MSC called to the attention of North American Rockwell the number of discrepancies found at KSC that could have been found at Downey before hardware shipment. In an effort to reduce the discrepancies North American was requested to obtain and use the KSC receiving inspection criteria as a guide for shipping inspections. It was also suggested that the possibility of sending a few key inspectors to KSC for periods of three to six months to gain additional experience might be investigated.
Bellcomm engineers presented to NASA a proposed plan for lunar exploration during the period from the first lunar landing through the mid-1970s. The proposed program - based upon what the company termed "reasonable" assumptions concerning hardware capabilities, scientific objectives, launch rates, and relationships to other programs - was divided into four distinct phases:
NASA lunar exploration program developed for the period from the first lunar landing to the mid-1970s. A lunar exploration program had been developed which would cover the period from the first lunar landing to the mid-1970s. The program would be divided into four phases: (1) An Apollo phase employing Apollo hardware. (2) A lunar exploration phase untilizing an extended LM with increased landed payload weight and staytime capability. (3) A lunar orbital survey and exploration phase using the AAP-1A carrier or the LM/ATM to mount remote sensors and photographic equipment on a manned polar orbit mission. (4) A lunar surface rendezvous and exploration phase which would use a modified LM in an unmanned landing to provide increased scientific payload and expendables necessary to extend an accompanying manned LM mission to two weeks duration.
NASA budgetary restraints required an additional cut in AAP launches. The reduced program called for three Saturn IB and three Saturn V launches, including one Workshop launched on a Saturn IB, one Saturn V Workshop, and one ATM. Two lunar missions were planned. Launch of the first Workshop would be in April 1970.
A Parachute Test Vehicle (PTV) test failed at El Centro, Calif. The PTV was released from a B-52 aircraft at 15,240 meters and the drogue chute programmer was actuated by a static line connected to the aircraft. One drogue chute appeared to fail upon deployment, followed by failure of the second drogue seven seconds later. Additional Details: here....
The geodetic instrumentation systems included (1) four optical beacons, (2) two C-band radar transponders, (3) a passive radar reflector, (4) a sequential collation of range radio range transponder, (5) a Goddard range and range rate transponder, (6) laser reflectors, and (7) Doppler beacons. Non-geodetic systems included a laser detector and a Minitrack interferometer beacon. The objectives of the spacecraft were to optimise optical station visibility periods and to provide complementary data for inclination-dependent terms established by the Explorer 29 (GEOS 1) gravimetric studies. The spacecraft was placed into a retrograde orbit to accomplish these objectives. Operational problems occurred in the main power system, optical beacon flash system, and the spacecraft clock, and adjustments in scheduling resulted in nominal operations.
Area survey photo reconnaissance satellite. Unsuccessful mission. Spacecraft failed to separate from Block I stage. Attempt was made to conduct mission without orientation system. APO self destruct system destroyed spacecraft on 126th revolution over Sea of Okhotsk. First generation, low resolution photo surveillance; recovery probably failed.
He is shown the Volga and L1 trainers, takes a seat in the trainer, and is given a simulated space flight. At the air base he reviews the aircraft and the TBK-60 altitude chamber. Throughout the tour, Mishin constantly wore a soft expression and used coarse language. Afanasyev was briefed on and recognised problems with development and delivery of the Salyut digital computer needed for the L1 guidance system. But he was not told that cooperation had broken down totally on the L3 simulator development and crew selection.
The last scheduled Air Force Thrust Augmented Thor/Agena (SLV-2A //498/SS-01B #2733) to be launched from Vandenberg AFB was the 150th Thor/ Agena vehicle fired from there since Discoverer I was launched on 28 February 1959. From now on, the Air Force would use the more advanced Long Tank Thrust Augmented Thor (SLV-2G) - Thorad - and the newer SLV-2H.
NASA launched Apollo 5 - the first, unmanned LM flight - on a Saturn IB from KSC Launch Complex 37B at 5:48:08 p.m. EST. Mission objectives included verifying operation of the LM structure itself and its two primary propulsion systems, to evaluate LM staging, and to evaluate orbital performances of the S-IVB stage and instrument unit. Flight of the AS-204 launch vehicle went as planned, with nosecone (replacing the CSM) jettisoned and LM separating. Flight of LM-1 also went as planned up to the first descent propulsion engine firing. Because velocity increase did not build up as quickly as predicted, the LM guidance system shut the engine down after only four seconds of operation, boosting the LM only to a 171 x 222 km orbit. Mission control personnel in Houston and supporting groups quickly analyzed the problem. They determined that the difficulty was one of guidance software only (and not a fault in hardware design) and pursued an alternate mission plan that ensured meeting the minimum requirements necessary to achieve the primary objectives of the mission. The ascent stage separated and boosted itself into a 172 x 961 km orbit. After mission completion at 2:45 a.m. EST January 23, LM stages were left in orbit to reenter the atmosphere later and disintegrate. Apollo program directors attributed success of the mission to careful preplanning of alternate ways to accomplish flight objectives in the face of unforeseen events.
The 'big' Soviet of Chief Designers meets and the three-launch landing concept developed a month earlier is presented in detail. Pilyugin pointed out that this was a typical contradiction. Mishin had just made a presentation to the expert commission justifying that the one-launch scheme was safe and reliable. Now they wanted to put forward a new scheme because the one-launch scheme was unsafe and unfeasible. Additional Details: here....
The parachute failed to inflate after the capsule separated from the escape tower. The recovery apparatus on both the Soyuz and L1 versions of the capsule continue to perform badly. The soft landing engines have ignited at altitudes of 2000 to 4000 m instead of the 1.2 m required for a soft landing. On the first UR-500K abort the SAS functioned, but the parachute failed to separate after landing, dragging the capsule for 600 m across the steppes. On the second UR-500K abort, there was a premature opening of the parachute, and reaction control system venting led to burn-through of some of the parachute lines.
Kamanin, Gagarin, Titov, Popovich, Belyayev, and Leonov meet with Marshal Yakabovskiy. They inform him that Mishin is blocking further development of the 7K-VI military manned spacecraft and also trying to kill Chelomei's Almaz military space station. They get nowhere. The Marshal says that while he doesn't understand much about space himself, Ustinov had assured him that Mishin and Afanasyev were taking all measures necessary to correct the necessary material...
Nomenclature for the OWS included in the AAP presented in the FY 1969 budget was confirmed by NASA. The ground-outfitted OWS to be launched with Saturn V would be designated the 'Saturn V Workshop.' (This had sometimes been called the 'dry Workshop.') The OWS that would be launched by a Saturn IB would be referred to as the 'Saturn I Workshop.' (Colloquially it had been referred to as the 'wet workshop.') Terminology 'Uprated Saturn I' would not be used officially. This launch vehicle would be referred to as the 'Saturn IB.'
Chertok compared the "Kontakt" and "Liga" systems, and noted that the "Liga" elements in the control loop control system simplified LK landing. MS Ryazanskiy noted that this contradicted a decision two years ago to have the LK make an autonomous landing on the moon (LK homing on and landing near a beacon was postponed at that time). But AS Mnatsanakyan supported the approach, saying it was necessary to speed up the development of the "Liga"; it provided a precision landing on the moon within 50 to 100 m of the target. (Mishin Diaries 2-120).
In preparation for a Soviet of Chief Designers four days later, detailed consideration of many issues was underway. Among them, changes to the baseline LK orbit and ascent trajectories to allow rendezvous with the waiting LOK even after a delay of more than six orbits in departure; and changes to the landing profile to prevent shrapnel from jettison of the LKR's Block D lunar crasher stage impacting the waiting cosmonaut's LK. 250 liters of increased propellant would be required in the LKR for a higher Block D jettison; or the Block D could make a maneuver after separation to assure it would impact well away from the active landing site. (Mishin Diaries 2-119)
VVS Party Conference. It is clear to Kamanin that there is no support from the Air Force for manned spaceflight. Kamanin only heard yesterday that Babakin is working on an automatic soil sample return spacecraft. He will need a minimum of two to three years to complete it. Kamanin complained that it would interfere with plans for the L1 program. An uninterrupted series of flights will be needed to complete the L1 spacecraft qualification, and the Ye-8, using the same booster, could be an interference in achieving that goal.
A Senior Flammability Review Board meeting at MSC reached a number of decisions on the CSM. Attending were Robert R. Gilruth, chairman; George M. Low, Kenneth S. Kleinknecht, Aleck C. Bond, Maxime A. Faget, Donald K. Slayton, Charles A. Berry, and Rodney G. Rose, all of MSC; Samuel C. Phillips, NASA Hq.; William B. Bergen and Dale D. Myers, North American Rockwell; and George Stoner, Boeing (nonvoting observer).
Several previous action assignments were reviewed:
The Board concluded that the material changes made in the CM had resulted in a safe configuration in both the tested atmospheres. The Board agreed "that there will always be a degree of risk associated with manned space flight," but the risk of fire "was now substantially less than the basic risks inherent in manned space flight."
Among decisions reached were:
The final medical report rejects Feoktistov's fitness to be a cosmonaut. Mishin accepts the findings of the report, but in classic manner ignores it and advocates Feoktistov be appointed as commander of the active spacecraft in the first Soyuz docking mission after return to flight. Kamanin is livid. Feoktistov has had years of training for EVA, but he has not had one day of training as a spacecraft commander, and now he wants him to command a mission due to launch in only two to three months! However agreement is finally reached on L1 commander assignments: Leonov, Bykovskiy, Popovich, Voloshin. Agreement is not reached on the second (civilian) crew member position for the flights. According to Mishin, the Soyuz and L1 flights planned from March 1 to the end of 1968 will require 16 to 18 crew members total.
Failed launch of an E-6LS radio-equipped version of the E-6 used to test tracking and communications networks for the Soviet manned lunar program. Suggestions for the abnormal consumption included the seizing up of a pintle valve for controlling fuel supply into the regulator or the seizing up of the fuel inlet control. The upper stages broke up in the atmosphere.
Grumman President L. J. Evans wrote ASPO Manager George M. Low stating his agreement with NASA's decision to forego a second unmanned LM flight using LM-2. (Grumman's new position - the company had earlier strongly urged such a second flight - was reached after discussions with Low and LM Manager G. H. Bolender at the end of January and after flight data was presented at the February 6 meeting of the OMSF Management Council.) Although the decision was not irreversible, being subject to further investigations by both contractor and customer, both sides now were geared for a manned flight on the next LM mission. Additional Details: here....
It is currently organised in three cosmonaut detachments: Nikolayev commands the first detachment, which is training for L3, L1, and Soyuz fiights. Popovich commands the second, training for Almaz and 7K-VI military space missions. Nikeryasov commands the third, which is the 'observer' detachment.
Kamanin states his belief that the L1 will not be ready for manned flight for 2 to 3 years, and will need 8 unmanned flight tests before it can be man-rated. Others disagree, and the final decision is that four unmanned flights without significant failure will be required before the spacecraft is man-rated.
In discussing the results of a manned test with MSC Director Robert R. Gilruth, George M. Low mentioned that a single 45-degree motion of the abort handle was required to initiate a launch abort in Apollo. Gilruth voiced concern that an abort could be caused by a single motion. Additional Details: here....
The booster failure on the previous launch was found to be due to premature fuel injection during engine start, causing initial chamber temperatures to rise 200 degrees above normal. Glushko and Konopatov both guarantee their engines for the next launch. The next L1 flight will use the 'Kruga' landing predictor. This will predict the landing point to within a 150 x 150 km area two to three hours before re-entry. Landing points on the three previous flights would have been 2000 km from Madagascar and India, Novosibirsk, and the North Pole... Mishin plans the next dual Soyuz flight for 5-10 April. Kamanin protests that the parachute and sea trials of the redesigned capsule are not yet complete. Mishin, as usual, dismisses his concerns.
Keldysh heads a Soviet on plans through 1975 for automated probes and space research of the moon and planets. Barmin attends, his interest being the relation of this work to his lunar base. Kamanin finds the plan not well thought out... Tereshkova sees Kamanin and tells him she cannot handle the stress of both political demands on her time and cosmonaut training. She wants Kamanin's assistance to get her out of political tasks.
For this L1 launch Chelomei wants to film separation of the first and second stages of the Proton rocket at 126 seconds into the flight - altitude 41 km, distance downrange 47 km. To do this two An-12 and one Tu-124 with long focal-length cameras will orbit 35 to 40 km from base. The discussion turns to how to recover the L1 if it lands in the ice-bound Aral Sea. The circle of possible landing points has a radius of 500 km from a point west of Karaganda. For political reasons it is not possible to deploy recovery forces to areas of Iran and India that are within this circle.
What at first seemed to be a success, very much needed by the L1 program, ended in failure. The Proton booster lifted off in 18 m/s winds, -3 deg C temperatures, and into very low clouds - it disappeared from view at only 150 m altitude. Aircraft at 9, 10, and 11 km altitude reported the cloud deck topped 8300 m, with 1.5 to 2.0 km visibility. The spacecraft was successfully launched into a 330,000 km apogee orbit 180 degrees away from the moon. On reentry, the guidance system failed, and the planned double skip maneuver to bring the descent module to a landing in the Soviet Union was not possible. Ustinov had ordered the self-destruct package to be armed and the capsule blew up 12 km above the Gulf of Guinea. Kamanin disagreed strongly with this decision; the spacecraft could have still been recovered in the secondary area by Soviet naval vessels after a 20 G reentry. The decsion was made to recover the spacecraft in the future whenever possible.
Officially: Solar Orbit (Heliocentric). Study of remote regions of circumterrestrial space, development of new on-board systems and units of space stations.
