Author: Andrew Hills

United States of America (1916)
Armored Car – None Built

In 1916, there was one war sucking up all of the attention – the war in Europe, which was seeing the largest European empires battling it out at extreme costs. The USA did not enter the war until April 1917, and, in the meantime, already had a military challenge of its own to contend with – a revolution in Mexico which led to numerous border raids by armed forces. Some armored cars were deployed by the US Army to the border, but one man in southern Alabama also had an idea. His name was Erasmus Blacksher and his vehicle would allow for an armored car with improved mobility and protection over existing designs.

The Man

The man behind this invention was Erasmus Manford Blacksher. Erasmus was a “farmer & financier” from Brewton, a small town in southern Alabama. Born on 4th August 1878 in Boykin, Alabama to Uriah and Martha Blacksher, he was born into a wealthy family, one which had made its money in the timber industry. In 1911, he was a wealthy man and built a grand house called ‘Marinia’ on his family estate known as ‘Alco’. In records, he was giving his occupation as a farmer throughout this time and even beyond WW1. During that war, he, like millions of other men, was required to register for the draft, and he did so in September 1918.

In 1929, following the stock market crash, Blaskher’s family fortunes dwindled, but they still had some notable assets in the area. He died on 23rd April 1957, aged 78 and is buried in Union Cemetery, Brewton.

Between 1915 and 1930, he filed patents for an improved rail tie (1915), an improved airplane (1918), a safety device for an airplane (1930), and this armored automobile. The automobile was filed first in the United states in September 1916, which was then followed by a filing in Canada in July 1917.

Design

Layout

The design of Blacksher’s armored car was a combination of both conventional and unconventional. Conventional in form, unconventional in function and design. Based around a simple four wheeled chassis, the drawing does not show anything more than a simple rectangular vehicular frame and four wheels. However, he was clear in the patent that it should have had some form of steering, although omitted any details of it. There is no mention of any form of propulsion, but, as it was an automobile, it had to be powered by some form of motor or engine. Just as there is no mention of the form of propulsion, there is also no mention of where such an engine might have been placed or what sort of drive train might have been involved. The only hint are the air vents on the roof.

With a body shape encompassing and completely enclosing the chassis and these 4 main wheels, the vehicle, in plan view, had a distinctive pill-shape with parallel sides and a “rounded contour… modeled as closely as consistent with the shell of a tortoise”. This was the key feature of the patent, which Blacksher described as a “protective casing”. The only large features on this shell was a large rectangular door on the side. Only one side is shown, but another one on the other side would have been a convenient feature for the design.

This armored shell was supported by a series of springs placed all around the body of the vehicle in order to allow for movement of the body and yielding when hit by enemy fire. Each corner of the chassis had a spring connected to the shell, with two more on each side for a total of 8 large springs.

Only the very top of the vehicle was flat in profile, where the upwards curving sides met. Centrally, within the roof of the vehicle, was a fully revolving turret in the shape of “an inverted cup” with a conical or tapering top. The bottom lip of the turret armor was overlapped by the armored body so there were no gaps for bullets to get through. One or more turrets could be added as needed, but Blacksher showed a design with just this single centrally-positioned turret.

Turret

The turret was meant to be supported on wheels mounted to a ring within the turret itself and ran along an annular track. Rotated by a gear wheel, the turret is shown in the drawing to be armed with a single gun. On one side of the turret (it is unclear whether it is in front or behind it) are a couple of funnels, presumably to draw air inside.

These would therefore appear to be what Blacksher described as “air chutes” which were to be “… of light metal so that, if struck by a bullet or the like, they will be pierced without damaging the same so far as their function of ventilation is concerned”. Unfortunately, the positioning and height of them is such that they would likely interfere with the traversing of the main gun.

A third projection is also visible, this time from the apex of the roof of the turret. This projection was a mirrored periscope for observation purposes rather than something for ventilation.

Automotive

The armored body of the vehicle was carried separate to the vehicle itself by means of 6 wheels, with two on each side slightly inwards of the chassis wheels, and one more on the front and back. Arranged around the outside of the armored body were also 6 rollers (3 at each end). These were fitted with springs as well and could move vertically to accommodate undulations in the ground. Arranged in this way, the vehicle would not ground out when traversing rough ground.

No engine or even steering system was shown in the plan view, leaving just a plain and simple rectangular frame for the vehicle. In effect, what Blacksher provided therefore was not a specific chassis design but a template on which to mount such an armored body.

