Welcome to the forum OGP.

The answer is that batteries store electrical energy based on the chemical properties of the materials that the battery(ies) are constructed from...

To keep things simple, lets look at a 12 volt automotive Flooded Cell Lead Acid Battery (note: These batteries are of slightly different construction vs Flooded Cell Deep Cycle Lead Acid batteries--But are close enough for our discussion).

More or less, your car battery is "full" it measures 12.8 volts (~100% State of charge, not charging, not discharging--Rested for 3+ hours). And more or less, is "mostly empty" at 11.8 volts (basically around 20% state of charge).

https://footprinthero.com/lead-acid-battery-voltage-charts

And is pretty much "dead" at 11.5 (unloaded) to 10.5 volts (with some electrical loads). Most rechargeable batteries taken to "dead" will not recover when recharged.

Some articles to read:

https://www.solar-electric.com/learning-center/deep-cycle-battery-faq.html/
https://batteryuniversity.com/
https://www.rollsbattery.com/wp-content/uploads/2018/01/Rolls_Battery_Manual.pdf

Batteries are "pretty simple" at a surface level... But the details can get very deep when you do more research. Add different designs, constructions, materials, etc... And it is very easy to get lost in the details.

For lead acid batteries, more or less you want to run them from 50% to 100% state of charge --And you can go down towards 20% State of charge--If you quickly recharge the battery bank (if you let them sit at less than 75% SoC for days/weeks/months--You will end up with a sulfated battery that has almost no useful storage capacity).

Also, the deeper you cycle the batteries, the less cycle life they will have... For example Rolls Surette's deep cycle batteries may have around 1,400 cycle life if discharged to 50% SoC and recharged the next day or so...  If you discharge to 20% SoC, perhaps 700 Cycle Life--And discharge to 75% SoC--Perhaps a 2,800 Cycle life. The deeper you cycle, the faster the battery bank will wear out.

Note that measuring resting voltage for Lead Acid batteries is not a very accurate method to determine State of Charge... Better is to use a hydrometer to measure the Specific Gravity of the electrolyte of each cell--And monitor a single "pilot cell" for quick checks.

At this point, we don't know very much about your system (brand/model of battery bank, Amp*Hour Capacity, age, etc.). We also do not know how much energy you used per day (Watt*Hours, Amp*Hours @ xx Volts), the size and location (nearest city is a good start) of your solar array, generator+charger setup/specifications, etc.

The battery bank is the "heart" of your system. You need to understand how much you discharge/recharge your battery bank on a daily basis. How well is your system working (is the solar array working as expected or do have a failed panel or wiring connection)? Are you using more power than your system can provide (wear out batteries quicker, use more fuel to keep the battery bank in a good operational range, etc.).

The battery bank is the first thing that usually gets "murdered" when things are not going "right". And batteries are not cheap these days--So taking care of them is usually a top priority.

When you "inherit" an off grid home--You need to quickly get control of the situation. Usually that means ensuring that you have energy conservation in mind. LED Lighting, an efficient refrigerator, an efficient well pump, an energy efficient laptop computer, (if you have these), and typically use other fuels (propane and such) for cooking, Hot water, space heating, etc.
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Generally, when designing an off grid system--Our rule of thumb to get started is to plan on using 1/4 of battery bank AH capacity per day (total energy usage) and have the solar array recharge the battery bank the next day. With solar, that usually means the solar array is almost 2x your daily loads (allows for winter sun, occasional guests, running a clothes washer a couple times a week, etc.). 

The idea is that you have enough solar and battery bank such that, in general, you only need to run the Genset during stormy weather or in deep winter areas (more northern areas, a few days of dark/stormy weather, etc.). In many reasonably sunny areas--You might be able to get away with almost zero Genset usage. In Alaska, Canada, etc.--In winter you are stuck with using a Genset during those long dark winter days.

Do you have anybody nearby that can help you that has off grid power system experience (installer, handy neighbor)? Did you get any information from the previous owner?

In any case--Need to get started with the basics. What and where is your system? What is your energy usage/exceptions? Do you have a hydrometer and a good quality voltmeter? Also very nice for debugging and understanding your system, an AC+DC Current Clamp DMM (digital multi-meter) is very helpful...

https://www.solar-electric.com/midnite-solar-battery-hydrometer.html
https://www.amazon.com/Battery-Testing-Hydrometer/s?k=Battery+Testing+Hydrometer (with glass construction)
https://www.amazon.com/Auto-Ranging-Resistance-Klein-Tools-CL800/dp/B019CY4FB4 (mid priced AC+DC Current Clamp DMM)

At this point, you are probably behind the curve here... If the battery bank is charged during the day, and you are drawing a "reasonable" (i.e., not very much) amount of power overnight, the generator should not be starting the Genset. There is a good chance the battery bank is failing--But it is also possible that your system is not property charging (solar, Genset, etc.).

Your system is probably on the "larger size" (48 volt Xantrex units are not "small", and should have a pretty substantial battery bank running it. And a larger (8-12 kW or so?) Gen$et will $uck down the fuel pretty quickly too.

At this point, at least you have a working (if not working well) battery bank. This gives you a few days/weeks to measure/understand your daily energy needs, how well the solar array is working, and double check the programming & operation of your Genset+Xantrex inverter-charger.

The Xantrex XW and related hardware is a complex piece of kit... You do not want to make assumptions that it is setup and running correctly--And at the same time, you do not want to just start changing settings--It is very easy to end up in the dark if you program the system incorrectly.

You are diving into the deep end of the solar pool... And this can cost you (very likely multiple) $10,000's to get the system fully operational for your needs.

Batteries (depending on brand/model/chemistry/how well maintained/how they are cycled) may last 5-8 years (FLA). Electronics (inverter, charger, etc.) 10+ years. And solar array should last 20+ years (assuming no rocks/branches breaking panels).

Your thoughts, information, etc.?

-Bill