Pratt & Whitney Aircraft
R-4360 Wasp Major Development History
Compiled by Kimble D. McCutcheon
Published 18 Apr 2025; Revised 4 Jun 2025

Liquid-Cooled H-3730 (L) and Air-Cooled R-4360 (R)

Circumstances Surrounding Initial R-4360 Engine Studies For several years, Pratt & Whitney Aircraft experimented with various liquid-cooled aircraft engine types including diesel, gasoline, sleeve-valve and poppet-valve arrangements. During the 1938 to 1940 period, efforts were directed primarily at developing two liquid-cooled 24-cylinder sleeve-valve "H" type engine designs, the Army X-1800 displacing 2,597.7 in³ and takeoff-rated 2,200 hp at 3,200 rpm, and the Navy H-3730 displacing 3,732.2 in³ and takeoff rated 2,600 hp at 3,000 rpm. Several fuel injection innovations brought about by integral multi-stage supercharging and intercooling created many unusual and difficult problems in the induction and carburetion systems of these engines. Similarly, problems not inherent with radial engines were introduced in the design and manufacture of durable sleeve valves, reduction gears, and crankcases, problems with which the majority of personnel at Pratt & Whitney Aircraft had little or no experience. For these reasons, and undoubtedly many more, plus the fact that a war seemed imminent, it was felt that by reverting to designs with which Pratt & Whitney Aircraft was familiar and also a design that was readily adaptable to existing tools and manufacturing procedure, the company could do a much better with a 28-cylinder air-cooled four-row radial displacing 4,362.49 in³. Therefore, it was decided (with the consent of both Army and Navy) to abandon development of the liquid-cooled sleeve-valve engines.

Historic R-4360 Dates

Prototype R-4360 Engine

1. Design work was authorized by the Management, 11 Nov 1940.
2. The first engine, made up largely of salvaged 3130 reduction gees, R-2180 rods, R-2800 cylinders, a cast steel crankshaft and hurriedly manufactured crankcase, ran on 28 Apr 1941.
3. During 1941, three four-row engines and one single-row engine were run and parts for six engines had been mostly machined, At the end of 1941, approximately one year after starting design, 500 hours of full scale operation, 176 hours of single-row operation and 1,412 hours of single-cylinder operation had bean completed.

Vultee Vengence V-85

4. The R-4360 first flew on 25 May 1942, using the third R-4360 engine. This flight was made in a converted Vultee Vengeance known as the V-85. Unfortunately, this airplane was wrecked late in 1942 during a forced landing in a tobacco field north of Hartford, Connecticut. The forced landing was caused a ruptured fuel nozzle diaphragm combined with a plugged nozzle vent passage resulting in cutting off the engine fuel supply. Fortunately, there were no serious injuries. However, there were later two serious accidents, one involving Howard Hughes and the second a mid-air collision of two Navy aircraft.
5. During 1942, the engine was released to Semi-Production and in 1943, ten engines were delivered as experimental models for prototype aircraft.
6. The original R-4360 was made with R-2800 front-bank cylinders; the fourth engine was the first to operate with forged heads. However, the intake pipes were located in the position now occupied by the exhaust. This was the only engine operated in this manner, it being found more efficient from a performance standpoint to operate with s top intake and side exhaust. This method also allowed a very simple manifolding system to be used on both pusher and tractor engines without any other cylinder changes other reversing it 180° on the crankcase.

Experimental R-4360 No. X-109 with top exhausts.

7. With the final R-4360 designs, it was possible to take any power section and convert it to a tractor or pusher model by changing only the cam, reversing the cylinders and changing the intake pipes and baffles, The same basic power section was used on all the multiplicity of models designed around the R-4360. A similar application was made to the rear section where converting from single to auxiliary stage involved little more than removing a rear cover plate and substituting the additional stage parts, or a single-stage, single-speed rear section could be converted to a single-stage variable-speed rear with a simple addition of parts. Similar applications were present, although to a lesser degree, in converting from single to dual rotation reduction gear. The object of this was to manufacture an engine that could be easily converted to any number of models without having to have a great number of different machine operations for each, with a consequent reduction in coats, machining space and equipment. A review of the large number of models produced would indicate the need for this procedure.
8. By 1944, 21,805 hours of multi-cylinder testing, 1,980 hours of single-row testing and 34,720 hours of single-cylinder tasting were accumulated. Specifications for 33 different models, each one adapted to a particular airplane installation or installations, had been accomplished. The Experimental Section operated a total of 26 mu1t-cylinder engines for purposes of development, model and type tests, performance, and flight test. The culmination of this development work was R-4360-B Series engine production.

