Trjtdtk

• The outer skin of a zeppelin could start to rip. Someone would have to go on top to sew it up and stop the rip.


• Internally, bracing struts might snap and need to be replaced.


• Many airships had engine pods which were designed for in-flight maintenance.


• Malfunctions might make it necessary to go to the ballast tanks and manually release them. (First image on this page).

Photograph by Alfred Eisenstaedt: Repairing the Hull of the Graf Zeppelin During the Flight over the Atlantic, 1934

A failure that's quite likely in a violent storm is damage to fins, rudders, or elevators. Presuming these are built similarly to what they were on the Zeppelins of the 1900-1940 era, turbulence could snap rudder cable, tear off guy attachments, fracture and buckle ribs or spars, even tear fabric covering.

None of these present a great danger of an immediate crash, just extra drama trying to control pitch by shifting fuel and water ballast, or steer with differential thrust (throttle up starboard engines, idle port side, to turn slowly to port). Even better, all are repairable without landing, at least to the extend of jury rigging something to restore limited control until the ship can land in a safe place.

The engine could break down. If your engine is a steam engine this could be anything from the fire going out to the boiler rupturing/exploding.

Also if the propellers are driven by chains (or similar) they might break. That might require someone to go outside to affix a new chain.

First, read: Airship R505

Here are some of the things that can go wrong:

• Damaged engines


• Damaged propellers


• Leaking fuel


• Damaged fuel lines


• Leaking gas


• Low gas and low ballast from maneuvers during the storm


• Ripped gas bags


• Damaged skin of the airship


• Damaged control surfaces of the airship


• Damaged cables going to said control surfaces


• Damaged structural members (beams, supports)


• Loss of the gondola

Loss of structural integrity in the inner truss system:

The USS Macon, a rigid airship of the US Navy, was badly damaged while transiting through mountains of Arizona. Among other failures, mechanical failures of the rigid truss structure were repaired in flight:

Following a severe drop, a diagonal girder in ring 17.5, which supported the forward fin attachment points, failed. Rapid damage control by Chief Boatswain's Mate Robert Davis repaired the girders before further failures could occur. The Macon completed the journey safely but the buckled ring and all four tailfins were judged to be in need of strengthening. (Wikipedia)

The failure of the Navy to heed advice and have design flaws mitigated lead to the crash of the airship Macon on February 12, 1935.

Air Balloons

A zeppellin made of multiple tiny air balloons (with a bigger protection on top) might be more resistant to any event (bullets for instance, or a lightning/hailstorm in your case), because only a few ones will pop.

However, after an accident, the crew will have to repair/use new ones, and inflate them, then replace them.

Crew is incapacitated or dead.

New technology was installed in the control cabin. It was not appreciated that this new tech effectively bypassed the built-in lightning protection on the airship, allowing a channel for lightning to traverse the airship that took the charge right through the control cabin.

After the strike, the airship is fine but many crew members who were in the control cabin are dead from side splash charge and others badly hurt. The new tech is beyond repair but the airship is otherwise ok. Your protagonist can save one or two crew members s(he) finds in the control cabin, and then must pilot the ship.

The book "Slide Rule" by Neville Shute documents exactly this happening to the R100 after it flew into a storm over the St. Lawrence river. They had crew members walk out on top of the ship and patch the damage while in flight.

Volcanic ash can potentially a violent storm, and has the potential to damage/stall the engines

This is also what happened with British Airways Flight 9, where the airplane entered a volcanic cloud in the night, despite seeing nothing on their weather radar. After a while, the ash melted inside the engines, stalling them.

They eventually recovered their engines by flying low enough (and the usual turbulence shaking the solidified ash away), and repeated attempts of restarting, but 1 engine caught fire, so it had to be shut down again.

With a bit of creativity, this fits your definition of "repairable failure", as to repair the damage, they basically need to shutdown their engines (if they didn't stall already),
decent below the ash cloud and "shake the engines up" to remove the ash (or make them fly though an patch of turbulent air)