A B-Class Blimp just after takeoff. This type would be the first in a long line of USN patrol blimps. [US National Archives]The B-Class Blimp was a type of non-rigid airship used for training and patrol duty by the United States Navy during, and after the First World War. The type would be the first successful patrol blimp series the Navy would field and would be used until the early 1920s. Its success would prove the effectiveness of coastal patrol airships in the US, and would mark the beginning of a long line of airships operated by the Navy.
A Rocky Start
Two B-Class blimps during a training exercise. Two spherical observation balloons can also be seen. [US National Archives]The First World War was one that saw considerable technological breakthroughs, with many different ideas coming to fruition for the first time or previously small endeavors in weapons now being used in large numbers. Nowhere was this more clear than with aircraft design. Aside from conventional airplanes, lighter-than-air aircraft also saw their first widespread combat use, ranging from the large Zeppelin raids on London, to the observation balloons at the front. Britain would develop their own unique series of non-rigid dirigibles for the sole purpose of patrolling their coastlines and surrounding waters to search for enemy ships and submarines. At first, the Sea Scout class of airship would fill this role, but later the much larger North Sea and Coastal-classes of airship would also be built. These airships would prove very effective in their patrol duties, with some capable of patrolling for hours on end without stopping. The success of these airships would inspire the United States Navy to begin work on their own design in 1915.
An example of a British coastal patrol airship is the Sea-Scout class, which were heavily used during the First World War to patrol the coastline. This type in particular would serve as a basis for the B-class Blimp [Imperial War Musuem]The first of the Navy’s patrol airships would be the DN-1, later considered the A-Class but never officially known as this. The DN-1 was built by the Connecticut Aircraft Company in 1915 using intelligence from German and Austrian non-rigid airship designs of the time. The DN-1 would prove to be a massive failure, having a poor top speed, inadequate lift, and engine troubles which led the type to not be mass produced. Seeking to avoid a repeat of the DN-1, the Navy would begin looking for a more successful design. Their search would lead to the creation of the improved B-Class
The B-Class Blimp
Rear view of the B-1, the first of the B-Class. [US National Archives]The designers at the Bureau of Construction and Repair (Bu. of C&R) would instead look towards the British for inspiration for their improved design over the German/Austrian based DN-1. The result would be the B-Class. Its overall design took heavy inspiration from the British Sea Scout class of airship. The design would be drafted by the Bu. of C&R. There were several expected requirements to the B-class. The airship had to have a top speed of at least 45mph, a 35mph cruising speed with an endurance of 12 hours, communication range of 150 miles, a crew of three, and it had to be able to land on water for emergencies or towing. The design was approved on January 26th by the General Board and a day later by the Navy. An initial order for two B-class blimps was arranged, but this would change on February 4th when a total of 16 were now ordered. This amount was too much for a single company to construct, so instead 5 companies were approached; Goodyear, Goodrich, the Connecticut Aircraft Company, Curtiss and U.S. Rubber. All of these companies, despite being rivals, would work closely together on the construction of the B-class blimps. Three companies would construct the main balloon section themselves, Goodyear, Goodrich and Connecticut. Goodyear was tasked with building B-1 through B-9, Goodrich would build B-10 through B-14 and Connecticut would build B-15 and B-16. Curtiss would focus on building the gondolas of the B-class, which were modified JN-4 Jenny fuselages, as well as building the OXX engines and fins for the craft. U.S. Rubber would supply Connecticut with fabric for the skin. At the start, Curtiss was meant to build three blimps but these would be instead given to Goodrich, as Curtiss had other aircraft projects to focus on. Building military airships was a new endeavor for most of these companies, aside from Connecticut who produced the previously mentioned DN-1. Goodyear had the most experience in terms of production of lighter-than-air aircraft, as they had already produced a number of free and kite balloons for the Navy, and were found to be the most prepared for production of this scale. Thus the first few B-Class were assigned to them.
Design
Underside view of a B-Class and its gondola. [US National Archives]Closeup view of the modified Curtiss JN-4 Jenny fuselages used as the gondola for the B-class. [US National Archives]The B-Class was a blimp designed for patrolling the offshore waters of the American coastline during World War One. The B-Class had a large, teardrop shaped body that was filled with hydrogen. It would be 160 ft (48.8 m) long. The overall volume of the B-classes differed between the companies that built it. At the rear of the body were several fins, two horizontal, one ventral and one dorsal. Each of these, except the dorsal fin, would have control surfaces to move the airship in the desired direction. Hung underneath the body was the gondola. The gondola was a modified Curtiss JN-4 Jenny fuselage with its wings and tail surfaces removed. An additional third seat was added compared to the standard two seats of the JN-4. In the nose of the gondola was a single Curtiss 100 hp OXX-2 engine powering a two-blade wooden propeller. On the two Connecticut B-classes, 100 hp Hall-Scott engines would be used instead. Beneath the gondola, the B-Class originally retained the landing gear from the JN-4, but these were swapped out later for two flotation bags. On the last B-Class built, B-20, a completely new gondola was designed and the craft was much larger than the standard design.
