Chelomei's preliminary draft project for the UR-700M launch vehicle and LK-700 spacecraft was reviewed by a government expert commission. Based on the decades worth of development and tens of billions or roubles required to realise the project, the state commission recommended that further work on manned Mars expeditions be deferred indefinitely.
TsKBEM was given a completely new structure as a result of the findings of the expert commissions on the disasters for the previous year, Mishin remained as the Chief Designer for the organisation, but each programme now had its own chief designer:
MSC proposed that SL-1 should be flown at an altitude of 435 km and that the orbit should be controlled by removing any insertion dispersions and drag effects with burns of the SL 2 CSM reaction control system after that spacecraft had rendezvoused and docked with SL-1. Additional Details: here....
Manned Spacecraft Center Robert R. Gilruth was appointed to the newly created position of NASA Director of Key Personnel Development. He would integrate NASA planning to fill key positions, identify actual and potential candidates, and guide them through appropriate work experience.
Christopher C. Kraft, Jr., MSC Deputy Director, was named Director of MSC. Both Kraft and Gilruth were original members of the NASA Space Task Group established in 1958 to manage Project Mercury.
Over Pacific. Spacecraft engaged in practical applications and uses of space technology such as weather or communication (US Cat C). Launch vehicle put payload into geosynchronous transfer orbit Positioned in geosynchronous orbit over the Pacific Ocean at 174 deg E in 1972-1974; over the Pacific Ocean 179 deg E in 1975-1982; over the Atlantic Ocean 1 deg W in 1982-1983 As of 28 August 2001 located at 178.00 deg E drifting at 1.569 deg W per day. As of 2007 Mar 7 located at 155.84W drifting at 1.593W degrees per day.
MSFC and MSC completed a Memorandum of Agreement with the National Oceanic and Atmospheric Administration (NOAA) for support contracts for Skylab. The contract would include both ATM and crew radiation monitoring support in the areas concerning the solar network and Mission Control Center Operations. ATM support performed by the National Oceanic and Atmospheric Administration as required by MSFC and MSC would be contracted for by MSC, with that Center providing the technical monitor for the contract and technical direction during the mission simulation and inflight operations phases. Requirements would include a variety of solar data on current solar conditions and predicted solar conditions. These data would ensure effective scheduling of ATM experiments and ATM data for Principal Investigators in the form of photographs, line drawings, etc., to support their detailed analyses of solar activity. The crew radiation monitoring support would be contracted by MSC, with all technical direction provided by the MSC technical monitor. These activities would include management and operation of facilities for acquisition and transmission of solar data for crew radiation monitoring during simulations and inflight operations; a 24-hour solar watch and photographic record; and monitoring of current and future radiation environments to provide an assessment of the biological effect on the flight crew.
Soft landed on Moon; returned soil samples to Earth. Landed on Moon 21 February 1972 at 19:19:00 GMT, Latitude 3.57 N, Longitude 56.50 E - Mare Fecunditatis. Luna 20 was placed in an intermediate earth parking orbit and from this orbit was sent towards the Moon. It entered lunar orbit on February 18, 1972. On 21 February 1972, Luna 20 soft landed on the Moon in a mountainous area known as the Apollonius highlands, 120 km from where Luna 18 had crashed. While on the lunar surface, the panoramic television system was operated. Lunar samples were obtained by means of an extendable drilling apparatus. The ascent stage of Luna 20 was launched from the lunar surface on 22 February 1972 carrying 30 grams of collected lunar samples in a sealed capsule. It landed in the Soviet Union on 25 February 1972. The lunar samples were recovered the following day.
Jupiter flyby December 1973; first man-made object to leave solar system. The spacecraft achieved its closest approach to Jupiter on December 3, 1973, when it reached approximately 2.8 Jovian radii (about 200,000 km). As of Jan. 1, 1997 Pioneer 10 was at about 67 AU from the Sun near the ecliptic plane and heading outward from the Sun at 2.6 AU/year and downstream through the heliomagnetosphere towards the tail region and interstellar space. Additional Details: here....
