|
Curator: Al Globus If you find any errors on this page contact Al Globus. |
 |
This site was hosted by the NASA Ames Research Center from 1994-2018 and is now hosted by:
Space resources must be used to support life on the Moon and
exploration of Mars. Just as the pioneers applied the tools they
brought with them to resources they found along the way rather than
trying to haul all their needs over a long supply line, so too must
space travelers apply their high technology tools to local
resources.
The pioneers refilled their water barrels at each river they
forded; moonbase inhabitants may use chemical reactors to combine
hydrogen brought from Earth with oxygen found in lunar soil to make
their water. The pioneers sought temporary shelter under trees or
in the lee of a cliff and built sod houses as their first homes on
the new land; settlers of the Moon may seek out lava tubes for
their shelter or cover space station modules with lunar regolith
for radiation protection. The pioneers moved further west from
their first settlements, using wagons they had built from local
wood and pack animals they had raised; space explorers may use
propellant made at a lunar bass to take them on to Mars.
The concept for this report was developed at a NASA-sponsored
summer study in 1984. The program was held on the Scripps campus of
the University of California at San Diego (UCSD), under the
auspices of the American Society for Engineering Education (ASEE).
It was jointly managed by the California Space Institute and the
Lyndon B. Johnson Space Center, under the direction of the Office
of Aeronautics and Space Technology (OAST) at NASA Headquarters.
The study participants (listed in the addendum) included a group of
18 university teachers and researchers (faculty fellows) who were
present for the entire 10-week period and a larger group of
attendees from universities, Government, and industry who came for
a series of four 1 - week workshops.
The organization of this report follows that of the summer study.
Space Resources consists of a brief overview and four detailed
technical volumes: (1) Scenarios; (2) Energy, Power, and Transport;
(3) Materials; (4) Social Concerns. Although many of the included
papers got their impetus from workshop discussions, most have been
written since then, thus allowing the authors to base new
applications on established information and tested technology. All
these papers have been updated to include the authors' current
work.
This overview, drafted by faculty fellow Jim Burke, describes the
findings of the summer study, as participants explored the use of
space resources in the development of future space activities and
defined the necessary research and development that must precede
the practical utilization of these resources. Space resources
considered included lunar soil, oxygen derived from lunar soil,
material retrieved from near-Earth asteroids, abundant sunlight,
low gravity, and high vacuum. The study participants analyzed the
direct use of these resources, the potential demand for products
from them, the techniques for retrieving and processing space
resources, the necessary infrastructure, and the economic
tradeoffs.
This is certainly not the first report to urge the utilization of
space resources in the development of space activities. In fact,
Space Resources may be seen as the third of a trilogy of NASA
Special Publications reporting such ideas arising from similar
studies. It has been preceded by Space Settlements: A Design
Study (NASA SP-413) and Space Resources and Space
Settlements (NASA SP-428).
And other, contemporaneous reports have responded to the same
themes. The National Commission on Space, led by Thomas Paine, in
Pioneering the Space Frontier, and the NASA task force led
by astronaut Sally Ride, in Leadership and America's Future in
Space, also emphasize expansion of the space infrastructure;
more detailed exploration of the Moon, Mars, and asteroids; an
early start on the development of the technology necessary for
using space resources; and systematic development of the skills
necessary for long-term human presence in space.
Our report does not represent any Government-authorized view or
official NASA policy. NASA's official response to these challenging
opportunities must be found in the reports of its Office of
Exploration, which was established in 1987. That office's report,
released in November 1989, of a 90-day study of possible plans for
human exploration of the Moon and Mars is NASA's response to the
new initiative proposed by President Bush on July 20, 1989, the
20th anniversary of the Apollo 11 landing on the Moon: "First, for
the coming decade, for the 1990s, Space Station Freedom, our
critical next step in all our space endeavors. And next, for the
new century, back to the Moon, back to the future, and this time,
back to stay. And then a journey into tomorrow, a journey to
another planet, a manned mission to Mars." This report, Space
Resources, offers substantiation for NASA's bid to carry out that
new initiative.
Future space activities may benefit from the use of natural
resources found in space: energy from the Sun, certain properties
of space environments and orbits, and materials of the Moon and
near-Earth asteroids. To assess this prospect and to define
preparations that could lead to realizing it, a study group
convened for 10 weeks in the summer of 1984 at the California Space
Institute at the University of California at San Diego. Papers
written by this study group were edited and then recycled through
most of the contributors for revision and updating to reflect
current thinking and new data on these topics. This is a summary
report of the group's findings.
The sponsors of the study-NASA and the California Space
Institutecharged the study group with the task of defining possible
space program objectives and scenarios up to the year 2010 and
describing needed technologies and other precursor actions that
could lead to the large-scale use of nonterrestrial resources. We
examined program goals and options to see where, how, and when
space resources could be of most use. We did not evaluate the
longrange program options and do not recommend any of them in
preference to others. Rather, we concentrated on those near-term
actions that would enable intelligent choices among realistic
program options in the future. Our central conclusion is that
near-Earth resources can indeed foster the growth of human
activities in space. Most uses of the resources are within the
space program, the net product being capabilities and information
useful to our nation both on and off the Earth.