At 07:35 the first midcourse manoeuvre for Zond 4, then 225,000 km from earth, was cancelled due to an orientation system problem. The sun tracker worked, but the star tracker could not acquire Sirius. The first and second midcourse manoeuvres are not strictly necessary. However if the third midcourse fails, when the spacecraft is 167,000 km from earth on the return leg, the spacecraft will miss the atmosphere and head back out into space. A meeting is held on cosmonaut training. The simulators are still not adequate. Feoktistov is still demanding that he be trained for the first Soyuz docking mission.
OGO 5 carried 25 experiments, 17 of which were particle studies, and two were magnetic field studies. In addition, there was one each of the following types of experiments: radio astronomy, UV spectrum, Lyman-alpha, solar X ray, plasma waves, and electric field. By April 1971, spacecraft perigee had increased to 26,400 km and inclination had increased to 54 deg. The spacecraft attitude control failed on August 6, 1971, after 41 months of normal operation. The spacecraft was placed in a standby status on October 8, 1971. Four experiments (Meyer, Blamont, Thomas, and Simpson) were reactivated for the period from June 1 to July 13, 1972, after which all operational support terminated. Spacecraft orbit parameters changed significantly over the spacecraft life.
The L1 reaches its apogee. The time comes to attempt the third midcourse manoeuvre. There are three attempts to orient the spacecraft. The first was at the minimum sensitivity setting for the star tracker, the second at the maximum setting, and the third using a high-density filter. Sirius is finally acquired the third time. The spacecraft is oriented and makes a 15 second burn with a 9.129 m/s delta-V (versus 9.202 m/s planned). This is good enough to assure the spacecraft will hit the re-entry corridor without a further correction.
Design Certification Reviews of CSM 101 and LM-3 were held at MSC. Significant program-level agreements reached included validation of a 60-percent-oxygen and 40-percent-nitrogen cabin atmosphere during launch; reaffirmation of the February 6 Management Council decision that a second unmanned LM flight was not required; and the conclusion that, in light of successful static firing of the 102 service propulsion system and subsequent analysis, a static-firing of the 101 system was not required.
It is estimated that Zond 4 will fly 45.8 km below the initial re-entry corridor at an altitude of 145 km, after which it will ricochet back out into space and proceed to a final re-entry and landing on Soviet territory. It is calculated it will land on 7 March at 21:56, 13 minutes later than the originally estimated time.
Mishin certified to MAP on 5 March that the Soyuz parachute system development is complete, but Tkachayev has dissented, saying that the system was unreliable and overweight (this from the same chief designer that certified the previous design as having an 0.999 reliability!). The parachute trials will not be finished until May - meaning there will be no manned Soyuz launch in April. This problem is holding up the L1, L3, and Almaz projects as well.
The L1's SUS guidance system failed on re-entry. It hit the atmosphere precisely at the calculated time, but wasn't guided to generate lift and fly out of the atmosphere again. A ballistic re-entry would mean no recovery on Soviet soil, so the APO destruct system automatically blew up the capsule at 10 to 15 km altitude, 180-200 km off the African coast at Guinea.
NASA technicians at KSC completed the flight readiness test for Apollo 6. The two-day event was delayed several days because of difficulties in modifying the service propulsion system tank skirt. With that significant launch-preparation event completed, program officials were reassessing the launch date in light of work remaining on the vehicle.
The ATM Principal Investigators presented the status of their experiments at Ball Brothers Research Corporation in Boulder, Colorado. They reported good progress in the development of their instruments and presented material to support their assessment that delivery would be on schedule. They also stressed the importance of flying a mission as early as possible during a period of high solar activity.
Gagarin wants better organisation of the TsPK for the L1 circumlunar manned flights, including: better training in manual navigation in case of failure of automated systems; improved training in survival of 20 G re-entries if the automated SUS capsule guidance system fails. The cosmonauts review material for the Seventh International UFO Conference in Mainz (!).
Titov is going to Italy, Feoktistov to Hungary. The 30 month program for the L3 lunar landing is settled. The cosmonauts already began training in January. The first LK lunar lander will be tested in low earth orbit in the second half of 1969. The first Soviet manned lunar landing cannot take place any earlier than 1970-1971. The resolution had set the date as 1967-1968, but the N1 and L3 will not be ready in time. The L3 is still conceptual, a purely paper spacecraft. The first N1 was to have been moved to the pad by March of this year, but it won't even make that milestone by May.
Six Apollo spacecraft are to be flown into earth orbit in 1968, four unmanned and two manned. Five flights are planned for 1969, including the first landing on the moon. Beyond this is the Apollo Applications Program. Expenditures for this are planned as $179 million in 1968 and $435 million in 1969, leading to the first orbital laboratory in 1970.
Meeting with Gay Ilyich Severin. Two spacesuits are being developed for the L3 program: the Krechet-94 and Orlan. Both have been in development for two years. The Krechet-94 will allow six hours of lunar surface activity, the Orlan, 2.5 hours. Both weigh about 90 kg. There are consumables for a total of 52 hours of life support in the LK and the LT Lunar Cart. Kamanin feels the suits are too heavy, due to Mishin's demand for a 5 km range from the LK over a three day traverse with the LT. Severin could have instead developed the spacesuit used by Leonov to have a four hour autonomous operation, but Mishin insisted on doubling of the capacity.
The lunar landing research vehicle was operating and training was being conducted, MSC Director Robert R. Gilruth wrote Langley Research Center's Acting Director Charles J. Donlan. MSC intended to conduct a second class for LLRV pilots and one of the first requirements for checkout was a familiarization program on Langley's Lunar Landing Research Facility. He requested that a program be conducted for not less than four nor more than six MSC pilots between April 15 and May 15.
Apollo drogue chute test 99-5 failed at the El Centro, Calif., parachute facility. The drop was conducted to demonstrate the slight change made in the reefed area and the 10-second reefing cutter at ultimate load conditions. The 5,897-kilogram vehicle was launched from a B-52 aircraft at 10,668 meters and programmer chute operation and timing appeared normal. At drogue deployment following mortar activation, one drogue appeared to separate from the vehicle. Additional Details: here....
Hours are spent arguing over flying Feoktistov as a cosmonaut. Finally the matter is referred to the VPK. Kamanin briefs Ustinov's deputy on his position against Feoktistov. The L1 is reviewed. The star sensor only operated on Zond-4 on the fourth day of flight. However when it worked, it provided a 2 km positional accuracy at re-entry versus the 10 km required. The next L1 is to be launched on 23 April. If that date cannot be met, it will be launched on 25-30 April on a deep-space trajectory (not aimed at the moon).
The Joint Pacific Area Scheduling Office (JPASO) was established at Vandenberg AFB to centralize coordination and scheduling for all Department of Defense offensive/defensive ballistic missile tests.This was without regard to point of origin. Representatives from the Air Force Western Test Range, the Army's Kwajalein Missile Range (KMR), and the Navy's Pacific Missile Range (PMR) were the primary participants in the scheduling meetings.
Russian pilot cosmonaut 1960-1968. First person in space. Due to his fame, the Soviet leadership did not want to risk him on another flight, but later relented. Died in MiG trainer crash while requalifying for flight status. 1 spaceflight, 1.8 hours in space. Flew to orbit on Vostok 1 (1961). Gagarin was flying together with instructor pilot Sergin on a flight in a UTI MiG-15 trainer. Gagarin was being requalified as a jet pilot after being denied flight status by the leadership for a long time. At that time the mean flight hours between fatal accidents hours for Soviet jet fighters were: MiG-15, 18,440 hours; MiG-17, 11,460 hours; MiG-19, 4,475 hours; MiG-21, 4,422 hours; Su-7, 2,245 hours; Su-11, 2,100 hours. Gagarin's UTI MiG-15 s/n 612739 was built at the Vodokhod factory in Czechoslovakia and delivered on 19 March 1956. It had a 2100 hour airframe life, and had flown 1113 hours. It had two overhauls to date: one on 13 July 1962, after 13,834 'mil' hours, and the second on 30 March 1967, after 36,986 'mil' hours. It should have had a 500 hour life after the second overhaul, had flown only 62 hours since then, and had 438 hours left.
After completion of an agreement between the Defense Department and the North Atlantic Treaty Organization (NATO), SAMSO initiated procurement of a two-satellite communications system for NATO. Philco-Ford Corporation was selected to build the two satellites that would be nearly identical to those produced for the United Kingdom's Skynet program.
NASA Hq. confirmed oral instructions to MSC and KSC to use 60 percent oxygen and 40 percent nitrogen to pressurize the Apollo CM cabin in prelaunch checkout operations and during manned chamber testing, as recommended by the Design Certification Review Board on March 7 and confirmed by the NASA Administrator on March 12. This instruction was applicable to flight and test articles at all locations.
The second successful launch of the Saturn V stunned the Soviet engineers. They could not believe the variety and volume of data telemetered back in real-time to the launch centre. They viewed with jealousy the launch room set-up at Cape Canaveral - where each engineering speciality could sit in their own comfortable chair, viewing data as the booster ascended on a computer screen.
He agrees that only pilots should be assigned as crew commanders. However he says that the increase of the training centre to 500 staff will need discussion with the party. Furthermore, Kamanin's wish to move management of manned spacecraft projects from the RSVN to the VVS is a 'difficult subject' that has to be discussed at the highest levels of the Ministry of Defence.
Apollo 6 (AS-502) was launched from Complex 39A at Kennedy Space Center. The space vehicle consisted of a Saturn V launch vehicle with an unmanned, modified Block I command and service module (CSM 020) and a lunar module test article (LTA-2R).
Liftoff at 7:00 a.m. EST was normal but, during the first-stage (S-IC) boost phase, oscillations and abrupt measurement changes were observed. During the second-stage (S-II) boost phase, two of the J-2 engines shut down early and the remaining three were extended approximately one minute to compensate. The third stage (S-IVB) firing was also longer than planned and at termination of thrust the orbit was 177.7 x 362.9 kilometers rather than the 160.9-kilometer near-circular orbit planned. The attempt to reignite the S-IVB engine for the translunar injection was unsuccessful. Reentry speed was 10 kilometers per second rather than the planned 11.1, and the spacecraft landed 90.7 kilometers uprange of the targeted landing point.
The most significant spacecraft anomaly occurred at about 2 minutes 13 seconds after liftoff, when abrupt changes were indicated by strain, vibration, and acceleration measurements in the S-IVB, instrument unit, adapter, lunar module test article, and CSM. Apparently oscillations induced by the launch vehicle exceeded the spacecraft design criteria.
The second-stage (S-II) burn was normal until about 4 minutes 38 seconds after liftoff; then difficulties were recorded. Engine 2 cutoff was recorded about 6 minutes 53 seconds into the flight and engine 3 cutoff less than 3 seconds later. The remaining second-stage engines shut down at 9 minutes 36 seconds - 58 seconds later than planned.
The S-IVB engine during its first burn, which was normal, operated 29 seconds longer than programmed. After two revolutions in a parking orbit, during which the systems were checked, operational tests performed, and several attitude maneuvers made, preparations were completed for the S-IVB engine restart. The firing was scheduled to occur on the Cape Kennedy pass at the end of the second revolution, but could not be accomplished. A ground command was sent to the CSM to carry out a planned alternate mission, and the CSM separated from the S-IVB stage.
A service propulsion system (SPS) engine firing sequence resulted in a 442-second burn and an accompanying free-return orbit of 22,259.1 x 33.3 kilometers. Since the SPS was used to attain the desired high apogee, there was insufficient propellant left to gain the high-velocity increase desired for the entry. For this reason, a complete firing sequence was performed except that the thrust was inhibited.
Parachute deployment was normal and the spacecraft landed about 9 hours 50 minutes after liftoff, in the mid-Pacific, 90.7 kilometers uprange from the predicted landing area (27.40 N 157.59 W). A normal retrieval was made by the U.S.S. Okinawa, with waves of 2.1 to 2.4 meters.
The spacecraft was in good condition, including the unified crew hatch, flown for the first time. Charring of the thermal protection was about the same as that experienced on the Apollo 4 spacecraft (CM 017).
Of the five primary objectives, three - demonstrating separation of launch vehicle stages, performance of the emergency detection system (EDS) in a close-loop mode, and mission support facilities and operations - were achieved. Only partially achieved were the objectives of confirming structure and thermal integrity, compatibility of launch vehicle and spacecraft, and launch loads and dynamic characteristics; and of verifying operation of launch vehicle propulsion, guidance and control, and electrical systems. Apollo 6, therefore, was officially judged in December as "not a success in accordance with . . . NASA mission objectives."
Astronauts James A. Lovell, Jr., Stuart A. Roosa, and Charles M. Duke, Jr., participated in a recovery test of spacecraft 007, conducted by the MSC Landing and Recovery Division in the Gulf of Mexico. The test crew reported that while they did not "recommend the Apollo spacecraft for any extended sea voyages they encountered no serious habitability problems during the 48-hour test. Additional Details: here....
Lunar Orbiter; studied lunar gravitational field, Earth-Moon gravitational relationship, and conducted further scientific experiments in circumlunar space. Not revealed until years later was that the E-6LS was primarily intended to test tracking and communications networks for the Soviet manned lunar program. The Luna 14 spacecraft entered a 140 x 870 km x 42 degree lunar orbit on April 10, 1966. The spacecraft instrumentation was similar to that of Luna 10 and provided data for studies of the interaction of the earth and lunar masses, the lunar gravitational field, the propagation and stability of radio communications to the spacecraft at different orbital positions, solar charged particles and cosmic rays, and the motion of the Moon. This flight was the final flight of the second generation of the Luna series.