Detailed R-4360 Timeline

• Summer 1940. Design studies to determine the optimum arrangement of a multi-bank radial of around 3,000 hp.
• 11 Nov 1940. Design began on an air-cooled 28-cylinder 4-row radial of 4,362.49 in³.
• 28 Apr 1941. An "A Series" semi-production engine, rated 2,800 hp at 2,600 rpm first ran. During 1941 500 hrs run time was accumulated. Total expenditure was engineering cost was 1,500,000.
• 1 Mar 1942, XR-4360-2. First military designation assigned to an engine purchased by the U.S. Navy for type test. The R-4360-1 designation was never assigned.
• 30 Apr 1942. Model designations were assigned to cover various prototype airplane applications. By the time these model designations were assigned, testing revealed that 3,000 hp could be realized; this rating was used for all engines after the R-4360-2. Even-numbered designations were Navy, odd ones Army.

  R-4360-8	R-4360-10

  • R-4360-3 = Single-stage single-speed dual rotation tractor or pusher for Curtiss XP-71 and Republic XP-72.
  • R-4360-4 = Single-stage variable-speed tractor for P&WA flight test. This was the basic model and other models were variations.
  • R-4360-5 = Single-stage single-speed two-speed reduction gear for Consolidated XB-36.
  • R-4360-6 = Two-stage variable-speed, none built.
  • R-4360-7 = Single-speed single-stage, remotely mounted two-speed dual-rotation reduction gear for Northrop XB-35.
  • R-4360-8 = Single-speed dual-rotation for Douglas XTB2D and Curtiss XBTC.
  • R-4360-9 = 0.500 instead of 0.381 reduction gear for Vultee XA-41.
  • R-4360-10 = Two-stage variable-speed, dual-rotation two-speed reduction gear for Boeing XF8B1.
  • R-4360-11 = Similar to R-4360-7 with longer extension shaft for Northrop XB-35 inboard nacelles.
  • R-4360-13 = Remotely-mounted two-stage variable-speed supercharger, 0.425 single-rotation reduction gear to replace the R-4360-3 in the Republic XP-72.

Remote Reduction Gear and Shafting for Northrop XB-35	Remote Supercharger

 

• 25 May 1942. First flight.

Starting in 1942, additional engine model designations were assigned for new aircraft projects or production models. The production models were identified as "B Series" engines.

• Jul 1942, R-4360-12 = Dual-rotation two-speed reduction gear for Curtiss XTBC-2, replacing the R-4360-8 previously planned.
• At the end of 1942 3,500 hrs test stand operation had been accumulated and $5,700,000 in engineering had been spent.
• Feb 1943, R-4360-15 = Single-rotation 0.425 reduction gear for Douglas C-74.
• Feb 1943, R-4360-17 = R-4360-7 production version for Northrop YB-35 outboard nacelle.
• Feb 1943, R-4360-19 = R-4360-13 production version for Republic P-72.
• Feb 1943, R-4360-21 = R-4360-11 production version for Northrop YB-35 inboard nacelle.
• Mar 1943, R-4360-23 = R-4360-3 production version for Curtiss XP-71.
• Mar 1943, R-4360-25 = R-4360-5 production version for Consolidated B-36 and C-99.
• Mar 1943, R-4360-27 = R-4360-15 production version for Douglas C-74.
• 7 Jun 1943. First military engine shipped to the Navy Aeronautical Engine Laboratory, Philadelphia, Pennsylvania.
• Jun 1943, R-4360-29 = Two-stage variable-speed supercharger for prototype R-4360-powered B-29.
• Aug 1943, R-4360-14 = Single-speed dual-rotation reduction gear with #50-#70 shaft in place of the #60-#80 R-4360-8 shaft in Curtiss XBTC-2.

