This library uses the Arduino Serial library to communicate with a DALY BMS over UART. It was originally designed for use with the Teensy 4.0 as a part of this project and has not been tested on official Arduino hardware.
-Download a zip of this library using the green button above
-Follow the instructions here under "Manual installation"
-Use the public functions defined in "daly-bms-uart.h" to read data from the BMS and populate the "get" struct
-Don't forget to construct a Daly_BMS_UART object and Init()!
-See the example that's included in this library
Below is a picture of the side of my DALY bms (yours might look slightly different) showing which pins are used to communicate over UART. I used this library on a teensy 4.0, who's serial pins are only 3V tolerant, so I also used this logic level shifter to bring the logic level up to 5V, which is what I observed while using the PC UART USB adapter included with the BMS.
I found the UART Protocol used by the Daly BMS described in the PDF inside /docs/ on diysolarform.com. It can be a little tough to decipher, so here's a brief overview.
Here's what an outgoing packet will look like. It's always fixed 13 bytes, and the reference manual from Daly doesn't mention anything about how to write data so the "Data" section of outgoing packets is just always going to be 0. See "Future Improvements" below for more on this.
Start Byte | Host Address | Command ID | Data Length | Data | Checksum |
---|---|---|---|---|---|
0xA5 | 0x80 | See below | 0x08 (fixed) | 0x0000000000000000 (8 bytes) | See below |
This is what an incoming packet might look like. In this case it's the "Voltage, Current, and SOC" command.
Start Byte | Host Address | Command ID | Data Length | Data | Checksum |
---|---|---|---|---|---|
0xA5 | 0x01 | 0x90 (see below) | 0x08 (fixed?*) | 0x023A0000753001ED (8 bytes) | 0x0D (See below) |
*It's not made totally clear in the protocol description but the received data length might actually be longer for certain commands. Reading all cell voltages & all temperature sensor readings for instance results in a response with a much longer data section.
The first two bytes of the Data correspond to the Voltage in tenths of volts (0x023A = 570 = 57.0V). I'm honestly not sure what the next two bytes are for, the documentation calls them "acquisition voltage". They always come back 0 for me so lets skip them. The next two bytes are the current in tenths of amps, with an offset of 30000 (0x7530 = 300000 - 30,000 = 0 = 0.0A). The final two bytes are the state of chare (or SOC) in tenths of a percent (0x01ED = 493 = 49.3%).
The last byte of the packet is a checksum, which is calculated by summing up all the rest of the bytes in the packet and truncating the result to one byte. (0xA5 + 0x01 + 0x90 + ... + 0xED = 0x30D = 0x0D).
Here's an overview of the commands that are supported by this library. See the full protocol info in /docs/ for more info.
Command | Hex | Support API |
---|---|---|
Voltage, Current, SOC | 0x90 | getPackMeasurements() |
Min & Max Cell Voltages | 0x91 | getMinMaxCellVoltage() |
Min & Max Temp Sensor readings | 0x92 | getPackTemp() will take the min and max temperature readings, average them, and return that value. Most of the DALY BMSs that I've seen only have one temperature sensor. |
Charge/Discharge MOSFET state | 0x93 | getDischargeChargeMosStatus() |
Status Information 1 | 0x94 | getStatusInfo() |
Individual Cell Voltages | 0x95 | getCellVoltages() |
Temperature Sensors | 0x96 | getCellTemperature() |
Cell Balance States | 0x97 | getCellBalanceState() |
Failure Codes/Alarms | 0x98 | getFailureCodes() |
- The BMS has no internal power source, and needs to be connected to the battery for the UART communication to work.
- Make sure your Tx/Rx aren't mixed up, in the picture above Tx/Rx are labeled with respect to the BMS.
- I could not have made this work/debugged this without a logic analyzer hooked up to the UART lines to see what's going on. They can be had pretty cheaply and are an invaluable tool for working on these kinds of things.
- Uncomment this define and set your Serial port to get lots of debug printing to the Arduino Serial Monitor. I added these statements to help as I developed the code and ran into issues. Beyond that, I've done my best to comment extensively.
First & foremost there are a lot of wacky things in this repo that work, but are not done the best possible way. Cleaning things up and correcting bad coding practices would help maintainability & make tinkering with the library more approachable.
The protocol description (see /docs/) doesn't mention anything about how to write data to the BMS, but it must be possible because the PC application (see /pc-software/) can set the parameters of the BMS. I've included some logic analyzer captures of communication between the BMS and PC application that someone can probably use to reverse engineer the protocol. I'm certain it's pretty simple, I honestly wouldn't be surprised if it were just the reading protocol with some small tweak.
Update 4/22: softwarecrash added the ability to send commands to enable/disable the charge/discharge MOSFETs, which is awesome. I think there's even more to add here.
maland16 - Created the repo, laid the groundwork
softwarecrash - Redesigned the "getters", added a ton of new functionality
pricemat - Cpp consultant, moral support