Slightly Longer-term idea here, but what if you followed a sort-of real-estate approach? Instead of one company building the whole station (expensive), the company builds a "shell" station. This would have little more than the basics - a Heavy-duty balancing system, a spin-up/down system, and minimal life support. The company can then sell "land" on the station and make a profit without as much capital expenditure as required to build the entire station.
Slightly Longer-term idea here, but what if you followed a sort-of real-estate approach? Instead of one company building the whole station (expensive), the company builds a "shell" station.
This would have little more than the basics - a Heavy-duty balancing system, a spin-up/down system, and minimal life support.
The company can then sell "land" on the station and make a profit without as much capital expenditure as required to build the entire station.
Quote from: jdon759 on 09/25/2021 09:49 amSlightly Longer-term idea here, but what if you followed a sort-of real-estate approach? Instead of one company building the whole station (expensive), the company builds a "shell" station. This would have little more than the basics - a Heavy-duty balancing system, a spin-up/down system, and minimal life support. The company can then sell "land" on the station and make a profit without as much capital expenditure as required to build the entire station.Effectively, that is a whole station. The minimum build before you can sell "land" is exactly what any commercial space station would involve.Power, thermal, life-support, pressure shell, MMOD/rad shielding, attitude control, attitude thrusters/OMS, and in the case of a spin station, spin-up/down system and mass distribution control.
I have a rotating space station design that could be progressively built like that, but I think most of the cost of a rotating space station would be for the station itself - outfitting living spaces would likely be the minority of the total cost.
Those are good points about it being most of the station already, and it is a problem I am aware of - the most expensive part has to be done anyway.
But I think you may be overestimating how "complete" my suggested station is.
I do not expect the initial "shell station" to have much more habitable volume than a reentry capsule. Modules with their own life support, pressure shell and MMOD/rad shielding would be the "buildings" that are built on the "land" of the shell-station's structure.
But I think you may be overestimating how "complete" my suggested station is. I do not expect the initial "shell station" to have much more habitable volume than a reentry capsule. Modules with their own life support, pressure shell and MMOD/rad shielding would be the "buildings" that are built on the "land" of the shell-station's structure. Power and stationkeeping would be all that is provided to these buildings by the shell-station. This requires a heavy-duty balancing system because the station is assured to be imbalanced due to decentralised design and non-simultaneous construction. It's analogous to a Stanford torus where the dwellings within the torus are not built at the time the torus is "complete", but are added later by the people living there.
The problem I have with the real-estate model is that with an "empty" site on Earth, there's common "infrastructure" that we take for granted that doesn't exist in space. Air. (Duh.) But also everything that it allows, such easier thermal control (just circulate air through your building, or through your heat-exchanger,) and easier access to neighbouring sites and access to other infrastructure like roads. Seemingly little things like pressure automatically equalising in any system that isn't gas-tight. For example, in sewerage systems. Makes construction and use vastly easier.
That said, I agree that the "mass balancing" requirement is probably overblown. This isn't a wheel-on-an-axle, where even slight imbalances cause vibration, free-rotating objects find their own centre-of-rotation. Beyond the intermediate-axis issue discussed {waves hand} over a bunch of threads, the system will be innately stable. The only requirement for a fixed centre-of-rotation is for docking. And IMO it's better to design a docking system that can cope with off-axis approach, rather than require the station (and approaching spacecraft) to be perfectly balanced around a (shared) fixed physical axis. It's yet-another-system-to-develop (yay!) but once solved, it eliminates so much hassle.
It's not just that "it's harder". It's "different" to the point that not only does the analogy break down, but that such a method of construction would end up costing everyone more than simply not doing it. It wouldn't even save money in the development stage of the core station (pushing costs forward to the clients, reducing buy-in for early investors.)
and Paul you assumed I was arguing a point that I wasn't arguing.
Quote from: Paul451 on 09/28/2021 04:33 pmsuch a method of construction would end up costing everyone more than simply not doing it. It wouldn't even save money in the development stage of the core stationI [....] still argue that a division of function/outsourcing of components can make the whole process more cost-effective for everyone involved - and that this is a better way to approach the problem. The entities that want space on a rotating spacecraft don't necessarily want to build the spacecraft itself, but they will find value in being able to build the module/habitat that is to be placed on such a spacecraft.
