The size and payload capacity of the Saturn V dwarfed those of all other previous rockets successfully flown at that time. With the
Apollo spacecraft on top, the Saturn V stood tall, and, ignoring the fins, had a diameter of at its base. Fully fueled, the Saturn V had a mass of , with a low Earth orbit (LEO) payload capacity of about , and could send about to the Moon. The Saturn V was primarily designed by the
Marshall Space Flight Center in Huntsville, Alabama. The rocket used the powerful
F-1 and
J-2 rocket engines. When all five F-1 engines of the first stage were tested together at the
Stennis Space Center, their low-frequency roar shattered the plate-glass window of a bank building in
Picayune, 15 miles away. Designers decided early on to attempt to use as much technology from the
Saturn I program as possible for the Saturn V. Consequently, the S-IVB third stage of the Saturn V was based on the
S-IVB second stage of the Saturn I. The Saturn V was primarily constructed of
aluminum,
titanium,
polyurethane,
cork and
asbestos. Blueprints and other plans of the rocket are available on
microfilm at the Marshall Space Flight Center. The Saturn V consisted of three stages—the S-IC first stage, S-II second stage, S-IVB third stage, and the
instrument unit. All three stages used
liquid oxygen (LOX) as the
oxidizer. The first stage used
RP-1 for fuel, while the second and third stages used
liquid hydrogen (LH2). LH2 has a higher
specific energy (energy per unit mass) than RP-1, which makes it more suitable for higher-energy orbits, such as the
trans-lunar injection required for Apollo missions. Conversely, RP-1 offers higher
energy density (energy per unit volume) and higher thrust than LH2, which makes it more suitable for reducing aerodynamic drag and gravity losses in the early stages of launch. If the first stage had used LH2, the volume required would have been greater, which would have been aerodynamically infeasible at the time. The second and third stages also used small solid-propellant
ullage motors that helped to separate the stages during the launch to ensure proper positioning of the liquid propellants for pump intake.
S-IC first stage Saturn V being erected in the
VAB on February 1, 1968 The S-IC was built by the Boeing Company at the
Michoud Assembly Facility, New Orleans, and the
Mississippi Test Facility (now known as the Stennis Space Center),
Hancock County, Mississippi. Most of its launch mass was propellant: RP-1 fuel with liquid oxygen as the oxidizer. The stage was tall and in diameter. It provided of thrust at sea level. The S-IC had a dry mass of about . When fully fueled at launch, it had a total mass of . The S-IC was powered by five
Rocketdyne F-1 engines arrayed in a
quincunx. The center engine was fixed, while the four outer engines were
hydraulically turned with
gimbals to steer the rocket. The S-IC had a burn time of approximately 150 seconds.
Structure The S-IC structure design reflects the requirements of the F-1 engines,
propellants, control,
instrumentation, and interfacing systems. The stage is primarily built of
aluminum alloy, specifically
7075 and
2219 aluminum alloys. The major components are the forward skirt, oxidizer tank, intertank section, fuel tank, and thrust structure. The
aft end of the forward skirt is attached to the oxidizer (liquid oxygen) tank and the forward end interfaces with the
S-II. The skin panels, fabricated from 7075 aluminum, are stiffened and strengthened by ring frames and stringers. The liquid oxygen tank is the structural link between the forward skirt and the intertank section. Ring baffles attached to the skin stiffeners stabilize the tank wall and serve to reduce liquid oxygen sloshing. The tank is made of 2219 aluminum alloy and is a cylinder with
ellipsoidal upper and lower
bulkheads. The skin thickness is tapered in eight steps from at the aft section to at the forward section. The intertank structure helps provide structural continuity between the liquid oxygen and fuel tanks. The skin panels and ring frames are fabricated from 7075 aluminum. The fuel tank provides the structural link between the thrust and intertank structures. It is
cylindrical with ellipsoidal upper and lower bulkheads. Anti-slosh ring baffles are located on the inside wall of the tank and anti-
vortex cruciform baffles are located in the lower bulkhead area. Five liquid oxygen ducts run from the liquid oxygen tank, through the RP-1 tank, and terminate at the F-1 engines. The 2219 aluminum skin thickness is decreased in four steps from at the aft section to at the forward section. The thrust structure assembly redistributes the loads of the five F-1 engines to the periphery of the fuel tank. It also provides support for the engine accessories, base
heat shield, engine
fairings and
fins, propellant lines,
retrorockets, and environmental control ducts. The lower thrust ring has four holddown points, which support the fully loaded rocket and, as necessary, restrain the vehicle from lifting off at full F-1 engine thrust. The skin segments are fabricated from 7075 aluminum alloy.
