Pioneer P-3
File:Able IV World's First Space Engine.jpg
Able IV, The World's first space engine[clarification needed]
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Mission type | Lunar orbiter |
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Operator | NASA |
Mission duration | Failed to orbit |
Spacecraft properties | |
Launch mass | 168.70 kilograms (371.9 lb) |
Start of mission | |
Launch date | 26 November 1959, 07:26:00 | UTC
Rocket | Atlas D Able |
Launch site | Cape Canaveral LC-14 |
Pioneer P-3 (also known as Atlas-Able 4 or Pioneer X) was intended to be a lunar orbiter probe, but the mission failed shortly after launch. The objectives were to place a highly instrumented probe in lunar orbit, to investigate the environment between the Earth and Moon, and to develop technology for controlling and maneuvering spacecraft from Earth. It was equipped to take images of the lunar surface with a television-like system, estimate the Moon's mass and topography of the poles, record the distribution and velocity of micrometeorites, and study radiation, magnetic fields, and low frequency electromagnetic waves in space. A mid-course propulsion system and injection rocket would have been the first United States self-contained propulsion system capable of operation many months after launch at great distances from Earth and the first U.S. tests of maneuvering a satellite in space.
Mission
The probe was originally intended for launch on Atlas 9C in October, but the launch vehicle was destroyed in a static firing accident on September 24, so it was decided to use the Atlas D (operational version of the Atlas ICBM) rather than the Atlas C, which was still a test model. Launch took place on Thanksgiving, November 26, 1959 from LC-14 at Cape Canaveral Air Station using Atlas vehicle 20D, which had originally been the backup booster for the Mercury Big Joe test in September. Since that flight was successful, Atlas 20D was reused for the Able program, coupled to Thor-Able upper stages including an Able x 248 rocket third stage. All proceeded normally until T+45 seconds when a shock was recorded by the Atlas's rate gyros followed by the fiberglass payload fairing breaking off of the launch vehicle. The third stage and payload were stripped away after being subjected to severe aerodynamic loads while passing Max Q and the second stage sustained damage followed by loss of its telemetry at T+104 seconds. The Atlas itself was unaffected by the incident and completed its burn on schedule. The failure was traced to an improperly vented payload shroud that broke apart when the air pressure inside started exceeding the external pressure as the atmosphere thinned with altitude. In addition to changing prelaunch procedures, the shroud was redesigned to be more aerodynamic on future flights.
Spacecraft design
Pioneer P-3 was a 1 meter diameter sphere with a propulsion system mounted on the bottom giving a total length of 1.4 meters. The mass of the structure and aluminum alloy shell was 25.3 kg and the propulsion units 88.4 kg. Four solar panels, each 60 x 60 cm and containing 2200 solar cells in 22 100-cell nodules, extended from the sides of the spherical shell in a "paddle-wheel" configuration with a total span of about 2.7 meters. The solar panels charged chemical batteries. Inside the shell, a large spherical hydrazine tank made up most of the volume, topped by two smaller spherical nitrogen tanks and a 90 N injection rocket to slow the spacecraft down to go into lunar orbit, which was designed to be capable of firing twice during the mission. Attached to the bottom of the sphere was a 90 N vernier rocket for mid-course propulsion and lunar orbit maneuvers which could be fired four times. This space engine was designed and built under contract with NASA by the Space Technology Laboratories (STL) of TRW.
Around the upper hemisphere of the hydrazine tank was a ring-shaped instrument platform which held the batteries in two packs, two 5 W UHF transmitters and diplexers, logic modules for scientific instruments, two command receivers, decoders, a buffer/amplifier, three converters, a telebit, a command box, and most of the scientific instruments. Two dipole UHF antennas protruded from the top of the sphere on either side of the injection rocket nozzle. Two dipole UHF antennas and a long VLF antenna protruded from the bottom of the sphere.
Thermal control was planned to be achieved by a large number of small "propeller blade" devices on the surface of the sphere. The blades themselves were made of reflective material and consist of four vanes which were flush against the surface, covering a black heat-absorbing pattern painted on the sphere. A thermally sensitive coil was attached to the blades in such a way that low temperatures within the satellite would cause the coil to contract and rotate the blades and expose the heat absorbing surface, and high temperatures would cause the blades to cover the black patterns. Square heat-sink units were also mounted on the surface of the sphere to help dissipate heat from the interior.
On-board equipment
The scientific instruments consisted of an ion chamber and Geiger-Müller tube to measure total radiation flux, a proportional radiation counter telescope to measure high energy radiation, a scintillation counter to monitor low-energy radiation, a VLF receiver for natural radio waves, a transponder to study electron density, and part of the television facsimile system and flux-gate and search coil magnetometers mounted on the instrument platform. The television camera pointed through a small hole in the sphere between two of the solar panel mounts. The micrometeorite detector was mounted on the sphere as well. The total mass of the science package including electronics and power supply was 55 kg.