A bullet according to any one of the preceding combination(s), wherein the bullet comprises at least one cavity disposed about (ex. on, in, inside, through, along and/or any other suitable disposition) about a portion of the main body, and being configured for receiving a portion of gun gas from the cartridge (and/or cartridge blast).
3. A bullet according to any one of the preceding combination(s), wherein the at least one cavity includes at least one cavity external to the main body of the bullet.
4. A bullet according to any one of the preceding combination(s), wherein the at least one cavity includes at least one cavity internal to the main body of the bullet.
5. A bullet according to any one of the preceding combination(s), wherein the at least one cavity includes at least one cavity being both external and internal to the main body of the bullet.
6. A bullet according to any one of the preceding combination(s), wherein the at least one cavity includes at least one cavity disposed about a rearward section of the bullet.
7. A bullet according to any one of the preceding combination(s), wherein the at least one cavity includes at least one cavity disposed about a central section of the bullet.
8. A bullet according to any one of the preceding combination(s), wherein the at least one cavity includes at least one cavity disposed about a frontward section of the bullet.
9. A bullet according to any one of the preceding combination(s), wherein the at least one cavity includes a plurality of cavities each being disposed about a corresponding section of the bullet (ex. rearward section, central section and/or forward section, and/or other type of section).
10. A bullet according to any one of the preceding combination(s), wherein the at least one cavity includes a single cavity disposed about a plurality of different sections of the bullet (ex. rearward section, central section and/or forward section, and/or any combination thereof).
11. A bullet according to any one of the preceding combination(s), wherein the at least one cavity (whether external, internal and/or a combination of both, or whether rearward cavity, central cavity, forward cavity and/or any combination thereof) is configured to be in fluid communication with at least one peripheral orifice provided about a portion of the bullet (whether the at least one peripheral orifice be provided directly on the main body of the bullet and/or on another component thereof).
12. A bullet according to any one of the preceding combination(s), wherein the at least one peripheral orifice includes at least one peripheral orifice (ex. a rearward orifice) disposed about a rearward surface of the bullet.
13. A bullet according to any one of the preceding combination(s), wherein the at least one peripheral surface includes at least one peripheral orifice (ex. a side orifice) disposed about a side surface of the bullet.
14. A bullet according to any one of the preceding combination(s), wherein the at least one peripheral orifice includes at least one peripheral orifice (ex. a frontward orifice) disposed about a frontward surface of the bullet.
15. A bullet according to any one of the preceding combination(s), wherein the at least one peripheral orifice (ex. rearward orifice, side orifice and/or frontward orifice) is configured for allowing a passage of fluid (ex. liquid, gas, vapour, etc.) to and/or from the at least one cavity.
16. A bullet according to any one of the preceding combination(s), wherein the at least one peripheral orifice is positioned, shaped and sized for receiving a portion of gun gas from the cartridge (and/or cartridge blast) intended to be introduced into the at least one cavity upon firing of the weapon (ex. riffle, etc.).
17. A bullet according to any one of the preceding combination(s), wherein the at least one cavity includes a cross-sectional profile being substantially variable along a given segment of a longitudinal axis of the bullet.
18. A bullet according to any one of the preceding combination(s), wherein the at least one cavity includes a cross-sectional profile being substantially constant along a given segment of a longitudinal axis of the bullet.
19. A bullet according to any one of the preceding combination(s), wherein the at least one cavity includes a substantially circular cross-sectional profile.
20. A bullet according to any one of the preceding combination(s), wherein the at least one cavity includes at least one substantially cylindrical cavity.
21. A bullet according to any one of the preceding combination(s), wherein the at least one cavity has a diameter being smaller than a diameter of the main body of the bullet.
22. A bullet according to any one of the preceding combination(s), wherein the at least one peripheral orifice has a cross-sectional area being different from a cross-sectional area of the at least one cavity.
23. A bullet according to any one of the preceding combination(s), wherein the cross-sectional of the at least one peripheral orifice is smaller than a cross-sectional area (ex. a “constant” cross-sectional area and/or an “average” cross-sectional area) of the at least one cavity.
