- published: 22 Aug 2011
- views: 7399
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As part of ConnectEd's "Day in the Life" series, we interview Veronica Navarro, a Satellite Operations Engineer at Space Systems/Loral. Her duties include monitoring the health of a satellite prior to and during its launch into space.
Explore more career videos at http://connectedstudios.org/life_videos
Follow us on Facebook! https://facebook.com/connectedstudios
We thank you for your support: http://www.AzimuthalEquidistant.org "...more and more Professional Engineers, Lawyers, Airline Pilots, Navigators, Surveyors, etc. are waking up and becoming proponents for flat earth.
The All Seeing Heart thinks that it is reassuring, inspiring, and natural; after all, not unlike nature, deep down all we really want to do is grow."
Brian Mullin said it best, "...think about all this!"
Shared from Channel: Brian Mullin
Series: Balls Out Physics
Episode: 4.0, The ISS, Satellites, and the Thermosphere
Channel URL: https://www.youtube.com/channel/UCArBP0HP6aYpSVQQ4YbuYqQ
- published: 09 Jul 2016
- views: 22466
Space Systems Engineer Stefanie Kohl leads us around the satellite assembly and testing facilities at Surrey Satellite Technology Ltd, and provides us with a glimpse of her daily life in what she regards as a complex but highly enjoyable role as a satellite engineer.
- published: 09 Nov 2012
- views: 1569
How do you send satellites into space? Boeing engineer, Keith Watts, helps make sure satellites can be packed as small as possible or expanded out, depending on what is needed. Keith has to think about all the different sizes and configurations that the satellite will have to be, known as dynamic constraints. The satellite Keith builds has to be small enough to fit into the nose of the rocket to send into space. But once in space, the satellite leaves the rocket and has to find its own power source, the sun! The satellite must deploy giant solar arrays to get energy from the sun, as well as its antennae to send and receive messages.
Visit us at http://www.curiositymachine.org to build design challenges and explore more science and engineering at home!
- published: 13 Jul 2015
- views: 755
Origami is a source of inspiration for BYU mechanical engineers who are working with the National Science Foundation, NASA/JPL and origami master Robert Lang to design complaint mechanisms for use in space and in other applications.
(Video produced by BYU News. Producer Julie Walker, Photographer Brian Wilcox, Editor Samuel Reimer. Additional images provided by NASA/JPL, langorigami.com, BYU Compliant Mechanisms Research Group, Matthew Gong, and Carrie Henzie (Redpath Museum).
See more about BYU space research and collaborations with origami master Robert Lang at http://bit.ly/17WMdRX
BYU engineers turn to origami to solve astronomical space problem; Partnership with NASA could send origami to the final frontier
BYU engineers have teamed up with a world-renown origami expert to solve one of space exploration's greatest (and ironic) problems: lack of space.
Working with NASA's Jet Propulsion Laboratory, a team of mechanical engineering students and faculty have designed a solar array that can be tightly compacted for launch and then deployed in space to generate power for space stations or satellites.
Applying origami principles on rigid silicon solar panels -- a material considerably thicker than the paper used for the traditional Japanese art -- the BYU-conceived solar array would unfold to nearly 10 times its stored size.
"It's expensive and difficult to get things into space; you're very constrained in space," said BYU professor and research team leader Larry Howell. "With origami you can make it compact for launch and then as you get into space it can deploy and be large."
The current project, detailed in the November issue of the Journal of Mechanical Design, is propelled by collaboration between BYU, NASA and origami expert Robert Lang. Howell reached out to Lang as part of landing a $2 million National Science Foundation grant in 2012 to explore the combination of origami and compliant mechanisms. (Joint-less, elastic structures that use flexibility to create movement.)
BYU was already working with NASA through the Jet Propulsion Lab, where grad student Shannon Zirbel has been instrumental in the project. The research team plans to work together for several more years on various projects, but hopes NASA can put their work to good use before they're through.
"It's hard to predict what the greatest outcome of this collaboration will be, but it would be a great success if a solar array based on our concept flew on a NASA mission," Lang said.
The particular solar array developed by the group can be folded tightly down to a diameter of 2.7 meters and unfolded to its full size of 25 meters across. The goal is to create an array that can produce 250 kilowatts of power. Currently, the International Space Station has eight solar arrays that generate 84 kilowatts of energy.
Howell said origami through compliant mechanisms is a perfect fit for space exploration: It is low cost and the materials can handle harsh solar environments.
"Space is a great place for a solar panel because you don't have to worry about nighttime and there are no clouds and no weather," he said. "Origami could also be used for antennas, solar sails and even expandable nets used to catch asteroids."
The research team has already looked beyond the final frontier for origami applications in engineering. Some applications Howell said may be possible include:
Stents or implants that can be inserted through small incisions before expanding inside the body
Phones that can be compact when you're not using them and then unfold for use
Deployable housing or shelters that can be shipped or parachuted compactly and then expanded for emergency use
"If we can extend the knowledge of origami artists to work in materials beyond paper, it will lead to powerful systems with unprecedented performance," Howell said. "We will do things no one has ever done before."
- published: 27 Nov 2013
- views: 116754
When Boeing engineer Keith Watts designs and builds a satellite, he has to think how the satellite will be packaged in different sizes. A satellite needs to be small when its sent into space inside a rocket, but once in space, the solar arrays and antennae must be easily opened. The solar arrays are used to catch the sun's energy, so they need to be very large to let the satellite send important messages through its antennae. In order to fit these dynamic constraints, Keith has to make solar arrays and antennae that can fold up and deployed quickly using latches. Some of them even use controlled explosions!
Visit the http://www.curiositymachine.org to build and deploy your very own satellite!
- published: 13 Jul 2015
- views: 453
Thanks for watching! I actually had an early version of this ready last week. Which you can watch here on my second channel:
https://www.youtube.com/watch?v=x9B0xCm87xI
I decided, with the help of my Patreon supporters, that it wasn't good enough. Have a few ideas for my next video. Space X is winning right now. What do you think? I may try to work on two videos at once this week.
Woops forgot the math:
The equation is a=(w^2)*r where a is the acceleration, w is the angular velocity and r is the radius.
First we must convert RPM to radians per second. There is 2(pi) radians per revolution and 60 seconds in a minute. So one RPM equals 2(pi)/60. We then simply enter these values into the equation. For our first calculation on space station v we get a=(0.1047)^2*150=1.65 ms^-2
Patreon:
https://www.patreon.com/user?u=2825050&ty;=h
Facebook:
http://facebook.com/realengineering1
Instagram:
https://www.instagram.com/real.engineering
Twitter:
https://twitter.com/Fiosracht
Once again thanks to Bensound.com for the amazing royalty free music. This time I used Bensound - New Dawn
- published: 29 Jun 2016
- views: 606159
In the history of space, one rocket stands out as an icon of not only the space race but of the mighty power it symbolised.
That one rocket, which is still the Tallest, heaviest and most powerful ever built, was the Saturn V, which was designed to take men to the moon and later launched the first American Space station, Skylab.
But if things had been a little different back in the 60’s we might have had a different rocket to hang on the bedroom walls of the space fans of the 70’s and 80’s.
In the early 1960’s, a rocket was designed which made the Saturn V look small comparison.
This was the Sea Dragon, a super heavy lift rocket that would have been 10 times more powerful with 80 Million lb’s of thrust compared to the Saturn’s 7.8 million and that was from just one massive engine.
It was designed to lift a payload of 1,100,000 lbs into orbit, compared to the 310,000 lbs of the Saturn V. This meant it could have lifted an entire space station into Low Earth Orbit in one mission.
The rocket bell of this single engine would be so large at 75 feet in diameter, that you could fit the entire first stage of a Saturn V with all 5 of its F1 engines inside with room to spare.
So what happened to the Sea Dragon and why didn’t it get built ?.
At the time of the design in 1962, it was thought that by the 1970’s, 80’s and beyond, thousands of people would be working in space and on the moon, even on Mars and as such, rockets with huge lifting capabilities would have been in great demand as they would dramatically lower the cost of getting materials into space.
The sea dragon was designed by Robert Truax, a US navy Captain and Rocket engineer. He was one of the pioneers of American rocketry and worked on the Thor and Polaris missiles amongst others. His team debriefed the German Rocket engineers at the end of World War 2 including Werner Von Braun who went on to design the Saturn V.
Traux believed it was complexity that drove up the cost of rockets and not their size. His designs for the Sea Dragon were very simple but very big. The sea dragon would have been 75 ft in diameter and 500ft tall, half the Hight of Chrysler building.
This type of low-cost super heavy rocket is now known as a “big dumb booster” due to its simplistic design.
Instead of having very complicated turbopump driven engine like the Saturn’s, his were the simplest possible design for a rocket engine.
In place of having powerful fuel pumps to push the huge amounts of rocket fuel and oxidizer in the engine, he proposed a pressure fed system with a separate liquid nitrogen tank to pressurise the fuel tanks, this would push the fuel into the massive combustion chamber.
His engines were literally not much more than the valves to turn on the fuel and the huge engine bell, this would make them not only much cheaper to manufacture but much easier to refurbish and reuse, unlike the F1 engines of the Saturn which were left crash in the sea and be discarded.
The rocket would be a two-stage design, the first stage would lift it to a height of 130,000 ft before it separated and fell back into the sea, using drag bags to slow it impacts with the water, where it would be recovered for reuse.
Although it’s design was much less efficient that of the Saturn, the overall increase in size made up for the short fall, so in theory it would be much cheaper per pound of payload compared to smaller rocket systems, even ones the size of the Saturn.
However, there were problems of making such a huge rocket, firstly just transporting the parts, let alone the fully assembled version, this together with the 80 million lbs of thrust meant that it could not be launched from land.
This amount of thrust would have destroyed any existing launch pad. It’s estimated that the noise level at take-off would have been around 165 decibels at 5 miles away or the equivalent of standing next to 5000 hp top fuel dragster at full throttle.
Then there is the exhaust plume, this would have been up to 1 mile long. For these reasons, the Sea Dragon would have had be launched at sea, hence the name, not from a floating platform but from beneath the water.
This is not mad as it seems and there have been examples of sea-launched rockets before and after.
In 2002 a low-cost sea-launched rocket delivery system called the Aquarius with a very similar design the Sea Dragon but much smaller was proposed to deliver consumables in to Low earth orbit for supplying things like the space station but failed to get selected.
The US Navy also did research in to floating launch rockets and found that the take-off was smoother and less stressful on the rocket than that of a normal land based take off.
And if you wondering why the water didn’t put out the flames, it’s because the rocket has it own liquid oxygen supply just like rockets that work in space where there is no air and the thrust just blows the water out of the engine bell.
- published: 02 Apr 2017
- views: 5469
Satellite
In the context of spaceflight, a satellite is an artificial object which has been intentionally placed into orbit. Such objects are sometimes called artificial satellites to distinguish them from natural satellites such as Earth's Moon.
The world's first artificial satellite, the Sputnik 1, was launched by the Soviet Union in 1957. Since then, thousands of satellites have been launched into orbit around the Earth. Some satellites, notably space stations, have been launched in parts and assembled in orbit. Artificial satellites originate from more than 40 countries and have used the satellite launching capabilities of ten nations. About a thousand satellites are currently operational, whereas thousands of unused satellites and satellite fragments orbit the Earth as space debris. A few space probes have been placed into orbit around other bodies and become artificial satellites to the Moon, Mercury, Venus, Mars, Jupiter, Saturn, Vesta, Eros, Ceres, and the Sun.
Satellites are used for a large number of purposes. Common types include military and civilian Earth observation satellites, communications satellites, navigation satellites, weather satellites, and research satellites. Space stations and human spacecraft in orbit are also satellites. Satellite orbits vary greatly, depending on the purpose of the satellite, and are classified in a number of ways. Well-known (overlapping) classes include low Earth orbit, polar orbit, and geostationary orbit.
This page contains text from Wikipedia, the Free Encyclopedia -
https://wn.com/Satellite
This article is licensed under the Creative Commons Attribution-ShareAlike 3.0 Unported License, which means that you can copy and modify it as long as the entire work (including additions) remains under this license.
This article is licensed under the Creative Commons Attribution-ShareAlike 3.0 Unported License, which means that you can copy and modify it as long as the entire work (including additions) remains under this license.
Sea Dragon
Sea Dragon may refer to:
Fish
Military
Other
See also
This page contains text from Wikipedia, the Free Encyclopedia -
https://wn.com/Sea_Dragon
This article is licensed under the Creative Commons Attribution-ShareAlike 3.0 Unported License, which means that you can copy and modify it as long as the entire work (including additions) remains under this license.
This article is licensed under the Creative Commons Attribution-ShareAlike 3.0 Unported License, which means that you can copy and modify it as long as the entire work (including additions) remains under this license.
SSL (company)
SSL, formerly Space Systems/Loral, LLC (SS/L), of Palo Alto, California, is a wholly owned manufacturing subsidiary of MacDonald Dettwiler and Associates (MDA). SSL designs and builds satellites and space systems for a wide variety of government and commercial customers. Its products include high-powered direct-to-home broadcast satellites, commercial weather satellites, digital audio radio satellites, Earth observation satellites and spot-beam satellites for data networking applications.
On June 26, 2012 SSL was acquired for $875 million by the Canadian aerospace company MacDonald Dettwiler (MDA). SSL was acquired in 1990 for $715 million by Loral Corp. from Ford Motor Company as the Space Systems Division of Ford Aerospace. The company was founded as the Western Development Laboratories (WDL) of Philco (Philco-Ford since 1966).
SSL's customers include AsiaSat, Bank Rakyat Indonesia (Persero) Tbk. (BRI), Broadcasting Satellite System Corporation, Bulgaria Sat (Bulsatcom), DirecTV, EchoStar, Eutelsat, Globalstar, Google's Skybox Imaging, Hispasat, Hughes Network Systems, ICO Global Communications, Intelsat, Japan MTSAT, JSC Gascom, Loral Skynet, NASA/NOAA (GOES), nbn, Optus, PanAmSat, Pasifik Satelit Nusantara (PSN), QuetzSat, Satmex, SES S.A., SES World Skies, Shin Satellite, Singtel, Sirius Satellite Radio, Sky Perfect JSAT Corporation, SpainSat, Star One, Telenor, Telesat Canada, Thaicom, ViaSat, WildBlue, and XM Satellite Radio.
This page contains text from Wikipedia, the Free Encyclopedia -
https://wn.com/SSL_(company)
This article is licensed under the Creative Commons Attribution-ShareAlike 3.0 Unported License, which means that you can copy and modify it as long as the entire work (including additions) remains under this license.
This article is licensed under the Creative Commons Attribution-ShareAlike 3.0 Unported License, which means that you can copy and modify it as long as the entire work (including additions) remains under this license.
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3:36Day in the Life: Satellite Operations Engineer
Day in the Life: Satellite Operations EngineerDay in the Life: Satellite Operations Engineer
As part of ConnectEd's "Day in the Life" series, we interview Veronica Navarro, a Satellite Operations Engineer at Space Systems/Loral. Her duties include monitoring the health of a satellite prior to and during its launch into space. Explore more career videos at http://connectedstudios.org/life_videos Follow us on Facebook! https://facebook.com/connectedstudios -
41:49Satellite Engineering
Satellite Engineering -
34:43Pro. Engineer Explains Problems with the ISS, Satellites & the Thermosphere. Flat Earth.
Pro. Engineer Explains Problems with the ISS, Satellites & the Thermosphere. Flat Earth.Pro. Engineer Explains Problems with the ISS, Satellites & the Thermosphere. Flat Earth.
