The described embodiments relate generally to recoil systems for weaponry. More particularly, the present embodiments relate to systems and methods for controlling compressible flow in a recoil system.
In artillery systems, compressible fluid can be used to move components of a recoil system in order to counteract various forces associated with firing a weapon. For example, a volume of compressible fluid can be displaced in order to move a recoil rod and induce a momentum generally counteracting forces associated with firing a round of the weapon. However, ambient conditions can change a volume of the compressible fluid, which in turn can modify the momentum of recoiling components. An increase or decrease in temperature, for example, can cause the fluid to expand or contract, respectively. Therefore, in traditional systems, the momentum of the recoiling parts can be susceptible to environmental changes, including temperature increases from use of the weapon system, and as such, the induced momentum may be inappropriate for a given operational condition. As such, the need continues for systems and techniques to regulate compressive fluid volume in a recoil system.
Embodiments of the present invention are directed to a temperature compensator and methods of use thereof in a recoil system. The recoil system can generally be used to counteract forces associated with firing a round of a weapon system, such an artillery-type weapon. The recoil system can employ compressible fluid, such as a compressible oil, in order to drive a recoil rod or other component in a direction that induces a momentum in the weapon system that generally opposes the momentum induced by firing the round. The momentum at which the recoil rod is driven can therefore be based on a volume of the compressible fluid displaced, among other factors. Ambient conditions, such as temperature variations, can increase or decrease the volume of the compressible fluid. Failing to account for possible variations in compressible fluid volume could cause the recoiling parts to be driven with excessive momentum, such as where excess heat expands the compressible fluid volume.
The temperature compensator of the present disclosure allows a recoil system to regulate the volume of compressible fluid used to displace the recoil components. More particularly, the temperature compensator can limit the total volume of compressible fluid used to displace the compressible fluid, limiting the momentum of the recoiling parts to an appropriate or a desired level. The temperature compensator can thus allow a weapon system to be subjected to high-heat ambient and operational conditions (e.g., heat generated by successive quick-fires), without such conditions contributing to excess recoil momentum.
For example, the recoil system can employ a floating piston to drive the compressible fluid from a recuperator cylinder and into a recoil cylinder. The recoil cylinder generally houses the recoil rod and/or other recoiling components. The volume of compressible fluid displaced from the recuperator cylinder can depend on a travel length of the floating piston associated with evacuating some or all of the compressible fluid from the recuperator cylinder. The temperature compensator disclosed herein generally operates to limit the travel of the floating piston within the recuperator cylinder to a predetermined length or distance. As such, the temperature compensator permits release of a defined volume of compressible fluid from the recuperator cylinder, notwithstanding a potentially increased volume of the compressible fluid in the recuperator cylinder due to expanded volume by ambient temperature increase. Upon recoil of the weapon, the temperature compensator also facilitates compressible fluid flow from the recoil cylinder and back into the recuperator cylinder. For example, various flow control features, such as one-way valves, can alternate to permit flow back into the recuperator cylinder at a rate that moves the floating piston to an appropriate position for firing a subsequent round.
While many examples are described here, in one embodiment, a soft recoil system for a gun is disclosed. The system includes a recuperator cylinder fluidly connected to a recoil cylinder. The recoil cylinder houses a slideable recoil rod that counteracts a force associated with firing a round. The system further includes a floating piston positioned within the recuperator cylinder. The system further includes a temperature compensator positioned at least partially within the recuperator cylinder and arranged between the floating piston and the recoil cylinder. The temperature compensator is configured to alternate between: (i) a first configuration in which the temperature compensator limits a volume of fluid the floating piston drives toward the recoil cylinder, and (ii) a second configuration in which the temperature compensator permits fluid flow therethrough for driving the floating piston away from the recuperator cylinder.
In another embodiment, the recuperator cylinder can have an outlet fluidly coupling the volume of fluid with the recoil cylinder. The temperature compensator can be engageable with the outlet to restrict fluid flow therethrough. The temperature compensator can be immersed with the volume of fluid. With this, the floating piston can define a boundary within the recuperator cylinder between the volume of fluid and a pressurizable zone. The pressurizable zone can be adapted to expand, forcing the volume of fluid toward the outlet via the floating piston.