In other words, this patent was concerned with the provision of an armored body and turret which could potentially be made and then fitted over a regular truck chassis. This idea would match the location of those air-chutes on the roof, as they would indicate an engine potentially underneath them, suggesting a conventional style of truck layout inside.

Armament

No armament is directly indicated in terms of what gun or guns and of what type or size should be mounted. Instead, Blacksher simply provided an impression of the vehicle mounting a single gun inside this turret.

A cross-sectional view of the vehicle and turret provided another view of the gun and an indication that it was not to be a machine gun but potentially a small cannon mounted to a framework and supported from the floor of the ‘cup’ in which the turret was formed.

Employment and Conclusion

Although Blacksher’s vehicle was never built, it could, at first glance, be supposed to be some idea for service in WW1. Designed in 1916, this would certainly be a possibility, but there is another option as well and one hinted at by the presence of the cacti in the background of his illustration – the US southern border with Mexico.

In 1910, Mexico fell into a civil war, and due to the insecurity which resulted, US armed forces were deployed to the border area to help provide security and prevent Mexican forces from crossing over. There were numerous skirmishes between American and various Mexican rebel groups, and in 1916, these culminated in the famous raid by Pancho Villa into New Mexico, where he attacked the town of Columbus in March. Despite being repulsed by a US Cavalry force, the city was virtually destroyed. It was not the last raid either, as Villa’s forces searched for supplies. In April 1916, they crossed into Texas and raided the towns of Glenn Springs and Boquillas.

Incensed at this incursion, the US Army crossed over into Mexico under the command of General J. Pershing, as part of what was known as the ‘Punitive Expedition’. Operations over the border to secure it continued through 1918, and, although Villa was never caught by US forces, this conflict was a small taste of a mobile hit and run kind of warfare which was becoming possible thanks not only to horses but to trucks – some of which were staring to be armored.

It is not hard to see, in light of this conflict on the border, what sort of inspirations might have attracted Blacksher. All the design needed normal truck, a simple armored body and a degree of mobility to fight border banditry. Indeed, in this terrain, perhaps more than the ground of the Western Front in France and Belgium, these armored cars were more capable of off-road movement. At the time Blacksher submitted his patent, the US armed forces were not even involved in WW1, but they were engaged in this operation in the south.

US forces would eventually go to war in Europe and Blacksher got his draft papers completed in 1918. The war ended before he got called up and never got the chance to either see war directly for himself, or see his invention or something similar in action.

Sources

Blackshear, P. (1954). Blacksheariana. Perry Lynnfield Blackshear, Atlanta, Georgira, USA.
Canadian Patent CA180017, Armoured Automobile, filed 20th July 1917, granted 30th October 1917.
Canadian Patent CA193774, Aeroplane. Filed 9th December 1918, granted 11th November 1919.
French Patent FR501168, Aeroplane, filed 30th June 1919, granted 19th January 1920, published 6th April 1920.
Grimes, L. 2011. Images of America; Brewton and East Brewton. Arcadia Publishing, Charleston, USA.
Swiss Patent CH93150, Luftfahrzeug mit vom motor aus autreibbaren stabilisation propellern, filed 13th June 1919, granted 16th February 1922.
The Brewton Standard, Blacksher’s Haunter Legend lives on. 3rd October 2018.
https://www.brewtonstandard.com/2018/10/03/blackshers-haunted-legend-lives-on/
The Brewton Standard. More about the Blacksher’s, 7th April 2004.
https://www.brewtonstandard.com/2004/04/07/more-about-the-blackshers/
US Census 1920, enumeration district 87, Supervisor’s District 2, Sheet 4A.
US Census 1930, enumeration district 27-6, Supervisor District 10, Sheet 23A.
US Draft Registration Card, Erasmus Manford Blacksher, 12th September 1918.
US Patent US1229869, Armored Automobile, filed 26th September 1916, granted 12th June 1917.
US Patent US1147321, Combination cement-tie and rail-clamping means, filed 25th January 1915, granted 20th July 1915.
US Patent US1789033, Safety Appliance for Airplanes, filed 18th February 1930, granted 13th January 1931.
Zaloga, S. Early US Armour: 1915-1940. Osprey Publishing, UK.

United States of America (1918)
Tank – None Built

At the start of 1918, WW1 was by no means waning in terms of combat or intensity. The war had, to that point, been characterized in the public mindset by the slaughter in Belgium and France. This picture was one of trench lines of men just a few hundred meters apart, unable to make the breakthrough they needed thanks to defenses in depth, barbed wire, and the firepower of the modern machine gun. Tanks, as unveiled on the battlefield in September 1916, had begun to make a real difference in the war. The armies of Germany, Great Britain, France, Austria-Hungary, and Italy were tired by 1918. Russia had dropped out of the war, but the United States, a relatively youthful imperial power, was coming to the war in its place, having declared war in April 1917. Despite this, the US forces headed for Europe did not get to see combat for over a year, first seeing action at Cantigny in May 1918. That year was the first year the US forces got their first tanks too, but those did not get used until the last few weeks of the shooting war, in September 1918. There was therefore a gap between the first tanks of 1916, America’s war entry, and their first tank use. A few inventors and designers came to this American tank void. Some of them had an engineering background, or a military background, or both. One of them, Frank Lauterbur, designed machines relating to the mixing and baking of bread dough – he too designed a tank. A tank more like a rolling pin than one of 1916, but undoubtedly an armored rolling weapon of war.

Mr. X.

The man behind this machine was Francis ‘Frank’ Xavier Lauterbur from the town of Sidney, Ohio, USA. Lauterbur was born in August 1887 at Fort Laramaie in Ohio, to Paul (b.1855, d.1932) and Margarettia ‘Margaret’ (neé Hillans) Lauterbur (b.1859, d.1925). This meant that, when he filed his patent for his ‘Tractor’ on 6th February 1918, he was around 31 years old, putting him at the upper end of the age group liable for conscription to go and fight in the war.*

(*The first conscription under the Selective Service Act of 1917 was 5th June 1917 for all men aged between 21 and 31 – he would have been 29 or 30 years old at the time).

Lauterbur died in October 1932, aged just 45 years old, leaving his wife Wilhelmina (b.1900, d. 1970). Between 1918 and when he passed away in 1932, Lauterbur left a legacy of over 50 patents for machines relating to the mixing of dough, involving variously beaters and clutches, variable speed rotating members, sieves and sifting, weighing and blending. Whilst the flour mixing or bread industry might not seem like a likely source from which a tank might originate, the mechanisms designed for transmitting torque to a mixer, belts, pulleys, and drive are not small things in engineering terms. Such knowledge and skills in engineering relatively mundane or non-military equipment certainly would have left Lauterbur with more than a passing knowledge of technology when he designed this vehicle. His intention was to produce a “small ‘tank’ for military purposes and adapted to operate either as a unicycle or as a tractor”.

The Rolling Pin

The design was to be built around the concept of a rolling cylinder, like a rolling pin. This cylinder would be either a pair of what he called “tractor wheels” or, in extended form, made from four or more of these wheels. They were not tractor wheels in the sense of a normal farmer’s tractor, but wide hollow wheels running around the outside of the cylinder on low-friction bearings and to the surface of which were a series of 3 circumferential rows of spikes. These spikes formed the tractive element of the wheels, as they would be stabbed into the ground during travel to provide purchase on whatever surface it was passing over.

This would also, therefore, mean the vehicle would cause potential damage to roads or other fixed infrastructure on route towards a battle, something which would be a problem for any conventional forces which may be following.

The vehicle itself was this simple cylinder about which the wheels rotated and the rounded ends both featured a single hinged door with a horizontal slot in it from which the crew could see out. A further such slot was located in the center of the cylinder, facing forwards, and was situated directly between the center two of the tractor wheels.

Atop the machine was a single large periscope reminiscent of an alpine horn more than anything from a submarine and which formed the primary means of observation for the vehicle. Whilst this would provide a theoretical 360º of view for the man operating it, it would obviously also limit observation by other members of the crew to those three slots already mentioned. Within those slots too were to be machine guns, forming the primary armament, so they would already be quite occupied with combat as well as being a good distance from the man at the bottom of the telescope, presumably the commander, to tell them what was going on, making internal communications and direction more difficult. Assuming one commander using that periscope and one man per machine gun, this would be 4 men and, adding in a dedicated driver, would mean not less than 5 men would be required to operate such a machine.

