KLHA KD37V10 LED Temperature and Humidity Sensor User Manual
- June 5, 2024
- KLHA
Table of Contents
KLHA KD37V10 LED Temperature and Humidity Sensor
KD37V10 using the standard, easy access to PLC DCS and other instruments or systems for monitoring temperature, and humidity state quantities. The internal use of high precision sensing core and related devices to ensure high reliability and excellent long-term stability can be customized RS232, RS485, CAN,4 20mA, DC0~5V 10V, ZIGBE E, Lora, WIFI, GPRS, and other output methods.
Technical Parameters
| Technical parameter | Parameter value |
|---|---|
| Brand | KLHA |
| Temperature measuring range | -30℃~80℃ |
| Temperature measuring accuracy | ±0.5℃ @25℃ |
| Interface | RS485/4-20mA/DC0-5V/DC0-10V |
| Power | DC12~24V 1A |
| Running temperature | -40~80°C |
| Working humidity | 5%RH~90%RH |
Product Selection
Product DesignRS485,4 20mA, DC0 5V, DC0 10VMultiple output methods, the products are divided into the following models depending on the output method.
| Product model | output method |
|---|---|
| KD37V1B | RS485 总线 |
| KD37V1M | 4-20mA |
| KD37V1V5 | DC0-5V |
| KD37V1V10 | DC0-10V |
Product Size
How to wiring?
Application solution
How to use it?
Communication Protocol
The product uses RS485 MODBUS RTU standard protocol format, all operation or
reply commands are hexadecimal data. The default device address is 1 when the
device is shipped, the default baud rate is 9600, 8, n, 1
Read Data (Function id 0x03)
Inquiry frame (hexadecimal), sending example: Query 1# device 1 data, the host
computer sends the command:01 03 00 00 00 02 C4 0B .
| Device ID | Function id | Start Address | Data Length | CRC16 |
|---|---|---|---|---|
| 01 | 03 | 00 00 | 00 02 | C4 0B |
| --- | --- | --- | --- | --- |
For the correct query frame, the device will respond with data:01 03 04 00 7A 00 00 DB EA , the response format is parsed as follows:
| Device ID | Function id | Data Length | 数据 1 | 数据 2 | Check Code |
|---|---|---|---|---|---|
| 01 | 03 | 04 | 00 79 | 00 7A | DB EA |
Data Description: The data in the command is hexadecimal. Take data 1 as an
example. 00 79 is converted to a decimal value of 121. If the data
magnification is 100, the actual value is 121/100=1.21.
Others and so on.
Data Address Table
| Address | Start Address | Description | Data type | Value range |
|---|---|---|---|---|
| 40001 | 00 00 | 1#temperatureregister | Read-only | 0~65535 |
| 40002 | 00 01 | 2#temperatureregister | Read-only | 0~65535 |
| 40101 | 00 64 | model code | read/write | 0~65535 |
| 40102 | 00 65 | total points | read/write | 1~20 |
| 40103 | 00 66 | Device ID | read/write | 1~249 |
| 40104 | 00 67 | baud rate | read/write | 0~6 |
| 40105 | 00 68 | mode | read/write | 1~4 |
| 40106 | 00 69 | protocol | read/write | 1~10 |
read and modify device address
Read or query device address
If you don’t know the current device address and there is only one device on
the bus, you can use the command FA 03 00 64 00 02 90 5F Query device address.
| Device ID | Function id | Start Address | Data Length | CRC16 |
|---|---|---|---|---|
| FA | 03 | 00 64 | 00 02 | 90 5F |
FA is 250 for the general address. When you don’t know the address, you can
use 250 to get the real device address, 00 64 is the device model register.
For the correct query command, the device will respond, for example, the
response data is: 01 03 02 07 12 3A 79, the format of which is as shown in the
following table:
| Device ID | Function id | Start Address | Model Code | CRC16 |
|---|---|---|---|---|
| 01 | 03 | 02 | 55 3C 00 01 | 3A 79 |
The response should be in the data, the first byte 01 indicates that the real address of the current device is, 55 3C converted to decimal 20182 indicates that the current device’s main model is 21820, and the last two bytes 00 01 Indicates that the device has a status quantity.
Change devise address
For example, if the current device address is 1, we want to change to 02, the
command is:01 06 00 66 00 02 E8 14.
| Device ID | Function id | Start Address | Destination | CRC16 |
|---|---|---|---|---|
| 01 | 06 | 00 66 | 00 02 | E8 14 |
After the change is successful, the device will return information: 02 06 00 66 00 02 E8 27 , its format is parse d as shown in the following table:
| Device ID | Function id | Start Address | Destination | CRC16 |
|---|---|---|---|---|
| 01 | 06 | 00 66 | 00 02 | E8 27 |
The response should be in the data, after the modification is successful, the first byte is the new device address. After the general device address is changed, it will take effect immediately. At this time, the user needs to change the query command of the software at the same time.
