This invention relates generally to recoil systems for weaponry.
N/A
Not Applicable
Artillery weapons have been used for hundreds of years. These weapons have been continuously developed to improve accuracy, effectiveness, and efficiency. For example, U.S. Pat. Nos. 4,945,813; 6,024,007; and 6,595,103 disclose various designs for gun systems, all of which patents are incorporated by reference herein in their entireties.
When an artillery weapon is fired, the energy of the round must be absorbed by the weapon's structure and eventually transmitted to the ground. Modern artillery systems incorporate recoil mechanisms to modulate the forces associated with these firings to a level that can be effectively and reliably supported by the structure. With some recoil mechanisms, the energy of the round is dissipated by throttling fluid over the length of the recoil. The minimum level of this modulating force is directly proportional to the length of recoil.
In a soft recoil system, the recoiling parts are accelerated forward prior to the firing of the round by an internal gas spring. When the round is fired, nearly half of the energy of the round is used to stop the forward motion of the recoiling parts and the remaining energy is used to force the recoiling parts rearward, recompressing the gas spring. The recoiling parts are then captured by a latch in preparation for the next firing. This use of momentum exchange and energy conservation by the soft recoil technique results in recoil force reductions as high as 75% when compared to conventional recoil systems.
Although the soft recoil technique offers considerable advantages, there are some drawbacks associated with the cycle. Among these are: (1) A different run-up velocity is required for each of the different zones/charges being fired to maximize the benefits, (2) If the round fails to fire during the run up (known as a misfire), the buffing load required to bring the forward velocity of the recoiling parts to zero may be high enough to cause some weapon instability, and (3) If the round fires prematurely from the latch position (known as a “cookoff”), the conventional recoil-style buffer rearward of the latch point may induce sufficient forces to cause the weapon to slide rearward or become unstable.
Embodiments of the present inventions are directed to soft recoil systems.
In one embodiment, a soft recoil system for mitigating a force of firing a round is disclosed. The soft recoil system includes a hydraulic cylinder cooperatively engaged with a gun barrel. The hydraulic cylinder includes an outer cylinder. The hydraulic cylinder further includes an inner cylinder mounted within the outer cylinder. The inner cylinder defines a group of fluid passages formed therein to allow fluid communication between the inner and outer cylinders. The group of fluid passages has a first fluid passage with a first width and a second fluid passage with a second width less than the first width. The hydraulic cylinder further includes a recoil piston positioned within the inner cylinder. The recoil piston is slideable with respect to the inner cylinder along a portion of the inner cylinder. The hydraulic cylinder further includes an elongated recoil rod having a first end portion cooperatively engaged with the gun barrel and a second end portion cooperatively engaged with the recoil piston. The soft recoil system further includes a valve positioned around the inner cylinder. The valve is slideable between: (i) a first position in which the first and second passages are exposed to the outer cylinder, and (ii) a second position in which the valve blocks fluid flow through the first passage.
In another embodiment, a soft recoil system for mitigating a force of firing a round is disclosed. The soft recoil system includes a hydraulic cylinder cooperatively engaged with a gun barrel. The hydraulic cylinder includes an outer cylinder. The hydraulic cylinder further includes an inner cylinder mounted within the outer cylinder. The inner cylinder defines a group of fluid passages therein to allow fluid communication between the inner and outer cylinders. The hydraulic cylinder further includes a recoil piston positioned within the inner cylinder. The recoil piston is slideable with respect to the inner cylinder along a portion of the inner cylinder. The hydraulic cylinder further includes an elongated recoil rod having a first end portion cooperatively engaged with the gun barrel and a second end portion cooperatively engaged with the recoil piston. The soft recoil system further includes a group of valves corresponding to the group of fluid passages. The valves are configured to close a fluid passage of the group of fluid passages as the recoil piston slides away from the group of fluid passages.
In addition to the exemplary aspects and embodiments described above, further aspects and embodiments will become apparent by reference to the drawings and by study of the following description.
In order that the advantages of the invention will be readily understood, a more particular description of the invention briefly described above will be rendered by reference to specific embodiments illustrated in the appended drawings. Understanding that these drawings depict only typical embodiments of the invention and are not therefore to be considered limited of its scope, the invention will be described and explained with additional specificity and detail through the use of the accompanying drawings.