The idea of using the energy, environments, and materials of space
to support complex activities in space has been implicit in many
proposals and actions both before and during the age of space
flight. As illustrated in figure 1,
the deep gravity well of the Earth makes it difficult and expensive
to haul all material supplies, fuel, and energy sources into space
from the surface of the Earth; it is clearly more efficient to make
maximum use of space resources. Up to now, however, our ability to
employ these resources has been limited by both technology and
policy. Studies and laboratory work have failed to bring the
subject much beyond the stage of speculations and proposals,
primarily because until now there has been no serious intent to
establish human communities in space.
With progress in the Soviet program of long-duration manned
operations in Earth orbit and with the coming of an American space
station initiative, the picture appears to be changing. The present
study is one step in a process laying groundwork for the time when
living off Earth, making
large-scale use of nonterrestrial resources, will be both
technologically feasible and socially supported.
The 18 faculty fellows who participated in the summer study organized themselves into four groups. The focus of each group corresponded with that of a 1-week workshop held in conjunction with the summer study and attended by 10 to 20 experts in the target field. The first working group generated the three scenarios that formed the basis of the subsequent discussions. The other three groups focused on these areas of inquiry:
Before we could evaluate the benefits and opportunities
associated with the use of space resources, we had to consider what
might be going on in space in the future. The target date defined
for this study, 2010, is beyond the projection of present American
space initiatives but not too far in the future for reasonable
technological forecasting. The U. S. space program is now set on a
course that can carry it to the end of this century, with
increasing capabilities in low Earth orbit (LEO) and geosynchronous
Earth orbit (GEO) and modest extensions into deeper space. At the
present rate of progress, there would not be much new opportunity
to exploit nonterrestrial resources before the year 2000.
A typical plan for space activities is illustrated in figure 2, which shows a sequence of
milestones leading to human enterprises in LEO, in GEO, and on the
Moon, plus automated probing of some near-Earth asteroids and of
Mars. In this plan, most of the space activity before 2010 is
concentrated in low Earth orbit, where the basic space station is
expanded into a larger complex over a period of 20 years. In
geosynchronous Earth orbit, an experimental platform is replaced in
2004 by an outpost to support manned visits leading to a
permanently manned station by 2012. Until the year 2010 only
unmanned missions are sent to the Moon. In that year, nearly 20
years after the establishment of the space station, a small lunar
camp is established to support short visits by people. In this
plan, the only American missions to Mars in the next 40 years are
two unmanned visits: a sample return mission and a roving
surveyor.
It is clear that, if the plan in figure
2 is followed, natural resources from the Moon, Mars, or other
planetary bodies will not be used until at least 2016.
If we consider the plan in figure 2
to be our baseline, then figure 3
illustrates an alternative departing from that baseline in the
direction of more and earlier use of nonterrestrial resources. In
this plan, a growing lunar base has become a major goal after the
space station. Lunar and asteroidal resources would be sought and
exploited in support of this goal rather than for any external
purpose. The establishment of a lunar camp is moved up 5 years to
2005 and advanced lunar base is
in place by 2015.In this plan, lunar resources are used to support
the construction and operation of this base and lunar-derived
oxygen is used to support transportation to and from base.
Asteroidal material from automated mining missions would also
contribute to supporting these space operations after 2015
Figure 4 shows a different departure from the baseline. Here, the objectives are balanced among living off Earth, developing near-Earth resources for a variety of purposes, and further exploring the solar system with an eventual human landing on Mars. In this alternative scenario, a LEO space station, a small GEO outpost, and a small manned lunar station are all in operation by 2005, with a manned Mars visit and establishment of a camp by 2010, some 12 to 14 years earlier than in the previous plans. Automated asteroid mining and return starts by 2010. The focus of this program is longer term than that of the program diagramed in figure 3. By building up a balanced infrastructure at various locations, it invests more effort in activities whose benefits occur late in the next century and less in shorter range goals such as maximizing human presence on the Moon.
These three scenarios, the baseline and two alternates, have served as a basis for our discussion of the uses of nonterrestrial resources. None is a program recommended by the study group, since that was not our charter. They are merely illustrative examples of programs that, we believe, might materialize over the next two decades as a result of national or international trends in space. The two alternate scenarios assume some acceleration and focusing of American efforts in space, as happened during the Apollo era, while the baseline scenario assumes a straightforward extrapolation of our present program, with only modest budget growth and no particular concentration on the use of nonterrestrial resources.
Heavy Lift Vehicle
An unmanned heavy lift launch vehicle derived from the Space
Shuttle to lower the cost of transporting material to Earth orbit
would make it feasible to transport to orbit elements of a lunar
base or a manned spacecraft destined for Mars. Its first stage
would be powered by two solid rocket boosters, shown here after
separation. Its second stage would be powered by an engine cluster
at the aft end of the fuel tank that forms the central portion of
the vehicle. All this pushes the payload module located at the
forward end. This payload module can carry payloads up to 30 feet
(9.1 meters) in diameter and 60 feet (18.3 meters) in length and up
to 5 times as heavy as those carried by the Shuttle orbiter.
Artist-Dennis Davidson
|
Curator: Al Globus If you find any errors on this page contact Al Globus. |
|
This site was hosted by the NASA Ames Research Center from 1994-2018 and is now hosted by: