Tag: Spacecraft

#MadeInChina #中國製造| #中科宇航 #ZhongkeAerospace #ChinaAcademyOfScience #CASSPace #August2024 | #CarrierRocket #ReusableCarrierRocket #MannedReusableCarrierRocket #CarrierRocket Series The three-core parallel Lijian-2 has entered the engineering development stage, and its first flight will be equipped with a cargo spacecraft!

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Beijing Zhongke Aerospace Exploration Technology Co., Ltd. is the first domestic aerospace enterprise with mixed ownership, and it is also the target enterprise that Oriental Aerospace Port focuses on introducing. Relying on the scientific research strength and resource advantages of the Institute of Mechanics of the Chinese Academy of Sciences and the Aerospace Flight Technology Center of the Chinese Academy of Sciences, China Aerospace Science and Technology has been committed to the research and development and integration of space technology and aerospace vehicles as a platform for the transformation of major national scientific research projects, as well as the transformation and provision of technological achievements. Aerospace launch service. The Lijian-1 rocket project also adds a brand-new name card to the Oriental Space Port, which will surely promote the construction of the Oriental Space Port to take a solid step forward.

Static test of composite cabin of “Lijian-2” liquid launch vehicle

Before July 29, 2024, the static test of the composite cabin of the “Lijian-2” liquid launch vehicle was successful. This test mainly verifies whether the structural scheme meets the design requirements under the maximum design load and assesses the feasibility of the composite scheme. Since the beginning of this year, the development of the “Lijian-2” rocket has been rapidly advanced and is steadily moving towards its first flight.

Three cores in parallel, bundled recycling

“Lijian-2” is a medium-sized cryogenic liquid carrier rocket developed by the China Aerospace Science and Technology Corporation (CAS Space). It adopts a two-and-a-half-stage configuration. The take-off stage adopts a CBC configuration, in which the core first stage and two core first stage module boosters are bundled side by side, and the core second stage is connected in series on the core first stage.

The first stage of the rocket core is equipped with three YF-102 liquid oxygen-kerosene engines, adopting an open gas generator cycle and a pump-front swing design, supporting double swing of ±6°, a single sea level thrust of approximately 85 tons (835 kN), a sea level specific impulse of 275.5 seconds, and a thrust-to-weight ratio of not less than 130; the two boosters are configured basically the same as the first stage of the core; the second stage of the core is equipped with a YF-102V liquid oxygen-kerosene engine with a thrust of approximately 72 tons (710 kN), which can achieve 55%~100% variable thrust, a vacuum specific impulse of 320 seconds (throttling)~330 seconds, and support repeated starts for no less than 2 times.

Schematic diagram of the Force Arrow II

The entire rocket of “Force-2” is 52 meters high. The diameters of the core stage, core stage and booster are all 3.35 meters. It is equipped with a fairing with a diameter of 4.2 meters. The take-off mass is 625 tons and the take-off thrust is 766 tons. Its low-Earth orbit (LEO) carrying capacity is 12 tons and its 500-kilometer sun-synchronous orbit (SSO) carrying capacity is 8 tons.

The ultimate goal of “Force Arrow II” is to become a reusable launch vehicle, realize multiple recovery and reuse of the core stage and boosters, and support reuse more than 20 times. The three-core parallel launch stage of the arrow will implement cluster separation and cluster recovery. The convenience lies in that it only needs to be equipped with a flight control system and a recovery and landing system, the latter includes a set of sang rudders and a set of landing legs. Two of the four sang rudders are distributed in the core stage, and the other two are distributed in the boosters. Two of the four landing legs are distributed in the core stage, and the other two are distributed in the boosters. According to the plan, “Force Arrow II” will realize the recovery of the core stage and booster modules in 2028.

The first flight is to launch a cargo spacecraft

Since the proposal, the “Lijian-2” has undergone major changes in the plan. The current design is very different from the previous single-stage plan, and the first flight has been postponed for several years. According to the plan, in August 2025, the “Lijian-2” will make its first flight at the No. 2 station of the Wenchang Commercial Space Launch Site, and the takeoff stage will not be recovered.