Behind the rolling pin was a trailing wheel arrangement to provide support. This wheel was fastened to a tail coming from the back of the cylinder but attached to a pair of separately rotating collars, narrower than the wheels but wider than the cylinder. These collars could therefore rotate freely without blocking the weapons or observation devices, forming a hollow in the tail to clear the periscope and allow controlled rotation of the tail around the machine.

Mobility

The engine for propelling this machine was to be located low down in the central part of it, which was also roughly where the periscope was as well. Drive was transmitted via a shaft to a large gear wheel, which was connected in turn to a smaller gear wheel via a drive chain around a small rim projecting from the large gear to the small one and holding them a fixed distance apart. This connection on the shaft of the large gear was also a pivot point around which the smaller gear could move via rotation of this arm. Thus, the drive shaft could still be rotating in the same direction and could still be driving the big gear and small gear in turn, but with the arm pivoted behind the big gear, it would cause drive to imparted backwards upon the wheel. By this method, no complex gearing was needed from the shaft or gearbox and steering or rotating the vehicle on the spot could be achieved by switching from forward to rear motion on an individual wheel or side of the machine.

This small arrangement by which an arm could be rotated around a center-pivot point was a key feature of the design not only for steering via these gears, but also for obstacle climbing. This function was achieved with a much bigger rotating arm, namely the ‘arm’ which was the tail of the machine. More than simply a trailing wheel for stabilization, this whole arm (or in the case of a wide machine, multiple arms) could be rotated. As soon as this tail was rotated, the entirety of the vehicle would be borne on its wheels in the manner of what Lauterbur described perhaps erroneously as a “unicycle”. With the tail rotating, the fact that it was hollow allowed it to go over and around the periscope without striking it and then continue its rotation to the front of the vehicle.

With the tail wheels moved forwards, the action allowed the vehicle to exert pressure down onto an obstacle to improve the climbing and crossing ability of the machine. Likewise, it would also allow the vehicle to rapidly change direction.

Conclusion

Lauterbur certainly put some of his knowledge of gearing systems to work within the design. Multiple overlapping rotating elements, pivots, arms, and wheels all worked together to produce a vehicle for war. Given the shape, the size, and the inherent weight, it is hard to consider how the vehicle could be powered by a single motor in a single wheel, but maybe he was more interested in the gearing and process of movement than the engine, which, afteral,l gets only a brief mention. One small engine in each wheel might have been possible but would only have served to make control harder and this was the biggest failing of the design – control.
The commander, assuming it was he using the periscope, would be directly in the way of the forward machine gunner and the driver at the same time. If he was to use the machine gun, then he would clearly not be able to operate it effectively and, if the driver was using the periscope, then the commander would have little or no vision.

The control issue gets worse the bigger the vehicle gets. Those side machine gunners would only get further from the driver and/or commander as the vehicle got bigger, the weight would increase and the width occupied by the vehicle would increase dramatically as well. All of these problems would only be magnified by the even more obvious lack of space inside the machine. Every single wheel had gearing, and there were multiple moving surfaces and gears along the entire width of the vehicle. Any fighting position would be right next to open gearing and moving machinery, creating a significant hazard for their safety. For the hapless crew in the middle, a veritable obstacle course was presented when needing to exit the vehicle by the side hatches in the event of an emergency, such as catching fire or becoming trapped.

Whatever value the vehicle might have had or offered in terms of improving the steering or moving ability of a cylindrical machine of war was outweighed by the volume of problems, technical, human, practical, and military ranged against it. Lauterbur’s machine was never built, but he appears to have done well for himself with his technical expertise better suited to the bread industry than the war. Had he not passed away before WW2, it is interesting to consider what else such a fertile mind might have created for the next great conflict.

Sources

https://www.findagrave.com/memorial/115392006/frank-x_-lauterbur
Ohio County births 1841-2003
US Census 1900, S.D. 3, E.D. 92, Sheet 7
US Census 1930, S.D. 11, E.D. 75-4, Sheet 4A
US Patent US1313095, ‘Tractor’, filed 6th February 1919, granted 12th August 1919.

United States of America (1916)
Landship – None Built

February 1916 marked one year since the formal British programme to resolve the problem of getting men across no-man’s land under cover of armor had begun. There were ideas for a variety of machines, including wheeled ones, but it was the tracks, first from Crompton and then by Tritton, which would win over ideas of wheeled armor on the battlefields of WW1.

