The present technology relates to thermal protection systems for rockets that cool and/or insulate the rocket during flight.
Rocket manufacturers continually strive to reduce the cost of launching a payload into space. One approach for reducing such costs is to retrieve one or more booster stages used to propel the space launch vehicle. In a particular approach, the booster is launched and landed vertically and refurbished for another launch. One drawback to this approach is that the exterior surfaces of the booster, including the engine nozzles, are subjected to high temperatures, which can result in damage to these surfaces during ascent and/or descent. To overcome this drawback, launch and reentry vehicle manufacturers utilize insulation and cooling systems designed to reduce the amount of heat the engine nozzles and/or other surfaces are exposed to during flight. Conventional types of insulation include single-use insulation (which must be replaced after every rocket launch), metal shielding (which can change shape due to thermal expansion when subjected to high temperatures), and insulating tiles and blankets (which are not very robust and which often require refurbishment between launches). For example, conventional insulating blankets, such as the Advanced Flexible Reusable Surface Insulation (AFRSI) used on the space shuttle, are formed from silica insulation and quartz fabric and threads, which stitch the insulation and fabric together with a square stitching pattern. Quartz fibers are typically not very durable and are easily damaged if impacted during flight. Accordingly, there is a need for an improved thermal protection system for reusable launch vehicles.
Several embodiments of the present technology are directed to systems and apparatuses for cooling and/or insulating rocket engine nozzles and other launch vehicle components in order to reduce the effects of heat on the components. For example, the present technology can include a flexible thermal protection apparatus having an insulation layer positioned between two fabric layers. The insulation layer and the fabric layers can be stitched together with a tight stitching pattern using thread. The outermost fabric layers and/or the thread can be formed from a metal that provides impact resistance and improves the durability of the thermal protection apparatus. In some embodiments, the thermal protection apparatus can be attached to the rocket components using adhesive and the apparatus can be saturated with water. This approach can utilize the high heat capacity and high heat of vaporization of water to insulate launch vehicle components when the launch vehicle reenters the atmosphere and lands. For example, when exposed to high temperatures, water trapped within the thermal protection apparatus can be heated to a temperature at or near the boiling point of water. As the water vaporizes, it can transpire out of the thermal protection apparatus, thereby removing the energy from the thermal protection apparatus. Further, as the vaporized water moves out of the thermal protection apparatus, it can absorb additional energy from the outer layers of the thermal protection apparatus. As a result, the thermal protection apparatus can absorb a large amount of heat that would otherwise be absorbed by the rocket engine nozzles and other launch vehicle components.
Specific details of several embodiments of the disclosed technology are described below with reference to particular, representative configurations. The disclosed technology can be practiced in accordance with launch vehicles, rocket engine nozzles, and/or insulation having other suitable configurations unrelated to launch vehicle applications. Specific details describing structures or processes that are well-known and often associated with launch vehicles and insulation but that can unnecessarily obscure some significant aspects of the presently disclosed technology, are not set forth in the following description for purposes of clarity. Moreover, although the following disclosure sets forth some embodiments of different aspects of the disclosed technology, some embodiments of the technology can have configurations and/or components different than those described in this section. Further, unless otherwise specifically noted, elements depicted in the drawings are not necessarily drawn to scale. As such, the present technology can include some embodiments with additional elements and/or without several of the elements described below with reference to
The first stage 113 of the launch vehicle 110 includes a propulsion system 120 positioned at the second end 112 and having a plurality of nozzles 121 oriented to direct exhaust products in a generally downward direction (i.e. in the second direction 102). Each of the nozzles 121 can be a de Laval nozzle having a generally frustoconical shape and having an exterior surface 123 and an interior surface 122. The nozzles 121 are typically formed from metal (e.g., copper) and can include multiple layers of different metals, such that the exterior surface 123 can include a first metal while the interior surface 122 includes a second metal (e.g., a metal different from the first metal). In some embodiments, the propulsion system 120 can include seven nozzles 121. In other embodiments, however, the propulsion system 120 can include just a single nozzle 121, or can include between two and six nozzles 121, or can include more than seven nozzles 121. The propulsion system also includes one or more combustion chambers located within the body of the launch vehicle 110, with each of the nozzles 121 coupled to a given one or more of the combustion chambers. Each of the combustion chambers receives fuel from a fuel pump coupled to a fuel tank. An igniter ignites the fuel within the combustion chamber, creating high energy exhaust products that are directed through the associated nozzle 121. Each of the nozzles 121 is positioned to direct the exhaust products away from the second end 112 of the launch vehicle 110 (e.g., in the second direction 102), thereby generating thrust that pushes the launch vehicle in the first direction 101.
