Is the US Space Force Researching Space-Based Solar Power? (cleantechnica.com) 38
The "technology building blocks" for space solar are already available, reports Clean Technica. "It's just a matter of scaling, systems integration, and adjustments for space-hardiness."
And several groups are looking at it — including the U.S. Space Force To help push costs down, the California Institute of Technology has proposed a sandwich-type solar module that integrates solar harvesting along with conversion to a radio frequency into one compact package, accompanied by a built-in antenna. Last month researchers at the school wrapped up a months-long, in-space test of different types of solar cells. Another approach is illustrated by the Michigan startup Virtus Solis, an industry partner of the University of Bristol. Last June the company and the school received £3.3 million in funding from the UK Net Zero Innovation program, for developing an open-source model for testing the performance of large, centralized antennas in space. "The concept depends upon the use of gigascale antenna arrays capable of delivering over 2GW of power from space onto similar gigascale antenna arrays either at sea or on the ground," the school explained.
As for how such a thing would be launched into space, that's where the U.S. Space Force comes in. Last August, the Space Force awarded a small business contract to the U.S. startup Orbital Composites. The company is tasked with the mission of developing its patented "quantum antenna" and in-space fabrication tools for secure communications in space applications, including space-to-space as well as space-to-Earth and vice versa. The basic idea is to let 3D printing doing much of the work in space. According to Orbital, in-space fabrication would save more than 100 times the cost of applying conventional fabrication methods to large-scale orbiting antennas. "By harnessing the potential of In-Space Servicing, Assembly, and Manufacturing (ISAM), the company eyes the prospect of creating significantly larger space antennas," Orbital Composites explains. "By fabricating antennas in space, larger and more complex designs are possible that eliminate the constraints of launch and rocket fairings...."
If you're guessing that a hookup between Virtus and Orbital is in the works, that's a good guess. On February 1, at the SpaceCOM conference in Orlando, Florida, Virtus Solis let slip that it is working with Orbital Composites on a space solar pilot project. If all goes according to plan, the project will be up and running in 2027, deploying Virtus's robot-enabled fabrication system with Orbital's 3D printing. As of this writing the two companies have not posted details, but Space News picked up the thread. "The 2027 mission is designed to showcase critical power-generation technologies including in-space assembly of solar panels and transmission of more than one kilowatt to Earth," Space News explained. "The news release calls the 2027 mission "a precursor to large-scale commercial megawatt-class solar installations in space by 2030...."
To be clear, Orbital's press release about its new Space Force quantum antenna contract does not mention anything in particular about space solar. However, the pieces of the puzzle fit. Along with the Virtus and Grumman connections, in October of 2022 Orbital won a small business contract through SpaceWERX, the Space Force's innovative technologies funding arm, to explore the capabilities of ISAM systems.
"SpaceWERX comes under the umbrella of the U.S. Air Force's AFWERX innovation branch, which has developed a program called SSPIDR, short for Space Solar Power Incremental Demonstrations and Research Project," the article points out. (While Virtus believes most space-based solar power systems could deliver megawatt hours of electricity at prices comparable to today's market.)
And several groups are looking at it — including the U.S. Space Force To help push costs down, the California Institute of Technology has proposed a sandwich-type solar module that integrates solar harvesting along with conversion to a radio frequency into one compact package, accompanied by a built-in antenna. Last month researchers at the school wrapped up a months-long, in-space test of different types of solar cells. Another approach is illustrated by the Michigan startup Virtus Solis, an industry partner of the University of Bristol. Last June the company and the school received £3.3 million in funding from the UK Net Zero Innovation program, for developing an open-source model for testing the performance of large, centralized antennas in space. "The concept depends upon the use of gigascale antenna arrays capable of delivering over 2GW of power from space onto similar gigascale antenna arrays either at sea or on the ground," the school explained.