The Skylab rescue mission was a definite NASA commitment. The hardware, procedures, documentation, and training would need to be available immediately after the launch of Skylab 2 for a potential rescue mission. To accomplish this requirement, the rescue mission would be treated as a separate mission in the Skylab Program. The rescue mission would be established as a standing agenda item for major boards and panels, and its status would be reviewed on a regular basis with other missions.
NASA decided that the shuttle booster will be 2 x 156 inch solid rocket motors. This would reduce the total development cost by $700 million, from $ 5.85 billion to $ 5.15 billion. It was also decided to delete the requirement for the shuttle to be equipped with air-breathing engines for final approach and ferry, and to add Abort Solid Rocket Motors that would pull the shuttle away from the external tank in case of a failure of the solid rocket boosters or external tank during the first portion of the ascent to orbit.
The third Athena H rocket was launched from the Green River, Utah, launch complex. The flight test completed qualification of the vehicle for operational use in the Advanced Ballistic Reentry Vehicle (ABRES) program managed by SAMSO's Deputy for Reentry Systems (RS).
Venus atmospheric probe. The spacecraft took 117 days to reach Venus, entering the atmosphere on 22 July 1972. Descent speed was reduced from 41,696 km/hr to about 900 km/hr by aerobraking. The 2.5 meter diameter parachute opened at an altitude of 60 km, and a refrigeration system was used to cool the interior components. Venera 8 transmitted data during the descent and continued to send back data for 50 minutes after landing. The probe confirmed the earlier data on the high Venus surface temperature and pressure returned by Venera 7, and also measured the light level as being suitable for surface photography, finding it to be similar to the amount of light on Earth on an overcast day.
Central Committee of the Communist Party and Council of Soviet Ministers Decree 'On use of Molniya and Ekran for a unified satellite communications system' was issued. The YeSSS was defined as the Molniya-2 in elliptical orbit and Raduga (Statsionar) in geosynchronous orbit.
During an Orbital Workshop meteoroid shield test at MSFC, it was discovered that in one hinge section of the foldout panel, nine of the 15 torsion springs were installed in such a manner that they were only 50-percent effective in action to assist shield deployment. Action was initiated to ensure proper spring action.
NASA announced that the Kennedy Space Center in Florida and Vandenberg AFB in California would be the operational bases for the future Space Transportation System (STS). The research and development launches of the Space Shuttle would be made from Cape Canaveral, as would the civilian space launches, while the military Space Shuttle launches would be from Vandenberg AFB. SAMSO was the responsible Defense Department agency for defining the military applications and requirements for the Space Shuttle and for cooperating with NASA in the development of the STS.
The Apollo 16 (AS-511) space vehicle was launched from Pad A, Launch Complex 39, KSC, at 12:54 p.m. EST April 16, with a crew of astronauts John W. Young, Thomas K. Mattingly II, and Charles M. Duke, Jr. After insertion into an earth parking orbit for spacecraft system checks, the spacecraft and the S-IVB stage were placed on a trajectory to the moon at 3:28 p.m. CSM transposition and docking with the LM were achieved, although a number of minor anomalies were noted.
One anomaly, an auxiliary propulsion system leak on the S-IVB stage, produced an unpredictable thrust and prevented a final S-IVB targeting maneuver after separation from the CSM. Tracking of the S-IVB ended at 4:04 p.m. EST April 17, when the instrument unit's signal was lost. The stage hit the lunar surface at 4:02 p.m. April 19, 260 kilometers northeast of the target point. The impact was detected by the seismometers left on the moon by the Apollo 12, 14, and 15 missions.
Spacecraft operations were near normal during the coast to the moon. Unexplained light-colored particles from the LM were investigated and identified as shredded thermal paint. Other activities during the translunar coast included a cislunar navigation exercise, ultraviolet photography of the earth and moon, an electrophoresis demonstration, and an investigation of the visual light-flash phenomenon noted on previous flights. Astronaut Duke counted 70 white, instantaneous light flashes that left no after-glow.