Once the launch vehicle 110 reaches a specific and pre-determined point in the launch process (e.g., a specific altitude or speed, a specific amount of fuel consumed, anomaly detection, etc.), the first and second stages 113 and 114 separate from each other at the separation location 116. In some embodiments, the second stage 114 includes a secondary propulsion system used to propel the second stage 114 towards its final destination after the first and second stages 113 and 114 separate, while the first stage 113 returns back to Earth. In other embodiments, the second stage 114 does not include a secondary propulsion system and/or both the first and second stages 113 and 114 return to Earth after separation. The first stage and second stages 113 and 114 can also include lateral thrusters coupled to the first stage and second stages 113 and 114 used to stabilize and control the first stage and second stages 113 and 114. Further details of the lateral thrusters are included in pending U.S. Published Patent Application No. US 2017/0349301, incorporated herein by reference.
As the first stage 113 descends, the propulsion system 120 and the lateral thrusters work together to control the orientation and speed of the first stage 113. In a representative embodiment, the propulsion system 120 and the lateral thrusters control the descent of the first stage 113 such that first stage 113 moves in the second direction 102 and the vehicle axis V is generally parallel to the second direction 102. As it approaches the landing site, the first stage 113 can have a generally vertical orientation such that the second direction 102 and the vehicle axis V are both oriented perpendicular to the ground and the one or more nozzles 121 direct the exhaust products downwards, causing the first stage 113 to decelerate. Landing gear, which can be stowed away during ascent and descent, extends from the body of the first stage 113 and supports the weight of the first stage 113 as it lands. Once the first stage 113 lands, the propulsion system 120 shuts down and the first stage 113 is secured to the landing site. The landing site can include a platform in a body of water. In this way, the first stage 113 can be used for subsequent launches and only minor refurbishments and part replacements may be required between subsequent launches of the first stage 113.
Throughout the launching and landing processes, the launch vehicle 110 is subjected to extreme conditions. For example, the nozzles 121 are exposed to large amounts of heat during the ascent as the fuel is ignited and the nozzles 121 expel the exhaust products. Further, as it reenters and descends through the atmosphere, the second end 112 of the first stage 113 is subjected to high air pressures and temperatures caused by friction between the air and the second end 112. To reduce the effects of the high temperatures, the launch vehicle 110 includes a thermal protection system that includes shielding, insulation, active cooling, and/or other elements or sub-systems. For example, referring now to
In a representative embodiment, the thermal protection apparatus 140 is coupled to the exterior surfaces 123 of each of the nozzles 121. Accordingly, the thermal protection apparatus 140 can be generally flexible, and can be sized and shaped to conform to the curved exterior surfaces 123. In the illustrated embodiment, the thermal protection apparatus 140 is wrapped around an individual nozzle 121 such that the entire exterior surface 123 of the nozzle 121 is covered. In other embodiments, only a portion of the exterior surface 123 may be covered. For example, in some embodiments, only the bottom portion of the exterior surface 123 of each nozzle 121 is covered while the top portion is uncovered.
As shown in
In representative embodiments, the outer fabric layer 145 is formed from a fabric having strength and oxidation resistance at high temperatures. In some embodiments, the outer fabric layer 145 can include metal alloy fibers (e.g., fibers of Inconel alloys available from Special Metals Corporation or Haynes 230® available from Haynes International). Such fibers have high strength and resist oxidation when exposed to high temperatures (e.g., up to 2100° F.) for prolonged periods of time, have excellent long-term stability, are easily fabricated and formed, and/or have high impact resistance. As such, the metal alloy fibers can improve the durability and strength of the apparatus 140, which can improve the longevity of both the apparatus 140 and the nozzle 121 to which it is attached. In other embodiments, the outer fabric layer 145 can be formed from quartz fibers (e.g., formed from Astroquartz® available from JPS Composite Materials), which are capable of withstanding high temperatures for short periods of time and have a low density, and/or ceramic fibers (e.g., formed from Nextel™ 440 available from 3M), which can withstand extremely high temperatures (e.g., up to 2500° F.) for short periods of time without degradation. In general, the outer fabric layer 145 can be formed from any suitable material that has high thermal resistance and is capable of withstanding high temperatures without significant deformation or degradation.
In representative embodiments, the outer fabric layer 145 can have an angle-interlock architecture. Fabrics having an angle-interlock architecture include a plurality of layers of weft fibers stacked on top of each other and woven together with warp fibers that weave between the weft fiber layers. The individual weft fiber layers can be selectively oriented with respect to each other by angling the individual layers relative to each other. In the illustrated embodiment, the outer fabric layer 145 includes two layers 159 of weft fibers layered on top of each other and woven together with warp fibers. With this angle-interlocked architecture, the outer fabric layer 145 remains generally flexible while also providing durability and improved impact resistance for longevity. Further, the angle-interlocked architecture can help to trap any broken fibers so that the structural integrity of the outer fabric layer 145 is not significantly impacted by the presence of such fibers. Although the outer fabric 145 is depicted as being formed form two layers 159 of weft fibers, in other embodiments, the outer fabric layer 145 can be formed from three or more layers 159 woven together in an angle-interlock architecture. In still other embodiments, the outer fabric layer 145 may be formed from just a single layer 159 of weft fibers.