For armament, the B-class would have a Lewis machine gun. For anti-submarine duties, it could carry depth charges or bombs. Additional equipment for the crew included a radio transmitter and receiver, flashlights, a flare pistol with green and red flares, life preservers, rations, drinkable water, maps, a camera, carrier pigeons and signal books.
The B-Class in the War
A B-Class blimp above the Goodyear hangar at Akron. Two Upson kite balloons can be seen in the hangar. [US National Archives]The first B-Class, B-1, would be completed by Goodyear sometime in April/May of 1917. At the time of its creation, Goodyear had been working on building a facility in Akron to house and operate airships, but it was still under construction when B-1 was completed. Thus, Goodyear had to transport the B-1 to the Goodrich facility near Chicago to inflate the craft. The craft was finally inflated and first flown on May 24th, 1917, with Ralph H. Upson at the controls. Upson was an airship engineer and pilot at Goodyear, and a pioneer in the lighter-than-air field, winning an airship race in 1913 and designing his own kite balloons at Goodyear only a few years earlier. He was thoroughly impressed with the first test flights. Upson would take the B-1 up again 5 days after the first flight and would try to fly from Chicago all the way to Akron. His flight started at midnight. Due to an oil leak, he would have to set the craft down at noon, just 10 miles outside of Akron. Despite not making it to his intended destination, Upson had achieved a record for lighter-than-air aircraft travel distance in America. The Navy had doubts surrounding the B-Class after the failure of the DN-1, but with the type already achieving world records on only its second flight, these doubts were quickly amended. The type was already proving its effectiveness even before entering active service. Production of the rest of the 15 B-classes soon commenced and the B-1 was shipped to Pensacola on August 7th, 1917.
B-Class at Akron, Ohio. [US National Archives]As production continued, the various B-Classes would be sent across America to different air stations for duties. These included Naval Air Stations; Pensacola, Cape May, Montauk, Key West, Rockaway, San Diego, and Coco Solo in Panama. B-classes would also be stationed at Hampton for mostly testing purposes. Several improvements of the B-class would occur during its service, improving its top speed from 40mph to 48mph. The B-Class was responsible for patrol and rescue operations off the coastlines of America, and hunting for the dreaded U-Boat. It was found that blimps were much better for patrol duties than airplanes thanks to their long range, extended endurance time, and the ability to hover in midair assisted in spotting enemy warships. The B-Class would perform this duty until the end of the war. If a B-Class encountered a U-Boat, it could deploy depth charges or bombs, or radio in for aerial support from the NAS the aircraft was stationed at. During its service life, at least two B-classes would spot a U-boat and attempt to destroy it, but none would be sunk by the B-Class. The service of the B-class was impressive. It is estimated that the B-classes together patrolled for over 13,600 hours across 400,000 miles. Aside from patrol duties, another impact the B-Class had on the military was its extensive use as a training craft. Several B-classes would be stationed at the aforementioned Goodyear Akron facility solely for the purpose of training. Over 170 aviators would train and be certified on the B-Class, with many headed overseas to operate European dirigibles in service with France and Britain. No B-class blimps were ever sent to Europe.
A B-Class preparing for takeoff. [US National Archives]The B-class was not without its accidents. Throughout their service life, many B-class blimps would suffer damage or be completely destroyed while on duty. B-4, B-5, B-6, B-7, B-9, B-12, B-14 and B-16 were all destroyed in accidents before the end of the First World War.
B-Class at Akron Ohio. [US National Archives]Despite its effectiveness, the B-class was found to be lacking as a patrol craft, and the Navy would order a successor design in September of 1918 to amend the shortcomings of the B-class. This was the C-Class (no relation to the aforementioned British Coastal Class which was also known as the C-Class coastal airship) and it took many aspects of the B-Class and improved upon them. The shape of the balloon itself was overall the same, but the C-Class had a much larger gondola that sported two engines instead of one, granting improved speed and maneuverability. The C-Class however wouldn’t be ready before the end of the war, but was instead operated postwar.
The B-Class Postwar
View of a B-class during operations patrolling the Atlantic. This photo was taken from a USN submarine. [US National Archives]The First World War would end on November 11th, 1918, with the B-Class having served well in its duties. Despite the C-Class approaching production, the B-Classes still in service would continue to operate, however a few were stricken off to reduce the fleet size. Three B-Class blimps would be rebuilt reusing the envelopes from previously damaged blimps. These would be B-17, B-18 and B-19. B-17 is known to have reused the envelope from B-1, which was damaged on June 17th, 1920. B-18 likely used the envelope from B-13. Details on B-19 are lacking. It is known that these three blimps were constructed sometime in 1920. The final B-class built would be the B-20. Details are also sparse on this craft but it is known to have had a completely unique gondola design and was much larger than the standard B-Class. In the bureau number list, B-20 is listed as being before the aforementioned rebuilt gondolas. Interestingly, these B-classes were all built after not only the introduction of the C-Class, but even after its successor, the D-Class. All postwar built B-classes were constructed by Goodyear. The remaining B-classes continued to serve into the early 1920s, with many of them being scrapped due to accidents or deterioration with age. By 1924, three B-classes remained, B-3, B-8 and B-15. B-8 was heavily deteriorated but B-3 and B-15 were still in operational condition. By this point however, the B-class was heavily outdated, and with its services no longer required, the last 3 were surveyed and scrapped in 1924. The B-class actually wound up being in service longer than its successor, as the few remaining C-Classes had been scrapped in 1922.
