Supposedly, according to Bezos like a year+ ago, they'll be moving to "monocoque" tanks for the GS2. By which he seemed to mean neither orthogrid nor skin and stringer. Just skin, that's thick enough to handle the structural loads, and they just take the mass hit.
He is erroneously referring to this structure I've outlined in red is actually added structure to the 9 x 4's GS2. Note the corrugation on the outside, which indicates a true boat tail compartment rather than just MLI blankets surrounding the BE-3U turbomachinery.
This would potentially make the 9 x 4 configuration 10.1 meters in diameter.
This role supports the development of the 2nd Generation of New Glenn, a heavy-lift orbital launch vehicle capable of routinely carrying people and payloads to low-Earth orbit, geostationary transfer orbit, cislunar, and beyond. This position will be directly involved in the design of the next progression of New Glenn Payload Accommodations hardware, including the larger diameter 8.7M payload fairing and adapters.
As part of a small, passionate and accomplished team of experts, you will support the design, development, and test of launch vehicle mechanical and decelerator systems. Your primary focus will be supporting re-entry and mechanical system design development that are critical to enabling safe, reliable, and cost-effective spaceflight.[...]Participate in the entire design cycle of aero-decelerator and mechanical subsystems, including conceptual and detailed design, trade studies, structural analysis, development testing and qualification.[...]Experience in aerospace designs such as separation systems and/or deployable devices. Experience with re-entry decelerator systems and devices such as trailing parachutes, inflatables, etc.
Quote from: JEF_300 on 12/06/2025 12:04 amSupposedly, according to Bezos like a year+ ago, they'll be moving to "monocoque" tanks for the GS2. By which he seemed to mean neither orthogrid nor skin and stringer. Just skin, that's thick enough to handle the structural loads, and they just take the mass hit. not really, see Centaur
Quote from: Jim on 12/07/2025 06:13 pmQuote from: JEF_300 on 12/06/2025 12:04 amSupposedly, according to Bezos like a year+ ago, they'll be moving to "monocoque" tanks for the GS2. By which he seemed to mean neither orthogrid nor skin and stringer. Just skin, that's thick enough to handle the structural loads, and they just take the mass hit. not really, see CentaurNo. Bezos, in this case, was talking about aluminum-lithium tanks, and using them on a slot-in upgrade to the current GS2. It cannot possibly be a centaur-like pressure stabilized situation.
Quote from: JEF_300 on 12/13/2025 07:19 pmQuote from: Jim on 12/07/2025 06:13 pmQuote from: JEF_300 on 12/06/2025 12:04 amSupposedly, according to Bezos like a year+ ago, they'll be moving to "monocoque" tanks for the GS2. By which he seemed to mean neither orthogrid nor skin and stringer. Just skin, that's thick enough to handle the structural loads, and they just take the mass hit. not really, see CentaurNo. Bezos, in this case, was talking about aluminum-lithium tanks, and using them on a slot-in upgrade to the current GS2. It cannot possibly be a centaur-like pressure stabilized situation.Why not? Monocoque construction works really well in stainless steel, but it can be applied to aluminum tanks as well. I believe Falcon 9 Lox tanks are monocoque.
Quote from: briantipton on 12/13/2025 10:52 pmQuote from: JEF_300 on 12/13/2025 07:19 pmQuote from: Jim on 12/07/2025 06:13 pmQuote from: JEF_300 on 12/06/2025 12:04 amSupposedly, according to Bezos like a year+ ago, they'll be moving to "monocoque" tanks for the GS2. By which he seemed to mean neither orthogrid nor skin and stringer. Just skin, that's thick enough to handle the structural loads, and they just take the mass hit. not really, see CentaurNo. Bezos, in this case, was talking about aluminum-lithium tanks, and using them on a slot-in upgrade to the current GS2. It cannot possibly be a centaur-like pressure stabilized situation.Why not? Monocoque construction works really well in stainless steel, but it can be applied to aluminum tanks as well. I believe Falcon 9 Lox tanks are monocoque.Re-read my posts. What I am saying GS2 WILL be made monocoque, and WON'T be pressure stabilized like Centaur. Making it like Centaur would require totally different support infrastructure to keep it structurally stable during ground operations, making it functionally a totally new upper stage, not an upgrade.
https://www.blueorigin.com/es-MX/new-glenn/9x4QuotePowered by four BE-3U engines, 9x4’s second stage carries 70 metric tons to low Earth orbit, 14 metric tons to Geostationary Orbit Direct, and 20 metric tons to Trans Lunar Injection.
Powered by four BE-3U engines, 9x4’s second stage carries 70 metric tons to low Earth orbit, 14 metric tons to Geostationary Orbit Direct, and 20 metric tons to Trans Lunar Injection.