R-4360-5 First "B Series" Engine Shipped

• Sep 1943. The first semi-production ("B Series") engines were shipped; an R-4360-5 with locked one-speed reduction gear to Consolidated for test rig work, and an R-4360-13 to Republic for the XP-72.
• Oct 1943. An R-4360-7 was shipped to Martin for use on the B-35 program and an R-4360-8 was shipped to Curtiss for the XBTC-2 program.
• Nov 1943. An R4360-9 was shipped to Vultee for the XA-41.
• Dec 1943. An R-4360-9 was shipped to Wright Field, an R-4360-15 was shipped to Douglas and an R-4360-8 was shipped to Curtiss-Wright Corporation, Columbus, Ohio.
• No R-4360-16 designation was ever assigned.
• Dec 1943, R-4360-18 = Single-stage single-speed supercharger for Lockheed C-89.
• Dec 1943, R-4360-31 = Single-stage single speed, dual rotation for Hughes F-11 and Republic F-12.

As 1943 ended a total of six engines had been shipped for Army project and two for Navy projects. A total of 7,200 hrs of test stand operation had been accumulated and $10,000,000 expended on engineering. During January and February 1944, a total of eight "B Series" engines was shipped, including four R-4360-4s, one R-4360-7, one R-4360-8, one R-4360-11, and one R-4360-13.

• Mar 1944, R-4360-33. Two-stage variable-speed supercharger for Boeing XB-44.

During the remainder of 1944, a total of 19 more "B Series" engines were shipped, including six R-4360-5s, one R-4360-13, four R-4360-10s, four R-4360-4s, one R-4360-9, and two R-4360-8s. At 1944's end, a total of 17 Army and 13 Navy "B Series" engines were shipped. Test stand operation had reached 12,000 and engineering cost was $15,300,000.

• Jan 1945. The first "C Series" production engine was shopped, an R-4360-4.
• Feb 6 1945. First 150 hr Type Test was completed at the Navy Aircraft Engine Laboratory.

During Summer 1945, it became necessary to provide additional takeoff power for the Boeing B-50. To accomplish this, the B3 Series engine was developed. This engine reduced the compression ratio from 7.0:1 to 6.7:1, cylinder baffles were changed to protect the rocker boxes and ignition systems from exhaust heat (hooded baffles) and power section reduction gearing was strengthened.

• Jul 1945, R-4360-35 = Single-stage single-speed supercharger and 3,500 hp rating for the Boeing B-50.
• Nov 1945, R-4360-37 = Single-stage supercharger and single-speed reduction gear for the Republic F-12, replacing the R-4360-31.

Late in 1945 it was realized that to have an engine that could be rated in excess of 3,500 hp it would be necessary to redesign the "B Series" engine to provide additional strength throughout. To accomplish this, the "C Series" engine was laid out. It differed from the "B Series" in all major parts. The crankshaft was changed to permit crankcase strengthening. The crankcase was made heavier and stronger, the mounting system was changed to permit the use of stronger main case attachment, the cylinder was changed to provide better cooling, and the rear case was changed to accommodate direct fuel injection, and the reduction gear was strengthened to transmit higher power. During 1945, engine shipments totaled 30 "B Series" engines and 81 production engines, for at total of 62 Army and 79 Navy engines. Development test time reached 17,000 hrs and engineering costs reached $19,700,000.

• Jan 1946, R-4360-39 = "C Series" single-stage single speed engine rated at 3,800 hp.
• Mar 1946, R-4360-20 = Basic engine model having 3,250 hp (subsequently raised to 3,500 hp) for use in Martin AM-2, Martin P4M and Fairchild C-119 aircraft.
• In July 1946 the 150 hr model test of the R-4360-35 (for the Boeing B-50) and the R-4360-25 engine for the B-36 were completed. It was decided that B-36 engines should also have features that would permit operation at 3,500 hp.
• Oct 1946, R-4360-41 Consolidated B-36 engine having 3,500 hp in place of the R-4360-25.

