Showing posts with label Alzheimer’s Risk for Spacefarers. Show all posts
Showing posts with label Alzheimer’s Risk for Spacefarers. Show all posts

Wednesday, January 16, 2013

'SPACE' in News



Cause of Breeze-M Failure Discovered
Final assembly of the Breeze-M at the Khrunichev Center 

Roscosmos has determined the cause of an underperforming Breeze-M upper stage on December 8 to be a broken turbopump bearing.

The incident occurred when a Proton-M with Breeze-M upper stage launched from Baikonour Cosmodrome in Kazakhstan on December 8 carrying Gazprom telecommunication satellite Yamal-402, built by Thales Alenia Space. The Breeze-M released the satellite four minutes early due to four shortened burns, ending well short of the intended orbit. Yamal-402 was eventually nudged into the correct highly elliptical orbit by means of its own emergency propellant reserve. The successful maneuver was conducted via four burns that cost the satellite four years of operational life, concluding on December 15. The satellite is now expected to last 11 years.

The Breeze-M C5.98 rocket turbopump assembly in question is said to have been produced by Isaev Khimmash design center, located near Moscow. Khimmash has accepted responsibility, although the bearing itself was purchased from an undisclosed third party.

Final results of the investigation are expected to be officially announced by the end of the year, although Kommersant reports that the announcement has been delayed seven times already because of disagreement among the investigation panel as to appropriate corrective action. In the meantime, Roscosmos is preparing to check all turbopumps that may be affected. This follows just months after all Breeze-M units were inspected as a result of an August 6 failure whose cause was declared to be a ”manufacturing defect.” That incident resulted in an orbital debris explosion and loss of communication satellites Telkom-3 and Ekspress-MD2. The investigation into the incident continued for weeks and ended with the announcement of a complete reorganization of the Russian space industry into a model that promises an increased governmental role.


Bigelow Contract Could Bring Inflatable Module to ISS by 2016
The Bigelow Expandable Activity Module (BEAM) on the ISS as it
should appear in 2016 
Bigelow Aerospace and NASA have signed a $17.8 million contract that could bring an inflatable module to be attached on the International Space Station.

NASA spokesman Trent Perrotto told Space News that the deal was signed in late December 2012, but he did not reveal the terms of the agreement, saying only that it centers on the Bigelow Expanded Aerospace Module (BEAM).

Although the details will be revealed later, it can be supposed that BEAM would be an inflatable addition to ISS, proving out the technologies and paving the way for future commercial space stations. The deployment of the module will represent a perfect demonstration for habitation and storage in a space environment, giving also significant data on the duration of inflatable modules compared to the existing metallic ones. According to NASA officials, the agency will ask one of its Commercial Resupply Services contractors, SpaceX or Orbital Sciences Corp., to carry BEAM to the ISS, most likely before the end of 2016.

Bigelow Aerospace, situated in Las Vegas, Nevada, has been in the space station business for several years, having deployed two orbiting prototypes called Genesis 1 and 2 in 2006 and 2007 respectivley, both launched with Russian rockets. In 2010, Bigelow won a nonpaying contract with NASA to develop a list of procedures and protocols to add BEAM to ISS. The company is now growing after a period of downturn, opening new facilities and hiring again to increase the working force up to 90 staff. Bigelow specializes in inflatable space habitat technology that it aquired from NASA. The company has aspirations to open a Commerical Space Station using the modules.

Meanwhile in Russia, RSC Energia has signed an important contract with Roscosmos to develop a draft design for for OKA-T-MKS, an orbiting unmanned lab to be connected to International Space Station. It seems clear that the ISS partners want to capitalize on the remaining funded life of the station as much as possible. ISS is currently expected to remain operational though at least 2020.

Related story
http://www.space.com/19236-space-station-inflatable-module-bigelow.html


Study Suggests Enhanced Alzheimers Risk for Spacefarers

Plaques between neurons is one of the indicators of Alzheimers
Disease and seem to be increased with GCR exposure
A study published in PLOS One on December 31 suggests that there may be unforeseen long term effects on spacefarers health. Long term exposure to heavily charged Galactic Cosmic Radiation (GCR) could increase the chances of incurring Alzheimers.