The sewing threads 150 can include outer threads 151 and inner threads 152. The outer threads 151 are positioned adjacent to the outer surface 142 and the inner threads 152 positioned adjacent to the inner surface 143. In some embodiments, the threads 150 are formed from the same fibers that form the outer fabric layer 145. For example, in embodiments for which the outer fabric layer 145 is formed from metal alloy fibers, the inner and outer threads 152 and 151 can also be formed from the metal alloy fibers. In other embodiments, however, the inner and outer threads 152 and 151 can be formed form different fibers. For example, in some embodiments, the outer threads 151 can be formed from metal alloy fibers while the inner threads 152 are formed from Kevlar® fabric fibers. In some embodiments, a CNC sewing machine can be used to stitch the outer fabric layer 145, the layer of insulation, and the inner fabric layer 146 together.
Threads 150 are used to stitch the outer fabric layer (e.g., the weft fibers combined with the warp fibers) to the structure below. The threads 150 can be arranged in any suitable pattern. In representative embodiments, the threads 150 can be arranged to form a plurality of columns 154. The columns 154 can be configured such that, when the thermal protection apparatus 140 is coupled to the nozzle 121, the columns 154 generally align along the vehicle axis V (
In some embodiments, the launch vehicle 110 can be designed to fly in inclement weather, such as on rainy days. When the launch vehicle 110 is launched in inclement weather, rain drops (or other forms of atmospheric condensation) can impact the thermal protection apparatus 140 at high speeds. These high-speed rain drops typically travel in a direction perpendicular to the rows 153 (e.g., second direction 102) such that, if rain drops impact a thread 150 that forms one of the rows 153, the rain drop can pull on the thread 150, causing the thread 150 to stretch and deform. The deformed threads 150 can increase the surface roughness of the thermal protection apparatus 140, which can increase the heating on the outer fabric layer 145. The rain drops can even cause the thread 150 to be pulled out of the thermal protection apparatus 140. In contrast, the threads 150 that form the columns 154 may not be significantly affected by the rain. Accordingly, in some embodiments, the thermal protection apparatus 140 may not include any rows 153 and may only include columns 154, which are generally parallel to the direction of travel of the vehicle and are therefore less prone to being pulled out by the rain drops. In other embodiments the apparatus 140 includes some rows 153, but fewer rows 153 than columns 154.
In some embodiments, the outer fabric layer 145 can be formed from more than one type of fiber. For example, in some embodiments, the outer fabric layer 145 can include an outer layer of metal alloy fabric stacked on and stitched to one or more layers of quartz fabric and/or ceramic fabric. While the metal alloy fibers have useful thermal and mechanical properties, the metal alloy fibers are dense, so forming the outer fabric layer 145 exclusively from metal alloy fibers can increase the weight of the thermal protection apparatus 140. By forming the outer fabric layer 145 from both metal alloy and quartz/ceramic fibers, the weight of the outer fabric layer 145 can be reduced while still taking advantage of some of the beneficial thermal and mechanical properties associated with metal alloys. In still other embodiments, the outer fabric layer 145 includes individual metal alloy fibers woven into layers of quartz and/or ceramic fibers to improve the thermal and mechanical properties of the outer fabric layer 145 without significantly affecting the weight of the layer 145. Further, the metal alloy fibers can be more electrically conductive than the quartz and ceramic fibers and can therefore better withstand lightning strikes, discharge electricity, and/or avoid charge build-up due to lightning, static charges, and/or other sources.
When the outer fabric layer 145 is exposed to heat, the layer of insulation 147 adjacent to the outer fabric layer 145 is also exposed to heat. To prevent or at least restrict the heat from passing through the layer of insulation 147 to the nozzle 121, the insulation 147 can be formed from a material or materials having high temperature capabilities and low thermal conductivity. In some embodiments, the layer of insulation 147 comprises insulation formed from small diameter (˜1-3 μm) ceramic fibers (e.g., Saffil® alumina fibers or HSA fibers available from Unifrax) that maintain their thermal and structural properties up to very high temperatures (2900° F. for Saffil® fibers and 2000° F. for HSA fibers), are efficient at rejecting radiant heat, and have low thermal conductivity. In some embodiments, the layer of insulation 147 can be formed from multiple sheets of insulation stacked together. For example, in some embodiments, multiple sheets of 0.125-inch-thick insulation can be stacked together to form the layer of insulation 147. In some embodiments, the layer of insulation can include between 1 and 10 sheets of insulation stacked together.
To further increase the insulating properties of the thermal protection apparatus 140, the layer of insulation 147 can be at least partially saturated with water. Water has both a high heat capacity and a high heat of vaporization. Accordingly, a large amount of heat is required to both increase the temperature of the water and to vaporize the heated water. However, water is dense and incorporating water can increase the weight of the launch vehicle 110 (
The inner fabric layer 146 can be formed from woven fibers and can be used to contain the layer of insulation 147. Further, the inner fabric layer 146 can act as a backing material for the threads 150. In some embodiments, the inner fabric layer 146 is formed from woven fiberglass fabric (e.g., S2-glass fabric). In other embodiments, the inner fabric layer 146 can be formed from other suitable fabrics, such as Kevlar. The inner fabric layer 146 is generally not exposed to temperatures as high as those experienced by the outer fabric layer 145, and so a wider range of materials are suitable.
In some embodiments, the thermal protection apparatus 140 is saturated with water before the launch vehicle launches. The water can be stored in an external vessel and sprayed onto the thermal protection apparatus 140 prior to launch using a hose or other spraying apparatus, with the water soaking into the apparatus 140 through gaps in the fibers that form the outer fabric layer 145 and wicking throughout layer 147. Alternatively, the thermal protection apparatus 140 can include a water distribution system 134 that includes conduits (e.g., drippers, pipes, tubes, hoses, etc.) positioned throughout the thermal protection apparatus 140. In some embodiments, the conduits can be arranged between the inner fabric layer 146 and the exterior surface 123 of the nozzle 121 (e.g., within the adhesive 144) and can extend through the inner fabric layer 146 into the layer of insulation 147. In still other embodiments, the conduits can be arranged along an edge of the thermal protection apparatus 140 so that gravity and/or other forces can distribute the water to the rest of the thermal protection apparatus 140. The water distribution system 134 can be couplable to an on-board and/or off-board water source 133 to distribute water throughout the thermal protection apparatus 140 and wet and saturate the layer or part of the layer of insulation 147 before launch. Because the layer of insulation 147 can rapidly distribute the water via wicking, the water distribution system may be relatively sparse and/or non-uniform without significantly affecting the overall water distribution.
As the launch vehicle lifts off and ascends, the hot exhaust products heat the nozzles 121. The regenerative cooling systems within the nozzles 121 provide sufficient levels of cooling to the nozzles 121 while the propulsion system 120 is activated so that the temperature of the thermal protection apparatuses 140 does not increase significantly above the atmospheric temperature. As such, most of the water within the thermal protection apparatus 140 remains below its boiling point, and little water is initially lost to evaporation. As the launch vehicle ascends, both the temperature and the atmospheric pressure of the air surrounding the launch vehicle 110 decrease. As is well known in the art, the boiling temperature of water decreases with air pressure. As a result, some of the water within the thermal protection apparatus 140 can boil and evaporate out of the thermal protection apparatus 140 (e.g., through gaps in the fibers that form the fabric of the apparatus 140) as the launch vehicle continues to ascend, despite the cooler air temperatures. The water continues to cool and evaporate as the air temperature and pressure fall until the water begins to freeze. Once all of the water remaining within the thermal protection apparatus 140 freezes, between 20% and 50% of the water originally present in the thermal protection apparatus 140 may have evaporated during the ascent phase of the launch vehicle 110. The evaporated water pre-cools the structure but is not available to provide later cooling to the nozzles during the descent phase.
To supplement the cooling ability of the thermal protection apparatus 140, in some embodiments, the launch vehicle can include an onboard water source 133 (e.g., a vessel or tank) coupled to the water distribution system 134 to replenish the water lost to evaporation during ascent. In these embodiments, the onboard water source 133 is filled with water prior to launch and is activated to at least partially maintain the amount of water available for cooling and insulation during descent. Further, as the onboard water source 133 is only required to replenish a portion of the water that the thermal protection apparatus 140 can hold, the onboard water source 133 can be relatively small and need not contribute significantly to the weight of the vehicle. To ensure that the water within the onboard water source 133 does not freeze, the onboard water source 133 can be located in a portion of the launch vehicle (e.g., an insulated portion) that remains above freezing.
In other embodiments, the thermal protection apparatus 140 is not saturated with water before the launch vehicle takes off. Instead, the launch vehicle includes a larger onboard water source 133 that holds all of the water that the thermal protection apparatus 140 is to be saturated with, and the water distribution system 134 provides the water to the thermal protection apparatus 140 only after the launch vehicle takes off. In this way, the amount of water lost to evaporation during ascent can be reduced and the total amount of water carried by the launch vehicle can also be reduced.