During 1946 a total of 323 Air Force and 221 Navy engines were shipped. Test time was increased to 24,000 hrs and engineering costs reached $25,700.00. During "C Series" engine development, studies of various compounding means showed that by removing the engine-driven supercharger and using exhaust energy in a turbosupercharger to do all the engine supercharging, a 500 hp takeoff rating increase could be realized along with an 8% cruising fuel consumption reduction. "C-series" development work was carried out to permit its use with such arrangements.

• Apr 1947, R-4360-43 = "C Series" engine with external supercharging and a 4,300 hp rating for the Boeing YB-50C and B-54.
• Apr 1947, R-4360-45 = Single-rotation reduction gear replacing the R-4360-17 in Northrop XB-35 outboard nacelles.
• Apr 1947, R-4360-47 = Single-rotation reduction gear replacing the R-4360-21 in Northrop XB-35 inboard nacelles.
• May 1947, R-4360-22 = Single-stage single-speed 3,500 hp engine replacing the R-4360-17 in the Lockheed C-89.
• Jun 1947, R-4360-51 = Externally-supercharged "C Series" tractor with remotely-mounted 0.3125 reduction gear and cooling fan and 4,300 hp rating for the Consolidated B-36C.

During 1947, 790 engines were shipped, bringing the total to 1,025 Air Forces engines and 289 Navy engines. Engineering costs were at $33,200,000.

• Mar 1948, R-4360-49 = 3,500 hp engine replacing the R-4360-27 in the Douglas C-74.

During 1948, 1,005 engines were shipped, bringing the total to 2,009 Air Forces engines and 310 Navy engines. Engineering costs were at $40,600,000.

• Jun 1949, R-4360-53 = Single-stage single-speed "C Series" pusher with 3,800 hp rating and cooling fan to replace the R-4360-41 in the Consolidated B-36.
• Jun 1949, R-4360-55 = Externally-supercharged "C Series" pusher with external cooling fan, rated at 4,300 hp and replacing R-4360-41 or R-4360-53 in later Consolidated B-36s.
• Jun 1949, R-4360-57 = Advanced development of the R-4360-55 with compression ratio increase to improve Consolidated B-36 fuel consumption by 20%.

Through Jun 1949, 719 engines were shipped, bringing the total to 2,644 Air Forces engines and 394 Navy engines. Engineering costs were at $42,900,000.

Airplanes Using R-4360 Engines

R-4360 Development Problems

In developing a new engine, the ratings at which initial development is started are usually at the current brake mean effective pressure (bmep) rating of the most recent production model of the next largest size engine. In the R-4360's case, initial development centered around ratings similar to that of the R-2800 "B Series". Usually engine ratings rapidly exceed those of previous engine models; the R-2800 exceeded that of the R-1830, etc. This is generally caused by the inability to stay within dimensional limitations for installation or service replacement requirements and it became necessary to introduce an entirely new engine. This point is only now being reached in the R-4360 engine where P&WA was now going from an R-4360 "B Series" to the R-4360 "C Series". The "A Series" R-4360 never materialized much beyond the tinkering stage as it was found in early development that the engine was capable of 3,000 hp instead of the original 2,800 hp "A Series" rating. It does appear at this time that the current 3,500 hp takeoff rating for the "B Series" engine was about as high as P&WA could go, although war emergency ratings up to 4,400 hp or higher were probably possible.

During development, an R-4360 was drawn from production and operated in excess of 4,400 hp for three days and accumulated approximately 22 hours of operation in this range. This same engine was also calibrated and run for about an hour as high as 4,850 hp and subsequently for 100 hours at 3,000 hp and approximately 50 hours at 3,500 hp before disassembly. This engine was still in serviceable condition.