We thank you for your support: http://www.AzimuthalEquidistant.org "...more and more Professional Engineers, Lawyers, Airline Pilots, Navigators, Surveyors, etc. are waking up and becoming proponents for flat earth. The All Seeing Heart thinks that it is reassuring, inspiring, and natural; after all, not unlike nature, deep down all we really want to do is grow." Brian Mullin said it best, "...think about all this!" Shared from Channel: Brian Mullin Series: Balls Out Physics Episode: 4.0, The ISS, Satellites, and the Thermosphere Channel URL: https://www.youtube.com/channel/UCArBP0HP6aYpSVQQ4YbuYqQ -
3:57Day in the Life of Stefanie Kohl -- Space Systems Engineer, Surrey Satellite Technology Ltd
Day in the Life of Stefanie Kohl -- Space Systems Engineer, Surrey Satellite Technology LtdDay in the Life of Stefanie Kohl -- Space Systems Engineer, Surrey Satellite Technology Ltd
Space Systems Engineer Stefanie Kohl leads us around the satellite assembly and testing facilities at Surrey Satellite Technology Ltd, and provides us with a glimpse of her daily life in what she regards as a complex but highly enjoyable role as a satellite engineer. -
3:15Packaging and Deployment of Boeing Satellites with Engineer Keith Watts
Packaging and Deployment of Boeing Satellites with Engineer Keith WattsPackaging and Deployment of Boeing Satellites with Engineer Keith Watts
How do you send satellites into space? Boeing engineer, Keith Watts, helps make sure satellites can be packed as small as possible or expanded out, depending on what is needed. Keith has to think about all the different sizes and configurations that the satellite will have to be, known as dynamic constraints. The satellite Keith builds has to be small enough to fit into the nose of the rocket to send into space. But once in space, the satellite leaves the rocket and has to find its own power source, the sun! The satellite must deploy giant solar arrays to get energy from the sun, as well as its antennae to send and receive messages. Visit us at http://www.curiositymachine.org to build design challenges and explore more science and engineering at home! -
3:21Origami in Space: BYU-designed solar arrays inspired by origami
Origami in Space: BYU-designed solar arrays inspired by origamiOrigami in Space: BYU-designed solar arrays inspired by origami
Origami is a source of inspiration for BYU mechanical engineers who are working with the National Science Foundation, NASA/JPL and origami master Robert Lang to design complaint mechanisms for use in space and in other applications. (Video produced by BYU News. Producer Julie Walker, Photographer Brian Wilcox, Editor Samuel Reimer. Additional images provided by NASA/JPL, langorigami.com, BYU Compliant Mechanisms Research Group, Matthew Gong, and Carrie Henzie (Redpath Museum). See more about BYU space research and collaborations with origami master Robert Lang at http://bit.ly/17WMdRX BYU engineers turn to origami to solve astronomical space problem; Partnership with NASA could send origami to the final frontier BYU engineers have teamed up with a world-renown origami expert to solve one of space exploration's greatest (and ironic) problems: lack of space. Working with NASA's Jet Propulsion Laboratory, a team of mechanical engineering students and faculty have designed a solar array that can be tightly compacted for launch and then deployed in space to generate power for space stations or satellites. Applying origami principles on rigid silicon solar panels -- a material considerably thicker than the paper used for the traditional Japanese art -- the BYU-conceived solar array would unfold to nearly 10 times its stored size. "It's expensive and difficult to get things into space; you're very constrained in space," said BYU professor and research team leader Larry Howell. "With origami you can make it compact for launch and then as you get into space it can deploy and be large." The current project, detailed in the November issue of the Journal of Mechanical Design, is propelled by collaboration between BYU, NASA and origami expert Robert Lang. Howell reached out to Lang as part of landing a $2 million National Science Foundation grant in 2012 to explore the combination of origami and compliant mechanisms. (Joint-less, elastic structures that use flexibility to create movement.) BYU was already working with NASA through the Jet Propulsion Lab, where grad student Shannon Zirbel has been instrumental in the project. The research team plans to work together for several more years on various projects, but hopes NASA can put their work to good use before they're through. "It's hard to predict what the greatest outcome of this collaboration will be, but it would be a great success if a solar array based on our concept flew on a NASA mission," Lang said. The particular solar array developed by the group can be folded tightly down to a diameter of 2.7 meters and unfolded to its full size of 25 meters across. The goal is to create an array that can produce 250 kilowatts of power. Currently, the International Space Station has eight solar arrays that generate 84 kilowatts of energy. Howell said origami through compliant mechanisms is a perfect fit for space exploration: It is low cost and the materials can handle harsh solar environments. "Space is a great place for a solar panel because you don't have to worry about nighttime and there are no clouds and no weather," he said. "Origami could also be used for antennas, solar sails and even expandable nets used to catch asteroids." The research team has already looked beyond the final frontier for origami applications in engineering. Some applications Howell said may be possible include: Stents or implants that can be inserted through small incisions before expanding inside the body Phones that can be compact when you're not using them and then unfold for use Deployable housing or shelters that can be shipped or parachuted compactly and then expanded for emergency use "If we can extend the knowledge of origami artists to work in materials beyond paper, it will lead to powerful systems with unprecedented performance," Howell said. "We will do things no one has ever done before." -
1:50Deploying Satellites with Boeing Engineer Keith Watts
Deploying Satellites with Boeing Engineer Keith WattsDeploying Satellites with Boeing Engineer Keith Watts
When Boeing engineer Keith Watts designs and builds a satellite, he has to think how the satellite will be packaged in different sizes. A satellite needs to be small when its sent into space inside a rocket, but once in space, the solar arrays and antennae must be easily opened. The solar arrays are used to catch the sun's energy, so they need to be very large to let the satellite send important messages through its antennae. In order to fit these dynamic constraints, Keith has to make solar arrays and antennae that can fold up and deployed quickly using latches. Some of them even use controlled explosions! Visit the http://www.curiositymachine.org to build and deploy your very own satellite! -
2:49Crazy Engineering: CubeSats
Crazy Engineering: CubeSats -
6:34Can We Create Artificial Gravity?
Can We Create Artificial Gravity?Can We Create Artificial Gravity?
Thanks for watching! I actually had an early version of this ready last week. Which you can watch here on my second channel: https://www.youtube.com/watch?v=x9B0xCm87xI I decided, with the help of my Patreon supporters, that it wasn't good enough. Have a few ideas for my next video. Space X is winning right now. What do you think? I may try to work on two videos at once this week. Woops forgot the math: The equation is a=(w^2)*r where a is the acceleration, w is the angular velocity and r is the radius. First we must convert RPM to radians per second. There is 2(pi) radians per revolution and 60 seconds in a minute. So one RPM equals 2(pi)/60. We then simply enter these values into the equation. For our first calculation on space station v we get a=(0.1047)^2*150=1.65 ms^-2 Patreon: https://www.patreon.com/user?u=2825050&ty;=h Facebook: http://facebook.com/realengineering1 Instagram: https://www.instagram.com/real.engineering Twitter: https://twitter.com/Fiosracht Once again thanks to Bensound.com for the amazing royalty free music. This time I used Bensound - New Dawn -
7:36The Biggest Rocket ever Designed? - The Sea Dragon
The Biggest Rocket ever Designed? - The Sea DragonThe Biggest Rocket ever Designed? - The Sea Dragon
In the history of space, one rocket stands out as an icon of not only the space race but of the mighty power it symbolised. That one rocket, which is still the Tallest, heaviest and most powerful ever built, was the Saturn V, which was designed to take men to the moon and later launched the first American Space station, Skylab. But if things had been a little different back in the 60’s we might have had a different rocket to hang on the bedroom walls of the space fans of the 70’s and 80’s. In the early 1960’s, a rocket was designed which made the Saturn V look small comparison. This was the Sea Dragon, a super heavy lift rocket that would have been 10 times more powerful with 80 Million lb’s of thrust compared to the Saturn’s 7.8 million and that was from just one massive engine. It was designed to lift a payload of 1,100,000 lbs into orbit, compared to the 310,000 lbs of the Saturn V. This meant it could have lifted an entire space station into Low Earth Orbit in one mission. The rocket bell of this single engine would be so large at 75 feet in diameter, that you could fit the entire first stage of a Saturn V with all 5 of its F1 engines inside with room to spare. So what happened to the Sea Dragon and why didn’t it get built ?. At the time of the design in 1962, it was thought that by the 1970’s, 80’s and beyond, thousands of people would be working in space and on the moon, even on Mars and as such, rockets with huge lifting capabilities would have been in great demand as they would dramatically lower the cost of getting materials into space. The sea dragon was designed by Robert Truax, a US navy Captain and Rocket engineer. He was one of the pioneers of American rocketry and worked on the Thor and Polaris missiles amongst others. His team debriefed the German Rocket engineers at the end of World War 2 including Werner Von Braun who went on to design the Saturn V. Traux believed it was complexity that drove up the cost of rockets and not their size. His designs for the Sea Dragon were very simple but very big. The sea dragon would have been 75 ft in diameter and 500ft tall, half the Hight of Chrysler building. This type of low-cost super heavy rocket is now known as a “big dumb booster” due to its simplistic design. Instead of having very complicated turbopump driven engine like the Saturn’s, his were the simplest possible design for a rocket engine. In place of having powerful fuel pumps to push the huge amounts of rocket fuel and oxidizer in the engine, he proposed a pressure fed system with a separate liquid nitrogen tank to pressurise the fuel tanks, this would push the fuel into the massive combustion chamber. His engines were literally not much more than the valves to turn on the fuel and the huge engine bell, this would make them not only much cheaper to manufacture but much easier to refurbish and reuse, unlike the F1 engines of the Saturn which were left crash in the sea and be discarded. The rocket would be a two-stage design, the first stage would lift it to a height of 130,000 ft before it separated and fell back into the sea, using drag bags to slow it impacts with the water, where it would be recovered for reuse. Although it’s design was much less efficient that of the Saturn, the overall increase in size made up for the short fall, so in theory it would be much cheaper per pound of payload compared to smaller rocket systems, even ones the size of the Saturn. However, there were problems of making such a huge rocket, firstly just transporting the parts, let alone the fully assembled version, this together with the 80 million lbs of thrust meant that it could not be launched from land. This amount of thrust would have destroyed any existing launch pad. It’s estimated that the noise level at take-off would have been around 165 decibels at 5 miles away or the equivalent of standing next to 5000 hp top fuel dragster at full throttle. Then there is the exhaust plume, this would have been up to 1 mile long. For these reasons, the Sea Dragon would have had be launched at sea, hence the name, not from a floating platform but from beneath the water. This is not mad as it seems and there have been examples of sea-launched rockets before and after. In 2002 a low-cost sea-launched rocket delivery system called the Aquarius with a very similar design the Sea Dragon but much smaller was proposed to deliver consumables in to Low earth orbit for supplying things like the space station but failed to get selected. The US Navy also did research in to floating launch rockets and found that the take-off was smoother and less stressful on the rocket than that of a normal land based take off. And if you wondering why the water didn’t put out the flames, it’s because the rocket has it own liquid oxygen supply just like rockets that work in space where there is no air and the thrust just blows the water out of the engine bell.
-
Day in the Life: Satellite Operations Engineer
As part of ConnectEd's "Day in the Life" series, we interview Veronica Navarro, a Satellite Operations Engineer at Space Systems/Loral. Her duties include monitoring the health of a satellite prior to and during its launch into space. Explore more career videos at http://connectedstudios.org/life_videos Follow us on Facebook! https://facebook.com/connectedstudios
published: 22 Aug 2011 -
-
Pro. Engineer Explains Problems with the ISS, Satellites & the Thermosphere. Flat Earth.
We thank you for your support: http://www.AzimuthalEquidistant.org "...more and more Professional Engineers, Lawyers, Airline Pilots, Navigators, Surveyors, etc. are waking up and becoming proponents for flat earth. The All Seeing Heart thinks that it is reassuring, inspiring, and natural; after all, not unlike nature, deep down all we really want to do is grow." Brian Mullin said it best, "...think about all this!" Shared from Channel: Brian Mullin Series: Balls Out Physics Episode: 4.0, The ISS, Satellites, and the Thermosphere Channel URL: https://www.youtube.com/channel/UCArBP0HP6aYpSVQQ4YbuYqQ
published: 09 Jul 2016 -
Day in the Life of Stefanie Kohl -- Space Systems Engineer, Surrey Satellite Technology Ltd
Space Systems Engineer Stefanie Kohl leads us around the satellite assembly and testing facilities at Surrey Satellite Technology Ltd, and provides us with a glimpse of her daily life in what she regards as a complex but highly enjoyable role as a satellite engineer.
published: 09 Nov 2012 -
Packaging and Deployment of Boeing Satellites with Engineer Keith Watts
How do you send satellites into space? Boeing engineer, Keith Watts, helps make sure satellites can be packed as small as possible or expanded out, depending on what is needed. Keith has to think about all the different sizes and configurations that the satellite will have to be, known as dynamic constraints. The satellite Keith builds has to be small enough to fit into the nose of the rocket to send into space. But once in space, the satellite leaves the rocket and has to find its own power source, the sun! The satellite must deploy giant solar arrays to get energy from the sun, as well as its antennae to send and receive messages. Visit us at http://www.curiositymachine.org to build design challenges and explore more science and engineering at home!
published: 13 Jul 2015 -
Origami in Space: BYU-designed solar arrays inspired by origami
Origami is a source of inspiration for BYU mechanical engineers who are working with the National Science Foundation, NASA/JPL and origami master Robert Lang to design complaint mechanisms for use in space and in other applications. (Video produced by BYU News. Producer Julie Walker, Photographer Brian Wilcox, Editor Samuel Reimer. Additional images provided by NASA/JPL, langorigami.com, BYU Compliant Mechanisms Research Group, Matthew Gong, and Carrie Henzie (Redpath Museum). See more about BYU space research and collaborations with origami master Robert Lang at http://bit.ly/17WMdRX BYU engineers turn to origami to solve astronomical space problem; Partnership with NASA could send origami to the final frontier BYU engineers have teamed up with a world-renown origami expert to solve o...
published: 27 Nov 2013 -
Deploying Satellites with Boeing Engineer Keith Watts
When Boeing engineer Keith Watts designs and builds a satellite, he has to think how the satellite will be packaged in different sizes. A satellite needs to be small when its sent into space inside a rocket, but once in space, the solar arrays and antennae must be easily opened. The solar arrays are used to catch the sun's energy, so they need to be very large to let the satellite send important messages through its antennae. In order to fit these dynamic constraints, Keith has to make solar arrays and antennae that can fold up and deployed quickly using latches. Some of them even use controlled explosions! Visit the http://www.curiositymachine.org to build and deploy your very own satellite!
published: 13 Jul 2015 -
Crazy Engineering: CubeSats
Honey, I shrunk the satellites! Mini-satellites are following in the footsteps of cell phones and computers. CubeSats are small but highly capable of performing a variety of space missions. For more about our CubeSats, visit http://www.jpl.nasa.gov/cubesat/
published: 03 Dec 2015 -
Can We Create Artificial Gravity?
Thanks for watching! I actually had an early version of this ready last week. Which you can watch here on my second channel: https://www.youtube.com/watch?v=x9B0xCm87xI I decided, with the help of my Patreon supporters, that it wasn't good enough. Have a few ideas for my next video. Space X is winning right now. What do you think? I may try to work on two videos at once this week. Woops forgot the math: The equation is a=(w^2)*r where a is the acceleration, w is the angular velocity and r is the radius. First we must convert RPM to radians per second. There is 2(pi) radians per revolution and 60 seconds in a minute. So one RPM equals 2(pi)/60. We then simply enter these values into the equation. For our first calculation on space station v we get a=(0.1047)^2*150=1.65 ms^-2 Patreon: h...
published: 29 Jun 2016 -
The Biggest Rocket ever Designed? - The Sea Dragon
In the history of space, one rocket stands out as an icon of not only the space race but of the mighty power it symbolised. That one rocket, which is still the Tallest, heaviest and most powerful ever built, was the Saturn V, which was designed to take men to the moon and later launched the first American Space station, Skylab. But if things had been a little different back in the 60’s we might have had a different rocket to hang on the bedroom walls of the space fans of the 70’s and 80’s. In the early 1960’s, a rocket was designed which made the Saturn V look small comparison. This was the Sea Dragon, a super heavy lift rocket that would have been 10 times more powerful with 80 Million lb’s of thrust compared to the Saturn’s 7.8 million and that was from just one massive engine. It was ...
published: 02 Apr 2017
Day in the Life: Satellite Operations Engineer
- Order: Reorder
- Duration: 3:36
- Updated: 22 Aug 2011
- views: 7399
As part of ConnectEd's "Day in the Life" series, we interview Veronica Navarro, a Satellite Operations Engineer at Space Systems/Loral. Her duties include monit...