Before the various embodiments of the present invention are explained in detail, it is to be understood that the invention is not limited in its application to the details of construction and the arrangements of components set forth in the following description or illustrated in the drawings.
The invention is capable of other embodiments and of being practiced or of being carried out in various ways. Also, it is to be understood that phraseology and terminology used herein with reference to device or element orientation (such as, for example, terms like “front”, “back”, “up”, “down”, “top”, “bottom”, and the like) are only used to simplify description of the present invention, and do not alone indicate or imply that the device or element referred to must have a particular orientation. In addition, terms such as “first”, “second”, and “third” are used herein and in the appended claims for purposes of description and are not intended to indicate or imply relative importance or significance. The term “recoiling parts” as used herein generally refers to those elements of a piece of a gun 12 and/or a soft recoil system 10 that move in response to the energy of expending a round in the gun 12. This term may encompass, but is not limited to, the barrel 20, muzzle brake, breech 24, first rail 28, second rail 30, rear yoke 32, middle yoke 34, forward yoke 36, muzzle yoke 38, flange 39, tie rod 40, first recoil rod 52, second recoil rod 62, and recoil piston 64 (although the recoil rods 52, 62 and recoil piston 64 may also be considered as part of the soft recoil system 10).
One embodiment of an artillery weapon, such as a howitzer (or more generally, gun 12), may be mounted to a base 14 and include a soft recoil system 10 as shown in
A gun 12 without a soft recoil system 10 and removed from a base 14 is shown in
The rails may be firmly retained in place by a plurality of yokes 32, 34, 36; a first or rear yoke 32, a second or middle yoke 34, and a third or forward yoke 36 attached to an intermediate portion of the barrel 20. The yokes 32, 34, 36 circumferentially clasp or are secured to the barrel 20 at positions along its longitudinal axis. The forward yoke 36 may include a latch point 36a to provide an interface between the recoiling parts and the latch mechanism 200, which is described in detail below.
In addition, a muzzle yoke 38 may circumferentially clasp an intermediate portion of the barrel 20 at a position that is spaced from and forward of the third yoke 36. The muzzle yoke 38 may be configured to include a pair of opposed end portions or flanges 39, which extend generally transverse to the longitudinal axis of the barrel 20 as shown in
Each recoil cylinder 51, 61 may be hydro-pneumatically linked to an associated gas reservoir or recuperator 56, 66 through a fluid transfer manifold, wherein only fluid transfer manifold 65 for the second recoil cylinder 61 and recuperator 66 is shown in
In another embodiment of a soft recoil system 10, only a single recoil cylinder 61 and recuperator 66 are used. In this embodiment, the recoil cylinder 61 and recuperator 66 may be positioned parallel with respect to the barrel 20 of the gun 12 to which the soft recoil system 10 is cooperatively engaged. It is contemplated that in such an embodiment of a soft recoil system 10 it will be especially advantageous to position the recoil cylinder 61 and/or recuperator 66 either directly above or directly below the barrel 20 such that a vertical plan will bisect the barrel 20, recoil cylinder 61, and recuperator 66. However, other configurations and/or orientations may be used without limitation.
