OrbitalHub

Wikipedia dicit:

The SpaceX Starship is a fully reusable second stage and space vehicle being privately developed by SpaceX. It is being designed to be a long-duration cargo- and passenger-carrying spacecraft. While currently it is tested on its own, it will be used on orbital launches with an additional booster stage, the Super Heavy, where Starship would serve as the second stage on a two-stage-to-orbit launch vehicle. The combination of spacecraft and booster is called Starship as well. Beginning in mid-2019, prototype versions are being flown with Starship as an independent rocket in its own right—without any launch vehicle booster stage at all—as part of an extensive suborbital flight testing program to get launch and landing working and iterate on a variety of design details, particularly with respect to atmospheric reentry of the vehicle.

Integrated system testing of Starship began in March 2019 with the addition of a single Raptor rocket engine to the first flight-capable propellant structure, Starhopper. Starhopper was used through August 2019 for static testing and low-altitude, low-velocity flight testing of vertical launches and landings in July/August. Two additional test articles, Starship orbital prototypes, are being built by competing teams in Texas and in Florida. They are planned to be used for high-altitude, high-velocity testing beginning in late 2019. All test articles have a 9-meter (30 ft)-diameter stainless steel hull.

Video Credit: SpaceX

Northrop Grumman dicit:

Northrop Grumman is developing the next generation of the GEM family of strap-on boosters to support intermediate- and large-class space launch vehicles. These boosters build on the company’s extensive history of the successful GEM 40, GEM 46, and GEM 60 motors. The GEM 63 and GEM 63XL motors will be capable of supporting national security, science and commercial payloads. The company is leveraging its industry-leading expertise in composite large solid rocket motor development and manufacturing to provide customers with a cost-effective, reliable, flexible, and on-time system, starting in 2019 for United Launch Alliance’s Atlas and Vulcan launch vehicles.

Video Credit: Northrop Grumman

NASA dicit:

Exploration Ground Systems continued to make sure the mobile launcher is ready for Artemis I with a multi-arm swing test on Friday, October 4, 2019 at Launch Pad 39B at Kennedy Space Center in Florida. The Umbilical Arm Simultaneous Retract Test included retraction of the connections that will provide fuel, coolant and communications to the Space Launch System rocket up until launch. The umbilicals tested included the Interim Cryogenic Propulsion Stage Umbilical (ICPSU), the Core Stage Forward Skirt Umbilical (CSFSU) and the Core Stage Intertank Umbilical (CSIU).

Video Credit: NASA

Wikipedia dicit:

The Orion Multi-Purpose Crew Vehicle (Orion MPCV) is a US-European spacecraft intended to carry a crew of four astronauts to destinations at or beyond low Earth orbit (LEO). As of August 2019, it is under development by NASA and the ESA for launch on the Space Launch System (SLS), Orion is intended to be the main crew vehicle of the Artemis lunar exploration program and other missions not far beyond lunar space. Artemis 1 is planned to be the first flight of Orion on SLS, Artemis 2 the first crewed flight, and Artemis 3 the first lunar landing via the Lunar Gateway.

The Orion MPCV uses the same basic configuration as the Apollo command and service module (CSM) that first took astronauts to the Moon, but with an increased diameter, updated thermal protection system, and a host of other modern technologies. Orion will support long-duration deep space missions with up to 21 days active crew time plus 6 months quiescent spacecraft life. During the quiescent period crew life support would be provided by another module, such as the proposed Deep Space Habitat. The spacecraft’s life support, propulsion, thermal protection, and avionics systems can be upgraded as new technologies become available. The Orion spacecraft includes both crew and service modules, and a spacecraft adapter. The Orion’s crew module is larger than Apollo’s and can support more crew members for short or long-duration missions. The European service module propels and powers the spacecraft as well as storing oxygen and water for astronauts.

Video Credit: Lockheed Martin

Today we are joined by Yasunori Yamazaki, Chief Business Officer at Axelspace. Axelspace are pioneers of microsatellite technology advancing the frontiers of space business, reimagining traditional ways of using space, and creating a society where everyone on our planet can make space part of their life.

Orbital Hub: Axelspace’s goal is to advance the frontiers of space business. How is Axelspace making space more accessible?

Yasunori Yamazaki: Our vision is to bring the space technology down to earth for universal access, empowering everyone with actionable earth observation data to make smart decisions.

O.H.: Could you share any details about innovative technologies used by Axelspace when designing and building satellites?