The study, which was conducted at the University of Rochester and Harvard Medical School with funding from NASA’s Space Radiobiology Research Program, exposed mice to doses of high energy, high charge (HZE) particles akin to those found in GCR. The mice received a dose of 100 cGy, equivalent to the total dose astronauts might experience on a trip to Mars. After six months, the mice experienced cognitive impairment and presented with plaques that have been correlated to Alzheimer’s disease.

It is very difficult to protect against powerful GCR radiation. ”One would have to essentially wrap a spacecraft in a 6-foot (2 meters) block of lead or concrete,” explained corresponding author M. Kerry O’Banion, something that would be clearly prohibitive for mass-constrained launches. Unlike solar radiation, GCR is emitted isotropically throughout all points in space, making avoiding such radiation nearly impossible.

Unlike astronauts, the mice received their radiation dose all at once instead of gradually over time and were irradiated with only the heaviest ion - iron – rather than a range of ions that are present in GCR. The mice were also preselected for being genetically disposed to contract Alzheimer’s. It is not known how these factors could affect the results, but it is likely that this study represents a worst case scenario for the stated conditions. “I would add that there are at least three other laboratories pursuing similar studies,” said O’Banion, so some of these questions may be answered soon.

Although the radiation hazards of space travel have been known for sometime, this is the first indication of long term effects beyond typical radiation sickness. More such effects are likely to emerge as humans spend longer periods of time in space. One such discovery was made in 2012 when it was discovered that some male astronauts’ vision became apparently permanently impacted following cumulative long duration deployments on the International Space Station and Space Shuttle.


Energomash to Develop and Test New High-Performance Rocket Fuel

Experts from Russian manufacturer NPO Energomash “V.P. Glushko” and RSC Applied Chemistry have developed a state-of-the-art high-performance rocket fuel, working on a completely novel mixture of acetylene and ammonia called Atsetam.“A mixture of acetylene and ammonia is 20 times cheaper than hydrogen, as a kilogram of hydrogen costs about 2,000 rubles ($67) and a kilo of Atsetam is maximum of 100 rubles ($3.35),” explained Energomash’s Director of Innovative Technology, Anatoly Likhvantsev.

At the beginning of December 2012, Energomash obtained the first experimental batch of Atsetam, confirming the findings of previous theoretical studies. The batch also proved the effectiveness of the technology developed for the fuel’s production. The new Atsetam fuel is not only cheaper than hydrogen but it can also be easily stored and transported, whereas hydrogen requires special storage and transportation conditions.

Energomash has also started developing an engine to work with the new mixture. The engine will be assembled on the basis of the RD-161, originally designed to work with oxygen and kerosene.  The development will not require major structural changes to existing rocket motors since the physical properties of Atsetam do not differ much from kerosene.
Energomashs liquid engines. The company has started
development of a new rocket engine using Atsetam as a
fuel, planning to reduce the cost of rocket
launches of about 1/3
Although the exact engines parameters will be determined during upcoming tests that are scheduled to last until 2016, Energomash chief executive Vladimir Solntsev is persuaded that the Atsetam fuel will help increase the efficiency of rocket engines by at least 30% in the future.

Energomash is carrying out work on processing and certifying Atsetam as a prospective rocket fuel application at its own expense, partially supported by the Skolkovo Innovation Centre. In 2013-2014, Energomash plans to develop a technology for generating industrial quantities of Atsetam. It also plans to develop a test bed and carry out firing tests of the new oxygen-Atsetam liquid propellant engine prototype.

If all goes well in the test and certification phase, and depending on funding, the first launch with the new engine will occur in 2017-2018.


Is China Preparing an Anti-Satellite Test?

U.S. experts think China is preparing to perform another anti-satellite (ASAT) test in January.