The soft recoil system 10 may include a pair of recoil rods 52, 62, which may be positioned within and extend from the forward ends of the recoil cylinders 51, 61. When the soft recoil system 10 is fitted onto the gun 12 of
For brevity, the following description regarding the internal function, configuration, and/or components of the soft recoil system 10 depicted in
In
Still referring to
A stuffing box 82, which may be configured to encircle the recoil rod 62, may be secured to the end seal 72 to form a fluid bearing and seal element for the reciprocating recoil rod 62. The recoil piston 64 separates the interior chamber defined by the inner cylinder 81 into a forward inner chamber 84 and rear inner chamber 85. The tolerances between the recoil piston 64 and the inner cylinder 81 are selected such that a predetermined amount of fluid flow or leakage may occur at the space or interface between the sidewalls of the recoil piston 64 and inner cylinder 81 under certain circumstances. It is contemplated that for most embodiments of the soft recoil system 10 any leakage between the recoil piston 64 and the inner cylinder 81 will be a relatively low volumetric amount compared to that of fluid flowing directly from the forward inner chamber 84 to the rear inner chamber 85 and vice-versa. As shown in
The inner cylinder 81 includes a plurality of fluid passages 87, 88, 89, and 90 (first, second, third, and fourth fluid passages, respectively) spaced along the length thereof on the forward or muzzle side of the partition 74. The inner cylinder 81 also includes a plurality of fluid passages 92 rearward of the partition 74. These fifth fluid passages 92 allow the transfer of fluid directly between the rear inner chamber 85 and rear outer chamber 78, which as shown in
Still in general reference to
The width of the collar portions 104, 106, 108 and length of the finger portions 105 may be selected so that the sixth fluid passages 94 in the inner cylinder 81 will be exposed when the check valve 100 is in a first operative position (as shown in
In the second embodiment of a check valve 100, the peripheral collar portion 108 may include a relief fluid passage 108a. In the illustrative embodiment of the soft recoil system 10, when the second embodiment of a check valve 100 is in the second operative position, the relief fluid passage 108a is aligned with the third fluid passage 89 (see
As shown in
When the external latch mechanism 200 is released, the unbalanced force of the gas pressure in fluid chamber 68 acts upon the floating piston 67 to move the floating piston 67 to the right and to force the fluid out of chamber 69 and into the first or forward outer chamber 77, as generally depicted in
As a result of this leakage and the force differential on the opposite axial surfaces of the recoil piston 64, the recoil piston 64 and the recoil rod 62 are caused to move to the right with respect to the recoil cylinder 61, as shown in
The “recoil” phase (shown at the beginning of the phase in
When the check valve 100 does move (i.e., to the right in
When this occurs, recoil piston 64 will be to the left or rear of the partition 74, as shown in
The sixth fluid passage 94 may be sized to provide sufficient flow area so that the velocity of the recoiling parts during the run-up phase is only slightly affected by the pressure drop across the sixth fluid passage 94. As shown in
Port 75 may be sized to provide sufficient cross-sectional area for fluid flow through partition 74 so that fluid flowing from the rear outer chamber 78 to the forward outer chamber 77 may pass through the partition 74 with minimal pressure drop when check valve 100 is pushed away from the partition 74. Port 75 may also be positioned and sized so that it may be closed to fluid flow when the check valve 100 is in its rearward position (i.e., abutting the partition 74).
The “counter-recoil” phase, which is depicted schematically in
The greater surface area on the rear axial surface of the recoil piston 64 compared to the front axial surface thereof and the fluid flow into the rear inner chamber 85 causes the recoil piston 64 to move forward, (i.e., to the right). As the recoil piston 64 moves forward in the inner cylinder 81, the gas pressure in the first recuperator chamber 68 begins to drop. Also, as the forward edge of recoil piston 64 reaches the position of the partition 74, the resulting pressure differential and the velocity of the recoiling parts may be controlled by the leakage of fluid at the interface between the recoil piston 64 and the inner cylinder 81, by the position of fluid passages 92 with respect to adjacent fluid passages 92 and the partition 74, and/or through a combination thereof. The resulting reduced velocity of the recoiling parts continues until the recoiling parts reach and make contact with the external latch 200 (i.e., when the recoil piston 64 is adjacent the partition 74). This completes a cycle.
A “misfire buffing” phase may be provided in the event that the round fails to fire during the run-up phase, as depicted in
While
It is contemplated that the general orientation, elevation, and/or azimuth of the gun 12 may have an active control via a PLC and various sensors, wherein the PLC controls a translator of some sort (e.g., base 14, actuator 16, and/or a combination thereof). In an active control situation, the PLC would analyze data from the various sensors and output commands to the translator, which translator would adjust the orientation, elevation, and/or azimuth of the gun 12 accordingly.