As part of ConnectEd's "Day in the Life" series, we interview Veronica Navarro, a Satellite Operations Engineer at Space Systems/Loral. Her duties include monitoring the health of a satellite prior to and during its launch into space.
Explore more career videos at http://connectedstudios.org/life_videos
Follow us on Facebook! https://facebook.com/connectedstudios
https://wn.com/Day_In_The_Life_Satellite_Operations_Engineer
As part of ConnectEd's "Day in the Life" series, we interview Veronica Navarro, a Satellite Operations Engineer at Space Systems/Loral. Her duties include monitoring the health of a satellite prior to and during its launch into space.
Explore more career videos at http://connectedstudios.org/life_videos
Follow us on Facebook! https://facebook.com/connectedstudios
- published: 22 Aug 2011
- views: 7399
Satellite Engineering
- Order: Reorder
- Duration: 41:49
- Updated: 28 Oct 2013
- views: 6856
Lecture: Satellite Engineering
Julien Tallineau - Physics and Space System Engineer, QinetiQ Space nv
Lecture: Satellite Engineering
Julien Tallineau - Physics and Space System Engineer, QinetiQ Space nv
https://wn.com/Satellite_Engineering
Pro. Engineer Explains Problems with the ISS, Satellites & the Thermosphere. Flat Earth.
- Order: Reorder
- Duration: 34:43
- Updated: 09 Jul 2016
- views: 22466
We thank you for your support: http://www.AzimuthalEquidistant.org "...more and more Professional Engineers, Lawyers, Airline Pilots, Navigators, Surveyors, e...
We thank you for your support: http://www.AzimuthalEquidistant.org "...more and more Professional Engineers, Lawyers, Airline Pilots, Navigators, Surveyors, etc. are waking up and becoming proponents for flat earth.
The All Seeing Heart thinks that it is reassuring, inspiring, and natural; after all, not unlike nature, deep down all we really want to do is grow."
Brian Mullin said it best, "...think about all this!"
Shared from Channel: Brian Mullin
Series: Balls Out Physics
Episode: 4.0, The ISS, Satellites, and the Thermosphere
Channel URL: https://www.youtube.com/channel/UCArBP0HP6aYpSVQQ4YbuYqQ
https://wn.com/Pro._Engineer_Explains_Problems_With_The_Iss,_Satellites_The_Thermosphere._Flat_Earth.
We thank you for your support: http://www.AzimuthalEquidistant.org "...more and more Professional Engineers, Lawyers, Airline Pilots, Navigators, Surveyors, etc. are waking up and becoming proponents for flat earth.
The All Seeing Heart thinks that it is reassuring, inspiring, and natural; after all, not unlike nature, deep down all we really want to do is grow."
Brian Mullin said it best, "...think about all this!"
Shared from Channel: Brian Mullin
Series: Balls Out Physics
Episode: 4.0, The ISS, Satellites, and the Thermosphere
Channel URL: https://www.youtube.com/channel/UCArBP0HP6aYpSVQQ4YbuYqQ
- published: 09 Jul 2016
- views: 22466
Day in the Life of Stefanie Kohl -- Space Systems Engineer, Surrey Satellite Technology Ltd
- Order: Reorder
- Duration: 3:57
- Updated: 09 Nov 2012
- views: 1569
Space Systems Engineer Stefanie Kohl leads us around the satellite assembly and testing facilities at Surrey Satellite Technology Ltd, and provides us with a gl...
Space Systems Engineer Stefanie Kohl leads us around the satellite assembly and testing facilities at Surrey Satellite Technology Ltd, and provides us with a glimpse of her daily life in what she regards as a complex but highly enjoyable role as a satellite engineer.
https://wn.com/Day_In_The_Life_Of_Stefanie_Kohl_Space_Systems_Engineer,_Surrey_Satellite_Technology_Ltd
Space Systems Engineer Stefanie Kohl leads us around the satellite assembly and testing facilities at Surrey Satellite Technology Ltd, and provides us with a glimpse of her daily life in what she regards as a complex but highly enjoyable role as a satellite engineer.
- published: 09 Nov 2012
- views: 1569
Packaging and Deployment of Boeing Satellites with Engineer Keith Watts
- Order: Reorder
- Duration: 3:15
- Updated: 13 Jul 2015
- views: 755
How do you send satellites into space? Boeing engineer, Keith Watts, helps make sure satellites can be packed as small as possible or expanded out, depending on...
How do you send satellites into space? Boeing engineer, Keith Watts, helps make sure satellites can be packed as small as possible or expanded out, depending on what is needed. Keith has to think about all the different sizes and configurations that the satellite will have to be, known as dynamic constraints. The satellite Keith builds has to be small enough to fit into the nose of the rocket to send into space. But once in space, the satellite leaves the rocket and has to find its own power source, the sun! The satellite must deploy giant solar arrays to get energy from the sun, as well as its antennae to send and receive messages.
Visit us at http://www.curiositymachine.org to build design challenges and explore more science and engineering at home!
https://wn.com/Packaging_And_Deployment_Of_Boeing_Satellites_With_Engineer_Keith_Watts
How do you send satellites into space? Boeing engineer, Keith Watts, helps make sure satellites can be packed as small as possible or expanded out, depending on what is needed. Keith has to think about all the different sizes and configurations that the satellite will have to be, known as dynamic constraints. The satellite Keith builds has to be small enough to fit into the nose of the rocket to send into space. But once in space, the satellite leaves the rocket and has to find its own power source, the sun! The satellite must deploy giant solar arrays to get energy from the sun, as well as its antennae to send and receive messages.
Visit us at http://www.curiositymachine.org to build design challenges and explore more science and engineering at home!
- published: 13 Jul 2015
- views: 755
Origami in Space: BYU-designed solar arrays inspired by origami
- Order: Reorder
- Duration: 3:21
- Updated: 27 Nov 2013
- views: 116754
Origami is a source of inspiration for BYU mechanical engineers who are working with the National Science Foundation, NASA/JPL and origami master Robert Lang to...
Origami is a source of inspiration for BYU mechanical engineers who are working with the National Science Foundation, NASA/JPL and origami master Robert Lang to design complaint mechanisms for use in space and in other applications.
(Video produced by BYU News. Producer Julie Walker, Photographer Brian Wilcox, Editor Samuel Reimer. Additional images provided by NASA/JPL, langorigami.com, BYU Compliant Mechanisms Research Group, Matthew Gong, and Carrie Henzie (Redpath Museum).
See more about BYU space research and collaborations with origami master Robert Lang at http://bit.ly/17WMdRX
BYU engineers turn to origami to solve astronomical space problem; Partnership with NASA could send origami to the final frontier
BYU engineers have teamed up with a world-renown origami expert to solve one of space exploration's greatest (and ironic) problems: lack of space.
Working with NASA's Jet Propulsion Laboratory, a team of mechanical engineering students and faculty have designed a solar array that can be tightly compacted for launch and then deployed in space to generate power for space stations or satellites.
Applying origami principles on rigid silicon solar panels -- a material considerably thicker than the paper used for the traditional Japanese art -- the BYU-conceived solar array would unfold to nearly 10 times its stored size.
"It's expensive and difficult to get things into space; you're very constrained in space," said BYU professor and research team leader Larry Howell. "With origami you can make it compact for launch and then as you get into space it can deploy and be large."
The current project, detailed in the November issue of the Journal of Mechanical Design, is propelled by collaboration between BYU, NASA and origami expert Robert Lang. Howell reached out to Lang as part of landing a $2 million National Science Foundation grant in 2012 to explore the combination of origami and compliant mechanisms. (Joint-less, elastic structures that use flexibility to create movement.)
BYU was already working with NASA through the Jet Propulsion Lab, where grad student Shannon Zirbel has been instrumental in the project. The research team plans to work together for several more years on various projects, but hopes NASA can put their work to good use before they're through.
"It's hard to predict what the greatest outcome of this collaboration will be, but it would be a great success if a solar array based on our concept flew on a NASA mission," Lang said.
The particular solar array developed by the group can be folded tightly down to a diameter of 2.7 meters and unfolded to its full size of 25 meters across. The goal is to create an array that can produce 250 kilowatts of power. Currently, the International Space Station has eight solar arrays that generate 84 kilowatts of energy.
Howell said origami through compliant mechanisms is a perfect fit for space exploration: It is low cost and the materials can handle harsh solar environments.
"Space is a great place for a solar panel because you don't have to worry about nighttime and there are no clouds and no weather," he said. "Origami could also be used for antennas, solar sails and even expandable nets used to catch asteroids."
The research team has already looked beyond the final frontier for origami applications in engineering. Some applications Howell said may be possible include:
Stents or implants that can be inserted through small incisions before expanding inside the body
Phones that can be compact when you're not using them and then unfold for use
Deployable housing or shelters that can be shipped or parachuted compactly and then expanded for emergency use
"If we can extend the knowledge of origami artists to work in materials beyond paper, it will lead to powerful systems with unprecedented performance," Howell said. "We will do things no one has ever done before."
https://wn.com/Origami_In_Space_Byu_Designed_Solar_Arrays_Inspired_By_Origami
Origami is a source of inspiration for BYU mechanical engineers who are working with the National Science Foundation, NASA/JPL and origami master Robert Lang to design complaint mechanisms for use in space and in other applications.
(Video produced by BYU News. Producer Julie Walker, Photographer Brian Wilcox, Editor Samuel Reimer. Additional images provided by NASA/JPL, langorigami.com, BYU Compliant Mechanisms Research Group, Matthew Gong, and Carrie Henzie (Redpath Museum).
See more about BYU space research and collaborations with origami master Robert Lang at http://bit.ly/17WMdRX
BYU engineers turn to origami to solve astronomical space problem; Partnership with NASA could send origami to the final frontier
BYU engineers have teamed up with a world-renown origami expert to solve one of space exploration's greatest (and ironic) problems: lack of space.
Working with NASA's Jet Propulsion Laboratory, a team of mechanical engineering students and faculty have designed a solar array that can be tightly compacted for launch and then deployed in space to generate power for space stations or satellites.
Applying origami principles on rigid silicon solar panels -- a material considerably thicker than the paper used for the traditional Japanese art -- the BYU-conceived solar array would unfold to nearly 10 times its stored size.
"It's expensive and difficult to get things into space; you're very constrained in space," said BYU professor and research team leader Larry Howell. "With origami you can make it compact for launch and then as you get into space it can deploy and be large."
The current project, detailed in the November issue of the Journal of Mechanical Design, is propelled by collaboration between BYU, NASA and origami expert Robert Lang. Howell reached out to Lang as part of landing a $2 million National Science Foundation grant in 2012 to explore the combination of origami and compliant mechanisms. (Joint-less, elastic structures that use flexibility to create movement.)
BYU was already working with NASA through the Jet Propulsion Lab, where grad student Shannon Zirbel has been instrumental in the project. The research team plans to work together for several more years on various projects, but hopes NASA can put their work to good use before they're through.
"It's hard to predict what the greatest outcome of this collaboration will be, but it would be a great success if a solar array based on our concept flew on a NASA mission," Lang said.
The particular solar array developed by the group can be folded tightly down to a diameter of 2.7 meters and unfolded to its full size of 25 meters across. The goal is to create an array that can produce 250 kilowatts of power. Currently, the International Space Station has eight solar arrays that generate 84 kilowatts of energy.
Howell said origami through compliant mechanisms is a perfect fit for space exploration: It is low cost and the materials can handle harsh solar environments.
"Space is a great place for a solar panel because you don't have to worry about nighttime and there are no clouds and no weather," he said. "Origami could also be used for antennas, solar sails and even expandable nets used to catch asteroids."
The research team has already looked beyond the final frontier for origami applications in engineering. Some applications Howell said may be possible include:
Stents or implants that can be inserted through small incisions before expanding inside the body
Phones that can be compact when you're not using them and then unfold for use
Deployable housing or shelters that can be shipped or parachuted compactly and then expanded for emergency use
"If we can extend the knowledge of origami artists to work in materials beyond paper, it will lead to powerful systems with unprecedented performance," Howell said. "We will do things no one has ever done before."
- published: 27 Nov 2013
- views: 116754
Deploying Satellites with Boeing Engineer Keith Watts
- Order: Reorder
- Duration: 1:50
- Updated: 13 Jul 2015
- views: 453
When Boeing engineer Keith Watts designs and builds a satellite, he has to think how the satellite will be packaged in different sizes. A satellite needs to be ...
When Boeing engineer Keith Watts designs and builds a satellite, he has to think how the satellite will be packaged in different sizes. A satellite needs to be small when its sent into space inside a rocket, but once in space, the solar arrays and antennae must be easily opened. The solar arrays are used to catch the sun's energy, so they need to be very large to let the satellite send important messages through its antennae. In order to fit these dynamic constraints, Keith has to make solar arrays and antennae that can fold up and deployed quickly using latches. Some of them even use controlled explosions!
Visit the http://www.curiositymachine.org to build and deploy your very own satellite!
https://wn.com/Deploying_Satellites_With_Boeing_Engineer_Keith_Watts
When Boeing engineer Keith Watts designs and builds a satellite, he has to think how the satellite will be packaged in different sizes. A satellite needs to be small when its sent into space inside a rocket, but once in space, the solar arrays and antennae must be easily opened. The solar arrays are used to catch the sun's energy, so they need to be very large to let the satellite send important messages through its antennae. In order to fit these dynamic constraints, Keith has to make solar arrays and antennae that can fold up and deployed quickly using latches. Some of them even use controlled explosions!
Visit the http://www.curiositymachine.org to build and deploy your very own satellite!
- published: 13 Jul 2015
- views: 453
Crazy Engineering: CubeSats
- Order: Reorder
- Duration: 2:49
- Updated: 03 Dec 2015
- views: 83456
Honey, I shrunk the satellites! Mini-satellites are following in the footsteps of cell phones and computers. CubeSats are small but highly capable of performing...
Honey, I shrunk the satellites! Mini-satellites are following in the footsteps of cell phones and computers. CubeSats are small but highly capable of performing a variety of space missions. For more about our CubeSats, visit http://www.jpl.nasa.gov/cubesat/
https://wn.com/Crazy_Engineering_Cubesats
Can We Create Artificial Gravity?
- Order: Reorder
- Duration: 6:34
- Updated: 29 Jun 2016
- views: 606159
Thanks for watching! I actually had an early version of this ready last week. Which you can watch here on my second channel:
https://www.youtube.com/watch?v=x9...
Thanks for watching! I actually had an early version of this ready last week. Which you can watch here on my second channel:
https://www.youtube.com/watch?v=x9B0xCm87xI
I decided, with the help of my Patreon supporters, that it wasn't good enough. Have a few ideas for my next video. Space X is winning right now. What do you think? I may try to work on two videos at once this week.
Woops forgot the math:
The equation is a=(w^2)*r where a is the acceleration, w is the angular velocity and r is the radius.