In the course of R-4360 development the problems common with other engine models and currently being investigated by the other P&WA engine groups were very often sidetracked and the efforts of the R-4360 Group concentrated entirely on features peculiar only to the R-4360. As an example, R-2800 and R-4360 piston and ring assemblies at elevated powers were subject to ring sticking, a constant source of annoyance. The R-4360 Group suffered along by overcooling or babying the piston assemblies through endurance testing and the R-2800 Group carried on with development of a piston and ring assembly that would be free of sticking. At the conclusion of their investigation, the piston and ring assembly adopted for the R-2800 was used in the R-4360. This was possible to do in most cases but often cases arose where items used satisfactorily in other engines could not be used on the R-4360.

Hose clamps and connections on R-2800 rocker drain systems proved quite satisfactory, but R-4360 rocker drain system oil temperatures were considerably higher than in the R-2800, which resulted in severe and rapid rocker drain hose deterioration. It was therefore necessary to develop a rocker drain system using a more heat-resistant material. This was very satisfactorily done by the use of the new silicone rubbers. Silicone, however, had an unusual property of flowing readily and therefore had to be completely confined. This rubber's flow characteristics were addressed by a spring-loaded compressive installation that eliminated the need to service these parts during engine operation.

The following items are some of the more interesting and complex problems encountered during R-4360 development and for the most part are peculiar to that engine type. At some time or other, almost every engine part required some improvement or design change and parts that were initially trouble-free became troublesome as the engine was further developed and accrued more and more time at elevated powers. Probably the most interesting part of engine development was the constant possibility that anything from a cotter pin to a crankshaft could be the next item to be troublesome as the power conditions were elevated.

Crankshaft

The crankshaft actually lost weight during its initial development. In some experimental overspeed testing conditions (not conditions encountered for any appreciable time in service) it was possible, after 50 hours of operation at this condition, to develop cracks at the crank cheek. This condition was traced to stiffness in this crankshaft, which, because of the flexibility of other shaft portions, resulted in stress concentration under the resonant vibration characteristics experienced at this overspeed point. By removing material from the crankshaft and providing greater radii at the edges, this cracking was eliminated even though the actual crankshaft twisting was probably increased. Also, during engine development, it was noticed that the front intermediate main bearing was subject to frequent unexplained test stand failures. It was further found that this failure could be induced either by reducing main oil pressure below 75 psi or introducing air into the oil pump inlet, a condition prevalent in a large number of aircraft not having a good oil system and means of eliminating air entrained in the oil leading to the tank from the engine. This bearing burning problem was solved in two ways. Engineers instrumented the oil passage through the crankshaft and noted that when the main oil pressure was at 75 psi, only 10 to 15 psi reached the front intermediate main bearing. There were two main oil supplies to the engine nose, one through the crankshaft and the second through oil passages at the crankcase top. However, due to the crankshaft's oil flow requirements, oil entering the rear crankshaft section only reached the front intermediate main bearing; the front crankshaft section was fed from the line traversing the crankcase upper half. The second cure for this bearing burning was the installation of air separators in the main journals where small diameter holes were drilled on the exact crankshaft center line or ones that led from this center line. The crankshaft's whirling motion tended to separate the oil from the air, concentrating air at the crankshaft center. Since it is also necessary to provide sludge traps in the crankshaft, the oil feeds from one crankshaft section to the other were necessarily taken as close to the center line as possible, which resulted in feeding air rather than oil. These small bleed holes offered little resistance to the air but sufficiently resisted oil flow so that no detrimental pressure losses were encountered.

Scavenging

According to G.E. Armbruster, "…the initial R-4360 wouldn't scavenge nohow." This problem was rectified by a scheme that presented with no breathing difficulties or excessive power loss up to 40,000 ft. In order to obtain this scavenging efficiency, a large numbers of changes were made over a period of 2.5 years, changes that involved increasing the scavenge pumps' capacity, adding scavenge pump stages or locations, revising scavenge pump inlet conditions, and installing screens in certain compartments to act as air separators that reduced the oil volume and increased its density so it could be efficiently handled by the scavenge pumps. The fact that this was a dry sump engine meant that oil had be collected by the pump "on the run." Several scavenge rigs were made and engines were tested both on the test stand and in flight. A converted Vought F4U was used for flight testing because of its high climb angle and high rate of climb, which provided the most severe scavenge conditions that could be encountered.