In another embodiment, the temperature compensator can include a flange slidably engaged with an interior of the recuperator cylinder and moveable therein to a position adjacent to and covering the outlet. The temperature compensator can further include a tube extending from the flange and slideable through the outlet, the tube defining an elongated through portion permitting fluid flow through the temperature compensator. In some cases, the tube can define a free end opposite the flange that can be positioned within a transfer manifold. The transfer manifold can be fluidly coupled with the recoil cylinder. The elongated through portion can be open at the free end. Accordingly, the tube can include a tube wall having a slot extending therethrough fluidly coupling an exterior of the tube wall with the transfer manifold via the elongated through portion.
In another embodiment, the temperature compensator can include a one-way valve configured to restrict fluid flow through the temperature compensator in response to the volume of fluid moving toward the recoil cylinder. The one-way valve can be further configured to increase fluid flow through the temperature compensator in response to the volume of fluid moving away from the recoil cylinder. In some cases, the temperature compensator can define an elongated through portion along an axis of the recuperator cylinder. The one-way valve can be operable to overlap the elongated through portion in the first configuration, and in the second configuration, expose an entire cross-dimension of the through portion to the floating piston.
In another embodiment, a temperature compensator for regulating compressible flow in a soft recoil system is disclosed. The temperature compensator includes a tube having opposing first and second ends. The tube includes an elongated through portion extending between the opposing first and second ends. The temperature compensator further includes a flange extending radially from the first end of the tube and configured for sliding engagement within a recuperator cylinder of the soft recoil system. The temperature compensator further includes a biasing element associated with the tube and compressible against the flange as the second end moves away from the recuperator cylinder. The temperature compensator further includes a one-way valve coupled to the flange at the first end and configured to restrict fluid entry to the elongated through portion via the first end.
In another embodiment, the flange defines a face adapted to extend across a diameter of the recuperator cylinder. In this regard, the elongated through portion extends through the face. In some cases, the one-way valve can be arranged at the face and covering the through portion, in a first configuration. Further, the one-way valve can include a pair of articulable doors moveable from a closed position covering the through portion in the first configuration, to an open position in which the one-way valve completely uncovers the through portion at the face. The flange can define one or more ports about the through portion, providing fluid flow through the flange independent of a configuration of the one-way valve.
In another embodiment, the tube can define slots adjacent the flange and extending into the through portion. The second end can be moveable through a transfer manifold fluidly coupled with a recoil cylinder. In such configuration, the recoil cylinder can house a slideable recoil rod that counteracts a force associated with firing a round. The slots can define a flow path from within the recuperator cylinder adjacent the flange to within the transfer manifold. In some cases, the biasing element can include a spring with the tube extending therethrough. The spring can be configured to bias the temperature compensator away from the transfer manifold.
In another embodiment, a method for regulating compressible fluid flow in a soft recoil system is disclosed. The method includes slideably engaging a floating piston and a temperature compensator within a recuperator cylinder. The recuperator cylinder is fluidly couplable with a recoil rod separated from the floating piston by the temperature compensator. The method further includes using the floating piston to displace a volume of fluid out of the recuperator cylinder to move the recoil rod. The volume of fluid can be limited by a travel of the temperature compensator at least partially out of the recuperator cylinder. The method further includes defining a reverse flow path for the fluid through the temperature compensator to move the floating piston away from the recoil rod.
In another embodiment, the floating piston can define a boundary between the volume of fluid and a pressurizable zone within the recuperator cylinder. Further, the operation of using the floating piston can include moving the floating piston toward the temperature compensator by expanding the pressurizable zone, thereby driving the volume of fluid out of the recuperator cylinder. In this regard, the method can further include engaging an outlet of the recuperator cylinder with the temperature compensator, in response to the movement of the floating piston.
In another embodiment, the temperature compensator can include a flange having a surface facing the floating piston and extending across a diameter of the recuperator cylinder. The surface can restrict flow through the flange and be configured to move the temperature compensator in response to the floating piston driving the volume of fluid out of the recuperator cylinder. In some cases, the operation of defining the reverse flow path can include opening a one-way valve configured to permit flow of the volume of fluid along the reverse flow path through the temperature compensator. In this regard, the operation of slideably engaging can include mounting the floating piston and the temperature compensator at a position within the recuperator cylinder using circumferential sealing elements.
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.