“The first media report on these rumours appeared in October,” wrote Gregory Kulacki of the Union of Concerned Scientists on a blog post dated January 4th. “China’s Ministry of Defence challenged the information in that report, but in November contacts in China told us an announcement about an upcoming ASAT test was circulated within the Chinese government.”


Rumours of an upcoming anti-satellite test have been circulating for several months in the
Debris from 2007 ASAT test involving Fengyun satellite

U.S. defence and intelligence community. China has previously carried out ASAT tests on January 11th 2007 and 2010, so it is possible that they plan to carry out the test on the same date this year. In the 2007 test China destroyed the defunct Fengyun-1C weather satellite via an anti-satellite device. The explosion created approximately 3000 pieces of debris. The 2010 test used a similar technology to destroy an object that was not in orbit.

The target of the possible test remains unclear. Some U.S. officials suspect China may want to target the medium Earth orbit (MEO) region, which can be viewed as a potential threat to the U.S. and Russian navigational satellites. However, Kulacki is not sure that the possibly imminent ASAT test, would necessarily be as destructive as the 2007 event. On the contrary, it could involve a technology that doesn’t physically destroy the satellite. Since China is planning to put more navigational satellites in MEO, it’s unlikely they would risk creating more debris which could affect their own satellites.

China is not the sole instigator of ASAT tests. Both the United States and the former Soviet Union conducted equally destructive ASAT tests during the development of their space programs. They eventually decided to stop these tests due to the danger to their own space presence; hopefully China will do the same.

Sleep Issues Could Affect Future Mars Mission

A study based on Mars500 data revealed that the crew experienced increasing lethargy over the course of the mission, resulting in hypokinesis connected to sleep disturbances.

“The success of interplanetary human spaceflight will depend on many factors,” said biomedical and psychiatric researchers from the US and Russia who published the findings in the Proceedings of the National Academy of Sciences,  “including the behavioral activity levels, sleep, and circadian timing of crews exposed to prolonged microgravity and confinement.”

In the Mars500 experiment, six volunteers were confined in a mock spaceship in Star City, Russia to simulate a 17-month journey to Mars and back. The high-fidelity ground simulation of a Mars mission was conducted to study the physical and psychological reactions of the crewmembers to isolation. The research used a number of continuous measurements including wrist actigraphy, light exposure, and weekly computer-based neurobehavioral assessments. The majority of crewmembers experienced issues connected to sleep quality resulting in a state of extended lethargy. Four had considerable trouble sleeping, with one having minor problems and the sixth mostly unaffected. It is still unknown if the men’s lethargy was just due to lack of sleep or was also caused by other factors such as lack of privacy, close quarters, or being away from their families for so long. Their state also led the crew to neglect exercise that will be extremely critical to maintaining physiological health on a long term zero gravity mission.

The loss of sleep is a crucial point in a Mars mission’s development. Astronauts will have to perform many and difficult tasks not only on their journey to Mars but also while they are on the Red Planet. Moreover there will be no real time communications with Earth, so these potentially tired and judgment-impaired astronauts will need to continually make decisions critical to their own survival.

Sleep quality is already a concern on the International Space Station where the noisy environment, microgravity, rapid solar cycle, and arrhythmic station maneuvers all contribute to less than ideal sleeping conditions. A new initiative to install blue-tinted LEDs in crew areas that can be used during rest times is expected to bring some improvements, starting with the first delivery of the lights in 2015.

The world record for continuous time in space is held by the cosmonaut Valery Polyakov, who lived on the Russian space station Mir for 14 months. In 2015, American astronaut Scott Kelly and Russian cosmonaut Mikhail Kornienko are scheduled to spend a whole year in space on the International Space Station.