Although additional scavenge pumps with increased capacity contributed greatly, effective scavenging was not achieved until screens were used. These screens worked on the theory that oil in the engine was whipped to a froth similar to soap suds in the kitchen sink. When draining the sink, the solid water under the soap suds flowed out of the drain, but if this water contained enough soap, removing the drain plug after beating into a froth had no effect on the draining the soap suds. A similar condition existed is the engine and the scavenge pumps could not remove the oil suds. Since the oil foam was traveling at high velocity and had more inertia than the air in it, when the foam impinged upon a screen the large bubbles could not pass through small hole, but the oil, by virtue of its own inertia, seperated out, passed through the screens and emerged with a greatly reduced air content, thus approaching a more nearly liquid condition prior to entering the scavenge pumps.

An engine sometimes threw oil out the breathers instead of scavenging, which was evidenced by a high temperature rise and horsepower loss. Initially, the R-4360 with a four-coupling variable-speed supercharger drive developed around 200 less horsepower less for a given manifold pressure than the same engine with a two-gear fixed supercharger drive in the same compartment; the couplings were whirling the oil around at such a rate that it could not be scavenged from the compartment. The R-4360-4 blower drive compartment had a 120 lb/min oil flow, yet the compartment's oil capacity was less than 15 lb. It was in the blower drivev compartment that screens contributed their most valuable results by reducing horsepower loss from over 200 to less than 35.

Cylinders

Fortunately, no great amount of trouble was experienced with the use of the fore-and-aft forged head cylinder. There were a few weaknesses that showed up such as exhaust valve guide erosion, intake valve seat warpage, exhaust rocker ear valve gear coking, and rocker cap gasket oil leakage. Exhaust valve guide wear was corrected by the use of steel-tipped guides that scraped lead deposits off the valve stems. As the performance numbers of fuels increased, the increased lead content icaused combustion chamber and exhaust passage lead deposits to become more and more troublesome. Exhaust rocker ear coking was primarily caused by too few cooling fins on that ear and very little cooling air circulation, a condition non-existent in other Pratt & Whitney engines up to that time. The revised baffle system on the R-4360-35 engine greatly helped to alleviate this condition. This, combined with an oil cooling jet in the ear and the use of silicone rocker cap gaskets alleviated most of the troubles. The intake valve seat warpage was simply eliminated by changing from a bronze to a steel seat plus a change in valve seat width and valve spring action.

The initial R-4360 baffle system was such that ignition harness, rocker ear, intake pipes, etc., cooling was dependent upon the care the aircraft manufacturer took in providing proper exits for the hot air from the engine. Experience indicated that the engine experience of people employed by the aircraft manufacturers with such details was necessarily limited and that it was far better for Pratt & Whitney to completely enclose the engine so as to control these operating conditions. Further, the use of the R-4360-35 type of hooded baffle greatly reduced temperatures in these parts by enclosing them in the cooling system's cold-air side, resulting in considerably longer parts life.

Intake Pipes

R-4360 intake pipes had much larger radii on the engine than other models. The cylinders were very flexible and under high power operation weaved about considerably, imposing considerable stresses on the intake pipes. It became necessary to impose very wide gaps between the pipes on adjacent cylinders in order to allow sufficient flexibility without pipe strain. Whereas this was successful in reducing pipe failures, serious hose connection failure epidemics resulted. A successful solution to hose and coupling bursting caused by backfires was accompanied by installing a metal shield supported by a bulge in the coupling. However, these rubber hoses were still subject to deterioration and development continued to find a satisfactory all-metal coupling. After considerable experimentation a metal coupling was developed.