Quote from: StraumliBlight on 11/21/2025 09:11 amhttps://www.blueorigin.com/es-MX/new-glenn/9x4QuotePowered by four BE-3U engines, 9x4’s second stage carries 70 metric tons to low Earth orbit, 14 metric tons to Geostationary Orbit Direct, and 20 metric tons to Trans Lunar Injection.Do we know if those figures are with the first stage reused or expended? (Companies sometimes quote expendable performance even for vehicles that are planned to be reused to make their vehicle look better.)I bet those figures are expendable for the following reason: 9x4's LEO/GEO payload ratio is 70/14=5.0, which is comparable to almost-three-stage expendable vehicles' ratios such as Vulcan VC6's 3.9, Vulcan VC2's 5.4 and Falcon Heavy expendable's 6.8. Two stage vehicles usually have a much larger ratio especially with first stage reuse, e.g. Falcon ASDS and Starship have infinite ratios since they can't do direct GEO and 7x2's ratio (dunno if it's with reuse) is 38870/1440=27.0. (The payloads I used to calculate the ratios for the other vehicles are from https://elvperf.ksc.nasa.gov/Pages/Query.aspx viewed many months ago using 200 km LEO, I forget the inclination, and using C3=24 km^2/s^2 as an approximation of direct GEO since that takes roughly the same 4.27 km/s beyond LEO delta-vee.)If those figures are expendable then 9x4 has roughly half the capability of SLS when expended (SLS block 1B can do 42 tonnes to TLI) so 9x4 is Falcon Heavy class, not SLS/Saturn V/Starship class. Still, 70 tonnes to LEO expendable and some fraction of that reusable is plenty of performance for every plausible need in the next few decades including crewed exploration of the moon and Mars. IMO unless the US government makes a silly requirement for a larger launcher Blue should probably not design any more vehicles (e.g. New Armstrong) until Blue gets second stage reuse working.
Current New Glenn is ~7 t to TLI per NASA LSP. Extrapolating based on the 49% booster thrust increase bumps that to 10.5 t. There's a slight increase in performance from improved mass ratios from subcooling, and from increased upper stage thrust, but neither of those seem like they would get it to 20 t.
Since Blue pitched it for constellation deploying and all future plans require much higher cadence, it is unreasonable to assume 94 will be expanded(would be too expensive). Honestly the claim smells cope.
Do we know if those figures are with the first stage reused or expended? (Companies sometimes quote expendable performance even for vehicles that are planned to be reused to make their vehicle look better.)
I checked with our contacts at Blue Origin when the news was released last month, and they confirmed that those 9x4 numbers assume first stage recovery.
Also, keep in mind that the upper stage is growing more than the first stage is; a more than 100% increase in thrust from the current GS2, in fact. This means the ∆V split between the stages is probably different on 9x4 than 7x2, and the staging point is probably different, and that makes using 7x2 as a starting point for 9x4 calculations... dicey.
It would really make sense to use this for a new 3rd stage on top of New Glenn 9x4, for high energy launches:4 BE-3Us in the second stage give almost 400 tonnes of thrust, which gives very small gravity losses with huge second stage and allows lifting 70 tonnes to LEO, but the tanks of this huge second stage are quite heavy and the tank weight eats payload to higher orbits.But, lets add a smallish third stage with single BE-7.This stage would only stage at orbital speed, eliminating gravity loss, so the very weak engine would not matter much (only losing small amount of performance due to less oeberth effect)70 tonnes of initial mass , 30 tonnes of propellant, 40 tonnes of final mass (something like 3.5 tonnes of mass for the stage and 36.5 tonnes of payload) would get from earth to GTO.Or for TLI, 28-tonne payload would give delta-v of 3 km/s for this stage. As the staging would happen slightly higher at slightly elliptic orbit due to only 61.5 tonnes of payload weight lifted by the second stage, this should be enough for TLI.This is about the same than what SLS Block 1 can lift to TLI.Or, towards Mars: 22-tonne payload would mean delta-v of 3.5 km/s for this stage.the remaining 300 m/s is easily done be earlier stages, due to only 55.5 tonnes (instead of 70 tonnes) of weight lifted by the second stage.This is much more than Falcon Heavys 17 tonnes towards Mars.Could even launch decent-size probes towards outer solar system without slow complicated gravity slings, for example 5-tonne payload would get delta-v of 6.8 km/s.and as the second stage would only need lift 38.5 tonnes, the staging would happen at considerably higher that LEO, total delta-v might be over LEO+8 km/sAnd this is for mass about 6 times bigger than the Voyager probes.The stage would have quite a long burn time (about 45 minutes)This stage should also be quite cheap.