Canada confirms plans for RADARSAT Constellation mission

The Canadian Space Agency announced this week that it will press ahead with the country's next-generation radar satellite imaging system, signing a contract with a Canadian firm to build the satellites. The RADARSAT Constellation system will feature three radar imaging satellites in polar orbits to provide shorter revisit times for radar imagery. MacDonald, Dettwiler and Associates (MDA) will build the three satellites under a C$706-million (US$718-million) contract announced January 9. The satellites are slated for launch in 2018 to ensure continuous service with the RADARSAT-2 satellite currently operating. There had been concerns in recent months that the program might be delayed, scaled back, or even cancelled because of funding problems.

 Competition Reshaping Launcher Industry

For decades, space-launch providers have survived, and prospered, on government support in the form of development funding, launch contracts and infrastructure subsidies to maintain access to space. That is changing as international competition increases, privately funded players enter the market and government budgets come under pressure. The result is an unprecedented set of challenges to traditional launch providers even as the industry continues to worry about future demand.

The replacement cycles of large commercial communications-satellite operators that have driven demand for launch services are nearing an end and, beginning around 2014, fewer launches are expected. In addition, budget constraints on governments are expected to limit their satellite procurements.

Europe's government-supported Ariane 5 currently launches roughly half of the world's commercial satellites, but faces increasing competition from the Russian Proton, which remains competitive despite a spate of launch mishaps. China, India and Japan are all developing potentially competing launchers, and SpaceX in the U.S. has more than $1 billion in commercial launch contracts for its privately developed, low-cost Falcon 9.

In November 2012, the European Space Agency agreed to proceed with the upgraded Ariane 5 Midlife Evolution (ME) and to continue studying a modular, lower-cost successor dubbed Ariane 6. Germany is backing the Ariane 5ME, to fly in 2017-18, and a decision has been set for 2014 on development of the French-backed Ariane 6, to enter service after 2020. French space agency CNES is studying three modular configurations for the Ariane 6, two solid-propellant and one all-liquid. All would use the Vinci cryogenic upper-stage engine under development for the 5ME.
  
Similar challenges face United Launch Alliance (ULA), which provides Atlas V and Delta IV launches for the U.S. government under the Evolved Expendable Launch Vehicle (EELV) program. The merger of Boeing and Lockheed Martin's launcher businesses to form ULA, satellite delays and NASA's withdrawal from the market have driven up launch costs under EELV.

SpaceX conducted the first of up to 12 commercial resupply missions for NASA in October 2012, its Falcon 9 launching the Dragon cargo capsule to the ISS.  Lockheed with the Athena, Orbital Sciences with the Antares and SpaceX with an upgraded Falcon 9 have formally stated their intent to certify their boosters for national security missions. Once certified, they will be allowed to compete for launches. These could begin in 2014.

While Europe sees India and Russia as its main competitors in the future, it is SpaceX that continues to shake up the market. The company conducted its first two resupply missions to the International Space Station (ISS) in 2012 using the Falcon 9 booster and Dragon cargo spacecraft, and is on contract to fly 20,000 kg to the ISS through 2015.

CCiCap is a commercial adjunct to NASA's plan to develop the heavy-lift Space Launch System (SLS) to support human spaceflight missions and replace the space shuttle, which was retired in 2012. The SLS is intended to launch the Orion multi-purpose crew vehicle—development of which began under the now-canceled Constellation program—and other equipment into deep space.

A first uncrewed flight of the SLS is planned for 2017, followed in 2021 by the first launch of the Orion capsule and up to four astronauts. The SLS will use RS-25 engines from the shuttle and the J-2X upper-stage engine developed for the canceled Ares I booster. The initial 70,000 kg-payload version of the SLS will use two shuttle-style solid-rocket boosters. The evolved version, with up to a 130,000-kg payload, will use advanced liquid or solid boosters.

As NASA develops the SLS, Russia and China will be the only countries able to transport humans into space. While Russia continues to fly the Soyuz to ferry crews to the ISS, China is developing a manned space program that includes the Shenzhou capsule (four crewed flights to 2012), Tiangong laboratory (first launch in 2011), and a space station that is planned to be launched in sections between 2015 and 2020.

A new era in commercial space transportation is open.


