SpaceX Falcon 9 - Cassiope

  SpaceX Falcon 9 V1.1 - Cassiope  - Launching September 29, 2013

Screenshot from dxrts copy of SpaceX Webcast of the launch of Cassiope

Mission Rundown: SpaceX Falcon 9 V1.1 - Cassiope

Written: February 5, 2021

Lift Off Time (Subject to change see rocket cam ) 16:00:42.78 - T+00:00:29 = 16:00:13	September 29, 2013 - 16:00:13 UTC - 09:00:13 PDT 13 second delay later found in DANDE’s launch data
Mission Name	Cassiope
Launch Provider	SpaceX
Customer	Canadian Space Agency Technology Partnerships Canada program
Rocket	Falcon 9 V1.1 serial number B1003
Launch Location	Space Launch Complex 4 East -SLC-4E Vandenberg Air Force Base, California
Payload	1 Earth Science Satellite - Cascade and e-POP 5 Earth Science CubeSats
Payload mass	500 kg ~ 1 100 pounds
Where are the satellites going?	Polar Low Earth Orbit - 410 km x 1 421 km x 80°
Will they be attempting to recover the first stage?	No. It’s flying “bareback” with no landing legs, but testing RCS thrusters and engine reignitions
Where will the first stage land?	A ”controlled” test landing on the Pacific ocean
Will they be attempting to recover the fairings?	No - Not expected to survive reentry or water impact
Are these fairings new?	Yes - Two Type 1 boat hull sized fairings - 34 x 17 feet with 10 evenly spaced ventilation ports in a circle
This will be the:	– 6th flight of all Falcon 9 rockets – 1st maiden flight of Falcon 9 V1.1 rocket – 1st use of fairings to protect the satellite – 1st SpaceX launch from SLC-4E – 162nd launch from Space Launch Complex 4E – 6th crash landing. Soft, hard, deliberate, ups... – 2nd mission for SpaceX in 2013
Where to watch Where to read more	No decent SpaceX link, but a good dxrts link Found a low resolution link from Matthew Travis Want to learn more link visit Tim Dodd

Launch debriefing (This is what happend)

T-00:45:00 Hosts: - T 00:00:00 T+00:01:16 T+00:02:58 T+00:03:08 T+00:03:33 T+00:07:49 T+00:08:18 T+00:09:04 - T+00:14:15 T+00:17:45 T+00:20:25 T+00:21:25 - T+00:57:10 -

SpaceX live but mute feed until 02:50 audio on Jessica Jensen, John Insprucker and Kiko Dontchev in a Occupy Mars T-shirt Liftoff at 43:08 - downlink unstable and jumping MaxQ at 44:12 MECO 46:06, stage separation 46:08 SES-1 at 46:16 Faring separation at 46:55 Entry burn 50:57 by 3 Merlin 1D Landing burn 51:48 by 1 Merlin 1D - Failure SECO at 50:01 and coasting Rap up from hosts at 53:34 Cassiope deploys first according to news article POPACS deployed 3:30 minutes later 2 CUSat deployed 2:40 minutes later again DANDE deployed last 1:00 minute after - Tweet SpaceX doesn’t resumes live feed SES-2 and SECO-2 doesn't happen, the TEA-TEB igniter fuel lines froze shut - Test failure

C100	COTS-1	COTS-2+	CRS-1 ORBCOMM OG2	CRS-2
CASSIOPE	SES-8	Thaicom 6	CRS-3	ORBCOMM OG2-1

Go west young man, and then jump south

CASSIOPE is a satellite project from the Canadian Space Agency, launched by SpaceX on 29 September 2013 on the first flight of the Falcon 9 v1.1 launch vehicle, a new and much larger redesign of the Falcon 9 V1.0 with a number of launch mission firsts including first flight of new rocket engines on a 30-percent larger launch vehicle with 50-percent more initial thrust, and was also the first launch from a new launch pad at Vandenberg Air Force Base, a site SpaceX had not previously flown from.

The satellite is planned to be deployed in an elliptical polar orbit and will carry a commercial communications system called Cascade as well as a scientific experiment package called e-POP (enhanced Polar Outflow Probe). This combination gives rise to the acronym CASSIOPE, from "CAscade, SmallSat and IOnospheric Polar Explorer"

After the second stage separated from the booster stage, SpaceX conducted a novel flight test where the booster conducted a test to attempt to reenter the lower atmosphere in a controlled manner and decelerate to a simulated over-water landing. The test was partially successful, but the booster stage was not recovered.

The Science Payload

Cascade, Smallsat and Ionospheric Polar Explorer (CASSIOPE), is a Canadian Space Agency (CSA) multi-mission satellite operated by the University of Calgary. The mission development and operations from launch to February 2018 was funded through CSA and the Technology Partnerships Canada program.