None of this work would have been known to the common man in the street in February 1916, but the official embodiments of trying to use technology, armor, and guns to close on and destroy the enemy were equally in the common consciousness as well. The majority of these ideas would focus on wheels and the use of wheels was also seriously limited by their fundamental design. A wheel, by design, has a tiny area in contact with the ground. This can be improved by making the wheel wider and/or adding more wheels, but even a vehicle with multiple wheels will struggle to cross obstacles such as trenches and ramparts, as the climbing ability is approximately limited to a function depending on the height of the wheel. If, however, the wheel could be made not only wider but also substantially larger, then a wheeled vehicle might, perhaps, have been a solution?

Certainly, this was a regular train of thought for numerous designers of the period. One such example can be found in the pages of the February 1916 edition of the Electrical Experimenter, a popular periodical of the era. Featuring a gloriously bright and optimistic front cover of a giant machine happily crushing and/or variously shooting at the enemy, this was an eye-catching machine, resembling a giant armored motorbike more than a weapon of war. The design and ideas of the design certainly had some engineering skill within them, but the entirety of the idea was completely and utterly wrong. The tanks which appeared to the world in September 1916 would shake ideas of armor warfare in the common mind to the core and ideas like this giant wheeled contraption would, in less than a year, be little more than a rather silly and naive footnote.

Eric R. Lyon A.B. wrote several articles for the magazine. This gyro-cruiser in February 1916, and ‘Minic Atoms and their experimental formation’ was published in June 1916. He also designed a one-man electrically-operated submarine in 1917, which was at least of sensible proportions. As far as is known, he never tried to patent the design.

Layout

The basic shape of the machine was that of a motorbike, albeit one more akin to a Penny Farthing-style bicycle with a huge front wheel and smaller trailing wheel behind. Mounted onto these wheels was a huge body, with the bulk of it at the front, formed in a manner similar to that of the rounded front hull of a warship. This enormous triangular section at the front was rounded and bulbous at the base with vertical sides which then stepped-out to become even wider and formed a stepped platform onto which a series of turrets were arranged. In the center of this section was a raised platform above the level of those turrets, with a giant ‘crown’ turret on top. On top of this was a rangefinder and the entire design was overlooked by a gigantic mast arrangement projecting vertically from the back to a height well above the crown turret.

All of the machinery involved in the vehicle was contained inside and within the area occupied by the giant front wheel. The vehicle was to measure 160 feet (48.77 m) high to the rangefinder and 180 feet (54.86 m) to the top of the mast at the back. At 230 feet (70.10 m) long, the vehicle was at least proportional in its dimensions in terms of height to length, but the width was ‘just’ 86 feet (26.21 m) from side to side, meaning a rather narrow, very high, and extremely long machine. As might be suspected by a machine of such gargantuan proportions, it was going to be eye-wateringly heavy too, at 20,000 US tons (18,143.70 tonnes).

The vehicle was to operate on a pair of wheels simply because the maximum road width on which it might operate would limit the size of the wheels used. Placing wheels side by side would inherently create a wider track-width for them on the road, meaning one or more would have to be off-road all the time. Making it so that the single-width wheels were the whole ground-contact presence of the vehicle would therefore mean that a substantially larger vehicle could be used on a standard road than which could otherwise be achieved.

This also meant the wheels used could be anywhere on a road from 25 to 50 feet (7.72 to 15.24 m) wide and to ensure it would not go over the width of the road, limiting the wheel width to a far more modest 25 feet (7.72 m).

A total of 6 ‘small’ turrets surrounded the platform at the top of the hull, each fitted with a pair of large guns and surmounted by a massive turret known as the ‘crown’ turret on top of the raised section between them. This ‘crown’ turret would measure 40 feet (12.19 m) in diameter and, on top of this huge turret, was a domed cupola. This cupola or mini-turret could independently rotate and housed a wide stereoscopic-type range finder. In front of the crown turret and not shown in the drawings was to be a huge spotlight for the illumination of the enemy.

It is noteworthy that the design, as drawn and explained inside the magazine and the artwork on the cover of the magazine, were different. In the cover artwork, just 6 turrets are shown, with a single large turret at the front and the crown turret on top. A close look at the layout drawing, however, shows that there would be no space for this single central front turret, as it would be in the space occupied by the large front wheel.