ASA's Robotic Refueling Demo Set to Jumpstart Expanded Capabilities in Space

This artist's concept shows a scene from the upcoming refueling demo aboard the International Space Station. The Robotic Refueling Mission, or RRM, Multifunction Tool (right) removes a cap from the RRM module (left).

In mid-January, NASA will take the next step in advancing robotic satellite-servicing technologies as it tests the Robotic Refueling Mission, or RRM aboard the International Space Station. The investigation may one day substantially impact the many satellites that deliver products Americans rely upon daily, such as weather reports, cell phones and television news.

During five days of operations, controllers from NASA and the Canadian Space Agency will use the space station's remotely operated Special Purpose Dexterous Manipulator, or Dextre, robot to simulate robotic refueling in space. Operating a space-based robotic arm from the ground is a feat on its own, but NASA will do more than just robotics work as controllers remotely snip wires, unscrew caps and transfer simulated fuel. The team also will demonstrate tools, technologies and techniques that could one day make satellites in space greener, more robust and more capable of delivering essential services to people on Earth.

Why Fix or Refuel a Satellite?

"Every satellite has a lifespan and eventual retirement date, determined by the reliability of its components and how much fuel it can carry," explains Benjamin Reed, deputy project manager of NASA's Satellite Servicing Capabilities Office, or SSCO.

Repairing and refueling satellites already in place, Reed asserts, can be far less expensive than building and launching entirely new spacecraft, potentially saving millions, even billions of dollars and many years of work.

The RRM demonstration specifically tests what it would take to repair and refuel satellites traveling the busy space highway of geosynchronous Earth orbit, or GEO. Located about 22,000 miles above Earth, this orbital path is home to more than 400 satellites, many of which beam communications, television and weather data to customers worldwide.

By developing robotic capabilities to repair and refuel GEO satellites, NASA hopes to add precious years of functional life to satellites and expand options for operators who face unexpected emergencies, tougher economic demands and aging fleets. NASA also hopes that these new technologies will help boost the commercial satellite-servicing industry that is rapidly gaining momentum.

Besides aiding the GEO satellite community, a capability to fix and relocate "ailing" satellites also could help manage the growing orbital debris problem that threatens continued space operations, ultimately making space greener and more sustainable.

What's Next in Robotic Satellite Servicing?

The satellite-servicing concept that RRM is advancing is one that NASA has been developing for years. Beginning with the Solar Maximum repair mission in 1984, the servicing philosophy paved the way for five successful astronaut-based missions to upgrade and repair the Hubble Space Telescope and has been practiced more recently in spacewalks to assemble and maintain the space station.

On July 12, 2011, spacewalking astronauts Mike Fossum and Ron Garan successfully transferred the Robotic Refueling Mission, or RRM, module from the Atlantis shuttle cargo bay to a temporary platform on the International Space Stations Dextre robot.

With the RRM on the space station and a robust technology development campaign being conducted on the ground, NASA is testing capabilities for a new robotic servicing frontier. Since 2009, the Satellite Servicing Capabilities Office at NASA's Goddard Space Flight Center in Greenbelt, Md., has been aggressively advancing the robotic technologies for a free-flying servicer spacecraft that could access, repair and refuel satellites in GEO.

To this end, the SSCO team has been studying a conceptual servicing mission and building technologies to address uncharted territory such as autonomous rendezvous and docking, propellant transfer systems for zero gravity and specialized algorithms (computer commands) to orchestrate and synchronize satellite-servicing operations. A systems engineering review on this conceptual mission was recently conducted with positive responses from peer experts and external participants.

Reed and the SSCO team see many applications across NASA for these new, game-changing capabilities.

"The technologies we're building to help rescue satellites in five years could be the very same ones used to clean up space ten years in the future or save a spacecraft on the way to Mars 30 years from now," says Reed. "NASA is acting today to ensure that we have the capabilities America needs for the future. With satellite servicing technologies, we're bolstering the agency's long-term strategy as we invest in near-term tactical technology investments. RRM is just the beginning."

Related links: