Military Wiki
British-built SPAD SVII of the RFC
Role biplane fighter
Manufacturer SPAD
Designer Louis Béchereau
First flight May 1916
Primary users Aéronautique Militaire
Royal Flying Corps - Belgium - Italy
Number built ~6000[1]

The SPAD S.VII was the first of a series of highly successful biplane fighter aircraft produced by Société Pour L'Aviation et ses Dérivés (SPAD) during the First World War. Like its successors, the S.VII was renowned as a sturdy and rugged aircraft with good climbing and diving characteristics. It was also a stable gun platform, although pilots used to the more manoeuvrable Nieuport fighters found it heavy on the controls. It was flown by a number of the famous aces, such as France's Georges Guynemer, Italy's Francesco Baracca and Australia's Alexander Pentland.

Design and development


Performance in early aircraft designs was largely dependent on engines. In February 1915, Swiss designer Marc Birkigt had created an overhead cam aviation powerplant based on his Hispano-Suiza V8 automobile engine, resulting in a 330 lb engine capable of producing 140 hp at 1,400 rpm. Further refinement of the engine brought the power to 150 hp by July 1915. Given the engine's excellent reputation, French officials ordered that production be set up as soon as possible and called upon aircraft designers to create a new high-performance fighter around the engine, called the Hispano-Suiza 8A.

Louis Béchereau, chief designer of the SPAD company, quickly produced drawings for a prototype fighter equipped with the new engine. The SPAD V was basically a smaller version of the SPAD A.2 two-seat "pulpit fighter", although as a single seater it dispensed with the so-called "pulpit" which carried the observer in front of the propeller.


One common design feature between the new SPAD V and the A.2 was the use of a single-bay biplane wing with additional light struts mounted mid bay at the point of junction of the flying and landing wires. This design simplified interstrut arrangement and reduced flying wire vibration, reducing drag. The fuselage was of a standard construction, consisting of a wooden frame covered with fabric, while the forward part was covered with steel sheeting. A .303 Vickers machine gun was installed above the engine, synchronized to fire through the propeller arc. The prototype was also fitted with a large spinner, to be abandoned later.

SPAD test pilot Bequet flew the SPAD V for the first time in April 1916.[2] Flight testing revealed excellent maximum speed (192 km/h, 119 mph) and climb rate (4.5 min to 2,000 m or 6,500 ft). The airframe's sound construction also enabled remarkable diving performance. In comparison, the Nieuport sesquiplane fighters that equipped a large part of the fighter units could occasionally shed a lower wings in steep power on dive as a result of having a single spar in the lower wing. The combination of high speed and good diving ability promised to give Allied pilots the initiative to engage or leave combat. If the new fighter was a rugged and stable shooting platform, some pilots regretted its lack of maneuverability, especially when compared to lighter types such as the Nieuport 17.

In the face of such performance, an initial production contract was made on 10 May 1916, calling for 268 machines, to be designated SPAD VII C.1 (C.1, from avion de chasse in French, indicating the aircraft was a single-seat fighter).[2]

Early production aircraft suffered from a number of defects which took some time to solve and limited the delivery rate to units. While a few SPADs arrived to frontline units as early as August 1916, large numbers would only begin to appear in the first months of 1917. Among the problems encountered were problems with the Hispano-Suiza engine. In hot weather, the engine was prone to overheating. In cold weather, the engine would not warm up. Various field modifications were used to counter the problem, including cutting extra holes in the metal sheeting to provide more air flow over the engine. On the production lines, the cowling opening was first enlarged and eventually redesigned with vertical shutters to solve both problems. The engine mount also proved too weak and reinforcements were designed to counter that.[3] Early production aircraft also had two ammunition drums: one for normal rounds and the other for empty ones. This system was prone to jamming and was only solved when Prideaux disintegrating ammo links were introduced.

With the initial teething problems solved, several subcontractors began producing the SPAD VII under license in order to supply frontline units with the fighter. The subcontractors were the firms Grémont, Janoir, Kellner et Fils, de Marçay, Société d'Etudes Aéronautiques, Régy and Sommer. It was not, however, until February 1917 that the initial batch of 268 aircraft was delivered.[4] In early 1917, an improved version of the engine developing 180 hp, the Hispano-Suiza 8Ab, was made available. This new powerplant provided the SPAD VII with even better performance, the top speed increasing from 192 km/h (119 mph) to 208 km/h (129 mph). The new engine gradually became the standard powerplant for the SPAD VII and by April 1917, all newly produced aircraft were equipped with it.