Apollo 16 entered a lunar orbit of 314 by 107.7 kilometers at 3:22 p.m. April 19. After separation of LM-11 Orion from CSM 112 Casper, a CSM active rendezvous kept the two vehicles close together while an anomaly discovered on the service propulsion system was evaluated. Tests and analyses showed the redundant system to be still safe and usable if required. The vehicles were again separated and the mission continued on a revised timeline because of the 5 3/4-hour delay.
The lunar module landed with Duke and Young in the moon's Descartes region, about 230 meters northwest of the planned target area at 9:23 p.m. EST April 20. A sleep period was scheduled before EVA.
The first extravehicular activity began at 11:59 a.m. April 21, after the eight-hour rest period. Television coverage of surface activity was delayed until the lunar roving vehicle systems were activated, because the steerable antenna on the lunar module could not be used. The lunar surface experiments packages were deployed, but accidental breaking of the electronics cable rendered the heat flow experiment inoperable. After completing activities at the experiments site, the crew drove the lunar roving vehicle west to Flag Crater, where they performed the planned tasks. The inbound traverse route was just slightly south of the outbound route, and the next stop was Spook Crater. The crew then returned via the experiment station to the lunar module and deployed the solar wind composition experiment. The duration of the extravehicular activity was 7 hours 11 minutes. The distance traveled by the lunar roving vehicle was 4.2 kilometers. The crew collected 20 kilograms of samples.
The second extravehicular traverse, which began at 11:33 a.m. April 22, was south-southeast to a mare-sampling area near the Cinco Craters on Stone Mountain. The crew then drove in a northwesterly direction, making stops near Stubby and Wreck Craters. The last leg of the traverse was north to the experiments station and the lunar module. The second extravehicular activity lasted 7 hours 23 minutes. The distance traveled by the lunar roving vehicle was 11.1 kilometers.
Four stations were deleted from the third extravehicular traverse, which began 30 minutes early at 10:27 a.m. April 23 to allow extra time. The first stop was North Ray Crater, where "House Rock" on the rim of the crater was sampled. The crew then drove southeast to "Shadow Rock." The return route to the LM retraced the outbound route. The third extravehicular activity lasted 5 hours 40 minutes, and the lunar roving vehicle traveled 11.4 kilometers.
Lunar surface activities outside the LM totaled 20 hours 15 minutes for the mission. The total distance traveled in the lunar roving vehicle was 26.7 kilometers. The crew remained on the lunar surface 71 hours 14 minutes and collected 96.6 kilograms of lunar samples.
While the lunar module crew was on the surface, Mattingly, orbiting the moon in the CSM, was obtaining photographs, measuring physical properties of the moon and deep space, and making visual observations. Essentially the same complement of instruments was used to gather data as was used on the Apollo 15 mission, but different areas of the lunar surface were flown over and more comprehensive deep space measurements were made, providing scientific data that could be used to validate findings from Apollo 15 as well as add to the total store of knowledge of the moon and its atmosphere, the solar system, and galactic space.
The LM lifted off from the moon at 8:26 p.m. EST April 23, rendezvoused with the CSM, and docked with it in orbit. Young and Duke transferred to the CSM with samples, film, and equipment, and the LM was jettisoned the next day. LM attitude control was lost at jettison; therefore a deorbit maneuver was not possible and the LM remained in lunar orbit, with an estimated orbital lifetime of about one year.
The particles and fields subsatellite was launched into lunar orbit and normal system operation was noted. However, the spacecraft orbital shaping maneuver was not performed before ejection and the subsatellite was placed in a non-optimum orbit that resulted in a much shorter lifetime than the planned year. Loss of all subsatellite tracking and telemetry data on the 425th revolution (May 29) indicated that the subsatellite had hit the lunar surface.
The mass spectrometer deployment boom stalled during a retract cycle and was jettisoned before transearth injection. The second plane-change maneuver and some orbital science photography were deleted so that transearth injection could be performed about 24 hours earlier than originally planned.
Activities during the transearth coast phase of the mission included photography for a contamination study for the Skylab program and completion of the visual light-flash-phenomenon investigation that had been partially accomplished during translunar coast. A 1-hour 24-minute transearth extravehicular activity was conducted by command module pilot Mattingly to retrieve the film cassettes from the scientific instrument module cameras, inspect the equipment, and expose a microbial-response experiment to the space environment. Two midcourse corrections were made on the return flight to achieve the desired entry interface conditions.
After separation of LM-11 Orion from CSM 112 Casper, a CSM active rendezvous kept the two vehicles close together while an anomaly discovered on the service propulsion system was evaluated. Tests and analyses showed the redundant system to be still safe and usable if required. The vehicles were again separated and the mission continued on a revised timeline because of the 5 3/4-hour delay. The lunar module landed with Duke and Young in the moon's Descartes region, about 230 meters northwest of the planned target area. A sleep period was scheduled before EVA.
Entry and landing were normal, completing a 265-hour 51-minute mission. The command module was viewed on television while dropping on the drogue parachutes, and continuous coverage was provided through crew recovery. Splashdown was at 2:45 p.m. EST (19:45 GMT) in mid-Pacific, 5 kilometers from the recovery ship U.S.S. Ticonderoga. All primary mission objectives had been achieved.
Entry and landing were normal, completing a 265-hour 51-minute mission. The command module was viewed on television while dropping on the drogue parachutes, and continuous coverage was provided through crew recovery. Splashdown was at 19:44 GMT in mid-Pacific, 5 kilometers from the recovery ship U.S.S. Ticonderoga. Additional Details: here....
A compact shower assembly for use on Skylab Earth-orbital missions was designed and built at MSFC. The shower remained stored on the floor when not in use. Astronauts would step inside a ring on the floor and raise a fireproof beta cloth curtain on a hoop and attach it to the ceiling. A flexible hose with push-button shower nozzle could spray 2.8 liters of water from the personal hygiene tank during each bath. Used water would be vacuumed from the shower enclosure into a disposable bag and deposited in the waste tank.
In the second half of 1972 and first half of 1973 TsKBEM began technical development of a Multi-module Orbital Complex (MOK). MOK was not a single spacecraft but an integrated collection of earth-based and near-earth orbital systems consisting of the Multi-module Cosmic Base Station (MKBS); autonomous spacecraft, operating from the MKBS; and logistics systems (expendable and reusable launch vehicles, interorbital tugs, earth launch sites, etc). MOK was dependent on the N1 launch vehicle, and was abandoned when this was cancelled in 1974.
He realized he had been sidelined at NASA and that future plans for lunar and Mars exploration were not to be. He became the vice-present of Fairchild Industries in Germantown, Maryland. There he was also active in establishing and promoting the National Space Institute.
Given that NASA had dictated in great detail the final design, the contractors' proposals differed only in detail. Grumman's orbiter had a 747-type hump-backed configuration, while Lockheed's featured a double-deck crew space. McDonnell-Douglas proposed an alternate auxiliary liquid propellant rocket motor for aborts in place of the mandated Abort Solid Rocket Motors. North American Rockwell's design featured a rounded double-delta wing. All contractors struggled with thermal protection system issues. Ablative materials were lighter, but the bad experience with the use of spray-on ablator on the X-15A-2 made such a solution for an operational vehicle problematic.
Over Indian Ocean. Spacecraft engaged in practical applications and uses of space technology such as weather or communication (US Cat C). Launch vehicle put payload into geosynchronous transfer orbit Positioned in geosynchronous orbit over the Indian Ocean at 61 deg E in 1972-1975; over the Indian Ocean 60 deg E in 1976-1980; over the Pacific Ocean 179 deg E in 1980-1981 As of 2 September 2001 located at 8.61 deg E drifting at 0.536 deg W per day. As of 2007 Mar 9 located at 73.10W drifting at 0.625W degrees per day.
"1. Klyucharev VM: Omsk plant (Director Kolupaev) - Delayed production of 7KS living compartments. ZEM - develop work and schedules to recover schedule for completion of 7KS modules. 2. Chertok: 7K-OK number 18 - rework using the proulsion system from number 36. Work on "Kontakt" to continue, as it can be used in the MKBS'.