such a method of construction would end up costing everyone more than simply not doing it. It wouldn't even save money in the development stage of the core station
Quote from: Paul451 on 09/28/2021 04:33 pmThe problem I have with the real-estate model is that with an "empty" site on Earth, there's common "infrastructure" that we take for granted that doesn't exist in space. Air. (Duh.) But also everything that it allows, such easier thermal control (just circulate air through your building, or through your heat-exchanger,) and easier access to neighbouring sites and access to other infrastructure like roads. Seemingly little things like pressure automatically equalising in any system that isn't gas-tight. For example, in sewerage systems. Makes construction and use vastly easier.I've worked on a design for a Earth-level gravity rotating space station that would have provided open space for future tenants, but the infrastructure issue, as you point out, becomes a big challenge. Bottom line is that there were too many challenges to solve with that design, and it was highly unlikely that anyone would need a 1G station anytime soon. Instead I'm focused on a Mars-level gravity rotating space station that will be fully built out, though some internal spaces could be customized, and I'm using the same approach for my rotating spaceship designs.QuoteThat said, I agree that the "mass balancing" requirement is probably overblown. This isn't a wheel-on-an-axle, where even slight imbalances cause vibration, free-rotating objects find their own centre-of-rotation. Beyond the intermediate-axis issue discussed {waves hand} over a bunch of threads, the system will be innately stable. The only requirement for a fixed centre-of-rotation is for docking. And IMO it's better to design a docking system that can cope with off-axis approach, rather than require the station (and approaching spacecraft) to be perfectly balanced around a (shared) fixed physical axis. It's yet-another-system-to-develop (yay!) but once solved, it eliminates so much hassle.Agreed.
Quote from: Coastal Ron on 09/29/2021 02:12 amQuote from: Paul451 on 09/28/2021 04:33 pmThat said, I agree that the "mass balancing" requirement is probably overblown. This isn't a wheel-on-an-axle, where even slight imbalances cause vibration, free-rotating objects find their own centre-of-rotation. Beyond the intermediate-axis issue discussed {waves hand} over a bunch of threads, the system will be innately stable. The only requirement for a fixed centre-of-rotation is for docking. And IMO it's better to design a docking system that can cope with off-axis approach, rather than require the station (and approaching spacecraft) to be perfectly balanced around a (shared) fixed physical axis. It's yet-another-system-to-develop (yay!) but once solved, it eliminates so much hassle.Agreed.I'm sure that issues with rotational stability are solvable, but I wouldn't be too quick to dismiss these problems. Rotating structures often behave in very counter intuitive ways:
Quote from: Paul451 on 09/28/2021 04:33 pmThat said, I agree that the "mass balancing" requirement is probably overblown. This isn't a wheel-on-an-axle, where even slight imbalances cause vibration, free-rotating objects find their own centre-of-rotation. Beyond the intermediate-axis issue discussed {waves hand} over a bunch of threads, the system will be innately stable. The only requirement for a fixed centre-of-rotation is for docking. And IMO it's better to design a docking system that can cope with off-axis approach, rather than require the station (and approaching spacecraft) to be perfectly balanced around a (shared) fixed physical axis. It's yet-another-system-to-develop (yay!) but once solved, it eliminates so much hassle.Agreed.
As for the cubesat analogy....Modularity helps, but cubesats are cheap mainly because they're small. Space station modules are not small.Space station modules also kill people when they fail, so all the additional QA and testing adds a fair bit of cost. If a cubesat fails, nobody dies.I think we'll see nano-racks inside a rotating space station, allowing universities to fly cheap payloads. But I doubt we'll see university-level budgets (or even single company-level budgets) launching entire habitation modules any time soon.I think the station-to-module connection is the wrong place to put the customer interface. To borrow a phrase, "rotating space stations are not LEGO." Just like rockets, the whole thing really needs to be designed all together (structurally, infrastructurally, crew circulation and emergency egress, rotational balance, etc). This is less true for purely microgravity stations like the ISS, of course.
I should clarify that my thinking on this is mainly framed by my aim to implement a small ISS-deployed spin-G free-flyer, carrying payload modules around the size of 6U (long) cubesats. Treading a bit of a fine line here because of IP concerns, but basically we're designing something where the (deployable) framework can be taken up in a Dragon2 trunk, while the pressurised modules go up (and come back) in the pressurised section of Dragon. Agreed you have to design the whole thing at the beginning, but making the modules interchangeable like cartridges would be highly desirable if it can be done, because you can then run iterative 3-6 month partial g experiments, reusing the framework component multiple times. Being able to bring those modules down from orbit after completion would be invaluable for a number of fields, so I'm pretty sure there's a saleable service there - if we can get it to be interchangeable.