Variants and experiments

Numerous experiments were made with new equipment or engines in the hope of further improving the SPAD VII's performance. A Renault V8 150 hp powerplant was tested but required some major redesign and the resulting performance was not considered worthwhile. A supercharged Hispano-Suiza engine was also tested, and also failed to improve performance by any significant proportion. It also appears different wing profiles were tested; the results of these experiments is not very clear but they were not incorporated in production models. One field modification was applied in Czechoslovakia after the war when the undercarriage struts of one S.VII were faired over in an attempt to reduce drag and increase maximum speed.

Very early in the development of the S.VII, the British RFC and RNAS had shown an interest in the new fighter. An initial order for 30 aircraft was made but difficulties in early production were such that the delivery rate was very low, production being barely enough for French units alone. As the RFC was encountering an increasing opposition over the Front, measures were taken to set up production of the S.VII in the United Kingdom. Blériot & SPAD Aircraft Works and Mann, Egerton & Co. Ltd. were supplied with plans and sample aircraft and ordered to initiate production as soon as possible.

The first British-built S.VII was flown and tested in April 1917, and the first aircraft was reported to have performance equal to that of French models. There were however differences between the two types. The British were worried about the light armament of the S.VII: most German fighters were now carrying two guns and various experiments were made to fit an extra machine gun on the S.VII. One aircraft was fitted with an extra Lewis machine gun on the top wing and tested at Martlesham Heath in May 1917, while front line units also made field modifications with Foster mounts as used on the S.E.5. The resulting drop in performance was considered too drastic for the installation to become standard, and most SPAD S.VIIs continued to fly with a single Vickers.

Other distinguishing features of the British-built S.VIIs included a gun fairing and a solid cowling access panel. The gun fairing partially covered the gun and extended rearwards, replacing the windshield. This, however, seriously limited pilot vision to the front and, though it was retained on training aircraft, standing orders were given to have it removed on aircraft destined to front line units in France. The bulged engine access panel located under the exhaust pipe on British models was made of a solid sheet of metal, in place of the louvered panel fitted on French production models. Some British SPADs were also fitted with small spinners on the prop hub.

It quickly became apparent that the British production lines of the S.VII had lower quality standards than their French counterparts, resulting in aircraft with lower performances and handling. Poor fabric sewing, fragile tailskids and radiators of insufficient effectiveness plagued the British SPADs. Photographic evidence shows that a number of British SPADs had the cylinder banks fairings, or even the entire upper engine cowling, cut out to compensate for the ill-functioning radiators. Most British S.VIIs were used for training purposes, front line units being equipped with French-built models. After some 220 aircraft had been produced, British production of the S.VII was halted in favour of better British types that were becoming available.

In a similar fashion, Russia produced approximately 100 S.VIIs under license in 1917 at the Dux factory in Moscow, with engines supplied by France. It would appear the engines were often used and/or of lower quality, and that the Dux used lower-grade material in building the airframes. This combination of extra weight and weaker powerplant resulted in aircraft with significantly lowered performance.

The total number of aircraft produced seems uncertain, sources varying from 3,825 to some 5,600 SPAD S.VIIs built in France, 220 in the United Kingdom and approximately 100 in Russia.

The SPAD XII was an extrapolation of the S.VII, equipped with a 37 mm cannon. However, it required a fair amount of redesign and should be considered as a distinct aircraft rather than just a variant of the S.VII.

Operational history


An original SPAD S.VII at the Musée de l'Air et de l'Espace, once flown by Georges Guynemer in World War I

The French Aviation Militaire had been sufficiently impressed by the performance of the SPAD V prototype to order a batch of 268 aircraft on 10 May 1916. However, teething problems soon appeared and it would be several months before the SPAD VII would serve in significant numbers on the front, the last aircraft of the initial batch being delivered in February 1917.