No cosmonauts will be sent to witness the next series of unmanned Soyuz flights beginning on 14 April. All cosmonaut staff efforts are concentrated on the Gagarin crash investigation. Kamanin notes the flight of Apollo 6. According to his information the first manned Apollo flight will take place in May-October 1968, and the first American moon landing by the end of 1969.
Cosmos 213 was the target for Cosmos 212 in a successful test of Soyuz 7K-OK rendezvous and docking systems. The Cosmos 213 launch was the most accurate yet. The spacecraft was placed in orbit only 4 km from Cosmos 212, ready for a first-orbit docking. Both spacecraft were recovered, but Cosmos 213 was dragged by heavy wind across the steppes when the parachute lines didn't jettison at touchdown. This failure caused the upcoming Soyuz 2/3 manned docking mission to be scaled back.
Officially: Investigation of outer space, development of new systems and elements to be used in the construction of space devices. Additional Details: here....
This was a reserve day in the L1 countdown, in case of problems in preparation. However all is on schedule for the launch. The same cannot be said for the N1. There are many delays. Mishin promised the first N1 rollout in the first half of March, but it is still in the assembly building, with no end in sight of preparations. The weather at the cosmodrome is -5 deg at night, clear pleasant days. The Hotel Kosmonavt was finished on 15 April. Although it has all of its furniture, it was not completely painted before the furniture was moved in!
However the Commission did not agree to disarm the APO destruct system aboard the capsule. They don't want any chance of 'Soviet electronic secrets' falling into the hands of the Americans. Kamanin disagrees - he thinks they should conduct one fully ballistic re-entry and landing of an L1 to see if the landing system would function and the crew would survive. What's the point of deploying recovery ships to the Indian Ocean if they are only going to blow up the capsule anyway if the SUS fails and it reverts to ballistic mode? Mishin's answer: 'I was always against having those forces in the Indian Ocean!' Yet he had demanded those 7 to 9 recovery ships in February!
L1 launch attempt, lift-off at 02:00 local time. The spacecraft was to separate at 589 seconds into the flight. Instead at 260 seconds, a short circuit in the malfunction detection system incorrectly indicated a launch vehicle failure. This in turn triggered the SAS abort system. The SAS shut down the good stage and separated the spacecraft from the booster. The capsule landed safely 520 km downrange from the launch site. This was the third such abort, which if nothing else proved the reliability of the SAS - all of the spacecraft landed safely.
The cosmonauts and VVS staff will watch the Proton launch from Area 130. Kamanin observes from Area 81, near the pads. It is a warm, starry night and the booster heads toward space on pillars of fire. Up until T+260 seconds all proceeds normally, then the stage 2 shuts down 79 seconds into its burn. At 02:50 it is reported that the capsule separated successfully from the inert booster and has landed 520 km from the launch pad, 110 km east of Dzhezkazgan. Two Il-14 search aircraft and one Mi-4 helicopter fly over the recovery zone, but no signal is received from the capsule. Mishin immediately blames Chelomei's TsKBEM for the booster failure -- later it is shown that Mishin's L1 spacecraft sent an erroneous abort command to the rocket, which then shut down it engines! The capsule is sighted after dawn and picked up by a Mi-6 helicopter and delivered to Dzhezkazgan airfield at 15:00. It is then taken to Moscow for examination. The SAS abort and capsule landing systems have certainly been proven reliable! They have worked perfectly on the last three launches!
Over 10,000 people come out to the steppe, some driving hundreds of kilometres for the event. Kamanin discharges Matinchenko from the cosmonaut corps. He was in two bad automobile accidents on 19 and 21 April. In one of the accidents a six-year-old child was killed.
ASPO Manager George M. Low explained to the Apollo Program Director the underlying causes of slips in CSM and LM delivery dates since establishment of contract dates during the fall of 1967. The general excuse, Low said, was that slips were the result of NASA-directed hardware changes. "This excuse is not valid." He recounted how NASA-imposed changes had been under strict control and only essential changes had been approved by the MSC Level II Configuration Control Board (CCB). Additional Details: here....
Nikolayev is to be commander of the first group, with Leonov as his deputy. Titov would command the second group, with Popovich as his deputy. But Kamanin doesn't consider any of them to be command officer material yet. The automobile accidents of Popovich, the mess that led to Matinchenko's dismissal, the bad performance of Belyayev in his duties as chief of staff of the VVS group at Baikonur - none of these men have any discipline!
Mishin calls Kamanin and asks what he would think of a revised scenario for the next manned Soyuz flight. Mishin's '2+2' concept would call for four, instead of five cosmonauts, aboard two Soyuz capsules with transfer of only one cosmonaut by EVA. He gives Kamanin until 6 May to give his opinion on the change of plan. Titov is planning on selling his Volga automobile and buying a Moskovich.
Headquarters USAF issued a System Management Directive (SMD) to initiate the Hard Rock Silo (HRS) Development Program for Minuteman III. The aim of the program was to develop and test a new, very hard basing system that would be compatible with an Advanced ICBM but initially used for Minuteman III. This SMD was the culmination of previous studies undertaken by the Defense Department and the Air Force on advanced ICBM systems.
It is decided that the TsPK will be named for Gagarin. Meanwhile 400 soldiers and 50 officers have combed the Gagarin crash site, recovering pieces of the aircraft. Gagarin's widow will receive a one-time payment of 5000 roubles, plus 200 roubles/month pension, plus 100 roubles/month for Gagarin's daughter. This is in addition to base amounts of 150/month for the widow and 75/month for the daughter.
Lunar landing research vehicle (LLRV) No. 1 crashed at Ellington Air Force Base, Tex. The pilot, astronaut Neil A. Armstrong, ejected after losing control of the vehicle, landing by parachute with minor injury. Estimated altitude of the LLRV at the time of ejection was 60 meters. LLRV No. 1, which had been on a standard training mission, was a total loss - estimated at $1.5 million. LLRV No. 2 would not begin flight status until the accident investigation had been completed and the cause determined. Additional Details: here....
Kamanin meets with Yuryshev, Deputy Chief of NTK/General Staff, and Maksimov, Deputy Chief of TsKIK, to review military spacecraft. Such spacecraft can be placed in two general categories: Category 1 would be manoeuvrable spacecraft that use active gliding to be guided to a landing point. This technology was currently being developed in the Soyuz and L1 projects. Category 2 would be an orbital aircraft which would be launched from a winged, recoverable, aircraft first stage booster. Less work has been accomplished on such spacecraft. The Mikoyan and Tupolev bureaux have been authorised to begin design and development, but this was still in its earliest stages. But Kamanin believes the second approach has the greatest future potential, and should be pursued more vigorously.
Kamanin reviews the ongoing controversy with Mishin over assignment of Feoktistov to spaceflights. He then turns to the trials of the revised parachute system for Soyuz. The new design has been proven in three landings of spacecraft and 23 tests of mock-ups from aircraft. The SAS abort system has not been retested -- Korolev took full responsibility for its design, and the VVS accepted that in the old days. In any case the likelihood of having to use the SAS or the reserve parachute was not great. Yet still Mishin refuses to recommend going ahead with manned flights. 'I will only proceed when the Central Committee orders me!' he has said. Nevertheless he does declare that Soyuz is now ready to resume manned flights, except for the reserve parachute system, which needs two to three months more development. Based on successful completion of these tests, a manned flight will be possible in the first half of August.
A September 1968 flight test was planned. However the first stage LOX tank developed hairline cracks during ground tests. 4L was removed from the pad in June 1968. The first stage was cannibalized; the upper stages were incorporated into the 1M1 mockup for further training of the launch crews.
Holidays - in the first ten days of May, the civilians work only two days, while the military must work four. Kamanin assigns cosmonauts to the State Commission that will select the design for the Gagarin memorial obelisk. He then reviews cosmonaut pilot aircraft type qualifications. Titov is current on the Su-7, MiG-21, and several other high-performance aircraft. Nikolayev and Leonov are still certified to fly two or three MiG fighter types. Belyayev, Bykovsky, Popovich, Kutachov, and the others are only current on the L-29 trainer. The L-29 is 20 times more reliable than the MiG-21 or Su-7, and the MiG-15 trainer is 4x to 5x more reliable than the high performance types. In general the cosmonauts are against plans to move the air regiment to TsPK from Chkalovsky air field due to greater air space restrictions over Moscow.
One engineer has resigned in the belief that the Gagarin crash was due to a hydraulic accumulator failure. The reason Mishin has been pushing for a reduced Soyuz crew is revealed when the reserve parachute will burst when subjected to forces greater than 1300 kgf/square metre. This implies that the Soyuz SA has to be reduced by 150 to 200 kg mass to allow safe functoning of the reserve parachute in an emergency. A reserve parachute system redesign is not an alternative due to the schedule requirements. Mishin's solution is to fly only two crew in each Soyuz. So he is proposing that the two-Soyuz manned flight carry only two crew in each capsule. No crew transfer will take place, but the BO living module will be depressurised to check its function as an airlock. Kamanin is furious -- this conclusion is reached now, when two years ago crews were standing by for launch on what is now believed to be an unsafe mission! The cosmonauts are also against Mishin's concept - such a flight proves nothing new.
Christopher C. Kraft, Jr., MSC Director of Flight Operations, expressed concern to ASPO Manager George M. Low over the escalation of E-mission objectives; the flight now loomed as an extremely complex and ambitious mission. The probability of accomplishing all the objectives set forth for the mission, said Kraft, was very low. He did not propose changing the mission plan, however. "If we are fortunate," he said, "then certainly the quickest way to the moon will be achieved." Kraft did suggest caution in setting mission priorities and in "apply(ing) adjectives to the objectives." Additional Details: here....
Volynov conducts tests in a pressurised suit to see if it is possible to go from the SA capsule to the BO living module in a two-man crew transfer scenario. He shows it is not possible - exit from the SA to the BO is very unsafe, there is a good chance of getting stuck in the hatch. This shows it would be difficult or impossible for the spacecraft commander in the SA to go to the assistance of a single cosmonaut attempting to transfer from one Soyuz to another. Feoktistov proposes another alternative - launch of 3 cosmonauts in one Soyuz, one cosmonaut in another. After docking, a single cosmonaut would transfer from one Soyuz to another, but at least a second cosmonaut would be in the BO to assist him in case of difficulties. Two cosmonauts would return in each Soyuz capsule, meeting the reserve parachute mass limitations. This solution also takes care of a problem with the 1+2 scenario, in that it implied a crew consisting of Khrunov and Yeliseyev, but neither has been trained as a spacecraft commander. A crew could consist of Volynov and one of these, but then the problem is that no spacesuit has been fabricated for Volynov, and it requires two months to make one.
Titov is to tour. He will spend the next two days in Semipalatinsk, then go to Italy in the first week of June. He has been offered command of the second unit at TsPK, but says he doesn't want to be an administrator. He would rather pursue a career as a test pilot, at either OKB MiG or GNIKI VVS. Mishin is now pushing for a 1+2 Soyuz mission in August on safety grounds. He is also still pushing Khrunov as a spacecraft commander, even though Khrunov has no training in manual docking and it would take at least two months to train and qualify him.
Tereshkova is fighting against her appointment to the Committee of Soviet Women with the requirement for constant tours, appearances, committee sessions, and so on. He has gone to see Suslov about it. Meanwhile the Communist Central Committee and the Soviet Ministers are having a fight over the dates for the planned cosmonaut tour of Africa (the secret objective is to give the cosmonauts training in recognition of southern hemisphere constellations in preparation for lunar missions). Leonov is involved in sending mixed signals to the leadership.
Khrunov tries to don the Yastreb space suit unassisted, in another test of the feasibility of a 1+2 Soyuz mission. He simply cannot accomplish the task in the four minute maximum time required. Mishin now has Ustinov interested in his 1+2 mission, with Yeliseyev to make a solo EVA from one Soyuz to another.
Mishin still wants to eventually conduct a 2+2 mission, but now wants the flight in August to be a 0+1 test flight. In this he is supported by Keldysh and Ustinov. He wants Feoktistov to be the pilot. Kamanin is adamantly opposed and offers him Beregovoi, Volynov, or Shatalov.
NASA released a new AAP launch readiness and delivery schedule. The schedule decreased the number of Saturn flights to 11 Saturn IB flights and one Saturn V flight. It called for three Workshops. One of the Workshops would be launched by a Saturn IB, and another would serve as a backup. The third Workshop would be launched by a Saturn V. The schedule also included one ATM. Launch of the first Workshop would be in November 1970. Lunar missions were no longer planned in the AAP.
George E. Mueller, Associate Administrator for Manned Space Flight, wrote MSC Director Robert R. Gilruth to express his personal interest in lunar extravehicular activity (EVA) training for the Apollo crews of the F and G missions (i.e., the initial lunar landing and subsequent flights). Because of the complexity of the EVA tasks that the astronauts must perform, Mueller said, crews for those missions should be selected as early as possible. Also, realistic training - including a realistic run-through of many of the lunar surface tasks, especially development of the S-band antenna and the Apollo Lunar Surface Experiments Package and sampling operations - must be conducted to ensure that the crews competently carried out the various scientific experiments and other tasks during their brief stays on the moon.
Leonov is raked over the coals concerning his latest accident. In the first place, he had no permission to even be meeting with the Italians. In the second place, he was supposed to be chauffeured when in Moscow, not driving himself. In the third place, he was in training for an L1 lunar mission, and was supposed to be in bed by 23:00, instead of gallivanting around Moscow at all hours of the night.