Conclusion
A B-Class above the Naval Air Station at Key West, Florida. [US National Archives]The B-Class was an important achievement to the United States Navy, proving the effectiveness of patrol airships and paving the way for a long line of succeeding designs. The B-Class would train aviators that would go on to protect allied countries in foreign built dirigibles, and would protect the American coasts from U-Boats. B-Class blimps would serve the Navy well past its expiration date, even surpassing its own successor. The Navy’s LTA airship fleet began with the humble B-Class, and would continue for almost five decades later.
One of the early B-Classes built by Goodrich. Notice the double ventral fins. [US National Archives]
Service List
B-1: The first in the B-Class series, B-1 would survive the war. On June 17th, 1920, B-1 would be damaged at Pensacola and would be stricken off. The gas bag was later reused on B-17.
B-2: B-2 would survive the war and would be stationed at Key West. On February 28th, 1919, B-2 would completely wreck.
B-3: B-3 would survive the war and continue to serve until it was surveyed in 1924. The ship was damaged several times but was fully repaired each time.
B-4: Stationed at Hampton NAS for testing. On August 8th, 1918 the craft was damaged and stricken. The blimp was salvaged for spare parts.
B-5: Stationed at Akron. While on maneuvers, it would be completely destroyed on November 21st, 1917.
B-6: Service details are lacking, stricken from the Navy on September 7th, 1918.
B-7: Stricken June 8th, 1918.
B-8: Survived the war and served until March 19th, 1924, where it was surveyed due to deterioration.
B-9: Stationed at Key West. On April 21st, 1919 would completely wreck due to engine failure.
B-10: Stationed at Cape May. During maneuvers on December 7th, 1918, it would be heavily damaged. The craft was sent back to Goodrich but the repairs were considered too expensive and B-10 was scrapped. The envelope was torn up and distributed to other air stations to serve as repair materials on other blimps.
B-11: Shipped to Pensacola, service ended on August 15th, 1919. Service unknown.
B-12: B-12 wrecked while on patrol on July 26th, 1918.
B-13: Damaged numerous times during service at Montauk Naval Air Station. Envelope appears to have been salvaged and later reused but on what aircraft is unknown, possibly B-18. It was recommended to be stricken off at two different stations in 1919, at Montauk and Rockaway.
B-14: Wrecked July 20th, 1918 at Montauk(?).
B-15: Served at Pensacola through the war and after. Was finally surveyed on April 22nd, 1924.
B-16: Official report is spotty but on June 17th, 1918, the craft was destroyed.
B-17: Rebuilt gondola, reused the envelope from B-1, service unknown.
B-18: Rebuilt gondola, envelope possibly from B-13. Service unknown.
B-19: Rebuilt gondola, service unknown.
B-20: Last B-class. Built in 1920. Completely new gondola design. Service unknown.
Variants
Goodyear/Goodrich B-Class (1 through 14) – B-classes built by Goodyear/Goodrich would use Curtiss OXX-2 engines. The first few of these had double fins but these were later changed to a single fin.
Connecticut B-Class (15 & 16) – The two B-Classes built by Connecticut would use Hall-Scott engines. These two appear to have the double fins as well. Unknown if any of these were later changed.
B-20 – The last B-class produced. It would have a unique gondola design.
Operators
United States of America – The 20 B-classes built would be operated by the United States Navy for patrol and training purposes until 1924.
B-Class (Goodyear) Specifications
Length
160 ft / 48.8 m
Diameter
31.5 ft / 9.6 m
Volume
(Varies between companies)
77,000 ft³ / 2180.4 m³
Engine
1x 100 hp ( 73kW ) Curtiss OXX-2 8-cylinder engine
USA (1915) Observation & Training Balloon – 10+ Built
The Kite Balloon operated by the Navy at Pensacola. This particular balloon is based off the first patent. [Naval History and Heritage Command]The Upson Kite Balloons, also known as Goodyear Kite Balloons or simply Upson Balloons, were a series of three observation balloon designs by Ralph Hazlett Upson to improve upon the design of the German Parseval-Sigsfeld Drachenballon. Two of the designs would be built by the Goodyear Corporation and sent to various balloon training schools and even operate off of ships, but the type was found to not offer much improvement over the Drachenballon, and the much more advanced Caquot balloon which would be introduced only a year after the Upson balloons were built, making the type null. A 3rd design would be patented but wouldn’t be built.
