Why would SpaceX need to make investments for CRS2? Can't they just offer Dragon V1 and V2? There was talk of an extended trunk. But I don't think SpaceX has other plans for improving Dragon.
Does the F9 have the lift capability to do a crew and cargo at the same time?
Quote from: baldusi on 09/18/2014 09:34 pmQuote from: docmordrid on 09/18/2014 08:33 pmISTM, not for pressurized cargo. That said, aren't the major drivers in Cygnus expansion how many segments are in the pressure vessel and perhaps an increased prop margin? Doesn't sound that difficult.There's a presentation of a super Cygnus with an extra pressurized ring (four total) that has a mass capability of 3,400kg and 33m³. But it would require something like 5,500kg to 300km x 51.6deg from the Antares. The 131 can do 5,260kg and it would also require an extra fairing extension. If the new re-engined Antares can get the extra performance, the total cost to OSC of this development will be quite low.I believe that the SpaceX solution that I propose is also relatively cheap. But in general it's quite clear that SNC, Boeing, SpaceX and OrbitalATK will need some investments for CRS-2 and thus I expect a pretty leveled field.Why would SpaceX need to make investments for CRS2? Can't they just offer Dragon V1 and V2? There was talk of an extended trunk. But I don't think SpaceX has other plans for improving Dragon.
Quote from: docmordrid on 09/18/2014 08:33 pmISTM, not for pressurized cargo. That said, aren't the major drivers in Cygnus expansion how many segments are in the pressure vessel and perhaps an increased prop margin? Doesn't sound that difficult.There's a presentation of a super Cygnus with an extra pressurized ring (four total) that has a mass capability of 3,400kg and 33m³. But it would require something like 5,500kg to 300km x 51.6deg from the Antares. The 131 can do 5,260kg and it would also require an extra fairing extension. If the new re-engined Antares can get the extra performance, the total cost to OSC of this development will be quite low.I believe that the SpaceX solution that I propose is also relatively cheap. But in general it's quite clear that SNC, Boeing, SpaceX and OrbitalATK will need some investments for CRS-2 and thus I expect a pretty leveled field.
ISTM, not for pressurized cargo. That said, aren't the major drivers in Cygnus expansion how many segments are in the pressure vessel and perhaps an increased prop margin? Doesn't sound that difficult.
I ignore...
But the pressing issue is the cargo density.
Quote from: e of pi on 04/29/2014 12:44 amQuote from: deltaV on 04/29/2014 12:16 amThat RFI requests up to 16.8 tonnes of pressurized upmass yearly with a volume of up to 70 m^3. The maximum allowed number of flights is 5 yearly, so this works out to 3.4 tonnes and 14 m^3 per flight.A dragon has only 11 m^3 of pressurized volume (http://www.spacex.com/dragon), so a larger dragon is presumably required. I have no idea whether a F9 1.1 would be sufficient to haul an enlarged dragon to ISS.I'll just note that you quote "up to" 3.4 tonnes and 14 m^3. If that's the language from the original, then that would simply to me imply an upper bound, or a rough ballpark they'd like. I think you could also mix-and-match payloads between operators: put denser payloads into Dragon, and save lighter, bulkier ones for Cygnus. (Just to pick a combination of the two existing vehicles.)The RFI says that it should generally represent 55 to 70 m^3. It doesn't seem to be a hard requirement. But SpaceX would meet it anyways. They should also meet the payload requirement 5 x 3 mt = 15mt. Quote from: draft RFIDelivery of 14,250 to 16,750 kilograms (kg) per year of pressurized cargo.o The typical volume of the mass of cargo quoted above is 55 to 70 cubic meters (m3) which must be accommodated.
Quote from: deltaV on 04/29/2014 12:16 amThat RFI requests up to 16.8 tonnes of pressurized upmass yearly with a volume of up to 70 m^3. The maximum allowed number of flights is 5 yearly, so this works out to 3.4 tonnes and 14 m^3 per flight.A dragon has only 11 m^3 of pressurized volume (http://www.spacex.com/dragon), so a larger dragon is presumably required. I have no idea whether a F9 1.1 would be sufficient to haul an enlarged dragon to ISS.I'll just note that you quote "up to" 3.4 tonnes and 14 m^3. If that's the language from the original, then that would simply to me imply an upper bound, or a rough ballpark they'd like. I think you could also mix-and-match payloads between operators: put denser payloads into Dragon, and save lighter, bulkier ones for Cygnus. (Just to pick a combination of the two existing vehicles.)
That RFI requests up to 16.8 tonnes of pressurized upmass yearly with a volume of up to 70 m^3. The maximum allowed number of flights is 5 yearly, so this works out to 3.4 tonnes and 14 m^3 per flight.A dragon has only 11 m^3 of pressurized volume (http://www.spacex.com/dragon), so a larger dragon is presumably required. I have no idea whether a F9 1.1 would be sufficient to haul an enlarged dragon to ISS.
Delivery of 14,250 to 16,750 kilograms (kg) per year of pressurized cargo.o The typical volume of the mass of cargo quoted above is 55 to 70 cubic meters (m3) which must be accommodated.
The IG says that SpaceX would meet the requirements for CRS2 (see table 4 on page 26 of the report). That is also my understanding. The number of flights (5) isn't a hard requirement either. See below. Quote from: yg1968 on 04/29/2014 12:49 amQuote from: e of pi on 04/29/2014 12:44 amQuote from: deltaV on 04/29/2014 12:16 amThat RFI requests up to 16.8 tonnes of pressurized upmass yearly with a volume of up to 70 m^3. The maximum allowed number of flights is 5 yearly, so this works out to 3.4 tonnes and 14 m^3 per flight.A dragon has only 11 m^3 of pressurized volume (http://www.spacex.com/dragon), so a larger dragon is presumably required. I have no idea whether a F9 1.1 would be sufficient to haul an enlarged dragon to ISS.I'll just note that you quote "up to" 3.4 tonnes and 14 m^3. If that's the language from the original, then that would simply to me imply an upper bound, or a rough ballpark they'd like. I think you could also mix-and-match payloads between operators: put denser payloads into Dragon, and save lighter, bulkier ones for Cygnus. (Just to pick a combination of the two existing vehicles.)The RFI says that it should generally represent 55 to 70 m^3. It doesn't seem to be a hard requirement. But SpaceX would meet it anyways. They should also meet the payload requirement 5 x 3 mt = 15mt. Quote from: draft RFIDelivery of 14,250 to 16,750 kilograms (kg) per year of pressurized cargo.o The typical volume of the mass of cargo quoted above is 55 to 70 cubic meters (m3) which must be accommodated.
I thought that the actual numbers acheived were less because of volume constraints not because of capability issues.
Quote from: yg1968 on 09/20/2014 01:39 amI thought that the actual numbers acheived were less because of volume constraints not because of capability issues.I never implied anything but density limitations for Dragon (Cygnus is performance limited, for now).
SpaceX has also talked (vaguely) about transitioning to V2 only at some point. As others have noted Dragon V2 itself has several drawbacks from a cargo perspective. An optional extended trunk with a removable pressurized cargo module (and CBM interface) could be a relatively cost effective way to achieve cargo and crew with the same system. Maybe even simultaneously, as in the old Liberty proposal (the best feature of that proposal, in my opinion).
One of the major findings of the CAIB which lead directly to the cancellation of Shuttle as soon after RTF as possible, was that mixing crew and cargo within the confines of the same spacecraft was a definitive contributing factor to the loss of the Columbia crew. The recommendation was for NASA to use separate spacecraft for cargo so that crew would not be placed at risk for the sake of cargo delivery.
Quote from: clongton on 09/20/2014 01:33 pmOne of the major findings of the CAIB which lead directly to the cancellation of Shuttle as soon after RTF as possible, was that mixing crew and cargo within the confines of the same spacecraft was a definitive contributing factor to the loss of the Columbia crew. The recommendation was for NASA to use separate spacecraft for cargo so that crew would not be placed at risk for the sake of cargo delivery.Doesn't fly. Crewed Dragons are going up regardless, so the flights are for the sake of ISS crew replacement, not cargo delivery. Adding cargo to a DragonRider flight doesn't change the necessity of risking crew on an orbital launch.
Quote from: GreenShrike on 09/20/2014 01:58 pmQuote from: clongton on 09/20/2014 01:33 pmOne of the major findings of the CAIB which lead directly to the cancellation of Shuttle as soon after RTF as possible, was that mixing crew and cargo within the confines of the same spacecraft was a definitive contributing factor to the loss of the Columbia crew. The recommendation was for NASA to use separate spacecraft for cargo so that crew would not be placed at risk for the sake of cargo delivery.Doesn't fly. Crewed Dragons are going up regardless, so the flights are for the sake of ISS crew replacement, not cargo delivery. Adding cargo to a DragonRider flight doesn't change the necessity of risking crew on an orbital launch.But adding additional modules increases complexity, and that might lead to unanticipated increases in risk.If the crew vehicle has seats that aren't being used anyway, throwing in some cargo instead of passengers seems fine to me. Adding big new trunks and/or pressurized modules crosses the line for me to adding that risk the CAIB warned about.
I'm sure it would be a lot more complex and costly than putting a pressurized container in the trunk, but would it be feasible to make a cargo Dragon in a Soyuz-like configuration with a second pressurized module on top? Seems like it would be much easier to actually use at the ISS.
What kind of volume and mass does dreamchaser carry? Could it fill the requirements?