The first rocket carried a Naval Research Laboratory and University of Maryland payload to a 179-km altitude to flight test a design verification unit of the high-resolution spectroheliograph planned for use on the ATM. The second rocket carried an American Science and Engineering, Inc., payload to a 150-km altitude to obtain high-resolution x-ray pictures of active regions of the Sun during solar flare and general x-ray emission of solar corona. The rocket and instrumentation performed satisfactorily, but the payload of the first rocket failed to separate, thus preventing functioning of the parachute recovery system.
Dale D. Myers, Apollo CSM Program Manager at North American Rockwell, advised MSC officials of his company's investigation of two pilot-chute riser failures during recent drop tests of the Block II earth-landing system. Should there be any imperfections in either hardware or assembly techniques, Myers explained, the Block II pilot chute and riser system could be a marginal-strength item. Investigations had determined that early manufacturing processes had allowed a differential length between the two plies of nylon webbing in the pilot-chute riser which caused unequal load distribution between the two plies and low total riser strength. Because of the earlier test failures, Myers said, the pilot chute riser had been redesigned. The two-ply nylon webbing had been replaced by continuous suspension lines (i.e., 12 nylon cords) and the 5.5-millimeter-diameter cable was changed to 6.3-millimeter cable. He then cited a series of recent tests that verified the redesigned pilot-chute riser's strength to meet deployment under worst-case operational conditions.
Mishin wants one more unpiloted Soyuz launch, resulting in a 0+1 unmanned/manned test flight in September, to be followed by the design 1+3 mission with crew transfer in November/December. The reserve chute failed in tests at an SA re-entry capsule mass of 2800 kg. Therefore, Mishin feels the 0+1 mission would be safe, resulting in a mass for the manned capsule of 2650 kg. But Ustinov insists on the 1+3 mission, meaning an SA mass of 2750 kg. Another consideration is that the capsule may need ballast anyway in order to obtain the correct centre of gravity location for the lifting re-entry manoeuvres. It must be balanced in such a way so that it can re-enter the atmosphere at its maximum 23 degree angle of attack.
An Air Force Titan IIIC, Vehicle #16, was launched from Cape Canaveral and successfully inserted eight 100-pound communications satellites into near-synchronous orbits. These satellites augmented and completed the deployment of the Initial Defense Satellite Communications System (IDSCS) which now consisted of 26 operational satellites Space craft engaged in investigation of spaceflight techniques and technology (US Cat A).
An Air Force Titan IIIC, Vehicle #16, was launched from Cape Canaveral and successfully inserted eight 100-pound communications satellites into near-synchronous orbits. These satellites augmented and completed the deployment of the Initial Defense Satellite Communications System (IDSCS) which now consisted of 26 operational satellites Space craft engaged in investigation of spaceflight techniques and technology (US Cat A).
Apollo Program Director Phillips wrote MSC Director Gilruth concerning the April 10 proposal for a two-burn lunar orbit insertion (LOI) maneuver and a spring ejection of the LM from the spacecraft-lunar module adapter. Phillips agreed to the two-burn LOI in place of the originally planned one burn if results of an analysis should prove the requirement. He specified that an analysis be made of the tradeoffs and that the analysis include the risk of crash, the assumed risks due to lengthening the lunar orbit time (about four hours), and risks due to an additional spacecraft propulsion system burn, as well as the effect of the lunar gravitational potential on the ability to target the LOI maneuver to achieve the desired vector at the time of LM descent. The proposal for spring ejection of the LM from the SLA was approved with the provision that a failure analysis be made in order to understand the risks in the change.
Force Modernization work was officially completed on the first squadron (12th Strategic Missile Squadron) of Minuteman II missiles at Malmstrom AFB, Montana. The work included renovation of the underground launch facilities (LFs) so that they would accommodate the Minuteman II missile.
Construction of the test facilities at Zagorsk for the N1 were directed by Tabakov's NII-229. First static test of the EU-15 test article of the N1's 1200 tonne thrust Block B second stage began on 23 June 1968. Test of the EU-16 Block V third stage began in early 1969, with three trials tests completed. But for the Block A first stage, only single engine tests were undertaken at Kuznetsov's OKB-236. Additional Details: here....
Thiokol-Wasatch Division test fired the 10th, and final, 156-inch diameter, solid-propellant rocket motor (156-8-T). The motor developed one million pounds of thrust during its 118-second firing, which tested a segmented fiberglass case and non-hydroclaved nozzle provided by the Air Force Materials Laboratory (AFML). This test firing completed the Large Solid Rocket Motor Program (Program 623A) begun under Space Systems Division management in 1963.
The State Commission determines the cause of the Proton booster shutdown in April was a short in the L1 abort system. This sent an incorrect abort signal to the launch vehicle, triggering it to shut down its engines. The next L1 launch is set for 19 July, followed by one launch per month thereafter. After 3 or 4 successful unmanned circumlunar missions, the spacecraft will be cleared for a manned lunar flyby.
State commission sets November as date for manned circumlunar flight. The next L1 flight was set for July, with flights to continue at monthly intervals at each translunar launch window. 3 or 4 unmanned flights had to be successful before a manned flight would be attempted.
The information led NASA to decide to send Apollo 8 on a risky lunar orbital mission at the end of December 1968. Interestingly enough the CIA warning to NASA came within days of the L1 State Commission's meeting and decision to press for a November circumlunar flight.
NASA and contractor technicians successfully conducted the final parachute drop test to qualify the Apollo CSM earth-landing system. The Block II ELS thus was considered ready for manned flight after 12 Block I, 4 Block II, and 7 increased-capability Block II Qualification Tests - that had followed 77 Block I, 6 Block II, and 25 increased-capability Block II Development Drop Tests.
The VPK confirms the Soyuz flight plan - a 0+1 mission to be followed by a 1+3 mission with crew transfer. Chiefs of the cosmonaut detachments are confirmed and announced. Nikolayev will be Deputy Chief of TsPK; Bykovsky, Commander of the First Detachment of Cosmonauts; Titov, Commander of the Second Detachment, and Popovich, Deputy Commander of the Second Detachment. Kuznetsov, Belyayev, and Leonov are not happy with these appointments. The General Staff also approves creation of a fourth training detachment at TsPK, charged with flight, engineering, and experiment development - requiring an additional 200 staff.
Marshal Zakharov has consulted with Ryabikov at Gosplan on what commitments Grechko has made from Ministry of Defence funds for L3 recovery forces. Gosplan advised him that 800 million roubles and 21,000 staff were committed, but the justification for these amounts were not methodically developed. Mishin is now saying that hundreds, not thousands of cadres will be required, see he can set the return capsule down in within the confines of the cosmodrome.
VVS has been charged with arranging for ocean recovery of the L3 capsule in case it splashes down in the Indian Ocean since 1966. TsNII-30 did the research work under project 'Ellips', resulting in the recommendation that the VVS and VMF jointly develop the air and naval forces to recover the capsule at sea, at a cost of 800 million roubles. The Ellips concept requires that the L3 capsule be equipped with radio beacons and dye markers. Despite knowing this for two years, Mishin has done nothing to implement these features into the spacecraft.
During launch preparations with the fuelled Proton / L1, there was an explosion, killing three technicians. Their death alone indicates the area around the pad was unsafe at the time. The Block D oxidiser tank of the L1 exploded - the first such failure in 30 uses. The rocket and spacecraft were relatively undamaged. The third stage of the Proton had some external damage due to exposure to the Block D's fuel, but it can be cleaned. The real question is how to remove the L1 spacecraft on the pad. A helicopter could hoist the spacecraft away, but the available Mi-6 or V-10 helos can lift only 8 to 10 tonnes, and the L1 weighs 14 tonnes. A V-10 crew is sent to investigate the possibilities anyway. Some engineers suggest just firing the BPO abort tower and lifting the capsule away from the stack! Emergency political and military meetings are held at the cosmodrome to discuss the impending invasion of Czechoslovakia.
The cosmonauts are revolting against the selection of Nikolayev as their commander. They have written a letter demanding that Belyayev be put in the position. Leonov is also lobbying for the job, but Kamanin notes he has made two serious mistakes since April, no chance. Leonov attends a self-criticism meeting with the 'Gagarin comrades', self-confesses and emotionally says he will leave the cosmonaut unit if there are no future chances for promotion due to his repeated mistakes. Finally he is told that if does good work in the future, he could achieve the deputy commander position, but he can never, never make mistakes again.
A Zenit-2 spy satellite capsule has gone off course, splashed down in the Volga River, and sunk. Vershinin is in the hospital with intestinal polyps. Kamanin is reminded of Korolev's case, although he is told Vershinin's condition is not serious. There is criticism of the botched Zenit-2 recovery from Kutakhov. Meanwhile the Central Committee has decided to take no action on Czechoslovakia but send a letter to the Czech Communist Party. Kamanin is sick of this limp-wristed talk, talk, talk.
In the continuing effort to reduce costs while still maintaining a balanced and viable program, ASPO Manager George M. Low recommended to NASA Hq. that CSM 102 be deleted from the manned flight program. He estimated total savings at $25.5 million (excluding cost of refurbishment after the current ground test program). In addition, he said, during the static structural test program at North American Rockwell, CSM 102 would be subjected to loads that would compromise structural integrity of the vehicle for manned flight.
Vershinin looks bad after his surgery. His loss would be a blow for Kamanin's cause - Vershinin was steadfast against the unobjective positions of Mishin and Smirnov. Vershinin had just sent yet another letter about the procurement of the 16 m centrifuge for the TsPK. This is a six-year long story. The VVS has been trying to procure this essential piece of cosmonaut training equipment since 1962, but it still has not been delivered. Vershinin also has issued a letter on the L3 recovery force issue. He points out that the resolution of the Central Committee ordered the expenditure of 600 million roubles and the commitment of 9,000 men for recovery services. Another 400 million roubles and 12,000 men were earmarked by the Rocket Forces. Despite this huge commitment, Mishin now says he doesn't need any of them, that he can bring his L1 and L3 spacecraft to precision landings within the confines of the cosmodrome, eliminating the need for any Indian Ocean recoveries. This optimism is not accepted, but it is agreed the total requirement can be reduced to 400 million roubles and 7,000 men, through use of lighter recovery ships of the Leninskiy Komsomol class, and the use of three airborne relay stations instead of nine.
The first "stretched" Atlas SLV-3A/ Agena D was launched from the Eastern Test Range. The "stretched" Atlas had an additional 117-inch tank section to provide more fuel, a longer burn time, and increased payload capability. First launch in a communications intelligence program operated by the USAF within the National Reconnaissance Office, on behalf of the National Security Agency. The first generation series, CANYON, was based on the Agena vehicle. The Agena D remained attached to the spacecraft. Positioned in geosynchronous orbit over the Indian Ocean. Last known longitude (30 December 1968) 98.50 deg W drifting at 0.166 deg E per day.
On August 7, Low asked MSC's Director of Flight Operations Christopher C. Kraft, Jr., to look into the feasibility of a lunar orbit mission for Apollo 8 without carrying the LM. A mission with the LM looked as if it might slip until February or March 1969. The following day Low traveled to KSC for an AS-503 review, and from the work schedule it looked like a January 1969 launch. Additional Details: here....
The Apollo Design Certification Review (DCR) Board convened at MSC to examine LM-3 further for proof of design and development maturity and to assess and certify the design of the LM-3 as flightworthy and safe for manned flight. This Delta review was identified as a requirement at the March 6 LM-3 DCR. The Board concluded at the close of the Delta DCR that LM-3 was safe to fly manned with the completion of open work and action items identified during the review.
ASPO Manager George M. Low and several members of his staff met at KSC with Center Director Kurt H. Debus, Launch Operations Director Rocco A. Petrone, and KSC Apollo Program Manager R. O. Middleton to discuss test and checkout problems for AS-503 and AS-504. Additional Details: here....
The next flight of an unmanned Soyuz has been delayed yet again. It had been set for 27 July, then 10 August, and now 20 August. The problem is qualification of the reserve parachute system. The test at Fedosiya on 3 August was a failure - the SA capsule's parachute hatch didn't jettison, the parachute system couldn't operate, and the capsule was destroyed on impact with the ground. The system needed 3 to 5 final tests for qualification. The first test in the series was successful, but this second test was a disaster. Another setback for Mishin. The same parachute hatch mechanism had never failed before in 200 flights of Vostok, Zenit, and Soyuz spacecraft. Meanwhile the invasion of Czechoslovakia is underway…
Applications Technology Satellite that was to have been put into a geosynchronous transfer orbit, instead was left in a nearly-useless LEO orbit. ATS-4 included two cesium contact ion engines. Flight test objectives were to measure thrust and to examine electromagnetic compatibility with other spacecraft subsystems. The 5 cm diameter thrusters were designed to operate at 0.02 kW and provide about 89 microN thrust at about 6700 s specific impulse. The thrusters had the capability to operate at 5 setpoints from 18 to 89 microN. Thrusters were configured so they could be used for East-West station-keeping. Prior to launch, a 5 cm cesium thruster was life tested for 2245 hours at the 67 microN thrust level. However the Centaur upper stage did not achieve a second burn and the spacecraft remained attached to the Centaur in a 218 km by 760 km orbit. It was estimated that the pressure at these altitudes was between 10^-6 and 10^-8 Torr. Each of the two engines was tested on at least two occasions each over the throttling range. Combined test time of the two engines was about 10 hours over a 55 day period. The spacecraft re-entered the atmosphere on October 17, 1968. TheATS-4 flight was the first successful orbital test of an ion engine. There was no evidence of IPS electromagnetic interference related to spacecraft subsystems. Measured values of neutralizer emission current were much less than the ion beam current, implying inadequate neutralization. The spacecraft potential was about -132V which was much different than the anticipated value of about -40V.
