B2500 Meter

This project replicates a Smart Meter device for a B2500 energy storage system while allowing integration with various smart meters.

Getting Started

Prerequisites

1. Python Installation: Make sure you have Python 3.7 or higher installed. You can download it from the official Python website.

2. Configuration: Create a config.ini file in the root directory of the project and add the appropriate configuration as described in the Configuration section.

Windows

1. Open Command Prompt

   • Press Win + R, type cmd, and hit Enter.

2. Navigate to the Project Directory

   cd path\to\b2500-meter

3. Install Dependencies

   pipenv install

4. Run the Script

   pipenv run python main.py

macOS

1. Open Terminal

   • Press Cmd + Space, type Terminal, and hit Enter.

2. Navigate to the Project Directory

   cd path/to/b2500-meter

3. Install Dependencies

   pipenv install

4. Run the Script

   pipenv run python main.py

Linux

1. Install Dependencies

   pipenv install

2. Run the Script

   pipenv run python main.py

Additional Notes

When the script is running, switch your B2500 to "Self-Adaptation" mode to enable the powermeter functionality.

Configuration

The configuration is managed using an ini file called config.ini. Below, you'll find the configuration settings required for each supported powermeter type.

General Configuration

Optionally add a general section with the option to enable or disable summation of phase values.

[GENERAL]
# By default, the script will sum the power values of all phases and report them as a single value on phase 1. To disable this behavior, add the following configuration to the `config.ini` file
DISABLE_SUM_PHASES = False
# Setting this to true, disables the powermeter test at the beginning of the script.
SKIP_POWERMETER_TEST = False
# By default, the script sends an absolute value of the measured power. This seems to be necessary for the storage system, since it can't handle negative values (results in an integer overflow). Set this to true to clamp the values to 0 instead of sending the absolute value.
DISABLE_ABSOLUTE_VALUES = False
# Sets the interval at which the script sends new power values to the B2500 in seconds. The original Smart Meter sends new values every second.
POLL_INTERVAL = 1

Shelly

Shelly 1PM

[SHELLY]
TYPE = 1PM
IP = 192.168.1.100
USER = username
PASS = password
METER_INDEX = meter1

Shelly Plus 1PM

[SHELLY]
TYPE = PLUS1PM
IP = 192.168.1.100
USER = username
PASS = password
METER_INDEX = meter1

Shelly EM

[SHELLY]
TYPE = EM
IP = 192.168.1.100
USER = username
PASS = password
METER_INDEX = meter1

Shelly 3EM

[SHELLY]
TYPE = 3EM
IP = 192.168.1.100
USER = username
PASS = password
METER_INDEX = meter1

Shelly 3EM Pro

[SHELLY]
TYPE = 3EMPro
IP = 192.168.1.100
USER = username
PASS = password
METER_INDEX = meter1

Tasmota

[TASMOTA]
IP = 192.168.1.101
USER = tasmota_user
PASS = tasmota_pass
JSON_STATUS = StatusSNS
JSON_PAYLOAD_MQTT_PREFIX = SML
JSON_POWER_MQTT_LABEL = Power
JSON_POWER_INPUT_MQTT_LABEL = Power1
JSON_POWER_OUTPUT_MQTT_LABEL = Power2
JSON_POWER_CALCULATE = True

Shrdzm

[SHRDZM]
IP = 192.168.1.102
USER = shrdzm_user
PASS = shrdzm_pass

Emlog

[EMLOG]
IP = 192.168.1.103
METER_INDEX = 0
JSON_POWER_CALCULATE = True

IoBroker

[IOBROKER]
IP = 192.168.1.104
PORT = 8087
CURRENT_POWER_ALIAS = Alias.0.power
POWER_CALCULATE = True
POWER_INPUT_ALIAS = Alias.0.power_in
POWER_OUTPUT_ALIAS = Alias.0.power_out

HomeAssistant

[HOMEASSISTANT]
IP = 192.168.1.105
PORT = 8123
HTTPS = True
ACCESSTOKEN = YOUR_ACCESS_TOKEN
CURRENT_POWER_ENTITY = sensor.current_power
POWER_CALCULATE = True
POWER_INPUT_ALIAS = sensor.power_input
POWER_OUTPUT_ALIAS = sensor.power_output

VZLogger

[VZLOGGER]
IP = 192.168.1.106
PORT = 8080
UUID = your-uuid

ESPHome

[ESPHOME]
IP = 192.168.1.107
PORT = 6052
DOMAIN = your_domain
ID = your_id

AMIS Reader

[AMIS_READER]
IP = 192.168.1.108

Modbus TCP

[MODBUS]
HOST = 192.168.1.100
PORT = 502
UNIT_ID = 1
ADDRESS = 0
COUNT = 1

MQTT

[MQTT]
BROKER = broker.example.com
PORT = 1883
TOPIC = home/powermeter
JSON_PATH = $.path.to.value (Optional for JSON payloads)
USERNAME = mqtt_user (Optional)
PASSWORD = mqtt_pass (Optional)

The JSON_PATH option is used to extract the power value from a JSON payload. The path must be a valid JSONPath expression. If the payload is a simple integer value, you can omit this option.

Modbus

[MODBUS]
IP =
PORT =
UNIT_ID =
REGISTER =

Script

You can also use a custom script to get the power values. The script should output at most 3 integer values, separated by a line break.

[SCRIPT]
COMMAND = /path/to/your/script.sh

Node-RED Implementation

This project also provides a Node-RED implementation, allowing integration with various smart meters. The Node-RED flow is available in the nodered.json file.

Installation and Setup

1. Import the Node-RED Flow

   • Open your Node-RED dashboard.
   • Navigate to the menu in the top right corner, select "Import" and then "Clipboard".
   • Copy the content of nodered.json and paste it into the import dialog, then click "Import".

2. Hooking Powermeter Readings

   • Ensure your powermeter readings are available as a Node-RED message with the power values in the payload.
   • Connect the output of your powermeter reading nodes to the input node of the subflow named "B2500". The subflow can handle:
     • An array of 3 numbers or strings containing numbers, representing the power values of each phase, e.g. [100, 200, 300].
     • A single number or string containing a number, which will be interpreted as the value for the first phase, with the other two phases set to 0.
   • Ensure that a fresh powermeter reading is sent to the flow every second.

3. Running the Flow

   • Deploy the flow by clicking the "Deploy" button on the top right corner of the Node-RED dashboard.
   • The flow will now listen for powermeter readings and handle the UDP and TCP communications as configured.

License

This project is licensed under the General Public License v3.0 - see the LICENSE file for details.