In February, 2018 CASSIOPE became part of the European Space Agency's Swarm constellation through the Third Party Mission Program, known as Swarm Echo, or Swarm-E. It was launched September 29, 2013, on the first flight of the SpaceX Falcon 9 v1.1 launch vehicle. CASSIOPE is the first Canadian hybrid satellite to carry a dual mission in the fields of telecommunications and scientific research. The main objectives are to gather information to better understand the science of space weather, while verifying high-speed communications concepts through the use of advanced space technologies.

The satellite deployed in an elliptical polar orbit has a commercial communications system called Cascade as well as a scientific experiment package called e-POP (enhanced Polar Outflow Probe). The satellites payloads are instrument packages with a given design function which are mounted on the main satellite “Bus”, that is providing solar power, thrust, stability in orbit and control over satellite position relative to the Earth, the stars and the orbit position at any given time. SatNav at its best.

CASSIOPE is a 500 kg (1,100 lb) small satellite that is 180 cm (5.9 ft) long and 125 cm (4.10 ft) deeb. It combines the function of two distinct missions in order to be more cost-effective and reduce risk.

Five nanosatellite spacecrafts plus one dispenser were also carried to orbit on the same launch vehicle that carried the CASSIOPE primary payload:

• Nanosat-4 with CUSat 1 and 2 built by Cornell University are released together, and will separate from each other after establishment of ground contact and determination of position and orientation - CUSat 2 didn’t separate

• Drag and Atmospheric Neutral Density Explorer (DANDE) built by University of Colorado Boulder and apparently first released two weeks after launch pending a thorough check out from ground station prior to deployment

• 3U CubeSat releasing 3 Polar Orbiting Passive Atmospheric Calibration Spheres (POPACS), each a 10 cm (4 in) white aluminum sphere, built by a joint project of Morehead State University, University of Arkansas, Montana State University, Drexel University, and Planetary Systems Corporation.

Falcon 9 V1.1 test program

After the second stage separated from the booster stage, SpaceX conducted a novel flight test where the booster conducted a test to attempt to reenter the lower atmosphere in a controlled manner and decelerate to a simulated over-water landing. The test was successful, but the booster stage was not recovered.

After the three-minute boost phase of September 29, 2013 launch, the booster stage attitude was reversed, and three of the nine engines relit at high altitude, as planned, to initiate the deceleration and controlled descent trajectory to the surface of the ocean. The first phase of the test worked well and the first stage re-entered safely.

However, the first stage began to roll due to aerodynamic forces during the descent through the atmosphere, and the roll rate exceeded the capabilities of the booster attitude control system (ACS) to null it out.

The fuel in the tanks centrifuged to the outside of the tanks and the single engine involved in the low-altitude deceleration maneuver shut down. Debris from the first stage RUD - Rapid Unscheduled Disassembly - was subsequently retrieved from the ocean.

SpaceX also ran a post-mission test on the second stage. While a number of the new capabilities were successfully tested on the September 29, 2013, CASSIOPE flight, there was an issue with the second stage restart test.

The test to reignite the second stage Merlin 1D vacuum engine once the rocket had deployed its primary payload (CASSIOPE) and all of its nanosat secondary payloads was unsuccessful. The Merlin vacuum engine failed to restart while the second stage was coasting in low Earth orbit. The fuel lines froze solid, disabling the reignition. The problem is now solved by bleeding the Merlin 1D vacuum engines fuel and oxygen pipes until they are empty, thus disabling freezing shut and with insolation of the smaller pipes.

The Falcon 9 upper stage used to launch CASSIOPE was left derelict in a decaying elliptical low Earth orbit that, as of January 20, 2016, had a perigee of 317 km (197 mi) and an apogee of 1,283 km (797 mi).

Falcon 9 V1.1 Rocket

SpaceX has after launching five Falcon 9 V1.0 or Block 1 rockets gathered enough flight data to rebuild its current launch vehicle to the new longer, heavier, stronger and more powerful Falcon 9 V1.1, F9R or Block 2, as it will be known later on.

Falcon 9 V1.1 is 68,4 meter - 224 feet tall, has the same diameter of 3,66 meter - 12 feet and is now capable of launching payloads to other planets, though it will mainly launch satellites to a geostationary orbit, ISS and other low earth orbits. The new Merlin 1D engines have a total of 5 885 kN - 1 400 000 lbf of thrust and can be throttled down to 70% by reducing propellant flow in the main fuel pipes.