On August 12 Kraft informed Low that December 20 was the day if they wanted to launch in daylight. With everyone agreeing to a daylight launch, the launch was planned for December 1 with a "built-in hold" until the 20th, which would have the effect of giving assurance of meeting the schedule. LTA (LM test article)-B was considered as a substitute; it had been through a dynamic test vehicle program, and all except Kotanchik agreed this would be a good substitute. Grumman suggested LTA-4 but Low decided on LTA-B.
Kleinknecht had concluded his CSM 103-106 configuration study by August 13 and determined the high-gain antenna was the most critical item. Kraft was still "GO" and said December 20-26 (except December 25) offered best launch times; he had also looked at January launch possibilities. Slayton had decided to assign the 104 crew to the mission. He had talked to crew commander Frank Borman and Borman was interested.
During a key meeting of Apollo senior figures - top NASA management first approached regarding an Apollo 8 lunar mission in December - reaction: negative. Participants in the August 14 meeting in Washington were Low, Gilruth, Kraft, and Slayton from MSC; von Braun, James, and Richard from MSFC; Debus and Petrone from KSC; and Deputy Administrator Thomas Paine, William Schneider, Julian Bowman, Phillips, and Hage from NASA Hq. Low reviewed the spacecraft aspects; Kraft, flight operations; and Slayton, flight crew support. MSFC had agreed on the LTA-B as the substitute and were still ready to go; and KSC said they would be ready by December 6. Additional Details: here....
Phillips and Paine discussed the plan with Webb in Vienna. Webb wanted to think about it, and requested further information by diplomatic carrier. That same day Phillips called Low and informed him that Mueller had agreed to the plan with the provisions that no full announcement would be made until after the Apollo 7 flight; that it could be announced that 503 would be manned and possible missions were being studied; and that an internal document could be prepared for a planned lunar orbit for December.
NASA Associate Administrator for Manned Space Flight George E. Mueller reported to his superiors that launch preparations for the Apollo 7 mission were running ahead of schedule. Spacecraft 101 had been erected and mated with the launch vehicle on August 9. Additional Details: here....
An Atlas/Burner II (SLV-3, #7004), the first Atlas to be launched with a Burner II upper stage, was launched from Space Launch Complex 3 East (SLC-3E) at Vandenberg but failed to place its payload in orbit due to a malfunction of the nose-fairing heat shield separation system. First of two Atlas/Burner II space launches. 1 of 13 satellite launch attempts; investigate effects of ionosphere on radio signals.
An Atlas/Burner II (SLV-3, #7004), the first Atlas to be launched with a Burner II upper stage, was launched from Space Launch Complex 3 East (SLC-3E) at Vandenberg but failed to place its payload in orbit due to a malfunction of the nose-fairing heat shield separation system.
Webb approves Apollo 8 lunar orbit mission for December - but no public announcement until after a successful Apollo 7 flight. Phillips and Hage visited MSC, bringing the news that Webb had given clear-cut authority to prepare for a December 6 launch, but that they could not proceed with clearance for lunar orbit until after the Apollo 7 flight, which would be an earth-orbital mission with basic objectives of proving the CSM and Saturn V systems. Phillips said that Webb had been "shocked and fairly negative" when he talked to him about the plan on August 15. Subsequently, Paine and Phillips sent Webb a lengthy discourse on why the mission should be changed, and it was felt he would change his mind with a successful Apollo 7 mission.
In a Mission Preparation Directive sent to the three manned space flight Centers, NASA Apollo Program Director Samuel C. Phillips stated that the following changes would be effected in planning and preparation for Apollo flights:
George M. Low, ASPO Manager, set forth the rationale for using LTA-B (as opposed to some other LM test article or even a full-blown LM) as payload ballast on the AS-503 mission. That decision had been a joint one by Headquarters, MSFC, and MSC. Perhaps the chief reason for the decision was Marshall's position that the Saturn V's control system was extremely sensitive to payload weight. Numerous tests had been made for payloads of around 38,555 kilograms but none for those in the 29,435- to 31,750-kilogram range. MSFC had therefore asked that the minimum payload for AS-503 be set at 38,555 kilograms. Additional Details: here....
Eberhard Rees, Director of the Apollo Special Task Team at North American Rockwell, notified the contractor that facilities the team had used at Downey, Calif., were relinquished to the company. Thus ended the mission of the group formed some nine months earlier to oversee the contractor's preparations during the period of adjustment following the Apollo 1 accident.
MSFC Director Wernher von Braun performed a full-pressure suit test in the Saturn I Workshop immersed in the Neutral Buoyancy Tank. He reported that the upgraded seals used in the aft dome penetration sealing study were 'very good,' but recommended additional handholds and tether points.
In response to a letter from Apollo Program Director Samuel C. Phillips concerning proposed revisions of the first lunar landing mission plan, MSC Director Robert R. Gilruth presented MSC's position on the three major topics:
200 aircraft and helicopters are ready for the L1 launch, as well as eight ships in the Indian Ocean. The latter are spaced at 300 km intervals in an area 2500 km long x 400 km wide along the re-entry trajectory. There are Ka-25 helicopters aboard only three of the ships. For manned flights, a minimum of nine ships, all equipped with helicopters, plus a long range Tu-95 search aircraft will be required. But this has been recommended 20 times by Kamanin, and rejected 20 times by the Ministry of Defence. Later the L1 State Commission meets in the new three-story building at Area 81. Launch is set for 15 September at 00:42:10.6, which will mean a night landing at 19:00 on 21 September. The capsule has no visual lights or beacons, which will make it very hard to locate. But Mishin is adamant he cannot change the landing time.
First successful circumlunar flight with recovery. Test flight of manned spacecraft; launched from an earth parking orbit to make a lunar flyby and return to earth. On September 18, 1968, the spacecraft flew around the moon at an altitude of 1950 km. High quality photographs of the earth were taken at a distance of 90,000 km. A biological payload of turtles, wine flies, meal worms, plants, seeds, bacteria, and other living matter was included in the flight. Before re-entry the gyroscopic platform went off line due to ground operator failure. However this time the self destruct command was not given. After a ballistic 20G re-entry the capsule splashed down in the Indian Ocean at 32:63 S, 65:55 E on September 21, 1968 16:08 GMT. Soviet naval vessels were 100 km from the landing location and recovered the spacecraft the next day, shipping it via Bombay back to Soviet Union. Additional Details: here....
Apollo Program Director Samuel C. Phillips formally notified ASPO Manager George M. Low at MSC and Saturn V Program Manager Lee B. James at MSFC of changes in the Apollo Program Specification. As agreed on during the MSF Management Council meeting on August 6, the Apollo payload interface was set at 46,040 kilograms (with a flight geometry reserve of 137 kilometers per hour). Also, the present spacecraft loading philosophy allowed a total spacecraft weight of 46,266 kilograms for lunar missions having less than maximum flight geometry requirements. Additional Details: here....
It is decided to orient Zond 5 using the earth sensor. This is not as accurate as the star tracker, but it is good enough to ensure the spacecraft can be put on a course that will take it back to earth. However it is not accurate enough to allow a a lifting re-entry with a double skip manoeuvre and landing in the Soviet Union. It means the spacecraft must follow a high-G ballistic re-entry and land in the Indian Ocean. Afanasyev is personally supervising the midcourse orientation and engine burn.
The Zond 5 situation remains the same. The star trackers quit working, and the use of the back-up systems has not been completely successful. However the spacecraft is on course for a ballistic re-entry. At Area 112 Afanasyev heads the State Commission for the N1-L3 first launch. There are problems with the launch complex. The main electrical cable to the launch complex was accidentally bulldozed. The back-up cables were buried only 30 cm from the main line and both were destroyed. The cables were poorly marked. It will take 50 days to repair the damage. This will delay first launch until the second half of November 1968, and the second launch to February 1969. Most likely the first launch cannot take place until next year.
Tereshkova is having political problems. Titov is to go to Mexico, although he still is making errors of judgement which make it questionable whether he can be trusted on foreign tours. Beregovoi is to complete his cosmonaut examinations on 27 September, and then will be certified for flight.
At the Fedosiya test range a Soyuz parachute test failed when the parachute hatch wouldn't jettison. This was due to an incorrectly inserted safing pin - it was not a spacecraft problem. So the Soyuz was still cleared for manned flight. Aboard Zond 5, the star tracker has completely failed. So the spacecraft will have to make a ballistic re-entry with splashdown in the Indian Ocean planned at 31 deg 58' S, 65 deg 21' E.
At 17:00 communications with Zond 5 are lost as it re-enters over the South Pole. It has to re-enter at an angle of 5 to 6 degrees to the horizontal. One degree too high, and it will skip off the atmosphere and be lost into space; one degree too low and the G-forces will increase from 10-16 to 30-40 - which are not only enough to kill the crew, but to destroy the spacecraft. The safe entry corridor is only 13 km across and it has to be hit at 11 km/sec. - like hitting a kopek with a rifle at 600 m range. The re-entry schedule:
Meeting of VVS, Mishin, and other designers at Fedosiya to review trials of the improved Soyuz parachute system. The Soyuz is cleared for manned flights. Mishin tells Leonov he will not support him in his bid to make the first lunar flight. Kamanin tells Leonov that of the three crews - Leonov-Voronov, Bykovsky-Rukavishnikov, Popovich-Makarov - the Bykovsky crew is favoured.
A Titan ITIC space booster (Vehicle #5) was launched from Complex 41 at the Eastern Test Range and inserted four satellites into separate earth orbits. The primary payload was the Lincoln Experimental Satellite (LES-6) which was the second all-solid-state ultrahigh frequency (UHF) band communication satellite to be placed into a synchronous orbit. It was designed to test communications with aircraft, ships, and ground forces. The other three satellites were Office of Aerospace Research (OAR) payloads - two Experimental Research Satellites (ERS-21 and ERS-28) and an Orbiting Vehicle (OV 2-5) research satellite. Environmental research. Space craft engaged in investigation of spaceflight techniques and technology (US Cat A). As of 22 August 2001 located at 128.37 deg E drifting at 4.618 deg E per day. As of 2007 Feb 27 located at 91.48E drifting at 4.631E degrees per day.
A Titan ITIC space booster (Vehicle #5) was launched from Complex 41 at the Eastern Test Range and inserted four satellites into separate earth orbits. The primary payload was the Lincoln Experimental Satellite (LES-6) which was the second all-solid-state ultrahigh frequency (UHF) band communication satellite to be placed into a synchronous orbit. It was designed to test communications with aircraft, ships, and ground forces. The other three satellites were Office of Aerospace Research (OAR) payloads - two Experimental Research Satellites (ERS-21 and ERS-28) and an Orbiting Vehicle (OV 2-5) research satellite. Experimental commsat. Space craft engaged in investigation of spaceflight techniques and technology (US Cat A). Positioned in geosynchronous orbit over the Atlantic Ocean at 38 deg W in 1968-1975 As of 26 August 2001 located at 61.90 deg W drifting at 0.101 deg E per day. As of 2007 Mar 9 located at 73.59W drifting at 0.201E degrees per day.
The Allison descent-stage propellant tank, being redesigned at Airite Division of Sargent Industries to a "lidless" configuration, blew up during qualification test at Airite. The crew noticed loss of pressure and therefore tightened fittings and repressurized. As the pressure went up, the tank blew into several pieces. Grumman dispatched a team to Airite to determine the cause and the necessary corrective action.
The results will establish the order in which they will fly as Soyuz commanders. A 25-person board, consisting of spacecraft designers and cosmonauts, conduct the oral examinations. Each cosmonaut must answer five mandatory essay questions and select two two-part questions. All three are certified for flight and have a complete mastery of the Soyuz systems.
Mishin and Kamanin meet and decide on L1 crews: Leonov-Makarov (with Kuklin as back-up); Bykovsky-Rukavishnikov (Klimuk back-up); and Popovich-Sevastyanov (Voloshin back-up). But that evening Leonov has yet another automobile accident. He hit a bus with his Volga at kilometre 24 near Shchelkovsky. This was his second accident in four months. Kamanin decides to prohibit him from driving automobiles for six months.
The L1 cosmonauts are doing training in autonomous navigation, zero-G training, and TBK-60 simulator training. Due to the continuing L1 failures, there would probably be no manned L1 flight until April-May 1969. As for Soyuz, a 0+1 (docking of one unmanned spacecraft and a manned spacecraft with a single cosmonaut aboard) is planned for 25 October, to be followed by a 1+3 mission with a crew transfer by December at the earliest - possibly not until February-March of the following year. Kamanin reassured Beregovoi that he will indeed fly following his excellent exam results -- but Beregovoi still has doubts. Later Kamanin confronts Leonov over his driving. Leonov has had three auto accidents in four months - simply too much. If he is such a bad driver on earth, how will be in space? Kamanin tells him to take two to three days off work and seriously consider his attitude and position. Next there are commissions to attend in charge of selecting monument designs for Gagarin memorials. There are to be obelisks at the Gagarin crash site, at the Vostok 1 landing site, and in Star City. These commissions are taking up a lot of the cosmonauts' time. Kuznetsov meets with Kamanin and tells him that cosmonauts Belyayev and Nikolayev rated Beregovoi poorly in the exam, giving him only a 5 and citing errors in his logic.
