# Wrightstown Solar - System Design **Created:** 2026-02-09 **Status:** Planning --- ## System Overview Whole-house UPS using DIY 48V LiFePO4 battery packs with Victron MultiPlus II inverter. Seamless grid-to-battery switchover with generator backup for extended outages. --- ## Cell Selection: EVE C40 | Spec | Value | |---|---| | Chemistry | LiFePO4 (LFP) | | Form Factor | 40135 Cylindrical | | Model | EVE IFR40135 / C40 | | Nominal Voltage | 3.2V | | Capacity | 20Ah (20,000mAh) | | Energy per Cell | 64Wh | | Weight | 366g | | Max Continuous Discharge | 50-60A | | Pulse Discharge | 100A | | Standard Charge | 10A | | Fast Charge | Up to 8A | | Internal Resistance (DC) | <=8 milliohm | | Internal Resistance (AC) | <=3 milliohm | | Operating Temp | 0-55C | | Certifications | CB, UL1642, UN38.3 | ### Why Cylindrical Over Prismatic - Individual cell failure is contained (easier thermal runaway management) - No compression hardware needed (prismatic cells need clamping) - Modular -- add capacity by adding parallel strings - Smaller units easier to handle - Trade-off: More connections to make, need cell holders --- ## Battery Pack Design ### Per-Pack Configuration: 16S5P | Parameter | Value | |---|---| | Series cells | 16 (51.2V nominal) | | Parallel strings | 5 | | Total cells per pack | 80 | | Pack voltage (nominal) | 51.2V | | Pack voltage (full) | 58.4V (3.65V/cell) | | Pack voltage (empty) | 48.0V (3.0V/cell cutoff) | | Pack capacity | 100Ah / 5.12kWh | | Max continuous discharge | 100A (limited by BMS) | | Weight (cells only) | ~29.3kg (80 x 366g) | ### Full System: 4 Packs (16S5P x 4) | Parameter | Value | |---|---| | Total cells | 320 | | Total capacity | 400Ah / 20.48kWh | | Packs in parallel | 4 (at DC bus) | | Total weight (cells) | ~117kg | ### Expansion Plan 1. **Pack 1** -- Build, test, run for 1 month to validate design 2. **Pack 2** -- Parallel with Pack 1 (now 10kWh) 3. **Packs 3 & 4** -- Build together once confident in process --- ## Inverter: Victron MultiPlus II 48/5000 | Spec | Value | |---|---| | Model | MultiPlus II 48/5000/70-50 | | Continuous output | 4,000W | | Peak output | 9,000W | | Transfer switch | Built-in, <20ms switchover | | AC inputs | 2 (grid + generator) | | Battery voltage | 48V nominal | | Max charge current | 70A | | Transfer relay | Physical disconnect (no backfeed) | ### Key Features for This Build - **UPS Function:** <20ms transfer time, seamless for all electronics - **Anti-Island:** Physical relay opens on grid loss, zero backfeed risk - **Generator Support:** AC Input 2 accepts generator, charges battery + powers loads simultaneously - **Micro-Grid:** Creates stable AC output that Fronius IG Plus can sync to during outages - **PowerAssist:** Supplements grid during high-demand periods ### Parallel Option Two MultiPlus II 48/5000 units in parallel provide: - 8,000W continuous / 18,000W peak - Full whole-house coverage including AC units - Consider for future expansion if single unit isn't enough --- ## GX Device: Cerbo GX | Spec | Value | |---|---| | Price | $320-350 | | BMS-CAN Port | Yes (500kbit/s) | | USB Ports | 2 (for dbus-serialbattery driver) | | Display | Built-in touchscreen or HDMI | | Connectivity | Ethernet, WiFi, Bluetooth | | Remote Monitoring | VRM Portal (free) | ### Functions - DVCC (Distributed Voltage and Current Control) -- lets BMS control charge/discharge - Battery monitoring and SOC display - Remote monitoring via Victron VRM portal - Generator auto-start/stop control - System configuration interface --- ## Existing Solar: Fronius IG Plus - **Type:** Grid-tie string inverter (NO battery port) - **Status:** Keep as-is - **Normal Operation:** Feeds solar to grid, offsets electricity bill - **During Outage:** Victron creates micro-grid, Fronius syncs to it and produces solar to charge battery and power loads - **Future:** Replace with hybrid inverter when Fronius reaches end of life --- ## System Architecture ### Normal Operation (Grid Available) ``` Solar Panels | [Fronius IG Plus] ---> Grid (net metering) | [Victron MultiPlus II] ---> House Panel | (pass-through) [48V Battery Bank] (trickle charge / standby) ``` - Fronius produces solar, feeds grid - Victron passes grid through to house - Battery maintains float charge - Victron can charge battery from grid if configured ### Grid Down (Battery Mode) ``` Solar Panels | [Fronius IG Plus] ---> [Victron MultiPlus II] ---> House Panel (syncs to | (relay OPEN, (powered from Victron | grid isolated) battery) micro-grid) | [48V Battery Bank] (discharging) ``` - Transfer relay opens (grid physically disconnected) - Battery powers house via Victron - Victron creates AC micro-grid - Fronius detects stable AC, resumes solar production - Solar charges battery + powers loads ### Extended Outage (Generator Mode) ``` [Generator] ---> [Victron MultiPlus II] ---> House Panel | [48V Battery Bank] (charging from generator) ``` - Generator connects to AC Input - Victron simultaneously powers loads AND charges battery - When battery full, can signal generator to shut down - Battery takes over, generator restarts when battery low (auto-start capable) --- ## Runtime Estimates (5kWh Single Pack) | Load Scenario | Consumption | Runtime | |---|---|---| | Essentials (fridge, lights, internet, outlets) | ~500W | 8-10 hours | | Moderate (+ TV, computers, fans) | ~1,000W | 4-5 hours | | Heavy (+ AC or electric cooking) | ~2,000W | 2-2.5 hours | | Full house (everything) | ~4,000W | 1-1.25 hours | ### At Full 20kWh (4 Packs) | Load Scenario | Runtime | |---|---| | Essentials only | 32-40 hours | | Moderate use | 16-20 hours | | Heavy use | 8-10 hours | --- ## Installation Plan ### Electrical Work Required 1. **Critical Loads Sub-Panel** -- Move essential circuits to new sub-panel (or use whole panel) 2. **Victron Placement** -- Between grid and sub-panel 3. **Battery Location** -- Garage, basement, or utility room (ventilated, temperature controlled) 4. **Generator Connection** -- Dedicated inlet with proper gauge wiring 5. **Grounding** -- Victron system ground per local code ### Safety Requirements - DC disconnect between battery and inverter - Proper fusing on each battery pack (class T fuse recommended) - Breaker on AC output - Ventilation for battery area - Fire extinguisher (Class D) nearby - Temperature monitoring on cells --- ## Cell Voltage Reference (LiFePO4) | State | Voltage/Cell | Pack Voltage (16S) | |---|---|---| | Full Charge | 3.65V | 58.4V | | ~90% SOC | 3.35V | 53.6V | | ~50% SOC | 3.30V | 52.8V | | ~20% SOC | 3.20V | 51.2V | | Low Cutoff | 3.00V | 48.0V | | Absolute Min | 2.50V | 40.0V | Note: LFP has a very flat voltage curve between 20-90% SOC (~3.2-3.35V). This makes SOC estimation from voltage alone unreliable -- coulomb counting via BMS is essential.