First we must convert RPM to radians per second. There is 2(pi) radians per revolution and 60 seconds in a minute. So one RPM equals 2(pi)/60. We then simply enter these values into the equation. For our first calculation on space station v we get a=(0.1047)^2*150=1.65 ms^-2
Patreon:
https://www.patreon.com/user?u=2825050&ty;=h
Facebook:
http://facebook.com/realengineering1
Instagram:
https://www.instagram.com/real.engineering
Twitter:
https://twitter.com/Fiosracht
Once again thanks to Bensound.com for the amazing royalty free music. This time I used Bensound - New Dawn
https://wn.com/Can_We_Create_Artificial_Gravity
Thanks for watching! I actually had an early version of this ready last week. Which you can watch here on my second channel:
https://www.youtube.com/watch?v=x9B0xCm87xI
I decided, with the help of my Patreon supporters, that it wasn't good enough. Have a few ideas for my next video. Space X is winning right now. What do you think? I may try to work on two videos at once this week.
Woops forgot the math:
The equation is a=(w^2)*r where a is the acceleration, w is the angular velocity and r is the radius.
First we must convert RPM to radians per second. There is 2(pi) radians per revolution and 60 seconds in a minute. So one RPM equals 2(pi)/60. We then simply enter these values into the equation. For our first calculation on space station v we get a=(0.1047)^2*150=1.65 ms^-2
Patreon:
https://www.patreon.com/user?u=2825050&ty;=h
Facebook:
http://facebook.com/realengineering1
Instagram:
https://www.instagram.com/real.engineering
Twitter:
https://twitter.com/Fiosracht
Once again thanks to Bensound.com for the amazing royalty free music. This time I used Bensound - New Dawn
- published: 29 Jun 2016
- views: 606159
The Biggest Rocket ever Designed? - The Sea Dragon
- Order: Reorder
- Duration: 7:36
- Updated: 02 Apr 2017
- views: 5469
In the history of space, one rocket stands out as an icon of not only the space race but of the mighty power it symbolised.
That one rocket, which is still the ...
In the history of space, one rocket stands out as an icon of not only the space race but of the mighty power it symbolised.
That one rocket, which is still the Tallest, heaviest and most powerful ever built, was the Saturn V, which was designed to take men to the moon and later launched the first American Space station, Skylab.
But if things had been a little different back in the 60’s we might have had a different rocket to hang on the bedroom walls of the space fans of the 70’s and 80’s.
In the early 1960’s, a rocket was designed which made the Saturn V look small comparison.
This was the Sea Dragon, a super heavy lift rocket that would have been 10 times more powerful with 80 Million lb’s of thrust compared to the Saturn’s 7.8 million and that was from just one massive engine.
It was designed to lift a payload of 1,100,000 lbs into orbit, compared to the 310,000 lbs of the Saturn V. This meant it could have lifted an entire space station into Low Earth Orbit in one mission.
The rocket bell of this single engine would be so large at 75 feet in diameter, that you could fit the entire first stage of a Saturn V with all 5 of its F1 engines inside with room to spare.
So what happened to the Sea Dragon and why didn’t it get built ?.
At the time of the design in 1962, it was thought that by the 1970’s, 80’s and beyond, thousands of people would be working in space and on the moon, even on Mars and as such, rockets with huge lifting capabilities would have been in great demand as they would dramatically lower the cost of getting materials into space.
The sea dragon was designed by Robert Truax, a US navy Captain and Rocket engineer. He was one of the pioneers of American rocketry and worked on the Thor and Polaris missiles amongst others. His team debriefed the German Rocket engineers at the end of World War 2 including Werner Von Braun who went on to design the Saturn V.
Traux believed it was complexity that drove up the cost of rockets and not their size. His designs for the Sea Dragon were very simple but very big. The sea dragon would have been 75 ft in diameter and 500ft tall, half the Hight of Chrysler building.
This type of low-cost super heavy rocket is now known as a “big dumb booster” due to its simplistic design.
Instead of having very complicated turbopump driven engine like the Saturn’s, his were the simplest possible design for a rocket engine.
In place of having powerful fuel pumps to push the huge amounts of rocket fuel and oxidizer in the engine, he proposed a pressure fed system with a separate liquid nitrogen tank to pressurise the fuel tanks, this would push the fuel into the massive combustion chamber.
His engines were literally not much more than the valves to turn on the fuel and the huge engine bell, this would make them not only much cheaper to manufacture but much easier to refurbish and reuse, unlike the F1 engines of the Saturn which were left crash in the sea and be discarded.
The rocket would be a two-stage design, the first stage would lift it to a height of 130,000 ft before it separated and fell back into the sea, using drag bags to slow it impacts with the water, where it would be recovered for reuse.
Although it’s design was much less efficient that of the Saturn, the overall increase in size made up for the short fall, so in theory it would be much cheaper per pound of payload compared to smaller rocket systems, even ones the size of the Saturn.
However, there were problems of making such a huge rocket, firstly just transporting the parts, let alone the fully assembled version, this together with the 80 million lbs of thrust meant that it could not be launched from land.
This amount of thrust would have destroyed any existing launch pad. It’s estimated that the noise level at take-off would have been around 165 decibels at 5 miles away or the equivalent of standing next to 5000 hp top fuel dragster at full throttle.
Then there is the exhaust plume, this would have been up to 1 mile long. For these reasons, the Sea Dragon would have had be launched at sea, hence the name, not from a floating platform but from beneath the water.
This is not mad as it seems and there have been examples of sea-launched rockets before and after.
In 2002 a low-cost sea-launched rocket delivery system called the Aquarius with a very similar design the Sea Dragon but much smaller was proposed to deliver consumables in to Low earth orbit for supplying things like the space station but failed to get selected.
The US Navy also did research in to floating launch rockets and found that the take-off was smoother and less stressful on the rocket than that of a normal land based take off.
And if you wondering why the water didn’t put out the flames, it’s because the rocket has it own liquid oxygen supply just like rockets that work in space where there is no air and the thrust just blows the water out of the engine bell.
https://wn.com/The_Biggest_Rocket_Ever_Designed_The_Sea_Dragon
In the history of space, one rocket stands out as an icon of not only the space race but of the mighty power it symbolised.
That one rocket, which is still the Tallest, heaviest and most powerful ever built, was the Saturn V, which was designed to take men to the moon and later launched the first American Space station, Skylab.
But if things had been a little different back in the 60’s we might have had a different rocket to hang on the bedroom walls of the space fans of the 70’s and 80’s.
In the early 1960’s, a rocket was designed which made the Saturn V look small comparison.
This was the Sea Dragon, a super heavy lift rocket that would have been 10 times more powerful with 80 Million lb’s of thrust compared to the Saturn’s 7.8 million and that was from just one massive engine.
It was designed to lift a payload of 1,100,000 lbs into orbit, compared to the 310,000 lbs of the Saturn V. This meant it could have lifted an entire space station into Low Earth Orbit in one mission.
The rocket bell of this single engine would be so large at 75 feet in diameter, that you could fit the entire first stage of a Saturn V with all 5 of its F1 engines inside with room to spare.
So what happened to the Sea Dragon and why didn’t it get built ?.
At the time of the design in 1962, it was thought that by the 1970’s, 80’s and beyond, thousands of people would be working in space and on the moon, even on Mars and as such, rockets with huge lifting capabilities would have been in great demand as they would dramatically lower the cost of getting materials into space.
The sea dragon was designed by Robert Truax, a US navy Captain and Rocket engineer. He was one of the pioneers of American rocketry and worked on the Thor and Polaris missiles amongst others. His team debriefed the German Rocket engineers at the end of World War 2 including Werner Von Braun who went on to design the Saturn V.
Traux believed it was complexity that drove up the cost of rockets and not their size. His designs for the Sea Dragon were very simple but very big. The sea dragon would have been 75 ft in diameter and 500ft tall, half the Hight of Chrysler building.
This type of low-cost super heavy rocket is now known as a “big dumb booster” due to its simplistic design.
Instead of having very complicated turbopump driven engine like the Saturn’s, his were the simplest possible design for a rocket engine.
In place of having powerful fuel pumps to push the huge amounts of rocket fuel and oxidizer in the engine, he proposed a pressure fed system with a separate liquid nitrogen tank to pressurise the fuel tanks, this would push the fuel into the massive combustion chamber.
His engines were literally not much more than the valves to turn on the fuel and the huge engine bell, this would make them not only much cheaper to manufacture but much easier to refurbish and reuse, unlike the F1 engines of the Saturn which were left crash in the sea and be discarded.
The rocket would be a two-stage design, the first stage would lift it to a height of 130,000 ft before it separated and fell back into the sea, using drag bags to slow it impacts with the water, where it would be recovered for reuse.
Although it’s design was much less efficient that of the Saturn, the overall increase in size made up for the short fall, so in theory it would be much cheaper per pound of payload compared to smaller rocket systems, even ones the size of the Saturn.
However, there were problems of making such a huge rocket, firstly just transporting the parts, let alone the fully assembled version, this together with the 80 million lbs of thrust meant that it could not be launched from land.
This amount of thrust would have destroyed any existing launch pad. It’s estimated that the noise level at take-off would have been around 165 decibels at 5 miles away or the equivalent of standing next to 5000 hp top fuel dragster at full throttle.
Then there is the exhaust plume, this would have been up to 1 mile long. For these reasons, the Sea Dragon would have had be launched at sea, hence the name, not from a floating platform but from beneath the water.
This is not mad as it seems and there have been examples of sea-launched rockets before and after.
In 2002 a low-cost sea-launched rocket delivery system called the Aquarius with a very similar design the Sea Dragon but much smaller was proposed to deliver consumables in to Low earth orbit for supplying things like the space station but failed to get selected.
The US Navy also did research in to floating launch rockets and found that the take-off was smoother and less stressful on the rocket than that of a normal land based take off.
And if you wondering why the water didn’t put out the flames, it’s because the rocket has it own liquid oxygen supply just like rockets that work in space where there is no air and the thrust just blows the water out of the engine bell.
- published: 02 Apr 2017
- views: 5469
-
Day in the Life: Satellite Operations Engineer
As part of ConnectEd's "Day in the Life" series, we interview Veronica Navarro, a Satellite Operations Engineer at Space Systems/Loral. Her duties include monitoring the health of a satellite prior to and during its launch into space. Explore more career videos at http://connectedstudios.org/life_videos Follow us on Facebook! https://facebook.com/connectedstudios
published: 22 Aug 2011 -
-
Pro. Engineer Explains Problems with the ISS, Satellites & the Thermosphere. Flat Earth.
We thank you for your support: http://www.AzimuthalEquidistant.org "...more and more Professional Engineers, Lawyers, Airline Pilots, Navigators, Surveyors, etc. are waking up and becoming proponents for flat earth. The All Seeing Heart thinks that it is reassuring, inspiring, and natural; after all, not unlike nature, deep down all we really want to do is grow." Brian Mullin said it best, "...think about all this!" Shared from Channel: Brian Mullin Series: Balls Out Physics Episode: 4.0, The ISS, Satellites, and the Thermosphere Channel URL: https://www.youtube.com/channel/UCArBP0HP6aYpSVQQ4YbuYqQ
published: 09 Jul 2016 -
Day in the Life of Stefanie Kohl -- Space Systems Engineer, Surrey Satellite Technology Ltd
Space Systems Engineer Stefanie Kohl leads us around the satellite assembly and testing facilities at Surrey Satellite Technology Ltd, and provides us with a glimpse of her daily life in what she regards as a complex but highly enjoyable role as a satellite engineer.
published: 09 Nov 2012 -
Packaging and Deployment of Boeing Satellites with Engineer Keith Watts
How do you send satellites into space? Boeing engineer, Keith Watts, helps make sure satellites can be packed as small as possible or expanded out, depending on what is needed. Keith has to think about all the different sizes and configurations that the satellite will have to be, known as dynamic constraints. The satellite Keith builds has to be small enough to fit into the nose of the rocket to send into space. But once in space, the satellite leaves the rocket and has to find its own power source, the sun! The satellite must deploy giant solar arrays to get energy from the sun, as well as its antennae to send and receive messages. Visit us at http://www.curiositymachine.org to build design challenges and explore more science and engineering at home!
published: 13 Jul 2015 -
Origami in Space: BYU-designed solar arrays inspired by origami
Origami is a source of inspiration for BYU mechanical engineers who are working with the National Science Foundation, NASA/JPL and origami master Robert Lang to design complaint mechanisms for use in space and in other applications. (Video produced by BYU News. Producer Julie Walker, Photographer Brian Wilcox, Editor Samuel Reimer. Additional images provided by NASA/JPL, langorigami.com, BYU Compliant Mechanisms Research Group, Matthew Gong, and Carrie Henzie (Redpath Museum). See more about BYU space research and collaborations with origami master Robert Lang at http://bit.ly/17WMdRX BYU engineers turn to origami to solve astronomical space problem; Partnership with NASA could send origami to the final frontier BYU engineers have teamed up with a world-renown origami expert to solve o...
published: 27 Nov 2013 -
Deploying Satellites with Boeing Engineer Keith Watts
When Boeing engineer Keith Watts designs and builds a satellite, he has to think how the satellite will be packaged in different sizes. A satellite needs to be small when its sent into space inside a rocket, but once in space, the solar arrays and antennae must be easily opened. The solar arrays are used to catch the sun's energy, so they need to be very large to let the satellite send important messages through its antennae. In order to fit these dynamic constraints, Keith has to make solar arrays and antennae that can fold up and deployed quickly using latches. Some of them even use controlled explosions! Visit the http://www.curiositymachine.org to build and deploy your very own satellite!
published: 13 Jul 2015 -
Crazy Engineering: CubeSats
Honey, I shrunk the satellites! Mini-satellites are following in the footsteps of cell phones and computers. CubeSats are small but highly capable of performing a variety of space missions. For more about our CubeSats, visit http://www.jpl.nasa.gov/cubesat/
published: 03 Dec 2015 -
Can We Create Artificial Gravity?
Thanks for watching! I actually had an early version of this ready last week. Which you can watch here on my second channel: https://www.youtube.com/watch?v=x9B0xCm87xI I decided, with the help of my Patreon supporters, that it wasn't good enough. Have a few ideas for my next video. Space X is winning right now. What do you think? I may try to work on two videos at once this week. Woops forgot the math: The equation is a=(w^2)*r where a is the acceleration, w is the angular velocity and r is the radius. First we must convert RPM to radians per second. There is 2(pi) radians per revolution and 60 seconds in a minute. So one RPM equals 2(pi)/60. We then simply enter these values into the equation. For our first calculation on space station v we get a=(0.1047)^2*150=1.65 ms^-2 Patreon: h...
published: 29 Jun 2016 -
The Biggest Rocket ever Designed? - The Sea Dragon
In the history of space, one rocket stands out as an icon of not only the space race but of the mighty power it symbolised. That one rocket, which is still the Tallest, heaviest and most powerful ever built, was the Saturn V, which was designed to take men to the moon and later launched the first American Space station, Skylab. But if things had been a little different back in the 60’s we might have had a different rocket to hang on the bedroom walls of the space fans of the 70’s and 80’s. In the early 1960’s, a rocket was designed which made the Saturn V look small comparison. This was the Sea Dragon, a super heavy lift rocket that would have been 10 times more powerful with 80 Million lb’s of thrust compared to the Saturn’s 7.8 million and that was from just one massive engine. It was ...
published: 02 Apr 2017
Day in the Life: Satellite Operations Engineer
- Order: Reorder
- Duration: 3:36
- Updated: 22 Aug 2011
- views: 7399
As part of ConnectEd's "Day in the Life" series, we interview Veronica Navarro, a Satellite Operations Engineer at Space Systems/Loral. Her duties include monit...
As part of ConnectEd's "Day in the Life" series, we interview Veronica Navarro, a Satellite Operations Engineer at Space Systems/Loral. Her duties include monitoring the health of a satellite prior to and during its launch into space.
Explore more career videos at http://connectedstudios.org/life_videos
Follow us on Facebook! https://facebook.com/connectedstudios
https://wn.com/Day_In_The_Life_Satellite_Operations_Engineer
As part of ConnectEd's "Day in the Life" series, we interview Veronica Navarro, a Satellite Operations Engineer at Space Systems/Loral. Her duties include monitoring the health of a satellite prior to and during its launch into space.