The first flight mission of “Lijian-2” carried a heavy-duty cargo spacecraft. The cargo spacecraft was developed by the Microsatellite Innovation Institute of the Chinese Academy of Sciences. In the bidding for the overall plan of the low-cost cargo transportation system for the Chinese space station released by the China Manned Space Engineering Office in May 2023, the Chinese Academy of Sciences and the Satellite Innovation Institute jointly carried out ship-rocket joint demonstration and key technology research, and carried out the “ship-rocket-cargo” integrated space-to-earth transportation system plan design. With the ship-rocket collaborative solution of the low-cost cargo spacecraft and the “Lijian-2” rocket, it was successfully shortlisted in the bidding and entered the detailed design stage of the plan.

The launch mission of the low-cost cargo spacecraft to be carried out by the Lijian-2 rocket is the first time that a Chinese commercial aerospace enterprise has participated in the development and launch of a low-cost cargo transportation project for the Chinese space station. If it is finally selected, the Lijian-2 will become China’s first commercial rocket to carry out manned space missions, which will also be a recognition of the reliability of the Lijian-2.

Build your own advantages by networking for the constellation!

As a commercial aerospace enterprise, China Aerospace Science and Technology is targeting the vast commercial space launch market, especially the low-orbit satellite constellation launch service market. my country’s currently planned low-orbit constellation contains tens of thousands of satellites, which require launch vehicles to provide large-capacity, high-frequency, low-cost, and high-reliability launch services. Compared with China’s liquid commercial rockets of the same level, the “Lijian-2” rocket does not have an advantage in capacity, but it can work hard on high frequency, low cost, and high reliability.

Create high-frequency launches. At the Hainan Commercial Space Launch Center in China, two launch stations have been built. Both stations have a designed launch capacity of 16 times per year. Station 2 is a general-purpose station that needs to support the launch of more than a dozen types of rockets, which is far from enough for high-frequency launches. In addition to using Hainan Commercial Launch Station 2, China Science and Technology Aerospace is building a dedicated technical preparation plant at the Jiuquan Satellite Launch Center and is about to build a dedicated launch station for the “Lijian-2” rocket. Based on self-built stations, China Science and Technology Aerospace will be able to achieve dozens of launch frequencies per year.

The core secondary box section of “Lijian-2”

Achieve low cost. “Lijian-2” uses a lot of mature technologies. The main power is all YF-102 series engines. All stages use mainstream tank modules with a diameter of 3.35 meters. It uses the same avionics system as “Lijian-1”. The application of mature and common technologies means that costs can be greatly reduced. At the same time, simplifying the design is another important way to control costs. For example, the core second-stage box section takes into account the functions of the traditional liquid rocket instrument cabin and cancels the core second-stage instrument cabin, which simplifies the cabin structure and saves materials.

Achieve high reliability. While applying mature and general technologies, the power system and avionics system adopt redundant design, and the separation scheme is simple, making the rocket highly reliable. For example, the launch stage of the rocket is equipped with 9 YF-102 engines, with a single sea level thrust of about 85 tons, a total rocket takeoff thrust of 766 tons, a takeoff mass of 625 tons, and a thrust-to-weight ratio of 1.23, achieving a large power redundancy, and can complete the launch mission in the event of one engine failure.

Schematic diagram of the heavy-duty “Force Arrow II”

Building a stronger model

After my country’s low-orbit constellation enters the large-scale networking period, the intensive networking and launch of tens of thousands of satellites requires a large-scale reusable launch vehicle, but the current “Lijian-2” has obviously insufficient capacity.

Based on the Lijian-2, China Aerospace Science and Technology will develop a more powerful “Lijian-2” heavy-lift launch vehicle (called “heavy”, but actually large). The latter is based on the former and adds two core-stage module boosters to achieve five cores in parallel (5CBC). The “Lijian-2” heavy-lift rocket is 56 meters high, with optional fairings of 4.2 meters and 5 meters in diameter, a takeoff mass of 913 tons, a low-Earth orbit (LEO) capacity of 22 tons, and a 500-kilometer sun-synchronous orbit (SSO) capacity of 15 tons. The core stage and booster can be reused more than 20 times.

In general, the “Force-2” will be a high-quality rocket that can meet market demand to a large extent. Facing the needs of constellation network launches, with its advantages of high frequency, low cost and high reliability, the “Force-2” is bound to become one of the main near-Earth “flights”.

