|14"/50 caliber railway gun|
Firing from Thierville-sur-Meuse, NW of Verdun
|Place of origin||United States|
|In service||1918 - 1920s|
|Used by||United States|
|Wars||World War I|
|Manufacturer||Baldwin Locomotive Works (train)|
|Number built||Mk I : 11|
Mk II : 2
|Variants||Mk I, Mk II|
|Barrel length||700 inches (17.780 m) (50 calibers)|
|Shell||1,400 pounds (640 kg)|
|Caliber||14-inch (355.6 mm)|
|Recoil||hydro - pneumatic + spring, 44 inches (1,120 mm)|
|Carriage||railway truck, 12 or 20 axles|
|Elevation||0° - 43°|
|Traverse||2.5° L & R|
|Muzzle velocity||2,800 feet per second (853 m/s)|
|Maximum range||42,000 yards (38,000 m) @ 43°|
In 1917 the Allies were losing an artillery duel against heavy German guns along the Flanders coast in Belgium, and the important French Channel port of Dunkirk was being shelled by 38 cm German guns sited in Belgium at a range of over 24 miles (39 km). There was also a need for the Allies to bombard strategic targets in the German rear areas to hinder German capability to stage attacks. The largest Allied guns in the area were British 12-inch Mk X guns which were outranged.
Upon its entry into the war, the US chose its largest and longest-ranged available naval gun to fill the gap - the 14"/50 caliber Mk 4 gun with a muzzle velocity of 2800 feet per second. The new 16-inch gun would have been preferable, but it was not yet available in numbers; spare 14-inch guns kept for the active fleet were used instead.
Baldwin Locomotive Works delivered five trains for the United States Navy during April and May 1918. Each train transported and supported a 14"/50 caliber Mk 4 gun mounted on a rail carriage with four 6-wheel bogies.
Arrival in France
There was some doubt as to whether the Flanders coast and French Channel ports were now safe Allied ports following the German Spring offensive successes in March and April 1918 which brought those areas within German artillery and attack range. The guns were therefore diverted from the British zone in the north to further south, to the port of St. Nazaire, to avoid the risk of having such valuable assets captured or destroyed.
Each battery composed of a locomotive, gun car, ammunition cars, supporting equipment cars, and accommodation cars for the crew was under the command of a United States Navy lieutenant, and under overall command of Rear Admiral Charles Peshall Plunkett. After delivery by ship, these trains were assembled in St. Nazaire in August.
Before a gun arrived at a firing position, a curved length of track was laid at a position calculated suitable for firing at a specific target, and a pit 9 feet deep involving the removal of 103 cubic yards of earth was dug between the rails into which the gun recoiled 44 inches. Supports were also embedded in this pit connected to the gun mounting, to transmit remaining recoil energy directly to the ground and avoid placing excessive vertical strain on the gun car (and, through it, the track) and prevent it from moving backwards. In fact, by late 1918 the French had already constructed many such curved spurs (épis) for their own guns and hence the US guns were often able to re-use these.
The gun car was positioned over the pit, the wheels were locked and the platform was locked into position with gun mount and car's weight shifted from the trucks (bogies) directly to the ground by jacks and lifting screws. The gun could elevate up to 43° which gave it a maximum range of 42,000 yards (23.8 miles/38.4 km), and could be traversed 2.5° left and right of center. Any greater change of direction required the gun to be moved forward or backward along its curved track and a new recoil pit dug. The gun used the standard naval gun mounting and recoil system, with the addition of a pneumatic system to assist the runout springs to return the gun to firing position after recoil at the higher maximum elevation of 43° compared to maximum 30° in naval use.
A major disadvantage of the Mark I mount was that the weight was distributed forward, placing weight on the leading axles that was above the normally allowable weight for French railways and also caused axle bearings to overheat at any speed over 5 - 10 mph. The armored enclosed gun house lacked ventilation and caused condensation to form which promoted rusting. The necessity to excavate a recoil pit was also not acceptable as a long-term solution of recoil control. Hence Mark I, while functioning as designed, was seen as only a compromise measure necessitated by wartime time constraints.
The guns served to support General Pershing's army offensive in the Meuse-Argonne sector of the Western Front in France. They operated as single-gun batteries designated Battery 1 - Battery 5. Battery 2 commanded by Lieutenant (JG) E D Duckett, US Navy, had the distinction of being the first all-US gun (crew, gun and ammunition) to fire in action on the Western Front. On 6 September 1918 they fired from the forest of Compiegne at the important German railway center of Tergnier in support of an Allied attack.
