A gun may accelerate a projectile through a barrel by creating high pressure behind that projectile. Conventional guns employ some type of propellant to create that high pressure. The propellant may be gases resulting from burning gun powder, smokeless powder, rocket fuel, other chemical(s). Steam and other gasses have also been used. As a propellant pushes a projectile through a gun barrel, the propellant expands and the pressure in the propellant drops, thereby reducing the force accelerating the projectile. This pressure loss may be increased as heat energy in the propellant is transferred to the gun barrel.
This Summary is provided to introduce a selection of some concepts in a simplified form as a prelude to the Detailed Description. This Summary is not intended to identify key or essential features.
A projectile accelerator, such as a gun or a propulsion system, may include a barrel with one or more heaters configured to heat a bore of the barrel. An inner barrel may comprise a tungsten sleeve that may be heated to high temperatures. A pressurized propellant may be released into a breach chamber to move a projectile through the barrel. Heat from the barrel may be transferred to the expanding propellant behind the projectile, thereby reducing pressure loss and increasing acceleration of the projectile. The propellant may comprise hydrogen, helium, and/or other gases. Propellant may be recovered from near the barrel exit and recycled. A shutter may cover the barrel exit to prevent incursion of air into the heated barrel bore.
These and other features are described in more detail below.
Some features are shown by way of example, and not by way of limitation, in the figures of the accompanying drawings and in which like reference numerals refer to similar elements.
A gun barrel may be deliberately heated so as to reheat propellant in the barrel. This reheating may increase pressure in the propellant and thereby increase acceleration imparted to a projectile which the expanding propellant is driving through the barrel bore. Because a heated barrel may add energy into the propellant, the initial propellant energy at the gun's breach may be reduced. This may reduce the peak pressure in the barrel and peak acceleration of the projectile. This may allow a much smoother pressure profile in the barrel, and a smoother acceleration profile for the projectile, than may be available using a traditional gun.
A gun barrel may be heated to very high temperatures. The gun barrel may include an inner barrel that is a sleeve formed from a tungsten alloy and/or from other materials able to retain ductility at high temperatures. The sleeve may be sized so that it has a heat capacity and a thermal conductivity that allow the sleeve to maintain a high temperature as heat is drawn from the inner sleeve by propellant. A light gas may be used as a propellant. Examples of light gases include, without limitation, hydrogen (H2), helium (He), mixtures of H2 and He, and H2 and/or He combined small amounts of other gases and/or other materials. In general, a light gas may be any gas or gas mixture that, at a given pressure and temperature, has a higher speed of sound than air (He/H2 mixtures have a speed of sound that is approximately 3× that of air, or more) and/or has a higher heat absorption rate from a heated barrel than air. A light gas may also or alternatively be a gas or gas mixture chosen so as to be non-reactive with a barrel material (e.g., a gas or gas mixture containing no oxygen or only containing trace amounts of oxygen).
The gun 10 may include a barrel 12 and a launcher 14. The launcher 14 may include a forward section 16 that includes a breach and a portion of a compression chamber and a rear section 17 that includes another portion of the compression chamber. The breach and the compression chamber, as well as other elements of the launcher 14, are described below. The forward section 16 and the rear section 17 may include flanges 20 and 21 that may be pushed together to seal the compression chamber and separated to permit access to the breach. Hydraulic rams, not shown, may be positioned around the circumferences of the flanges 20 and 21 to open and close the launcher 14.
The barrel 12 may include one or more heating elements along its length. Those elements may be ohmic, inductive, and/or other type heating elements that are electrically powered via cables 23. The cables 23 from the individual heating elements may join a wiring harness 24 that connects the heaters to an electrical power source (not shown). A rear shutter assembly 59 may separate the barrel 12 from the launcher 14. A front shutter assembly 25 may be positioned at the muzzle of the barrel 12.