Yasu: We have been developing satellites for more than 11 years now, experimenting with various methods and implementing new technology to constantly improve and innovate. This trial and error itself is a new concept in our industry as the cost of making a mistake is prohibitive from an investment perspective.

O.H.: What is the approach used by Axelspace for microsatellite design? Do you use custom designs specific to each mission or a modular design that allows reuse and minimal mission specific customization?

Yasu: The designing process depends on the mission. For unique purposes, we will start with a whiteboard, deep diving into the problem and figuring out the most efficient and effective way of delivering the solution. We are also in the process of constructing an orbital infrastructure, based on proprietary modulated satellite, GRUS, to bring down the cost of manufacturing, thus passing on the savings to the users of the data.

O.H.: What payload types can be integrated with Axelspace microsatellites?

Yasu: Most anything can be carried by our microsatellites, as we can build from small to large satellites. The largest we have successfully deployed into space is a 200 kg satellite, which is a fantastic platform to carry most any payloads, but in a radically cost effective way.

O.H.: What type of stabilization is used by Axelspace microsatellites?

Yasu: We don’t comment on specific internal technology.

O.H.: What type of propulsion systems are integrated with Axelspace microsatellites? Are they mission specific?

Yasu: We don’t comment on specific internal technology.

O.H.: Is Axelspace designing and manufacturing only remote sensing microsatellites?

Yasu: We have been focusing on perfecting our expertise on remote sensing microsatellites. As we are market driven company, our limitation is not technology, but true market demand. Our business team is constantly monitoring the trends in the market and ready to dive into any direction when the time is ripe.

O.H.: Any plans for deep space exploration missions? Could the current bus be repurposed for a deep space mission?

Yasu: We are open for any mission, as long as there is a concrete market and sustainable paying clients. The company never works on a technology, without concrete business visibility.

O.H.: Remote sensing satellites are usually deployed on Sun-synchronous polar orbits. This leads to crowded LEO and increased collision risks above the polar regions. What end-of-life strategies are Axelspace missions using?

Yasu: As a constellation player, we are conscious of EOL operation and complies with the international guidelines on securing the sustainable usage of our orbits.

O.H.: What is AxelGlobe?

Yasu: AxelGlobe is a web based platform to access earth observation data from our proprietary satellite, GRUS, to empower anyone with actionable data to make smart decision.

O.H.: Launching and managing a fleet of 50+ microsatellites in LEO must be a challenging endeavour. Can you elaborate on some of these challenges? How is Axelspace tackling them?

Yasu: Absolutely! There is no shortcut in implementing space technology. To be successful in this business, these are the 4 most important simple, yet critical points to cover:

1. Transformational IDEA to bring value to the market
2. Proven Engineering to bring IDEA into product
3. Solid Financial Resource to bring product into reality
4. Paying clients to have a sustainable business model

To achieve the above, we have inspiring leadership team that brings IDEA to the table, experienced engineer team that can convert anything into a product, insightful finance team to secure the funding and powerful business team to generate revenue for the TEAM.

O.H.: What does the future hold for Axelspace holding? Any exciting plans to share with our readers?

Yasu: When we started the company 11 years ago, no one believed that a startup can actually do anything meaningful in the space industry. Now, after years of hard work, we have 5 operating satellites in space. Next year, we have 4 more confirmed launches and will continue to deploy every year. As a pioneer in the commercial microsatellite world, we will keep working hard and focus on engineering for good.

Northrop Grumman dicit:

SpaceLogistics LLC, a wholly owned subsidiary of Northrop Grumman, provides cooperative in-orbit satellite servicing to geosynchronous satellite operators using its fleet of commercial servicing vehicles. Our initial servicing vehicle, the Mission Extension Vehicle (MEV)™ docks with customers’ existing satellites providing the propulsion and attitude control needed to extend their lives. We have now introduced our next generation system, Mission Extension Pods (MEPs)™, which is a smaller and less expensive life extension service that only performs orbit control. The MEPs are installed by a robotic servicing vehicle called the Mission Robotic Vehicle (MRV)™ which can perform all the functions of an MEV while adding new robotic capabilities for additional services.

Our life extension services are compatible with virtually all geosynchronous satellites with minimal interruption to operations. They enable satellite operators to significantly extend satellite mission life, activate new markets, drive asset value and protect their franchises. SpaceLogistics delivers life extension services that are flexible, scalable, capital-efficient and low-risk. Our breakthrough innovations provide satellite operators unprecedented flexibility in asset deployment, enabling game-changing advances in financial and operating flexibility, and risk mitigation.

Video Credit: Northrop Grumman