While the outer fabric layer 145 can have some insulating properties and can be capable of repelling some heat, most of the heat passes through the outer fabric layer 145 towards the layer of insulation 147. This heat causes the ice in the layer of insulation 147 to sublimate or melt and causes the liquid water to heat up and evaporate. However, because water has a high heat of vaporization, a significant amount of heat is required to vaporize all of the water. Accordingly, the layer of insulation 147 remains at the boiling temperature for a long period of time even as additional heat is applied during the descent. Because the outer surface 142 heats up before the inner surface 143, water near the outer surface 142 evaporates out of the thermal protection apparatus 140 before water near the inner surface 143 does. This can result in the formation of a dry spot near the outer surface 142, which can heat up. However, the water near the inner surface 143 will also evaporate and move through the thermal protection apparatus 140 towards the outer surface 142. As it passes through the dry spot, the steam can absorb the extra heat from the dry spot, thereby cooling the dry spot.
The heated steam eventually evaporates out of the thermal protection apparatus 140, thereby removing heat from the thermal protection apparatus 140 in the process. Furthermore, the vaporized water reduces the amount of heat impinging on the thermal protection apparatus 140 by transpiring through the outer surface 142 and forming a relatively cool boundary layer between the thermal protection apparatus 140 and the outside air.
During the descent, some portions of the thermal protection apparatus 140 can be exposed to more heat than other portions. For example, the portions of the thermal protection apparatus 140 far from the heat shield 131 (
Toward the end of the descent, the propulsion system 120 (
While saturating the layer of insulation 147 with water increases the insulating and cooling properties of the thermal protection apparatus 140, if the thermal protection apparatus is not expected to be exposed to temperatures above 2000° F., the thermal protection apparatus 140 can also be used without saturating the layer of insulation 147 with water. For example, some portions of the first stage of the launch vehicle do not experience temperatures greater than 2000° F. Accordingly, in some embodiments, the thermal protection apparatus 140 can be positioned around and adhered to the exterior surface 123 of each of the nozzles 121 (and/or other vehicle surfaces) without saturating the layer of insulation 147. In contrast, the heat shield of a reentry vehicle that reenters the atmosphere from orbit often experiences temperatures well above 2000° F. Accordingly, the thermal protection apparatuses 140 for such a vehicle may be saturated with water even if the thermal protection apparatuses 140 for the first stage are not.
By using the thermal protection apparatuses 140 without water, the weight of the launch vehicle 110 can often be decreased and the operating cost of launching the launch vehicle 110 can also decrease. To offset the absence of water, the thermal protection apparatus 140 can include a thicker layer of insulation 147. To prevent water from being absorbed by the thermal protection apparatus 140 (e.g., due to weather such as rain or snow, etc.), in some embodiments, the thermal protection apparatus 140 can include waterproofing that is applied to the thermal protection apparatus 140. In some embodiments, the entire thermal protection apparatus 140 is waterproofed. In other embodiments, only a portion of the thermal protection apparatus may be waterproofed. For example, in embodiments for which the layer of insulation is formed from multiple sheets of insulation stacked together, some of the insulation sheets can be waterproofed while other sheets may not be. More specifically, the innermost sheet of insulation (i.e., the sheet positioned closest to the nozzle 121) may not be waterproofed (and can still be saturated with cooling water) while the outer sheets of insulation (i.e., the sheets positioned further from the nozzle 121) may be waterproofed. With this arrangement, the amount of water for cooling can be reduced while also allowing the outer fabric layer 145 to remain hot so that it radiates heat and reduces the need for convective heat transfer. The waterproofing may help to limit the amount of water that the thermal protection apparatus 140 absorbs so that the weight of the launch vehicle 110 is not affected by inclement weather. However, the high temperatures associated with the launch and descent of the launch vehicle 110 can burn off some of the waterproofing. As such, the waterproofing may need to be reapplied between launches.
In embodiments of the thermal protection apparatus 140 that incorporate liquid water, the high wicking and wetting ability of the insulation fibers enable the liquid water to easily flow throughout the entire layer of insulation 147. As such, when the thermal protection apparatus 140 accelerates, the liquid water tends to flow through the layer of insulation 147 in a direction opposite the direction of acceleration. For example, during ascent, the launch vehicle accelerates in the first direction 101 and the liquid water moves in the second direction 102 towards an end portion 148 of the thermal protection apparatus 140. The end portion 148 can be adjacent to the opening of the nozzle 121 shown in
In some embodiments, the thermal protection apparatus 140 can include edge binding 149 positioned around the perimeter of the thermal protection apparatus 140 and stitched to the thermal protection apparatus 140 with a perimeter stitch 158. The edge binding 149 can include a strip of flexible fabric that wraps around the edge portions 148 and extends from the outer surface 142 to the inner surface 143. In some embodiments, the edge binding 149 is formed from the same fabric that forms the outer fabric layer. For example, in embodiments where the outer fabric layer 145 comprises metal alloy fibers, edge binding 149 can also comprise the metal alloy fibers. In other embodiments, however, the edge binding 149 can be formed from a different material than the fabric that forms the outer fabric layer 145. The perimeter stitch 158 can be formed from the same type of fibers that form the inner and outer threads 152 and 151. The edge portion 148 can also include waterproofing 157 applied to the edge binding 149. The waterproofing 157 acts as a barrier that limits the flow of water to prevent, or at least partially prevent, water from flowing through the edge binding 149. The waterproofing 157 can be or can include silicone and/or other suitable materials.
In the embodiments shown in
In addition to providing cooling and insulation to portions of the launch vehicle, the thermal protection apparatus 140 can be used to provide cooling and insulation to other portions of the system. For example,
Heat given off by the propulsion system when the launch vehicle 110 lifts off can damage the platform 161 and/or the tower 162, including the supply conduits, electronic components, and other components. To protect these and other portions of the launch site 160, the thermal protection apparatus can be applied to at least some portions of the launch site 160. For example, the thermal protection apparatus can be applied to the ground service equipment that houses various electronic components and cables so as to protect the electronic components from damage. The thermal protection apparatus can also be applied to portions of the tower 162 adjacent to a second stage of the launch vehicle 110 (e.g., a shelter room) so that technicians, astronauts, or other personnel are protected from high temperatures. Further, the launch site 160 can include a water vessel (e.g., a water tank) and the thermal protection apparatuses can be at least partially saturated with water from the water vessel to provide further cooling and insulation. In some embodiments, a conduit (e.g., a hose) coupled to the water vessel can be used by a technician to spray the thermal protection apparatuses with the water while in other embodiments, a water distribution system that includes conduits distributed throughout the thermal protection apparatuses and coupled to the water vessel can be used to distribute water from the water vessel to the thermal protection apparatuses, as discussed above. In this way, the thermal protection apparatuses can provide cooling and insulation to the various components at the launch site 160 so that the components can be protected from heat when the launch vehicle 110 takes off. Other portions of the system 100, such as the landing site, can also include the thermal protection apparatus.
In addition to increasing the insulation and cooling properties of the thermal protection apparatus 140, saturating the thermal protection apparatus 140 with water can also provide other benefits. For example, saturating the thermal protection apparatus 140 with water can reduce, or even eliminate, the infrared signature of the launch vehicle by reducing the apparent temperature difference between launch vehicle and the background (e.g., the sky). As a result, infrared detectors are less able to distinguish between the launch vehicle and the background, which can make it harder for the launch vehicle to be tracked and/or targeted during flight.
Test Results
Several tests have been conducted to demonstrate the insulating performance of the thermal protection apparatus. The test results shown in
For the dry sample, the measured temperatures, which are represented by line 6a, rose quickly from an initial temperature of 70° F. to a temperature near the boiling point of water (i.e., 212° F.) after approximately 4 seconds. The temperature continued to rise quickly and reached a temperature of 400° F. after 16 seconds and a temperature of 600° F. after 48 seconds. For the wet sample, the measured temperatures, which are represented by line 6b, initially rose at a similar rate, reaching the boiling point of water after about 4 seconds. However, the measured temperature remained at this temperature for another 28 seconds (i.e., 32 seconds after heating began). The temperature then began to increase again and reached a temperature of 400° F. after another 22 seconds (i.e., 54 seconds after heating began) and a temperature of 600° F. after an additional 28 seconds had elapsed (i.e., 82 seconds after heating began). For the frozen sample, the measured temperatures, which are represented by line 6c, initially rose at a rate similar to that of the dry and wet samples, reaching a temperature near the boiling point of water (from an initial temperature of about 20° F.) in only 8 seconds. The frozen sample then remained at this temperature for a prolonged period of time, staying at the boiling temperature of water for approximately 42 seconds (i.e., after 50 total seconds of heating). The temperature then began to increase again and reached a temperature of 400° F. 11 seconds later (i.e., after 61 total seconds of heating) and a temperature of 600° F. after an additional 25 seconds of heating (i.e., 86 seconds after heating began).
These results demonstrate, in situ, the insulating effects of a representative thermal protection system that includes water. Once the temperature of the thermal protection apparatus reached the boiling point of water, the liquid water began to vaporize. However, the temperature remained at or near the boiling point of water for a prolonged amount of time because subsequent heat applied to the apparatus vaporized more of the liquid water instead of heating up the steam or the apparatus. Once all of the water vaporized, the measured temperature again began to rise at a rate similar to that of the dry sample.