Front Wheel

The front wheel is worthy of attention in its own right, not least due to its preposterous dimensions and construction. Measuring some 108 feet (32.92 m) in diameter, this was not a wheel in the conventional sense, like that of a bicycle or motorbike, rotating around a central axle. In fact, there was no axle at all. The wheel was toroidal in shape, with a heavily armored steel tyre weighing 500 US tons (453.59 tonnes) in its own right. At 25 feet (7.62 m) wide, the wheel was certainly going to help spread the load of the vehicle, but it alone was going to weigh around 10% of the total mass, at 2,000 US tons (1,814,37 tonnes). This meant that, aside from the armor, another 1,500 US tons (1,360.78 tonnes) of material made up the structure of it.

This was because the wheel was not simply a wheel, but was also the stabilization mechanism for the vehicle and formed a colossal gyroscope. The wheel itself was to be hollow and allowed for the addition of giant hollow iron balls some 15 feet (4.57 m) in diameter which were faced with non-magnetic steel. Twelve such balls, each weighing 40 US tons (36.29 tonnes), would float freely within the liquid inside the wheel, held off from contact with the sides by magnetic forces and their own buoyancy of around 10 US tons (9.07 tonnes) per ball.

With an outer diameter of 108’ (32.92 m) and an inner diameter of 50 feet (15.24 m), the volume of the torus is calculated using the formula V=(πr2)(2πR) to equal 5,353 m3. Deducting the volume of the dozen iron spheres (49.97 m3 each / 599.69 m3 total) leaves 4,753.31 m3 of space inside and this void was to be filled with fluid. The fluid initially selected was water. This volume of water would have weighed 4,753 tonnes. With 12 balls at 40 US tons (36.29 tonnes) and the armored tyre at 500 US tons (453.59 tonnes), this would have meant a total mass of 5,642 tonnes, nearly 3 times what was being proposed by Lyons in his guestimate of 2,000 US tons (1,814.37 tonnes). That gets worse when he suggests an alternative fluid filling for the wheel which…

Mercury, on top of being extremely toxic, is a liquid metal at room temperature and also 13.5 times denser (13.5 grams per milliliter) than water (1 gram per milliliter). That would mean a space of 4,753.31 m3 filled with mercury, would, aside from being a rolling ecological disaster waiting to happen, weigh 64,169 tonnes, more than 3 times the estimated complete weight for the vehicle!

The wheel, as already stated, was not to run on an axle. The space inside the wheel would be occupied by the powerplant. Instead, the wheel would be ‘attached’ to the body by a series of ball bearings running in a radial groove on the wheel so that it could rotate with the minimum of friction.

Power Plant

Little is mentioned of the power plant for the design, although a drawing in cross section was provided in the article. Located within the hull and surrounded by the wheel rotating around it, the form of power was primarily a large diesel engine producing 60,000 hp. Attached to this was a large electrical generator which could provide 40,000 hp, as well to drive the wheel via 2-speed multi-polar motors, each of which was 70 feet (71.34 m) in diameter. Drive of the wheel was provided electrically, as the torroid of the wheel was ringed in, banded by sections of magnets and non-magnetic metal, whereby the ring of the wheel was moved by the motors. This presumably would also function as the braking system for the wheel, although this was not mentioned by Lyons.

Rear Wheel

At the rear of this machine was the ‘small’ wheel, measuring just 60 feet (18.29 m) in diameter. This wheel not only assisted in balancing the machine, but also provided the steering for the machine. It was fixed to the rear part of the body, operating on a normal fixed type axle and relied upon this rear part of the vehicle to be able to move independently of the front part. Like the front wheel, this wheel was also to be clad in heavy steel armor plating and was to be bevel shaped.

Due to the weight and size of the wheel, steering of this tail section and wheel would have to be done in some means, such as hydraulic pumps or electric motors.

Performance

As usual with some of these giant vehicle ideas, the designer got a little carried away with overly optimistic performance figures and Lyon here is no exception. Lyon estimated a top speed of 60 mph (96.56 km/h) which, for a vehicle weighing several thousand tons, would be as remarkable as it is improbable on land.

Lyon calculated that rotating the giant wheel just 15 or 16 times a minute was sufficient and this is borne out by checking his math. With a diameter of 32.92 m, the radius would be 16.45 m. The circumference (2πr) of the giant wheel would therefore be 103.4 m. At 15 revolutions per minute, this means 15 x 103.4 m = 1,551 m, 1.55 km per minute, or 15 x 60 x 103.4 m per hour = 93,060 meters per hour; or 93.1 km/h, which is roughly 57.8 mph.

