Sbsp affirmative- arl lab- ndi 2011


***Solvency*** US Key



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***Solvency***




US Key


Whoever sets up SSP first controls the game


O’Neill 08 (Ian, Universe Today, Harvesting Solar Power from Space, http://www.universetoday.com/14646/harvesting-solar-power-from-space/, JG)
In a new report, the viability of sending solar panels into space to collect a vast quantity of uninterrupted energy has been re-investigated. Although the idea has been around since the 1970′s, space solar power has always been viewed as prohibitively expensive. In the current energy climate down here on Earth with spiralling oil prices and a massive push toward green energy sources, sending massive solar arrays into geosynchronous orbit doesn’t seem like such a strange (or expensive) idea. There are many obstacles in the way of this plan, but the international community is becoming more interested, and whoever is first to set up an orbital array will have a flexible and unlimited energy resource… It sounds like the perfect plan: build a vast array of solar panels in space. This avoids many of the practical problems we have when building them on Earth such as land availability, poor light conditions and night time, but sending a sunlight farm into space will be expensive to set up. In the 1970′s a plan was drawn up by NASA for the possibility of orbital sunlight “harvesting”, but it was deemed too expensive with a hefty price tag of at least $1 trillion. There was no country in the world that could commit to such a plan. But as we slowly approach an era of cheaper space travel, this cost has been slashed, and the orbital solar energy case file has been re-opened. Surprisingly, it isn’t the most developed nations in the world that are pushing for this ultimate renewable energy source. India and China, with their ballooning populations are reaching a critical point for energy consumption and they are beginning to realize their energy crisis may be answered by pushing into space. “A single kilometer-wide band of geosynchronous Earth orbit experiences enough solar flux in one year to nearly equal the amount of energy contained within all known recoverable conventional oil reserves on Earth today.” – Pentagon’s National Security Space Office 2007 report. So how could this plan work? Construction will clearly be the biggest expense, but the nation who leads the way in solar power satellites will bolster their economy for decades through energy trading. The energy collected by highly efficient solar panels could be beamed down to Earth (although it is not clear from the source what technology will go into “beaming” energy to Earth) where it is fed into the national grid of the country maintaining the system. Ground based receivers would distribute gigawatts of energy from the uninterrupted orbital supply. This will have obvious implications for the future high demand for electricity in the huge nations in Asia and will wean the international community off carbon-rich non-renewable resources such as oil and coal. There is also the benefit of the flexible nature of this system being able to supply emergency energy to disaster (and war-) zones. “It will take a great deal of effort, a great deal of thought and unfortunately a great deal of money, but it is certainly possible.” – Jeff Keuter, president of the George C. Marshall Institute, a Washington-based research organization. The most optimistic time frame for a fully operational space-based sunlight collection satellite would be 2020, but that is if we started work now. Indeed some research is being done (Japan is investing millions of dollars into a potential prototype to be put into space in the near future), but this is a far cry from planning to get full-scale operations underway in a little over a decade…

Technologically Feasible




We’re technologically ready – materials and energy advances prove



NSSO, ‘7 National Security Space Office [10/10/07, “Space-Based Solar Power as an Opportunity for Strategic Security: Report to the Director, National Security Space office Interim Assessment Release 0.1,” http://www.nss.org/settlement/ssp/library/final-sbsp-interim-assessment-release-01.pdf, DS]
FINDING: The SBSP Study Group found that SpaceBased Solar Power is a complex engineering challenge, but requires no fundamental scientific breakthroughs or new physics to become a reality. SpaceBased Solar Power is a complicated engineering project with substantial challenges and a complex tradespace not unlike construction of a large modern aircraft, skyscraper, or hydroelectric dam, but does not appear to present any fundamental physical barriers or require scientific discoveries to work. While the study group believes the case for technical feasibility is very strong, this does not automatically imply economic viability and affordability—this requires even more stringent technical requirements. FINDING: The SBSP Study Group found that significant progress in the underlying technologies has been made since previous government examination of this topic, and the direction and pace of progress continues to be positive and in many cases accelerating. - 20 - • Significant relevant advances have occurred in the areas of computational science, material science, photovoltaics, private and commercial space access, space maneuverability, power management, robotics, and many others. • These advances have included (a) improvements in PV efficiency from about 10% (1970s) to more than 40% (2007); (b) increases in robotics capabilities from simple tele‐operated manipulators in a few degrees of freedom (1970s) to fully autonomous robotics with insect‐class intelligence and 30‐100 degrees of freedom (2007); (c) increases in the efficiency of solid state devices from around 20% (1970s) to as much as 70%‐90% (2007); (d) improvements in materials for structures from simple aluminum (1970s) to advanced composites including nanotechnology composites (2007); and many other areas.