The various fluid passages 87, 88, 89, 90, 92, 93, and 94, outer cylinder 71, inner cylinder 81, ports 75, and the partition 74 are configured such that the force of the spending the round is distributed over a longer distance of the soft recoil system 10 than that of prior art recoil systems. Additionally, the time over which the force is distributed is longer using the soft recoil system 10 than that of the prior art. One profile of the various fluid passages 87, 88, 89, 90, 92, 93, and 94 and their respective spacing and areas for an inner cylinder 81 are shown in
As is apparent from
In the embodiment of a soft recoil system 10 shown in
A “coast” length may be engineered into the inner cylinder 81 so that the recoil piston 64 may be in a window of approximately five inches in length (for the illustrative embodiment of the soft recoil system 10, but which length will vary from one embodiment of the soft recoil system 10 to the next) along the inner cylinder 81 behind (i.e., toward the breech 24) of larger fluid passages 93. If the recoil piston 64 is positioned in at a point in the coast length, the gun 12 may fire and the soft recoil system 10 will perform as designed. In the illustrative embodiment of the soft recoil system 10, the coast length is substantially located in an area between the larger fluid passage 93 and a point five inches rearward therefrom (i.e., toward the breech 24). However, in other embodiments of the soft recoil system 10 the coast length may be differently positioned along the inner cylinder 81, and/or the coast length may be longer or shorter than that shown herein. The embodiment shown in
One embodiment of a misfire recovery system 130 is shown in
During the run-up phase, the misfire valve 132 would typically be positioned as shown in
However, in the event of misfire, which situation is depicted in
One embodiment of a counter-recoil control system 110 is shown in perspective in
As shown in
In the embodiment of a soft recoil system 10 shown in
In operation, the embodiment of a soft recoil system 10 shown in
It is to be understood that the embodiment of the soft recoil system 10 shown in
The latch mechanism 200 may be positioned at any convenient location along the length of the soft recoil system 10 that is suitable for the particular embodiment thereof. In the illustrative embodiment of the soft recoil system 10 pictured herein, the latch mechanism 200 is engaged with the mounting bracket 57, which is adjacent the forward yoke 36 when the recoiling parts are in the latch position. However, other positions and/or orientations of the latch mechanism 200 may be used with the soft recoil system 10 without limiting the scope thereof.
Generally, the latch mechanism 200 functions to retain the recoiling parts in the latched position (as shown in
Various views of one embodiment of a latch mechanism 200 that may be used with a soft recoil system 10 are shown in perspective in
A latch assembly 240 may be pivotally engaged with a housing 202 via a latch assembly aperture 206 formed in the housing 202, a corresponding cover aperture 208b formed in the housing cover 208, and a latch assembly mount 242 formed in the latch assembly 240. In the illustrative embodiment of a latch assembly 240 pictured herein the latch assembly mount 242 is generally formed as a tube or rod that fits into the latch assembly aperture 206 and corresponding cover aperture 208b. However, the latch mechanism 200 and/or soft recoil system 10 disclosed and claimed herein is not limited by the configuration of the latch assembly aperture 206, housing cover 208, and/or the latch assembly mount 242. The latch assembly 240 may include a latch body 241 that is secured to the latch assembly mount 242. A link connector 243 (two link connectors 243 are shown in the illustrative embodiment pictured herein) may extend from the latch body 241 to provide a connection point for a link 220 described in detail below.
A plunger 244 may be positioned within a portion of the latch body 241. The plunger 244 may be selectively moveable in one dimension (i.e., the vertical dimension from the vantage shown in
The complimentary surfaces of the plunger 244 and latch point 36a facilitate movement of the recoiling parts in a rearward direction even when the latch point 36a contacts the plunger ramp 244b via the interaction between the angled surface of the latch point 36a and the plunger ramp 244b in conjunction with the biasing member 245, which is shown in
The plunger ramp 244b in cooperation with the biasing member 245 allow a portion of the recoiling parts to move past the plunger 244 in a direction from the front of the gun 12 to the rear of the gun 12 when the latch point 36a overcomes the biasing force of the biasing member 245 (thereby pushing the plunger 244 down against the biasing force of the biasing member 245 as shown in
A crank 210 may be pivotally engaged with the housing 202 via a crank aperture 204 formed in the housing, a corresponding cover aperture 208b formed in the housing cover 208, and a crank mount 212 formed in the crank 210. In the illustrative embodiment of a crank 210 pictured herein, the crank mount 212 is generally formed as a tube or rod that fits into the crank aperture 204 and corresponding cover aperture 208b. However, the latch mechanism 200 and/or soft recoil system 10 disclosed and claimed herein is not limited by the configuration of the crank aperture 204, housing cover 208, and/or the crank mount 212. The crank may include a crank arm 214 (two of which are shown in the illustrative embodiment of a latch mechanism 200 pictured herein) extending from the crank mount 212.
