THE P6M Seamaster, a swept wing seaplane powered at near-supersonic speeds by four jet engines, has been assigned a leading role in antisubmarine warfare even before it has completed flight tests. Forthcoming production models of this 600-mile-per-hour mine laying seaplane will be used to strike at enemy submarines in their home ports in the event of any big war. Refueling from submarines or other small units en route, the long-range seaplane could deliver mines or nuclear weapons against any target within range. This includes any target that lies within 2000 or more miles from the Seamaster tenders or advance bases.
In its last major aircraft design, Martin returned to an earlier concept of the flying boat as a bomber. By the end of the 1940's the Soviet Union had tested a nuclear bomb, and the Cold War was in full swing. The newly created Air Force was busy buying and deploying long-range bombers to deliver nuclear weapons, a monopoly viewed by the Navy as unacceptable. Noting the inherent limitations of its force of short-range carrier attack and maritime patrol aircraft, the Navy looked at several means of joining the Air Force as in strategic deterrent. A super-carrier (the United States) was designed to handle larger propeller and jet aircraft then under design. The United States ran afoul of military budget limitations and vehement opposition from the Air Force "bomber lobby." The Navy Bureau of Aeronautics then developed the concept of a "Seaplane Striking Force" centered around the development of large jet-powered seaplanes that could offer performance equal to that of land-based jets. Capable of operating from most of the earth's surface, a small number of these seaplanes could perform mining, conventional and nuclear strike, and photo reconnaissance missions that would complement those of the new Strategic Air
With only a tender or submarine needed for re-arming and re-fueling, the SSF promised an economical means of force projection.
Requests to industry were let in April 1951. After a short but fierce design competition with Convair, Martin was awarded contracts for two prototype XP6M-1's, six pre-production service-test YP6M-1's, and up to 24 production P6M-2's. Martin named the SSF aircraft the SeaMaster. The Navy was now in the bomber business.
Design specifications for the SeaMaster were demanding. Required to carry
30,000 pounds of payload to a target 1,500 miles away, the plane was also
required to be capable of a high-speed dash at .9 Mach at low altitude.
Its hull had to be stressed for open-ocean operations. Design Engineer
George Trimble, hydrodynamicist J.D. Pierson, and aerodynamicist J.L.
Decker led the design team. Refining work already done on the Marlin's
hull design, they adopted a new length-to-beam ratio of 15 to 1 as most
efficient in both air and water. The XP5M-1 airframe was rebuilt to test
the new hull, redesignated Martin Model 270. Hydroflaps like those on the
Marlin were fitted for dual use as air brakes.
A compound turbo/ramjet from Curtiss-Wright was initially designated as the SeaMaster powerplant. After several failures in testing, this engine was dropped in favor of modified Allison J71's, mounted in tandem overwing nacelles. The P6M had the same variable-incidence "flying" T-tail and spoiler ailerons as the XB-51, and its payload was carried in a rotating bomb-bay, pneumatically sealed to be watertight. Swept wings with slight anhedral drooped close enough to the water for wingtip tanks to serve as stabilizing floats, without the drag of struts. The overall result was an airplane with proportions so sleek and simple that they could be described as classic.
The first prototype was rolled out in secrecy on December 21, 1954, and
after several months of load-verification tests the XP6M-1 finally took to
the air on July 14, 1955, flown by Martin chief test pilot George Rodney.
Initial tests revealed only one major problem that required a "fix": the
design of the nacelles allowed the afterburner exhaust to scorch and
sonically fatigue the rear fuselage. After keeping the plane's development
secret, the Navy invited the press for the roll-out in November of the
second prototype, which was outfitted with a complete set of navigation
and bombing equipment.
All went well with the testing program until December 7, 1955 (two days after the death of Glenn L. Martin), when the first XP6M-1 prototype crashed into the Chesapeake Bay during a routine check ride for the first Navy pilot. All four members of the crew were lost. With no onboard data recorders to help, the accident-investigation team was unable to find a specific fault. Months were lost re-configuring the second prototype with test instrumentation and ejection seats for all the crew. It was not until May, 1956, that flight testing resumed with Ship #2.
By autumn, solutions were being sought for a frequent airframe buzz that plagued both prototypes. One "fix" involved locking the elevators together with the variable-incidence "flying tail." A test flight on November 9 verified that improvement in the vibration, however, in recovering from a shallow dive at high speed, pilot Bob Turner lost pitch control of the aircraft, which started a violent outside loop. The crew ejected safely as the airframe broke up. Information from the flight data recorders indicated that the modified tail configuration had been overpowered by dynamic forces at high speed, due to a previously undiscovered mathematical error in calculating loads for the hydraulic control actuators.