Shown in
A piston 46 may separate the combustion chamber 31 from the compression chamber 32. The piston 46 may be moveable along the interior surface of the rear section 17. A gas-tight seal may be formed between the piston 46 and the inner wall of the rear section 17 so that an increase in gas pressure in the combustion chamber 31 pushes the piston forward into the compression chamber 32. An outer surface of the piston 46 may include compression rings and/or other types sliding seals between the piston 46 and the inner wall of the rear section 16.
As indicated above, the rear section 17 and the front section 16 may be joined together at the flanges 21 and 20 to close and seal the compression chamber 32. High temperature gaskets, metal-to-metal seals, and/or other components may be included between the flanges 21 and 20 to form a gas-tight seal.
The compression chamber 32 may include a port 49. A valve 51 may be openable to allow flow of a light gas (LG) into the chamber 32 through the port 49 and closable to prevent flow in or out of the chamber 32 through the port 49. A forward portion of the compression chamber 32 may taper to form an entrance to the breach 33. The interface between the chamber 32 and the breach 33 may include a lip 52 configured to hold a shear plate, as described below. The breach 33 may include ports 55 and 56. A valve 57 may be openable to allow flow of a purge gas into the breach 33 through the port 55 and closable to prevent flow in or out of the breach 33 through the port 55. A valve 58 may be openable to allow flow of a purge gas out of the breach 33 through the port 56 and closable to prevent flow in or out of the breach 33 through the port 56.
The launcher may include a rear shutter assembly 59 that includes a rear shutter 60. The rear shutter 60 may have a closed position, shown in
The barrel 12 may include an inner barrel that comprises a sleeve 65 in which the bore 62 is formed. The sleeve 65, including the surface of the bore 62, may be formed from one or more tungsten alloys. An inner barrel sleeve may also or alternatively formed from one or more other materials. As but one example, an inner barrel may be formed from steel. The barrel 12 may further include multiple heaters 66.1 through 66.n positioned along the length of the barrel 12. For convenience, heaters 66.1 through 66.n may be referred to collectively or generically as the heaters 66. Each of the heaters 66 may be an annular heating element that may be individually controllable. By varying the heat output of individual heaters 66, a desired temperature gradient may be generated along the barrel 12. For example, and as described in more detail below, one or more heaters at the rear end of the barrel 12 may be set (e.g., by adjusting power input) to output less heat than one or more heaters at the front end of the barrel 12.
Insulation 68 may surround the heaters 66 to retain heat. As explained in more detail below, the heaters 66 may be used to heat some or all of the barrel 12 to extremely high temperatures (e.g., 2200° K or higher). To prevent damage to other elements in the gun from the high temperatures of the barrel 12, a rear insulator 70 may separate the heated portions of the barrel 12 from the launcher 14. A front insulator 71 may separate the heated portions of barrel 12 from elements in the muzzle of the barrel 12. Examples of materials that may be used for the insulators 70 and 71 and for the insulation 68 include, without limitation, thorium dioxide and other ultra-high temperature ceramics (e.g., hafnium diboride, zirconium diboride, hafnium nitride, zirconium nitride, titanium carbide, titanium nitride, tantalum carbide, as well as combinations and/or composites comprising one or more of those compounds). Additional reinforcement may be included, e.g., titanium bands surrounding the insulators 70 and/or 71.