The motors would have had 2 speed settings, with the low speed setting for operating on steep slopes uphill or downhill and the high speed for flat hard ground.

Armament

A big vehicle is a tempting repository for the designer to install as much armament as possible and, indeed, Lyon did just that. This vehicle would truly be the giant battleship mounting a full set of no less than twelve 17-inch (431.8 mm) guns, this ludicrous armament was arranged in pairs across the six small turrets.

Each of the side turrets was clearly drawn in the cross-section, showing a pair of these guns. The ‘crown’ turret on top of the hull, however, was not armed with these huge guns. Instead, it was to use a single machine gun, not firing bullets, but something much larger. This ‘machine gun’ was effectively an enlarged version of the classical style of ‘Gatling’ gun with multiple barrels rotating and firing in turn, except that, instead of rifle-caliber barrels rotating, this weapon was to use 6-inch (152.4 mm) caliber rifles. Fired electrically, a single man would be able to operate the gun although how it, or the 17-inch (431.8 mm) were to be fed with ammunition was not addressed.

Aiming for the guns was to be addressed by means of the fire controller, working from the top of the mast in coordination with the commander in the ‘crown’ turret and the use of the rangefinder. This rangefinder was 160 feet (48.77 m) above the ground, more than high enough to see over trees and obstacles. The reason for this height is not speculated upon, but probably, coincidentally, it was almost precisely the same height as the top of the nave on a cathedral, like Beauvais in France, at 47.5 m. If nothing else, this comparison provides an indication of the ridiculous proportions for this vehicle.

Around the lower part of the hull were what appears to be some weapons as well. These are not described at all in the document. Despite this, two projections which appear to be guns project directly from the front, one about half way up the hull and the other just at the top of the rounded part of the lower hull. Three more circular features are also apparent in this lower section, around from the front to the sides of the vehicle. They may also be weapons ports but, once more, cannot be confirmed.

Armor

No armor other than ‘thick’ or ‘heavy’ is mentioned, but given that the big front wheel itself was to have 500 US tons of protection (probably for the best if it was filled with mercury), then heavy armor would be needed elsewhere. This enormous machine would be a target even the semi-literate half conscious enemy gunner might hit with zero effort, so if it was not to be destroyed very easily, then it would have needed substantial armor plating. Given all of the naval sized ammunition it would have to carry, it would also have to have a magazine of some sort. On a warship, if it was compromised, it could flood the magazine with sea water to prevent explosion. No such possibility would exist for this vehicle, so the designer would either have to accept the possibility of several thousand tons of mercury being blasted all over northern
France when his vehicle’s armor got breached, or else have provided substantially thicker armor than would otherwise be acceptable – several inches at least.

Crew

Other than a command staff of some sort operating a bridge inside the crown turret, there appears to have been little if any consideration of a crew. Whatever that crew may have been would not have been small. With 12 main guns, multiple smaller guns, a command team, probably some mechanics, drivers, spotters, ammunition handlers, etcetera to add into the count, at least a hundred men are likely to have been needed.

Conclusion

It is hard to take the design seriously or even semi-seriously. Even Lyon must have accepted, like others, that such gargantuan vehicles might make attractive and eye-catching cover art, but not practical vehicles.

For the cost in material of a warship or three, hundreds of men needed for the vehicle, and the vast problems which would come with even just trying to move the vehicle to where it might be used without crushing everything on its way into oblivion, the investment would simply be redundant. The vehicle was a huge target and the guns were positioned far too high up to be usefully depressed to actually fight the enemy it was rolling over/past. The stabilization might have been viable for a machine in theoretical terms using a gyroscope. In fact, in this regard, the design was rather clever, but the scale is devoid of and detached from reality. It is not even clear if the vehicle would be able to remain in any state other than one of perpetual motion or risk toppling over. In light of the total impracticality of the concept, it seems likely this idea was just a desperate attempt to try and envisage a means by which technology, armor, guns, and mechanical traction could somehow break the deadlock of trench warfare.

The correct answer would be unveiled several months later and this idea, like so many others, were quite rightly consigned to the dustbin of bad ideas.

Sources

Lyon, E. (1916). The Electric Gyro-Cruiser. Electrical Experimenter Magazine, February 1916.
Secor, H. (1917). A one-man electric submarine. Electrical Experimenter Magazine, May 1917.