The reason for continuing with development of the L3 Kontakt docking system even after the L3 was cancelled was that it was to be used in MKBS. The note reads: Chertok - 7K-OK number 18 - rework using the propulsion system from number 36. Work on "Kontakt" to continue, as it can be used in the MKBS).
NASA Deputy Administrator George M. Low and Associate Administrator for Manned Space Flight Dale D. Myers met and decided there was no foreseeable mission for CSMs 115 and 115a; funds would not be authorized for any work on these spacecraft; and skills would not be retained specifically to work on them.
"Review the possibility of testing and testing of avionics for the spacecraft on the MKBS in real space conditions instead of working in ground conditions with stands and costly ground installations that simulate space flight conditions.
Review MV Melnikov's materials on the use of electronic and neutron beams for special purposes". (Mishin Diaries 3-65):
North American Rockwell received NASA contract NAS9-14000, valued at $2.6 billion, for development of the space shuttle orbiter. Included are two flight articles, the STA Structural Test Article, and the MPTA Main Propulsion Test Article. Later production of two additional orbiters will be added, bringing the final contract value to $ 5.815 billion by 1996.
North American Rockwell issues a study on safety concepts for the space shuttle. These include putting an Apollo command module in the shuttle payload bay as an emergency re-entry capsule in case of inability of the shuttle to re-enter due to heat shield damage or a propulsion system failure. The study finds that all solutions have unacceptable weight penalties, and that any upper stages carried in the payload bay had to be man-rated in order to ensure crew safety. Liquid propellant upper stages (such as Centaur and the planned Space Tug) were probably too dangerous to be taken to orbit by the shuttle.
The Lunar Science Institute's summer study on post-Apollo lunar science arrived at a number of conclusions and recommendations. Some conclusions were: Lunar science would evolve through three rather distinct phases. For two years immediately following Apollo 17, high priority would be given to collection, organization, and preliminary analysis of the wealth of information acquired from the exploration of the moon. In the next two years (1975 and 1976), emphasis would shift to a careful first look at all the data. In the next years, investigations would be concentrated on key problems. Additional Details: here....
An Orbital Workshop all-systems test began on 17 July 1972 and was completed on 7 August 1972 at McDonnell Douglas' Huntington Beach Vehicle Checkout Laboratory. Following the test, which lasted 309 hours, a meeting was held to verify that the OWS all-systems test had been successfully completed. At the conclusion of the meeting, it was agreed that pending closeout of the test anomalies, all test requirements had been satisfied.
The first Long Tank Thrust Augmented Thor/Delta to be launched from Vandenberg AFB using nine solid rocket motors successfully placed the Environmental Resources Technology Satellite (ERTS-A) in orbit. Earth Resources Technology Satellite. Spacecraft engaged in practical applications and uses of space technology such as weather or communication (US Cat C).
The leadership is not returning Mishin's calls and he considers alternate approaches to accelerate the space program. For study:
1. Increase the payload for the launch vehicle for the 7KST by modernizing Block I by using the 11D58M engine.
2. OB-7KST - New arrangement with the container in front (and for scientific and military research equipment).
3. Work out our technical policy for DOS 7KT in a given situation.
- Spacecraft numbers 34, 33, 35 - maybe defer some of them to DOS-3.
- As was provided for in this case in ZEM plan for 1972
4. Utmost acceleration of 7KS.
5. N1-L3 in this situation - a general solution. All for a successful operation. (But we need to agree with MOM.)
6. Accelerate work on MOK - MKBS 1st step. (Mishin Diaries 2-370)
The Soyuz 7K-S had two parallel designs - the base variant, which was for special-purpose military solo missions; and a space station transport variant 7K-ST. The Soyuz 7K-S program was to consist of four unmanned, followed by two manned test flights, then two operational launches.
The State Commission was held to verify readiness of N1 7L for launch. Mishin was 'sick' the whole week of the hearings and had to be represented by his deputies. However neither Mishin or his first deputy Okhapkin were available - both were in the hospital. The commission nearly ruled that until Mishin was available, no launch could be approved. However the review continued. Additional Details: here....