A lever member 213 may be cooperatively engaged with the crank 210 such that the lever member 213 communicates mechanical forces to the crank 210 and vice versa. In the illustrative embodiment of the latch mechanism 200, the lever member 213 is operable to communicate at least rotational forces to the crank 210 via the crank mount 212, and is positioned on the exterior of the housing cover 208. A rotational biasing member 215, which may be configured as a torsion spring in certain embodiments of the latch mechanism 200, may bias the crank 210 in a counterclockwise direction from the vantage shown in
A link 220 may communicate mechanical forces between the crank 210 and the latch assembly 240. A link first end 222 may be pivotally engaged with the latch assembly 240 at the link connector(s) 243. A link second end 224 may be pivotally engaged with the crank 210 at the distal end of the lever member(s) 213. In the illustrative embodiment of a latch mechanism 200 pictured herein, the link 220 is curved downward from the vantage depicted in
When the latch mechanism 200 is in the position shown in
A trip assembly 230 may be pivotally engaged with a housing cover 208 via a trip assembly bracket 208a formed in the housing cover 208 and a trip mount 232 formed in the trip assembly 230. In the illustrative embodiment of a trip assembly 230 pictured herein, the trip assembly bracket 208a is generally formed as a channel bracket having at least one aperture, wherein the trip assembly bracket 208a is engaged with the exterior surface of the housing cover 208, and the trip mount 232 is generally formed as a tube or rod that fits into the aperture formed in the trip assembly bracket 208a and a corresponding cover aperture 208b. However, the latch mechanism 200 and/or soft recoil system 10 disclosed and claimed herein is not limited by the configuration of the trip assembly bracket 208a, housing cover 208, and/or the trip mount 232. A lever member engager 234 may extend from the trip assembly 230 to engage the lever member 213 when the crank 210 and trip assembly 230 are in a certain orientation with respect to one another.
To release the recoiling parts (and thereby begin the run-up phase), a user may rotate the trip assembly 230 in a counterclockwise direction. This may be done manually via pulling a lanyard that is connected to the trip assembly 230. The illustrative embodiment of the trip assembly 230 includes a bar 236 engaged with the trip assembly such that rotating the bar 236 causes the trip assembly 230 to rotate. The bar 236 may serve as an attachment point for a lanyard. Additionally, a safety mechanism may be engaged with the housing 202 adjacent the bar 236 to prevent an unwanted release of the latch mechanism 200.
The rotation of the trip assembly 230 causes the lever member engager 234 to contact the lever member 213. Continuing to rotation the trip assembly 230 in a counterclockwise direction causes the lever member 213 to rotate in a clockwise direction, which causes the crank 210 to rotation in a clockwise direction. This rotation of the crank 210 causes the link second end 224 to move down with respect to the link first end 222. When the connecting line passes below the axis of rotation of the crank mount 212 with respect to the crank aperture 204, the rotational biasing force the latch point 36a imparts to the latch assembly 240 via the plunger 244 will cause the latch assembly 240 to rotate clockwise, thereby releasing the recoiling parts and beginning the run-up phase (which position of the latch mechanism 200 is depicted in
When the recoiling parts are moving rearward during the recoil phase, the latch point 36a on the recoiling parts will typically pass the latch position. The latch point 36a will typically overcome the biasing force that the biasing member 245 places on the plunger 244 due to the kinetic energy of the recoiling parts, thereby depressing the plunger 244 and allowing the recoiling parts to pass freely rearward of the latch position (as shown in
The link 220 in the illustrative embodiment of the latch mechanism 200 is designed to serve two functions, both of which may be achieved through a curved configuration of the link 220 as shown for the illustrative embodiment of a latch mechanism 200 as pictured herein. First, as part of the over-centered linkage system comprised of the crank 210, link 220, and latch assembly 240, the link 220 cooperates to hold the latch assembly 240 in position to overcome the potential energy of the compressed fluid in the soft recoil system 10 and thereby selectively prevent the recoiling parts from accelerating forward (i.e., entering the run-up phase). Secondly, the link 220 provides a shock absorbing capacity to the latch mechanism 200. When the recoiling parts impact the plunger 244 during the counter-recoil phase, the tensile load imparted to the link 220 causes the curvature of the link 200 to straighten, thereby slightly lengthening the link 220. This lengthening of the link 220 absorbs a portion of the impact energy recoiling parts impart to the latch mechanism in much the same way a spring would absorb that energy. It is contemplated that in the illustrative embodiment of the latch mechanism 200, the link 220 will absorb normal impact loads without permanent deformation. It is also contemplated that the link 220 in the illustrative embodiment of the latch mechanism 200 will provide additional protection from damage to the various elements of the latch mechanism 200 (which damage may be caused by excessive impact loads) by straightening to the point that the over-center distance in the retaining position of the latch mechanism (shown in
Although the latch mechanism 200 pictured herein is generally manually operated, the latch mechanism 200 and/or soft recoil system 10 as disclosed and claimed herein is not so limited. The latch mechanism 200 may be outfitted with multiple layers of automation and/or actuation. For example, in an embodiment not pictured herein, the rotation of the trip assembly 230 may be caused by an electrical, pneumatic, or other type of powered actuator. Additionally, the rotational biasing member 215 and biasing member 245 may be electrical, pneumatic, or otherwise externally powered as opposed to being configured as mechanical springs.