There is a 60% increase in overall weight of the launch vehicle, as well as a claimed  60% increase in thrust enabling it to maintain its old thrust to weight ratio, but it’s lower now because the thrust increase from 549 kN to 654 kN is only 19%. The engine block design is changed from a square 3 x 3 to a round welded octaweb with 8 engines in a circle and the last engine nr. 9 in the center position.

First stage consists of an engine block 3,8 meter tall attached to a 46,1 meter tank section minus bulkheads containing propellants in the form of RP-1 and LOX. On top of the tanks is the 6,1 meter long interstage sleeve hiding and protecting the Merlin 1D vacuum engine before stage separation. First stage stands 47 meter from the engine bell bottom edge to the top edge of the interstage.

Second stage consists of an Merlin 1D vacuum engine attached to the bottom of a 8 meter long tank section minus two bulkheads also containing propellants in the form of RP-1 and LOX and a short Payload Adaptor Fitting on top, upon which the 13,1 meter tall fairings and satellite payloads can be attached. A taller 1,1 meter “turtleneck” Payload Adaptor Fitting is used to hold the 7,2 meter tall Trunk and Cargo Dragon.

Falcon 9 V1.1 carrying a Cargo Dragon stands 63,3 meter tall, about 5,1 meter shorter than the satellite launching Falcon 9 V1.1 with its huge fairings. The amount of RP-1, LOX, compressed Helium used as tank backfiller, and RCS Nitrogen gas carried in the fuel tanks in COPV tanks of varying sizes is as yet unknown.

There are also tanks containing igniter fluids TEA-TEB which stands for Triethylaluminum and Triethylborane who both are strongly porophoric in contact with oxygen.

My source for lengths above is from Ed Kyle. Link to it is dead, I'm sad to say.

Author William Graham link link

Coauthor/Text Retriever Johnny Nielsen link to launch list

SpaceX Falcon 9 - CRS-2

  SpaceX Falcon 9 V1.0 - CRS-2 - Launching March 1, 2013

Screenshot from SpaceX Webcast of the launch of CRS-2

Mission Rundown: SpaceX Falcon 9 V1.0 - CRS-2

Written: February 6, 2021

Lift Off Time	March 1, 2013 - 15:10:13 UTC - 10:10:13 am EST
Mission Name	CRS-2
Launch Provider	SpaceX
Customer	NASA
Rocket	Falcon 9 V1.0 serial number B0007
Launch Location	Space Launch Complex 40 - SLC-40 Cape Canaveral Air Force Station, Florida
Payload	Cargo Dragon serial number C104
Payload mass	898 kg ~ 1.980 pounds
Where are the Dragon going?	Low Earth Orbit to the International Space Station (ISS)
Will they be attempting to recover the first stage?	No. It’s a regularly rocket, so one way ticket only
Where will the first stage land?	The Atlantic ocean east of North Carolina
Will they be attempting to recover the fairings?	No. The Dragon capsule has a jettisonable nose cone and solar panel covers on the Trunk
This will be the:	– 5th and last flight of Falcon 9 V1.0 rocket – 5th SpaceX launch from SLC-40 – 60th launch from SLC-40 since Titan IIIC June 1965 – 5th crash landing. Soft, hard, deliberate, ups... – 1st mission for SpaceX in 2013
Where to watch Where to read more	SpaceX link Found the NASA launch link Want to know or learn more link visit Tim Dodd

Launch debriefing (This is what happend)

T-00:39:14 Hosts: T 00:00:00 T+00:01:25 - - T+00:03:07 T+00:03:19 - T+00:03:54 T+00:09:28 T+00:10:03 T+00:11:53 - - T+01:40:00 - T+46:45:47 595:45:47 601:23:47

SpaceX live feed at 00:38 Kiko Dontchev, John Insprucker and Jessica Jensen Liftoff at 39:54 - 15:10:13 UTC - March 1, 2013 MaxQ at 41:18 - Downlink clocks are uneven View of Merlin 1C Vacuum engine nozzle at 42:43 View of Merlin 1C Vacuum engine pipes at 45:52 MECO 43:01, stage separation 43:05 SES-1 at 43:12 - On left camera view - On right camera it’s delayed 3 seconds Nose cone separation audio at 43:48 - Unseen SECO at 49:21 and coasting Cargo Dragon C104 deployment at 49:56 - 14:20 pm Flight computer in abort passive - Yikes Rap up from John at 53:33 - Appears we got a fault Valve on pipe from helium COPV was stuck Solar Cell panels deployment at 15:50 pm ish… Other events during this CRS-2 mission were: Berthing with ISS Harmony Nadir airlock at 13:56 UTC Released from ISS after 23 days at 10:56 UTC Landed in Pacific Ocean near NRC Quest at 16:34 UTC

C100	COTS-1	COTS-2+	CRS-1 ORBCOMM OG2	CRS-2
CASSIOPE	SES-8	Thaicom 6	CRS-3	ORBCOMM OG2-1

One more time above and beyond?