LtGeneral Kenneth W. Schultz assumed command of SAMSO from LtGeneral Samuel C. Phillips who was reassigned to head the National Security Agency (NSA) at Fort George Meade, Maryland. General Schultz had been Deputy Chief of Staff/ Systems at Headquarters AFSC since August 1971 and previous to that had served as SAMSO's Deputy for Minuteman from June 1967 through August 1971 and as Deputy for Ballistic Missile Reentry Systems (D/BMRS) at Ballistic Systems Division from July 1965 to June 1967.
A special ceremony at McDonnell Douglas, Huntington Beach, marked completion of the OWS, the main section of the Skylab space station. The OWS, with a volume equivalent to that of a five-room house, was being readied for shipment to Cape Kennedy aboard the USNS Point Barrow. The trip would take 13 days.
The ATM, which had been at MSC since mid-July, was immediately moved to the Operations and Checkout Building in KSC's industrial area and placed in the cleanroom for intensive checkout. The ATM was scheduled to be moved in January 1973 to the Vehicle Assembly Building for mating with the OWS atop the two-stage Saturn V launch vehicle. The Skylab orbital assembly- consisting of the OWS, the ATM, and the AM/MDA-was scheduled to be launched from Pad A of Launch Complex 39 in late April 1973.
The Skylab 1 Orbital Workshop was offloaded from a NASA barge and moved into the transfer aisle of the Vehicle Assembly Building (VAB) at KSC. The OWS had arrived the preceding day (22 September) aboard the Point Barrow at Port Canaveral, where it was transferred to a smaller barge for the journey through the locks, up the Banana River, and through the access canal to the barge unloading area at the VAB. Following preliminary checkout, the OWS, with its 361.4 cu m of living and working area, was scheduled to be mated to the twostage Saturn V launch vehicle on 28 September.
An Atlas F/Burner IIA launch vehicle, carrying SAMSO's Space Test Program Flight 72-1, was launched from Vandenberg. This was the first use of this booster/upper stage combination. Space craft engaged in investigation of spaceflight techniques and technology (US Cat A).
An Atlas F/Burner IIA launch vehicle, carrying SAMSO's Space Test Program Flight 72-1, was launched from Vandenberg. This was the first use of this booster/upper stage combination. Space craft engaged in investigation of spaceflight techniques and technology (US Cat A).
AMSAT-OSCAR 6 was launched piggyback with ITOS-D (NOAA 2). AO-6 was the first phase 2 satellite (Phase II-A). Weight 16 kg. Box shaped 430 x 300 x 150 mm. Quarter-wave monopole antennas (144 and 435 MHz) and half-wave dipole antenna (29 MHz). Firsts: complex control system using discrete logic; satellite-to-satellite relay communication via AO-7; demonstrated doppler-location of ground station for search and rescue; demonstrated low-cost medical data relay from remote locations. Equipped with solar panels powering NiCd batteries, AO-6 provided 24 V at 3.5 W power to three transponders. It carried a Mode A transponder (100 kHz wide at 1 W) and provided store-and-forward morse and teletype messages (named Codestore) for later transmission. AO-6 lasted 4.5 years until a battery failure ceased operation on June 21, 1977. Subsystems were built in the United States, Australia, and Germany.
A Thor/Delta booster launched from Cape Canaveral successfully placed a Canadian communications satellite, ANIK I, into orbit. This was the 75th Thor/Delta to be launched from the Cape and the first Long Tank Thrust Augmented Thor/Delta to be launched from the Cape with nine strap-on solid rocket motors. It placed the Telestar-A (ANIK) communications satellite in orbit for Canada. Defense Meteorological Satellite Program.
Anik I and Anik II also registered as United States objects. .The satellites, act as space repeaters capable of receiving transmissions from earth stations and retransmitting them to other earth stations in Canada. The antenna coverage of the satellite pr ovides the capability of serving virtually all of Canada. Anik I and II had weights of 1240.59 lb and 1246.48 lb. Each satellite has 12 RF channels each capable of transmitting a color television signal or up to 900 one-way voice channels. Positioned in geosynchronous orbit over the Americas at 114 deg W in 1973-1976; over the Americas at 104 deg W in 1976-1982 As of 1 September 2001 located at 66.14 deg W drifting at 5.205 deg W per day. As of 2007 Mar 9 located at 107.03W drifting at 5.211W degrees per day.
