question

Why don't you want BMS to BMS communication?
There are lots of advantages to a modular system. Eg. Single Pack failure doesn't bring whole system offline, easier to transport etc.

"I realise that the market for 100kWh batteries is limited, but have been wondering if a 16s10p battery configuration, with a suitably sized BMS,as described above would not make things a lot easier."
Market is actually pretty big, most of our comical customers have more than 100kwh.
I am not sure what you mean by easier? Connecting the battery cables is probably less than 1% of the time it takes to complete an install. Physically moving of the batteries inverters and modifying the existing wiring takes the most time outside of installing the Panels. We have actually mostly stopped installing modules bigger than 20kwh because handling becomes a massive problem.

There are batteries out there at are large, FreedomWon makes 48V 100-500kwh batteries.
https://www.freedomwon.co.za/wp-content/uploads/Freedom-Won-Spec-sheet_LiTE-Commercial-52V-Range_Overview-1.pdf
But they literally ship the casing and cells separately and then assemble onsite for most installs.

For systems bigger than 100kwh we typically move to HV packs nowadays. 400-800V 128S1P or 220S1P. But then you have forklift, cranes etc, to move the battery.

Thanks for your replies. I see I have caused some confusion and have not made clear what I meant. I do not mean a single huge battery, but modular at the 3.2V rather than the 48V level.

Perhaps this explains what I mean:

Assume each module above contains 16 x 200Ah 3.2V cell, i.e. they each store 10kWh of energy. That size is reasonable easy to transport and handle.

The difference between the 2 options if that rather than having 16 x 48V/200Ah modules, you could also have 16 x 3.2V/3200Ah modules. The weight of each module is about the same (box + 16 x 3.2V cells), but in the modules on the left the cells are connected in series (16s1p) while on the right they are connected in parallel (1s16p).

The situation on the left requires 1 BMS per module and communication between the 16 BMS's.

The situation on the right requires only a single BMS (much larger of course).

Disadvantages:

As mentioned above of course single point of failure (the huge BMS). To be fair, the master BMS in the 48V system can also be seen as a single point of failure (reconfiguration of the system would be required to take the master module offline, e.g. setting up another module as master).

Much thicker (lower R) cabling between modules

Advantages:

No BMS to BMS communication required, eliminating a potential source of problems.

While cabling between modules needs to be much thicker (lower R), there is no longer a problem is they are unequal length (they do not have to be the same R).

Let's forget about LiFePO4 for a moment, and go back to lead acid where we do not need a BMS.

Assume I want to make a large 48V bank of lead acid batteries. It will be made up of 576 individual 2V cells.

I can make 48V packs (each having 24 x 2V cell in series, so 24s1p) and connect 24 of these 48V "batteries" in parallel

or

I can make 2V packs (each having 24 x 2V cells parallel, so 1s24p) and connect 24 of these 2V "batteries" in series.

or perhaps a mixture.

Is there an inherent advantage or is it up to the preference of the installer?