In spite of these delays, some aircraft were delivered to frontline units as early as August 1916, to complement to Nieuport fighters. At this date, Allied designs such as the Nieuport 11 /17 and D.H.2 had been able to regain air superiority after the infamous "Fokker scourge" episode but, by the second half of 1916, new types of more powerful German fighters threatened to give Germany mastery of the skies again. In this context, it was hoped the new SPAD VII would be able to fight the modern German fighters on equal terms. The first aircraft delivered to a frontline unit was S.112 flown by Lt Sauvage of N.65, followed by S.113, assigned to Georges Guynemer of N.3. Guynemer was already credited with 15 victories at the time, but it was Armand Pinsard of N.26 who was the first to score an aerial victory on 26 August, flying S.122.

The initial introduction of the SPAD VII was therefore not enough to change the balance of the air war but it allowed both pilots and mechanics to familiarize themselves with the new fighter. Quite a few pilots thought the SPAD lacked maneuverability and some even reverted to the nimble Nieuports they were accustomed to while waiting for the aircraft to become more reliable, but most were quick to realize its combat potential. René Fonck, France's leading ace of World War I with 75 victories, said of the introduction of the SPAD that "it completely changed the face of aerial warfare." New tactics based primarily on speed were developed to take advantage of the SPAD's power, and to compensate for its relative lack of maneuverability. The aircraft's capacity to dive safely up to 400 km/h (249 mph) was a superb advantage that permitted to leave combat rapidly without fear of pursuit if the situation demanded it.

With early problems solved and production shared between several manufacturers, the SPAD VII finally began appearing in large numbers at the front in early 1917. By mid 1917, some 500 SPADs were in front-line service, having almost completely replaced the Nieuport. The aircraft was a solid performer in combat and could cope with most of its opponents. It also acquired a reputation of being capable of absorbing far more damage than its flimsier predecessors. Its principal shortcoming was its one machine gun armament at a time when most opposition fighters were equipped with two.

The SPAD VII was gradually replaced by the improved SPAD XIII in front line units but remained an important asset of the Aviation Militaire throughout the war, being latterly used as a trainer aircraft. It was also used as the standard pilot certificate test aircraft until 1928.

Foreign Service

SPAD S.VII at the National Museum of the US Air Force

Allied air services were also equipped with the new fighter. The Royal Flying Corps was the first foreign service to receive the SPAD VII, although in spite of initial enthusiasm for the type only two squadrons (19 and 23 Squadrons) used it on the Western Front. In addition, fighter schools in the United-Kingdom and 30 Squadron in Mesopotamia also received SPADs. British-built SPADs were generally used in the training units and in the Middle East, while fighting units in France used superior French-built models. The SPAD VII was replaced by the Sopwith Dolphin in 19 Squadron in January 1918 – but No. 23 Squadron kept theirs until they also received Dolphins in April (incidentally becoming perhaps the last squadron to use S.VIIs in France).

Russia received a batch of 43 aircraft in spring 1917 which were successfully used and supplemented by approximately 100 SPAD VII manufactured by the Dux factory under license.

Ironically another early user of the SPAD VII was Germany. Several SPAD VIIs were captured intact by German and Austro-Hungarian forces and were reportedly used both in combat and for training. Rudolph Windisch of Jasta 66 flew a SPAD VII in combat with German markings. That any aerial victories were obtained by German pilots flying SPADs remains unknown.

Belgium equipped the 5e Escadrille (later renamed 10e Escadrille) with the S.VII. Edmond Thieffry was probably the most famous Belgian pilot to fly the type, most other aces preferring the Hanriot HD.1.

Italy began using the SPAD VII in March 1917, nine Squadriglia being equipped with it. As was the case in other air services, pilots accustomed to more maneuverable mounts had a difficult time adapting to the new fighter, and again some reverted to the Nieuport 24/27 or the Hanriot HD.1, which eventually became the standard Italian Fighter. Francesco Baracca, Italy's leading ace, was delighted with the new model and his personal aircraft is still preserved today in Italy.

When America entered the war in 1917, an order for 189 SPAD VIIs was placed for the United States Army Air Service of the American Expeditionary Force. The first aircraft were delivered in December 1917. Most were used as advanced trainers to prepare the American pilots for the SPAD XIII.