Ralph H. Upson and the Parseval-Sigsfeld Drachenballon
R.H Upson outside of the Goodyear Hangar in Akron, 1917 [US National Archives]Ralph H. Upson was a pioneer in balloon and airship development in America in the early 1900s. In 1913, using his own airship design, he would win the International Balloon Race. Upson was an employee of the aeronautics division of the Goodyear Rubber and Tire Corporation where he was a pilot and engineer on the various lighter-than-air projects the company had been working on. Upson would mainly work at the Goodyear plant in Akron, Ohio. In 1914, the company began building observation kite balloons for the US Army to use in their balloon divisions. The main type of kite balloon in use was the German designed Parseval-Sigsfeld Drachenballon. The Drachenballon was designed over a decade before in 1898 and was a replacement for the spherical observation balloons of the previous century, as the latter was found to be almost unusable when in windy conditions. The Parseval-Sigsfeld design was built in such a way it would face towards the wind thanks to a large, air-inflated steering bag at the rear of the balloon. Thus it was named Drachenballon, or “kite balloon”. America would build and operate several Drachenballons before their entrance into the First World War.
An example of a German-operated Parseval-Sigsfeld Drachenballon. [Waffen Arsenal 149]Upson would begin designing an improvement over the Drachenballon in 1915. Using the knowledge he learned from working on airships, he’d incorporate a number of features that would hopefully improve the overall stability of the German balloon. Two designs would be created at first in late 1915, with the patents on these designs being filed on June 20th, 1916.
Kite Balloon Design 1: Back to Basics
Kite Balloon Design 1 in the patent. The Navy-operated balloon in Pensacola is of this type. [Google Patents]An Upson balloon being inflated at Pensacola. [State Archives of Florida]The first of these designs was essentially a heavily modified Drachenballon. Its overall appearance and construction was the same. The balloon consisted of a large cylindrical gas bag. In the nose was a valve that regulates the pressure and gas and can be opened for release automatically or manually. On the underside was a neck to which the hydrogen gas was filled from. The Upson’s balloon’s neck was much longer than the neck on the Drachenballon. On the sides of the balloon were two stabilizing fins. On the Drachenballon, these fins are rectangular in shape. On Upson’s design, these would be triangular in shape and would sag down in flight. According to Upson, the rectangular fins of the Drachenballon only offered stabilization horizontally, while his fins would also prevent yaw and pitch movement. Internally at the rear was a large air bag to keep the balloon’s shape stable if the balloon isn’t fully inflated and keep the balloon at a 30-40 degree angle while in the air. The main difference between Design 1 and the Drachen involved the aft section of the balloon. On the standard Drachen is a large air-inflated steering bag that would keep the aircraft stable. On Upson’s design, the balloon would instead slightly taper at the rear. The steering bag would be removed altogether, instead replaced with a large keel-shaped bag. Upson’s thinking behind this change was that the steering bag wasn’t aerodynamic and instead opted for the more sleek keel bag over it, improving airflow. The keel bag and the ballonet were both connected via an intake at the tip of the keel. In addition, the tail of the balloon was connected to the keel, to which several tail cups were placed not only for stabilizing but to keep the keel straight. The tail cups were placed much closer to the balloon than on the Drachenballon. The rubber balloon girdle also differed from the Drachenballon slightly,as it wouldn’t be uniform all around the balloon, instead dipping slightly down near the front. The balloon would be made of rubberized and non rubberized fabric and filled with Hydrogen.
An Upson Kite Balloon in flight [US National Archives]One of the Upson balloons preparing for flight at the Goodyear Plant in Akron. The other is visible in background hangar. The USAAC roundel is barely visible on the underside. [US National Archives]BC-3 moored to the USS Huntington. [Wikipedia]The Upson balloon BC-3 operating off of the USS Huntington. [navsource.org]The Navy Design 1 balloon operating from the USS Oklahoma [NavalHistory.org]Several Design 1 balloons are known to be built. The first would be built at the Goodyear plant in Akron in late 1915. While testing was going on in November, it was observed by officials from the Navy who were looking to increase the USN’s LTA (Lighter Than Air) fleet. The Design 1 balloon was accepted into service for the Navy on December 22th and shipped to the Pensacola Naval Air Station in Florida. The balloon would finally arrive on April 5th, 1916, along with a handful of Goodyear employees who helped with training. Only two days after arriving, the balloon would be damaged from heavy winds and would break from its mooring. The balloon would be repaired shortly after. Once repaired, the balloon was stationed aboard the USS Nevada and USS Oklahoma for testing. The balloon was found to offer increased visibility, but there were a number of reasons why using it from a battleship was a bad idea. The balloon was a very easy target, explosive due to its hydrogen gas (which often leaked), and gave away the position of the battleship. Inflating the balloon was also slower than what was expected. In some cases the balloon itself affected the maneuverability of the ship. It was noted that many of these issues could be fixed in the future, but no changes to this balloon are known to have occurred. Despite not performing well aboard a ship, the Navy continued to use the Design 1 balloon at the Pensacola Air Station for testing and training. Two more balloons were ordered, with the designations of CB-2 and CB-3 for the Navy. Both of these balloons are known to have been tested on the USS Huntington for evaluation. Even further on, the balloon CB-4 was ordered. It is unknown what type of balloon this was, whether Design 1 or 2.