24. A bullet according to any one of the preceding combination(s), wherein the at least one peripheral orifice is provided on a nozzle component defined within the main body of the bullet.
25. A bullet according to any one of the preceding combination(s), wherein the nozzle component is made integral (ex. made essentially of the same piece and of the same material) to the main body of the bullet.
26. A bullet according to any one of the preceding combination(s), wherein the nozzle component is a component made separate to (ex. “distinct from”, etc.) the main body of the bullet, and is configured for being mountable (ex. inserted, affixed, attached connected, press-fitted, threaded, bonded, welded, and/or etc.) onto the main body of the bullet.
27. A bullet according to any one of the preceding combination(s), wherein the nozzle component is mountable (ex. inserted, affixed, attached, connected, threaded, bonded, welded, and/or etc.) onto a rearward section of the main body of the bullet.
28. A bullet according to any one of the preceding combination(s), wherein the nozzle component is mountable (ex. inserted, affixed, attached, connected, threaded, bonded, welded, and/or etc.) onto a rearward bore section of the main body of the bullet.
29. A bullet according to any one of the preceding combinations(s), wherein the nozzle component is configured to be threadedly engaged into the rearward section (and/or corresponding rearward bore section) of the main body of the bullet in a direction of rotation contrary to a direction of rotation of the bullet during flight.
30. A bullet according to any one of the preceding combination(s), wherein a portion (ex. outer portion) of the nozzle component is provided with threading, and wherein a portion (ex. inner portion) of the rearward section (and/or corresponding rearward bore section) of the main body of the bullet is provided with a complementary (ex. mating, etc.) threading.
31. A bullet according to any one of the preceding combination(s), wherein the nozzle component is configured to be mechanically-locked (ex. press-fitted, etc.) into the rearward section (and/or corresponding rearward bore section) of the main body of the bullet.
32. A bullet according to any one of the preceding combination(s), wherein the at least one cavity has a diameter being smaller than a diameter of the nozzle component (ex. choke annulus).
33. A bullet according to any one of the preceding combination(s), wherein the nozzle component has a given length spanning inwardly within the main body of the body, and comprises a fluid passage extending from one end (ex. inner end) to another end (ex. outer end) of the nozzle component.
34. A bullet according to any one of the preceding combination(s), wherein the fluid passage of the nozzle component includes a cross-sectional profile being substantially variable (ex. tapered, slanted, angled, etc.) along a given segment of a longitudinal axis of bullet.
35. A bullet according to any one of the preceding combination(s), wherein the fluid passage of the nozzle component includes a cross-sectional profile being substantially constant along a given segment of a longitudinal axis of the bullet.
36. A bullet according to any one of the preceding combination(s), wherein the fluid passage of the nozzle component includes a substantially circular cross-sectional profile.
37. A bullet according to any one of the preceding combination(s), wherein the fluid passage of the nozzle component includes at least one substantially cylindrical passage.
38. A bullet according to any one of the preceding combination(s), wherein the fluid passage of the nozzle component is part of a main fluid passage extending from one end (ex. a front end) of the bullet to another end (ex. a rear end) of the bullet.
39. A bullet according to any one of the preceding combination(s), wherein the nozzle component includes an outer surface that is cylindrical.
40. A bullet according to any one of the preceding combination(s), wherein the nozzle component is a choke annulus.
41. A bullet according to any one of the preceding combination(s), wherein the nozzle component (and/or corresponding features and/or components thereof) is made via additive manufacturing.
42. A bullet according to any one of the preceding combination(s), wherein the at least one cavity is positioned, shaped and sized for containing propellant configured for igniting upon receiving a portion of gun gas from the cartridge (and/or cartridge blast) via the fluid passage (of the nozzle component, for example).
43. A bullet according to any one of the preceding combination(s), wherein ignited propellant is in turn configured for exiting the bullet via the fluid passage (whether same passage and/or another one) of the nozzle component in order to further propel the bullet during flight trajectory.
44. A bullet according to any one of the preceding combination(s), wherein the main body of the bullet is substantially symmetrical about first and second axes of the bullet (ex. a longitudinal axis and a transversal axis of the bullet—in which case, the bullet would be a “spherical” bullet).