Even at this low point in the program the Navy BuAer still saw promise in the concept and optimistically continued funding for the SeaMaster and a number of expensive "options." A beaching cradle was designed that allowed SeaMasters to taxi in and out of the water on their own power. Two old amphibious-warfare dock ships and two conventional seaplane tenders began shipyard conversions as support ships for the SSF. The submarine U.S.S. Guavina, redesignated as an AO(SS) "oiler," was equipped to refuel SeaMasters at secret seadromes. There were also plans to use an old escort carrier equipped with a retractable rear ramp for "beaching" P6M's, which were too heavy to be hoisted aboard by cranes. Finally, an auxiliary naval air station was refurbished to serve as the SeaMasters' home base; it occupied 1,265 acres at NAS Harvey Point, near Elizabeth City, N.C.
Meanwhile service-test YP's were completed with "fixes" for the problems encountered in the prototypes. Engine nacelles were canted out five degrees from the fuselage and the intakes moved back from the wings' leading edges. Hydraulic control systems were upgraded in the tails. A year after the second crash, the first YP6M-1 was rolled out and flight testing resumed in January 1958. Five other YP's joined the program during 1958, and tests were carried out at a feverish pace. Mine-laying and navigation systems were qualified even though standard Navy mines could not yet withstand sea impact when dropped at high speed. Conventional and "special-weapon" (nuclear) practice shapes were successfully dropped from the rotary bomb-bay, and night and day photo reconnaissance pods were tested.
Early in 1959 production P6M-2's began to emerge from the Martin plant, and the full potential of the design was realized. Installation of newly developed Pratt and Whitney J75 engines gave the P6M-2's nearly 12,000 more pounds of static thrust. This allowed the gross weight to be increased to 195,000 pounds from 171,000 pounds in the YP's. Increased weight meant a greater draft for the hull, which in turn necessitated raising the wing anhedral to zero degrees. Other improvements included full-visibility canopies and transistorized Sperry navigation and bombing systems. Production P6M-2's were equipped with midair refueling probes, and "buddy-pack" refueling kits were designed to fit inside SeaMaster bomb-bays, allowing fast conversion into tankers.
Pilots reported that the planes handled well and were capable of flying
Mach .89 "on the deck." This was important, as the development of
radar-guided surface-to-air missiles had made low-level flying an
essential part of strategic penetration missions. The SeaMaster's wings
were especially strong for the extra stress of high speeds through thick
air; the aluminum skin at the wing roots was an inch thick. By contrast,
the Air Force's B-47 could only manage about Mach .58 at low altitude, the
newer B-52 only .55.
By the summer of 1959 all-Navy crews had begun flying three P6M-2's completed so far, and it appeared that operations could begin by early 1960. Rising costs, however, had led to two cutbacks, reducing the number of production items to eighteen, then eight. Then the bottom dropped out altogether. Citing "unforeseen technical difficulties," the Navy cancelled the entire program on August 21.
The decision was and still is highly controversial. More than $400 million had been spent on equipping the SSF, but during its long gestation period newer technologies had emerged. The development of the Polaris ballistic missile and submarine had finally given the Navy its strategic deterrent. Further, the atomic powered carrier Enterprise was going into service with long range nuclear capable strike aircraft, namely, the A3D Skywarriors and supersonic A3J Vigilantes.
Stunned, Martin engineers and executives tried to generate interest in an eight-jet transport version of the P6M, whimsically dubbed the SeaMistress, a huge nuclear-powered flying boat, and a supersonic seaplane somewhat resembling the Air Force Canberra. But there were no takers. Martin Chairman George Bunker announced that the company was now in the missile and electronics business. Fifty years of aircraft design and production was at an end.
Of the SeaMaster program little remains. The aircraft languished on the D Building ramp at Middle River for over a year after the cancellation before being scrapped. The "flying tails" and two rear fuselage sections were sent to Navy test facilities, while two sets of wing floats were used by a Martin supervisor to build a catamaran. Two tails, one fuselage section, and wing floats now belong to the Glenn L. Martin Aviation Museum.
|Martin P6M Seamaster|
|Wing span:||100 ft 0 in (30.48 m)|
|Length:||134 ft 0 in (40.84 m)|
|Height:||31 ft 0 in (9.45 m)|
|Payload:||30,000 lb (13,608 kg)|
|Max T/O:||160,000 lb (72,575 kg)|
|Maximum Speed:||600 mph (965 km/h)|
|Service Ceiling:||40,000 ft (12,200 m)|
|Range:||3,000 miles (4,830 km)|
|Four Pratt & Whitney J75-P-2 turbojets providing 17,500 lb (7,938 kg) st.|
|Six or eight .050
machine guns in the nose and amidships turrets plus,
up to 4,000 lbs (1,814 kg) of bombs or depth charges.
Please note that all information is provided without any guarantees