After the war, surplus SPAD VIIs were used into the late 1920s by numerous countries, including Brazil, Czechoslovakia, Finland, Greece, Japan, the Netherlands, Peru, Poland, Portugal, Romania, Siam, the United States and Yugoslavia.


Czechoslovakian SPAD S.VII

Ernesto Cabruna SPAD SVII

(Two aircraft)
(70–80 aircraft)
(One aircraft)
(Two aircraft)
 Russian Empire
 Soviet Union
 Siam (Thailand)
File:Ukraine1918.png Ukraine (two aircraft)
 United Kingdom
(185 aircraft)
United States
 Kingdom of Yugoslavia


SPAD S.VII in the Praha-Kbely Airport

Fulco Ruffo di Calabria SPAD S.VII

  • SPAD VII (s/n 103) (B9913) is on display at the Virginia Aviation Museum. It was one of 19 British made SPADS built in 1917 by Mann Egerton & Co. Ltd.. It was fully restored in 1973.[5]
  • SPAD VII (S.254) is on display at the Musée de l'Air et de l'Espace near Paris, France, once flown by Georges Guynemer in World War I.
  • SPAD VII.c.1 (B9916) is on display at the San Diego Air & Space Museum. Built at the Mann, Edgerton and Co. of Norwich, England in 1917, it was one of a batch shipped to the United States for use as a trainer. The aircraft is fully restored in 1990 and is 95% original.
  • SPAD VII is on display at the Letecke Muzeum at Kbely, a northeastern suburb of Prague, Czech Republic, flown post-World War I in Czechoslovak Air Force, in the Západočeský aeroklub (West-Bohemian Aero Club).

Specifications (S.VII)

Data from Sharpe 2000, p. 269.

General characteristics

  • Crew: One
  • Length: 6.08 m (19 ft 11 in)
  • Wingspan: 7.81 m (25 ft 8 in)
  • Height: 2.20 m (7 ft 2 in)
  • Wing area: 17.85 m² (192 ft²)
  • Empty weight: 510 kg (1,124 lb)
  • Max. takeoff weight: 740 kg (1,632 lb)
  • Powerplant: 1 × Hispano-Suiza 8Aa inline engine, 112 kW (150 hp)


  • Maximum speed: 192 km/h (119 mph)
  • Range: 360 km (225 mi)
  • Service ceiling: 5,335 m (17,500 ft)
  • Time to altitude: 4.5 min to 2,000 m (6,560 ft)Armament

    See also


    1. Sharpe 2000, p. 270.
    2. 2.0 2.1 Bruce 1981, p. 59.
    3. Bruce 1981, p. 61.
    4. Bruce 1981, p. 62.
    5. "Historic Aircraft, p. 5." Virginia Aircraft Museum. Retrieved: 14 February 2011.
    6. "Factsheets: SPAD VII". National Museum of the United States Air Force. Retrieved: 26 February 2012.
    7. [1] Italian Air Force Museum Retrieved: 6 January 2013.
    8. [2] Italian Air Force Museum Retrieved: 6 January 2013.
    • Bordes, Gerard. "SPAD." Mach 1, L'encyclopédie de l'Aviation, Volume 8. Paris: Atlas, 1981, pp. 2173–2187.
    • Bruce, J.M. "The First Fighting SPADs". Air Enthusiast, Issue 15, April–July 1981, pp. 58–77. Bromley, Kent: Pilot Press. ISSN 0143-5450.
    • Connors, John F., Don Greer and Perry Manley. SPAD Fighters in Action (Aircraft in Action No. 93). Carrollton, Texas: Squadron-Signal Publications, 1989. ISBN 0-89747-217-9.
    • Crosby, Francis. A Handbook of Fighter Aircraft. London: Hermes House, 2003. ISBN 1-84309-444-4.
    • Sharpe, Michael. Biplanes, Triplanes, and Seaplanes. London: Friedman/Fairfax Books, 2000. ISBN 1-58663-300-7.
    • United States Air Force Museum Guidebook. Wright-Patterson AFB, Ohio: Air Force Museum Foundation, 1975.

    External links

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