45. A bullet according to any one of the preceding combination(s), wherein the main body of the bullet is substantially symmetrical about a single axis of the bullet (ex. a longitudinal axis of the bullet).
46. A bullet according to any one of the preceding combination(s), wherein the main body of the bullet is substantially elongated.
47. A bullet according to any one of the preceding combination(s), wherein the main body of the bullet includes an ogive-shaped portion.
48. A kit with corresponding components for assembling a bullet according to any one of the preceding combination(s).
49. A weapon being configured for operating with at least one bullet (and preferably, a plurality of bullets) according to any one of the preceding combination(s).
50. A weapon being provided (ex. loaded, etc.) with at least one bullet (and preferably, a plurality of bullets) according to any one of the preceding combination(s).
51. A weapon according to any one of the preceding combinations(s), wherein the inside of the barrel of the weapon is treated with cold spray.
52. A weapon according to any one of the preceding combination(s), wherein the weapon is selected from the group consisting of riffle, gun, handgun, machine gun, revolver, automatic weapon, semi-automatic weapon, etc.
53. A kit with corresponding components for assembling a weapon according to any one of the preceding combination(s).
54. A method of reducing drag from a bullet propelled out of a barrel of a weapon via a cartridge, the method comprising the step of:
55. A method according to any one of the preceding combination(s), wherein the method further comprises the step of providing additional propellant inside the at least one cavity of the bullet, and triggering an ignition of said additional propellant via a blast of the cartridge.
56. A method according to any one of the preceding combination(s), wherein the method further comprises the step of releasing a fluid from an internal portion of the bullet about a peripheral orifice thereof (ex. a tip of the bullet) for reducing skin friction during flight of the bullet.
As may now better be appreciated, the present invention is a substantial improvement over the known prior art in that, by virtue of its design and components, as explained herein, and the particular configuration of the bullet and/or components/accessories thereof according to the present system enable to fire a projectile (ex. a bullet, etc.) in a more efficient, more precise, more accurate, more reliable, more adjustable, more versatile, more adaptable, more impactful, more strategic, more powerful, more lethal and/or more desirable manner (ex. depending on the circumstances, and the intended results, etc.) compared to what is possible with respect to other known conventional bullets and/or methods. Indeed, as previously explained, and depending on the different possible embodiments, the present system also advantageously enables to: a) improve a bullet's structural integrity; b) improve gyroscopic stability; c) improve cargo carrying capabilities; d) a higher muzzle velocity for the same weight of projectile without an increase in breech pressure; e) a base aerodynamic reduction during flight; f) a shorter time of flight to target; and/or etc.
Of course, and as can be easily understood by a person skilled in the art, the scope of the present invention should not be limited by the possible embodiments set forth in the examples, but should be given the broadest interpretation consistent with the description as a whole.
Furthermore, although preferred embodiments of the present invention have been briefly described herein and illustrated in the accompanying drawings, it is to be understood that the invention is not limited to these embodiments and that various changes and modifications could be made without departing form the scope and spirit of the present invention, as also apparent to a person skilled in the art.
| Filing Document | Filing Date | Country | Kind |
|---|---|---|---|
| PCT/CA2018/050398 | 3/29/2018 | WO | 00 |
| Publishing Document | Publishing Date | Country | Kind |
|---|---|---|---|
| WO2018/176157 | 10/4/2018 | WO | A |
| Number | Name | Date | Kind |
|---|---|---|---|
| 466056 | Bott | Dec 1891 | A |
| 3345948 | Sarvis | Oct 1967 | A |
| 3913487 | Scherr | Oct 1975 | A |
| 4133265 | Diesinger et al. | Jan 1979 | A |
| 7823510 | Hobart et al. | Nov 2010 | B1 |
| 20160131465 | Harrison | May 2016 | A1 |
| Number | Date | Country | |
|---|---|---|---|
| 20200025535 A1 | Jan 2020 | US |
| Number | Date | Country | |
|---|---|---|---|
| 62478305 | Mar 2017 | US |