Explore more career videos at http://connectedstudios.org/life_videos
Follow us on Facebook! https://facebook.com/connectedstudios
- published: 22 Aug 2011
- views: 7399
Satellite Engineering
- Order: Reorder
- Duration: 41:49
- Updated: 28 Oct 2013
- views: 6856
Lecture: Satellite Engineering
Julien Tallineau - Physics and Space System Engineer, QinetiQ Space nv
Lecture: Satellite Engineering
Julien Tallineau - Physics and Space System Engineer, QinetiQ Space nv
https://wn.com/Satellite_Engineering
Pro. Engineer Explains Problems with the ISS, Satellites & the Thermosphere. Flat Earth.
- Order: Reorder
- Duration: 34:43
- Updated: 09 Jul 2016
- views: 22466
We thank you for your support: http://www.AzimuthalEquidistant.org "...more and more Professional Engineers, Lawyers, Airline Pilots, Navigators, Surveyors, e...
We thank you for your support: http://www.AzimuthalEquidistant.org "...more and more Professional Engineers, Lawyers, Airline Pilots, Navigators, Surveyors, etc. are waking up and becoming proponents for flat earth.
The All Seeing Heart thinks that it is reassuring, inspiring, and natural; after all, not unlike nature, deep down all we really want to do is grow."
Brian Mullin said it best, "...think about all this!"
Shared from Channel: Brian Mullin
Series: Balls Out Physics
Episode: 4.0, The ISS, Satellites, and the Thermosphere
Channel URL: https://www.youtube.com/channel/UCArBP0HP6aYpSVQQ4YbuYqQ
https://wn.com/Pro._Engineer_Explains_Problems_With_The_Iss,_Satellites_The_Thermosphere._Flat_Earth.
We thank you for your support: http://www.AzimuthalEquidistant.org "...more and more Professional Engineers, Lawyers, Airline Pilots, Navigators, Surveyors, etc. are waking up and becoming proponents for flat earth.
The All Seeing Heart thinks that it is reassuring, inspiring, and natural; after all, not unlike nature, deep down all we really want to do is grow."
Brian Mullin said it best, "...think about all this!"
Shared from Channel: Brian Mullin
Series: Balls Out Physics
Episode: 4.0, The ISS, Satellites, and the Thermosphere
Channel URL: https://www.youtube.com/channel/UCArBP0HP6aYpSVQQ4YbuYqQ
- published: 09 Jul 2016
- views: 22466
Day in the Life of Stefanie Kohl -- Space Systems Engineer, Surrey Satellite Technology Ltd
- Order: Reorder
- Duration: 3:57
- Updated: 09 Nov 2012
- views: 1569
Space Systems Engineer Stefanie Kohl leads us around the satellite assembly and testing facilities at Surrey Satellite Technology Ltd, and provides us with a gl...
Space Systems Engineer Stefanie Kohl leads us around the satellite assembly and testing facilities at Surrey Satellite Technology Ltd, and provides us with a glimpse of her daily life in what she regards as a complex but highly enjoyable role as a satellite engineer.
https://wn.com/Day_In_The_Life_Of_Stefanie_Kohl_Space_Systems_Engineer,_Surrey_Satellite_Technology_Ltd
Space Systems Engineer Stefanie Kohl leads us around the satellite assembly and testing facilities at Surrey Satellite Technology Ltd, and provides us with a glimpse of her daily life in what she regards as a complex but highly enjoyable role as a satellite engineer.
- published: 09 Nov 2012
- views: 1569
Packaging and Deployment of Boeing Satellites with Engineer Keith Watts
- Order: Reorder
- Duration: 3:15
- Updated: 13 Jul 2015
- views: 755
How do you send satellites into space? Boeing engineer, Keith Watts, helps make sure satellites can be packed as small as possible or expanded out, depending on...
How do you send satellites into space? Boeing engineer, Keith Watts, helps make sure satellites can be packed as small as possible or expanded out, depending on what is needed. Keith has to think about all the different sizes and configurations that the satellite will have to be, known as dynamic constraints. The satellite Keith builds has to be small enough to fit into the nose of the rocket to send into space. But once in space, the satellite leaves the rocket and has to find its own power source, the sun! The satellite must deploy giant solar arrays to get energy from the sun, as well as its antennae to send and receive messages.
Visit us at http://www.curiositymachine.org to build design challenges and explore more science and engineering at home!
https://wn.com/Packaging_And_Deployment_Of_Boeing_Satellites_With_Engineer_Keith_Watts
How do you send satellites into space? Boeing engineer, Keith Watts, helps make sure satellites can be packed as small as possible or expanded out, depending on what is needed. Keith has to think about all the different sizes and configurations that the satellite will have to be, known as dynamic constraints. The satellite Keith builds has to be small enough to fit into the nose of the rocket to send into space. But once in space, the satellite leaves the rocket and has to find its own power source, the sun! The satellite must deploy giant solar arrays to get energy from the sun, as well as its antennae to send and receive messages.
Visit us at http://www.curiositymachine.org to build design challenges and explore more science and engineering at home!
- published: 13 Jul 2015
- views: 755
Origami in Space: BYU-designed solar arrays inspired by origami
- Order: Reorder
- Duration: 3:21
- Updated: 27 Nov 2013
- views: 116754
Origami is a source of inspiration for BYU mechanical engineers who are working with the National Science Foundation, NASA/JPL and origami master Robert Lang to...
Origami is a source of inspiration for BYU mechanical engineers who are working with the National Science Foundation, NASA/JPL and origami master Robert Lang to design complaint mechanisms for use in space and in other applications.
(Video produced by BYU News. Producer Julie Walker, Photographer Brian Wilcox, Editor Samuel Reimer. Additional images provided by NASA/JPL, langorigami.com, BYU Compliant Mechanisms Research Group, Matthew Gong, and Carrie Henzie (Redpath Museum).
See more about BYU space research and collaborations with origami master Robert Lang at http://bit.ly/17WMdRX
BYU engineers turn to origami to solve astronomical space problem; Partnership with NASA could send origami to the final frontier
BYU engineers have teamed up with a world-renown origami expert to solve one of space exploration's greatest (and ironic) problems: lack of space.
Working with NASA's Jet Propulsion Laboratory, a team of mechanical engineering students and faculty have designed a solar array that can be tightly compacted for launch and then deployed in space to generate power for space stations or satellites.
Applying origami principles on rigid silicon solar panels -- a material considerably thicker than the paper used for the traditional Japanese art -- the BYU-conceived solar array would unfold to nearly 10 times its stored size.
"It's expensive and difficult to get things into space; you're very constrained in space," said BYU professor and research team leader Larry Howell. "With origami you can make it compact for launch and then as you get into space it can deploy and be large."
The current project, detailed in the November issue of the Journal of Mechanical Design, is propelled by collaboration between BYU, NASA and origami expert Robert Lang. Howell reached out to Lang as part of landing a $2 million National Science Foundation grant in 2012 to explore the combination of origami and compliant mechanisms. (Joint-less, elastic structures that use flexibility to create movement.)
BYU was already working with NASA through the Jet Propulsion Lab, where grad student Shannon Zirbel has been instrumental in the project. The research team plans to work together for several more years on various projects, but hopes NASA can put their work to good use before they're through.
"It's hard to predict what the greatest outcome of this collaboration will be, but it would be a great success if a solar array based on our concept flew on a NASA mission," Lang said.
The particular solar array developed by the group can be folded tightly down to a diameter of 2.7 meters and unfolded to its full size of 25 meters across. The goal is to create an array that can produce 250 kilowatts of power. Currently, the International Space Station has eight solar arrays that generate 84 kilowatts of energy.
Howell said origami through compliant mechanisms is a perfect fit for space exploration: It is low cost and the materials can handle harsh solar environments.
"Space is a great place for a solar panel because you don't have to worry about nighttime and there are no clouds and no weather," he said. "Origami could also be used for antennas, solar sails and even expandable nets used to catch asteroids."
The research team has already looked beyond the final frontier for origami applications in engineering. Some applications Howell said may be possible include:
Stents or implants that can be inserted through small incisions before expanding inside the body
Phones that can be compact when you're not using them and then unfold for use
Deployable housing or shelters that can be shipped or parachuted compactly and then expanded for emergency use
"If we can extend the knowledge of origami artists to work in materials beyond paper, it will lead to powerful systems with unprecedented performance," Howell said. "We will do things no one has ever done before."
https://wn.com/Origami_In_Space_Byu_Designed_Solar_Arrays_Inspired_By_Origami
Origami is a source of inspiration for BYU mechanical engineers who are working with the National Science Foundation, NASA/JPL and origami master Robert Lang to design complaint mechanisms for use in space and in other applications.
(Video produced by BYU News. Producer Julie Walker, Photographer Brian Wilcox, Editor Samuel Reimer. Additional images provided by NASA/JPL, langorigami.com, BYU Compliant Mechanisms Research Group, Matthew Gong, and Carrie Henzie (Redpath Museum).
See more about BYU space research and collaborations with origami master Robert Lang at http://bit.ly/17WMdRX
BYU engineers turn to origami to solve astronomical space problem; Partnership with NASA could send origami to the final frontier
BYU engineers have teamed up with a world-renown origami expert to solve one of space exploration's greatest (and ironic) problems: lack of space.
Working with NASA's Jet Propulsion Laboratory, a team of mechanical engineering students and faculty have designed a solar array that can be tightly compacted for launch and then deployed in space to generate power for space stations or satellites.
Applying origami principles on rigid silicon solar panels -- a material considerably thicker than the paper used for the traditional Japanese art -- the BYU-conceived solar array would unfold to nearly 10 times its stored size.
"It's expensive and difficult to get things into space; you're very constrained in space," said BYU professor and research team leader Larry Howell. "With origami you can make it compact for launch and then as you get into space it can deploy and be large."
The current project, detailed in the November issue of the Journal of Mechanical Design, is propelled by collaboration between BYU, NASA and origami expert Robert Lang. Howell reached out to Lang as part of landing a $2 million National Science Foundation grant in 2012 to explore the combination of origami and compliant mechanisms. (Joint-less, elastic structures that use flexibility to create movement.)
BYU was already working with NASA through the Jet Propulsion Lab, where grad student Shannon Zirbel has been instrumental in the project. The research team plans to work together for several more years on various projects, but hopes NASA can put their work to good use before they're through.
"It's hard to predict what the greatest outcome of this collaboration will be, but it would be a great success if a solar array based on our concept flew on a NASA mission," Lang said.
The particular solar array developed by the group can be folded tightly down to a diameter of 2.7 meters and unfolded to its full size of 25 meters across. The goal is to create an array that can produce 250 kilowatts of power. Currently, the International Space Station has eight solar arrays that generate 84 kilowatts of energy.
Howell said origami through compliant mechanisms is a perfect fit for space exploration: It is low cost and the materials can handle harsh solar environments.
"Space is a great place for a solar panel because you don't have to worry about nighttime and there are no clouds and no weather," he said. "Origami could also be used for antennas, solar sails and even expandable nets used to catch asteroids."
The research team has already looked beyond the final frontier for origami applications in engineering. Some applications Howell said may be possible include:
Stents or implants that can be inserted through small incisions before expanding inside the body
Phones that can be compact when you're not using them and then unfold for use
Deployable housing or shelters that can be shipped or parachuted compactly and then expanded for emergency use
"If we can extend the knowledge of origami artists to work in materials beyond paper, it will lead to powerful systems with unprecedented performance," Howell said. "We will do things no one has ever done before."
- published: 27 Nov 2013
- views: 116754
Deploying Satellites with Boeing Engineer Keith Watts
- Order: Reorder
- Duration: 1:50
- Updated: 13 Jul 2015
- views: 453
When Boeing engineer Keith Watts designs and builds a satellite, he has to think how the satellite will be packaged in different sizes. A satellite needs to be ...
When Boeing engineer Keith Watts designs and builds a satellite, he has to think how the satellite will be packaged in different sizes. A satellite needs to be small when its sent into space inside a rocket, but once in space, the solar arrays and antennae must be easily opened. The solar arrays are used to catch the sun's energy, so they need to be very large to let the satellite send important messages through its antennae. In order to fit these dynamic constraints, Keith has to make solar arrays and antennae that can fold up and deployed quickly using latches. Some of them even use controlled explosions!
Visit the http://www.curiositymachine.org to build and deploy your very own satellite!
https://wn.com/Deploying_Satellites_With_Boeing_Engineer_Keith_Watts
When Boeing engineer Keith Watts designs and builds a satellite, he has to think how the satellite will be packaged in different sizes. A satellite needs to be small when its sent into space inside a rocket, but once in space, the solar arrays and antennae must be easily opened. The solar arrays are used to catch the sun's energy, so they need to be very large to let the satellite send important messages through its antennae. In order to fit these dynamic constraints, Keith has to make solar arrays and antennae that can fold up and deployed quickly using latches. Some of them even use controlled explosions!
Visit the http://www.curiositymachine.org to build and deploy your very own satellite!
- published: 13 Jul 2015
- views: 453
Crazy Engineering: CubeSats
- Order: Reorder
- Duration: 2:49
- Updated: 03 Dec 2015
- views: 83456
Honey, I shrunk the satellites! Mini-satellites are following in the footsteps of cell phones and computers. CubeSats are small but highly capable of performing...
Honey, I shrunk the satellites! Mini-satellites are following in the footsteps of cell phones and computers. CubeSats are small but highly capable of performing a variety of space missions. For more about our CubeSats, visit http://www.jpl.nasa.gov/cubesat/
https://wn.com/Crazy_Engineering_Cubesats
Can We Create Artificial Gravity?
- Order: Reorder
- Duration: 6:34
- Updated: 29 Jun 2016
- views: 606159
Thanks for watching! I actually had an early version of this ready last week. Which you can watch here on my second channel:
https://www.youtube.com/watch?v=x9...
Thanks for watching! I actually had an early version of this ready last week. Which you can watch here on my second channel:
https://www.youtube.com/watch?v=x9B0xCm87xI
I decided, with the help of my Patreon supporters, that it wasn't good enough. Have a few ideas for my next video. Space X is winning right now. What do you think? I may try to work on two videos at once this week.
Woops forgot the math:
The equation is a=(w^2)*r where a is the acceleration, w is the angular velocity and r is the radius.
First we must convert RPM to radians per second. There is 2(pi) radians per revolution and 60 seconds in a minute. So one RPM equals 2(pi)/60. We then simply enter these values into the equation. For our first calculation on space station v we get a=(0.1047)^2*150=1.65 ms^-2
Patreon:
https://www.patreon.com/user?u=2825050&ty;=h
Facebook:
http://facebook.com/realengineering1
Instagram:
https://www.instagram.com/real.engineering
Twitter:
https://twitter.com/Fiosracht
Once again thanks to Bensound.com for the amazing royalty free music. This time I used Bensound - New Dawn
https://wn.com/Can_We_Create_Artificial_Gravity
Thanks for watching! I actually had an early version of this ready last week. Which you can watch here on my second channel:
https://www.youtube.com/watch?v=x9B0xCm87xI
I decided, with the help of my Patreon supporters, that it wasn't good enough. Have a few ideas for my next video. Space X is winning right now. What do you think? I may try to work on two videos at once this week.
Woops forgot the math:
The equation is a=(w^2)*r where a is the acceleration, w is the angular velocity and r is the radius.
First we must convert RPM to radians per second. There is 2(pi) radians per revolution and 60 seconds in a minute. So one RPM equals 2(pi)/60. We then simply enter these values into the equation. For our first calculation on space station v we get a=(0.1047)^2*150=1.65 ms^-2
Patreon:
https://www.patreon.com/user?u=2825050&ty;=h
Facebook:
http://facebook.com/realengineering1
Instagram:
https://www.instagram.com/real.engineering
Twitter:
https://twitter.com/Fiosracht
Once again thanks to Bensound.com for the amazing royalty free music. This time I used Bensound - New Dawn
- published: 29 Jun 2016
- views: 606159
The Biggest Rocket ever Designed? - The Sea Dragon
- Order: Reorder
- Duration: 7:36
- Updated: 02 Apr 2017
- views: 5469
In the history of space, one rocket stands out as an icon of not only the space race but of the mighty power it symbolised.
