Yes, it is applicable everywhere, but it is important to note in which context it is meant to be used. It does not mean that the application as a whole crashes which, as @PeterM pointed out, can be catastrophic in many cases. The goal is to build a system which as a whole never crashes but can handle errors internally. In our case it was telecomms systems which are expected to have downtimes in the order of minutes per year.
The basic design is to layer the system and isolate central parts of the system to monitor and control the other parts which do the work. In OTP terminology we have supervisor and worker processes. Supervisors have the job of monitoring the workers, and other supervisors, with the goal of restarting them in the correct way when they crash while the workers do all the actual work. Structuring the system properly in layers using this principle of strictly separating the functionality allows you to isolate most of the error handling out of the workers into the supervisors. You try to end up with a small fail-safe error kernel, which if it correct can handle errors anywhere in the rest of the system. It is in this context where the "let-it-crash" philosophy is meant to be used.
You get the paradox of where you are thinking about errors and failures everywhere with the goal of actually handling them in as few places as possible.
How it is best to handle an error depends of course on the error and the system. Sometimes it is best to try and catch errors locally within a process and trying to handle them there, with the option of failing again if that doesn't work. If you have a number of worker processes cooperating then it is often best to crash them all and restart them again. It is a supervisor which does this.
You do need a language which generates errors/exceptions when something goes wrong so you can trap them or have them crash the process. Just ignoring error return values is not the same thing.