There were still three defects in the new digital computer systems and controversy as to whether to fly the fuel cells in the LOK. But without the fuel cells, there could be no translunar mission. The only power available would then be the batteries in the Block G, limiting the flight to low earth orbit. But the launch manager continued to insist there was danger in handling liquid hydrogen. This was simply a bureaucratic hold-up - only 600 kg of LH2 would be flying, which did not represent a real safety issue. Finally a waiver was agreed and the it was decided the LOK would fly with fuel cells.
All else seemed ready to go. The estimated engine reliability was 93%. The turbogenerators had achieved 100% reliability in test stands. There were still dissenting voices on the use of LH2 - the final vote was 7 for flying with it, and 2 against.
Unmanned test of manned lunar mission launch vehicle serial number 7L. This article incorporated significant changes to the previous model, including roll 'steering' engines to prevent the loss of control that destroyed 6L. The rocket ascended into the sky, and the engines ran 106.93 seconds, only seven seconds before completion of first stage burnout. Programmed shutdown of some engines to prevent overstressing of the structure led to propellant line hammering, rupture of propellant lines, and an explosion of engine number 4. The vehicle disintegrated. Additional Details: here....
Apollo 17 (AS-512), the final Apollo manned lunar landing mission, was launched from Pad A, Launch Complex 39, KSC, at 12:33 a.m. EST December 7. Crew members were astronauts Eugene A. Cernan, Ronald E. Evans, and Harrison H. Schmitt. The launch had been delayed 2 hours 40 minutes by a countdown sequencer failure, the only such delay in the Apollo program caused by a hardware failure.
All launch vehicle systems performed normally in achieving an earth parking orbit of 170 by 168 kilometers. After checkout, insertion into a lunar trajectory was begun at 3:46 a.m.; translunar coast time was shortened to compensate for the launch delay. CSM 114 transposition, docking with LM-12, and LM ejection from the launch vehicle stage were normal. The S-IVB stage was maneuvered for lunar impact, striking the surface about 13.5 kilometers from the preplanned point at 3:27 p.m. EST December 10. The impact was recorded by the passive seismometers left on the moon by Apollo 12, 14, 15, and 16.
The crew performed a heat flow and convection demonstration and an Apollo light-flash experiment during the translunar coast. The scientific instrument module door on the SM was jettisoned at 10:17 a.m. EST December 10. The lunar orbit insertion maneuver was begun at 2:47 p.m. and the Apollo 17 spacecraft entered a lunar orbit of 315 by 97 kilometers. After separation of the LM Challenger from the CSM America and a readjustment of orbits, the LM began its powered descent and landed on the lunar surface in the Taurus-Littrow region at 2:55 p.m. EST on December 11, with Cernan and Schmitt.
The first EVA began about 4 hours later (6:55 p.m.). Offloading of the lunar roving vehicle and equipment proceeded as scheduled. The Apollo Lunar Surface Experiment Package was deployed approximately 185 meters west northwest of the Challenger. Astronaut Cernan drove the lunar roving vehicle to the experiments deployment site, drilled the heat flow and deep core holes, and emplaced the neutron probe experiment. Two geological units were sampled, two explosive packages deployed, and seven traverse gravimeter measurements were taken. During the 7-hour 12-minute EVA, 14 kilograms of samples were collected.
The second extravehicular activity began at 6:28 p.m. EST December 12. Because of geological interest, station stop times were modified. Orange soil was discovered and became the subject of considerable geological discussion. Five surface samples and a double core sample were taken in the area of the orange soil. Three explosive packages were deployed, seven traverse gravimeter measurements were taken, and observations were photographed. Samples collected totaled 34 kilograms during the 7 hours and 37 minutes of the second EVA.
