China successfully launched a new model of carrier rocket, the Long March-11, at 9:41 a.m. Friday from the Jiuquan Satellite Launch Center in the northwestern province of Gansu.
The rocket carried four micro-satellites into space, which will be used mainly for testing.
The solid propellant rocket was developed by the China Academy of Launch Vehicle Technology with the China Aerospace Science and Industry Corporation.
The rocket will mainly be used for launching micro-satellites.
A statement from the academy said the successful launch of the rocket marked a major breakthrough for the nation in key technology for solid propellant rockets.
The trip was the 211th mission for the Long March rocket family.
Following the successful debut launch of the Long March-6 rocket just days previous, China has now debuted the new Long March-11 solid launch vehicle, orbiting three “Tianwang-1″ satellites with Portuguese technology on board. The launch, which included at least one other small satellite – Pujian-1 – took place at 01:41 UTC on Friday from the Jiuquan Satellite Launch Center.
The Tianwang-1 satellites:
The Tianwang-1 mission is composed by three small satellites that will demonstrate formation flying and inter satellite communication between the three satellites in orbit.
The three satellites – Tianwang-1A (SECM-1), Tianwang-1B (NJUST-2) and Tianwang-1C (NJFA-1) – were developed by the Nanjing University of Aeronautics and Astronautics. The satellites are based on CubeSat architecture, with SECM-1 and NJUST-2 being a CubeSat-2U and NJFA-1 a CubeSat-3U.
The satellites will make inter satellite communication sessions using the GAMALINK Portuguese technology developed by the Portuguese company Tekever.
Cooperation between Tekever and the Shanghai Engineering Center for Microsatellite (SECM) comes after an agreement signed in Lisbon on April 22, 2014 for the development of satellite technology to be integrated inside the microsatellite platform being developed by SECM.
The Tianwang-1 is designed and implemented by a consortium led by the Shanghai Engineering Centre for Microsatellite in China, together with GomSpace from Denmark, Tekever Space from Portugal and NanoSpace from Sweden.
According Ricardo Mends, CEO of Tekever, the GAMALINK technology will enable the three satellites to work together like a satellite constellation and not like a group of three individual satellites.
With this technology, various types of radio links can be taken on a single physical platform (hardware), each of which uses its own software. Before, each radio link had its own hardware, so this new technology makes the system simpler.
The same technology will be used on the European Space Agency’s PROBA-3, set to be launch in 2017.
A pair of satellites will fly together maintaining a fixed configuration as a ‘large rigid structure’ in space to prove formation flying technologies. The mission will demonstrate formation flying in the context of a large-scale science experiment.
The paired satellites will together form a 150-m long solar coronagraph to study the Sun’s faint corona closer to the solar rim than has ever before been achieved. Beside its scientific interest, the experiment will be a perfect instrument to measure the achievement of the precise positioning of the two spacecraft.
The main objective of the TW-1 mission is to experiment and to evaluate the use of a SDR (Software Defined Radio) payload in orbit.
The mission will demonstrate the formation flying by two CubeSats; Cubesats networking based on Gamalink and CubeSat Space Protocol (CSP); in-orbit demonstration and validation of CubeSat equipment such as dual-band GPS/BeiDou receiver, MEMS based cold-gas micropropulsion, etc.; monitoring sea ice and information about maritime traffic in polar regions based on the AIS (Automatic Identification System) on-board a CubeSat; monitoring air traffic flow when collecting ADS-B signals (Automatic Dependent Surveillance Broadcast), and observing the separation of the three satellites process.
The main payloads involve amateur radio technology used for the exchange of TT & C (Telemetry, Tracking, and Command) with a control ground station, and for transmitting beacon signals and telemetry data with other ground stations.
Other payloads are a GPS / BDS receiver, a video cameras, and AIS and ADS-B receivers.
The world of small satellites technology is new for China. According to SECM’s Zhang Chuan, “the motivation for the mission is very simple. This is the only way for our team to learn the technology for the development of a CubeSat and to demonstrate the reliability of taking the technology that is used every day on the ground and use it in space.”
The telemetry, beacon and the communication device signals details will be open to public for access, so the amateurs around the world may track the satellites, monitor the health of the satellites. Planned downlinks on VHF and on UHF are 57k6 GMSK and 2.4GHZ with spread spectrum at1Mbps, based on the GAMANET protocol.
TW-1 was originally schedule for the end of 2014 together with a remote sensing satellite. The launch was then delayed to May 2015 and later to the end of September.
The Long March-11:
The Long March-11 (Chang Zhwng-11) is a small solid-fueled quick-reaction launch vehicle developed by the China Academy of Launch Vehicle Technology (CALT).
It’s goal goal is to provide an easy to operate quick-reaction launch vehicle, that can remain in storage for long period and to provide a reliably launch on short notice.
Very little is known about the rocket, with only one badly taken photo available on the internet. However, LM-11 is known to be a solid-fueled launch vehicle equipped with a liquid-fueled trim stage.
Jiuquan Launch Center:
The Jiuquan Satellite Launch Center, in Ejin-Banner – a county in Alashan League of the Inner Mongolia Autonomous Region – was the first Chinese satellite launch center and is also known as the Shuang Cheng Tze launch center.
The site includes a Technical Centre, two Launch Complexes, Mission Command and Control Centre, Launch Control Centre, propellant fuelling systems, tracking and communication systems, gas supply systems, weather forecast systems, and logistic support systems.
Jiuquan was originally used to launch scientific and recoverable satellites into medium or low earth orbits at high inclinations. It is also the place from where all the Chinese manned missions are launched.
The LC-43 launch complex, also known by South Launch Site (SLS) is equipped with two launch pads: 921 and 603. Launch pad 921 is used for the manned program for the launch of the Chang Zheng-2F launch vehicle (Shenzhou and Tiangong). The 603 launch pad is used for unmanned orbital launches by the Chang Zheng-2C, Chang Zheng-2D and Chang Zheng-4C launch vehicles.
Other launch zones at the launch site are used for launching the Kuaizhou and the Chang Zheng-11 solid propellant launch vehicles.
The first orbital launch took place on April 24, 1970 when the CZ-1 Chang Zheng-1 rocket launched the first Chinese satellite, the Dongfanghong-1 (04382 1970-034A).