SBSP is technologically feasible


Lemonick 09 (Michael, senior writer at Climate Central, Yale Environment 360, Solar Power from Space: Moving Beyond Science Fiction, http://e360.yale.edu/content/feature.msp?id=2184, JG)
But there is a way to tap into the sun’s energy 24 hours a day, every day of the year, and send it anywhere on the globe: Launch solar panels into space and beam the power back to Earth. The concept sounds far-fetched and wildly impractical, and when the Pentagon and space enthusiasts began talking about it back in the 1960s and 1970s, it was. Recently, however, the idea of space-based solar power, or SBSP, has begun to look less like science fiction and more like a technology whose time may be coming, with the Pentagon and private companies ramping up efforts to make space-based solar power a reality. Image Gallery Solar ©Mafic Studios, Inc. HOW IT WORKS: Beaming space-based solar power back to Earth Two years ago, the Pentagon’s National Security Space Office (NSSO) issued a report recommending that the U.S. “begin a coordinated national program to develop SBSP.” A year ago, engineers did a small but successful experiment using some of the technology that will be employed in SBSP, taking energy from solar cells, converting it to microwaves, and then beaming it 92 miles from Maui to the Big Island of Hawaii, where it was converted back into 20 watts worth of electricity. And last spring, the California-based Solaren Corporation signed a contract with Pacific Gas & Electric (PG&E) to provide 200 megawatts of power — about half the output of an average coal-fired power plant — by 2016 by launching solar arrays into space.

Solvency Attainable – Planning leads to mastery of industrial space and SSP


Snead 09 (James M, The Space Review, The Vital Need For America to Develop Space Solar Power, http://www.thespacereview.com/article/1364/1, JG)
Successfully developing SSP and building the integrated spacefaring logistics infrastructure necessary to demonstrate SSP and prepare for serial production of the geostationary platforms can only be successfully undertaken by a true spacefaring nation. The United States is not there yet because, as the US National Space Policy emphasizes, we have not yet developed the “robust, effective, and efficient space capabilities” needed for America to effectively utilize space this century. Planning and executing a rational US energy policy that undertakes the development of SSP will jump-start America on the path to acquiring the mastery of industrial space operations we need to become a true spacefaring nation. This path will follow our nation’s hard-earned success, as seafarers and aviators, of building a world-leading maritime industry in the 18th and 19th centuries and an aviation industry in the 20th century. With this new spacefaring mastery, today’s dreams of expanded human and robotic exploration of space, of humans on Mars, of space colonies, of lunar settlements, and so on, will all move from the realm of wishful daydreams into an exciting future of actionable possibilities. The goal of nearly all American pro-space organizations is to make such a future a reality. Energetically supporting the incorporation of SSP into US energy planning and strongly advocating for the start of the development of SSP is how pro-space organizations can now take action to make their vision part of America’s broad-based spacefaring future. This is, indeed, a win-win opportunity that we cannot afford to miss.

All tech is within reach


Lemonick 09 (Michael, senior writer at Climate Central, Yale Environment 360, Solar Power from Space: Moving Beyond Science Fiction, http://e360.yale.edu/content/feature.msp?id=2184, JG)
Several other companies have announced their intentions to put up solar satellites of their own. Doubts abound that space-based solar power will come to pass anytime soon, and for good reason: The technology involves launching a series of large satellites into space, using robotic technology to assemble the solar arrays, transmitting the energy 22,000 miles to earth using microwave technology, and then converting that energy to electricity on the ground. The fact is, however, that all of that is now feasible — if pricey — thanks to technological advances in recent years. These include cheaper and more reliable launch technology, lighter and stronger materials for solar stations, significant improvements in the robotic technology needed to assemble the solar arrays, far more efficient solar cells, more precise digital devices to direct that energy accurately to earth, and significantly smaller and more powerful microwave transmitters and receivers. The big question is whether this engineering feat can be pulled off at a price competitive with terrestrial solar power. So far, the Pentagon’s estimate of what it will cost — $10 billion to put a 10-megawatt experimental solar station in orbit by 2016 — is five times higher than Solaren’s and would produce far less power.

We have the tech & we would be able to run/create SSP from space


NSS 07 (National Space Society, Space Solar Power Limitless clean energy from space, About Space Solar Power (SSP, also known as Space-Based Solar Power, or SBSP):, http://www.nss.org/settlement/ssp/, JG)
All of these technologies are reasonably near-term and have multiple attractive approaches. However, a great deal of work is needed to bring them to practical fruition. In the longer term, with sufficient investments in space infrastructure, space solar power can be built from materials from space. The full environmental benefits of space solar power derive from doing most of the work outside of Earth's biosphere. With materials extraction from the Moon or near-Earth asteroids, and space-based manufacture of components, space solar power would have essentially zero terrestrial environmental impact. Only the energy receivers need be built on Earth. Space solar power can completely solve our energy problems long term. The sooner we start and the harder we work, the shorter "long term" will be.


We have the tech – Testing, Engineering and Safety Principles


Snead 09 (James M, The Space Review, The End of Easy Energy and What to Do About It, pdf, JG)
The intent of this overview of the potential of space solar power was to indicate that the physics and basic engineering principles of the design, construction, and use of space solar power are understood and have been demonstrated and that the basic safety aspects of power transmission have been investigated with acceptable preliminary findings. The brevity of this overview, however, should not be taken to indicate that developing and constructing a network of hundreds, potentially thousands, of massive SSP platforms in GEO will be easy and quick or that further in-depth safety, environmental, and operational impact investigations are not needed. Just the opposite is true. Hence, pursuing SSP will need to involve:



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