Curtiss OX-5

OX-5
	Preserved OX-5 engine
Type	V-8 piston engine
National origin	United States
Manufacturer	Curtiss Aeroplane and Motor Company
First run	1915
Number built	12,600
Developed from	Curtiss O

Last updated September 21, 2023

The Curtiss OX-5 was an early V-8 American liquid-cooled aircraft engine built by Curtiss. It was the first American-designed aircraft engine to enter mass production, although it was considered obsolete when it did so in 1917.^[1] It nevertheless found widespread use on a number of aircraft, perhaps the most famous being the JN-4 "Jenny". Some 12,600 units were built through early 1919. The wide availability of the engine in the surplus market made it common until the 1930s, although it was considered unreliable for most of its service life.

Design and development

The OX-5 was the last in a series of Glenn Curtiss designed V engines, which started as a series of air-cooled V-twins for motorcycles in 1902. A modified version of one of these early designs was sold as an aircraft engine in 1906, and from then on the company's primary market was aircraft. The basic design had slowly expanded by adding additional cylinders until they reached the V-8 in 1906. They also started enlarging the cylinders as well, but this led to cooling problems that required the introduction of water cooling in 1908. These early engines used a flathead valve arrangement, which eventually gave way to a cross-flow cylinder with overhead valves in 1909, leading to improved volumetric efficiency. By this point engine design was a team effort; the team included Charles M. Manly, whose earlier Manly–Balzer engine had held the power-to-weight ratio record for 16 years.^[2] Curtiss continued the development of their V8 engines with demand for higher power outputs being largely driven by the US Navy’s requirement for seaplanes. By 1912 Curtiss V8’s were developing 75 hp and were known as the Curtiss Model O. The Curtiss O was further developed into the 90 hp Curtiss OX. OX series production began in 1913. The OX-5 was built between 1915 and 1919 and was by far the most popular OX variant.^[3]

Like most engines of the era, the OX-5's high-temperature areas were built mostly of cast iron, using individual cylinders bolted to a single aluminum crankcase, wrapped in a cooling jacket made of a nickel-copper alloy. Later versions used a brazed-on steel jacket instead.^[4] Cylinder heads were also attached to the crankcase, using X-shaped tie-downs on the top of the head attached to the block via four long bolts.^[5] Fuel was carbureted near the rear of the engine, then piped to the cylinders via two T-shaped pipes, the cylinders being arranged so the intake ports of any two in a bank were near each other. The cylinders had one intake and one exhaust valve, the exhaust valve operated by a pushrod from a camshaft running between the banks and inlet valve operated by a pull rod/tube working from the same camshaft. This arrangement caused the outer exhaust valves to have a rather long rocker arm. The push/pullrods were arranged one inside the other, the exhaust valve rod being on the inside and the intake valve rod a tube around it.^[4] The aluminum camshaft bearings were a split type bolted together and held in place by lock screws.^[6] The pistons were cast aluminum.^[6]

The OX-5 was not considered particularly advanced, nor powerful, for its era. By this point rotary engines such as the Oberursel or Gnome-Rhône were producing about 100 hp (75 kW), and newer inlines were becoming available with 160 hp (120 kW) or more. Nevertheless, the OX-5 had fairly good fuel economy as a result of its slow RPM, which made it useful for civilian aircraft. The OX-5 was used on the Swallow Airplane Swallow, Pitcairn PA-4 Fleetwing II, Travel Air 2000, Waco 9 and 10, the American Eagle, the Buhl-Verville CW-3 Airster, and some models of the Jenny.^[7] The primary reason for its popularity was its low cost after the war, with almost-new examples selling as low as $20. It was often used in boats as well as in aircraft.