The disclosure will be readily understood by the following detailed description in conjunction with the accompanying drawings, wherein like reference numerals designate like structural elements, and in which:
The use of cross-hatching or shading in the accompanying figures is generally provided to clarify the boundaries between adjacent elements and also to facilitate legibility of the figures. Accordingly, neither the presence nor the absence of cross-hatching or shading conveys or indicates any preference or requirement for particular materials, material properties, element proportions, element dimensions, commonalities of similarly illustrated elements, or any other characteristic, attribute, or property for any element illustrated in the accompanying figures.
Additionally, it should be understood that the proportions and dimensions (either relative or absolute) of the various features and elements (and collections and groupings thereof) and the boundaries, separations, and positional relationships presented therebetween, are provided in the accompanying figures merely to facilitate an understanding of the various examples described herein and, accordingly, may not necessarily be presented or illustrated to scale, and are not intended to indicate any preference or requirement for an illustrated example to the exclusion of examples described with reference thereto.
The description that follows includes sample systems, methods, and apparatuses that embody various elements of the present disclosure. However, it should be understood that the described disclosure may be practiced in a variety of forms in addition to those described herein.
The present disclosure describes systems, devices, and techniques related to controlling compressible fluid flow in a recoil system. A recoil system can include a collection of components, assemblies, and subassemblies that cooperate to counteract the force associated with firing a round, such as that from an artillery-type weapon. A recoil rod, as one example, can be driven in a direction that induces momentum in a direction that generally opposes a momentum induced from firing the round. The recoil rod, or other recoil component, can be driven by displacing a compressible fluid into a cylinder or other housing that holds the recoil component. For example, a compressive fluid can be arranged with a recuperator cylinder fluidly connected to the recoil cylinder and a floating piston can operate to drive the compressible fluid from the recuperator cylinder and into the recoil cylinder. However, temperature changes, such as those due to environmental conditions and/or system conditions (e.g., successive firings), can expand the compressible fluid within the recuperator cylinder and increase a potential travel of the floating piston. Left unmitigated, the floating piston could drive an excessive volume of compressible fluid into the recoil cylinder, inducing a momentum for the associated recoiling components that could be inappropriately high or otherwise unsuited for counteracting the recoil forces associated with firing the round.
The temperature compensator of the present disclosure can mitigate such issues, allowing the recoil parts to induce a momentum calibrated from the forces associated with firing the round, notwithstanding temperature increases in the compressible fluid used to drive the recoiling components. An artillery or other weapon system can be used in a variety of ambient conditions and operational factors, while maintaining a desired and repeatable amount of recoil for the target round. While many configurations are possible, the temperature compensator is generally arrangeable along a fluid path between the floating piston (driving the compressible fluid) and the recoil cylinder (housing the recoiling components, such as the recoil rod). In a first configuration, described in greater detail below as a “run up phase,” the floating piston drives the compressible fluid out of the recuperator cylinder and into the recoil cylinder for driving the recoiling components. In this run up phase, the temperature compensator limits the volume of the compressible fluid that the floating piston is capable of displacing, for example, by defining a physical barrier limiting the travel distance of the floating piston, which limits the flow of compressible fluid through the temperature compensator itself.
Subsequently, in a second configuration, described in greater detail below as “recoil phase,” the compressible fluid returns to the recuperator cylinder from the recoil cylinder. The temperature compensator facilitates moving the floating piston towards its initial position by increasing the flow of compressible fluid through the temperature compensator using one or more flow control elements. The multi-configuration operation of the temperature compensator not only allows compressible fluid to be regulated exiting the recuperator, but also permits return and substantial equalization of the recoil system components in preparation for firing a subsequent round.
To facilitate the foregoing, the temperature compensator can be provided with a flange slidably engageable with the recuperator cylinder. The temperature compensator can further include a tube having a first end connected to the flange that extends elongated from the first end to define a second, free end. The flange is arranged along a fluid path between the floating piston and the recuperator cylinder and can generally be adapted to respond to a change in fluid pressure within the recuperator cylinder caused by movement of the floating piston. In this regard, the floating piston can cause the temperature compensator to move along a fluid path towards the recoil cylinder as the floating piston displaces the compressible fluid. During such movement, the temperature compensator can engage an outlet of the recuperator cylinder fluidly connected to the recoil cylinder, controlling flow therethrough. Movement of the temperature compensator fluidly towards the recoil cylinder can be limited by the recuperator cylinder and associated geometries, as described herein, allowing the temperature compensator to “bottom out” at or near an outlet of the recuperator. This can provide resistance and a physical barrier with which to slow and stop the advancement of the floating piston, and thus limit the volume of compressible fluid that the floating piston is able to displace.