Images and visuals are from their respectives

#CNSA #ChinaNationalSpaceAdministration #国家航天局 |#BRI #July2024| #Shenzhou18 #Takionaut crew successfully performed   Second #EVA #Spacewalk #Tiangong #ChinaSpaceStation of working outside… #ASummary

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On the day of  3rd July  2024   Hours Hong- Kong SAR – Beijing time CNSA –China National Space Administration , China, People’s Republic of China At  Hong Kong SAR- Beijing Time Beijing time  Shenzhou 18 Takionaut crew….. Shenzhou 18 astronaut crew will carry out the second extravehicular activity …. Successfully completed the second extravehicular activity…… At 22:51 Beijing time on July 3, 2024, after about 6.5 hours of extravehicular activities, the Shenzhou 18 crew astronauts Ye Guangfu, Li Cong, and Li Guangsu worked closely together, and with the support of the space station’s robotic arm and ground scientific researchers, installed space debris protection devices for the space station’s extravehicular pipelines, cables and key equipment, and completed the extravehicular inspection mission. Extravehicular astronauts Ye Guangfu and Li Cong have safely returned to the Wentian laboratory module, and the extravehicular activity was a complete success.



So far, the Takionaut Crew of the Shenzhou 18 astronaut crew has been completed by one-third, and a large number of scientific experiments and technical experiments will be carried out in orbit in the future…..

Images and visuals are from their Respectives CMS China Manned SpaceCNSA-China National Space Administration  

#CNSA #ChinaNationalSpaceAdministration #国家航天局 |#BRI #June2024| #酒泉卫星发射中心 #JiuquanSatelliteLaunchCenter – #中国航天科技集团#ChinaAerospaceScienceAndTechnologyCorporation  – China’s first 10-kilometer-class vertical take-off and landing flight test of a #ReusableCarrierRocket was a complete success…

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[China’s first 10-kilometer-class vertical take-off and landing flight test of a reusable carrier rocket was a complete success]

On June 23rd 2024, China’s first 10-kilometer-class vertical take-off and landing flight test of a reusable carrier rocket was a complete success. The rocket was developed by the Eighth Academy of China Aerospace Science and Technology Corporation.

 At about 1300 hours Beijing Time, at the Jiuquan Satellite Launch Center, Inner Mongolia, China, People’s Republic of China , a 3.8-meter-diameter reusable carrier rocket new technology verification arrow was erected on the launch pad. Three variable thrust liquid oxygen-methane engines were ignited, spewing blue tail flames. The rocket body rose to an altitude of about 12 kilometers. The central engine adjusted the thrust, and the rocket descended in a controlled manner. At 50 meters from the ground, the four landing legs unfolded, and then the rocket slowly descended, approaching zero altitude, and landed steadily on the recovery field, achieving a fixed-point vertical soft landing.


This test is currently the largest-scale vertical take-off and landing flight test of a reusable carrier rocket in China, and it is also the first application of the domestically developed deep variable thrust liquid oxygen-methane engine in a 10-kilometer-class return flight.
The entire test took about 6 minutes. The rocket went through five stages: accelerated ascent, decelerated ascent, accelerated descent, decelerated descent, and slow descent, achieving “take-off, accurate control, unfolding, and stable landing”.

[Take off, control accurately, deploy, and land steadily! China’s first 10-kilometer-level vertical take-off and landing flight test of a reusable carrier rocket was a complete success]

Three variable thrust liquid oxygen-methane engines were ignited, spewing blue tail flames. The rocket body rose to an altitude of about 12 kilometers. The central engine adjusted the thrust, and the rocket descended in a controlled manner. At 50 meters from the ground, the four landing legs unfolded, and then the rocket slowly descended, the altitude approached zero, and landed steadily on the recovery field, achieving a fixed-point vertical soft landing.



The entire test took about 6 minutes. The rocket went through five stages: accelerated ascent, decelerated ascent, accelerated descent, decelerated descent, and slow descent, achieving “take off, control accurately, deploy, and land steadily.”

The test fully verified the 3.8-meter diameter rocket body structure, large load landing cushioning technology, high-thrust strong variable thrust reusable engine technology, dual cryogenic pressurization delivery technology, high-precision navigation guidance control technology for return and landing, and health monitoring technology, laying a technical foundation for the first flight of a 4-meter-class reusable carrier rocket as scheduled in 2025. This test is currently the largest-scale vertical take-off and landing flight test of a reusable carrier rocket in China, and it is also the first application of the domestically developed deep variable thrust liquid oxygen-methane engine in a ten-Kilometer-class return..


