Attention!!! 0.0.6 changed some of the pins and is not 100% compatible anymore. Please keep in mind, when using the ESPhome YAML or when implementing your own firmware.

If you need to assemble a few parts (ECAPs and optional stuff) or flash another firmware, watch my video on YouTube.

Introduction

At first, do not get confused, KM217 and KM271 ist the same, I just had a number swap in and it is simply impossible to change all the historic stuff and naming 🙁

If you ordered the module described in Reverse Engineering the Buderus KM271 – And Making It WiFi-Flying on ESPhome and Home Assistant from my Tindie store or built it on your own, this is the place to search for, when it comes to getting it up and running. You will find the Information for both versions (0.0.5 and 0.0.6 here). Version 0.0.6 is already available and can be ordered.

Known compatible Heating Control Units

  • Buderus Logamatic 2107 M (this is my own unit)
  • Logamatic HS2102 (not EcoMatic !!!)

If you have one of my boards and a different control unit that works, please tell me about, so I can add it to this list 🙂 If you are not 100% sure, I have still plenty of old bare 0.0.5-Boards for a very low price. Antoher option is to print one of the PCB pages with 1:1 scale, glue it on a cardboard cut it out and test if it fits in your heating controller.

The Hardware

To make your life easier for aseembly and to find the parts and signals, here is the interactie BOM.

The Software

There is a ton of software alternatives for the board, but I’ll only describe three of them in more detail. You can select the firmware when you order the board.

Default, no FW selected: Blinkenlights

At first, I’ll just tell you, what is on the board, when you did not select any firmware during your order on Tindie. It is a simple test program, that ensures, that the ESP32 and the LEDs are working.

It does nothing more than rolling through the 4 LEDs on the board.

It will be possibly extended in future to catch hardware and assembly bugs, should they arise in future.

You can find it on GitLab. Use VSCode with PlatformIO to open, compile and flash it. This is also a very nice foundation for developing your own firmware.

Flashing can be done, by connecting power, ground, RX and TX. IO0 and EN is not needed and can be triggered with the buttons. Press BOOT and keep it pressed, shortly press RESET and start your flash tool. Then release BOOT and flashing will start.

I’ll possibly improve the Blinkenlight to be able to update the board via WiFi or BLE. If you feel responsible to do this, I would be happy to take the pull request. If I get a working firmware, the minimal thing I would do is refunding the board you bought from me 🙂

Sven’s great MQTT-firmware

Sven published a firmware on GitHub for my module that speaks MQTT on the network. This was probably the most complete piece of code for my module before JEns accepted the challenge on the ESPhome part. The „only thing“ you need to do is installing VSCode and the PlatformIO addon, set the credentials for WiFi, MQTT and OTA (in include/Credentials.h), compile and flash it to the board.

ESPhome

If you selected ESPhome, you will get an (older) ESPhome firmware version for this board. But as you will update the firmware after adjusting the config, you will have the latest firmware aligned with your ESPhome instance. Currently, the firmware is likely to be feature complete and runs without problems. See the section below, ho to connect to your board.

Diggers Full Example YAML (Drop Down Accordeon)

esphome:
  name: buderus-km217
  platform: ESP32
  board: esp32dev

# Enable logging
logger:

# Enable Home Assistant API
api:

ota:
  password: "XYZ"

wifi:
  ssid: !secret wifi_ssid
  password: !secret wifi_pass

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

captive_portal:

uart:
  id: uart_bus
  tx_pin: GPIO2
  rx_pin: GPIO4
  baud_rate: 2400

external_components:
#  - source:
#      type: local
#      path: my_components/components
#    components: [ km271_wifi ]
  - source: github://the78mole/esphome_components@main
    components: [ km271_wifi ]
 

km271_wifi:
  - id: budoil
    uart_id: uart_bus

# SPI starting from version 0.0.6
spi:
  clk_pin: GPIO18
  mosi_pin: GPIO23
  miso_pin: GPIO19
  id: bus_spi1

# nCS for SPI is GPIO15

i2c:
  sda: GPIO13
  scl: GPIO16
  scan: true
  id: bus_i2c1

# For version 0.0.6
# For triggered actions, I2C devices can use GPIO14
# To enable the I2C level shifter (I2C_EXT_EN), use GPIO 12