For the frozen sample, the measured temperature initially rose at a comparable rate to the dry and wet samples, indicating that ice near the front plate melted soon after heating began and the temperature of the liquid water began to rise before the rest of the ice in the sample (e.g., ice near the back plate and ice near the edges of the plates) melted. Once the temperature reached the boiling point of water, the temperature remained at the boiling point of water for a longer period of time than the temperature of the wet sample did. However, this may be an artifact of the test set-up as the thermocouple is placed near the front plate and is only measuring the temperature near the front plate. Because the ice near the front plate melts and warms sooner than the ice near the back plate, the temperature measured by the thermocouple is only representative of the temperature of the water near the front plate and not the average temperature of the water. As such, the measured temperature of the frozen sample reached the boiling temperature quickly and stayed at the boiling temperature for a longer period of time than the temperature of the wet sample did despite the average temperature of the water taking longer to reach the boiling temperature. As more heat was applied, more of the ice melted and the liquid water continued to warm up until all the water reached the boiling temperature. Once all the ice melted and vaporized, the measured temperature began to rise again at a rate higher than that of the wet or dry sample. This may be due to more steam evaporating from the frozen sample before the temperature began to rise because the water at the front of the frozen sample stayed at the boiling temperature for a longer period of time than the water at the front of the wet sample did. Further, after 65 seconds of heating, the frozen and wet samples were at approximately the same temperature and continued to heat at the same rate.
For the frozen sample, the temperatures measured by the front thermocouple, which are represented by line 7a, are consistent with the results shown in
For the wet sample, which was thicker and included more water than the frozen sample, the temperatures measured by the thermocouple at the front of the sample, which are represented by line 7c, initially appear to be consistent with the results for the wet sample shown in
The foregoing tests further demonstrate the efficacy of representative thermal protection apparatus samples, and the effects of varying water content. For both the frozen and wet samples, the temperatures measured at the back of the samples remained at the boiling temperature of water for a substantially longer period of time than the temperatures measured at the front of the sample. For example, after 70 seconds of heating, the temperature measured at the back of the frozen sample remained at the boiling temperature while the temperature measured at the front had increased to approximately 480° F. Similarly, after 140 seconds of heating, the temperature measured at the back of the wet sample remained at the boiling temperature of water while the temperature measured at the front increased to approximately 600 degrees. Furthermore, because the wet sample is substantially thicker and includes more water than the frozen sample, more heat is absorbed and dissipated by the wet sample than the frozen sample. As a result, the temperatures measured by both thermocouples coupled to the wet sample remained at the boiling temperature of water for substantially longer than the temperatures measured by the thermocouples coupled to the frozen sample.
Tests were also performed to determine the durability of the thermal protection apparatus. In one such test, samples of the thermal protection apparatus, as well as samples of conventional insulating blankets, were put into a high-speed and high-temperature wind tunnel to simulate the possible conditions that the thermal protection apparatus may be exposed to during vehicle launch. In these tests, the wind tunnel generated velocities of approximately Mach 4 and gas temperatures of about 2600° F. The various samples were inserted into the wind tunnel for up to a minute before being removed. For these tests, the thermal protection apparatus included an outer fabric layer formed from metal alloy fibers and was tightly stitched together with columns of threads (i.e., threads that are generally parallel to the direction of the airflow in the testing chamber) spaced apart from each other by approximately 0.25 inches and rows of threads (i.e., threads that are generally perpendicular to the direction of the airflow in the testing chamber) spaced apart from each other by approximately 1.7 inches. Because of this construction, the samples of the thermal protection apparatus, which had an outer surface temperature of approximately 2000° F. during testing, were undamaged after being exposed to the high-temperature and high-speed wind during testing. In contrast, when the insulating blankets made from conventional materials were inserted into the test chamber, the insulating blankets, which include an outer fabric layer formed from a conventional and less durable material (e.g., a ceramic material) and were stitched together with a 0.25-inch by 1.7-inch stitching pattern, disintegrated almost immediately. Accordingly, the improved materials and construction of the disclosed thermal protection apparatus offered significant improvement on the durability and performance over conventional insulation blankets.
Additional tests were also run on other samples of the disclosed thermal protection apparatus. For example, a sample of the thermal protection apparatus having a purposely introduced defect was also tested.
Tests for determining the ability of the thermal protection apparatus 140 to withstand lightning strikes were also conducted. In these tests, electrical currents of different strength were applied to samples of the apparatus 140 to simulate lightning strikes and the effect of the different currents on the samples were observed. In one test, a current of 100,000 amps was applied to a sample. The applied current caused minor damage to an area having approximately a 1-inch diameter. In a second test, a current of 200,000 amps was applied to a second sample. In this test, the applied current caused minor damage to an area having a diameter of approximately 2 inches. In both tests, however, the damage was limited to these localized areas of the samples. The other areas of the tested samples remained intact and were generally unaffected by the applied currents.