Electrical and instrumentation systems The electrical power system of the S-IC is divided into three basic subsystems: an operational power subsystem, a measurement power subsystem, and a visual instrumentation power subsystem. On-board power is supplied by five 28-volt batteries, one each for the operational and measurement power systems. The operational power system battery supplies power to operational loads such as
valve controls, purge and venting systems,
pressurization systems, sequencing systems, and flight control. The measurement power system battery supplies power to measurement loads such as
telemetry systems,
transducers,
multiplexers, and
transmitters. Both batteries supply power to their loads through a common
main power distributor, but each system is completely
isolated from the others. In the visual instrumentation system, two batteries provide power for the liquid-oxygen tank strobe lights, while a third battery energizes the control circuits, camera motors, and thrusters of the film-camera portion of the visual instrumentation system. The instrumentation system monitors functional operations of stage systems and provides signals for vehicle tracking during the S-IC
burn. Prior to liftoff, measurements were telemetered by
coaxial cable to ground support equipment. During flight, data is transmitted to ground stations over
radio frequency (RF) links. The offset Doppler (ODOP) system uses the
Doppler principle to provide vehicle position and acceleration data during flight.
S-II second stage |left The S-II was built by
North American Aviation at Seal Beach, California. Using liquid hydrogen and liquid oxygen, it had five Rocketdyne J-2 engines arranged similarly to the S-IC, and also used the four outer engines for control. The S-II was tall with a diameter of , identical to the S-IC. The S-II had a dry mass of about ; when fully fueled, it weighed . The second stage accelerated the Saturn V through the upper atmosphere with of thrust in a vacuum. The S-II had a burn time of 395 seconds. When loaded with fuel, more than 90 percent of the mass of the stage was propellant.
Structure The S-II consisted of a body shell structure (forward and aft skirts and interstage), a propellant tank structure (liquid hydrogen and liquid oxygen tanks), and a thrust structure. The three are of the same basic design except that the aft skirt and interstage were generally of heavier construction because of higher structural loads placed on them. Each unit is a cylindrical shell of
semi-monocoque construction, built of 7075 aluminum alloy material, stiffened by external hat-section stringers and stabilized internally by circumferential ring frames. The forward skirt has a basic skin thickness of , while the aft skirt and interstage both have basic skin thicknesses of . The thrust structure, like the body shell structure, is of semi-monocoque construction but in the form of a
truncated cone increasing in size from approximately to in diameter. It is stiffened by circumferential ring frames and hat-section stringers like the body shell structure. Four pairs of thrust
longerons (two at each outboard engine location) and a center engine support beam distribute the thrust loads of the J-2 engines. The shell structure is of 7075 aluminum alloy. A fiberglass honeycomb heat shield, supported from the lower portion of the thrust structure, protects the stage base area from excessive temperatures. The liquid hydrogen tank consists of a long cylinder with a
concave modified ellipsoidal bulkhead forward and a convex modified ellipsoidal bulkhead aft. The aft bulkhead is also used by the liquid oxygen tank. The liquid hydrogen tank wall is composed of six cylindrical sections. Wall sections and bulkheads are all fabricated from
2014 aluminum alloy and are joined together by
fusion welding. The forward bulkhead has an diameter wide access
manhole built into its center. The common bulkhead is an adhesive-bonded sandwich assembly employing facing sheets of 2014 aluminum alloy and
fiberglass/
phenolic honeycomb core to prevent heat transfer and retain the
cryogenic properties of the two fluids to which it was exposed. The liquid oxygen tank consists of ellipsoidal fore and aft halves. The tank is fitted with three ring-type slosh baffles to control propellant sloshing and minimize surface disturbances and cruciform baffles to prevent the generation of vortices at the tank outlet ducts and to minimize residuals. A six-port sump assembly located at the lowest point of the tank provides a fill and drain opening and openings for five engine feed lines.
Electrical and instrumentation systems The S-II electrical system consists of the electrical power and electrical control subsystems. The electrical power system provides the stage with the electrical power source and distribution. The electrical power system consists of six
DC bus systems and a ground supplied
AC bus system. In flight, the electrical power system busses are energized by four
zinc-silver oxide batteries. The electrical control system interfaces with the instrument unit (IU) to accomplish the mission requirements of the stage. The
Launch Vehicle Digital Computer (LVDC) in the IU controls in-flight sequencing of stage functions through the stage switch selector. The stage switch selector can provide up to 112 individual outputs in response to the appropriate commands. These outputs are routed through the stage electrical sequence controller or the separation controller to accomplish the directed operation. The S-II instrumentation system consists of both operational and
R&D measurement and telemetry systems. The measurement system monitors and measures conditions on the stage while the telemetry system transmits this information to ground stations. The measurement system consists of transducers,
signal conditioners, and distribution equipment necessary to provide the required measurement ranges and to present suitably scaled signals to the telemetry system. The measurement system monitors numerous stage conditions and characteristics. This data is processed and conditioned into a form acceptable to the telemetry systems. The telemetry system accepts the signals produced by the measuring portion of the instrumentation system and transmits them to the ground stations. Telemetry equipment includes signal multiplexers,
subcarrier oscillators,
amplifiers, modulators, transmitters,
RF power amplifiers, RF multiplexers and an omni-directional system of four
antennas.