Photo of a Design 1 balloon at Fort Omaha, Nebraska [Museum of the United States Air Force]Aside from the Navy, the United States Army Air Service would also use two Design 1 balloons. One is known to be used for testing purposes. This balloon in particular has an extra set of stabilizing fins located a few feet in front of the regular stabilizing fins. Aside from testing, its service history is unknown. All that is known about it is comes from a US Army report evaluating it and a few photos to go along with said report. The report was very appraising of the type over the standard Drachenballon. The second known USAAS Design 1 balloon had an interesting history. From 1910 to 1919, the United States was in an armed conflict with Mexico on its border, known as the Mexican Border War. During this, many Army units would be stationed along the border. An Ohio National Guard Artillery unit was deployed along the border and stationed at El Paso, Texas in 1916. Accompanying the division was a Design 1 kite balloon gifted to the division by Goodyear. Along with the balloon, Ralph H. Upson himself would be assigned to assist in operations and training personnel for the balloon. The balloon would be used to observe Mexican forces moving near the border. Aside from its service in the War, the fate of this balloon is unknown. It was, however, the first observation balloon operated by the National Guard and is known to have been built shortly after the first Design 1 balloon.
Kite Balloon Design 2: All New
Design 2. This particular type would see several produced. [Google Patents]The second design was also included on the June 20th patent and would greatly differ from the standard Drachenballon. In fact the only two similarities between the two designs would be their overall layout, other than this, the two designs are greatly different. The overall shape wasn’t cylindrical, but instead more round. Carrying over from Design 1 are Upson’s unique side fins, keel bag, and extended neck. The evacuation valve in the nose was moved upward and is near the top of the nose instead of directly frontally. Instead of having a balloon girdle, the ropes connecting the mooring line and basket were instead connected to individual rubber connection points around the main body of the aircraft. The pattern of the connection points is the same shape as the girdle on Design 1, with it arching down towards the front. The aircraft would also be stabilized by an internal ballonet. Specifications for this balloon do exist. It was to have an internal volume of 25,000 ft³ (707.9 m³). The maximum service ceiling would be 6000ft (1828.8 m). On the underside of two of the balloons, a United States Army Air Corps roundel is printed.
Goodyear would build at least four of this balloon type for training and testing. Two of these would be sent to the Fort Omaha balloon school in late 1916. Here they would be used in the training of the balloon corps alongside Drachenballons and spherical balloons. Two more of this type were photographed at the Goodyear Akron plant during a maneuver with other lighter-than-air aircraft. There is a chance these two aircraft are the same as the ones in Omaha but their overall appearance differs slightly. On one of the balloons is a box-like structure located at the side of the balloon. These are not present in the patent or on the other balloons and their purpose is unknown. It is possible these were some form of additional stabilizers but it is not confirmed. This type appears to be exclusively used by the USAAS.
The same excercise as before at Akron with all balloons now airborne. What appears to be a B-Class Blimp is in the background as well. [US National Archives]On September 23rd, 1916, two pilots; Carl K. Wollam and Charlie Roth, were interested in one of the Goodyear Design 2 balloons then stationed at Dayton, Ohio. Both men, who were aircraft pilots, wanted to see how well the Upson balloon would do in untethered flight. It should be noted neither man had piloted a balloon before. The two would go up in the balloon, and then cut the cable. The balloon would go to an altitude between 5000 and 6000 ft (1524 and 1828.8 m) for a distance of over 120 miles (321.9 kilometers). The flight would last over 3 hours. The two wanted to head to Akron to land but their attempt failed and they were thrown off course for 70 miles (112.6 kilometers), finally landing in a farm near Circleville, Ohio. This would be the first free flight of a kite balloon in the US. Despite not being designed for this flight, the pilots said the balloon was hard to control, but overall performed well for the task.
Kite Balloon Design 3: Double Trouble
Side view of Design 3. This design was essentially two Design 2 kite balloon bodies sewn together. [Google Patents]Frontal view of Design 3. [Google Patents]The last of the Upson balloon designs was not included in the first patent document, instead being patented a few months later on November 9th, 1916. This 3rd balloon design differed greatly from most balloon designs of that era. Design 3 essentially was two Design 2 balloons sewn together side by side. Upson would call it a “Composite Balloon” in the patent. Each side of the balloon would have design features from Design 2. At the rear interior of the gas bag was an air-fed ballonet to keep the overall shape of the balloons intact when not fully inflated. The overall shape of the gas bag was changed, with Upson specifically mentioning that the bottom was flattened out to aid in aerodynamics. In each nose was an emergency gas escape valve to regulate the gas. On each side was one of Upson’s triangular stabilizing wings and at the rear was the keel bag. Instead of the tail cups that were common for kite balloons and used with the previous two designs, Upson would design a completely new tail stabilizing device. A large concave strip would connect to two ropes. Each rope would connect to an end of one of the gas bags. The strip would catch the wind like a parasail, stabilizing the balloon. Upson’s overall choice for the double body design was to greatly increase the stability and maximum height over contemporary balloon designs, with the idea that another body would assist in that regard considerably. The ropes connecting the basket were equally distributed to each of the balloon bags.
Despite Upson claiming it to be superior over his previous two designs, no composite balloon was ever built.
Too Late: The Caquot Arrives.