Senior management from NASA Hq. and the three manned Centers conducted the Apollo 7 flight readiness review at KSC. Crew, space vehicle, and all supporting elements were ready for flight. Countdown-to-launch sequence had started on October 6, and flight preparations were on schedule for launch readiness at 11:00 a.m. EDT on October 11.
Shonin, Khrunov, and Yeliseyev are in zero-G training aboard the Tu-104 aircraft. The cabin is outfitted with two partial Soyuz mock-ups. In space their EVA between two spacecraft is expected to take one hour and forty minutes, but they can only experience 20 to 25 seconds of weightlessness at a time in the aircraft. The 18 staff aboard the Tu-104 have parachutes in case of a serious problem with the aircraft, but it would take 32 seconds for all of them to jump from the three hatches on the aircraft. Meanwhile the pilot cosmonauts are only flying 50 to 60 hours per year, instead of the 150 to 200 hours that Kamanin had requested.
In preparation for the flight of Apollo 8, NASA and industry technicians at KSC placed CSM 103 atop the Saturn V launch vehicle. The launch escape system was installed the following day; and on October 9 the complete AS-503 space vehicle was rolled out of the Vehicle Assembly Building and moved to the launch pad, where launch preparations were resumed.
Tyulin is still complaining that the VVS never signed the L1 design specification. But the crews are ready for flight. The flight of Apollo 8 to the moon is announced. Kamanin considers this an adventure with no chance of success. After all, there have been only two Saturn V launches, the last one a partial failure. The US has never flown a crew to escape velocity or lunar distance. The whole thing is a risky, unsafe adventure.
Kamanin is at Tyuratam. There is a Soyuz review - the preparation of the spacecraft is on schedule. Mishin is 'sick' (drunk) again and does not attend. Beregovoi weighs in at 80.4 kg and his opponents are using this against him, saying he is too fat for the mission. He had been up to 86 kg, but had already lost weight on Kamanin's recommendation.
At Area 31 one of the Soyuz has thermoregulation system problems and is in repair - it can't be used for flight training. Kamanin notes that Apollo 7 has been launched - the Americans are back in space after almost two years and on the schedule announced a month ago.
Apollo 7 (AS-205), the first manned Apollo flight, lifted off from Launch Complex 34 at Cape Kennedy Oct. 11, carrying Walter M. Schirra, Jr., Donn F. Eisele, and R. Walter Cunningham. The countdown had proceeded smoothly, with only a slight delay because of additional time required to chill the hydrogen system in the S-IVB stage of the Saturn launch vehicle. Liftoff came at 11:03 a.m. EDT. Shortly after insertion into orbit, the S-IVB stage separated from the CSM, and Schirra and his crew performed a simulated docking with the S-IVB stage, maneuvering to within 1.2 meters of the rocket. Although spacecraft separation was normal, the crew reported that one adapter panel had not fully deployed. Two burns using the reaction control system separated the spacecraft and launch stage and set the stage for an orbital rendezvous maneuver, which the crew made on the second day of the flight, using the service propulsion engine.
Crew and spacecraft performed well throughout the mission. During eight burns of the service propulsion system during the flight, the engine functioned normally. October 14, third day of the mission, witnessed the first live television broadcast from a manned American spacecraft.
Soyuz 3 has 18 deficiencies remaining of a total of 55 originally identified. 11 have been cleared, the balance will not affect the flight or reduce redundancy in emergencies. It is decided that Beregovoi and his back-ups will not stay at the traditional cosmonaut cottage at Area 2 but rather at the Hotel Kosmonavt at Area 17.
Apollo Program Director Samuel C. Phillips ordered that the Saturn IB program be placed in a standby status pending any future requirements for Apollo or the Apollo Applications program. Phillips' action signaled the shift in Apollo to the Saturn V vehicle, effective with AS-503.
Two NASA investigation boards had reported that loss of attitude control caused the May 6 accident that destroyed lunar landing research vehicle No. 1, NASA announced. Helium in propellant tanks had been depleted earlier than normal, dropping pressure needed to force hydrogen peroxide propellant to the attitude-control lift rockets and thrusters. Additional Details: here....
Coordination problems between the ministries in preparation of the Soyuz spacecraft. VVS and MAP have managers assigned for quality control of each system, while MOM (Afanasyev) counterpart staff are disorganised. Yet again conflicts have to be appealed to 'Cardinal' Ustinov.
ASAT interceptor. Intercepted Cosmos 248 target on second orbit. Repeatedly approached Cosmos 248, verifying primary and reserve homing and guidance systems. Destroyed itself in test of on-board destruct system. Counted as a failure by Western observers because that target was not destroyed; but this was not an objective of the test. Left 109 fragments in orbit, of which 54 were still in orbit in 1996.
The SPS engine was used to deorbit after 259 hours 39 minutes of flight. CM-SM separation and operation of the earth landing system were normal, and the spacecraft splashed down about 13 kilometers from the recovery ship (27.32 N 64.04 W), the U.S.S. Essex at 11:11 GMT. Although the vehicle initially settled in an apex-down ("stable 2") attitude, upright bags functioned normally and returned the CSM to an upright position in the water. Schirra, Eisele, and Cunningham were quickly picked up by a recovery helicopter and were safe aboard the recovery vessel less than an hour after splashdown.
All primary Apollo 7 mission objectives were met, as well as every detailed test objective (and three test objectives not originally planned). Engineering firsts from Apollo 7, aside from live television from space, included drinking water for the crew produced as a by-product of the fuel cells. Piloting and navigation accomplishments included an optical rendezvous, daylight platform realignment, and orbital determination via sextant tracking of another vehicle. All spacecraft systems performed satisfactorily. Minor anomalies were countered by backup systems or changes in procedures. With successful completion of the Apollo 7 mission, which proved out the design of the Block II CSM (CSM 101), NASA and the nation had taken the first step on the pathway to the moon.
Although the systems worked, the crew became grumpy with head colds and talked back to the ground. As a result, NASA management determined that none of them would fly again. Apollo 7 landed at 07:12 GMT.
Kamanin visits the Korolev and Gagarin cottages. He finds them in bad condition, in need of repair. They should be restored as they were in 1961 and be made into museums. At 16:00 the rocket is rolled out to Area 31. 500 are present at the State Commission meeting.
Glushko has a private conversation with Isayev at the N1 MIK during the Soyuz 3 launch preparations. Glushko revealed to Isayev that in 1961 he had offered Korolev a compromise - if Korolev would use the same 'packet' scheme for the N1 that he had used on the R-7, so that the individual engine modules could be individually tested on the ground before flight, Glushko would give up his insistence on the use of storable propellants. However, after checking with Mishin, Korolev would not compromise. Additional Details: here....
Unmanned docking target for Soyuz 3. Soyuz 2 launched on time at 12:00 local time, in 0 deg C temperatures and 5 m/s winds. Launch was on time 'as in Korolev's time', notes Kamanin. Docking with Soyuz 3 a failure. Recovered October 28, 1968 7:51 GMT, 5 km from its aim point. Maneuver Summary:
177km X 196km orbit to 184km X 230km orbit. Delta V: 12 m/s.
Officially: Complex testing of spaceship systems in conditions of space flight.
Second manned Soyuz flight. Rendezvoused with the unmanned Soyuz 2 but failed to dock. Complex testing of spaceship systems; development, in joint flight with space ship Soyuz 2 of processes of space ship manoeuvring and docking in artificial earth satellite orbit; development of elements of celestial navigation; conduct of research under space flight conditions. The failed docking was blamed on manual control of the Soyuz by Beregovoi, who repeatedly put the spacecraft in an orientation that nulled the automatic docking system. Beregovoi used nearly all of his orientation fuel in his first attempt to dock - of 80 kg allocated, only 8 to 10 kg was remaining. Additional Details: here....
He can't understand why Beregovoi couldn't dock. Beregovoi seems garbled. The cabin atmosphere is all right. He is ordered to orient the spacecraft to the sun - which he accomplishes readily with minimum propellant expenditure. The Soyuz 2 45K star sensor is not functioning - 'as usual' notes Kamanin.
Meanwhile Beregovoi was instructed to conduct experiments with the 45K stellar sensor on Soyuz 3. He would quickly disengage the 45K, then orient the spacecraft to the sun. He would then reengage the sensor and the automatic orientation system. This did two complete turns of the spacecraft searching for the star, but not acquiring it. To Kamanin this shows the uselessness of the system, and the wastage of propellant it causes.
NASA began the design, bidding, and source selection process leading to a single national space shuttle. At the beginning the design was known by the same nomenclature previously used by the USAF - Integrated Launch and Re-entry Vehicle (ILRV). The development program was seen as: Phase A: Advanced Studies; Phase B: Project Definition; Phase C: Vehicle Design; and Phase D: Production and Operations. Four contractors or contractor teams were to be selected in Phase A; two contractors or teams for Phase B; and then a single contractor for Phases C and D (which were later combined). NASA Houston and Huntsville jointly issued the Request for Proposal for eight-month Phase A ILRV studies. The requirements were for 2,300 to 23,000 kg of payload to be delivered into a 500-km altitude orbit. The re-entry vehicle should have a cross range of at least 725 km (NASA persisted in this requirement even though it knew the USAF needed more). General Dynamics, Lockheed, McDonnell-Douglas, Martin Marietta, and North American Rockwell all were invited to bid.
The Space Shuttle Main Engine competition was run in parallel with the main shuttle development project, and also had four phases. Oversight for this program came from the USAF Space Division and its subcontractor, the Aerospace Corporation. Despite promising classified work on linear and conventional aerospike engines at the time, NASA dictated that the design had to use a conventional bell nozzle.
Telemetry analysis has shown Soyuz 3 used 30 kg of propellant during 20 minutes of manoeuvring in the automatic regime during docking, followed by 40 kg consumed in two minutes of manual manoeuvring. Essentially Beregovoi was trying to dock the spacecraft upside down. This was either due to incorrect configuration of the running lights or cosmonaut error. Soyuz 2 had two continuously illuminated lights on its upper side and two blinking lights on the lower side. Evidently Beregovoi didn't identify these correctly in weightlessness.
In case Beregovoi has to do a ballistic re-entry, Be-2 seaplanes are in the air in case of a splashdown in the Aral Sea. On his 81st revolution, Beregovoi manually oriented the spacecraft for retrofire, then engaged the vertical sensor and ion orientation system. But the spacecraft hit on ion pocket and it took two to three minutes for the automated system to engage. Retrofire started 3 seconds late, coming at 9:45:05 and continuing for 149 seconds, producing a delta V of 95 m/s. The main parachute deployed at 10:12:24 at 7000 m altitude. Beregovoi spent 13 minutes under the main parachute, descending at 4 to 5 m/s. Soyuz 3 landed 10 km from the aimpoint at 07:25 GMT.
The post-flight debriefing of Beregovoi reveals that the automated docking sequence from 11,000 to 200 m range from the Soyuz 2 target was normal. At 200 m Beregovoi took over manual control of the spacecraft. At a range of 30 to 40 m he observed the running lights on Soyuz 2 were inverted. He stopped his approach and waited until the spacecraft moved into daylight. By that time the spacecraft were still 30 to 40 m away, but had drifted so that he was 30 degrees off-angle from Soyuz 2. It was in attempting to bring the spacecraft back on axis that he used 30 kg of propellant. He then gave up and hand-flew the spacecraft around Soyuz 2 to take photographs. On the first day of his flight he constantly felt like he was hanging upside-down. This feeling only disappeared on the last day of the flight.
Apollo 7 - flown October 11-22 - far exceeded Low's expectations in results and left no doubts that they should go for lunar orbit on Apollo 8. At the November 10 Apollo Executive meeting Phillips presented a summary of the activities; James gave the launch vehicle status; Low reported on the spacecraft status and said he was impressed with the way KSC had handled its tight checkout schedule; Slayton reported on the flight plan; and Petrone on checkout readiness. Petrone said KSC could launch as early as December 10 or 12. Phillips said he would recommend to the Management Council the next day for Apollo 8 to go lunar orbit. Additional Details: here....
Test flight of manned circumlunar spacecraft. Successfully launched towards the moon with a scientific payload including cosmic-ray and micrometeoroid detectors, photography equipment, and a biological specimens. A midcourse correction on 12 November resulted in a loop around the moon at an altitude of 2,420 km on 14 November. Zond 6 took spectacular photos of the moon's limb with the earth in the background. Photographs were also taken of the lunar near and far side with panchromatic film from distances of approximately 11,000 km and 3300 km. Each photo was 12.70 by 17.78 cm. Some of the views allowed for stereo pictures. On the return leg a gasket failed, leading to cabin depressurisation, which would have been fatal to a human crew. The 7K-L1 then made the first successful double skip trajectory, dipping into the earth's atmosphere over Antarctica, slowing from 11 km/sec to suborbital velocity, then skipping back out into space before making a final re-entry onto Soviet territory. The landing point was only 16 km from the pad from which it had been launched toward the moon. After the re-entry the main parachute ejected prematurely, ripping the main canopy, leading to the capsule being destroyed on impact with the ground. One negative was recovered from the camera container and a small victory obtained over the Americans. But the criteria for a manned flight had obviously not been met and Mishin's only hope to beet the Americans was a failure or delay in the Apollo 8 flight set for December. The next Zond test was set for January. Additional Details: here....