The elements at the front end of the barrel 12 may include a propellant recovery manifold 75 and the front shutter assembly 25. The recovery manifold 75 may include a port 76 through which expanding propellant may flow to a propellant recovery and supply system 90, as described below. A valve 77 may be openable to allow flow of propellant out of the manifold 75 through the port 76 and closable to prevent flow in or out of the manifold 75 through the port 76. The front shutter assembly 25 may be located forward of the recovery manifold 75 and may include a front shutter 80. The front shutter 80 may have a closed position, shown in
Internal surfaces of the combustion chamber 31, the compression chamber 32, the breach 33, and the bore 62 may be circular in planes perpendicular to the longitudinal axis L of the gun 10 and to the view of
The gun 10 may also include a propellant recovery and supply system 90. The propellant may be a light gas. The system 90 may include one or more storage tanks 91 to hold a supply of propellant. The propellant in the tank(s) 91 may be pressurized. As shown with broken lines, an outlet of the tank(s) 91 may be connected by high pressure gas lines to the valve 51. The system 90 may also include a propellant pumping/processing subsystem 92. An inlet of the subsystem 92 may be connected to the valve 77 and may recover propellant after firing of the gun 10. As shown with broken lines, the valve 77 may be connected to the subsystem 92 by high pressure gas lines. The subsystem 92 may include one or more filters to remove particles (e.g., pieces of a shear plate and/or other by-products of firing) from recovered propellant. The subsystem 92 may also or alternatively include one or more gas separators to remove other gases from recovered propellant. The gases removed from recovered propellant could include, e.g., remnants of purge gas and/or air drawn in through the muzzle of the barrel 12 as a projectile exits. One or more high pressure pumps of the subsystem 92 may then transfer the recovered and processed propellant to the tank(s) 91.
As also shown in
As the compressed propellant in the compression chamber 32 expands into the breach 33, the projectile 100 is pushed forward through the breach 33, and into and through the heated bore 62 of the barrel 12. As the projectile 100 moves through the bore 62, heat from the bore 62 is transferred to the expanding propellant behind the projectile 100. This transfer of heat into the propellant may reduce the loss in pressure that would otherwise result from the increasing volume behind the projectile 100 as it travels along the bore 62. This reduction in propellant pressure loss results in the force pushing the projectile 100 being maintained for a longer period of time and/or at a higher level, thereby increasing the acceleration of the projectile 100.
The gun 210 may include a barrel 212 that is similar to the barrel 12, and a launcher 214 that includes a forward section 216 and a rear section 217. The sections 216 and 217 may be similar to the sections 16 and 17 described in connection with the gun 10, except that the rear of the rear section 217 may be modified to accommodate the railgun 311. Flanges 220 and 221 may be pushed together to seal a compression chamber and separated to permit access to a breach. Hydraulic rams, not shown, may be positioned around the circumferences of the flanges 220 and 221 to open and close the launcher 214.
In a railgun, drive current is applied to a pair of rails. A conductive armature spans the rails and is driven along those rails by the resulting magnetic fields. Conventional rail guns use the armature to directly accelerate a projectile being fired from the railgun. In the railgun 311, however, the armature 313 is not used to directly push a projectile. Instead, the armature is used to push the piston 246 in order to compress the propellant in the compression chamber 232. The railgun 311 may thus be operated at less extreme power levels than may be needed to directly accelerate a projectile, thereby allowing the rails, the armature 313, and other components of the railgun 311 to have a longer service life than components used in conventional railguns.
Although the armature 313 and the piston 246 move relative to one another in the gun 210, this need not be the case. For example, the railgun 311 may be configured so that the piston is attached to the end of the armature. The attached piston may be removable from the armature so that it can be replaced and/or so that the piston and armature may be made of different materials.
Other types of electrically-powered linear actuators may be used instead of, or in conjunction with, the railgun 311. For example, a linear induction motor may be used.
Using a heated gun barrel, e.g., a very hot gun barrel, reheats propellant as it travels in the barrel. This increases the gas pressure in the propellant, and hence acceleration of the projectile in the barrel. In contrast, a room temperature barrel absorbs energy from propellant and reduces pressure on a projectile. Because a hot barrel adds energy into propellant, the propellant's energy at the breach at the time of firing can be reduced. In particular, because gas pressure of the propellant may be maintained (or at least reduced at a slower rate) in a hot barrel, the initial propellant pressure at time of firing can be lower than would be needed if a cold barrel is used. This may reduce the peak propellant pressure and peak projectile acceleration in a gun. This may allow a much smoother pressure profile on the projectile than may be available using a traditional gun.