The guns were used to target key infrastructure deep behind the German lines such as railway junctions and other lines of communication and concentration, typically only opening fire after an Allied attack had begun to avoid giving the Germans any warning of Allied intentions.
They fired a total of 782 shells on 25 separate active days on the Western Front at ranges between 27 and 36 kilometers. This equated to an average of 156 rounds per gun, which was approximately half the 300 rounds expected life of these guns before they would need refurbishment. The guns were only fired for specific strategic purposes to conserve barrel life, with smaller guns being used whenever possible. Hence on many days they remained inactive or were being moved.
The last shot was fired by Battery 4 at 10:57:30 am on 11 November 1918, timed to land just before the scheduled Armistice at 11 am.
Mark I Army railway mount
The US Army ordered 3 units identical to the Navy Mark I mountings in May 1918 and another 3 in July 1918, also from Baldwin Locomotive Works. They were all completed by 20 September 1918 but the war ended before they were required to be shipped to France.
The new Mark II gun car developed during 1918 carried the same 14"/50 caliber Mk 4 gun but addressed the problem areas : it dispensed with the armoured gun house, with gunners working in the open; the weight was more evenly spread over 20 axles instead of 12; the French system of rolling recoil was adopted, in which the gun was mounted higher to allow full recoil at maximum elevation without striking the ground and the car rolled back 30–40 feet after firing to absorb remaining recoil. This made it possible to fire the gun along any part of its curved track without any prior preparation, with elevation up to 40°. After firing the gun car used a winch mounted at the front, connected to a strong point in the ground in front, to pull itself back to its firing position. World War I ended before Mk II entered service, and it was used for coastal defense in the US.
- 14-inch M1920 railway gun US successor
- List of railway artillery
- 14"/50 caliber gun: gun description and US Navy service
Weapons of comparable role, performance and era
- BL 14 inch Railway Gun: British equivalent
Notes and references
- 5 Mk I units were supplied to the Navy and were in action in France in 1918; 6 Mk I units were supplied to the Army late in 1918 and were not sent to France; 5 Mk II units were ordered in October 1918, 3 were cancelled, and the first of the 2 completed was tested in August 1919. Earle 1920, pages 192, 197-200
- Breck (1922), p. 3
- Breck (1922), pp. 3–4
- "Though it had been planned to ship the guns to the British transportation centers [in the northern Channel ports], conditions in France had so changed, owing to the threatening of the Channel ports by the Germans, that this plan seemed too risky, and Gen Pershing was therefore consulted as to the cooperation of the batteries with the [US] Army [i.e. in the French frontline sectors]. Gen. Pershing replied on May 23, requesting shipment... to France without delay". See Breck (1922), p. 7
- Many, Seymour B. (April 1965). "He Made No Complaint". United States Naval Institute Proceedings. p. 53.
- Miller 1921, page 330
- The pit was not required when firing at elevations up to 15°, where remaining recoil energy was absorbed by allowing the gun car to roll backwards until stopped by its brakes; but as the guns were never fired at the relatively short ranges achieved with such low elevation this was irrelevant. See Breck (1922), pp. 23–24
- Breck (1922), p. 47
- Breck (1922), pp. 23–26
- Miller (1921) discusses these problem areas in detail, pp. 331–333
- Breck (1922), p. 12
- Breck (1922), p. 18
- Breck (1922), pp. 14–15
- Breck (1922), p. 14
- Earle 1920, pages 196-198
- Breck, Edward (1922). The United States naval railway batteries in France. Department of the Navy, Office of Naval Records and Library. Washington, D.C.: Government Printing Office. http://www.archive.org/details/unitedstatesnava00unitrich.
- Ralph Earle, Editor (1920), "Navy Ordnance Activities. World War 1917-1918". Government Printing Office, Washington
- Miller, Harry W. (1921). Railway Artillery: A Report on the Characteristics, Scope of Utility, Etc., of Railway Artillery, Volume I. Department of the Army, Ordnance Department. Washington, D.C.: Government Printing Office. http://www.archive.org/details/railwayartiller00deptgoog.
- Willcox, Cornélis De Witt, and Edwin Roy Stuart (1918): The International Military Digest Annual for 1917. Cumulative Digest Corporation, New York. Pp. 169-170.
- TM 9-2300 standard artillery and fire control material. dated 1944
|Wikimedia Commons has media related to US 14 inch 50 caliber railway gun.|
- "Navy 14 Inch Railway Guns in France, 1918" original film of 14 inch railroad naval cannon in action in WW1.
- "Battleships on Wheels" Popular Science Monthly, January 1928, pp. 16–18/123-125, author was the US Navy admiral in charge of WW1 14 inch naval railroad cannon program.
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