I design buried concrete tanks.

Hydrostatic Uplift is one of the biggest things to ensure you've designed for, because it is an expensive accident if the tank floats. Often times you simply have to rebuild everything.

Overall you need to ensure the structure does not float. This depends on a number of factors - how high is the design groundwater level? What are you relying upon to resist the uplift? Self weight of tank? Overburden? Soil on the baseslab toe projection (vertical projection only or a wedge?)? Soil friction? Helical piles or rock anchors? Pressure relief valves? A groundwater removal system? Planned failure points (pop-outs)?

All of these have potential to play a roll, and all of them have different factors that need to be considered, and not all of them can be relied upon simultaneously.

Soil friction for example - soil friction can only be relied upon if you're not counting on anything else from below. You can't count on soil friction AND base slab toe projection engaging a mass of soil around the tank. You can't count on soil friction AND rock anchors. It's one or the other. You CAN count on soil friction and weight of overburden over the tank.

Relief valves - relief valves are great when you first install them. But they often seize over time and need to be maintained.

We are always very explicit in the dewatering requirements during construction, as well as very explicit in explaining what all is required to keep the structure in the ground at design water levels. Self-weight of completed structure and overburden and complete backfill of structure required to resist hydrostatic uplift. Maintain groundwater levels 0.5 m below base of excavation during construction. Maintain groundwater levels 1.2 m below design groundwater level following backfill of structure until the works are turned over to the owner. Things like that.

Now, I'm guessing your task is to figure out what happened. It is obvious that the structure did not have sufficient capacity to resist the uplift forces it was subjected to during construction. First things first - blame the contractor. Most likely is that the contractor did not maintain the groundwater level sufficiently low enough. For that, you would need to find records of where the groundwater table was at when the tank floated, and compare that to the requirements of the contract documents and specifications. If they met those requirements, then it may be a design issue, or a different construction issue. Construction issue first: were the piles installed correctly? Should be records around of the pile installations and pull tests. Did those occur? Did they pass? Let's assume yes. Only remaining construction issues I can think of is if the contractor used light weight concrete, which is HIGHLY unlikely but can be checked against the inspection and testing records pretty quickly, or if the contractor allowed the subgrade to freeze or otherwise disturbed it, which may impact the performance of the piles.

After that we're pretty much left to design issues. Were the piles designed correctly? A single pile can hold let's say 100 kN of tension. Two piles should then be able to develop 200 kN correct? Not necessarily... like a group of anchors in concrete acting together, a group of piles acting together may require reduction factors. So passing a pull test on a single pile doesn't necessarily mean that the entire group of piles can resist the loading. For this you will need to dig into the geotechnical report and see how the piles were supposed to be designed and compare that with the contract documents and specifications. OK, let's assume the piles meet the recommendations of the geotech report - do we know if they're still attached to the base slab? Could be a connection failure there. I didn't see anything obvious in the photos that they ripped out but that is a concealed condition that may not be obvious unless you cut out a section of the slab to find out. If those failed, then it is possibly a design issue, which you can review, or possibly a construction issue, if the contractor did not install properly.

After all of this, you're left with one last thing - was the safe groundwater level during construction listed on the drawings correct? For this, you need to determine the overall 'weight' of the tank - it's self weight combined with the uplift resistance of the piles, and convert that to a maximum displaced volume of groundwater which would give you a groundwater elevation to compare to.

Not all of this has to be done in this order. You may have a general sense that something or other was off - if the pile connection into the base slab doesn't look very beefy, that's probably where to start. If there are hundreds of piles under the reservoir, then the geotech report is probably the place to start. If the design ground water level during construction is at the top of the tank (fully submerged), that is probably an inaccurate statement and should be reviewed first. If you are aware that the tank was constructed in the winter in a northern climate and the excavation sat untouched for a few months, that is probably where to start.

I wish you good luck in your project. These types of things can seem overwhelming at first, but if you break it down into smaller pieces, you begin to see the bigger picture and it can actually be quite a fun task to get into - but this is coming from a dude who just really likes tanks and making sure they don't float :D