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spacecoach illustration
A “spacecoach” could make use of inflatable modules, solar electric propulsion, and thin film photovoltaics to offer an alternative concept for deep space missions. (credit: Rüdiger Klaehn)

A stagecoach to the stars


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“What if a spacecraft, like a cell, was made mostly of water?”

The core idea behind the spacecoach architecture is the use of water, and potentially waste streams, as propellant in electric engines.

That’s what Alexander Tolley and I asked when we were working on our paper for the Journal of the British Interplanetary Society, “A Reference Design For A Simple, Durable and Refuelable Interplanetary Spacecraft.”1 The paper explored the idea of a crewed spacecraft that used water as propellant in combination with solar electric propulsion. We dubbed them “spacecoaches,” as a nod to the stagecoaches of the Old West. Alex also gave the concept an excellent fictional treatment in Spaceward Ho!, also published here on Centauri Dreams. We are currently finishing a book about spacecoaches, to be published by Springer this fall. Visit spacecoach.org for updates about the book and spacecoaches in general.

The idea of crewed solar electric spacecraft is hardly new. In 1954, Ernst Stuhlinger proposed a “sun-ship” powered by solar steam turbines and cesium ion drives (see illustration below).2,3 Since then, solar electric propulsion has been used in a wide variety of uncrewed craft. Meanwhile, the convergence of several technologies will make crewed solar electric vehicles feasible in the near future.

illustration

The core idea behind the spacecoach architecture is the use of water, and potentially waste streams, as propellant in electric engines. Water, life support, and consumables are critical elements in a long-duration mission and, in a conventional ship, are dead weight that must be pushed around by propellant that cannot be used for other purposes. Water in a spacecoach, on the other hand, can be used for many things before it is reclaimed and sent to the engines, and it can be treated as working mass. This, combined with the increased propellant efficiency of electric engines, leads to a virtuous cycle that results in dramatic cost reductions compared to conventional ships while increasing mission capabilities. Cost reductions of one or two orders of magnitude, which would make travel to destinations throughout the inner solar system routine, are possible with this approach.

Water is, for example, an excellent radiation shielding material, comparable to lead on a per-kilogram basis—except you can’t drink lead. It is an excellent thermal battery, and can simply be circulated in reservoirs wrapped around the ship to balance hot and cold zones (this same reservoir doubles as the radiation shield.) When frozen into fibrous material to form pykrete, it forms a material as tough as concrete, which can potentially be used for debris shielding or for momentum wheels, and if positioned correctly, can double as a supplemental radiation shield. If mixed with dilute hydrogen peroxide, which is safely stored at low concentrations, oxygen can be generated by passing it through a catalyst, similar to a contact lens cleaner. Dilute hydrogen peroxide is also a potent disinfectant, and can also be used to process human waste, as is done in terrestrial wastewater treatment plants. Anything the crew eats or drinks can be counted as propellant, as the water can be reclaimed and used for propulsion. This greatly simplifies planning for long missions because the longer the mission is, the more propellant you have in the form of consumables. This will also provide excellent safety margins and enable crews to survive an Apollo 13 scenario in deep space.

A spaceship that is mostly water will be more like a cell than a conventional rocket-plus-capsule architecture. Space agriculture, or even aquaculture, becomes practical when water is abundant. Creature comforts that would be unthinkable in a conventional ship (hot baths, anyone?) will be feasible in a spacecoach. Meanwhile, inflatable structures will eventually enable the construction of large, complex habitats that will be more like miniature O’Neill colonies than a conventional spaceship.4

In the book, Alex and I present a reference design that combines inflatable structures and thin film photovoltaic (PV) arrays to form a kite-like structure that both has a large PV array area and can be rotated to provide artificial gravity in the outer areas. The ability to generate artificial gravity while providing ample radiation protection solves two of the thorniest problems in long-duration spaceflight. Alex wrote an excellent fictional treatment of the concept for Centauri Dreams called Spaceward Ho! This is intended as a straw man design to kickstart design competitions. We envision a series of design competitions for water-compatible electric propulsion technologies, large0scale solar arrays, and overall ship designs. Much of the reference design can be validated in ground-based competitions and experiments, followed by uncrewed test vehicles (similar to what Bigelow Aerospace did by flying its Genesis I and II habitats in low earth orbit).

Spacecoaches are possible not because of any one insight or breakthrough, but because of the convergence of improvements in component technologies, specifically thin film photovoltaics, electric propulsion, and inflatable structures. The combination of the three, particularly when you add water for propulsion, leads to improvements of one to two orders of magnitude in mission economics.

Spacecoaches are possible not because of any one insight or breakthrough, but because of the convergence of improvements in component technologies.