Another problem with the large-radius intake pipes was the matter of fuel and oil draining from the lower intake pipes. Since the intake pipe was considerably lower than the intake valve ports, pulling the engine through did not insure against hydraulic locks, as a very large amount of gasoline and/or oil could accumulate in the intake pipe lower part. The engine could run at low speeds with this fuel/oil collection in the pipe, but when the throttle was advanced and the air velocity within the intake pipe increased, a sudden wave of this liquid could develop and be forced into the front cylinder bank, wrecking the engine. To eliminate this, automatic drains were installed in the lower intake pipes; these drains would close whenever a differential air pressure in either direction was imposed. Since relatively small force was available to operate these valves, they had to be light; consequently, they were not very durable, particularly in conditions that promoted backfires and could stick very easily by gum or dust. Since, for normal shutdown periods oil generally did not leak past pistons and into cylinders in quantities that would cause hydraulic locks, and since most hydraulic locks were the result of improper mixture control during starting, engineers decided that if the fuel could be trapped in the blower before it got to the intake pipe, the danger of hydraulic locks could be eliminated.

Engines left in storage for any length of time had plugs in the lower pipes for manual drainage, but for day-to-day operation an annulus around the intake pipe as it left the blower leading to a chamber with a float valve was quite satisfactory in removing liquid fuel tending to flow to the lover pipes from the blower. Operating instructions specified that an engine should be started on the prime and that the mixture control should not be moved out of idle cut-off until the engine started to fire. With the new R-4360 priming system that injected fuel into the blower rim , this was a very easy and simple way to start, However, there remained a large number of people schooled in the theory that the only way to start an engine was to jockey the mixture control.

If during R-4360 starting, 15 psi boost pressure was supplied and the mixture control and throttle were moved to their full open positions, which had been known to happen among some of the very careless personnel, it required a 1.125" diameter hole in the intake pipe to drain enough fuel to prevent hydraulic lock. This not only resulted in a prohibitive hole size but might result in serious fire hazard should exhaust system torching set off this fuel, which would be pouring to the ground or the deck of an aircraft carrier. In the space allowed with the float type drain valve, P&WA was unable to get a valve of sufficient size to take care of more than 75% of this requirement. However, this extreme example was so unusual and rare that the probability of it happening was very remote.

Ignition

"C Series" Engine with Four-Magneto Ignition

Early engines used seven pressurized Bendix Scintilla D4RN-2 high-tension shielded magnetos with integral distributors operating at 1/2 crankshaft speed. Each magneto provided dual ignition for the bank of four cylinders directly behind it. Pratt & Whitney chose to use seven magnetos for simplicity, durability, and continued engine reliability should enemy action damage one or two of the magnetos. These parts produced relatively little trouble. Considerable controversy, however, arose over the merits of a single-piece molded and sealed ignition harness versus ones with detachable and leads. Later ignition harnesses featured detachable leads.

Later engines used four Bendix Scintilla S14RN-15 low-tension magnetos with integral distributors operating at 1/2 crankshaft speed. Magnetos on the engine's left side were designated L1 and L2; L1, the top-left magneto, fired the intake plugs on cylinder rows B and D; L2, the bottom-left magneto, fired the intake plugs on cylinder rows A and C. Magnetos on the engine's right side were designated R1 and R2; R1, the top-right magneto, fired the exhaust plugs on cylinder rows B and D; R2 the bottom-right magneto fired the exhaust plugs on cylinder rows A and C.

The Wasp Major Legacy

Pratt & Whitney Aircraft produced R-4360s through 1955 for total production of 18,769 units.

Wasp Major Crankcase Components	Wasp Major Cutaway

References

Armbruster, G.E. "History of the R-4360" Pratt & Whitney Service School Handbook
History of 4360 Type Engine. Pratt & Whitney publication.
Parts Catalog for Models R-4360-20, -20A, -20B, -20C, -20T, -20AT, -20W, -20WA, -20WB, -20WC, -22W, -35, -35A, -35B, -35C, -49, and -49A Aircraft Engines. (NAVY) AN 02A-10HE-4; (USAF) T.O. No. 2R-R4360-14. 1 Dec 1955.
Overhaul Manual Wasp Major (R-4360) B6 and CB2 Engines. Pratt & Whitney Aircraft Part No. 201529. Dec 1953.

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