That one rocket, which is still the ...
In the history of space, one rocket stands out as an icon of not only the space race but of the mighty power it symbolised.
That one rocket, which is still the Tallest, heaviest and most powerful ever built, was the Saturn V, which was designed to take men to the moon and later launched the first American Space station, Skylab.
But if things had been a little different back in the 60’s we might have had a different rocket to hang on the bedroom walls of the space fans of the 70’s and 80’s.
In the early 1960’s, a rocket was designed which made the Saturn V look small comparison.
This was the Sea Dragon, a super heavy lift rocket that would have been 10 times more powerful with 80 Million lb’s of thrust compared to the Saturn’s 7.8 million and that was from just one massive engine.
It was designed to lift a payload of 1,100,000 lbs into orbit, compared to the 310,000 lbs of the Saturn V. This meant it could have lifted an entire space station into Low Earth Orbit in one mission.
The rocket bell of this single engine would be so large at 75 feet in diameter, that you could fit the entire first stage of a Saturn V with all 5 of its F1 engines inside with room to spare.
So what happened to the Sea Dragon and why didn’t it get built ?.
At the time of the design in 1962, it was thought that by the 1970’s, 80’s and beyond, thousands of people would be working in space and on the moon, even on Mars and as such, rockets with huge lifting capabilities would have been in great demand as they would dramatically lower the cost of getting materials into space.
The sea dragon was designed by Robert Truax, a US navy Captain and Rocket engineer. He was one of the pioneers of American rocketry and worked on the Thor and Polaris missiles amongst others. His team debriefed the German Rocket engineers at the end of World War 2 including Werner Von Braun who went on to design the Saturn V.
Traux believed it was complexity that drove up the cost of rockets and not their size. His designs for the Sea Dragon were very simple but very big. The sea dragon would have been 75 ft in diameter and 500ft tall, half the Hight of Chrysler building.
This type of low-cost super heavy rocket is now known as a “big dumb booster” due to its simplistic design.
Instead of having very complicated turbopump driven engine like the Saturn’s, his were the simplest possible design for a rocket engine.
In place of having powerful fuel pumps to push the huge amounts of rocket fuel and oxidizer in the engine, he proposed a pressure fed system with a separate liquid nitrogen tank to pressurise the fuel tanks, this would push the fuel into the massive combustion chamber.
His engines were literally not much more than the valves to turn on the fuel and the huge engine bell, this would make them not only much cheaper to manufacture but much easier to refurbish and reuse, unlike the F1 engines of the Saturn which were left crash in the sea and be discarded.
The rocket would be a two-stage design, the first stage would lift it to a height of 130,000 ft before it separated and fell back into the sea, using drag bags to slow it impacts with the water, where it would be recovered for reuse.
Although it’s design was much less efficient that of the Saturn, the overall increase in size made up for the short fall, so in theory it would be much cheaper per pound of payload compared to smaller rocket systems, even ones the size of the Saturn.
However, there were problems of making such a huge rocket, firstly just transporting the parts, let alone the fully assembled version, this together with the 80 million lbs of thrust meant that it could not be launched from land.
This amount of thrust would have destroyed any existing launch pad. It’s estimated that the noise level at take-off would have been around 165 decibels at 5 miles away or the equivalent of standing next to 5000 hp top fuel dragster at full throttle.
Then there is the exhaust plume, this would have been up to 1 mile long. For these reasons, the Sea Dragon would have had be launched at sea, hence the name, not from a floating platform but from beneath the water.
This is not mad as it seems and there have been examples of sea-launched rockets before and after.
In 2002 a low-cost sea-launched rocket delivery system called the Aquarius with a very similar design the Sea Dragon but much smaller was proposed to deliver consumables in to Low earth orbit for supplying things like the space station but failed to get selected.
The US Navy also did research in to floating launch rockets and found that the take-off was smoother and less stressful on the rocket than that of a normal land based take off.
And if you wondering why the water didn’t put out the flames, it’s because the rocket has it own liquid oxygen supply just like rockets that work in space where there is no air and the thrust just blows the water out of the engine bell.
https://wn.com/The_Biggest_Rocket_Ever_Designed_The_Sea_Dragon
In the history of space, one rocket stands out as an icon of not only the space race but of the mighty power it symbolised.
That one rocket, which is still the Tallest, heaviest and most powerful ever built, was the Saturn V, which was designed to take men to the moon and later launched the first American Space station, Skylab.
But if things had been a little different back in the 60’s we might have had a different rocket to hang on the bedroom walls of the space fans of the 70’s and 80’s.
In the early 1960’s, a rocket was designed which made the Saturn V look small comparison.
This was the Sea Dragon, a super heavy lift rocket that would have been 10 times more powerful with 80 Million lb’s of thrust compared to the Saturn’s 7.8 million and that was from just one massive engine.
It was designed to lift a payload of 1,100,000 lbs into orbit, compared to the 310,000 lbs of the Saturn V. This meant it could have lifted an entire space station into Low Earth Orbit in one mission.
The rocket bell of this single engine would be so large at 75 feet in diameter, that you could fit the entire first stage of a Saturn V with all 5 of its F1 engines inside with room to spare.
So what happened to the Sea Dragon and why didn’t it get built ?.
At the time of the design in 1962, it was thought that by the 1970’s, 80’s and beyond, thousands of people would be working in space and on the moon, even on Mars and as such, rockets with huge lifting capabilities would have been in great demand as they would dramatically lower the cost of getting materials into space.
The sea dragon was designed by Robert Truax, a US navy Captain and Rocket engineer. He was one of the pioneers of American rocketry and worked on the Thor and Polaris missiles amongst others. His team debriefed the German Rocket engineers at the end of World War 2 including Werner Von Braun who went on to design the Saturn V.
Traux believed it was complexity that drove up the cost of rockets and not their size. His designs for the Sea Dragon were very simple but very big. The sea dragon would have been 75 ft in diameter and 500ft tall, half the Hight of Chrysler building.
This type of low-cost super heavy rocket is now known as a “big dumb booster” due to its simplistic design.
Instead of having very complicated turbopump driven engine like the Saturn’s, his were the simplest possible design for a rocket engine.
In place of having powerful fuel pumps to push the huge amounts of rocket fuel and oxidizer in the engine, he proposed a pressure fed system with a separate liquid nitrogen tank to pressurise the fuel tanks, this would push the fuel into the massive combustion chamber.
His engines were literally not much more than the valves to turn on the fuel and the huge engine bell, this would make them not only much cheaper to manufacture but much easier to refurbish and reuse, unlike the F1 engines of the Saturn which were left crash in the sea and be discarded.
The rocket would be a two-stage design, the first stage would lift it to a height of 130,000 ft before it separated and fell back into the sea, using drag bags to slow it impacts with the water, where it would be recovered for reuse.
Although it’s design was much less efficient that of the Saturn, the overall increase in size made up for the short fall, so in theory it would be much cheaper per pound of payload compared to smaller rocket systems, even ones the size of the Saturn.
However, there were problems of making such a huge rocket, firstly just transporting the parts, let alone the fully assembled version, this together with the 80 million lbs of thrust meant that it could not be launched from land.
This amount of thrust would have destroyed any existing launch pad. It’s estimated that the noise level at take-off would have been around 165 decibels at 5 miles away or the equivalent of standing next to 5000 hp top fuel dragster at full throttle.
Then there is the exhaust plume, this would have been up to 1 mile long. For these reasons, the Sea Dragon would have had be launched at sea, hence the name, not from a floating platform but from beneath the water.
This is not mad as it seems and there have been examples of sea-launched rockets before and after.
In 2002 a low-cost sea-launched rocket delivery system called the Aquarius with a very similar design the Sea Dragon but much smaller was proposed to deliver consumables in to Low earth orbit for supplying things like the space station but failed to get selected.
The US Navy also did research in to floating launch rockets and found that the take-off was smoother and less stressful on the rocket than that of a normal land based take off.
And if you wondering why the water didn’t put out the flames, it’s because the rocket has it own liquid oxygen supply just like rockets that work in space where there is no air and the thrust just blows the water out of the engine bell.
- published: 02 Apr 2017
- views: 5469
-
-
Ball's Out Physics Episode 4.1: Virgin Galactic, Telecom, & Thermal Radiation
DroidFuel's "Space is Hard": https://www.youtube.com/watch?v=vbTaJPD3oLs Virgin Galactic - Human Spaceflight: http://www.virgingalactic.com/human-spaceflight/ Balls Out Physics Episode 4.0: https://www.youtube.com/watch?v=_HaCEMy28u4 Satellite Thermal Control Engineering PowerPoint slides: http://www.tak2000.com/data/Satellite_TC.pdf ISS Cooling System per Space.com: http://www.space.com/21059-space-station-cooling-system-explained-infographic.html
published: 29 Mar 2016 -
Elon Musk comments on Falcon 9 explosion - Huge Blow for SpaceX (2015.7.7)
A week following SpaceX CRS-7 explosion, Elon Musk speaks at the ISS R&D; conference where he comments on the regrettable incident and the current efforts underway at SpaceX to identify the source(s) of the problem. He also touches other subjects surrounding SpaceX. Overview: 00:00. Intro 02:44. SpaceX CRS-7 explosion and post-analysis 09:20. Reusable rockets 12:14. Why space? 19:50. Manned flights 21:52. Dragon 2 applications Q&A; 26:40. How to keep going 28:37. Solar energy and Mars exploration 31:00. Role of government in SpaceX success 35:55. R&D; spendings strategy 38:05. 3D printed SuperDraco engines 40:52. Hyperloop & SpaceX 42:22. Coolness of ISS (International Space Station) 45:10. SpaceX space suit design 46:40. Internet satellites project 50:45. Virtual reality in Space Date: Jul...
published: 08 Jul 2015 -
Space Engineers Inspiration - Episode 109: Mercury Aircraft, Magnus Capital Ship, Brionic Satellite
Welcome to the Space Engineers Inspiration series!! I'm basically going to be picking out random ships/maps that I just find really awesome or impressive & doing walkthrough/showcase kind of thing to show all of you some of the really crazy stuff the community has done! There will always be links to the download page along with the author's name so that you can check them out yourself too. Check out my Patreon page if you would like to support my channel: http://www.patreon.com/SKS Sleepless Knights Studios group on Steam: http://steamcommunity.com/groups/SKStudios This Episode's Links: Mercury Vanilla Aircraft by Rose: http://steamcommunity.com/sharedfiles/filedetails/?id=750999552 [SMI] Magnus Capital Ship by wolverind: http://steamcommunity.com/sharedfiles/filedetails/?id=752260456...
published: 28 Aug 2016 -
Gravity FULL MOVIE
The crew of the Space Shuttle Explorer is working on the STS-157 mission. http://bit.ly/Gravity020 Mission Commander Matt Kowalski, medical engineer Dr. Ryan Stone - who is on her first ever space mission - and flight engineer Shariff Dasari are on a space walk when they learn from Houston control that an explosion has just occurred at a Russian satellite. Before the crew can do anything about it, the explosion debris comes hurtling toward Explorer, irreparably damaging the shuttle and station, immediately killing all the crew except Kowalski and Stone, and knocking out at least incoming communication with Houston control, although they have no idea if there is outgoing communication. The two are left in a precarious position as Stone is untethered with quickly decreasing oxygen on her pe...
published: 26 Sep 2015 -
Space Cowboys (2000) with Tommy Lee Jones, Donald Sutherland, Clint Eastwood Movie
When an engineer is gotten a phone to repair a failing satellite, he supposes that he & his colleagues got into space.
published: 27 Sep 2016 -
Satellite Launch | 3x12 | The Nidd Whitelist | Space Engineers
Minty and I launch my communications satellite into space using my reusable first-stage boosters. To see who plays on this server and what mods we use, go here: http://thenidd.com/server-list/space-engineers/the-nidd-whitelisted/ ------------------------------------------------- ABOUT This channel is a hobby that exists to somehow validate the many hours spent in front of a screen by producing something at the end of it all. Nothing new or great, but someone might enjoy it. -------------------------------------------------- LINKS Website: http://thenidd.com/ Steam Group: http://steamcommunity.com/groups/TheNidd Google+: http://goo.gl/u3IizR Facebook: http://goo.gl/xXtfy8 Twitter: http://goo.gl/oDkSHk
published: 11 Feb 2016 -
Space Cowboys (2000) Movie - Clint Eastwood, Tommy Lee Jones, Donald Sutherland
Space Cowboys (2000) When a retired engineer is called upon to rescue a failing satellite, he insists that his equally old teammates accompany him into space.
published: 01 Mar 2017 -
Space Cowboys
Space Cowboys 2000 When a retired engineer is called upon to rescue a failing satellite, he insists that his equally old teammates accompany him into space. Director: Clint Eastwood Writers: Ken Kaufman, Howard Klausner Stars: Clint Eastwood# Tommy Lee Jones# Donald Sutherland
published: 15 Dec 2016 -
Flat Earth? Thermal Radiation Physics Virgin Galactic Telecom
So ALL satellites and cooling systems are PERFECTLY made, that NONE ever broken? Hmm Or are they sending technicians every now and then to do service of thousands of satellites and cooling systems? Satellite Thermal Control Engineering PowerPoint slides: http://www.tak2000.com/data/Satellite... ISS Cooling System per Space.com: http://www.space.com/21059-space-stat... [Engineer Brian Mullin's channel: https://www.youtube.com/channel/UCArBP0HP6aYpSVQQ4YbuYqQ] ~*~*~*~*~*~*~*~*~*~*~*~*~*~*~*~*~*~*~*~ Copyright Disclaimer Under Section 107 of the Copyright Act 1976, allowance is made for "fair use" for purposes such as criticism, comment, news reporting, teaching, scholarship, and research. Fair use is a use permitted by copyright statute that might otherwise be infringing. Non-profit, e...
published: 13 Jan 2017
Satellite Engineering
- Order: Reorder
- Duration: 41:49
- Updated: 28 Oct 2013
- views: 6856
Lecture: Satellite Engineering
Julien Tallineau - Physics and Space System Engineer, QinetiQ Space nv
Lecture: Satellite Engineering
Julien Tallineau - Physics and Space System Engineer, QinetiQ Space nv
https://wn.com/Satellite_Engineering
Ball's Out Physics Episode 4.1: Virgin Galactic, Telecom, & Thermal Radiation
- Order: Reorder
- Duration: 43:26
- Updated: 29 Mar 2016
- views: 27759
DroidFuel's "Space is Hard": https://www.youtube.com/watch?v=vbTaJPD3oLs
Virgin Galactic - Human Spaceflight: http://www.virgingalactic.com/human-spaceflight/
...
DroidFuel's "Space is Hard": https://www.youtube.com/watch?v=vbTaJPD3oLs
Virgin Galactic - Human Spaceflight: http://www.virgingalactic.com/human-spaceflight/
Balls Out Physics Episode 4.0: https://www.youtube.com/watch?v=_HaCEMy28u4
Satellite Thermal Control Engineering PowerPoint slides: http://www.tak2000.com/data/Satellite_TC.pdf
ISS Cooling System per Space.com: http://www.space.com/21059-space-station-cooling-system-explained-infographic.html
https://wn.com/Ball's_Out_Physics_Episode_4.1_Virgin_Galactic,_Telecom,_Thermal_Radiation
DroidFuel's "Space is Hard": https://www.youtube.com/watch?v=vbTaJPD3oLs
Virgin Galactic - Human Spaceflight: http://www.virgingalactic.com/human-spaceflight/
Balls Out Physics Episode 4.0: https://www.youtube.com/watch?v=_HaCEMy28u4
Satellite Thermal Control Engineering PowerPoint slides: http://www.tak2000.com/data/Satellite_TC.pdf
ISS Cooling System per Space.com: http://www.space.com/21059-space-station-cooling-system-explained-infographic.html
- published: 29 Mar 2016
- views: 27759
Elon Musk comments on Falcon 9 explosion - Huge Blow for SpaceX (2015.7.7)
- Order: Reorder
- Duration: 53:04
- Updated: 08 Jul 2015
- views: 211864
A week following SpaceX CRS-7 explosion, Elon Musk speaks at the ISS R&D; conference where he comments on the regrettable incident and the current efforts underw...
