esphome-mitsubishiheatpump

Wirelessly control your Mitsubishi Comfort HVAC equipment with an ESP8266 or ESP32 using the ESPHome framework.

Features

Instant feedback of command changes via RF Remote to HomeAssistant or MQTT.
Direct control without the remote.
Uses the SwiCago/HeatPump Arduino libary to talk to the unit directly via the internal CN105 connector.

Requirements

https://github.com/SwiCago/HeatPump
ESPHome 1.15.0-dev or greater

Supported Microcontrollers

This library should work on most ESP8266 or ESP32 platforms. It has been tested with the following MCUs:

Generic ESP-01S board (ESP8266)
WeMos D1 Mini (ESP8266)
Generic ESP32 Dev Kit (ESP32)

Supported Mitsubishi Climate Units

The underlying HeatPump library works with a number of Mitsubishi HVAC units. Basically, if the unit has a CN105 header on the main board, it should work with this library. The HeatPump wiki has a more exhaustive list.

The same CN105 connector is used by the Mitsubishi KumoCloud remotes, which have a compatibility list available.

The whole integration with this libary and the underlying HeatPump has been tested by the author on the following units:

MSZ-GL06NA
MFZ-KA09NA

Usage

Step 1: Build a control circuit.

Build a control circuit with your MCU as detailed in the SwiCago/HeatPump README. You can use either an ESP8266 or an ESP32 for this.

Note: several users have reported that they've been able to get away with not using the pull-up resistors, and just directly connecting a Wemos D1 mini to the control board via CN105.

Step 2: Use ESPHome 1.15.0-dev or higher

The code in this repository makes use of a number of features in the as-yet unreleased 1.15.0 version of ESPHome, including various Fan modes.

Step 3: Clone this repository into your ESPHome configuration directory

This repository needs to live in your ESPHome configuration directory, as it doesn't work correctly when used as a Platform.IO library, and there doesn't seem to be an analog for that functionality for ESPHome code.

On Hass.IO, you'll want to do something like:

Change directories to your esphome configuration directory.
mkdir -p src
cd src
git clone https://github.com/geoffdavis/esphome-mitsubishiheatpump.git

Step 4: Configure your ESPHome device with YAML

Create an ESPHome YAML configuration with the following sections:

esphome: libraries: [https://github.com/SwiCago/HeatPump]
esphome: includes: [src/esphome-mitsubishiheatpump]
climate: - set up a custom climate entry, change the Serial port as needed.
ESP8266 only: logger: baud_rate: 0 - disable serial port logging on the sole ESP8266 hardware UART

The custom climate definition should use platform: custom and contain a lambda block, where you instanciate an instance of the MitsubishiHeatPump class, and then register it with ESPHome. It should allso contain a "climates" entry. On ESP32 you can change &Serial to &Serial1 or &Serial2 and re-enable logging to the main serial port.

If that's all greek to you, here's an example. Change "My Heat Pump" to whatever you want.

climate:
  - platform: custom
    lambda: |-
      auto my_heatpump = new MitsubishiHeatPump(&Serial);
      App.register_component(my_heatpump);
      return {my_heatpump};
    climates:
      - name: "My Heat Pump"

Note: this component DOES NOT use the ESPHome uart component, as it requires direct access to a hardware UART via the Arduino HardwareSerial class. The Mitsubishi Heatpump units use an atypical serial port setting ("even parity"). Parity bit support is not implemented in any of the existing software serial libraries, including the one in ESPHome. There's currently no way to guarantee access to a hardware UART nor retrieve the HardwareSerial handle from the uart component within the ESPHome framework.

Example configuration

Below is an example configuration which will include wireless strength indicators and permit over the air updates. You'll need to create a secrets.yaml file inside of your esphome directory with entries for the various items prefixed with !secret.

esphome:
  name: denheatpump
  platform: ESP8266
  board: esp01_1m
  # Boards tested: ESP-01S (ESP8266), Wemos D1 Mini (ESP8266); ESP32 Wifi-DevKit2

  libraries:
    - SwiCago/HeatPump

  includes:
    - src/esphome-mitsubishiheatpump

wifi:
  ssid: !secret wifi_ssid
  password: !secret wifi_password

  # Enable fallback hotspot (captive portal) in case wifi connection fails
  ap:
    ssid: "Denheatpump Fallback Hotspot"
    password: !secret fallback_password

captive_portal:

# Enable logging
logger:
  # ESP8266 only - disable serial port logging, as the HeatPump component
  # needs the sole hardware UART on the ESP8266
  baud_rate: 0

# Enable Home Assistant API
api:

ota:

# Enable Web server.
web_server:
  port: 80

  # Sync time with Home Assistant.
time:
  - platform: homeassistant
    id: homeassistant_time

# Text sensors with general information.
text_sensor:
  # Expose ESPHome version as sensor.
  - platform: version
    name: denheatpump ESPHome Version
  # Expose WiFi information as sensors.
  - platform: wifi_info
    ip_address:
      name: denheatpump IP
    ssid:
      name: denheatpump SSID
    bssid:
      name: denheatpump BSSID

# Sensors with general information.
sensor:
  # Uptime sensor.
  - platform: uptime
    name: denheatpump Uptime

  # WiFi Signal sensor.
  - platform: wifi_signal
    name: denheatpump WiFi Signal
    update_interval: 60s


climate:
  - platform: custom
    # ESP32 only - change &Serial to &Serial1 or &Serial2 and remove the
    # logging:baud_rate above to allow the built-in UART0 to function for
    # logging.
    lambda: |-
      auto my_heatpump = new MitsubishiHeatPump(&Serial);
      App.register_component(my_heatpump);
      return {my_heatpump};
    climates:
      - name: "Den Heat Pump"

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