The test fully verified the 3.8-meter-diameter rocket body structure, large-load landing buffer technology, large-thrust strong variable thrust reusable engine technology, dual low-temperature pressurization delivery technology, high-precision navigation guidance control technology for return and landing, and health monitoring technology, laying a technical foundation for the first flight of a 4-meter-class reusable carrier rocket as scheduled in 2025.


The apex of the flight profile of this test is the stratosphere at an altitude of about 12 kilometers. Subsequently, the research and development team will carry out a 70-kilometer-level vertical take-off and landing test of a reusable carrier rocket, which will basically cover the flight profile of the first stage of the rocket, and take another big step towards the goal of the first flight of a reusable carrier rocket.

Images and visuals are from their Respectives CMS China Manned SpaceCNSA-China National Space Administration

#MadeInChina #中國製造| #中科宇航 #ZhongkeAerospace #ChinaAcademyOfScience #CASSPace #June2024 | #CarrierRocket #ReusableCarrierRocket #CarrierRocket Series Lijian-2 China Aerospace Science and Technology has completed the joint test of the 85-ton kerosene #YF102  #CarrierRocketEngine in full flight conditions.  #ASummary

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Beijing Zhongke Aerospace Exploration Technology Co., Ltd. is the first domestic aerospace enterprise with mixed ownership, and it is also the target enterprise that Oriental Aerospace Port focuses on introducing. Relying on the scientific research strength and resource advantages of the Institute of Mechanics of the Chinese Academy of Sciences and the Aerospace Flight Technology Center of the Chinese Academy of Sciences, China Aerospace Science and Technology has been committed to the research and development and integration of space technology and aerospace vehicles as a platform for the transformation of major national scientific research projects, as well as the transformation and provision of technological achievements. Aerospace launch service. The Lijian-1 rocket project also adds a brand-new name card to the Oriental Space Port, which will surely promote the construction of the Oriental Space Port to take a solid step forward.

On the Week of 17th June 2024 China Aerospace Science and Technology has completed the joint test of the 85-ton kerosene engine in full flight conditions.

Recently, China Aerospace Science and Technology has completed the joint test of the 85-ton liquid oxygen-kerosene engine and servo matching in the first stage of the Lijian-2 liquid carrier rocket. The test engine is in a two-way swing state, which can meet the control requirements of a 6-degree swing circle. The swing test simulating the full-scale operation of the first stage during the test was successful, verifying the matching of the first-stage engine of the Lijian-2 and the servo system, and obtaining key data such as the dynamic swing characteristics of the engine. At the same time, this test tested the first flight state of the first-stage engine of the Lijian-2.


This test assessed the two-way swing performance of the first-stage engine of the Lijian-2 and verified the working coordination of the servo control system and the engine. In the future, the engine will continue to carry out life test on this basis.
Lijian-2 adopts a CBC configuration, with a universal core stage diameter of 3.35 meters, a total length of 53 meters, a take-off weight of 625 tons, and a take-off thrust of 766 tons. The SSO carrying capacity is 8 tons, and the LEO carrying capacity is 12 tons. It is scheduled to fly for the first time in 2025…

[The joint test of the 85-ton liquid oxygen-kerosene engine YF-102 and servo matching flight conditions of the first stage of the Lijian-2 liquid carrier rocket of China Aerospace Science and Technology was successfully completed]

Recently, China Aerospace Science and Technology completed the joint test of the 85-ton liquid oxygen-kerosene engine and servo matching flight conditions of the first stage of the Lijian-2 liquid carrier rocket. The test engine is in a two-way swing state and can meet the 6-degree swing circle control requirements. The swing test simulating the full-scale operation of the first stage during the test process was successful, verifying the matching of the first stage engine of the Lijian-2 with the servo system, and obtaining key data such as the dynamic swing characteristics of the engine. At the same time, this test tested the first flight state of the first stage engine of the Lijian-2.


This test simulated the process of increasing the oxidizer and fuel inlet pressure caused by the flight overload of the first stage engine of the Lijian-2 by changing the engine inlet pressure. The engine thrust and specific impulse met the overall design requirements, the engine parameters were stable, and the performance indicators such as the oxygen self-pressurization met the design requirements.