Thin film solar photovoltaics, which enable the construction of large-area PV sails, will enable ships to generate hundreds of kilowatts to several megawatts of electrical power (thin film PV material coincidentally is much more resistant to radiation than conventional silicon PV material.)5 While thin film solar is not as efficient as silicon in terms of power per unit area, from a power density (watts per kilogram) standpoint, it offers improvements of multiple orders of magnitude, and will continue to improve for decades due to dematerialization in manufacturing processes.

SEP (solar electric propulsion) is a well-understood, flight-ready technology. Engines that function with water or gasified waste will be well suited to the spacecoach architecture. We simply need to test existing SEP technologies with water and waste streams to pin down performance and efficiency numbers, which can be done via an X-Prize-style engineering competition. Scaling them to propel a large (40 tonne) ship will be done by clustering them in arrays, so there will be no need to build a single high power engine when an array of many 10–20 kilowatt units will do just fine, while also adding redundancy. One interesting discovery we made while doing our analysis is that ultra-high specific impulse engines, such as Ad Astra’s Variable Specific Impulse Magnetoplasma Rocket (VASIMR), are neither necessary nor desirable. Engines that operate at the low end of the electric propulsion envelope still yield excellent economics because of the synergies created by using water as propellant, while also being able to operate with less electrical power per unit of thrust, which reduces PV array size and mass.

Inflatable/expandable structures are just now being recognized as a flight-ready technology, with Bigelow Expandable Activity Module unit due to fly on the International Space Station later this year. Bigelow already has two uncrewed inflatable habitats in low Earth orbit. The basic idea with inflatable structures is to replace a rigid metal hull with a flexible. high-strength Kevlar-like material and utilize pressurization to inflate and deploy the structure. This also enables a large habitable space to be packed into a standard cargo fairing, thus minimizing the number of launches for initial delivery to orbit. We expect this technology to improve, both in terms of mass per unit of habitable space (currently about 60 kilograms per cubic meter), and in terms of the types of shapes that can be created.6

Spacecoaches will not be mission-specific ships. Even the first-generation ships will be able to travel to many destinations within the inner solar system. They will be fully reusable, travelling from a high Earth orbit or a Lagrange point to and from their destinations, without ever entering a planetary atmosphere. Spacecoaches will be able to travel to cislunar space, Mars, Venus, near Earth objects (NEOs), and maybe even Ceres and the main asteroid belt. They can also be dispatched for asteroid interception and deflection missions on short notice. This is a huge departure from conventional spacecraft, which are purpose-built for a specific mission, like Mars, planned decades in advance. While Mars is certainly an interesting destination, Ceres, with its abundant water resources and shallow gravity well, may turn out to be an even more interesting destination for human exploration and settlement.

The amount of water required for propellant on any given route will vary depending on the delta-v needed, and also the specific impulse of the engines on board, but water is easy to handle and store. Need to add an extra two kilometers per second to your delta-v budget? Just add water! (Or replace the electric engines with slightly more efficient models.) Because water is so easy to handle compared to conventional propellants, this will also simplify the construction and operation of orbiting fuel depots, which will be little more than orbiting water tanks.

Simplicity and upgradability is another key design element of the spacecoach. We assume that component technologies will continue to improve for decades. So instead of designing spacecoaches to fly only with today’s technology, they will be designed more like personal computers were in the 1980s. The original PCs were built around a common electrical and communication bus, called the ISA bus, which allowed memory, CPUs, and peripherals from many manufacturers to be combined. If you wanted to, you could buy the component parts from catalogs and build your own PC from scratch.

We envision something similar for the spacecoach, particularly for the electrical system and engines that will have standard electrical and fluid interconnects and uniform form factor requirements. The engines will also be mounted in a sealable compartment that can be pressurized so the crew can replace or upgrade engines without doing a spacewalk. This will not only make spacecoaches field upgradable, but will also reduce the need to design engines for extreme reliability. If a few units fail, crews would replace them in an operation not much different than replacing a rack-mounted server. Upgrading engines will be the best way to improve performance and reduce costs, as a small increase in specific impulse can yield significant mass and cost reductions, especially for high delta-v routes like Ceres and the asteroid belt.

And what about cost?

Even with engines operating at the low end of the electric propulsion performance envelope, our models predicted per mission costs in the hundreds of millions of dollars, a one- or two-order-of-magnitude reduction compared to conventional missions.

Mention crewed missions to Mars, much less anywhere else, and people automatically assume you’re talking tens of billions of dollars as a starting point. We modeled approximate round-trip mission costs to destinations throughout the inner solar system, using a 40,000-kilogram (40-tonne) dry hull and SpaceX’s published launch costs to get materials, including water, into low Earth orbit ($1,700 per kilogram via Falcon Heavy).7 Electric propulsion, with a specific impulse of between 1,500 to 3,000 seconds, would take over from there (electrode-less Lorentz force thrusters using water operate in this range.) Among the missions we modeled were EML-2 (Earth Moon Lagrange point 2) to/from cislunar space, Martian moons, NEO interception, Venus orbit, and Ceres.