status_led:
  id: ledgn1
  pin: 
    number: GPIO21
    inverted: true

number:
  - platform: km271_wifi
    warm_water_temperature:
      name: "Warmwassersolltemperatur Tag"

select:
  - platform: template
    name: "Warmwasser Betriebsart"
    id: warmwasser_betriebsart
    entity_category: config
    optimistic: true
    options:
      - Dauerhaft aus (0)
      - Dauerhaft ein (1)
      - Automatik (2)
    initial_option: Automatik (2)
    set_action: 
      - lambda:
          auto index = id(warmwasser_betriebsart).index_of(x);
          if (index.has_value()) {
            uint8_t command[] = {0x0C, 0x0E, (uint8_t)index.value(), 0x65, 0x65, 0x65, 0x65, 0x65};
            budoil->writer.enqueueTelegram(command, 8);
          }

binary_sensor:
  - platform: km271_wifi
    boiler_error:
      name: "KM271 Kesselfehler"
    boiler_running:
      name: "KM271 Kesselbetrieb"
    load_pump_running:
      name: "KM271 Ladepumpe"

sensor:
  - platform: km271_wifi
    heating_circuit_1_flow_target_temperature:
      name: "KM271 Vorlaufsolltemperatur"
    heating_circuit_1_flow_temperature:
      name: "KM271 Vorlauftemperatur"
    hot_water_target_temperature:
      name: "KM271 Warmwassersolltemperatur"
    hot_water_temperature:
      name: "KM271 Warmwassertemperatur"
    boiler_target_temperature:
      name: "KM271 Kesselvorlaufsolltemperatur"
    boiler_temperature:
      name: "KM271 Kesselvorlauftemperatur"
    outdoor_temperature:
      name: "KM271 Außentemperatur"
    heating_circuit_1_room_target_temperature:
      name: "KM271 Raumsolltemperatur"
    heating_circuit_1_curve_n10:
      name: "KM271 Heizkurve -10 °C"
    heating_circuit_1_curve_0:
      name: "KM271 Heizkurve 0 °C"
    heating_circuit_1_curve_p10:
      name: "KM271 Heizkurve +10 °C"
    boiler_turn_on_temperature:
      name: "KM271 Brennereinschalttemperatur"
    boiler_turn_off_temperature:
      name: "KM271 Brennerausschalttemperatur"

  - platform: wifi_signal
    name: "KM217 WiFi Signal Sensor"
    update_interval: 60s

  - platform: adc
    pin: 36
    unit_of_measurement: "V"
    name: "KM217 5V Supply"
    accuracy_decimals: 2
    update_interval: 5s
    attenuation: 6dB
    filters:
      - multiply: 27.7317
      - throttle_average: 60s
      
switch:
  - platform: gpio
    name: LED2_Green
    pin: 
      number: 22
      mode: OUTPUT
      inverted: true
  - platform: gpio
    name: LED3_Yellow
    pin: 
      number: 17
#     number: 23  # For 0.0.5
      mode: OUTPUT
      inverted: true
  - platform: gpio
    name: LED4_Red
    pin: 
      number: 25
      mode: OUTPUT
      inverted: true

Connecting to the board

I configured the ESPhome firmware to run a captive portal after approx one minute. So, after powering the board, you could (after one minute) connect to the SSID „Fallback Hotspot“. Turn of your cellular internet (it disturbs the WiFi very often) and select the Fallback (password is "Z8zfajgxVvNw"). When WiFi of your phone is connected (sometimes you need some tries), a pop-up should ask you to sign in to the network. Follow this. It will present the portal of the ESPhome firmware and show you all WiFis it has found. Select the appropriate one and enter the password of this WiFi.

When the module is correctly connected to the network, it should soon show up as a new ESPhome board in your Home Assistant. Sometimes, you need to wait for a few minutes for the notification to show up. When adopted, you will see it in your ESPhome devices overview and can enter adjust the YAML to your needs. New sensor nodes will also take a few minutes to be shown sometimes.

