Am I reading this right? They now want to do Mars Sample Return for $2B in 2028?https://twitter.com/mottbox_/status/1840279910578897055?s=46&t=eQrUtTJk6IAt4GyTzH7J2w
Richard French/Rocket Lab USA, Inc.Rocket Lab Proposal for Rapid Mission Design Studies for Mars Sample ReturnFor the last five years, Rocket Lab has methodically implemented a strategy for affordable planetary science that is uniquely suited to deliver a low cost, rapid Mars Sample Return (MSR) mission. As a vertically integrated launch service provider, Rocket Lab has proven capabilities across all required launch vehicle disciplines including vehicle design, production, logistics, regulatory, and operations. Rocket Lab plans to return 30 samples (29 samples tubes and at least 1 witness tube) back to Earth to meet Decadal-class science objectives, assuming 30 samples are available on the Perseverance rover for retrieval. The MAV is sized for at least 20 kg payload to provide margin against this sample goal. To maintain high science integrity and to emphasize the importance of science to the mission, Rocket Lab has organized a Science Advisory Council (SAC) to support the rapid mission study and ultimately support execution. The SAC will advise on all science issues to the Rocket Lab MSR study team. Rocket Lab will reduce cost and schedule for MSR through a simplified mission, targeting a total to NASA of less than $2B. Cost and schedule are reduced by leveraging Rocket Lab's vertically integrated commercial investments in affordable planetary science. Rocket Lab will reduce cost and schedule risk by working to the shortest schedule possible. Rocket Lab will challenge the program to hit a 2028 launch window to reduce costs while reducing risk associated with Perseverance lifetime, resulting in return of samples no later than Sept 2033, with the potential for earlier return in Sept 2031. Rocket Lab will reduce cost for MSR by performing as a single management organization as a prime contractor and using commercial approaches operating under firm fixed price. The mission design is a twolaunch solution, sized to Rocket Lab's Neutron launch vehicle. Launched roughly 2 weeks apart, launch 1 sends the ERO to orbit Mars while launch 2 sends the MLV, inclusive of the MAV and a cruise stage, on a direct entry to Mars. Samples will be delivered to the MLV by Perseverance which will then be loaded into the MAV with a 7-dof sampling arm. After MAV ascent, the ERO rendezvous with the MAV for sterilization of the samples and transfer to the EES, followed by return to Earth. Rocket Lab has demonstrated the experience and technical capabilities aligned with MSR and has assembled a team with the experience and skills to not only conduct a study of low cost, rapid MSR but also to execute on the mission once awarded. Rocket Lab demonstrated a rapid engine development program and a high delta-V (3.2 km/sec) spacecraft on the NASA CAPSTONE mission in June 2022 that successfully executed multiple critical burns targeting Earth escape. Rocket Lab is performing as a prime contractor for the US DoD, demonstrating our ability to manage a large team of mission partners with Class C mission assurance. Rocket Lab demonstrated precision entry system targeting using in-house propulsion and GNC capabilities in February 2024 with a successful re-entry of a capsule at UTTR. Rocket Lab is completing integration of two Mars science orbiters with high delta-V (2.6 km/sec) and deep space capable communications and navigation capabilities for launch in 2024. Rocket Lab is actively disrupting planetary science with affordable approaches [3] to delivering Decadal-class planetary science with the first private mission to Venus in search for organics in the cloud layer -- while integrating key NASA technology. Rocket Lab is gaining experience with long life, high reliability spacecraft based on Class C mission assurance to meet challenging environmental requirements like MSR with the Globalstar Program. Rocket Lab's FSW will control a lunar lander to the surface of the moon, a critical enabling capability for the Mars Lander Vehicle. Rocket Lab will demonstrate RPO, an enabling technology for the MAV rendezvous and docking operation with the ERO.
Phoenix mission had launch mass of 670kg and landed mass of 350kg. MLV mass is big question. I'm going to assume 250kg, DV is 4.2km/s, ISP 310 (HyperCurie ) which gives 62kgs dry mass to orbit, of which 20kg is samples.
Quote from: TrevorMonty on 09/29/2024 07:16 pmPhoenix mission had launch mass of 670kg and landed mass of 350kg. MLV mass is big question. I'm going to assume 250kg, DV is 4.2km/s, ISP 310 (HyperCurie ) which gives 62kgs dry mass to orbit, of which 20kg is samples. The problem with the existing MSR architecture isn't really the MLV per se; it's the MAV, which has to fit on the MLV. Without making a very large entry vehicle, the MAV is dimensionally too big to fit. So that requires making a new entry vehicle, which necessarily attaches a lot of operational risk.You might want to consider cross-posting this on the MSR Cost-Reduction thread. Problems with landers are extensively covered there. While I'm excited to see Rocket Lab playing in this space, the technical challenges are daunting.The original sin with MSR is the mass of the Orbiting Sample, which affects the size of the MAV, which then affects the form factor of the MLV. If RL has some magical MAV improvement (several of which comprise studies from other vendors), then I'm excited. Otherwise, they've merely reduced things to a set of unsolved problems.
Don't know what RL has planned but new entry vehicle/capsule design could open up a big money pit.
Rocket Lab is planning to use Neutron for its lander.
Quote from: deltaV on 09/30/2024 05:01 pmRocket Lab is planning to use Neutron for its lander.I don’t think Neutron is the lander, but if it is, then they have the same problem as Starship: the lander fairing is the same as the launch fairing from Earth, and it can’t be made planetary protection Category IV compliant.
Mars 2020 had launch mass 3,649 kg and landed mass 1700 kg, so landed mass is around 47% of launch mass (due to cruise stage and entry descent and landing hardware). Rocket Lab is planning to use Neutron for its lander. Neutron can send 1500 kg to Mars, so using Mars 2020's ratio of launch to landed mass RL's landed mass is probably around 700 kg. According to the RASMSR industry day slides part 2 slide 9 the NASA baseline sample retrieval lander has a landed mass of 2800 kg. How is RL's lander ~25% the mass of NASA's? Both are retrieving 30 samples.I suspect RL's mass estimates looked overly optimistic to NASA, which led NASA to reject its proposal initially. Then I guess RL appealed or something and RL got an award 2.6 months later.
Quote from: deltaV on 09/30/2024 05:01 pmMars 2020 had launch mass 3,649 kg and landed mass 1700 kg, so landed mass is around 47% of launch mass (due to cruise stage and entry descent and landing hardware). Rocket Lab is planning to use Neutron for its lander. Neutron can send 1500 kg to Mars, so using Mars 2020's ratio of launch to landed mass RL's landed mass is probably around 700 kg. According to the RASMSR industry day slides part 2 slide 9 the NASA baseline sample retrieval lander has a landed mass of 2800 kg. How is RL's lander ~25% the mass of NASA's? Both are retrieving 30 samples.I suspect RL's mass estimates looked overly optimistic to NASA, which led NASA to reject its proposal initially. Then I guess RL appealed or something and RL got an award 2.6 months later.There’s the possibility that rocket lab is proposing a expendable neutron or a neutron “block 2” for this mission
Quote from: TheRadicalModerate on 09/30/2024 05:38 pmQuote from: deltaV on 09/30/2024 05:01 pmRocket Lab is planning to use Neutron for its lander.I don’t think Neutron is the lander, but if it is, then they have the same problem as Starship: the lander fairing is the same as the launch fairing from Earth, and it can’t be made planetary protection Category IV compliant.Sorry, I meant RL is planning to use Neutron to launch its lander. I don't know what RL plans to use for its lander.
The 1700kg lander was going to be carrying retrieval helicopters and 450kg 2 stage SRM ascent vehicle. Besides mass MAV was also long due to use of SRM.Some of the other proposals thing they can reduce MAV to 250kg while still using SRMs. RL would most likely use Hypercurie with ultra light composite tanks, so ISP would be up while dry mass down compared to SRMs. Think Capstone Photon bus minus solar panels, startrackers. Will need enough batteries to supply engine 4.2km/s of endurance but they may do battery hot swap to help shred mass on ascent. As I stated in first post they may get away with using Phoniex landers entry capsule if lander is light enough.
Hazard avoid during land may require partnering with one of lunar lander companies.
On the negative side, the benefit of keeping this all "in house" does not, IMO, match the risk of relying on Neutron, "yet another proposed launch vehicle". (reference ESCAPADE on New Glenn).Falcon 9 lists 4020 kg to Mars (FH lists 16,800 kg!) and is fully operational, reliable, available and affordable.
Rocket Lab Awarded NASA Study Contract to Explore Bringing Rock Samples from Mars to Earth for the First TimeThe study proposes using Rocket Lab’s vertically integrated technologies to retrieve samples from the Red Planet for the first time in history as part of NASA’s Mars Sample Return Program.October 07, 2024 06:30 AM Eastern Daylight TimeLONG BEACH, Calif.--(BUSINESS WIRE)--Rocket Lab USA, Inc. (Nasdaq: RKLB) (“Rocket Lab” or “the Company”), a global leader in launch services and space systems, today announced the Company has been selected by NASA to complete a study for retrieving rock samples from the Martian surface and bringing them to Earth for the first time. The mission would fulfill some of the highest priority solar system exploration goals for the science community – to revolutionize humanity’s understanding of Mars, potentially answer whether life ever existed on the Martian surface, and help prepare for the first human explorers to the Red Planet.QuoteRetrieving samples from Mars is one of the most ambitious and scientifically important endeavors humanity has ever embarked upon. We’ve developed an innovative mission concept to make it happen affordably and on an accelerated scheduleNASA’s Rapid Mission Design Studies for Mars Sample Return solicits industry proposals to carry out rapid studies of mission designs and mission elements capable of delivering samples collected by the Mars Perseverance rover from the surface of Mars to Earth. The results of this study will inform a potential update to NASA’s Mars Sample Return Program and may result in future procurements with industry. Rocket Lab’s study will explore a simplified, end-to-end mission concept that would be delivered for a fraction of the current projected program cost and completed several years earlier than the current expected sample return date in 2040.“Retrieving samples from Mars is one of the most ambitious and scientifically important endeavors humanity has ever embarked upon. We’ve developed an innovative mission concept to make it happen affordably and on an accelerated schedule,” said Rocket Lab founder and CEO, Sir Peter Beck. “Rocket Lab has been methodically implementing a strategy for cost-effective planetary science in recent years, making us uniquely suited to deliver a low cost, rapid Mars Sample Return. We’ve demonstrated this strategy by delivering a NASA mission to the Moon, enabling rendezvous and proximity operations in orbit, successfully re-entering a capsule from orbit to Earth, delivering two spacecraft to NASA for a Mars mission, and much more. We look forward to bringing our proven capabilities together to deliver a compelling, innovative mission solution that puts Mars rocks in the hands of scientists sooner.”Rocket Lab’s proposed mission architecture will be revealed once the study is complete in the coming months.
Retrieving samples from Mars is one of the most ambitious and scientifically important endeavors humanity has ever embarked upon. We’ve developed an innovative mission concept to make it happen affordably and on an accelerated schedule
“Rocket Lab was not included in the initial study concepts selected by NASA in June 2024, but Rocket Lab’s proposal was later re-evaluated by NASA and selected for a study contract as it closely aligned with the solicitation’s stated focus on innovation,” Rocket Lab said in an Oct. 7 statement to SpaceNews.“All of the companies chosen submitted their proposals through the original ROSES solicitation and the addition of one more company will not delay the evaluation of the studies,” NASA said in a statement to SpaceNews Oct. 7 in response to inquiries about the Rocket Lab award Oct. 3 and 4. “NASA’s selection process allows for later additions at the selecting official’s discretion.”
Mars entry and landing vehicle is big unknown for RL. Likely to be <1000kg as earth departure mass is limited to 1500kg if designed for Neutron launch.One possibility is using HIAD for Mars entry. Its what NASA designed it for.
Quote from: TrevorMonty on 10/11/2024 01:37 amMars entry and landing vehicle is big unknown for RL. Likely to be <1000kg as earth departure mass is limited to 1500kg if designed for Neutron launch.One possibility is using HIAD for Mars entry. Its what NASA designed it for.If you want to start from a blank sheet of paper, there are all kinds of possibilities for lander architectures. The problem with all of them is that the MSR people have to make a decision on an architecture some time in the next 6 months. None of these architectures is anywhere close to being mature enough that they can actually reduce risk more than the risk the current architecture exposes the project to.So "big unknowns" simply aren't going to cut it. I think that the RL team is top-notch, but unless they've got something really revolutionary that nobody's thought of, this idea that they're going to sweep in, take over all the roles in the project, and save the day, is nuts.Just for reference, the SRL team from 3 years ago estimated the landed mass of the SRL, even for a dual-launch architecture, at more than 3t, an entry mass of more than 5t. That makes a landed payload of less than 1t sound pretty skimpy.I'm pretty sure that if there's a winning study, it's gonna produce a more compact MAV with a better payload fraction, and it's gonna do it by switching from solid motors to liquids. I could see RL coming up with something pretty interesting in that area. But a full-up SRL? I'm more than skeptical.
Quote from: TheRadicalModerate on 10/11/2024 04:16 amQuote from: TrevorMonty on 10/11/2024 01:37 amMars entry and landing vehicle is big unknown for RL. Likely to be <1000kg as earth departure mass is limited to 1500kg if designed for Neutron launch.One possibility is using HIAD for Mars entry. Its what NASA designed it for.If you want to start from a blank sheet of paper, there are all kinds of possibilities for lander architectures. The problem with all of them is that the MSR people have to make a decision on an architecture some time in the next 6 months. None of these architectures is anywhere close to being mature enough that they can actually reduce risk more than the risk the current architecture exposes the project to.So "big unknowns" simply aren't going to cut it. I think that the RL team is top-notch, but unless they've got something really revolutionary that nobody's thought of, this idea that they're going to sweep in, take over all the roles in the project, and save the day, is nuts.Just for reference, the SRL team from 3 years ago estimated the landed mass of the SRL, even for a dual-launch architecture, at more than 3t, an entry mass of more than 5t. That makes a landed payload of less than 1t sound pretty skimpy.I'm pretty sure that if there's a winning study, it's gonna produce a more compact MAV with a better payload fraction, and it's gonna do it by switching from solid motors to liquids. I could see RL coming up with something pretty interesting in that area. But a full-up SRL? I'm more than skeptical.Is NASA ultimately going to pick exactly one of the proposals from among those funded through these study contracts, or do they have the capability to mix and match? While Rocket Lab proposes an end-to-end solution, perhaps there's a secondary hope that even if they don't get the full contract, they could still win specific parts of the project.
Quote from: TrevorMonty on 10/11/2024 01:37 amMars entry and landing vehicle is big unknown for RL. Likely to be <1000kg as earth departure mass is limited to 1500kg if designed for Neutron launch.One possibility is using HIAD for Mars entry. Its what NASA designed it for.If you want to start from a blank sheet of paper, there are all kinds of possibilities for lander architectures. The problem with all of them is that the MSR people have to make a decision on an architecture some time in the next 6 months. None of these architectures is anywhere close to being mature enough that they can actually reduce risk more than the risk the current architecture exposes the project to.So "big unknowns" simply aren't going to cut it. I think that the RL team is top-notch, but unless they've got something really revolutionary that nobody's thought of, this idea that they're going to sweep in, take over all the roles in the project, and save the day, is nuts.Just for reference, the SRL team from 3 years ago estimated the landed mass of the SRL, even for a dual-launch architecture, at more than 3t, an entry mass of more than 5t. That makes a landed payload of less than 1t sound pretty skimpy.I'm pretty sure that if there's a winning study, it's gonna produce a more compact MAV with a better payload fraction, and it's gonna do it by switching from solid motors to liquids. I could see RL coming up with something pretty interesting in that area. But a full-up SRL? I'm more than skeptical.
Mars entry and landing vehicle is big unknown for RL. Likely to be <1000kg as earth departure mass is limited to 1500kg if designed for Neutron launch.One possibility is using HIAD for Mars entry. Its what NASA designed it for.
Is NASA ultimately going to pick exactly one of the proposals from among those funded through these study contracts, or do they have the capability to mix and match? While Rocket Lab proposes an end-to-end solution, perhaps there's a secondary hope that even if they don't get the full contract, they could still win specific parts of the project.
NASA may decide to not fund any and forget MSR. Asking industry for ideas was act of desperation as project was blowing budget and going to be cancelled.
Here are specfications on Capstone Photon Hypercurie 310ISP Photon dry mass is 55kg + 27kg Capstone + 210kg fuel (based on 300kg wet mass). No official thrust figures for Hypercurie but Steve calculated it at 450N. See RL payloads to moon and beyond thread from around post 20. (Pasting links is hit and miss on my ph). NB capstone bus had solar panels, star trackers, long range radios so lot more dry mass than on MAV. Assume 250kg wet would need 2-3engines plus pump batteries to reach orbit.
Quote from: TrevorMonty on 10/14/2024 09:57 amHere are specfications on Capstone Photon Hypercurie 310ISP Photon dry mass is 55kg + 27kg Capstone + 210kg fuel (based on 300kg wet mass). No official thrust figures for Hypercurie but Steve calculated it at 450N. See RL payloads to moon and beyond thread from around post 20. (Pasting links is hit and miss on my ph). NB capstone bus had solar panels, star trackers, long range radios so lot more dry mass than on MAV. Assume 250kg wet would need 2-3engines plus pump batteries to reach orbit.250kg gross liftoff mass for a MAV sounds pretty small. And even then, you'd need a T/W of 2 to 5. So that would be 5 to 11 HyperCuries. That's never gonna close.
450N =45kg x 3 =135kg. 250kg/3(mars gavity)= 83kg. 135/83 =1.6 T/WSamples weigh 11kg. 250kg would reach orbit (4.2km/s) with 63kg -11kg sample allows for 52kg vehicle dry mass. Battery hotswap would reduce that dry mass.
Quote from: TrevorMonty on 10/15/2024 08:10 am450N =45kg x 3 =135kg. 250kg/3(mars gavity)= 83kg. 135/83 =1.6 T/WSamples weigh 11kg. 250kg would reach orbit (4.2km/s) with 63kg -11kg sample allows for 52kg vehicle dry mass. Battery hotswap would reduce that dry mass.Eh?Thrust = 450NWeight = mass * marsG = 250kg * 3.72m/s^2 = 930NT/W = 450N / 930N = 0.48
Adding extra engines will reduce gravity losses but increase dry mass due extra engines and stronger tanks to handle higher Gs.More engines may not mean more battery mass. Battery mass is determined by KWh needed to power engines to orbit. More engines need more watts but for shorter period as it reaches orbit quickier.
A SuperHyperCurie could find its way into 3rd stage for Neutron. Would allow direct delivery of satellites to GEO.
The Escapade spacecraft are using Ariannespace supplied bipropellant engine 318 ISP & 397N. Pressure fed?Not Hypercurie that I assumed.
The MSR-SR will evaluate all 12 studies, but need not recommend a specific one as the best path forward for MSR. “It doesn’t necessarily have to be one of the proposed architectures. It may be that we learn things from all of the architectures,” he said. “They take those things, pieces of them, and say this is what we think the agency ought to be doing going forward.”The goal of the review is to provide that recommendation to agency leadership, including Administrator Bill Nelson, some time in December. “What we’re looking for is an architecture that gives us the highest likelihood of returning samples to Earth before 2040 and, if possible, for less than $11 billion,” Gramling said.
Quote from: TrevorMonty on 10/23/2024 04:57 pmThe Escapade spacecraft are using Ariannespace supplied bipropellant engine 318 ISP & 397N. Pressure fed?Not Hypercurie that I assumed.I think those are probably post deployment motors. Remember that there are two separate birds in Escapade, both of them deployed from the Photon Explorer, which uses either Curies or HyperCuries. I'd guess the latter, but I don't know.
The main propulsion engine is the S400-12 Biprop Thruster from Arianespace, which uses a combination of monomethylhydrazine (MMH) and dinitrogen tetroxide (NTO). Mandy said they weighed a number of factors when it came to choosing which components to build and which to procure, like the engines.“We looked at all the different options for engines that could get us [to Mars]. Rocket Lab has its own engines. We are more interested in mission success than anything else,” Mandy said. “There are these high heritage, very stable, long-duration mission engines that came out of other companies and we just picked one of those.”