For example, at least the flange of the temperature compensator is positioned within the recuperator cylinder. The flange is prevented from exiting from the recuperator cylinder as the outlet of the recuperator cylinder is smaller than the flange. The tube of the temperature compensator, however, is connected with the flange at the first end and capable of sliding engagement with the outlet. As such, the tube is arranged at least partially outside the recuperator cylinder and within a transfer manifold, which fluidly connects the recuperator cylinder and the recoil cylinder. To facilitate compressive fluid flow into the transfer manifold, the tube can define an elongated through portion open at the second, free end, in addition to various slots arranged along an exterior of the tube and extending into the elongated through portion. The tube can thus define a flow path for compressible fluid from a region of the recuperator cylinder at an exterior of the tube (such as adjacent the flange) and into the tube and to the transfer manifold during the run up phase of firing. The flange can also permit fluid flow therethrough during the run up phase, with ports arranged through a thickness of the flange, and having a diameter that is less than that of the tube, such as having a diameter that is substantially less than a diameter of the tube.
During the recoil phase, the temperature compensator increases a potential volume of fluid that can pass through the flange and tube. To facilitate this, the elongated through portion can define an opening on a surface that faces the floating piston within the recuperator cylinder. The elongated through portion extends to the opening, establishing a flow path from the surface of the flange to the second, free end of the tube. In the run up phase described above, the opening is covered and at least partially sealed by a flow control element, such as a one-way valve, and the compressible fluid is substantially blocked from traveling through the opening as the floating piston operates to displace the compressible fluid out of the recuperator cylinder. In the recoil phase, as compressible fluid reenters the recuperator cylinder, the flow control element substantially uncovers the opening at the flange, allowing the compressible fluid to flow therethrough. This increased flow through the temperature compensator via the one-way valve can help move the floating piston toward an initial or latch position, using the pressure from the returning compressible fluid, as described herein.
Various other components, assemblies, and subassemblies are described herein to facilitate the operation of the temperature compensator and associate recoil and artillery systems, as will be appreciated by study of the description herein. For example, the temperature compensator can include a spring or other biasing element that facilitates movement of the flange away from the outlet of the recuperator cylinder. The spring can provide a biasing force that encourages the temperature compensator to move toward an initial or latch position. The biasing force can enhance or augment the movement afforded by fluidic pressure changes in the compressible fluid. This can be beneficial, for example, in a “counter recoil” phase, or other phase of operation, in which the compressible fluid may be returning to a baseline pressure or flow. As another example, systems and techniques are provided to detect, tune, or control the temperature compensator, including using a magnetic-based detection sensor, to identify a position of the temperature compensator in the recuperator cylinder, among other possibilities.
Reference will now be made to the accompanying drawings, which assist in illustrating various features of the present disclosure. The following description is presented for purposes of illustration and description. Furthermore, the description is not intended to limit the inventive aspects to the forms disclosed herein. Consequently, variations and modifications commensurate with the following teachings, and skill and knowledge of the relevant art, are within the scope of the present inventive aspects.
The term “recoiling parts” as used herein generally refers to those elements of a piece of a gun 12 and/or a 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 the recoil system 10 as shown in
A gun 12 without the soft recoil system 10 and removed from a base 14 is shown in
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, where only fluid transfer manifold 65 for the second recoil cylinder 61 and recuperator 66 is shown in
In another embodiment of the 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 advantageous to position the recoil cylinder 61 and/or recuperator 66 either directly above or directly below the barrel 20 such that a vertical plane will bisect the barrel 20, recoil cylinder 61, and recuperator 66. However, other configurations and/or orientations may be used without limitation.
