Group: Cubic
Catalog excerpts
SPECIFICATION Product Name: Single Beam NDIR CO2 Sensor Module Item No.: CM1106SH Version: V0.2 Date: April 14, 2020
Open the catalog to page 1Single Beam NDIR CO2 Sensor Module CM1106SH Applications ▪ HVAC industry ▪ IAQ monitor ▪ Air purifier ▪ Automotive ▪ IoT devices ▪ Plant growth Description CM1106SH is a single beam NDIR CO2 sensor module, based on non-dispersive infrared (NDIR) technology, which can detect CO2 concentration of indoor air. With high accuracy, high stability, small size, it is widely used for ventilation system, air purifier, air conditioner, HVAC transmitter, IAQ monitor, etc. ▪ NDIR technology with independent intellectual property ▪ High accuracy, long term stability, long life (>10years) ▪ Temperature...
Open the catalog to page 3Note 1: Sensor is designed to measure in the range 0-10000ppm (UART) with specified in the table. Nevertheless exposure to concentrations below 400ppm may result in incorrect operation of ABC algorithm and shall be avoided for model with ABC ON. Note 2: In normal IAQ applications, accuracy is defined with 0°C -50°C ,0-85%RH, 0-2000ppm and after minimum three (3) ABC periods of continuous operation with ABC on. Some industrial applications do require maintenance. Contact Cubic for further information. Note 3: Specification is referenced to certified calibration mixtures. Uncertainty of...
Open the catalog to page 4Dimensions and Connector 1. Dimensions (Unit mm, tolerance ±0.2 mm) Power supply output (+3.3V/100mA) Power supply input (4.5V-5.5V) Power supply input (GND) UART-RX (Receiving)/I²C data, compatible with 3.3V and 5V communication UART-TX (Sending)/I²C clock, Compatible with 3.3V communication Output mode exchange: High level or floating is UART communication mode, low level is I²C communication mode Manual calibration
Open the catalog to page 5Typical Application Circuit Application scene: UART TTL serial port output Description of Calibration Auto Calibration: Rough installing and influence of transportation might result in a reducing of sensor reading accuracy and zero drift, sensor will correct the drift by the built-in self-correcting logic. Powering on the sensor for 15 days continuously, it will record the lowest CO2 concentration measurement value during these 15 days. Sensor will do auto calibration after 15 days and will regard the outdoor fresh air CO2 concentration (400ppm) as baseline. In order to ensure the reading...
Open the catalog to page 6PWM and Alarm Output PWM cycle: 1004ms Positive pulse width: 0-5000: (PPM/5) + 2ms CO2 concentration detection value: 500ppm range: (PWM Positive pulse width -2) *5 PWM output schema: Alarm Output If the CO2 concentration rises up to more than 1000ppm, the alarming will be triggered and output high level. When the CO2 concentration goes down to below 800ppm, the alarming will stop and output low level. Note Connect the pin of PWM to the oscilloscope. Add a pull-up resistor around 5K-10K between the pin of PWM and power supply.
Open the catalog to page 7Product Installation 1. In order to ensure airflow diffusion into the sensor inner, make sure the minimum distance between the area of waterproof filter and the other components is 1.5 mm, otherwise, quick response time of the sensor will be effected. Reference as below: 2. To avoid the influence of stress on sensor, please soldering by hand as much as possible when mounting the sensor to the PCB. Reference as below:
Open the catalog to page 81).The data in this protocol is all hexadecimal data. Example: “46” for decimal [70]. 2). Baud rate: 9600, Data Bits: 8, Stop Bits: 1, Parity: No, Flow control: No. 3). [x x] is for single-byte data (unsigned, 0-255); for double data, high byte is in front of low byte. Sending format of test software:
Open the catalog to page 94.1 Read Measured Result of CO2 Send: 11 01 01 ED Response: 16 05 01 DF1- DF4 [CS] Function: Read measured result of CO2 (Unit: ppm) Note: CO2 measured result = DF1*256+DF2 DF3 DF4 is reserved Example: Response: 16 05 01 02 58 00 00 8A Explanation: Hex is converted to decimal: 02 is 02; 58 is 88 CO2 concentration =02*256+88 = 600ppm 4.2 Open/Close ABC and Set ABC Parameter Send: 11 07 10 DF1 DF2 DF3 DF4 DF5 DF6 CS Response: 16 01 10 D9 Explanation: DF1: reserved, default 100 (0x64) DF2: open/close auto calibration (0: open; 2: close) DF3: calibration cycle (1-30 days optional, default is 15...