Conventional insulation blankets are typically too fragile to withstand the high acoustic environments experienced by the windward side of spacecraft during launch and reentry. Accordingly, conventional insulation blankets are relegated to the leeward side of the spacecraft. In contrast, the thermal protection apparatus 140 is durable enough to survive the extreme acoustic environments that the windward portions of the spacecraft (e.g., the heat shield of a launch vehicle or reentry module) experience during flight. To test the acoustic durability of the thermal protection apparatus 140, samples of the thermal protection apparatus were exposed to combined acoustic and thermal loads. In one test, samples were heated to a temperature of approximately 2000° F. and were exposed to an overall sound pressure level (OASPL) of 165 dB. After testing, the sample showed no signs of damage. A similar test was performed on a sample of conventional insulation blankets. After testing, most of the threads in the conventional insulation blanket sample were 80% broken. A second sample of the thermal protection apparatus 140 was tested using an even higher OASPL of 168 dB. As in the previous test, the sample showed no signs of damage after testing. These results demonstrate, in situ, the durability and reusability of representative thermal protection apparatuses, especially in comparison to conventional insulating blankets.
From the foregoing, it will be appreciated that several embodiments of the disclosed technology have been described herein for purposes of illustration, but that various modifications can be made without deviating from the technology. For example, in some applications, the thermal protection apparatus can be saturated with a liquid other than water and/or the thermal protection apparatus can include multiple layers of insulation. The thermal protection apparatus can be coupled to any portion of a launch vehicle and/or vehicles that do not ascend into space, such as airplanes and/or helicopters. The thermal protection apparatus can be applied to stationary structures such as furnaces and power plants. More generally, the thermal protection apparatus can be coupled to any structure to provide insulation and/or cooling to that structure.
Certain aspects of the technology described in the context of particular embodiments can be combined or eliminated in other embodiments. For example, the thermal protection apparatus can only include threading on the outer surface of the thermal protection apparatus but does not include separate threading on the inner surface. Further, while advantages associated with some embodiments of the disclosed technology have been described herein, configurations with different characteristics can also exhibit such advantages, and not all configurations need necessarily exhibit such advantages to fall within the scope of the technology. Accordingly, the disclosure and associated technology can encompass other arrangements not expressly shown or described herein. The following examples provide further representative descriptions of the present technology.
To the extent any materials incorporated herein by reference conflict with the present disclosure, the present disclosure controls. As used herein, the phrase “and/or” as in “A and/or B” refers to A alone, B alone, and both A and B.
This non-provisional patent application claims the benefit of and priority to U.S. Provisional Patent Application No. 62/669,830, titled “HIGH TEMPERATURE TRANSPIRATION COOLED THERMAL PROTECTION SYSTEM FOR ROCKETS, AND ASSOCIATED METHODS” and filed May 10, 2018, which is incorporated herein in its entirety by reference.
Number | Name | Date | Kind |
---|---|---|---|
4499134 | Whitely | Feb 1985 | A |
4619553 | Fischer | Oct 1986 | A |
5038693 | Kourtides | Aug 1991 | A |
5322725 | Ackerman | Jun 1994 | A |
5451448 | Sawko et al. | Sep 1995 | A |
5626951 | Hogenson | May 1997 | A |
5740985 | Scott et al. | Apr 1998 | A |
5811168 | Rasky | Sep 1998 | A |
6418973 | Cox | Jul 2002 | B1 |
6497390 | Fischer | Dec 2002 | B1 |
7510754 | DiChiara, Jr. | Mar 2009 | B2 |
20160031180 | Baroux et al. | Feb 2016 | A1 |
20170218542 | Stewart et al. | Aug 2017 | A1 |
Number | Date | Country |
---|---|---|
02078762 | Mar 1990 | JP |
2016348 | Jul 1994 | RU |
2142596 | Dec 1999 | RU |
2344972 | Jan 2009 | RU |
2622181 | Jun 2017 | RU |
179194 | May 2018 | RU |
Entry |
---|
ASM Aerospace Specification Metals Inc., Special MEtals INCONEL Alloy 718, 2005, ASM Aerospace Specification Metals Inc. (Year: 2005). |
Bergin, Chris, SLS Program pressing forward with engine heatshield design change, Sep. 3, 2012, NASASpaceFlight.com (Year: 2012). |
International Search Report and Written Opinion for International Patent Application No. PCT/US2019/031753, Applicant: Blue Origin, LLC., dated Sep. 12, 2019, 9 pages. |
Number | Date | Country | |
---|---|---|---|
20190345896 A1 | Nov 2019 | US |
Number | Date | Country | |
---|---|---|---|
62669830 | May 2018 | US |