A week following SpaceX CRS-7 explosion, Elon Musk speaks at the ISS R&D; conference where he comments on the regrettable incident and the current efforts underway at SpaceX to identify the source(s) of the problem. He also touches other subjects surrounding SpaceX.
Overview:
00:00. Intro
02:44. SpaceX CRS-7 explosion and post-analysis
09:20. Reusable rockets
12:14. Why space?
19:50. Manned flights
21:52. Dragon 2 applications
Q&A;
26:40. How to keep going
28:37. Solar energy and Mars exploration
31:00. Role of government in SpaceX success
35:55. R&D; spendings strategy
38:05. 3D printed SuperDraco engines
40:52. Hyperloop & SpaceX
42:22. Coolness of ISS (International Space Station)
45:10. SpaceX space suit design
46:40. Internet satellites project
50:45. Virtual reality in Space
Date: July 7, 2015
Elon was 44 years old
https://wn.com/Elon_Musk_Comments_On_Falcon_9_Explosion_Huge_Blow_For_Spacex_(2015.7.7)
A week following SpaceX CRS-7 explosion, Elon Musk speaks at the ISS R&D; conference where he comments on the regrettable incident and the current efforts underway at SpaceX to identify the source(s) of the problem. He also touches other subjects surrounding SpaceX.
Overview:
00:00. Intro
02:44. SpaceX CRS-7 explosion and post-analysis
09:20. Reusable rockets
12:14. Why space?
19:50. Manned flights
21:52. Dragon 2 applications
Q&A;
26:40. How to keep going
28:37. Solar energy and Mars exploration
31:00. Role of government in SpaceX success
35:55. R&D; spendings strategy
38:05. 3D printed SuperDraco engines
40:52. Hyperloop & SpaceX
42:22. Coolness of ISS (International Space Station)
45:10. SpaceX space suit design
46:40. Internet satellites project
50:45. Virtual reality in Space
Date: July 7, 2015
Elon was 44 years old
- published: 08 Jul 2015
- views: 211864
Space Engineers Inspiration - Episode 109: Mercury Aircraft, Magnus Capital Ship, Brionic Satellite
- Order: Reorder
- Duration: 38:43
- Updated: 28 Aug 2016
- views: 4936
Welcome to the Space Engineers Inspiration series!! I'm basically going to be picking out random ships/maps that I just find really awesome or impressive & doin...
Welcome to the Space Engineers Inspiration series!! I'm basically going to be picking out random ships/maps that I just find really awesome or impressive & doing walkthrough/showcase kind of thing to show all of you some of the really crazy stuff the community has done! There will always be links to the download page along with the author's name so that you can check them out yourself too.
Check out my Patreon page if you would like to support my channel: http://www.patreon.com/SKS
Sleepless Knights Studios group on Steam: http://steamcommunity.com/groups/SKStudios
This Episode's Links:
Mercury Vanilla Aircraft by Rose: http://steamcommunity.com/sharedfiles/filedetails/?id=750999552
[SMI] Magnus Capital Ship by wolverind: http://steamcommunity.com/sharedfiles/filedetails/?id=752260456
(Vanilla)Brionac Satellite Gun by YINKY: http://steamcommunity.com/sharedfiles/filedetails/?id=751559330
NOTE: These are in no way shape or form connected to ME. I had NO hand in making these I'm just showcasing them, they are totally someone else's work!
You can get the game on from its website below or from Steam
Space Engineers Website: http://www.spaceengineersgame.com/
Disclaimer:
Space Engineers is property of Keen Software House
https://wn.com/Space_Engineers_Inspiration_Episode_109_Mercury_Aircraft,_Magnus_Capital_Ship,_Brionic_Satellite
Welcome to the Space Engineers Inspiration series!! I'm basically going to be picking out random ships/maps that I just find really awesome or impressive & doing walkthrough/showcase kind of thing to show all of you some of the really crazy stuff the community has done! There will always be links to the download page along with the author's name so that you can check them out yourself too.
Check out my Patreon page if you would like to support my channel: http://www.patreon.com/SKS
Sleepless Knights Studios group on Steam: http://steamcommunity.com/groups/SKStudios
This Episode's Links:
Mercury Vanilla Aircraft by Rose: http://steamcommunity.com/sharedfiles/filedetails/?id=750999552
[SMI] Magnus Capital Ship by wolverind: http://steamcommunity.com/sharedfiles/filedetails/?id=752260456
(Vanilla)Brionac Satellite Gun by YINKY: http://steamcommunity.com/sharedfiles/filedetails/?id=751559330
NOTE: These are in no way shape or form connected to ME. I had NO hand in making these I'm just showcasing them, they are totally someone else's work!
You can get the game on from its website below or from Steam
Space Engineers Website: http://www.spaceengineersgame.com/
Disclaimer:
Space Engineers is property of Keen Software House
- published: 28 Aug 2016
- views: 4936
Gravity FULL MOVIE
- Order: Reorder
- Duration: 1:37:10
- Updated: 26 Sep 2015
- views: 32035
The crew of the Space Shuttle Explorer is working on the STS-157 mission. http://bit.ly/Gravity020
Mission Commander Matt Kowalski, medical engineer Dr. Ryan S...
The crew of the Space Shuttle Explorer is working on the STS-157 mission. http://bit.ly/Gravity020
Mission Commander Matt Kowalski, medical engineer Dr. Ryan Stone - who is on her first ever space mission - and flight engineer Shariff Dasari are on a space walk when they learn from Houston control that an explosion has just occurred at a Russian satellite. Before the crew can do anything about it, the explosion debris comes hurtling toward Explorer, irreparably damaging the shuttle and station, immediately killing all the crew except Kowalski and Stone, and knocking out at least incoming communication with Houston control, although they have no idea if there is outgoing communication. The two are left in a precarious position as Stone is untethered with quickly decreasing oxygen on her person meaning that Kowalski has to retrieve her quickly if she has any chance of survival. Even if he can retrieve her and get her some oxygen, they have the difficult task of trying to get to another satellite with whatever equipment is on hand, and from there ultimately back to Earth. Through the process, they are often on their own without the other leading to an extreme feeling of isolation which leads to individual questions and ultimate decisions about their own mortality and what may be best for the other at the expense of oneself.
https://wn.com/Gravity_Full_Movie
The crew of the Space Shuttle Explorer is working on the STS-157 mission. http://bit.ly/Gravity020
Mission Commander Matt Kowalski, medical engineer Dr. Ryan Stone - who is on her first ever space mission - and flight engineer Shariff Dasari are on a space walk when they learn from Houston control that an explosion has just occurred at a Russian satellite. Before the crew can do anything about it, the explosion debris comes hurtling toward Explorer, irreparably damaging the shuttle and station, immediately killing all the crew except Kowalski and Stone, and knocking out at least incoming communication with Houston control, although they have no idea if there is outgoing communication. The two are left in a precarious position as Stone is untethered with quickly decreasing oxygen on her person meaning that Kowalski has to retrieve her quickly if she has any chance of survival. Even if he can retrieve her and get her some oxygen, they have the difficult task of trying to get to another satellite with whatever equipment is on hand, and from there ultimately back to Earth. Through the process, they are often on their own without the other leading to an extreme feeling of isolation which leads to individual questions and ultimate decisions about their own mortality and what may be best for the other at the expense of oneself.
- published: 26 Sep 2015
- views: 32035
Space Cowboys (2000) with Tommy Lee Jones, Donald Sutherland, Clint Eastwood Movie
- Order: Reorder
- Duration: 1:53:25
- Updated: 27 Sep 2016
- views: 815
When an engineer is gotten a phone to repair a failing satellite, he supposes that he & his colleagues got into space.
When an engineer is gotten a phone to repair a failing satellite, he supposes that he & his colleagues got into space.
https://wn.com/Space_Cowboys_(2000)_With_Tommy_Lee_Jones,_Donald_Sutherland,_Clint_Eastwood_Movie
When an engineer is gotten a phone to repair a failing satellite, he supposes that he & his colleagues got into space.
- published: 27 Sep 2016
- views: 815
Satellite Launch | 3x12 | The Nidd Whitelist | Space Engineers
- Order: Reorder
- Duration: 45:53
- Updated: 11 Feb 2016
- views: 634
Minty and I launch my communications satellite into space using my reusable first-stage boosters.
To see who plays on this server and what mods we use, go here...
Minty and I launch my communications satellite into space using my reusable first-stage boosters.
To see who plays on this server and what mods we use, go here: http://thenidd.com/server-list/space-engineers/the-nidd-whitelisted/
-------------------------------------------------
ABOUT
This channel is a hobby that exists to somehow validate the many hours spent in front of a screen by producing something at the end of it all. Nothing new or great, but someone might enjoy it.
--------------------------------------------------
LINKS
Website: http://thenidd.com/
Steam Group: http://steamcommunity.com/groups/TheNidd
Google+: http://goo.gl/u3IizR
Facebook: http://goo.gl/xXtfy8
Twitter: http://goo.gl/oDkSHk
https://wn.com/Satellite_Launch_|_3X12_|_The_Nidd_Whitelist_|_Space_Engineers
Minty and I launch my communications satellite into space using my reusable first-stage boosters.
To see who plays on this server and what mods we use, go here: http://thenidd.com/server-list/space-engineers/the-nidd-whitelisted/
-------------------------------------------------
ABOUT
This channel is a hobby that exists to somehow validate the many hours spent in front of a screen by producing something at the end of it all. Nothing new or great, but someone might enjoy it.
--------------------------------------------------
LINKS
Website: http://thenidd.com/
Steam Group: http://steamcommunity.com/groups/TheNidd
Google+: http://goo.gl/u3IizR
Facebook: http://goo.gl/xXtfy8
Twitter: http://goo.gl/oDkSHk
- published: 11 Feb 2016
- views: 634
Space Cowboys (2000) Movie - Clint Eastwood, Tommy Lee Jones, Donald Sutherland
- Order: Reorder
- Duration: 1:48:43
- Updated: 01 Mar 2017
- views: 593
Space Cowboys (2000) When a retired engineer is called upon to rescue a failing satellite, he insists that his equally old teammates accompany him into space.
Space Cowboys (2000) When a retired engineer is called upon to rescue a failing satellite, he insists that his equally old teammates accompany him into space.
https://wn.com/Space_Cowboys_(2000)_Movie_Clint_Eastwood,_Tommy_Lee_Jones,_Donald_Sutherland
Space Cowboys (2000) When a retired engineer is called upon to rescue a failing satellite, he insists that his equally old teammates accompany him into space.
- published: 01 Mar 2017
- views: 593
Space Cowboys
- Order: Reorder
- Duration: 1:48:43
- Updated: 15 Dec 2016
- views: 488
Space Cowboys 2000
When a retired engineer is called upon to rescue a failing satellite, he insists that his equally old teammates accompany him into space.
Dir...
Space Cowboys 2000
When a retired engineer is called upon to rescue a failing satellite, he insists that his equally old teammates accompany him into space.
Director: Clint Eastwood
Writers: Ken Kaufman, Howard Klausner
Stars: Clint Eastwood# Tommy Lee Jones# Donald Sutherland
https://wn.com/Space_Cowboys
Space Cowboys 2000
When a retired engineer is called upon to rescue a failing satellite, he insists that his equally old teammates accompany him into space.
Director: Clint Eastwood
Writers: Ken Kaufman, Howard Klausner
Stars: Clint Eastwood# Tommy Lee Jones# Donald Sutherland
- published: 15 Dec 2016
- views: 488
Flat Earth? Thermal Radiation Physics Virgin Galactic Telecom
- Order: Reorder
- Duration: 43:26
- Updated: 13 Jan 2017
- views: 3759
So ALL satellites and cooling systems are PERFECTLY made, that NONE ever broken? Hmm
Or are they sending technicians every now and then to do service of thousa...
So ALL satellites and cooling systems are PERFECTLY made, that NONE ever broken? Hmm
Or are they sending technicians every now and then to do service of thousands of satellites and cooling systems?
Satellite Thermal Control Engineering PowerPoint slides: http://www.tak2000.com/data/Satellite...
ISS Cooling System per Space.com: http://www.space.com/21059-space-stat...
[Engineer Brian Mullin's channel: https://www.youtube.com/channel/UCArBP0HP6aYpSVQQ4YbuYqQ]
~*~*~*~*~*~*~*~*~*~*~*~*~*~*~*~*~*~*~*~
Copyright Disclaimer Under Section 107 of the Copyright Act 1976, allowance is made for "fair use" for purposes such as criticism, comment, news reporting, teaching, scholarship, and research. Fair use is a use permitted by copyright statute that might otherwise be infringing. Non-profit, educational or personal use tips the balance in favor of fair use. All copyrighted materials contained herein belong to their respective copyright holders, I do not claim ownership over any of these materials. I realize no profit, monetary or otherwise, from the exhibition of these videos.
https://wn.com/Flat_Earth_Thermal_Radiation_Physics_Virgin_Galactic_Telecom
So ALL satellites and cooling systems are PERFECTLY made, that NONE ever broken? Hmm
Or are they sending technicians every now and then to do service of thousands of satellites and cooling systems?
Satellite Thermal Control Engineering PowerPoint slides: http://www.tak2000.com/data/Satellite...
ISS Cooling System per Space.com: http://www.space.com/21059-space-stat...
[Engineer Brian Mullin's channel: https://www.youtube.com/channel/UCArBP0HP6aYpSVQQ4YbuYqQ]
~*~*~*~*~*~*~*~*~*~*~*~*~*~*~*~*~*~*~*~
Copyright Disclaimer Under Section 107 of the Copyright Act 1976, allowance is made for "fair use" for purposes such as criticism, comment, news reporting, teaching, scholarship, and research. Fair use is a use permitted by copyright statute that might otherwise be infringing. Non-profit, educational or personal use tips the balance in favor of fair use. All copyrighted materials contained herein belong to their respective copyright holders, I do not claim ownership over any of these materials. I realize no profit, monetary or otherwise, from the exhibition of these videos.
- published: 13 Jan 2017
- views: 3759
- Playlist
- Chat
3:36
Day in the Life: Satellite Operations Engineer
As part of ConnectEd's "Day in the Life" series, we interview Veronica Navarro, a Satellit...
published: 22 Aug 2011
Day in the Life: Satellite Operations Engineer
Day in the Life: Satellite Operations Engineer
- Report rights infringement
- published: 22 Aug 2011
- views: 7399
41:49
Satellite Engineering
Lecture: Satellite Engineering
Julien Tallineau - Physics and Space System Engineer, Qinet...
published: 28 Oct 2013
Satellite Engineering
Satellite Engineering
- Report rights infringement
- published: 28 Oct 2013
- views: 6856
34:43
Pro. Engineer Explains Problems with the ISS, Satellites & the Thermosphere. Flat Earth.
We thank you for your support: http://www.AzimuthalEquidistant.org "...more and more Pro...
published: 09 Jul 2016
Pro. Engineer Explains Problems with the ISS, Satellites & the Thermosphere. Flat Earth.
Pro. Engineer Explains Problems with the ISS, Satellites & the Thermosphere. Flat Earth.