The magnitude of the force(s) the rotational biasing member 215 imparts to the crank 210 and that the biasing member 245 imparts to the plunger 244 will vary from one embodiment of the latch mechanism 200 to the next, and are therefore in no way limiting to the scope thereof or to the scope of the soft recoil system 10. Similarly, the force required to rotate the lever member 213 to a point at which the over-center orientation of the crank 210, link 220, and latch assembly 240 is eliminated will vary from one embodiment of the latch mechanism 200 to the next, and are therefore in no way limiting to the scope thereof or to the scope of the soft recoil system 10.
In the embodiment pictured herein, it is contemplated that the latch mechanism 200 may be secured to the mounting bracket 57 adjacent the end of the actuator 16 opposite the base 14. However, the latch mechanism 200 may be secured to any other suitable structure for the particular embodiment of the gun 12, base 14, and/or soft recoil system 10 without limitation. The various components of the latch mechanism 200 may be constructed of any suitable material for the particular application of the latch mechanism 200. Such materials include but are not limited to metal, metallic alloys, synthetic materials, and combinations thereof
The optimal dimensions and/or configuration of the yokes 32, 34, 36, flange 39, tie rods 40, rail guides 50, 60, recoil cylinders 51, 61, recoil rods 52, 62, recuperators 56, 66, recoil piston(s) 64, mounting bracket 57, crossover bracket 59, floating piston 67, outer cylinder 71, partition 74, inner cylinder 81, stop element 83, check valve 100, latch mechanism 200, counter-recoil control valve 110, misfire recovery system 130, and various components thereof or interacting there with will vary from one embodiment of the soft recoil system 10 to the next, and are therefore in no way limiting to the scope thereof.
A gun 12 outfitted with the illustrative embodiment of the soft recoil system 10 disclosed herein conserves a portion of the energy from the firing of the round rather than simply dissipating that energy. The soft recoil system 10 then uses that conserved energy to offset the recoil from the firing of the next round. This allows for a faster cycle time in firing (with cycle times being reduced by as much as 50%) and longer periods of effective use. Because less energy is transferred to the fluid in the soft recoil system 10 than that in prior art systems (which reduction is equal to the energy required to stop the recoiling parts during the “run-up” phase), the fluid stays cooler during use as compared to prior arty systems.
The components of the soft recoil system 10 may be made any materials having the desired characteristics for the specific application of the soft recoil system 10 including but not limited to metals, metallic alloys, synthetic materials, and/or combinations thereof. For example, it is contemplated that for some applications of the soft recoil system 10 it will be advantages to construct the inner cylinder 81 using high-strength steel. Since the internal surfaces of the outer and inner cylinders 71, 81 may be exposed to high pressures, the internal surface of the cylinders 71, 81 must be strong enough to resist bursting. Additionally, it is contemplated that the inner cylinder 81 must be configured so that it resists deformation to mitigate leakage between it and recoil piston 64. The material used for the inner cylinder 81 must also exhibit a high degree of wear resistance as the recoil piston 64 moves forward and rearward repeatedly therein. While other materials might be selected (including but not limited to metal, metallic alloys, synthetic materials, and/or combinations thereof), high-strength steel may be a preferred choice for various embodiments of the soft recoil system 10 when considering cost, weight, and performance.
In certain applications of the soft recoil system 10 the recoil rods 52, 62 may be made from high-strength steel with a chrome-plated outside diameter. The high-strength steel provides the necessary strength and resistance to buckling. The chrome plating provides the degree of corrosion resistance necessary and functions efficiently for the dynamic seal interface purposes. It is contemplated that in the illustrative embodiment of the soft recoil system 10 the recoil piston 64 may be made from materials such as nodular cast iron or bronze. Both of these materials provide a certain amount of natural lubricity for sliding on materials such as steel. However, other materials may be used without limitation.
It is contemplated that for the illustrative embodiment of the soft recoil system 10, the outer cylinder 71 may be made from medium-strength aluminum. Since the high-pressure operations are generally confined to the inside of the inner cylinder 81, lower strength, lighter weight materials may be used for fluid transfer functions and lighter structural requirements. However, other materials may be used without limitation. Inasmuch as the soft recoil system 10 described and disclosed herein is subject to many variations, modifications and changes in detail, it is intended that all matter contained in the forgoing description or shown in the accompanying drawings shall be interpreted as illustrative and not in a limiting sense.
Although the specific embodiments pictured and herein pertain to a soft recoil system 10 adapted for use with a howitzer artillery piece, the soft recoil system 10 may be adapted for use with other types of gun 12, such as mortars. Additionally, it is contemplated that the soft recoil system 10 may be adapted for use with artillery pieces other than those shown herein, wherein those artillery pieces fire different rounds, have barrels 20 of differing lengths, are mounted to different structures, or are generally designed for different uses than the gun 12 pictured herein. Accordingly, it is contemplated that certain embodiments of the soft recoil system 10 may be adapted for use with artillery weapons of various sizes and mortar weapons of various sizes, regardless of whether such weapons are vehicle mounted or otherwise.
The soft recoil system 10 may be configured with other orientations and/or with different quantities of the various elements having different shapes and/or orientations than those shown and described herein without limitation. Accordingly, the scope of the soft recoil system 10 is in no way limited by the specific shape and/or dimensions of the barrel 20, rails 28, 30, yokes 32, 34, 36, flange 39, tie rods 40, rail guides 50, 60, recoil cylinders 51, 61, recoil rods 52, 62, recuperators 56, 66, recoil piston(s) 64, mounting bracket 57, crossover bracket 59, floating piston 67, outer cylinder 71, partition 74, inner cylinder 81, stop element 83, check valve 100, or the relative quantities and/or positions thereof.
Having described the preferred embodiment, other features, advantages, and/or efficiencies of the soft recoil system 10 will undoubtedly occur to those versed in the art, as will numerous modifications and alterations of the disclosed embodiments and methods, all of which may be achieved without departing from the spirit and scope of the soft recoil system 10 as disclosed and claimed herein. It should be noted that the soft recoil system 10 is not limited to the specific embodiments pictured and described herein, but are intended to apply to all similar apparatuses for mitigating recoil force and/or conserving the energy expended during the firing of a round. Modifications and alterations from the described embodiments will occur to those skilled in the art without departure from the spirit and scope of the soft recoil system 10.
This application is a continuation of U.S. patent application Ser. No. 15/669,691, filed Aug. 4, 2017, which is a continuation of U.S. patent application Ser. No. 14/803,975 filed on Jul. 20, 2015, which issued Aug. 29, 2017 as U.S. Pat. No. 9,746,269, which is a continuation of U.S. patent application Ser. No. 13/903,650 filed on May 28, 2013, which issued Aug. 25, 2015 as U.S. Pat. No. 9,115,946, which application claimed priority from and was a continuation of U.S. patent application Ser. No. 13/452,674 filed on Apr. 20, 2012, which issued Jun. 25, 2013 as U.S. Pat. No. 8,468,928, which claims the filing benefit under 35 U.S.C. § 119(e) of provisional U.S. Patent Application No. 61/478,053 filed on Apr. 21, 2011, each of which are incorporated by reference herein in their entireties.
Number | Date | Country | |
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61478053 | Apr 2011 | US |
Number | Date | Country | |
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Parent | 15669691 | Aug 2017 | US |
Child | 16576058 | US | |
Parent | 14803975 | Jul 2015 | US |
Child | 15669691 | US | |
Parent | 13903650 | May 2013 | US |
Child | 14803975 | US | |
Parent | 13452674 | Apr 2012 | US |
Child | 13903650 | US |