As for how such a thing would be launched into space, that's where the U.S. Space Force comes in. Last August, the Space Force awarded a small business contract to the U.S. startup Orbital Composites. The company is tasked with the mission of developing its patented "quantum antenna" and in-space fabrication tools for secure communications in space applications, including space-to-space as well as space-to-Earth and vice versa. The basic idea is to let 3D printing doing much of the work in space. According to Orbital, in-space fabrication would save more than 100 times the cost of applying conventional fabrication methods to large-scale orbiting antennas. "By harnessing the potential of In-Space Servicing, Assembly, and Manufacturing (ISAM), the company eyes the prospect of creating significantly larger space antennas," Orbital Composites explains. "By fabricating antennas in space, larger and more complex designs are possible that eliminate the constraints of launch and rocket fairings...."
If you're guessing that a hookup between Virtus and Orbital is in the works, that's a good guess. On February 1, at the SpaceCOM conference in Orlando, Florida, Virtus Solis let slip that it is working with Orbital Composites on a space solar pilot project. If all goes according to plan, the project will be up and running in 2027, deploying Virtus's robot-enabled fabrication system with Orbital's 3D printing. As of this writing the two companies have not posted details, but Space News picked up the thread. "The 2027 mission is designed to showcase critical power-generation technologies including in-space assembly of solar panels and transmission of more than one kilowatt to Earth," Space News explained. "The news release calls the 2027 mission "a precursor to large-scale commercial megawatt-class solar installations in space by 2030...."
To be clear, Orbital's press release about its new Space Force quantum antenna contract does not mention anything in particular about space solar. However, the pieces of the puzzle fit. Along with the Virtus and Grumman connections, in October of 2022 Orbital won a small business contract through SpaceWERX, the Space Force's innovative technologies funding arm, to explore the capabilities of ISAM systems.
"SpaceWERX comes under the umbrella of the U.S. Air Force's AFWERX innovation branch, which has developed a program called SSPIDR, short for Space Solar Power Incremental Demonstrations and Research Project," the article points out. (While Virtus believes most space-based solar power systems could deliver megawatt hours of electricity at prices comparable to today's market.)
Yes they are (Score:5, Interesting)
Re: Yes they are (Score:2)
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60k per kilogram launched
Except STS got retired twelve years ago already.
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And replaced by cheaper stuff. Falcon 9 has been launching for over a decade and is under $3k a kilo.
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And replaced by cheaper stuff. Falcon 9 has been launching for over a decade and is under $3k a kilo.
Falcon-9 published launch cost is 67 million dollars per launch, to low Earth orbit. So the original statement, "tens of millions," seems accurate.
...except you're not going to put up a space power system on a single Falcon 9 launch.
Ref: https://www.cnbc.com/2022/03/2... [cnbc.com]
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Falcon-9 published launch cost is 67 million dollars per launch, to low Earth orbit. So the original statement, "tens of millions," seems accurate. ...except you're not going to put up a space power system on a single Falcon 9 launch.
The Falcon Heavy is even cheaper per kilogram to orbit.
If you're measuring per kilo, then we already know you're charging drug-dealer rates.
STFU about being "cheaper" already.
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SpaceX has it down to about $5,500 per kilo.
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I don't think this is for use on Earth. But power for space missions is always one of the critical features, and we're low on the proper Plutonium isotopes.
Whether, and where, this will be practical is another matter.
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Less than 1% efficiency? Really? Links, please, to the evidence of this.
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Recently re-watched Real Genius [wikipedia.org] did ya? :-)
No, they are not. (Score:3)
The US Space Force is not researching space based solar power. The math has been gone over many times before and we are a long way from having the technology to make it work, certainly not to make it cheaper than some alternative. This would be double for the military, people that aren't afraid of using a nuclear power plant, and would not be held to the same regulations that drive up costs on civil nuclear power.
I can think up a lot of things they could be working on while using space based solar power as cover. It could be directed energy weapons. Maybe not something that can make things "go boom" but could melt the propellers on UAVs, disrupt radar/sensors/communications/etc., blow out tires, or cause other damage that isn't a strict "kill" but leave them unable to put up much of a fight. Think of this like a 25 mike-mike on a Bradley FV up against a battle tank. The Bradley isn't likely to penetrate the armor but it could bust up the view ports and knock off a track. That tank is now blind and hobbled, this leaves the tank unable to give chase to a fleeing Bradley and/or leave it immobile to buy time for a kill once reinforcements arrive.