During the test run, the engine extreme swing angle test, small swing angle joint training, load calibration, pressurized cold swing test, hot test combined swing test, etc. were carried out successively. During the ignition process, various waveform conditions such as square wave, triangle wave, and sine wave were tested. The maximum swing angle of the engine was 6°, and the servo feedback position and command tracking were good. The two-way swing performance of the first-stage engine of Lijian No. 2 was assessed, and the coordination between the servo control system and the engine was verified. Later, the engine will continue to carry out life survey tests on this basis.

Combined with this engine test run, liquid oxygen circuit immersion precooling, small flow precooling and large flow precooling tests were carried out simultaneously to obtain more accurate engine precooling characteristics and verify the correctness of the rocket body precooling scheme. In

addition, the low-order modal characteristics of the first-stage engine were obtained through structural modal tests of the installation process pull rod state and the installation servo mechanism state, providing important data support for the design of the attitude control system on the rocket. Environmental measurement points were added nearby to obtain environmental parameters such as noise.

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#CNSA #ChinaNationalSpaceAdministration #国家航天局 |#BRI #April2024 #Tiangong #ChinaSpaceStation #CMS #ChinaMannedSpace, #Takionauts #神州七号 #Shenzhou17 Departs returning back to the Motherland  Dongfeng Landing Site #China, #PeoplesRepublicOfChina. #ASummary 

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At 08:43 on April 30, 2024, Beijing time, the Shenzhou 17th manned spacecraft successfully separated from the  CNSA- China National Space AdministrationTiangong China  space station assembly. After transferring the command of the China Space station towards the new Crew of Shenzhou 18 whom arrived docked a few days ago from Jiuquan Satellite Launch Center Inner Mongolia ..  

Before separation, the Shenzhou 17th astronaut crew, with the cooperation of ground personnel, completed various pre-evacuation tasks such as setting the status of the space station assembly, collating and downloading experimental data, cleaning and transferring materials left in orbit, and working with the Shenzhou 18th crew. The team completed the work handover. Takionauts Tang Hongbo, Tang Shengjie, and Jiang Xinlin who were on a mission to the China Space Station have returned and embarked on their journey home. ….Wish the heroic Takionauts a safe journey! 神州七号 …..

At this moment, the Shenzhou 17 manned spacecraft completed two attitude adjustments and began to return to braking. The spacecraft is in normal working condition and the astronauts feel good. See you in the east wind…..

As of 11:24  30th April 2024 , the Takionauts of the Shenzhou 17 crew have been flying for 187 days, setting a new record for the Chinese Takionauts’ flight time in orbit!​​​

[The return capsule of the Shenzhou 17th manned spacecraft landed successfully, and the Shenzhou 17th manned mission achieved a complete success]

At 17:46 on April 30, 2024, Beijing time, the return capsule of the Shenzhou 17th manned spacecraft landed in Dongfeng The landing was successful. On-site medical supervision and medical insurance personnel confirmed that astronauts Tang Hongbo, Tang Shengjie, and Jiang Xinlin were in good health. The Shenzhou 17 manned mission was a complete success.


At 16:56, the Beijing Aerospace Flight Control Center issued a return command through the ground measurement and control station, and the orbital module of the Shenzhou 17 manned spacecraft was successfully separated from the return module. After that, the spacecraft returned to brake and ignited the engine, separated the propulsion module from the return module, and the return module successfully landed. The search and rescue team responsible for the search, rescue and recovery mission found the target in time and arrived at the landing site. After the door of the return module was opened, medical supervision and insurance personnel confirmed that the Takionauts were in good health.


The Shenzhou 17 manned spacecraft was launched from the Jiuquan Satellite Launch Center on October 26, 2023, and then docked with the Tianhe core module to form a combination. The three astronauts flew in orbit for 187 days, during which they conducted two extravehicular activities, cooperated with the completion of multiple cargo exodus missions of the space station, and successively carried out various tasks such as installation, debugging, and maintenance of equipment inside and outside the space station. They completed the on-orbit mission for the first time. The spacecraft extravehicular facility maintenance mission has accumulated valuable data and experience for the long-term stable on-orbit operation of the space station; at the same time, with the close cooperation of ground scientific researchers, it has completed tasks involving basic microgravity physics, space material science, space life science, A large number of space science experiments in aerospace medicine, aerospace technology and other fields

Images and visuals are from their Respectives CMS China Manned SpaceCNSA-China National Space Administration