Difference between revisions of "CJMCU-811"
| Line 55: | Line 55: | ||
A sensor like this could be used to monitor indoor air quality at Revspace. | A sensor like this could be used to monitor indoor air quality at Revspace. | ||
| − | + | See https://github.com/bertrik/tvocmeter | |
| − | + | * pin D1 goes to CCS811 SCL | |
| − | + | * pin D2 goes to CCS811 SDA | |
| + | * pin D3 goes to CCS811 WAK | ||
| + | * pin D8 goes to CCS811 GND | ||
| + | * pin D4 goes to Neopixel DIN | ||
| + | * pin 5V goes to Neopixel VDC | ||
| + | * pin GND goes to Neopixel GND | ||
| + | Unfortunately, I can't get the neopixel strip to work yet. | ||
Some reading material: | Some reading material: | ||
Revision as of 00:12, 6 January 2019
| Project CJMCU-811 | |
|---|---|
| |
| Playing around with a breakout board for the CSS-811 IC | |
| Status | Initializing |
| Contact | bertrik |
| Last Update | 2019-01-06 |
Introduction
I bought this board from Aliexpress, it's a breakout board for the AMS CCS-811. The CCS-811 is an ultra-low power digital gas sensor for monitoring indoor air quality.
It appears what they accomplished is integration of a metal-oxide gas sensor into a tiny package so it uses very little power and has a fast response. For example, the well-known MQ-135 typically uses 750 mW just for heating the sensitive layer.
The datasheet can be found here.
It is unclear what it measures exactly. It appears to be sensitive to temperature and humidity levels too, although the chip provides a way to let it know the humidity and temperature so it can compensate for it.
Hardware
Pins on the breakout board:
- VCC this is directly connected to the IC (there is no voltage regulator on board), connect this to 3.3V
- GND to ground obviously
- SCL signal from I2C
- SDA signal from I2C
- WAK this needs to be low (!) in order for the chip to be active
- INT can be left unconnected
- RST can be left unconnected
- ADD can be left unconnected. It appears to have a 10k pull-down to GND.
My board was apparently configured at I2C address 0x5A. I'm wiring it up to a Wemos D1 mini board with an ESP8266.
Firmware update
There is a firmware update available for the microcontroller inside the CCS811. My board shipped with the V1.1 version. I flashed it to the V2.0 version with this firmware updater by Maarten Pennings.
The newer 2.0 firmware fixes the upper range of eTVOC. In the older version, the maximum measured concentration is 1156 bpm, this limit is gone with the 2.0 firmware.
Software
I found the following libraries (in order of preference, top one most likely to use):
Interesting projects using it together with a BME280:
- https://github.com/maarten-pennings/CCS811/tree/master/examples/ccs811envdata
- https://github.com/codmpm/esp-ccs811-bme280-mqtt
- https://github.com/sparkfun/SparkFun_CCS811_Arduino_Library/blob/master/examples/Example2_BME280Compensation/Example2_BME280Compensation.ino
Application to air quality monitoring at RevSpace
A sensor like this could be used to monitor indoor air quality at Revspace.
See https://github.com/bertrik/tvocmeter
- pin D1 goes to CCS811 SCL
- pin D2 goes to CCS811 SDA
- pin D3 goes to CCS811 WAK
- pin D8 goes to CCS811 GND
- pin D4 goes to Neopixel DIN
- pin 5V goes to Neopixel VDC
- pin GND goes to Neopixel GND
Unfortunately, I can't get the neopixel strip to work yet.
Some reading material:
- Sara HÖgdahl, "Placing VOC Sensors for Assessing Air Quality - A CFD Study of Indoor VOC Distribution", MJ243X Degree project in Sustainable Buildings, second level, 2018-06-13, Stockhom.
- Ultrafine particles from 3d printing: https://www.3ders.org/images2016/new-study-shows-that-3d-printing-in-confined-spaces-can-be-bad-for-your-health-3.jpg
- Volatile organic compounds from 3d printing: https://www.3ders.org/images2016/new-study-shows-that-3d-printing-in-confined-spaces-can-be-bad-for-your-health-4.jpg