Maybe the USSF is working on power systems for satellites, space stations, and or craft to deep space. A kind of demonstration they can build a bigger solar array than anything before.
Maybe this is some kind of beam-powered propulsion. https://en.wikipedia.org/wiki/... [wikipedia.org]
With a big antenna in space pointed at Earth this could be for receiving than transmitting. This could be for picking up weaker signals on the ground. Maybe it does transmit but with a narrower beam than attempted before. Maybe for communications to the moon, Mars, or beyond.
All kinds of things could be going on. What is not going on is beaming solar power down to Earth, I'm quite certain about that.
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The US military spends a massive chunk of its budget transporting kerosene from one place to another. Often that kerosene is burned to produce electricity.
Space based solar power is cheaper than flying kerosene to a generator. So yes, it could be useful to the US military.
Nope. (Score:2)
>> Space based solar power is cheaper than flying kerosene to a generator.
HAHAHA. Nope.
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I don't disagree that it could be cheaper. Or that it could result in fewer casualities. But until it's actually been demonstrated and deployed, I would steer clear from such definitive assertions.
Or, put differently, [citation needed].
No, they do NOT give a fuck. (Score:2)
The US Military does not give one flying fuck about being "cheaper" or "green". See exemptions for proof.
Any space-based solar power savings will be shot out of a machine gun barrel in some "just" war, because rare earth minerals.
Stop deluding yourself and others with the government sales pitch.
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"Space based solar power is cheaper than flying kerosene to a generator. So yes, it could be useful to the US military."
Especially since you don't even need soldiers on the ground, you can just cook the enemy.
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The US Space Force is not researching space based solar power.
In fact, though, they are.
Do keep in mind, however, that researching space-based solar power is not the same as implementing space based solar power
Bond villians (Score:2)
Have two Bond movies been insufficient to show the obvious danger of such a deployment?
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Aww... come on. Solar death rays are cool! Stop trying to hold back progress!
Microwaves vs flow-in diesel (Score:2)
They're not serious yet (Score:2)
Space based solar power collection, converted to microwaves and beamed to a terrestrial rectenna farm is possible but difficult and currently with questionable economics. ...saying you will save money by 3D printing the solar array in orbit just sets off the bullshit alarms. The base mass you need to lift is the same, plus the manufacturing hardware, plus the technology doesn't exist yet.
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Think about all the whining and complaining about shredded birds and windfarms. Think about the complaints over fried birds at heliostat sites. Can you guess the reaction to microwaves frying things on the ground? IMHO, this idea is infeasible. Local pebble bed reactors or thorium reactors are a better solution. Both have issues, but I believe both are more easily solved and cheaper to implement.
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The energy density over the receiving rectenna farm wouldn't be enough to fry anything.
Nobody designing and promoting this system as an energy source has forgotten to do the math to ensure they aren't creating death rays from space. I'm a little surprised at how many people think the people smart and educated enough to come up with the concept would somehow overlook that.
"Hey, let's beam massive amounts of energy down from space and not look at the beam properties or for potential deleterious effects" is n
Ah, stop yer bitching about the military (Score:2)
The idea of beaming space-based solar back to earth has popped up in SciFi more than once. It works in novels. They gave it to the air force to mess with because the idea _isn't_ feasible. They don't want to tie up the high-energy labs that _do_ have a shot at actually producing cheaper power.
Space power works !!! (Score:2)
>> the idea of beaming space-based solar back to earth has popped up in SciFi more than once.
Nope. It works well in fact.
My personnal space power reception array gets a few picowatts of power, and feeds that power signal right into the LNA of my LCD-based gizmo which displays a picture as a result.
Space power works !!!
Space Force is a parody of itself, waste of money (Score:2)