The 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 recoil system 10 is fitted onto the gun 12 of
Within the first recuperator chamber,
As described in greater detail below, the first recuperator chamber 68 can define a pressurizable zone of the recuperator 66. For example, the compressible gas or other fluid that defines the fluid spring can be charged, released, or otherwise activated in order to increase a pressure within the first recuperator chamber 68. The pressure can increase to a threshold value in which the recoil system can initiate a process of displacing the inert oil from the second recuperator chamber 69. In this regard, the pressurized first recuperator chamber 68 can cause the floating piston 67 to move towards the outlet 82, thus displacing the inert oil held substantially between the floating piston 67 and the outlet 82 from the recuperator 66. The temperature compensator 70 is arranged substantially between the floating piston 67 and the outlet 82, in the inert oil or other fluid. The temperature compensator 70 defines a physical barrier limiting the volume of the inert oil displaceable by the floating piston. The displaceable inert oil exits the recuperator 66 and travels into the recoil cylinder 61 via the transfer manifold 65. The buildup of the inert oil in the recoil cylinder 61 can in turn cause the recoil rod to move, inducing the momentum tailored toward counteracting the forces associating with firing the accompanying weapon.
In the embodiment of
The tube 510 can also include a variety of slots extending through the tube wall 534. In the example of
While many configurations are possible, the slots 514, 516 can be dimensioned to induce certain fluid properties and flow paths relative to the temperature compensator 500 and with respect the various operational conditions or phases of the recoil system of the present disclosure. For example, the first end slots 514 can have a first slot width 591 and a first slot length 592 generally larger than the first slot width 591. One or more of the first end slots 514 can therefore be defined by an oval or oblong shape near the first end 512a. The second end slots 516 can have a cross-dimension 593 defining a diameter of the second end slots 516. As shown in
The tube 510 can generally define the elongated through portion 535 as having a width 590. In the case where the tube 510 is substantially cylindrical, the width 590 can represent a diameter of the tube 510. The width 590 is configured to accommodate compressible fluid flow through the tube 510. The width 590 allows sliding engagement of the temperature compensator 500 with the outlet of the recuperator and transfer manifold (e.g., outlet 80 and transfer manifold 65 of
For example,
The temperature compensator 500 is also shown in
The flange 520 also include a face 522. The face 522 can be an exterior surface of the flange 520 that is generally arranged toward the floating piston. The face 522 can be adapted to extend substantially across a diameter of the recuperator cylinder, and generally restrict the flow of compressible fluid thereacross. For example, the face 522 can define a physical barrier against which the floating piston displaces compressible fluid toward in order to move the temperature compensator within the recuperator cylinder. The face 522 therefore can define a sufficient surface area such that the compressible fluid displaced by the floating piston causes the temperature compensator to move within the recuperator cylinder.
The flange 520 can also include various openings, holes, ports, and so on in order to facilitate fluid flow through the flange.
The flange 520 and the tube 510 can be connected to one another at mechanical coupling 549. The mechanical coupling 549 can be a threaded connection, a weld, a snap-fit, or other appropriate connection, including a connection facilitated by other fasteners, locks, and so on. It will also be appreciated that while
In the embodiment of
The continuous through passage can also be selectively openable and closeable using various flow control elements. For example, the temperature compensator 500 is shown in
To facilitate the foregoing, in the embodiment of
The one-way valve 540 can include any appropriate structure to facilitate the articulation of the articulable doors 542a, 542b. For example, the one-way valve 540 can include hinge features 544a, 544b arranged at the face 522 of the flange 520. The hinge feature 544a, 544b can be arranged on opposing sides of the opening 521, in certain embodiments. The one-way valve 540 also includes pins 546a, 546b. The pins 546a, 546b can be used to pivotally mount the articulable doors 542a, 542b to the respective hinge feature 544a.