Reliability

The engine was considered unreliable,^[5] but unreliable is a relative term: aviation engine technology had not fully matured at the end of World War I. Certainly the JN4 with the OX-5 was underpowered, but the OX-5 proved a much better engine than the Hall Scott A7A that was the Achilles heel of the Standard J-1, the substitute primary trainer. In particular the valve gear was fragile, and it had no provisions for lubrication other than grease and oil applied by hand, leading to an overhaul interval as short as fifty hours. Additionally the engine featured a single spark plug in each cylinder, and a single ignition system, in an era when ignition equipment was less reliable,^[1] with dual ignition already being fitted to more advanced aviation powerplants like the French V-form Hispano-Suiza 8 and the inline-six cylinder series of Mercedes D.I through D.III German engines. Built by several contractors in large numbers, the OX-5 suffered from uneven quality control.^[5] However, while the overwhelming majority of training accidents in the U.S. were in JN-4s, this was because JN-4s were flown by the vast majority of trainee pilots, and the accident rate in the US for primary training was four times less than the advanced training rate in France (virtually all US airmen getting advanced training in France), approximately 2800 flying hours in the US primarily in OX-5 powered JN-4s per fatality to 761 hours per fatality in France in other types. Very few fatal accidents were caused by engine failure, although the lack of power may have been the cause of the many stall and spins that took about forty five percent of training lives. Anyone seeing a JN-4 today struggling into the air with an OX-5 can see very quickly that the JN-4 had to be flown in a narrow envelope. Also, the replacement of the A7A in Standard J-1s was contemplated, but the cost of $2,000 per aircraft compared with the need (by the time the J-1s were grounded in June 1918 JN-4s were in sufficient supply) led to the rejection of this idea. The successful civilian post-war use of the OX-5 (even in civilian purchased and converted J-1s) was due to its relative reliability in the more aerodynamically advanced designs of the 1920s, its simplicity of operation, and its low cost. By comparison the Hall Scott A7A created such a bad impression during the war that very few, if any, were used by civilian operators.

The OX-5 itself would be replaced by the well-proven Wright Aeronautical-built version of the 150 hp Hispano-Suiza HS-8a V8 engine in the nearly 930 examples of the later production Curtiss JN-4H Jenny biplanes.

Engines on display

A Curtis OX-5 engine is on public display at the Aerospace Museum of California.^{[ citation needed ]}
A Curtis OX-5 modified for marine use, reportedly in a Chris Craft, is on public display at the Iowa Great Lakes Maritime Museum.

Specifications (OX-5)

General characteristics

Type: 8-cylinder water-cooled 90° Vee piston engine^[1]^[4]
Bore: 4.0 in (102 mm)^[4]
Stroke: 5.0 in (127 mm)^[4]
Displacement: 503 in³ (8.2 L)^[4]^[5]
Length: 56.75 in (1441.45 mm)^[6]
Width: 29.75 in (755.65 mm)^[6]
Height: 36.75 in (933.45 mm)^[6]
Dry weight: 390 lb (177 kg)^[6]

Components

Valvetrain: One intake and one exhaust valve per cylinder, pushrod-actuated^[1]^[4]^[5]^[6]
Fuel system: Duplex Zenith Carburetor ^[6]
Oil system: Gear-pump 40 to 60 psi^[6] 3-gallon sump^[4]
Cooling system: Water-cooled^[4]^[6]

Performance

Power output:
90 hp (67 kW) at 1,400 rpm^[4]^[5]
105 hp (78 kW) at 1,800 rpm for brief periods
Specific power: 0.21 hp/in³ (9.5 kW/L)
Compression ratio: 4.9:1
Fuel consumption: 8.0 US gal/h (30.8 L/h) at 75% power^[4]
Specific fuel consumption: 0.53 lb/(hp·h) (0.32 kg/(kW·h)) at 75% power
Oil consumption: 0.5 US gal/h (1.9 L/h) at 75% power
Power-to-weight ratio: 0.27 hp/lb (440 W/kg)

Related Research Articles

The GM Ecotec engine, also known by its codename L850, is a family of all-aluminium inline-four engines, displacing between 1.4 and 2.5 litres. Confusingly, the Ecotec name was also applied to the final DOHC derivatives of the previous GM Family II engine, the architecture was substantially re-engineered for this new Ecotec application produced since 2000. This engine family replaced the GM Family II engine, the GM 122 engine, the Saab H engine, and the Quad 4 engine. It is manufactured in multiple locations, to include Spring Hill Manufacturing, in Spring Hill, Tennessee while the engine block and cylinder heads are cast at Saginaw Metal Casting Operations in Saginaw, Michigan.