Two Upson Balloons are part of an exercise at the Akron Goodyear Plant, along with two Caquot Balloons. The photograph label incorrectly states all four balloons are Caquot R Types. [US National Archives]From reports, the improvements done by Upson over the Drachenballon design did positively impact its design, making it much more stable in strong winds. A Design 1 balloon is known to have remained stable in 45mph winds. Despite the positive reception, there are still mentions that the Upson balloons design wasn’t perfect and it suffered still in terms of total stabilization compared to newer the newe balloons on the horizon, but overall it performed better than the Drachenballon in this regard. Upson’s balloon designs would have only just started their testing when the French officer, Albert Caquot, would create his superior balloon design in the later months of 1916. The design was created to completely fix the flaws of the Drachenballon. To fix the stability issues, two more air-inflated bags were placed at the rear of the balloon, totalling 3 stabilizers spaced 120 degrees apart from each other. The type was found to be completely superior over the Drachenballon and it quickly began replacing allied, and eventually German Drachenballons. Goodyear would later license build Caquot type balloons in 1918, for use by the American Balloon Corps. By their entrance in World War One, the US would only use Caquot types in combat operations in Europe. No further Upson balloons were built after 1917. Despite this, the two Design 2 balloons stationed at the Fort Omaha balloon school would continue to be used for training purposes until the closure of the school in 1919. It is unknown what fate befell the Navy operated kite balloons.
The Design 1 Balloon in operation at El Paso, Texas during the Mexican Border War. [texashistory.unt.edu]An Upson Balloon at the Fort Omaha Balloon School. [US National Archives]Due to a lack of information regarding these balloons, it is entirely possible, and extremely more than likely that more than the known amount of Upson balloons were built, but records and photos concerning the production of Design 1 and 2 types are severely lacking.
Upson would continue his work in the field of lighter-than-air aviation, working for Goodyear into the 1920s until he would leave the company to pursue his own vision of lighter-than-air aircraft. He would create the Aircraft Development Corporation, where he would design and build the metal-skinned airship ZMC-2 for the Navy. Upson would continue in the aviation industry all the way through the Second World War and into the 1950s.
A B-Class Blimp flies over the Goodyear hangar in Akron. One of the Upsons is being either taken in or out of storage. The second is visible in the hangar. [US National Archives]
Variants
*Note, the “Design” names are not the official designation, but named so here for simplicity.
Design 1– Heavily modified Drachenballon with improvements made by Upson. These include larger side stabilizers, the removal of the steering bag and the new keel bag for wind stabilizing. Five are confirmed to be built, with a possible 6th.
Design 2 – Completely original design that took the improvements from Design 1 and put them on a new design. Design 2 had a much more rounder body over Design 1. Four are known to have been built.
Design 3 – Composite balloon. Consisted of essentially two Design 2s sewn together. Reused all of the aforementioned modified side fins and keel bags. Would have a unique tail stabilizing parachute.
Operators
United States of America – The Upson types built were used by the balloon corps of the United States Army Air Corps and Navy.
Upson Kite Balloon Design 1 Specifications
Length
82 ft / 25 m
Diameter
22 ft / 6.7 m
Volumes
25,000 ft³ (707.9 m³)
Gas Type
Hydrogen
Material
Rubber-infused and non-infused cotton fabric
Maximum Service Ceiling
6000 ft / 1828.8 m
Crew
2 Observers
Equipment
Telephone
Upson Kite Balloon Design 2 Specifications
Volumes
25,000 ft³ (707.9 m³)
Gas Type
Hydrogen
Material
Rubber-infused and non-infused cotton fabric
Maximum Service Ceiling
6000 ft / 1828.8 m
Crew
2 Observers
Equipment
Telephone
Gallery
Illustration of Upson Balloon Design 1 by Ed Jackson
A side view of the LWF Model G-2. The firepower of the aircraft is evident, as the two of the four forward facing aircraft are visible near the engine, the double mount for the gunner, and beneath that the ventral gun is protruding. [US National Archives]The LWF Model G was a multi-purpose two-man aircraft designed by LWF in 1918. While it was originally designed as a reconnaissance plane, it was redesigned to be equipped as a heavy fighter or bomber. Two aircraft were built for the United States Army Air Services for evaluation, where the craft reached 138 mph in its fighter loadout whilst carrying seven 7.62mm guns. Both prototypes would unfortunately crash, and with the First World War over, the Army Air Service no longer needed the aircraft. After the war, a third Model G was built as a mailplane.
History
The L.W.F. Engineering Company was an American aircraft manufacturer founded in 1915 by Edward Lowe Jr, Charles F. Willard, and Robert G. Fowler, with the company name being an acronym of their last names. The three had worked in the aviation industry before forming the company, with each using the experience they had learned to contribute to the company’s designs. In particular, the company was well known for its laminated wood, monocoque fuselages. Their first commercial product would be the LWF Model V, a two-seat reconnaissance/trainer aircraft for the United States Army Air Service. This would be their most popular aircraft, with over 100 being built before the end of the war. LWF would further experiment with the Model V, creating an improved prototype called the Model F. The Model F would replace the 135 hp (100 kW) Thomas-Morse engine of the Model V with a powerful 350 hp (261 kW) Liberty L-12 engine. This is claimed to be the first aircraft in the world to fly with a Liberty engine. The success of the Model F would inspire a successor design also using the Liberty engine, the Model G.