The third and final EVA began at 5:26 p.m. EST December 13. Specific sampling objectives were accomplished. Samples - including blue-gray breccias, fine-grained vesicular basalts, crushed anorthositic rocks, and soils - weighed 66 kilograms. Nine traverse gravimeter measurements were made. The surface electrical properties experiment was terminated. Before reentering the LM, the crew selected a breccia rock to dedicate to the nations represented by students visiting the Mission Control Center. A plaque on the landing gear of the lunar module, commemorating all of the Apollo lunar landings, was then unveiled. After 7 hours 15 minutes, the last Apollo EVA on the lunar surface ended. Total time of the three EVAs was approximately 22 hours; the lunar roving vehicle was driven 35 kilometers, and about 115 kilograms of lunar sample material was acquired.
While Cernan and Schmitt were exploring the lunar surface, Evans was conducting numerous scientific activities in the CSM in lunar orbit. In addition to the panoramic camera, the mapping camera, and the laser altimeter, three new scientific instrument module experiments were included in the Apollo 17 orbital science equipment. An ultraviolet spectrometer measured lunar atmospheric density and composition; an infrared radiometer mapped the thermal characteristics of the moon; and a lunar sounder acquired data on the subsurface structure.
Challenger lifted off the moon at 5:55 p.m. EST December 14. Rendezvous with the orbiting CSM and docking were normal. The two astronauts transferred to the CM with samples and equipment and the LM ascent stage was jettisoned at 1:31 a.m. December 15. Its impact on the lunar surface about 1.6 kilometers from the planned target was recorded by four Apollo 17 geophones and the Apollo 12, 14, 15, and 16 seismometers emplaced on the surface. The seismic experiment explosive packages that had been deployed on the moon were detonated as planned and recorded on the geophones.
During the coast back to earth, Evans left the CSM at 3:27 p.m. EST December 17 for a 1-hour 7-minute inflight EVA and retrieved lunar sounder film and panoramic and mapping camera cassettes from the scientific instrument module bay. The crew conducted the Apollo light- flash experiment and operated the infrared radiometer and ultraviolet spectrometer.
Reentry, landing, and recovery were normal. The command module parachuted into the mid-Pacific at 2:25 p.m. EST December 19, 6.4 kilometers from the prime recovery ship, U.S.S. Ticonderoga. The crew was picked up by helicopter and was on board the U.S.S. Ticonderoga 52 minutes after the CM landed. All primary mission objectives had been achieved.
Environmental research. Primary experiments included a temperature-humidity infrared radiometer (THIR) for measuring day and night surface and cloudtop temperatures as well as the water vapor content of the upper atmosphere, electrically scanning microwave radiometer (ESMR) for mapping the microwave radiation from the earth's surface and atmosphere, infrared temperature profile radiometer (ITPR) for obtaining vertical profiles of temperature and moisture, Nimbus E microwave spectrometer (NEMS) for determining tropospheric temperature profiles, atmospheric water vapor abundances, and cloud liquid water contents, selective chopper radiometer (SCR) for observing the global temperature structure of the atmosphere, and a surface composition mapping radiometer (SCMR) for measuring the differences in the thermal emission characteristics of the earth's surface.
Military-Industrial Commission (VPK) Decree 'On establishment of the Planeta-S weather satellite system' was issued. The resolution ordered development of a third generation system. This used the Planeta-S sensor package in the non-co-orbital Meteor-3 system plus the geostationary system Elektro, which was to begin tests in 1982. Elektro suffered numerous delays due to equipment and software problems. Flight trials of Meteor-3 did not begin until 1984, and there was only a single launch of Elektro, in 1994.
Reentry, landing, and recovery were normal. The Apollo 17 command module parachuted into the mid-Pacific at 19:25 GMT, 6.4 kilometers from the prime recovery ship, U.S.S. Ticonderoga. The crew was picked up by helicopter and was on board the U.S.S. Ticonderoga 52 minutes after the CM landed. Manned exploration of the moon had ended.
Celesco Industries was issued a letter contract to activate an Athena launch complex on Wake Island and to launch 11 Athena H missiles in support of the HAVE MILL program. This program was managed by SAMSO's Deputy for Reentry Systems (RS) for the Army's Safeguard Systems Command (SAFSCOM).