The relevant part of the YAML is as follows:

esphome:
  name: km217-for-friends
  platform: ESP32
  board: esp32dev

# Enable logging
logger:

# Enable Home Assistant API
api:

ota:

wifi:
  ssid: "<YOUR WIFI SSID>"
  password: "<YOUR WIFI PASSPHRASE>"

  # Enable fallback hotspot (captive portal) in case wifi connection fails
  ap:
    ssid: "Fallback Hotspot"
    password: "Z8zfajgxVvNw"

Hardware Extensions

Exhaust Sensor

The Exhaust sensor is a simple 100 kOhm NTC-Resistor type, as you can order it e.g., at sensorshop24. In my case, I select the following options:

I realized, that the 25°C is very precise, but when the burner is working, my readings at 150°C are 15-20°C below the values the chimney sweeper is measuring with his calibrated device. The reason for this is most likely the characteristic curve, which is standardized for PT-Type (PT100, PT500, PT1000) temperature dependent resistors, but not for NTC. They are only defined at 25°C with their nominal value (here 100 kOhm), but not their B-value. But with ESPhome, you could easily correct this by filters for the sensor.

Other Settings

Renaming the module should be done using ESPhome GUI

For more detailed information, see my blog about the development of the module.

Using Arduino with MQTT

Coming soon 🙂

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28. September 2024

Hallo Daniel, vielen Dank für dieses tolle Projekt. Ich hoffe, damit meine Logamatic 4212 in Home Assistant einbinden zu können. Ist denn geplant, dass man das fertige Board noch einmal bei Dir bestellen kann?

Fabian

Antwort von MolesBlog

Hallo Fabian,

üblicherweise warte ich immer, bis 50 Interessenten auf der Warteliste stehen. Dann ordere ich 100 Stück (Lieferzeit etwa 1 Monat) und diese verkaufe ich dann in den nächsten ca. 3 Monaten ab. Allerdings ist die Nachfrage mittlerweile eher Rückläufig, daher erwarte ich, dass es noch 1-2 Monate (oder länger) dauern wird, bis es wieder so weit ist.

Grüße,

Daniel (der freundliche Maulwurf aus Deinem Blumenbeet… BTW: lecker)

replace the BFU

25. August 2024

Hello Daniel,

I am very interrested in your KM271 replacement and I would like to install it on my Buderus 2107 (don’t know if it is M or not, but I understand it works for both) and to integrate it with my existing Home Assistant set up. I am curently using a Buderus BFU Thernmostat and my quesstions at this point are as follows :

– will I be able to replace the BFU and control the room temperature with Home assistant?

– Can leave the BFU as is or will I need to disconnect it to avoid conflicts?

– or perhaps can I leave the BFU and set it at a very low temprature to keep the contact open?

Thank you for this and all the exellent work you have done on this topic.

Best regards,

Pierre Pichery

Pierre Pichery

Antwort von MolesBlog

Hello Pierre,

the BFU functionality can not be replaced by the KM271, but it can be installed in parallel. They address different aspects of the heating system. But I have no BFU myself, so I can only tell what I know from other users.

Regards,

Daniel

Nachschub

7. März 2024

Hi!

Wann meinst Du, wäre eine neue Lieferung bereit?

Meine Buderus macht während der Heizzeit immer das Warmwasser mit.

Das macht mich noch wahnsinnig 😀

Grüße

Dustin

Antwort von MolesBlog

Hallo Dustin,

aktuell sieht es nach Ende März aus. Die PCBs scheinen fertig zu sein, aber die Bestückung dauert meiner Erfahrung nach immer einige Tage (aktuell bei 5%). Bauteile müssen bestellt und zugordnet, Bestückungsmaschinen eingerichtet, Muster bestückt, Qualität kontrolliert,… und die Produktion durchgeführt werden. Und dann kommt natürlich noch DHL ins Spiel mit Zollabfertigung und so Quatsch…

Grüße,

Daniel