The articulable doors 542a, 542b, the hinge features 544a, 544b, and the pins 546a, 546b and/or other associated components can cooperate to articulate the articulable doors 542a, 542b between a first, closed position and a second, open position. For example,
In a subsequent firing phase, such as during a recoil phase, the articulable doors 542a, 542b, can pivot into the second, open configuration shown in
As described above, the flange 520 includes the series of ports 524 that can have the diameter 594. The diameter 594 of the ports 524 is less than the diameter 599 of the opening 521 of the flange 520. For example, the diameter 594 of the ports 524 can be substantially less than the diameter 599 of the opening 521, such that the total surface area of all of the series of ports 524 combined, is less than the surface area of the opening 521. Accordingly, the volume of fluid displaceable through the flange 520 can be increased when the one-way valve 540 transitions from the first, closed configuration of
It will be appreciated that while
Also shown in the embodiment of
The biasing element 530 can facilitate movement of the temperature compensator 500 toward the floating piston. As shown in greater detail with respect to
The temperature compensator 650 is shown in
With reference to
During the run up phase shown in
The temperature compensator 650 can continue moving fluidly toward the recoil cylinder until it reaches a “bottom out” position or stop position. At the bottom out position, as shown in
With reference to
The flow of compressible fluid into the recuperator cylinder 610 can cause the temperature compensator 650 and floating piston 624 to move fluidly away from the recoil cylinder 602. The compressible fluid can move into the recuperator cylinder 610 with sufficient driving force in order to move the flange 665 away from the outlet 630. The compressible fluid can also flow through the tube 655 and cause the one-way valve 680 to open. For example, the one-way valve 680 can include articulable doors (e.g., articulable doors 542a, 542b of
The one-way valve 680 can therefore be used to define a flow path through the temperature compensator 650 for the compressible fluid. The one-way valve 680 permits increased fluid flow through the temperature compensator 650 when in an open configuration, mitigating impediments to compressible fluid reentry into the recuperator cylinder 610. The compressible fluid can travel along this flow path, through the temperature compensator 650, and cause the floating piston 624 to move toward an initial or latch position. This is illustrated in
With reference to
The temperature compensator 650 can also be slideable engaged with the outlet 630 of the recuperator cylinder 610 and/or surface or associated features of the transfer manifold 620. For example, the tube 655 can extend through the outlet 630 and at least partially into the transfer manifold 620, sliding therein as the temperature compensator 650 moves during the various phases of operation of the recoil system.
The outlet 630 depicted in
In certain embodiments, such as that shown in
With reference to
In the counter recoil phase, the movement of the floating piston 624 back toward the outlet 630 can thus cause the one-way valve 680 to close. For example, where the one-way valve 680 is defined by articulable doors, the flow of compressible fluid can cause the doors articulated into a closed position, thus mitigating fluid flow through the elongated through portion of the temperature compensator 650. The floating piston 624 and temperature compensator 650 can generally continue to move together until the recoiling parts reach the latch position. Depending on the recoil distance behind the latch, the temperature compensator 650 may not necessarily bottom out during the counter recoil stroke. Once the recoiling parts are at latch, the biasing element 675 on the temperature compensator 650 can return the temperature compensator 650 to its original pre-fire position. For example, the biasing element 675 can be at least partially compressed during the counter recoil phase, as shown in
To facilitate the reader's understanding of the various functionalities of the embodiments discussed herein, reference is now made to the flow diagram in
In this regard, with reference to
At operation 1004, a floating piston and a temperature compensator can be slideably engaged within a recuperator cylinder. The recuperator cylinder can be fluidly couplable with a recoil rod that is separated from the floating piston by the temperature compensator. For example and with reference to
At operation 1008, the floating piston can be used to displace a volume of fluid out of the recuperator cylinder to move the recoil rod. The volume of fluid can be limited by a travel of the temperature compensator at least partially out of the recuperator cylinder. For example and with reference to
At operation 1012, a reverse flow path can be defined for the fluid through the temperature compensator to move the floating piston away from the recoil rod. For example and with reference to
Other examples and implementations are within the scope and spirit of the disclosure and appended claims. For example, features implementing functions may also be physically located at various positions, including being distributed such that portions of functions are implemented at different physical locations. Also, as used herein, including in the claims, “or” as used in a list of items prefaced by “at least one of” indicates a disjunctive list such that, for example, a list of “at least one of A, B, or C” means A or B or C or AB or AC or BC or ABC (i.e., A and B and C). Further, the term “exemplary” does not mean that the described example is preferred or better than other examples.
The foregoing description, for purposes of explanation, uses specific nomenclature to provide a thorough understanding of the described embodiments. However, it will be apparent to one skilled in the art that the specific details are not required in order to practice the described embodiments. Thus, the foregoing descriptions of the specific embodiments described herein are presented for purposes of illustration and description. They are not targeted to be exhaustive or to limit the embodiments to the precise forms disclosed. It will be apparent to one of ordinary skill in the art that many modifications and variations are possible in view of the above teachings.
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