A cold barrel can absorb approximately 30% of a typical gun propellant's energy. Heating a steel barrel may add energy to the propellant in the barrel, and applied to a state of the art tank gun, may raise muzzle velocity from Mach 5 to about Mach 7. However, the strength of steel is greatly reduced at higher temperatures, thus limiting the degree to which such a barrel could be heated and the amount of velocity gained from heating. A tungsten barrel may address these issues. For example, the sleeves 65, 265, and 465 in the guns 10, 210/210′, and 410 could be formed from one or more tungsten alloys. Tungsten has high strength and ductility at high temperatures. Indeed, many tungsten alloys are so hard that they may be brittle at room temperature. Tungsten also has good thermal conductivity and other properties. A light gas propellant such as hydrogen can absorb energy from a barrel at about ten times the rate of standard propellants, and is relatively non-reactive with tungsten, thereby reducing barrel erosion. The very high rate of the thermal energy absorption of hydrogen indicates that a hot barrel may add 300% to the propellant energy. That may achieve muzzle velocities in excess of Mach 5, and potentially greater than Mach 7.5.
The energy requirement to fire a barrage round (e.g., a 14 Kg projectile plus a 6 Kg sabot) at Mach 7.5 using a gun with a heated barrel is estimated to be about 270 Megajoules (MJ), e.g., approximately 50 MJ into the projectile, 20 MJ into the sabot, and 200 MJ into the propellant. Firing 10 rounds per minute infers a raw 45 Megawatt power requirement into the tungsten barrel to continuously heat and reheat it between and during fires. A tungsten barrel with light gas propellant can handle such an energy requirement. This raw 45 Megawatt estimate can potentially be reduced, however, by recycling heat energy from the propellant. For example, propellant recovered at firing (e.g., from the valves 77, 277, and 477 of the guns 10, 210/210′, and 410) would still be heated. The recovered propellant can be passed through a heat exchanger and recovered heat used to preheat propellant in the compression chamber prior to firing.
In the examples described above, a separate shear plate and projectile were shown. A projectile and a shear plate could be integral so that both can be loaded in a single motion. For example, a shear plate could be attached to the rear of a projectile. As another example, a shear plate may take the form of a ring that surrounds the outer circumference of projectile and that fits into a lip such as any of the lips 52, 252, or 452. A shear plate could be configured to remain in place after firing (e.g., a center portion may break away and travel with the projectile and leave a ring in place on the lip), and then be removed when the next projectile and shear plate are loaded.
Tungsten properties may be used to estimate reasonable pressure and temperature curves for a thermal gun to achieve Mach 7.5 muzzle velocity.
The rate of heat absorption into a pure hydrogen propellant may depend on: (1) the combination of its turbulence in the barrel and other factors that determine the thermal convection, (2) hydrogen's underlying thermal conductivity, (3) geometry factors of the barrel, and (4) the time available as the hydrogen travels through the barrel. Several approaches to estimating these factors have been used. For example, a 10× increase of thermal conductivity of hydrogen relative to propellants used in standard guns is based on a combination of: (1) hydrogen's very high thermal conductivity (more than a factor of 5 higher than standard propellants), and (2) its low viscosity (by more than a factor of 2), which raises the level of turbulence and thus the Nusselt number (the ratio of thermal convection to thermal conductivity) by a factor of 2. The two factors contribute multiplicatively (thermal convection=Nusselt Number×thermal conductivity) resulting in the factor of 10. Comparisons can also be made to tests performed by NASA on hydrogen gas heated by passage through heated tungsten tubes. Table 3 compares data reported from or derived based on) the NASA tests and estimates for a 132 mm thermal gun.
The bottom row of Table 3 shows that the temperature rise of the hydrogen per degree difference between the gas and wall temperature is similar for the NASA tubes and modeling for a 132 mm thermal gun. The NASA tubes show temperature rises of over 800° K for averaged temperature differences between gas and barrel temperature of about 600° K. A wall temperature of 3000° K in a thermal gun is correspondingly estimated to provide the temperature rise shown in
For the 132 mm bore barrel, estimated peak gas pressure is about 42,000 psi (
Depending on the amount of thermal convection and on the ability of a guided projectile to withstand accelerations up to 30,000 g, it is estimated that Mach 7.5 can be achieved with a 14 meter heated gun barrel. However, a longer barrel (e.g., 20 meters) may offer advantages. A longer barrel may allow reduced barrel pressure. A longer barrel may allow lower acceleration forces on electronics of a guided round. A longer barrel may allow higher velocities by increasing the barrel temperature and/or increasing the quantity of propellant.
As described above, a barrel may have multiple heating elements arranged along its length, and each of those heating elements may be individually controllable (e.g., by varying power inputs to the heating elements). This allows creation of a temperature gradient along the length of a barrel.
A gun with a heatable barrel (e.g., such as one or more of the guns 10, 210, 210′, or 410), may be used as part of a propulsion system, for example, in a spacecraft. In situ dust (hereafter “dust”) can be used to create projectiles. Sources of dust may include asteroids, moons, mining tailings, etc. Dust may include, for example, a high percentage (e.g., 40% or more) of silicon dioxide (SiO2). Other compounds present in significant quantities (e.g., approximately 10% or more) may include aluminum oxide (Al2O3), titanium dioxide (TiO2), ferrous oxide (FeO), magnesium oxide (MgO), and/or calcium oxide (CaO). Dust is relatively easy to process, e.g., by filtering or grinding dust to a 200μ size, and/or by compacting dust into pellet projectiles. Dust is relatively easy to store because of its higher density and non-need for pressurization, and is generally not corrosive. Dust itself may contain little or no chemical energy. However, it has mass, and ejection of dust (using a gun with a heated barrel) at high velocity may generate thrust. Projectiles may be created by compressing and heating dust sufficiently to bind the dust into a pellet that will retain integrity as is travels through most of a barrel. Because many materials of dust melt at temperatures much lower than tungsten, a projectile formed from dust may become fully or partially molten as it travels through the barrel and may exit a gun as smaller particles. Molten particles may quickly solidify after exit. Because particles exiting the barrel may be smaller than the pellet, the risk of damage to other objects in space may be reduced.
A gun may develop very high pressures to accelerate projectiles. The pressure drops as the projectile accelerates, though much more slowly in an isothermal process than in an adiabatic one. A heated barrel can be used to make a process more isothermal. For isothermal expansion, specific impulse (SI) for the projectile's mass can match (or possibly exceed) that of other engine types that use that same propellant without projectiles. In guns with barrel lengths 50 to 100 times greater than the bore diameter, acceleration may continue until the projectile is outpacing much of the propellant. The projectile velocity may exceed the speed of sound in the propellant.
The propulsion system 610 may lack a rear shutter assembly. A front portion 616 of a launcher 614 may lack ports and valves for purging of a breach 633 and/or may lack a rear shutter assembly, but may otherwise be similar to the front portion 416 of the gun 410. Other components of the propulsion system 610 may the same as, or similar, components of the gun 410. Each row of Table 4 indicates one or more elements of the gun 410 that may be structurally similar to, and that may operate in a similar manner as, one or more corresponding elements of the propulsion system 610.
Projectiles 700 may be formed from compressed dust. A magazine 702 may hold multiple projectiles 700 and corresponding shear plates 701. The magazine 705 may include additional structures, not shown to move the magazine 705 into or out of position for loading of a projectile into the breach 633. The magazine 705 may further include structures, also not shown, to push a single projectile 700/shear plate 701 out of the end of the magazine 705 and into the breach 633/lip 652. The magazine 705 may, for example, include one or more servos to release a projectile 700/shear plate 701 from the bottom of the magazine 705 and push the released projectile 700/shear plate 701 into position. In a zero-g environment of a spacecraft, the forces needed to manipulate a released projectile 700/shear plate 701 into position would be relatively small, and servos and/or other manipulation structures may be relatively lightweight.