Open the catalog to page 104.2.3 Change the Calibration Cycle The calibration cycle is 15 days by default. For example, if you want to change the calibration cycle to 10 days, you should set the DF3=10. Example: Send: 11 07 10 64 00 0A 01 90 64 75 Response: 16 01 10 D9 4.3 Calibration of CO2 Concentration Send: 11 03 03 DF1 DF2 CS Response: 16 01 03 E6 Function: Calibration of CO2 concentration Note: 1. Calibration target value = DF1*256+DF2 Unit: PPM, range (400-1500ppm) 2. Before calibration, please make sure CO2 concentration in current ambient is calibration target value. Keeping this CO2 concentration for two 2...
Open the catalog to page 111. Timing Diagram Introduction 1.1 Common Description a. This protocol is based on standard I2C timing sequence, the clock frequency is 10kHz~400kHz. b. Use big-endian format, the most significant bit to be sent first. 1.2 I2C Sequence Diagram Introduction Item fSCL (SCL clock frequency) tHD.STA (hold time of the starting bit) tSU.STA (setup time of the starting bit) tHD.DAT (hold time of the data) tSU.DAT (setup time of the data ) tSU.STO (setup time of the stop bit) Note: SCL clock frequency is generated by the master device with the range 10khz~400khz.
Open the catalog to page 121.3 Basic Data Transmission Formats S Picture 2: The general data format sends from the master device to the slave S Picture 3: The general data format received from the slave device to the master device The meaning of the symbol in picture 1.2 and picture 1.3: S: start condition SA: slave address W: write bit R: read bit A: acknowledge bit ~A: not acknowledge bit D: data, each data is 8bit P: stop condition Shadow: The signal generated from the master device No Shadow: The signal generated from the slave device 1.4 Timing Diagram Picture 4: The address byte sent from the master device...
Open the catalog to page 131.5 Notes The performance of the MCU which is used in the sensor is not very high. If you use I/O port to simulate I2C master device, it is suggested to reserve a period before and after ACK signal (such as 100 us), after sending every byte (8 bit) to leave enough time for the SCM to process the data. Within requirements of speed, it is recommended to lower the reading speed as much as possible. CO2 measuring result: DF0*256+DF1, Fixed output is 550ppm during preheating period
Open the catalog to page 14All Cubic Sensor and Instrument Co. catalogs and technical brochures
-
Cubic TDLAS CH4 Sensor
4 Pages
-
Gasboard-7500H-OPC
13 Pages
-
NDIR CO2 Sensor Module-CM1106LS
18 Pages
-
Laser Particle Sensor-PM2008M-M
22 Pages
-
Laser Particle Sensor-PM2012
19 Pages
-
Test Instruction of AM4100-I
7 Pages
-
Test Instruction of AM1008W
7 Pages
-
Test Instruction of PM5000
7 Pages
-
Test Instruction of PM1006
8 Pages
-
Test Instruction of CM1107T
7 Pages
-
Test Instruction of CM1107BN
8 Pages
-
Test Instruction of PM3006T
7 Pages
-
Test Instruction of PM2009
8 Pages
-
Test Instruction of CM1106SH
8 Pages
-
Test Instruction of CM1107
8 Pages
-
Test Instruction of CM1106S
8 Pages
-
Test Instruction of CM1106LS
8 Pages
-
Laser Particle Sensor-PM2008
21 Pages
-
Laser Particle Sensor-PM2009
20 Pages
-
Laser Particle Sensor-PM2105-M
20 Pages
-
NDIR CO2 Sensor Module-CM1106S
18 Pages
-
Gas Sensor Line-up
1 Pages
-
About Cubic
1 Pages
-
CEMS Solution - Gasboard 9050
22 Pages
-
NDIR CO2 Sensor Modules
7 Pages
-
Gasboard-7020
4 Pages
-
Gasboard-7500
7 Pages
-
Mainstream ETC02 module
5 Pages
-
Gasboard 3400P
5 Pages
-
Analyzer Gasboard 3800P
6 Pages
-
LANDFILL APPLICATIONS
8 Pages
Archived catalogs
-
Air quality monitor AM7000
11 Pages
-
RHB Series
8 Pages
-
Ultrasonic Flow meter 7200
1 Pages
-
Syngas portable analyzers
4 Pages
-
Opacity meter
1 Pages
-
Infrared Methane gas sensor
3 Pages