Space Exploration Technologies (SpaceX business name) successfully launched its fifth and last Falcon 9 V1.0 rocket with Dragon C104 spacecraft to orbit for SpaceX's second mission to ISS under its Commercial Resupply Services (CRS) contract with NASA.

Falcon 9 completed its job perfectly, continuing its 100 percent success rate.

The launch occurred on March 1, 2013. A minor technical issue arose on the Dragon spacecraft involving the RCS thruster pods. It occurred upon reaching orbit, but it was recoverable. The vehicle was released from the station on March 26, 2013, at 10:56 UTC and splashed down in the Pacific Ocean at 16:34 UTC.

Cargo Dragon separated from Falcon 9's second stage approximately nine minutes after launch, then a minor issue with some of Dragon's oxidation (Nitrogen Tetroxide) tanks was detected. Within a few hours, SpaceX engineers had identified and corrected the issue, normalizing the oxidation pressure and returning operations to normal.

Thruster Pod 1 had operational oxidizer pressure in one its four Nitrogen Tetroxide tanks from one of a common shared helium COPV. The shared four way valve was partially blocked, and the blockage was hammered loose during the first day.

Thruster Pod 1 has five Draco thrusters while Thruster Pod 4 only has four Draco thrusters. Thruster Pod 2 and 3 came online even later that day, so Thruster Pod 1 and 3 must be placed opposite with five Draco thrusters each and Thruster Pod 2 and 4 only have four Draco thrusters each.

Each Thruster Pod has a right and left roll Draco 400 Newton thruster, and one forward and one backward pointed pitch/yar Draco thruster. The two extra Draco thrusters in Thruster Pod 1 and 3 both point forward to aide in the deorbit maneuver so there are six forward pointed Draco thrusters available with 2.4 kN thrust.

Dragon recomputed its ascent profile as it was designed to and is now on its way to the International Space Station (ISS) with possible arrival on Sunday, just one day past the original timeline.

Dragon is the only spacecraft in the world capable of returning significant amounts of cargo to Earth. Dragon will stay on station for three weeks, during which astronauts will unload approximately 1,200 pounds of cargo and fill the capsule with return cargo, for return to Earth. Dragon is filled with supplies for the ISS, including critical materials to support science investigations.

Later this month, Dragon will return a payload that includes research results, education experiments and space station hardware.

The Dragon Payload

SpaceX CRS-2, also known as SpX-2, was the fourth flight for SpaceX's uncrewed Dragon cargo spacecraft, the fifth and final flight for the company's two-stage Falcon 9 v1.0 launch vehicle, and the second SpaceX operational mission contracted to NASA under a CRS Commercial Resupply Services contract.

When launched the CRS-2 Dragon was filled with about 1,493 lb (677 kg) of cargo, 1,268 lb (575 kg) without packaging. Included is 178 lb (81 kg) of crew supplies, 766 lb (347 kg) of scientific experiments and experiment hardware, 298 lb (135 kg) of hardware for the station and other miscellaneous items, among them a CD copy of the song "Up in the Air" by rock band Thirty Seconds to Mars, was premiered on board the International Space Station on March 18, 2013, during a NASA TV broadcast from the station.

The Dragon unpressurized trunk section, which allows the transport of unpressurized cargo to the ISS, had its first use on this flight. The two Heat Rejection Subsystem Grapple Fixtures (HRSGFs) had a combined weight of 487 lb (221 kg) and were transported to the ISS inside the unpressurized Dragon trunk as external cargo.

The Dragon returned 3,020 lb (1,370 kg) of cargo, 2,668 lb (1,210 kg) without packaging. Included is 210 lb (95 kg) of crew supplies, 1,455 lb (660 kg) of scientific experiments and experiment hardware, 884 lb (401 kg) of space station hardware, 84 lb (38 kg) of spacesuit equipment and other miscellaneous items.

On March 26, Dragon was unberthed from the Harmony node by the Canadarm2 at 08:10 UTC by commands from ground controllers. Its release from Canadarm2 occurred at 10:56 UTC; the Expedition 35 crew then commanded the spacecraft to slowly depart from the International Space Station.

The SpaceX Dragon fired its engines for the last time at 15:42 UTC sending it through the Earth's atmosphere for a splashdown in the Pacific Ocean at 16:34 UTC. A team of SpaceX engineers, technicians and divers recovered the vehicle and its scientific cargo off the coast of Baja, California, for the journey back to shore which took about 30 hours.

Author William Graham link + Chris Bergin link

Coauthor/Text Retriever Johnny Nielsen link to launch list