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It refers to the throttle setting. Nominal thottle setting is 104.5%, but the Block II SSMEs can go all the way up 109% if needed. So '''Single engine 104''' means that nominal MECO targets with a single engine running at 104.5% nominal thottle setting. | It refers to the throttle setting. Nominal thottle setting is 104.5%, but the Block II SSMEs can go all the way up 109% if needed. So '''Single engine 104''' means that nominal MECO targets with a single engine running at 104.5% nominal thottle setting. | ||
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==Aborts and emergencies== | ==Aborts and emergencies== | ||
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This can only be done while in controlled flight and at subsonic speeds, while the orbiter is still capable of gliding. The procedure can of course be done under control of the autopilot. | This can only be done while in controlled flight and at subsonic speeds, while the orbiter is still capable of gliding. The procedure can of course be done under control of the autopilot. | ||
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==Payloads== | ==Payloads== | ||
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STS Payload Bay has a diameter of 4.6 m and a length of 18.2 m. For [[ISS]] missions, however some of the space is taken up the [[Orbiter Docking System]] so the available free length of the PLB is approx. 16.25 m. | STS Payload Bay has a diameter of 4.6 m and a length of 18.2 m. For [[ISS]] missions, however some of the space is taken up the [[Orbiter Docking System]] so the available free length of the PLB is approx. 16.25 m. | ||
− | Maximum payload mass depends on orbiter vehicle and orbit needed for the payload. It can take more into a 300x300x28.5° orbit than | + | Maximum payload mass depends on orbiter vehicle and orbit needed for the payload. It can take more into a 300x300x28.5° orbit than 400x400x51.6° orbit. |
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− | + | As a spaceplane, the payload, which can be returned (download) to [[Earth]], is also limited by [[cross range]] and [[Center of gravity|CoG]] requirements. | |
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− | ==== | + | ==Guidance, Navigation and Control== |
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− | + | ===How is the Space Shuttle controlled in real life?=== | |
− | + | The orbiter is usually controlled automatically by the [[GPC|GPCs]] except during landing and some orbit maneuvers (eg docking). Manual control is possible by using [[Rotary hand controller|Rotary hand controllers]] and [[Translation hand controller|Translation hand controllers]], which can be used in many different operation modes. | |
− | The orbiter is usually controlled automatically by the [[GPC|GPCs]] except during landing and some orbit maneuvers (eg docking). Manual control is possible by using [[Rotary hand controller| | ||
− | + | ==Communications== | |
− | + | ===What is the purpose of the Ku-Band antenna?=== | |
The Ku-Band antenna gets used for: | The Ku-Band antenna gets used for: | ||
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*As [[rendezvous]] [[radar]] for tracking the rendezvous target. | *As [[rendezvous]] [[radar]] for tracking the rendezvous target. | ||
− | + | ==Payload Deployment and Retrieval System (PDRS)== | |
− | + | ===What is the PDRS?=== | |
The PDRS is used to maneuver itself or an attached [[payload]] in [[orbit]]. It consists of the | The PDRS is used to maneuver itself or an attached [[payload]] in [[orbit]]. It consists of the | ||
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*deploy and retrieve operations. | *deploy and retrieve operations. | ||
− | + | ===How does the PDRS get controlled?=== | |
All RMS operations involve a two-person operator team. Each member is vital to the success of the mission. The PDRS controls are located primarily on panels A8L, MA73C, and A8U. Other panels that affect the RMS are ML86B, A14, A7U, A6, and R13. The major PDRS CRT display is SPEC 94 PDRS CONTROL. PDRS OVERRIDE SPEC 95, PDRS STATUS DISP 169, and PDRS FAULTS SPEC 96 also control and monitor the RMS. DISP 97 PL RETENTION monitors payload retention device status. | All RMS operations involve a two-person operator team. Each member is vital to the success of the mission. The PDRS controls are located primarily on panels A8L, MA73C, and A8U. Other panels that affect the RMS are ML86B, A14, A7U, A6, and R13. The major PDRS CRT display is SPEC 94 PDRS CONTROL. PDRS OVERRIDE SPEC 95, PDRS STATUS DISP 169, and PDRS FAULTS SPEC 96 also control and monitor the RMS. DISP 97 PL RETENTION monitors payload retention device status. | ||
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*auto modes. | *auto modes. | ||
− | + | ===How is the RMS arm stored in the cargo bay while launch and reentry?=== | |
The [[Remote Manipulator System|RMS]] arm is held in place by a set of ''Mechanic Retention Latches''(MRL) of the ''Manipulator Positioning Mechanism'' (MPM). | The [[Remote Manipulator System|RMS]] arm is held in place by a set of ''Mechanic Retention Latches''(MRL) of the ''Manipulator Positioning Mechanism'' (MPM). | ||
− | + | ==Thermal protection system (TPS)== | |
− | + | ===If there will be a damaged heat shield how will the crew change it?=== | |
Currently, there's no no way to repair the orbiter's [[heat shield]] or [[thermal protection system]]. The TPS consists of both thermal blankets, silica tiles and [[reinforced carbon carbon]](RCC) nosecap and wing leading edge panels. | Currently, there's no no way to repair the orbiter's [[heat shield]] or [[thermal protection system]]. The TPS consists of both thermal blankets, silica tiles and [[reinforced carbon carbon]](RCC) nosecap and wing leading edge panels. | ||
− | + | ===How is a damaged Thermal Protection System detected?=== | |
During launch and ascent, there's a whole bunch of ground tracking cameras and radars that observes the space shuttle for any debris events. There's even a set of seven cameras on the shuttle itself! | During launch and ascent, there's a whole bunch of ground tracking cameras and radars that observes the space shuttle for any debris events. There's even a set of seven cameras on the shuttle itself! | ||
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Also during rendezvous with the [[International Space Station]], the orbiter will do a 360° pitch-around manuever that will allow the ISS crew to photograph the TPS that will later be downlinked to the ground. | Also during rendezvous with the [[International Space Station]], the orbiter will do a 360° pitch-around manuever that will allow the ISS crew to photograph the TPS that will later be downlinked to the ground. | ||
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