S-IVB third stage The S-IVB stage was built by
Douglas Aircraft Company at Huntington Beach, California. It had one Rocketdyne J-2 engine and used liquid hydrogen and liquid oxygen. The S-IVB used a common bulkhead to separate the two tanks. It was tall with a diameter of and was also designed with high mass efficiency, though not quite as aggressively as the S-II. The S-IVB had a dry mass of about and, when fully fueled, weighed about . The S-IVB had a burn time of 165 seconds the first burn, and 312 seconds for the second burn. Its single J-2 engine produced of thrust.
Structure The S-IVB consists of the following structural assemblies: the forward skirt, propellant tanks, aft skirt, thrust structure, and aft interstage. These assemblies, with the exception of the
propellant tanks, are all of a skin/
stringer type aluminum alloy
airframe construction. In addition, there are two longitudinal tunnels which house wiring, pressurization lines, and propellant dispersion systems. The tunnel covers are made of aluminum stiffened by
internal ribs. The forward skirt, cylindrical in shape, extends forward from the intersection of the liquid hydrogen tank sidewall and the forward dome, providing a hard attach point for the instrument unit (IU). It is the
load supporting member between the liquid hydrogen tank and the IU. An access door in the IU allows servicing of the equipment in the forward skirt. The thrust structure assembly is an inverted, truncated cone attached at its large end to the
aft dome of the liquid oxygen tank and attached at its small end to the engine mount. It provides the attach point for the J-2 engine and distributes the engine thrust over the entire tank circumference. Attached externally to the thrust structure are the engine piping, wiring and interface panels, eight ambient helium spheres,
hydraulic system, oxygen/hydrogen burner, and some of the engine and liquid oxygen tank instrumentation. The propellant tank is cylindrical with a hemispherical dome at each end, and a common bulkhead to separate the liquid oxygen from the liquid hydrogen. This bulkhead is of sandwich type construction consisting of two parallel hemispherical shaped 2014 aluminum alloy domes bonded to and separated by a fiberglass-phenolic honeycomb core. The internal surface of the liquid hydrogen tank is machine-
milled in a waffle pattern to obtain required tank stiffness with minimum structural weight. Attached to the inside of the liquid hydrogen tank are: a propellant utilization probe, nine cold
helium spheres, brackets with temperature and level sensors, a chill-down pump, a
slosh baffle, a slosh deflector, and fill, pressurization and vent pipes. Attached to the inside of the liquid oxygen tank are slosh baffles, a chill-down pump, a propellant utilization probe, temperature and level sensors, and fill, pressurization, and vent pipes. Attached externally to the propellant tank are helium pipes, propellant dispersion components, and wiring which passes through two tunnel fairings.
Electrical and instrumentation systems The electrical system of the S-IVB consists of two major subsystems: the electrical power subsystem which consists of all power sources on the stage; and the electrical control subsystem which distributes power and control signals to various loads throughout the stage. On-board power is supplied by four zinc/silver-oxide batteries. Two are located in the forward equipment area and two in the aft equipment area. These batteries are activated during the final pre-launch preparations. Heaters and instrumentation probes are an integral part of each battery. The electrical control subsystem function is to distribute the command signals required to control the electrical components of the stage. The major components of the electrical control subsystem are the power and control distributors, the sequencer assemblies, and the pressure sensing and control devices. The S-IVB instrumentation monitors functional operations of stage systems. Before liftoff, measurements are telemetered by coaxial cable to ground support equipment. During flight, radio frequency antennae convey data to ground stations, similar to the other two stages. The telemetry system consists of a
pulse-code-modulator (PCM) digital
data acquisition system (DDAS) for pre-launch checkout. The stage also contains a PCM frequency modulated (PCM/
FM) system, a FM/FM system, and a
single sideband (SS/FM) system for launch information. The radio frequency (RF) subsystem consists of a PCM-RF assembly, bi-directional coupler,
RF detectors,
DC amplifiers, coaxial switch,
dummy load, RF
power divider, and associated cabling. Omnidirectional antenna pattern coverage is provided by the folded-sleeve
dipoles. The
effective radiating power of the system is 20
watts nominal and 16 watts minimum.
Instrument unit for the
Apollo 4 Saturn V|left The Instrument Unit (IU) is a cylindrical structure installed on top of the S-IVB. The IU contains the guidance, navigation, and control equipment. In addition, it contains telemetry, communications, tracking, and crew safety systems, along with their supporting electrical power and environmental control systems. Developed from the
Saturn I IU, the Saturn V's IU was designed by the Marshall Space Flight Center and built by
IBM at their Huntsville, Alabama facility. The basic IU structure is a short cylinder fabricated of an aluminum alloy honeycomb sandwich material. The structure is fabricated from three honeycomb sandwich segments of equal length. The top and bottom edges are made from extruded aluminum channels bonded to the
honeycomb sandwich. This type of construction was selected for its high strength-to-weight ratio,
acoustical insulation, and thermal conductivity properties. The cylinder is manufactured in three 120-degree segments, which are joined by splice plates into an integral structure. The access door segment has an umbilical door, as well as an equipment/personnel access door. The access door has the requirement to carry flight loads and still be removable at any time prior to flight. The IU has a diameter of , a height of , and a weight of around . == Assembly ==