The LA engines are a family of pushrod OHV small block 90° V-configured gasoline engines built by Chrysler Corporation. They were factory-installed in passenger vehicles, trucks and vans, commercial vehicles, marine and industrial applications from 1964 through 1991 (318) & 1992 (360). Their combustion chambers are wedge-shaped, rather than polyspherical, as in the predecessor A engine, or hemispherical in the Hemi. LA engines have the same 4.46 in (113 mm) bore spacing as the A engines.

A W8 engine is an eight-cylinder piston engine with four banks of two cylinders each, arranged in a W configuration.

The Chevrolet small-block engine is a series of gasoline-powered V8 automobile engines, produced by the Chevrolet division of General Motors between 1954 and 2003, using the same basic engine block. Referred to as a "small-block" for its size relative to the physically much larger Chevrolet big-block engines, the small block family spanned from 262 cu in (4.3 L) to 400 cu in (6.6 L) in displacement. Engineer Ed Cole is credited with leading the design for this engine. The engine block and cylinder heads were cast at Saginaw Metal Casting Operations in Saginaw, Michigan.

In automotive engineering a multi-valve or multivalve engine is one where each cylinder has more than two valves. A multi-valve engine has better breathing and may be able to operate at higher revolutions per minute (RPM) than a two-valve engine, delivering more power.

The Ford flathead V8 is a V8 engine with a flat cylinder head designed by the Ford Motor Company and built by Ford and various licensees. During the engine's first decade of production, when overhead-valve engines were used by only a small minority of makes, it was usually known simply as the Ford V‑8, and the first car model in which it was installed, the Model 18, was often called simply the "Ford V-8", after its new engine. Although the V8 configuration was not new when the Ford V8 was introduced in 1932, the latter was a market first in the respect that it made an 8-cylinder affordable and a V engine affordable to the emerging mass market consumer for the first time. It was the first independently designed and built V8 engine produced by Ford for mass production, and it ranks as one of the company's most important developments. A fascination with ever-more-powerful engines was perhaps the most salient aspect of the American car and truck market for a half century, from 1923 until 1973. The engine was intended to be used for big passenger cars and trucks; it was installed in such until 1953, making the engine's 21-year production run for the U.S. consumer market longer than the 19-year run of the Ford Model T engine for that market. The engine was on Ward's list of the 10 best engines of the 20th century. It was a staple of hot rodders in the 1950s, and it remains famous in the classic car hobbies even today, despite the huge variety of other popular V8s that followed.

The Hispano-Suiza 8 is a water-cooled V8 SOHC aero engine introduced by Hispano-Suiza in 1914 that went on to become the most commonly used liquid-cooled engine in the aircraft of the Entente Powers during the First World War. The original Hispano-Suiza 8A was rated at 140 hp (100 kW) and the later, larger displacement Hispano-Suiza 8F reached 330 hp (250 kW).

The Hyundai Beta engines are 1.6 L to 2.0 L I4 built in Ulsan, South Korea.

The Toyota S Series engines are a family of straight-4 petrol or CNG engines with displacement from 1.8 L to 2.2 L produced by Toyota Motor Corporation from January 1980 to August 2007. The series has cast iron engine blocks and aluminium cylinder heads.

The Curtiss V-1570 Conqueror was a 12-cylinder vee liquid-cooled aircraft engine. Representing a more powerful version of the Curtiss D-12, the engine entered production in 1926 and flew in numerous aircraft.

