Landships II

The Army Ordnance magazine Vol 3-4, from 1922, has 2 articles on the subject. One advocates for hydro-spring, one for hydro-pneumatic. They can be found here:
https://www.google.com/books/edition/Army_Ordnance/trbmAAAAMAAJ?hl=en&gbpv=1&bsq=hydro

on pages 53-54 for the pro-hydrospring article (Spring Return versus Recuperator by J.E. Munroe) and on pages 230-233 for the pro-hydropneumatic article (Advantages of Hydro-Pneumatic Recoil Systems by D.A. Gurney and W.C. Young).  

In general hydro-spring recuperators are smaller and lighter for the smaller artillery, and are easier to manufacture and maintain.  For larger artillery pieces this falls away and more modern hydro-pneumatic recuperators started to weigh less than hydro-spring recuperators even for lighter guns (this is shown in the second article).  On the production of hydro-pneumatic recoil systems, when Singer tried to manufacture recuperators for the Canon de 75, they initially wanted to train people to lap the recoil cylinders by hand, just like the French did.  But they had no time to train people to lap the cylinders, the guns were needed as fast as possible.  One of my previous series of posts describes this:

The real trouble began at operation 42 which was the lapping of the small cylinder. Two thousandths of an inch had been allowed for this lap ping and proved to be sufficient to remove the tool marks of the finish-reaming. It was originally thought that it would not be possible to do this lapping entirely in a mechanical way and that a considerable time would be required to instruct and train men in the art of lapping. However, it was not thought practical to attempt to train men to a point where, by the mere skill of hands and eye, they would be able to produce both the extreme accuracy required and the beautiful finish which was said to be necessary.

The following method was adopted and proved to be entirely satisfactory for producing holes of the proper finish and of much higher accuracy than required in the specifications. It is believed that the success with the recoil mechanism as manufactured by the Singer Manufacturing Co. was largely, if not entirely, due to this method of lapping.

So the limitation of hydro-pneumatic recoil systems in WW1 was not directly in production costs, but in the ability to ramp up production (limited by the time required to train people to lap cylinders to high accuracy).

The main benefit of hydro-pneumatic recuperators was their longer lifespan, and their smaller size and weight for larger guns as well.  The second article I mentioned from Army Ordnance states:

It is fairly well established that the French 75-mm. mechanism may be expected to stand up for 20,000 rounds without any major difficulty, and some have been fired a greater number of rounds without overhaul.  It is very doubtful if any hydro-spring mechanism would endure more than 5,000 rounds without replacement of springs.  Breakage of springs is a very frequent occurrence.  For example, recently in a short target practice of 75-mm. guns, Model 1917 (British), 75 per cent of the springs in the battery broke during that practice.

It is interesting to note the results met with in the use of the 18-pdr. gun carriage, Model 1917 (British), during the World War.  The replacement of springs ran to a rather high percentage.  From the observation of a considerable number of carriages under these war conditions the replacements of springs required were very considerable.  Assuming the life of the 75-mm. gun to be about 14,000 rounds, reports indicate that during the life of every four guns over 200 springs required replacement.

In most nations that lifespan was decisive, so once production difficulties with hydropneumatic recuperators were solved (either with direct-contact hydropneumatic recuperators, which didn't need such precision, or with advanced machining technology for floating-piston hydropneumatic recuperators) they became the standard.  For Britain, this happened around 1916 with direct-contact recuperators, and around 1918 with floating-piston recuperators.  The one exception is tanks- they apparently use chydro-spring recoil systems (concentric recoil mechanisms) to this day, according to the Recoil Systems Handbook (page 42).  This is because of their smaller size and lower weight, and the fact that tanks are not likely to fire that many rounds compared to an artillery piece (this does mean that tanks used as mobile artillery during war will wear out their guns faster than dedicated self-propelled artillery guns will).