A pilot of the Model G-2 poses in front of the aircraft. [San Diego Air and Space Museum Archives]The LWF Model G was drawn up in late 1917 as a high-speed reconnaissance/training plane using the aforementioned Liberty engine. It would bear a strong resemblance to the Model F, only differing in length and a few minor details. The first Model G aircraft was built in early January of 1918. On January 16th, the aircraft would take flight for the first time. The flight would start smoothly after takeoff but with a strong wind the aircraft was forced into a loop and entered into a tailspin, crashing into the ground and being completely destroyed. A second prototype would be constructed not long after the destruction of the first. This new prototype would be known as the Model G-1. The G-1 improved greatly upon the standard G model, but had more than its original reconnaissance and training role in mind. Instead of being solely a reconnaissance plane, the G-1 was envisioned as a capable two-seat fighter and light bomber. Each of the different configurations differed in terms of what they carried, whether it be weapons, bombs or extra armor. The G-1 was completed and flying by the summer of 1918, and its performance was superb. Test flights were done numerous times in front of both military and government officials to demonstrate the engine and its performance. By this point the Liberty engine had been upgraded to have 435hp (324.3 kW). Thanks to its more powerful Liberty engine, it was able to achieve incredible feats. In its fighter configuration, it was to carry an impressive armament of seven 7.62 machine guns. During a test flight, the aircraft was able to achieve a speed of 128mph (206 km/h) while carrying all of its weapons, fuel, and crew. In its bomber configuration, it would carry the same amount of guns, as well as additional armor and bomb racks.
The LFW Model F in flight, the predecessor to the Model G. Overall the two aircraft looked similar. [US National Archives]Testing of the Model G-1 continued into late summer, when it was reworked into the Model G-2. The G-2 had several modifications to increase performance and handling. The control surfaces were fixed to be more balanced, and the ribs of the wings were doubled to improve structural stability. The improved design is noted as performing significantly better than the G-1. During a fully loaded flight , the improved Model G-2 went 10mph faster than the G-1, clocking in at 138mph. In comparison, the French Spad XIII fighter, one of the most highest performing production aircraft of the war, had the exact same top speed of 138mph (222 km/h) as the Model G-2, and it was a considerably lighter aircraft with only two machine guns. Testing of the G-2 continued through 1918 and showed excellent results. The aircraft was trialed in all three configurations and performance was recorded for each. On November 11th, the First World War came to an end. Despite there being no need for a fighter like the Model G, the type was still tested. A week after the end of hostilities, November 18th, the Model G-2 took off again. The aircraft however had taken off in dense fog, making visibility difficult. Due to the fog, the G-2 would crash and be totally destroyed. With the war over and both military prototypes destroyed, the pursuit of the Model G as a combat aircraft was over and LWF instead focused on the now-growing civilian market. There is mention on a photograph of the Model G-2 that an order for 600 of the aircraft was put out by the Army Air Service, but there is no mention of this in other sources. No production aircraft were built outside of the two military prototypes.
The mail-plane version of the Model G in 1919. Note the lack of armament and four bladed propeller. [US National Archives]In 1919, a 3rd Model G was built as a mailplane. Little is known regarding this aircraft outside of a single photo. In the photo, which is dated April of 1919, long after both of the previous aircraft had crashed, an unarmed Model G is depicted. What is interesting about this version is that it had a four-bladed wooden propeller, whereas the previous models only had a two blade. Converting the Model G from a combat aircraft to a mailplane was a logical evolution. The Liberty engine would allow it to make quicker deliveries than its contemporaries, and it was able to carry up to 1,200 Ib (544.3 Kg) of cargo. Despite this advantage, only a single example was built. The fate of the mailplane is unknown, but it was likely scrapped years later once service was done, hopefully not meeting the same fate as the previous two Model Gs. No more work was done on the aircraft after the mailplane was finished.
Design
Complimentary image to the gunner showing the elevation, here the depression is shown. Note the ventral gun pointed straight down. [San Diego Air and Space Museum Archives] Two of the forward facing guns are visible, one above the engine and one in the removed cowling area. [San Diego Air and Space Museum Archives]The LWF Model G, and its upgrades, were a two-seat biplane multirole aircraft. The fuselage was constructed of laminated wood monocoque in a very aerodynamic cigar shape. It bore a resemblance to the sleek monocoque fighters of Germany, like the Pfalz D.III or Albatros D.V. In the nose, a Liberty L-12 engine was connected to a 2-bladed wooden propeller. At first the engine would be 350 hp (261 kW) but it was later upgraded to 435hp (324.3 kW) on the Model G-1 and onward. On the postwar mailplane, a four bladed propeller was used. The engine itself wasn’t fully covered, with about half protruding from the fuselage. On the nose were two radiators. Behind the engine sat the pilot. A windscreen protected the pilot from the wind and elements. Flight surfaces were controlled via two control sticks. The wings were two-bay and covered in fabric, with ailerons used on both pairs of wings. Beneath the fuselage was the landing gear. Two rubber lined wheels held the aircraft up on a basic landing gear frame. At the end of the fuselage was a landing skid. Behind the pilot sat the observer, who would handle observation duties in its basic configuration, and would serve as the gunner on the fighter and bomber configurations. His position was protected by a small windscreen as well. At the end of the tail were the vertical and horizontal stabilizers. The horizontal stabilizers were supported by two struts connected to the tailfin.