Two Volga automobiles and two buses take the State Commission from the Hotel Kosmonavt to Area 81. The L1 launch into parking orbit is good (parameters 88.23 minutes period vs 88.3 planned; inclination 51.24 deg vs 51.5 deg planned; perigee 188.5 km vs 192 km planned; apogee 207 km vs 218 km planned). Translunar injection proceeds normally, but afterwards the high gain antenna doesn't deploy. As a result, there is no telemetry from the astro-navigation system. Kamanin rages, 100 million roubles in launch costs, ruined by one defect. The star sensors 100K and 101K will be tested tomorrow. However without course corrections the spacecraft will miss the earth by 1050 km on return. When the midcourse correction is attempted, the 101K sensor fails, but the 100K functions, and acquires Sirius. This is enough to orient the spacecraft, and 40 minutes later an 8.5 second engine burn is made to put the spacecraft on course.
The Apollo Crew Safety Review Board met to assess land landing of the CSM in the area of the launch site if a flight were aborted just before launch or during the initial phase of a flight. In general the Board was satisfied with overall planned recovery and medical operations. The only specific item to be acted on was some means of purging the interior of the spacecraft to expel any coolant or propellant fumes that might be trapped inside the cabin. The Board was also concerned about the likelihood of residual propellants trapped inside the vehicle even after abort sequence purging, a problem that MSC secured assistance from both the Ames and Lewis Research Centers to solve. At the Board's suggestion, MSC's Crew Systems Division also investigated the use of a helmet liner for the astronauts to prevent head injury upon impact. Finally, the Board recommended continued egress training with fully suited crews, including some night training.
Tracking of the L1 shows it will hit the earth on return, but without a further midcourse correction the perigee will be 200 km instead of the 45 km required. Therefore another correction will be needed on the way back from the moon. Ustinov calls a meeting and asks 'How do we answer Apollo 8?'. The reply of Mishin and Tyulin is that 'we are not ready to answer Apollo 8. Apollo 8 is a high-risk adventure. The Americans have not accomplished any unmanned lunar flybys to demonstrate that their systems will function correctly; and of only two Saturn V flight tests to date, the second was a failure. We need to make the L1 program public to show the seriousness and completeness of Soviet readiness'. Ustinov orders the following plan be carried out in the next two months: in December, one unmanned L1 flight, and the first launch of the N1 with an L3 mock-up. In January 1969, a lunar flyby with two cosmonauts; a Lunokhod robot rover will be placed on the lunar surface; and a dual Soyuz manned flight with 1+3 crewmembers. Kamanin notes that the problem with the technical approach of Korolev and Mishin is that cosmonauts are seen only as observers and back-ups to automated systems. Therefore the whole manned space program is based on a false assumption. Because of this the Soviets have lost 2-3 years in the space race, which would have been saved if they had followed the Gemini/Apollo 'pilot in the loop' approach. Afterwards Mishin meets with the L1 cosmonaut group. He wants to get rid of the on-board flight plan and reduce the manual for operation of the spacecraft to one page. 'Don't want to bring bureaucracy aboard the spacecraft' he says. This completely absurd idea again demonstrates his belief in total reliance on automated systems.
The L1 went behind the moon at 05:49:37, and emerges at 06:21:11. At the time of the next orientation session it is 390,000 km from the earth and moving at 0.6 km/s. All orientations have been made on Sirius so far. Two more are needed: one for the midcourse correction, and then the second for the guided re-entry. The 100K sensor has proven itself despite Kamanin's doubts. Mishin's grumbly voice was grating on everyone, and finally he was put to bed. Kamanin despairs that the Soviet space program is dependent on this poorly organised, capricious, shortsighted man. Discussions are held with Moscow. If Apollo 8 succeeds, the next L1 test in January and the manned flight in April are probably not worth the risk. Some of the scientists want to discuss the inclusion of new medical experiments on pending manned spaceflights, but Kamanin is opposed to it. He does not want anything interfering with the primary mission. What to name the manned L1 spacecraft is discussed. Leonov wants to call it Rodina, Sevastyanov Ural, and Kamanin - 'Academician Korolev'.
Overnight a serious situation has developed. The hydrogen peroxide temperature aboard the L1 capsule has fallen from +20 deg C to -2 deg C. By the following morning it was down to -5 deg C. At such temperatures it will disassociate into oxygen and water, and the capsule's orientation thrusters will not be able to function for re-entry. A colour television camera was supposed to have been included in the cabin. If it was there it could be turned on and warm the capsule, but Mishin had insisted to the State Commission that it be deleted. The spacecraft could be oriented so that the sun would shine directly over the peroxide tank and warm it, but this might damage the 100K star sensor, which was mounted right next to it. A proposal is made that an attempt is made to orient the spacecraft using the ONA gyroscope package as flywheels, but Mishin and his deputies don't want to try anything. Mishin suddenly says that the next L1 will not be ready until February or later (before the date was January). This was seen by Kamanin as a typical 180-degree turn for him. Mishin looks bad - probably he's been drinking again. Kamanin sees no solution but a complete reorganisation of the space program, moving the manned program to the VVS.
Mishin is comatose, pulse 88, blood pressure 160 over 90. The doctors want to put him in the hospital, but he stays. The side of the L1 where the tanks were mounted finally comes into the sun, and the temperature rises to -1 deg C, a safer temperature than before. But now there is a new problem -- the cabin pressure fell from 718 mm at 05:13 to 610 mm by 05:20. By 08:30 it was down to 350 mm - essentially a situation of a depressurised cabin as far as the landing instruments are concerned. By 18:00 the temperature and pressure in the capsule have stabilised and Mishin is in the hospital. Meanwhile Kosygin is visiting the TsPK.
The hydrogen peroxide temperature has risen to +1 deg C, and the cabin pressure is at 380 mm. The eighth stellar orientation and midcourse manoeuvre was made successful - the 100K sensor has rehabilitated itself. The 3.3-second burn moved the perigee by 25 km, and the spacecraft is expected to hit the center of the re-entry corridor - 49 km altitude plus/minus 7 km. But the State Commission has decided to arm the APO destruct system to destroy the spacecraft if it deviates from its ballistic trajectory.
By 20:00 the cabin pressure was down to 180 mm, and then reached 25 mm at re-entry. At 16:00 the spacecraft confirmed that all landing commands had been received successfully. At 16:20 it confirmed correct orientation for re-entry. The tracking vessel Komarov tracked the capsule in its first dip into the atmosphere over the Indian Ocean. The tracking ship crew estimated the capsule would miss the landing point by 1800 km. However Zond 6 successfully completed the double-skip re-entry. It was picked up by PVO radars 300 km from the border of Afghanistan, and tracked to 100 to 150 km north of the cosmodrome. Radio communications and the radar transponder aboard the capsule were inoperative, and the precise landing point could not be determined. The parachute should have deployed at 17:19 and Kiev and Baku received a brief 1 to 2 second radio burst from the capsule, but nothing thereafter. A search begins for the capsule using 50 aircraft and 12 helicopters. Finally at 06:35 the next morning an Mi-4 sees the parachute 38 km southeast of Novokazalinsk, 70 km from Baikonur. The spacecraft is found 3 km away at 12:00.
Martin L. Raines, MSC's Manager at the White Sands Test Facility, recommended to ASPO Manager George M. Low that he issue official direction to the two spacecraft contractors, North American Rockwell and Grumman, governing the phasedown of operations at the engine test site. Early action was needed, Raines said, for proper contractual action on the phasedown and for proper disposition of equipment and supplies. This action signaled the end of the long and difficult supportive development effort to prove out the Apollo spacecraft rocket engines for flight.
Titov still would prefer to be a test pilot, not a cosmonaut. The Soyuz group is scheduled to complete their training and to depart for the cosmodrome on 20 December for final preparations. Leonov's L1 group is to complete their training on 20 January 1969, then depart to the cosmodrome for a flight to the moon in February.
Kamanin attends an Yastreb spacesuit review with VVS doctors. The suit removes 200 cal/hour, but when the cosmonaut is exerting himself, he will generate 3 to 4 times more than this. So the cabin is chilled to 18 deg C prior to the EVA, and there will be lots of pauses during preparations to exit the spacecraft. The L1 cosmonaut-engineers at the meeting have little zero-G experience, and need to get a lot more. The new oxygen generating system for the L1 is still not complete. It will be 6 to 8 kg lighter than the old system (using calcium instead of the old material). Mishin insists that the new system should be completed and installed. Ground qualification testing will be completed on 1 January, but the system will not be flight-proven - Kamanin believes it needs test on low earth orbit missions before being adopted for lunar flights. Beregovoi's experience on Soyuz 3 is reviewed. He needed more time to adapt to zero-G before being required to attempt a docking. He had the impression he was upside-down and had intestinal tract problems.
The previous launch date of 25 November has been pushed back to January 1969. The N1 has completed a good cycle of ground tests, but work on the L3 has not even begun. There is no news when it will be ready. The L3 plan called for the first article to be ready in March 1968. 20 cosmonauts from the L1 and Soyuz groups were to have trained on the spacecraft. But MOM never issued the implementation plan to the industrial enterprises to begin work on the spacecraft.
Howard W. Tindall, Jr., Chief of Apollo Data Priority Coordination within ASPO, reported an operational system problem aboard the LM. To give a returning Apollo crew an indication of time remaining to perform a landing maneuver or to abort, a light on the LM instrument panel would come on when about two minutes worth of propellants remained in the descent propellant system tanks with the descent engine running at 25-percent thrust. The present LM weight and descent trajectory were such that the light would always come on before touchdown. The only hitch, said Tindall, was that the signal was connected to the spacecraft master alarm. "Just at the most critical time in the most critical operation of a perfectly nominal lunar landing mission, the master alarm with all its lights, bells, and whistles will go off." Tindall related that some four or five years earlier, astronaut Pete Conrad had called the arrangement "completely unacceptable . . . but he was probably just an Ensign at the time and apparently no one paid any attention." If this "is not fixed," Tindall said, "I predict the first words uttered by the first astronaut to land on the moon will be 'Gee whiz, that master alarm certainly startled me.'" Tindall recommended either rerouting the signal wiring to bypass the alarm or cutting the signal wire and relying solely on the propellant gauges to assess flight time remaining.
The primary issue in the next 3 to 4 months will be how to answer the impending American Apollo 8 flight. The Soviet Union needs to fly a manned L1 in the 8 to 12 December lunar launch window. But the spacecraft is still considered too unsafe for manned flight. The Apollo 8 mission is risky, but the US can't fly the Apollo spacecraft to the moon unmanned...
Beregovoi is to be named commander of the Gagarin Centre. Gagarin himself was being prepared for the job, but his death in a plane crash ended that plan. The other cosmonauts are not ready for command. The centre desperately needs the two planned L3 trainers: the TBK-150 and Volchuk. Kamanin has been jerked around for four months on the issue. Even if the simulators were delivered, he would still need 2 million roubles and an additional 30 to 40 staff to install and operate them.
The LM-11 midsection assembly collapsed in the assembly jig during the bulkhead prefitting stage of construction at Grumman. The structure buckled when the bulkheads, which had just been prefitted and drilled, were removed to permit deburring the drilled holes. Jig gates that were supposed to hold up the assembly were not in position, nor was the safety line properly installed. The structure was supported by hand. Damage to the skin of the structure was not severe, although a small radius bend was put in one of the upper skins.
Soyuz spacecraft 12 and 13 have begun their 45 day preparation cycle at Baikonur, which implies a 15 January 1969 launch for he Soyuz 4/5 mission. The crews will be ready by 25 December.
Kamanin compares the results of Soyuz capsule re-entries to date:
Soyuz s/n 7 8 9 10 11 Max G's 3.15 3.5 3.5 3.5 3.5 SA Propellant, kg 40.0 40.0 40.0 38.0 38.0 Propellant usage: Used Pre-reentry, kg 8.5 10.0 2.0 3.0 5.3 Used in Re-entry, kg 17.5 29.0 3.7 9.5 12.5 Total 26.0 39.0 5.7 12.5 17.8 Left at chute opening, kg 14.0 0.0 34.3 25.8 20.2 Miss distance, km 157 55 40 15 42
The State Commission investigating Gagarin's crash publishes it report. It found that pilot error put the aircraft into a critical situation. Kamanin judges that the Apollo 8 mission is only being flown to give US President Lyndon Johnson a triumph before he leaves office. He judges the mission has only a 25% chance of success.
Orbiting Astronomical Observatory; carried 11 telescopes; performed X-ray, UV, IR observations of stars. Spacecraft engaged in research and exploration of the upper atmosphere or outer space (US Cat B). Launch vehicle put payload into geosynchronous transfer orbit
During a routine flight of lunar landing training vehicle (LLTV) No. 1, MSC test pilot Joseph S. Algranti was forced to eject from the craft when it became unstable and he could no longer control the vehicle. The LLTV crashed and burned. A flight readiness review at MSC on November 26 had found the LLTV ready for use in astronaut training, and 10 flight tests had been made before the accident. Additional Details: here....
Articles appear in the Soviet newspapers explaining the risky nature of the Apollo 8 flight. Meanwhile an LLRV lunar landing trainer has crashed in America - Kamanin notes this is the second loss of an American 'lunar module'. The Apollo 8 flight has been delayed from 18 to 21 December due to engine problems.
Kamanin reviews the organisational structure of the NII-TsPK Gagarin Centre. There is a commander, three deputies, 700 staff, and 12 MiG-21's for flight training (8 single-seat combat aircraft and four two-seat trainers). There are three training tracks for the cosmonauts: Orbital, Lunar, and Military.
Final countdown for the launch of Apollo 8, the second manned Apollo mission, began on schedule at KSC. Significant launch preparation events included the "wet" countdown demonstration test on December 10, three days of flight simulations, an operational review, and launch site recovery exercises. Mission preparations were on schedule for launch on December 21. Launch preparations were also on schedule for the next two flights, Apollo 9 and 10.