Even with engines operating at the low end of the electric propulsion performance envelope, our models predicted per mission costs in the hundreds of millions of dollars, a one- or two-order-of-magnitude reduction compared to conventional missions, some of which, such as a crewed mission to Ceres, simply are not possible via chemical propulsion.

Such large cost reductions are possible due to a combination of the fuel efficiency of electric engines and the synergies created by using water as propellant. On one hand, electric engines require far less propellant for a given delta-v. On the other, virtually everything the crew consumes or uses for life support can eventually be sent to the engines. As a result, the only dead weight on the ship is the hull and whatever non-consumable materials and equipment are brought on board, which will also allow spacecoaches to carry larger crews. Reusability will also enable operators to amortize development and construction costs across many missions.

Spacecoaches are also well suited for in situ resource utilization (ISRU). Should we reach low gravity destinations with accessible water (Ceres is an especially interesting location), it will eventually be possible to refuel spacecoaches at these destinations, or even ship water inbound to cislunar depots. We assume for now that spacecoaches are fully supplied from Earth, but exploring ISRU destinations and capabilities will be a high priority early on. Partially reusable launch vehicles offer another way to reduce costs. Water will be an ideal payload for a heavily re-used Falcon 9R booster. Unlike most payloads, it has essentially zero replacement cost, so the launch operator can fly the reusable boosters until they fail, and can learn about potential failure modes and fixes in the process, all while delivering more water to orbit.

If you are part of a team working on electric propulsion technology, here’s one way you can help make these a reality. Test your engine with water vapor, carbon dioxide, and gasified waste (or a good analogue), and publish your results. The most important parameters ship designers will be interested in are specific impulse, efficiency (ideally the “wall plug” efficiency of the entire system so it can be modeled as a black box), and thrust-to-mass ratio. We already know several SEP technologies work reasonably well with water, but it will be great to examine all systems to see how well each works with water, compare performance across a variety of technologies, and identify opportunities for further improvement.

Spacecoaches will open the inner solar system out to the asteroid belt to human exploration and settlement.

It is easy to be cynical about new spaceflight concepts, especially one that promises large cost reductions, but most of this can be validated on the ground and via uncrewed testbeds in a short time and at little expense. It is a paradigm shift, and that will take people some time to accept. The rocket-plus-capsule design pattern served us well in the early years of spaceflight, so it’s hard to get away from that. But it’s time to move on to something that is more adaptable, something that’s more like a ship that can sail wherever her captain wants to go.

Spacecoaches will form the basis for a real world Starfleet, a fleet that will grow as ships are built, and which will reach new destinations as component technologies continue to improve in the coming decades. They will open the inner solar system out to the asteroid belt to human exploration and settlement, and with some spacecoaches operating in cislunar space, humanity will also have a rapid response capability should we be surprised by the discovery of an Earth threatening object.

Visit spacecoach.org to learn more, and to subscribe for notices about the upcoming book, which examines the spacecoach reference design and potential missions in detail. If you are interested in obtaining an advance copy of the book, acting as a technical reviewer or inviting us to speak, please get in touch.

References

  1. “Reference Design for a Simple, Durable and Refuelable Interplanetary Spacecraft”, B. S. McConnell; A. M. Tolley (2010), JBIS, 63, 108–119
  2. Image credit: Frank Tinsley/American Bosch Arma Corporation, 1954
  3. “Possibilities of Electrical Space Ship Propulsion,” E. Stuhlinger, Bericht über den V Internationalen Astronautischen Kongreß, Frederich Hecht, editor, 1955, pp. 100–119; paper presented at the Fifth International Astronautical Congress in Innsbruck, Austria, 5–7 August 1954
  4. “A Shape Grammar for Space Architecture – I. Pressurized Membranes”, Val Stavrev* Aeromedia, Sofia, Bulgaria, 40th International Conference on Environmental Systems, http://www.spacearchitect.org/pubs/AIAA-2010-6071.pdf
  5. “Super radiation tolerance of CIGS solar cells demonstrated in space by MDS-1 satellite”, Photovoltaic Energy Conversion, 2003. Proceedings of 3rd World Conference on, 18-18 May 2003, pp. 693–696 Vol.1
  6. Estimate based on BA330 mass per cubic meter of habitable space, per Bigelow Aerospace’s published specifications
  7. Per SpaceX published launch cost and delivery capacity for Falcon Heavy, as of April 2015

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