Another view of the gunner/observer position demonstrating the elevation of the double 7.62mm gun mount. [San Diego Air and Space Museum Archives]On the Model G and reconnaissance/training versions of the G-1 and G-2, no armament would be used. For armament on the fighter and bomber versions of the G-1 and G-2, a total of seven 7.62mm machine guns would be used; five Marlin and two Lewis guns. Two would be built into the fuselage, forward facing. Two more would also be forward facing but would be mounted on the engine itself. The remaining three would be operated by the gunner with two on a movable mount and the last protruding from the underside of the belly. The double mount was highly mobile and offered a great range of fire for the gunner to defend the aircraft. Four bomb racks capable of carrying up to 592 Ibs (268.5 Kg) of bombs were equipped for the bomber configuration. The bomber configuration also carried 66 Ib (30 Kg) of armor for protection of the crew/internals.
The aircraft was painted overall in two tones. From above it was painted a dark brown to blend in with the ground, while from below it was painted a sky blue. The tailfin was painted in the signature red-white-blue found on other American combat aircraft. Two Army Air Service roundels were painted on the upper and lower wings.
Conclusion
View of the pilot and gunner/observers position in the aircraft. Note the small windscreens. [San Diego Air and Space Museum Archives]The LWF Model G was an impressive aircraft all around, being able to carry a large arsenal of weapons while maintaining a high speed for an aircraft of its stature. Unfortunately, despite being so successful, the aircraft wasn’t adopted for production and with the loss of both prototypes, the military was possibly wary of the aircraft despite its success. With the war over, a need for the type wasn’t necessary, as the aviation industry moved into a more civilian-oriented market.
In the time frame of its development, even if it had been selected for production, it was so late in the war it likely wouldn’t have seen combat. Had it however, the LWF Model G would have been a truly terrifying foe to enemy aircraft, thanks to its powerful armament and fast top speed. With its seven 7.62mm machine guns, it carried more guns than several bombers of the time period.
LWF would continue designing their own aircraft post-war, most of them mailplanes like the Model G, but they too would never catch on. LWF would also license build aircraft from other companies during the 1920s. This wouldn’t last long, however, as the company would file for bankruptcy and become defunct in 1924.
Variants
LWF Model G – Prototype, unarmed. Equipped with Liberty V-12 engine. Crashed on first flight. One built.
LWF Model G-1 – 2nd Prototype, multirole. Improved upon the Model G and could be configured to do reconnaissance, dogfighting or bombing. Carried an impressive seven 7.62mm machineguns. Increased engine performance.
LWF Model G-2 – Modified version of the G-1. Had changes made to the design to increase handling and performance.
LWF Model G Mailplane – Unarmed mailplane version of the G-2. 1 built after the war.
Operators
United States of America – The LWF Model G was designed for use by the Army Air Service. Despite its success, the end of the war made the aircraft no longer needed. The 3rd Model G served as a mailplane.
LWF Model G-2 Specifications
Wingspan
41 ft 7 in /12.5 m
Length
29 ft 1 in / 8.8 m
Height
9 ft 4 in / 2.7 m
Wing Area
515.54 ft² / 47.9 m²
Engine
1x 435 hp ( 324.3 kW ) Liberty V-12 inline engine
Propeller
1x 2-blade 9 ft 7 in / 2.7 m wooden propeller (1,800 RPM)
Fuel Capacity
90 US Gal / 340.6 L
Water Capacity
14 US Gal / 53 L
Oil Capacity
6 US Gal / 22.7 L
Weights
Empty
2,675 lb / 1213.3 kg
Fighter
4,023 lb / 1824.8 kg
Bomber
4,879.5 lb / 2213.3 kg
Climb Rate
Time to 10,000 ft / 3048 m (Standard)
7.28 minutes
Time to 10,000 ft / 3048 m (Fighter)
9.18 minutes
Time to 10,000 ft / 3048 m (Bomber)
14.15 minutes
Maximum Speed
130 mph / 209.2 km/h at 10,000 ft / 3048 m
138 mph /222 km/h at Sea Level
Landing Speed
50 mph / 80.5 km/h
Endurance
4 hours
Maximum Service Ceiling
24,000 ft / 7315.2 m (Model G)
Crew
1 Pilot
1 Observer/Gunner
Armament
5x 30 Caliber (7.62mm) Marlin machineguns
2x 30 Caliber (7.62mm) Lewis machineguns
4 bomb racks (carrying capacity 592 Ib / 268.5 Kg)
Jane, F. (1969). Jane’s all the world’s aircraft 1919. New York: Arco Pub.
Green, W. & Swanborough, G. (2002). The complete book of fighters : an illustrated encyclopedia of every fighter aircraft built and flown. London: Salamander.
USA (1917)