The Allison V-3420 was a large experimental piston aircraft engine, designed in 1937 by the American Allison Engine Company.

The Sunbeam Manitou was an aero-engine produced by Sunbeam. Unsuccessful as an aero-engine, it is best known for having powered the Sunbeam 350HP racing car.

The Sunbeam Afridi was an aero-engine produced by Sunbeam during the First World War.

The Aeromarine B-90 is an aircraft engine built by the Aeromarine Plane and Motor Company in 1915. Aeromarine made two series of V-8 engines. The B series was developed by Joseph Boland and the L series by Charles F. Willard.

The Curtiss O was a 75 hp (56 kW) water-cooled V-8 aero-engine, which was the basis of the commercially successful Curtiss OX series of engines.

The De Dion-Bouton 78 hp, typically referred to as De Dion-Bouton 80 hp, was an eight-cylinder, air cooled vee aircraft engine that has been built by De Dion-Bouton.

The Volkswagen-Audi V8 engine family is a series of mechanically similar, gasoline-powered and diesel-powered, V-8, internal combustion piston engines, developed and produced by the Volkswagen Group, in partnership with Audi, since 1988. They have been used in various Volkswagen Group models, and by numerous Volkswagen-owned companies. The first spark-ignition gasoline V-8 engine configuration was used in the 1988 Audi V8 model; and the first compression-ignition diesel V8 engine configuration was used in the 1999 Audi A8 3.3 TDI Quattro. The V8 gasoline and diesel engines have been used in most Audi, Volkswagen, Porsche, Bentley, and Lamborghini models ever since. The larger-displacement diesel V8 engine configuration has also been used in various Scania commercial vehicles; such as in trucks, buses, and marine (boat) applications.

References

1 2 3 4 Smith, 1981, page 46
↑ Smith, 1981, page 12
↑ Rinek, Larry (1994). "Glenn H. Curtiss: An Early American Innovator in Aviation and Motorcycle Engines". SAE Transactions. 103: 927–945. Retrieved 31 Dec 2022.
1 2 3 4 5 6 7 8 9 10 11 Fisher, 2009, page 7
1 2 3 4 5 6 Gunston, 1995, page 47
1 2 3 4 5 6 7 8 9 10 Angle, 1940, pages 244-246
↑ Smith, 1981, page 47

Bibliography

Angle, Glenn D., AEROSPHERE 1939. New York: Aircraft Publications, 1940.
Gunston, Bill, World Encyclopedia of Aero Engines. Somerset: Haynes Publishing, 1995. ISBN 1-85260-509-X
Fisher, Scott M., The Curtiss OX-5, Aircraft Maintenance Technology. Cygnus Business Media, July 2009.
Smith, Herschel, Aircraft Piston Engines. McGraw-Hill Book Company, 1981. ISBN 0-07-058472-9

External links

Curtiss OX-5

This page is based on this Wikipedia article
Text is available under the CC BY-SA 4.0 license; additional terms may apply.
Images, videos and audio are available under their respective licenses.

[APE-1] 1 2 3 4 Smith, 1981, page 46

[APE_3-2] Smith, 1981, page 12

[:SY1-3] Rinek, Larry (1994). "Glenn H. Curtiss: An Early American Innovator in Aviation and Motorcycle Engines". SAE Transactions. 103: 927–945. Retrieved 31 Dec 2022.

[AMT_7-4] 1 2 3 4 5 6 7 8 9 10 11 Fisher, 2009, page 7

[Aero-5] 1 2 3 4 5 6 Gunston, 1995, page 47

[AERO1939-6] 1 2 3 4 5 6 7 8 9 10 Angle, 1940, pages 244-246

[APE_7-7] Smith, 1981, page 47

[1]

[2]

[3]

[4]

[5]

[6]

[7]

v t e Curtiss aircraft engines
Inline engines	A-2 B-8 C-6 Challenger D-12 K-12 Model K O OX-5 OXX V-1570 V-2
Radial engines	H-1640 R-600 R-1454