Without the bulky seats, the usable volume of the LM cabin became much greater. Seats were not required because the LM’s mission was relatively brief (initially two days) and the astronauts were at zero gravity while flying or at Moon gravity (one-sixth Earth’s) while on the surface. Even LM rocket firings did not exceed one-third G.3 Some form of restraint would be required while in zero G, and Harms had sketched foot restraints anchored to the deck and a spring-loaded cable and pulley arrangement clipped onto a belt on the astronaut’s waist. Handholds and armrests adjacent to the hand controllers provided additional anchor points.
Best of all, the standing position moved the pilot’s eyes closer to the window, yielding the same viewing angles with much less glass area. We discussed various approaches to window geometry and agreed to start with a flat window that would provide the same view angles. Will Bischoff and Len Paulsrud joined the discussion and were asked to prepare structural design arrangements for the new crew compartment. Harms and Paulsrud constructed a full-sized foam-board mockup of the crew compartment to work out the combined structural design and crew provisions concepts.
The lunar module’s ascent stage. (Courtesy Northrop/Grumman Corporation) (Illustration credit 5.2)
I visited the rudimentary cabin mockup every day as the LM crew compartment that was ultimately built and flown took shape. Computer-aided studies of window geometry led us to tilt the plane of the windows downward and outward, resulting in a small, flat, triangular pair of windows that provided greater vision angles than the original large curved windows. To provide structural rigidity to the flat, pressurized front face of the crew compartment, a pair of deep external beams were added on either side of the forward hatch. A cylindrical protrusion into the cabin behind the flight station was required to accommodate the upper end of the ascent rocket engine, but there was volume behind and on either side of this obstruction for crew equipment, spacesuit and backpack stowage and for rest stations equipped with mesh hammocks. A small rectangular window was added overhead to aid the docking maneuver.
As soon as we shared the new concept with NASA it was enthusiastically received, and a visit from the LM liaison astronaut Donn Eisele further confirmed the acceptability of this approach. (In Chariots for Apollo, NASA historians C. G. Brooks, et al. credit NASA crew systems engineers George C. Franklin and Louie G. Richard with originating the idea of eliminating LM’s seats. My recollection is that the Grumman team started it, but in any event the NASA and Grumman crew systems teams worked so closely and cooperatively together that the credit is properly shared.) We released the design for the wooden M-1 mockup to be reviewed by NASA in September 1963. An important piece of the LM design puzzle had been put into place.
The lunar module’s crew compartment and flight station. (Courtesy Northrop/Grumman Corporation) (Illustration credit 5.3)
Mechanical Systems and Explosive Devices
Another design area that required both innovation and careful attention to details was mechanical systems, including the landing gear, docking mechanisms, hatches, equipment stowage compartments and miscellaneous mechanical devices, and explosive devices for stage separation and propulsion-system activation. This was the province of Virgilio “Jiggs” Sturiale, the Mechanical Design section head, and his deputy Marcello “Marcy” Romanelli. This talented pair had many years of experience designing, building, and testing the complex mechanisms required in Grumman’s carrier-based aircraft, especially the flight-control mechanisms (for ailerons, flaps, rudders, and elevators), retractable landing gear, wing-fold mechanisms, ejection seats, canopy releases, and tailhook extension and retraction devices. The challenges facing them on the LM were different but no more demanding than the many critical devices to which navy pilots entrusted their lives on every flight of a Grumman aircraft.
Our proposed fixed landing gear contained a major design innovation that, although greatly altered in specifics, carried through into the flight LMs. Concerned about the weight and potential for leakage of fluid into space from conventional hydraulic or pneumatic energy absorbers, I insisted on a dry version. In the proposal we thought it would be some form of molded elastic compound, but as the design evolved into an extendible four-legged landing gear a new energy absorbing material had to be developed to dissipate sufficient energy in a short stroke. Jiggs and Marcy searched for suitable materials and came up with crushable aluminum honeycomb. Hexcell had developed aluminum honeycomb as a lightweight, rigid, high-strength filler material for aircraft control surfaces, particularly the trailing edges, which typically taper down to end in a point. Hexcell was exploring new uses for its material and believed that it could be configured as a highly efficient energy absorber for the LM landing gear. Marcy designed some test struts for which Hexcell fabricated cylindrical slugs of crushable honeycomb. The initial test results were very promising: they indicated that the amount of energy that could be absorbed by a three- to four-inch diameter honeycomb cylinder with a crushable stroke of twenty-four to thirty-six inches was in the range required by the LM’s landing conditions. I asked Jiggs to proceed with the landing-gear design using this approach, and we authorized Hexcell to conduct a development program to characterize and optimize crushable honeycomb for energy absorption.
The landing gear Jiggs and Marcy designed was as simple as possible, given the design constraints. It was spring-loaded extensible, released by explosively actuated strap cutters (uplocks), and locked into place by redundant mechanical downlocks on each landing-gear strut assembly. There was no requirement to retract the gear once extended. In the final design the main compression strut on each of the four legs had a stroke of thirty-two inches and the footpad was thirty-seven inches in diameter, a compromise value given the unknowns of the lunar surface that we felt would ensure minimal penetration of the LM into a low load-bearing strength surface.
There were conflicting opinions from the experts regarding the nature of the lunar surface even as LM was being designed. Radar echoes from the Moon hinted at a possible porous surface, which Thomas Gold, respected astrophysicist at Cornell University, interpreted as indicating the possibility that most of the surface was covered with deep, fine dust. Both visual and radar observations, however, showed many areas of boulders and exposed outcroppings of solid rock. This gave us a wide range of potential landing conditions, so we sought a design that would accommodate them all.
The lunar module’s descent stage. (Courtesy Northrop/Grumman Corporation) (Illustration credit 5.4)
To establish the most basic geometry of the landing gear, namely, its tread (distance between opposite footpads) and its height (distance from the surface to the bottom of the descent stage), required a complex systems engineering study. From analyses and ground-based flight simulations, the Flight Controls Group determined the expected tolerances in touchdown velocity that could be expected. These tolerances were expressed statistically as the probability of not exceeding a given value, based upon hundreds of computer and manned simulation runs. After examining the statistics and consulting with NASA and the astronauts, we recommended and NASA accepted the following touchdown parameter limits to be used in LM design: (1) ten feet per second vertical velocity with zero horizontal velocity, (2) seven feet per second vertical velocity with four feet per second horizontal velocity, and (3) vehicle attitude within six degrees of local horizontal.
These touchdown parameters had to be applied to a set of design assumptions about the lunar surface. Here I relied upon NASA, whose experts had been studying what was known about potential landing sites. We arrived at the following lunar surface characteristics for design: (1) six-degree maximum general slope, (2) twenty-four-inch depressions and protuberances, and (3) surface friction coefficients between ice and rock.
Our Structural Analysis Section under Dick Hilderman, working closely with the Structural and Mechanical Design Sections, worked out a multi-variable matrix of analyses, starting with different assumed LM spacecraft and landing-gear geometries and cover
ing the full range of touchdown velocities and lunar surface conditions. Many thousands of computer runs were required in this iterative, trial-and-error process to find the bounds of acceptable vehicle and landing-gear geometry for landing. The analyses extended over many months and were still being updated and refined well into 1966. By August 1963, though, we were able to freeze the geometry for the M-1 mockup, and the subsequent dimensional changes to the landing gear did not exceed a few inches.
As we explored the analyses, certain combinations of variables came to be recognized as critical, and we could save time by testing new geometries against these critical conditions first. For example, the critical condition for LM tipover resulted from landing at maximum horizontal velocity (four feet per second) downhill on a six-degree surface slope with the LM attitude pitched downhill at six degrees. The initial surface contacted was ice, but at maximum downhill sliding velocity the footpads hit a solid rock curb. The critical condition for energy absorption and ground clearance occurred when the LM touched down at maximum vertical velocity (ten feet per second) with all four footpads landing in twenty-four-inch-deep craters and twenty-four-inch boulders scattered on level ground underneath the descent stage.
Our designers responded good-naturedly to the outrageous combinations of landing design conditions dreamed up by the structural analysts. They took it as a challenge to overcome seemingly impossible landing requirements, if possible with margin to spare. Occasionally I would intervene, deciding that the likelihood of certain combinations appeared so slight that they should be moderated to avoid unduly penalizing the design. The end result, a lunar module twenty-three feet high and thirty-one feet in diameter across the landing gear, represented a cautious approach to the information available at the time. In hindsight, our landing-gear design proved to be extremely conservative. In the actual missions the astronauts skillfully set the LM down “like a crate of eggs” at touchdown velocities of four feet per second or less. The energy absorbing struts were never stroked more than six inches, and the lunar surface conditions were generally more benign than assumed.
The docking mechanism to connect LM to the CM was an interesting engineering problem. It had to be simple, strong, and absolutely reliable because a jam-up would force the astronauts to the more risky option of transferring from one vehicle to another by EVA. Our proposal design used a double-ended cylindrical docking module that could be mated to the docking rings on the CM and either the upper or the forward hatches on the LM. The idea was to provide docking hatch redundancy on the LM side of the connection.
By mid-1963 North American had begun working on an internal probe-and-drogue docking concept, designed to be assembled and disassembled inside the tunnel between the two spacecraft by the crew.4 The tunnel in each spacecraft was a thirty-two-inch diameter aluminum alloy cylinder about eighteen inches long located directly above (outside of) the hatches, with machined docking rings on the outer end of each tunnel. The probe mounted in the CM tunnel was driven home into the conical drogue in the LM tunnel and secured by spring-loaded latches. Both the mechanism and the docking maneuver were similar to the air force’s probe-and-drogue aerial refueling and very familiar to military pilots. This was a major argument in favor of the probe-and-drogue approach, and Grumman’s double-ended docking module was discarded.
After the probe was engaged and latched in the drogue it was retracted, drawing the docking rings on the LM and the CM together and triggering a dozen spring-loaded capture latches, mounted on the CM side, around the circumference of the docking rings to form a rigid structural and pressure tight connection. The drogue was held in place by three mounting lugs in the LM tunnel. It was set into position and later removed by the CM pilot, who also installed the collapsible probe assembly onto mounting lugs in the CM tunnel.
Grumman’s Mechanical Design Section worked closely with NASA’s astronauts and engineers and with North American to assure that all structural, mechanical, and functional aspects of the hatches, tunnels, docking rings, and mechanisms were coordinated and specified between the two spacecraft. Key physical and functional interfaces between LM and CM were controlled by interface control documents (ICDs), which were prepared and approved by both spacecraft contractors and approved and maintained by NASA. An extensive ground-test program was conducted jointly by Grumman and North American and flight demonstrations of rendezvous and docking took place on Apollo 9 in Earth orbit and Apollo 10 in Lunar orbit. This painstaking attention to detail paid off: the docking system functioned properly on every Apollo mission to the Moon, despite Mike Collins’ fears on Apollo 11 that the mechanisms would become jammed in the tunnel and spoil the mission.5
Mechanical Design was also responsible for designing a safety critical array of components known as the explosive devices subsystem. They fell into two categories: detonator cartridges, containing explosive charges of high yield, and pressure cartridges, containing propellant charges of relatively low yield. The former were components required to effect ascent/descent-stage separation during launch from the Moon’s surface: explosive nuts and bolts that secured the stages together, and the umbilical cutter and circuit interrupter that severed and inerted the interstage umbilical wire and tubing bundle. The landing-gear uplock that held the landing gear in its retracted (stowed) position until fired to deploy the gear was also in this category. In the pressure category were normally closed, explosively opened valves used to release helium from storage tanks into the RCS, ascent, and descent propulsion systems. By containing the helium in its storage tanks and leaving the propellant tanks unpressurized until shortly before these systems were required to function during the mission, the risk of leaking precious propellant or pressurant into space was reduced.