Although the propulsion system 610 is similar to the gun 410, propulsion systems similar to the guns 10, 210, and/or 210′ could also or alternatively be used. Additional modifications may also be made to propulsion systems and/or guns. For example,
Unlike the propulsion system 610, the propulsion system 810 may use a low enrichment uranium (LEU) nuclear pile 909 to heat the barrel 812. Although the pile 909 is shown as a single element for simplicity, multiple piles could be used. An LEU nuclear pile could also be combined with ohmic or other electrically powered heating elements, e.g., to control temperature in different zones of the barrel 812.
The thrust of a propulsion system may be increased by increasing a firing rate.
The propulsion system 1010 may include a nuclear pile, similar to the nuclear pile 909, instead of or in addition to the heaters 1066. Any of the guns 10, 210, 210′, or 410 could be modified to include a magazine similar to the magazine 1103.
Although the examples of
Barrels may be of different lengths. Longer barrels may be used to achieve higher projectile velocities. Non-limiting examples of barrel lengths include 14 m, 20 m, and 30 m. Barrel temperature may be used to control velocity, and thus range, of a projectile fired from a heated barrel. Temperatures to which a barrel bore may be heated may depend on material choice. Barrel sleeves formed from tungsten may be heated, e.g., to 2000° K or more, to 2200° K or more, to 2500° K or more, or to 3000° K or more. Barrel sleeves formed from steel and/or other materials may be used, but may be limited to lower temperatures. Barrels may include sleeves formed from multiple materials. For example, portions of a barrel sleeve adjacent a breach and extending toward a center of a barrel's length may be formed from steel, with remaining portions of the sleeve formed from tungsten.
Multiple propulsion systems using heatable barrels may be used in a single spacecraft. The multiple propulsion systems may be of the same type (e.g., with electrical or nuclear heating, with mechanical and/or electrical propellant compression, etc.) or of different types. Multiple propulsion systems in a single spacecraft may be fired in sequence to provide smoother thrust.
The foregoing has been presented for purposes of example. The foregoing is not intended to be exhaustive or to limit features to the precise form disclosed. The examples discussed herein were chosen and described in order to explain principles and the nature of various examples and their practical application to enable one skilled in the art to use these and other implementations with various modifications as are suited to the particular use contemplated. The scope of this disclosure encompasses, but is not limited to, any and all combinations, subcombinations, and permutations of structure, operations, and/or other features described herein and in the accompanying drawing figures.
This application is a continuation of U.S. patent application Ser. No. 16/901,286, titled “Projectile Accelerator with Heatable Barrel,” filed Jun. 15, 2020, which is a continuation of U.S. patent application Ser. No. 16/509,052, titled “Projectile Accelerator With Heatable Barrel,” filed Jul. 11, 2019, which is a continuation of U.S. patent application Ser. No. 16/168,184, titled “Projectile Accelerator With Heatable Barrel,” and filed Oct. 23, 2018, which claims priority to U.S. provisional patent application No. 62/576,316, titled “Thermal Gun for Hypervelocity Guided Projectile Launch and/or Use With In Situ Dust for Spacecraft Propulsion,” and filed Oct. 24, 2017. Application Nos. 62/576,316, 16/168,184, 16/509,052, and 16/901,286, in their entireties, are incorporated by reference herein.
Number | Date | Country | |
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62576316 | Oct 2017 | US |
Number | Date | Country | |
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Parent | 16901286 | Jun 2020 | US |
Child | 17515805 | US | |
Parent | 16509052 | Jul 2019 | US |
Child | 16901286 | US | |
Parent | 16168184 | Oct 2018 | US |
Child | 16509052 | US |