Nikolayev, Leonov, Popovich, Bykovsky, Khrunov, Gorbatko, Zaikin, Volynov, and Shonin all receive their diplomas from the Zhukovskiy Test Pilot Engineering Academy. Khrunov graduates with honours. All of them began training for a lunar landing on January 8. Titov and Gagarin will complete their studies for the diploma in May. Ponomareva and Solovyova willl graduate in the second half of 1968, leaving only Tereshkova, Kuznetsova, and Yerkina. Tereshkova has had her appendix removed in surgery at the Vishevskiy Centre. The surgery went well.
In a four-hour meeting, a number of issues are dealt with. First point was military control of the KIK control centre for lunar missions. A civilian mission control centre is requested. Next, the issue of recovery of L1 and L3 capsules in the Indian Ocean. The re-entry corridor within which landings might occur is 6000 km long and 100 km wide, stretching from Antarctica to India. To cover it will require 20 naval vessels, each with a helicopter, and 10 An-22 or Tu-95 long-range maritime reconnaissance and relay aircraft. Total cost: 600 million roubles. As Kamanin sees it, all this is due to Mishin's inability to design spacecraft capable of precision landing that also incorporates the landing and recovery aids requested by the VVS. Kamanin notes in his diary violent criticism of Mishin's disregard for the safety of the cosmonaut crews, development of crew-associated items at the last minute, unrealistic schedules and expectations, etc. etc. Severin reports that the lunar space suit he is designing will support the cosmonaut for three days, during walks extending 5 km. To do this requires a bulky suit weighing 100 kg. Kamanin disagrees, saying what is needed is to develop a simple and safe approach for the first landing, with a minimum programme for the cosmonaut - not the fantastic schemes of Mishin.
All pass. Volynov, Shatalov, and Khrunov do best; Gorbatko and Shonin make mistakes (for example stating that the spacesuit pressure is 35 atmospheres instead of 3.5 atmospheres). Kuznetsov had planned for Gagarin to be cosmonaut commander, and Beregovoi has been poorly prepared for the job. But he still plans to make Beregovoi his deputy in the position. The other cosmonauts bitterly oppose this decision, and spread stories of Beregovoi's incompetence.
Over Brazil. Spacecraft engaged in practical applications and uses of space technology such as weather or communication (US Cat C). Positioned in geosynchronous orbit over the Atlantic Ocean at 24 deg W in 1969-1970. As of 3 September 2001 located at 96.04 deg E drifting at 9.557 deg W per day. As of 2007 Mar 9 located at 48.04W drifting at 9.553W degrees per day.
Apollo 8 (AS-503) was launched from KSC Launch Complex 39, Pad A, at 7:51 a.m. EST Dec. 21 on a Saturn V booster. The spacecraft crew was made up of Frank Borman, James A. Lovell, Jr., and William A. Anders. Apollo 8 was the first spacecraft to be launched by a Saturn V with a crew on board, and that crew became the first men to fly around the moon.
All launch and boost phases were normal and the spacecraft with the S-IVB stage was inserted into an earth-parking orbit of 190.6 by 183.2 kilometers above the earth. After post-insertion checkout of spacecraft systems, the S-IVB stage was reignited and burned 5 minutes 9 seconds to place the spacecraft and stage in a trajectory toward the moon - and the Apollo 8 crew became the first men to leave the earth's gravitational field.
The spacecraft separated from the S-IVB 3 hours 20 minutes after launch and made two separation maneuvers using the SM's reaction control system. Eleven hours after liftoff, the first midcourse correction increased velocity by 26.4 kilometers per hour. The coast phase was devoted to navigation sightings, two television transmissions, and system checks. The second midcourse correction, about 61 hours into the flight, changed velocity by 1.5 kilometers per hour.
The 4-minute 15-second lunar-orbit-insertion maneuver was made 69 hours after launch, placing the spacecraft in an initial lunar orbit of 310.6 by 111.2 kilometers from the moon's surface - later circularized to 112.4 by 110.6 kilometers. During the lunar coast phase the crew made numerous landing-site and landmark sightings, took lunar photos, and prepared for the later maneuver to enter the trajectory back to the earth.
On the fourth day, Christmas Eve, communications were interrupted as Apollo 8 passed behind the moon, and the astronauts became the first men to see the moon's far side. Later that day , during the evening hours in the United States, the crew read the first 10 verses of Genesis on television to earth and wished viewers "goodnight, good luck, a Merry Christmas and God bless all of you - all of you on the good earth."
Subsequently, TV Guide for May 10-16, 1969, claimed that one out of every four persons on earth - nearly 1 billion people in 64 countries - heard the astronauts' reading and greeting, either on radio or on TV; and delayed broadcasts that same day reached 30 additional countries.
On Christmas Day, while the spacecraft was completing its 10th revolution of the moon, the service propulsion system engine was fired for three minutes 24 seconds, increasing the velocity by 3,875 km per hr and propelling Apollo 8 back toward the earth, after 20 hours 11 minutes in lunar orbit. More television was sent to earth on the way back.
Apollo 8 has been launched. Kamanin recalls that he first saw a model of the Saturn V during his visit to Washington DC with Titov in 1962. At that time the Soviet Union planned to fly the N1 in four years, but the only manned spacecraft on the drawing boards after Voskhod was the Sever. Khrushchev didn't give a go-ahead for the lunar program until 1964. In the gap between Voskhod and Soyuz flights, when the American Gemini program seized the lead, the USSR could have achieved a record by flying Volynov for 18 days in Voskhod 3. But this was cancelled at the last minute by the leadership because the Voskhod had 'no development potential'. Ustinov, Smirnov, Pashkov were responsible for this decision, which put the USSR permanently behind in the space race.
ASPO Manager George M. Low apprised Program Director Samuel C. Phillips of MSC's plans for television cameras aboard remaining Apollo missions. With the exception of spacecraft 104 (scheduled for flight as Apollo 9), television cameras were to be flown in all CMs. Also, cameras would be included in all manned LMs (LM-3 through LM-14).
The Soyuz 4 and 5 crews arrive at Tyuratam aboard an An-24. They work with their spacesuits at Area 31 until 23:00. On the bus back to the sleeping quarters Kamanin tells them of Ustinov's 'recommendation' that they do an automatic docking. They are against it, argue for a manual docking. If allowing enough time for the crew of the active spacecraft to adapt to zero-G is the issue, they propose switching the launch order of the active and passive spacecraft. This alternative is ruled out - it is too late and risky to modify the flight programs. Shatalov bursts out - 'Here we are debating this for the tenth time, while he Americans are orbiting the moon'. They call for the bus to stop. They exit out into the icy clear night and look at the moon. Thoughts came of the nine comrades who had died trying to put the USSR first to the moon, all to no avail.
A 'small Soviet' of designers was held to review whether to continue pursuing the N1 launch vehicle or not. Although a first manned lunar landing was not achievable, the N1 could still be used to establish a lunar base by the beginning of the 21st Century. Additional Details: here....
The L3 spacecraft still does not even exist in mock-up form. All of the leadership are responsible for this farce - Malinovskiy, Smirnov, Ustinov, Brezhnev. There is no single manager of the space program. The VPK and Central Committee operate on rumours. The Interagency Soviet headed by Keldysh was supposed to coordinate space activities, but in fact has not functioned in the last four to five years. There is no single military space organisation in the Ministry of Defence. Piloted flight tests are being run by former artillery officers in the RSVN. Various organizations of MAP and VVS coordinate ground and flight tests poorly. These are the reasons for the failure of the Soviet Union in space. Today in the Central Committee Ustinov asked - 'how to answer Apollo 8?' Ustinov relies on Keldysh, Keldysh supports Mishin, and Mishin is unfit for his duties. But Mishin is not even there! The program they come up with: In January 1969, 2 Venera probes will be launched, two manned Soyuz missions, and L1 s/n 13 will be sent around the moon. In February the first N1 will be launched. By the end of March the first Ye-8 robot will land on the moon and return lunar soil to the earth. This meeting is followed by a session of the VPK at 16:00. The crews are named for the Soyuz 4 and 5 flights.
Apollo 8 is on its way back to earth, but re-entry into the earth's atmosphere from lunar distances is risky, as the Soviet experience with the L1 has shown. The State Commission meets at 16:00 and sets the launch dates for Soyuz 4 and 5. Meanwhile Beregovoi and Yurasov are in the Soyuz spacecraft in the assembly building, running communications checks.
The training for the Soyuz 4 and 5 flights was completed last night. Today the crews undergo medical tests and start preparation of their flight logs/flight plans. On the return flight to Moscow Shatalov, Beregovoi, Severin, Kamanin, and Mnatsakanian get into a heated argument. The cosmonauts attack Mnatsakanian's Igla automated docking system. It limits docking manoeuvres to periods when the spacecraft are flying over the Soviet Union due to the requirement for ground stations to receive live television. The Americans worked only on the Apollo spacecraft for the last two to three years, while the Soviets have divided their efforts on no less than five spacecraft types: the L1, L3, Soyuz, Soyuz VI, and Almaz. This is all Mishin's fault...
A State Commission investigating the crash of Zond 6 determined that the coronal discharge effect which caused the parachute to jettison would only occur at the 25 mm capsule pressure. If the capsule had been completely depressurised to a high vacuum, the accident would not have occurred. A discussion was conducted on when to conduct the next L1 test. The next capsule in line was s/n 13 - an unlucky omen. It was even proposed not to fly the capsule with such an unlucky number. That evening, the Soviet engineers could watch live video from the moon from aboard Apollo 8 via Eurovision from Western Europe. They had in any case lost the race to fly a man around the moon. The flight of further L1's, and sending a Soviet man on a lunar flyby, seemed a moot point.
The General Staff considers the impending Soyuz 4 and 5 flights. Vershinin asks - what is the likelihood of Apollo 8 being successful? Kamanin tells him it is very good now; the final midcourse correction was made successfully. A State Commission convenes to consider the Zond 6 failure. Mishin and Tyulin do not attend - they send Bushuyev to represent them. It has been found that 70 km from the cosmodrome, as the spacecraft deployed its parachute, the parachute lines were pyrotechnically severed at 3 km altitude and the capsule crashed into the plain. This in turn was found to be due to an ONA landing antenna failure; and this in turn caused by the SUS going down to temperatures of -5 deg C during the flight and the depressurisation of the cabin. The hydrogen peroxide, due to the low temperature, put the spcecraft at a 45 degree attitude instead of the 18 degree maximum (?). There are five L1's left. Number 13 is at Tyuratam begin prepared for an unmanned flight due for launch on 20 or 21 January, number 11 is being readied for a March 1969 manned launch, to be followed by numbers 14, 15, and 16 in April, May, June. At 19:15 the successful splashdown of Apollo 8 is reported. The race to be first around the moon is over.
On the sixth day, the crew prepared for reentry and the SM separated from the CM on schedule. Parachute deployment and other re-entry events were normal. The Apollo 8 CM splashed down in the Pacific, apex down, at 15:51 GMT - 147 hours and 42 seconds after liftoff. As planned, helicopters and aircraft hovered over the spacecraft and pararescue personnel were not deployed until local sunrise, 50 minutes after splashdown. The crew was picked up and reached the recovery ship U.S.S. Yorktown at 17:20 GMT. All mission objectives and detailed test objectives were achieved, as well as five that were not originally planned.
The crew was in excellent condition, and another major step toward the first lunar landing had been accomplished.
Two to three days rest for the demoralised cadres is declared, before renewing anew the assault on the cosmos in January. Kamanin muses that some day Communism will be on all of the planets of the solar system, and men will travel in fully automated spacecraft. But full automation is the wrong approach now.
Meeting of the VPK Military-Industrial Commission to discuss how to beat the Americans to the lunar landing Ustinov called the meeting to order. Mishin was 'sick' again -- Okhapkin represented TsKBEM and gave a summary of the programme to that date:
Keldysh proposed that further work on the L1 be abandoned, and Proton boosters instead be used to launch the Ye-8-5 lunar soil return robot spacecraft being developed by Babakin. Babakin had been accelerating this programme since the beginning of 1968 with the support of Keldysh, even though it would only return around 100 g of lunar soil, versus the tens of kilograms the Apollo manned flights would return. However it now offered an interesting possibility - he proposed obtaining lunar soil and returning it to earth before an American manned landing. The government's organs of mass communication would say that the Soviet Union's lunar program only consisted of robot probes, emphasising that his was much safer and that Russia would never risk it's citizen's lives for mere political sensation. Additional Details: here....
After two days of snow, family, and rest at this dacha, Kamanin is called to a General Staff meeting - the issue - how to answer the Americans? Attending are Generals Kutakhov, Moroz, Ponomarev, Kustanin, Yoffe, Frolov, Kartakhov, and others. It is agreed that the only proper answer is a Soviet lunar landing - but that is two to three years away. The 1964 resolution authorising the lunar program required a lunar flyby to be conducted by 1967 and a landing by 1968. But Ustinov, Serbin, Smirnov, and Pashkov hindered the attainment of this order. They were always requiring meetings, analyses, reports. The result - now many volumes of reports, but no action. The VPK proposes to land a Ye-8-5 robot on the moon and return lunar soil to earth in a 50 cm diameter, 38 kg capsule. The capsule will descend under a parachute and transmit on two VHF beacons in order to be located. But this still does not exist in metal, just in mock-up form. Considered logically, it could not be available earlier than the second half of 1969. The existing schedule for it to fly in the first half of the year is illogical and unachievable. Kamanin looks back with bitterness on the year of 1968 -- they have lost the moon race, they have lost Gagarin. His only consolation is his family.