These devices could not be tested before use except for a low-voltage test of the igniter to assure that electrical continuity existed. Therefore their reliability depended upon redundancy in design (dual igniters, explosive charges, nuts and bolts both shattered, dual cutter blades, and so on), rigid process control during manufacture, and statistical sample test firings of components from each production lot. Any test failure caused rejection of the entire lot and an investigation of manufacturing steps to find the cause. Careful attention was paid to grounding and shielding to protect against premature un-commanded firing caused by stray currents or electromagnetic fields. Given the life or death importance of these devices, Sturiale and Romanelli were always among the most nervous Grumman engineers when supporting a flight mission, their worried expressions giving way to grins only after the capture latches clamped home to complete the ascent-stage docking to CM in lunar orbit, the last of the explosive devices having fired upon ascent-stage liftoff. As with their mechanical devices, they achieved a perfect record of explosive device performance on the Apollo missions.
Making LM Reliable
The issue of reliability, so clearly exemplified by the explosive devices subsystem, demanded much of my attention during the formative design period of 1963–64. Foremost in clarifying reliability requirements and expressing them in practical design policies and guidelines were Arnold Whitaker, assistant project engineer-Systems, Erick Stern, manager of Systems Analysis and Integration, and George Wiesinger, manager-LM Reliability Group.
NASA had posed a very broad requirement for reliability: each Apollo mission must provide .999 probability of crew safety (one in one thousand chance of fatality) and .99 probability of mission success (one in one hundred chance of aborting the mission). These overall probabilities had been apportioned by NASA to the individual elements making up the total mission, including the LM. We in turn had apportioned our total unreliability allowance (=1 — p) among each of the LM systems and subsystems, resulting in allowable failure probabilities of one in ten thousand or less for each system.
From a designer’s point of view these probabilities were not much help. In practical terms they could not be demonstrated because the allowable failure rates were so low that to prove them would require hun
dreds or even thousands of repetitive tests. Analyses, however, could be used to show relative failure rates of alternative system designs. The absolute value of such analyses was always suspect, but they would indicate the extent to which component redundancy or other system configuration changes would improve overall system reliability.
Reviewing the results of many systems analyses and tradeoff studies, I decided there were a few practical guidelines that we should follow to achieve the highest possible reliability for LM:
1. Specify the highest quality systems and components the current state of the art could achieve.
2. Provide system-level redundancy wherever possible, preferably by dissimilar means.
Examples of dissimilar redundancy: Lunar-orbit rendezvous, primary method, LM active with rendezvous radar; secondary method, CM active visually sighting LM or its tracking light through telescope; tertiary method, ground-based radar tracking of both LM and CM. Another example: Earth/LM communications, primary method, S-band steer able antenna on LM; secondary method, S-band omni and UHF omni antennae on LM, relay through steer able antenna on CM; tertiary method, LM omni antennae directly to Earth.
Examples of similar system-level redundancy: reaction control system, fully redundant A and B systems, each capable of maintaining flight control of LM; electrical power system, fully redundant A and B systems, each capable of providing power to all electrical loads, up to half the total ampere-hours of the combined systems. An additional partially redundant bus served essential loads only, and a completely separate redundant system and batteries powered the explosive devices system.
3. Provide component-level redundancy at the highest component level possible.
Component-level redundancy was provided in most systems, even those for which total system redundancy was impossible due to weight or functionality restrictions. For example, the ascent and descent propulsion systems had redundant valves, regulators, and pressurant lines, even though major components, such as rocket engines and propellant tanks, could not be duplicated. Extensive component-level redundancy existed in the environmental control system, although the cabin pressure shell structure and the spacesuit could not be duplicated.
Moon Lander: How We Developed the Apollo Lunar Module (Smithsonian History of Aviation and Spaceflight) Page 10