- Report rights infringement
- published: 09 Jul 2016
- views: 22466
3:57
Day in the Life of Stefanie Kohl -- Space Systems Engineer, Surrey Satellite Technology Ltd
Space Systems Engineer Stefanie Kohl leads us around the satellite assembly and testing fa...
published: 09 Nov 2012
Day in the Life of Stefanie Kohl -- Space Systems Engineer, Surrey Satellite Technology Ltd
Day in the Life of Stefanie Kohl -- Space Systems Engineer, Surrey Satellite Technology Ltd
- Report rights infringement
- published: 09 Nov 2012
- views: 1569
3:15
Packaging and Deployment of Boeing Satellites with Engineer Keith Watts
How do you send satellites into space? Boeing engineer, Keith Watts, helps make sure satel...
published: 13 Jul 2015
Packaging and Deployment of Boeing Satellites with Engineer Keith Watts
Packaging and Deployment of Boeing Satellites with Engineer Keith Watts
- Report rights infringement
- published: 13 Jul 2015
- views: 755
3:21
Origami in Space: BYU-designed solar arrays inspired by origami
Origami is a source of inspiration for BYU mechanical engineers who are working with the N...
published: 27 Nov 2013
Origami in Space: BYU-designed solar arrays inspired by origami
Origami in Space: BYU-designed solar arrays inspired by origami
- Report rights infringement
- published: 27 Nov 2013
- views: 116754
1:50
Deploying Satellites with Boeing Engineer Keith Watts
When Boeing engineer Keith Watts designs and builds a satellite, he has to think how the s...
published: 13 Jul 2015
Deploying Satellites with Boeing Engineer Keith Watts
Deploying Satellites with Boeing Engineer Keith Watts
- Report rights infringement
- published: 13 Jul 2015
- views: 453
2:49
Crazy Engineering: CubeSats
Honey, I shrunk the satellites! Mini-satellites are following in the footsteps of cell pho...
published: 03 Dec 2015
Crazy Engineering: CubeSats
Crazy Engineering: CubeSats
- Report rights infringement
- published: 03 Dec 2015
- views: 83456
6:34
Can We Create Artificial Gravity?
Thanks for watching! I actually had an early version of this ready last week. Which you ca...
published: 29 Jun 2016
Can We Create Artificial Gravity?
Can We Create Artificial Gravity?
- Report rights infringement
- published: 29 Jun 2016
- views: 606159
7:36
The Biggest Rocket ever Designed? - The Sea Dragon
In the history of space, one rocket stands out as an icon of not only the space race but o...
published: 02 Apr 2017
The Biggest Rocket ever Designed? - The Sea Dragon
The Biggest Rocket ever Designed? - The Sea Dragon
- Report rights infringement
- published: 02 Apr 2017
- views: 5469
- Playlist
- Chat
3:36
Day in the Life: Satellite Operations Engineer
As part of ConnectEd's "Day in the Life" series, we interview Veronica Navarro, a Satellit...
published: 22 Aug 2011
Day in the Life: Satellite Operations Engineer
Day in the Life: Satellite Operations Engineer
- Report rights infringement
- published: 22 Aug 2011
- views: 7399
41:49
Satellite Engineering
Lecture: Satellite Engineering
Julien Tallineau - Physics and Space System Engineer, Qinet...
published: 28 Oct 2013
Satellite Engineering
Satellite Engineering
- Report rights infringement
- published: 28 Oct 2013
- views: 6856
34:43
Pro. Engineer Explains Problems with the ISS, Satellites & the Thermosphere. Flat Earth.
We thank you for your support: http://www.AzimuthalEquidistant.org "...more and more Pro...
published: 09 Jul 2016
Pro. Engineer Explains Problems with the ISS, Satellites & the Thermosphere. Flat Earth.
Pro. Engineer Explains Problems with the ISS, Satellites & the Thermosphere. Flat Earth.
- Report rights infringement
- published: 09 Jul 2016
- views: 22466
3:57
Day in the Life of Stefanie Kohl -- Space Systems Engineer, Surrey Satellite Technology Ltd
Space Systems Engineer Stefanie Kohl leads us around the satellite assembly and testing fa...
published: 09 Nov 2012
Day in the Life of Stefanie Kohl -- Space Systems Engineer, Surrey Satellite Technology Ltd
Day in the Life of Stefanie Kohl -- Space Systems Engineer, Surrey Satellite Technology Ltd
- Report rights infringement
- published: 09 Nov 2012
- views: 1569
3:15
Packaging and Deployment of Boeing Satellites with Engineer Keith Watts
How do you send satellites into space? Boeing engineer, Keith Watts, helps make sure satel...
published: 13 Jul 2015
Packaging and Deployment of Boeing Satellites with Engineer Keith Watts
Packaging and Deployment of Boeing Satellites with Engineer Keith Watts
- Report rights infringement
- published: 13 Jul 2015
- views: 755
3:21
Origami in Space: BYU-designed solar arrays inspired by origami
Origami is a source of inspiration for BYU mechanical engineers who are working with the N...
published: 27 Nov 2013
Origami in Space: BYU-designed solar arrays inspired by origami
Origami in Space: BYU-designed solar arrays inspired by origami
- Report rights infringement
- published: 27 Nov 2013
- views: 116754
1:50
Deploying Satellites with Boeing Engineer Keith Watts
When Boeing engineer Keith Watts designs and builds a satellite, he has to think how the s...
published: 13 Jul 2015
Deploying Satellites with Boeing Engineer Keith Watts
Deploying Satellites with Boeing Engineer Keith Watts
- Report rights infringement
- published: 13 Jul 2015
- views: 453
2:49
Crazy Engineering: CubeSats
Honey, I shrunk the satellites! Mini-satellites are following in the footsteps of cell pho...
published: 03 Dec 2015
Crazy Engineering: CubeSats
Crazy Engineering: CubeSats
- Report rights infringement
- published: 03 Dec 2015
- views: 83456
6:34
Can We Create Artificial Gravity?
Thanks for watching! I actually had an early version of this ready last week. Which you ca...
published: 29 Jun 2016
Can We Create Artificial Gravity?
Can We Create Artificial Gravity?
- Report rights infringement
- published: 29 Jun 2016
- views: 606159
7:36
The Biggest Rocket ever Designed? - The Sea Dragon
In the history of space, one rocket stands out as an icon of not only the space race but o...
published: 02 Apr 2017
The Biggest Rocket ever Designed? - The Sea Dragon
The Biggest Rocket ever Designed? - The Sea Dragon
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- published: 02 Apr 2017
- views: 5469
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41:49
Satellite Engineering
Lecture: Satellite Engineering
Julien Tallineau - Physics and Space System Engineer, Qinet...
published: 28 Oct 2013
Satellite Engineering
Satellite Engineering
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- published: 28 Oct 2013
- views: 6856
43:26
Ball's Out Physics Episode 4.1: Virgin Galactic, Telecom, & Thermal Radiation
DroidFuel's "Space is Hard": https://www.youtube.com/watch?v=vbTaJPD3oLs
Virgin Galactic ...
published: 29 Mar 2016
Ball's Out Physics Episode 4.1: Virgin Galactic, Telecom, & Thermal Radiation
Ball's Out Physics Episode 4.1: Virgin Galactic, Telecom, & Thermal Radiation
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- published: 29 Mar 2016
- views: 27759
53:04
Elon Musk comments on Falcon 9 explosion - Huge Blow for SpaceX (2015.7.7)
A week following SpaceX CRS-7 explosion, Elon Musk speaks at the ISS R&D; conference where ...
published: 08 Jul 2015
Elon Musk comments on Falcon 9 explosion - Huge Blow for SpaceX (2015.7.7)
Elon Musk comments on Falcon 9 explosion - Huge Blow for SpaceX (2015.7.7)
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- published: 08 Jul 2015
- views: 211864
38:43
Space Engineers Inspiration - Episode 109: Mercury Aircraft, Magnus Capital Ship, Brionic Satellite
Welcome to the Space Engineers Inspiration series!! I'm basically going to be picking out ...
published: 28 Aug 2016
Space Engineers Inspiration - Episode 109: Mercury Aircraft, Magnus Capital Ship, Brionic Satellite
Space Engineers Inspiration - Episode 109: Mercury Aircraft, Magnus Capital Ship, Brionic Satellite
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- published: 28 Aug 2016
- views: 4936
1:37:10
Gravity FULL MOVIE
The crew of the Space Shuttle Explorer is working on the STS-157 mission. http://bit.ly/Gr...
published: 26 Sep 2015
Gravity FULL MOVIE
Gravity FULL MOVIE
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- published: 26 Sep 2015
- views: 32035
1:53:25
Space Cowboys (2000) with Tommy Lee Jones, Donald Sutherland, Clint Eastwood Movie
When an engineer is gotten a phone to repair a failing satellite, he supposes that he & hi...
published: 27 Sep 2016
Space Cowboys (2000) with Tommy Lee Jones, Donald Sutherland, Clint Eastwood Movie
Space Cowboys (2000) with Tommy Lee Jones, Donald Sutherland, Clint Eastwood Movie
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- published: 27 Sep 2016
- views: 815
45:53
Satellite Launch | 3x12 | The Nidd Whitelist | Space Engineers
Minty and I launch my communications satellite into space using my reusable first-stage bo...
published: 11 Feb 2016
Satellite Launch | 3x12 | The Nidd Whitelist | Space Engineers
Satellite Launch | 3x12 | The Nidd Whitelist | Space Engineers
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- published: 11 Feb 2016
- views: 634
1:48:43
Space Cowboys (2000) Movie - Clint Eastwood, Tommy Lee Jones, Donald Sutherland
Space Cowboys (2000) When a retired engineer is called upon to rescue a failing satellite,...
published: 01 Mar 2017
Space Cowboys (2000) Movie - Clint Eastwood, Tommy Lee Jones, Donald Sutherland
Space Cowboys (2000) Movie - Clint Eastwood, Tommy Lee Jones, Donald Sutherland
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- published: 01 Mar 2017
- views: 593
1:48:43
Space Cowboys
Space Cowboys 2000
When a retired engineer is called upon to rescue a failing satellite, h...
published: 15 Dec 2016
Space Cowboys
Space Cowboys
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- published: 15 Dec 2016
- views: 488
43:26
Flat Earth? Thermal Radiation Physics Virgin Galactic Telecom
So ALL satellites and cooling systems are PERFECTLY made, that NONE ever broken? Hmm
Or a...
published: 13 Jan 2017
Flat Earth? Thermal Radiation Physics Virgin Galactic Telecom
Flat Earth? Thermal Radiation Physics Virgin Galactic Telecom
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- published: 13 Jan 2017
- views: 3759
Satellite Engineering...
Ball's Out Physics Episode 4.1: Virgin Galactic, T...
Elon Musk comments on Falcon 9 explosion - Huge Bl...
Space Engineers Inspiration - Episode 109: Mercury...
Gravity FULL MOVIE...
Space Cowboys (2000) with Tommy Lee Jones, Donald ...
Satellite Launch | 3x12 | The Nidd Whitelist | Spa...
Space Cowboys (2000) Movie - Clint Eastwood, Tommy...
Space Cowboys...
Flat Earth? Thermal Radiation Physics Virgin Galac...
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Everything you need to know about why Julian Assange is still in the Ecuadorian embassy
Edit Irish Independent 19 Jun 2017
Julian Assange has now been holed-up in London’s Ecuadorian embassy for five years, but what took him there and why is he so controversial?. Here’s everything you need to know about the man behind Wikileaks and why he’s so unpopular with security officials. Who is Julian Assange?. Assange is an Australian computer programmer, who gained notoriety with cyber-security authorities as a teenage hacker in the late 1980s ... What is Wikileaks? ... ....
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US Shoots Down Syria Warplane in Raqqa Province
Edit News18 19 Jun 2017
Amman/Washington ... ....
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'Donald Trump's Cuba policy takes us back to the Cold War era'
Edit Mid Day 19 Jun 2017
The revised policy aims to halt the flow of US cash to Cuban military ... Trump vowed Friday to overhaul his predecessor Barack Obama's deal to restore ties with Cuba ... Trending Videos. Watch Video....
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Is Finsbury park attack a hate crime or an act of terrorism?
Edit International Business Times 19 Jun 2017
In the absence of a universal definition, how can one decide if an attack is an act of terrorism or hate crime? ... ....
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Pop superstar Beyonce gives birth to twins, hints her dad
Edit The Jakarta Post 19 Jun 2017
Pop diva Beyonce and her rap mogul husband Jay Z have welcomed twins, the US singer's father tweeted Sunday, appearing to confirm the arrival of new additions to a music family that already includes five-year-old Blue Ivy ... "They're here! #beyonce #twins #jayz #happybirthday," Mathew Knowles wrote on Twitter, though there was no such comment from Beyonce or Jay Z ... "We would like to share our love and happiness ... ....
1st LD: New broadcasting satellite fails to enter preset orbit
Edit Xinhua 19 Jun 2017
The solar panels and communication antennae, however, have been deployed and the satellite system is operating under normal conditions, according to the CASC....
Global Latest Satellite Payloads Market Analysis Report to 2021
Edit Community news 19 Jun 2017
Satellite Payloads Market Report by Material, Application, and Geography – Global Forecast to 2021 is a professional and in-depth research report on the world’s major regional market conditions, focusing on the main regions (North America, Europe and Asia-Pacific) and the main countries (United States, Germany, United Kingdom, Japan, South Korea and China) ... The report firstly introduced the Satellite Payloads basics....
China's 'Unhackable' Quantum Satellite Has Sent Its First Message
Edit Huffington Post 19 Jun 2017
China has successfully shown that its experimental ‘quantum satellite’ can send an encrypted message over potentially huge distances. The satellite has the ability to send ‘unhackable’ messages by encrypting them using quantum mechanics ... How does a quantum satellite work? ... China launched the satellite in August 2016 and has been steadily increasing the scope of its experiments....
SES Transfers Capacity from AMC-9 Satellite Following Significant Anomaly
Edit Market Watch 19 Jun 2017
LUXEMBOURG, Jun 19, 2017 (BUSINESS WIRE) -- SES (euronext paris.SESG) (luxx.SESG) announced that, following a significant anomaly, the company is in the process of transferring capacity from its AMC-9 satellite ... SES has taken immediate action in contacting all customers and is working to transfer services to alternative satellite capacity in order to minimise disruption ... https.//www.facebook.com/SES.Satellites....
SpaceX delays Bulgaria satellite again, plans 'doubleheader'
Edit Orlando Sentinel 19 Jun 2017
SpaceX CEO Elon Musk said Sunday that the rocket launch company could be in line for a twin bill this weekend. At about 3.29 p.m., the company posted on Twitter that its launch of a Bulgarian satellite, which had been planned for Monday morning, was going to be pushed back to either Friday or Saturday ... ....
How Tiny Satellites Are Changing The Way We Do Business
Edit Fast Company 19 Jun 2017
A number of companies use satellite imagery to predict annual farm yields—mostly focusing on major crops like wheat, corn and soy—and produce estimations that are useful for farmers and commodities traders alike ... Before the era of CubeSats, government-owned satellites tended to cover only the more populated areas of earth—leaving remote corners of the ocean in the dark....
Virginia spaceport plan hones in on rockets, drones and student satellites
Edit Daily Press 19 Jun 2017
Last month, when Gov. Terry McAuliffe made headlines and history by flying aboard an unpiloted Centaur aircraft on the Eastern Shore, it did more than officially kick off the state's new $5 million drone runway. It also ticked a key box in Virginia Space's five-year strategic plan to expand its ... ....
China sends 'unhackable' message using quantum satellite
Edit The Inquirer 19 Jun 2017
Breakthrough could pave the way for highly secure communications ... ....
Largest virtual universe may help solve dark matter mystery
Edit The Siasat Daily 19 Jun 2017
The gigantic catalogue of about 25 billion virtual galaxies generated from 2 trillion digital particles using a super computer is being used to calibrate the experiments on board the Euclid satellite, that will be launched in 2020. The satellite will investigate the nature of dark matter and dark energy....
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