Read and Modify Baud Rate
Read baud rate
The device’s default factory baud rate is 9600. If you need to change it, you
can change it according to the following table and the corresponding
communication protocol. For example, read the current device’s baud rate ID,
the command is:01 03 00 67 00 01 35 D5, and its format is parsed as follows.
| Device ID | Function id | Start Address | Data Length | CRC16 |
|---|---|---|---|---|
| 01 | 03 | 00 67 | 00 01 | 35 D5 |
Read the baud rate encoding of the current device. Baud rate encoding: 1 is
2400; 2 is 4800; 3 is 9600; 4 is 19200; 5 is 38400; 6 is 115200.
For the correct query command, the device will respond, for example, the
response data is: 01 03 02 00 03 F8 45, the format of which is as shown in the
fol lowing table:
| Device ID | Function id | Data Length | Rate ID | CRC16 |
|---|---|---|---|---|
| 01 | 03 | 02 | 00 03 | F8 45 |
coded according to baud rate, 03 is 9600, ie the current device has a baud rate of 9600.
Change the baud rate
For example, changing the baud rate from 9600 to 38400, ie changing the code
from 3 to 5, the command is: 01 06 00 67 00 05 F8 1601 03 00 66 00 01 64 15.
| Device ID | Function id | Start Address | Target Baud Rate | CRC16 |
|---|---|---|---|---|
| 01 | 03 | 00 66 | 00 01 | 64 15 |
Change the baud rate from 9600 to 38400, changing the code from 3 to 5. The new baud rate will take effect immediately, at which point the device will lose its response and the baud rate of the device should be queried accordingly. Modified.
Read Correction Value
When there is an error between the data and the reference standard, we can
reduce the display error by adjusting the correction value. The correction
difference can be modified to be plus or minus 1000, that is, the value range
is 0 1000 or 64535 65535. For example, when the display value is too small, we
can correct it by adding 100. The command is: 01 03 00 6B 00 01 F5 D6 . In the
command100 is hex 0x64 If you need to reduce, you can set a negative value,
such as 100, corresponding to the hexadecimal value of FF 9C, which is
calculated as 100 65535=65435, and then converted to hexadecimal to 0x FF 9C.
The correction value starts from 00 6B. We take the first parameter as an
example. The correction value is read and modified in the same way for
multiple parameters.
| Device ID | Function id | Start Address | Data Length | CRC16 |
|---|---|---|---|---|
| 01 | 03 | 00 6B | 00 01 | F5 D6 |
For the correct query command, the device will respond, for example, the response data is: 01 03 02 00 64 B9 AF, the format of which is as shown in the following table:
| Device ID | Function id | Data Length | Data value | CRC16 |
|---|---|---|---|---|
| 01 | 03 | 02 | 00 64 | B9 AF |
In the response data, the first byte 01 indicates the real address of the
current device, and 00 6B is the first state quantity correction value
register. If the device has multiple parameters, other parameters
operate in this way. The same, the genera l temperature, humidity have this
parameter, the light generally does not have this item.
Change correction value
For example, if the current state quantity is too small, we want to add 1 to
its true value, and the current value plus 100 correction operation command
is:01 06 00 6B 00 64 F9 FD.
| Device ID | Function id | Start Address | Destination | CRC16 |
|---|---|---|---|---|
| 01 | 06 | 00 6B | 00 64 | F9 FD |
After the operation is successful, the device will return information: 01 06 00 6B 00 64 F9 FD, the parameters take effect immediately after a successful change.
temperature and current computing relationship
For example, the range is 30~80 ℃℃, and the analog output is 4~20mA current
signal, temperature, and current The calculation relationship is as shown in
the formula: C = (A2 A1) * (X B1) / (B2 B1) + A1, where A2 is temperature
range upper limit, A1 is the lower limit of the range, B2 is current output
range upper limit, B1 is the lower limit, X is the currently read temperature
value, and C is the calculated current v alue. The list of commonly used
values is as follows:
| current(mA) | temperature value (℃) | Calculation Process |
|---|---|---|
| 4 | -30 | (80-(-30))*(4-4)÷(20-4)+-30 |
| 5 | -23.125 | (80-(-30))*(5-4)÷(20-4)+-30 |
| 6 | -16.25 | (80-(-30))*(6-4)÷(20-4)+-30 |
| 7 | -9.375 | (80-(-30))*(7-4)÷(20-4)+-30 |
| 8 | -2.5 | (80-(-30))*(8-4)÷(20-4)+-30 |
| 9 | 4.375 | (80-(-30))*(9-4)÷(20-4)+-30 |
| 10 | 11.25 | (80-(-30))*(10-4)÷(20-4)+-30 |
| 11 | 18.125 | (80-(-30))*(11-4)÷(20-4)+-30 |
| 12 | 25 | (80-(-30))*(12-4)÷(20-4)+-30 |
| 13 | 31.875 | (80-(-30))*(13-4)÷(20-4)+-30 |
| 14 | 38.75 | (80-(-30))*(14-4)÷(20-4)+-30 |
| 15 | 45.625 | (80-(-30))*(15-4)÷(20-4)+-30 |
| 16 | 52.5 | (80-(-30))*(16-4)÷(20-4)+-30 |
| 17 | 59.375 | (80-(-30))*(17-4)÷(20-4)+-30 |
| 18 | 66.25 | (80-(-30))*(18-4)÷(20-4)+-30 |
| 19 | 73.125 | (80-(-30))*(19-4)÷(20-4)+-30 |
| 20 | 80 | (80-(-30))*(20-4)÷(20-4)+-30 |
As shown in the above formula, when measuring 8mA, the current is 31.5 ℃。
humidity and current computing relationship
For example, the range is 0~100%RH, the analog output is 4~20mA current
signal, humidity and current The calculation relationship is as shown in the
formula: C = (A2 A1) * (X B1) / (B2 B1) + A1, where A2 is humidity range upper
limit, A1 is the lower limit of the range, B2 is current output range upper
limit, B1M is the lower limit, X is the currently read humidity value, and C
is the calculat ed current value. The list of commonly used values is as
follows:
| current(mA) | humidity value (%RH) | Calculation Process |
|---|---|---|
| 4 | 0.0 | (100-0)*(4-4)÷(20-4)+0 |
| 5 | 6.3 | (100-0)*(5-4)÷(20-4)+0 |
| 6 | 12.5 | (100-0)*(6-4)÷(20-4)+0 |
| 7 | 18.8 | (100-0)*(7-4)÷(20-4)+0 |
| 8 | 25.0 | (100-0)*(8-4)÷(20-4)+0 |
| --- | --- | --- |
| 9 | 31.3 | (100-0)*(9-4)÷(20-4)+0 |
| 10 | 37.5 | (100-0)*(10-4)÷(20-4)+0 |
| 11 | 43.8 | (100-0)*(11-4)÷(20-4)+0 |
| 12 | 50.0 | (100-0)*(12-4)÷(20-4)+0 |
| 13 | 56.3 | (100-0)*(13-4)÷(20-4)+0 |
| 14 | 62.5 | (100-0)*(14-4)÷(20-4)+0 |
| 15 | 68.8 | (100-0)*(15-4)÷(20-4)+0 |
| 16 | 75.0 | (100-0)*(16-4)÷(20-4)+0 |
| 17 | 81.3 | (100-0)*(17-4)÷(20-4)+0 |
| 18 | 87.5 | (100-0)*(18-4)÷(20-4)+0 |
| 19 | 93.8 | (100-0)*(19-4)÷(20-4)+0 |
| 20 | 100.0 | (100-0)*(20-4)÷(20-4)+0 |
As shown in the above formula, when measuring 8mA, the current is 29%RH 。
temperature and DC0 5Vvoltage computing relationship
For example, the range is 30~80 ℃℃, the analog output is 0~5V DC0 5Vvoltage
signal, temperature and DC0 5Vvoltage The calculation relationship is as shown
in the formula: C = (A2 A1) * (X B1) / (B2 B1) + A1, where A2 is temperature
range upper limit, A 1 is the lower limit of the range, B2 is DC0 5Vvoltage
output range upper limit, B1 is the lower limit, X is the currently read
temperature value, and C is the calculated DC0 5Vvoltage value. The list of
commonly used values is as follows:
| DC0-5Vvoltage(V) | temperature value (℃) | Calculation Process |
|---|---|---|
| 0 | -30 | (80-(-30))*(0-0)÷(5-0)+-30 |
| 1 | -8 | (80-(-30))*(1-0)÷(5-0)+-30 |
| 2 | 14 | (80-(-30))*(2-0)÷(5-0)+-30 |
| 3 | 36 | (80-(-30))*(3-0)÷(5-0)+-30 |
| 4 | 58 | (80-(-30))*(4-0)÷(5-0)+-30 |
| 5 | 80 | (80-(-30))*(5-0)÷(5-0)+-30 |
As shown in the above formula, when measuring 2.5V, the current DC0 5Vvoltage is 55 ℃。
humidity and DC0 5Vvoltage computing relationship
For example, the range is 0~100%RH, the analog output is 0~5V DC0 5Vvoltage
signal, humidity and DC0 5Vvoltage The calculation relationship is as shown in
the formula: C = (A2 A1) * (X B1) / (B2 B1) + A1, where A2 is humidity range
upper limit, A1 is the lower limit of the range, B2 is DC0 5Vvoltage output
range upper limit, B1 is the lower lim it, X is the currently read humidity
value, and C is the calculated DC0 5Vvoltage value. The list of commonly used
values is as follows:
| DC0-5Vvoltage(V) | humidity value (%RH) | Calculation Process |
|---|---|---|
| 0 | 0.0 | (100-0)*(0-0)÷(5-0)+0 |
| 1 | 20.0 | (100-0)*(1-0)÷(5-0)+0 |
| 2 | 40.0 | (100-0)*(2-0)÷(5-0)+0 |
| 3 | 60.0 | (100-0)*(3-0)÷(5-0)+0 |
| 4 | 80.0 | (100-0)*(4-0)÷(5-0)+0 |
| 5 | 100.0 | (100-0)*(5-0)÷(5-0)+0 |
As shown in the above formula, when measuring 2.5V, the current DC0 5Vvoltage is 50%RH 。
temperature and DC0 10Vvoltage com putting the relationship
For example, the range is 30~80 ℃℃, the analog output is 0~10V DC0 10Vvoltage signal, temperature and DC0 10Vvoltage The calculation relationship is as shown in the formula: C = (A2 A1) * (X B1) / (B2 B1) + A1, where A2 is temperature range upper limit, A1 is the lower limit of the range, B2 is DC0 10Vvoltage output range upper limit, B1 is the lower limit, X is the currently read temperature value, and C is the calculated DC0 10Vvoltage value. The list of commonly used values is as follows:
| DC0-10Vvoltage(V) | temperature value (℃) | Calculation Process |
|---|---|---|
| 0 | -30 | (80-(-30))*(0-0)÷(10-0)+-30 |
| 1 | -19 | (80-(-30))*(1-0)÷(10-0)+-30 |
| 2 | -8 | (80-(-30))*(2-0)÷(10-0)+-30 |
| 3 | 3 | (80-(-30))*(3-0)÷(10-0)+-30 |
| 4 | 14 | (80-(-30))*(4-0)÷(10-0)+-30 |
| 5 | 25 | (80-(-30))*(5-0)÷(10-0)+-30 |
| 6 | 36 | (80-(-30))*(6-0)÷(10-0)+-30 |
| 7 | 47 | (80-(-30))*(7-0)÷(10-0)+-30 |
| 8 | 58 | (80-(-30))*(8-0)÷(10-0)+-30 |
| 9 | 69 | (80-(-30))*(9-0)÷(10-0)+-30 |
| 10 | 80 | (80-(-30))*(10-0)÷(10-0)+-30 |
As shown in the above formula, when measuring 5V, the current DC0 10V voltage is 55 ℃。
humidity and DC0 10Vvoltage computing relationship
For example, the range is 0~100%RH, the analog output is 0~10V DC0 10Vvoltage
signal, humidity and DC0 10Vvoltage The calculation relationship is as shown
in the formula: C = ( A2 A1) * (X B1) / (B2 B1) + A1, where A2 is humidity
range upper limit, A1 is the lower limit of the range, B2 is DC0 10Vvoltage
output range upper limit, B1 is the lower limit, X is the currently read
humidity value, and C is the calculated DC0 10Vvoltage value. The list of
commonly used values is as follows:
| DC0-10Vvoltage(V) | humidityValue (%RH) | Calculation Process |
|---|---|---|
| 0 | 0.0 | (100-0)*(0-0)÷(10-0)+0 |
| 1 | 10.0 | (100-0)*(1-0)÷(10-0)+0 |
| 2 | 20.0 | (100-0)*(2-0)÷(10-0)+0 |
| 3 | 30.0 | (100-0)*(3-0)÷(10-0)+0 |
| 4 | 40.0 | (100-0)*(4-0)÷(10-0)+0 |
| 5 | 50.0 | (100-0)*(5-0)÷(10-0)+0 |
| 6 | 60.0 | (100-0)*(6-0)÷(10-0)+0 |
| 7 | 70.0 | (100-0)*(7-0)÷(10-0)+0 |
| 8 | 80.0 | (100-0)*(8-0)÷(10-0)+0 |
| 9 | 90.0 | (100-0)*(9-0)÷(10-0)+0 |
| 10 | 100.0 | (100-0)*(10-0)÷(10-0)+0 |
As shown in the above formula, when measuring 5V, the current DC0 10Vvoltage is 50%RH 。
Disclaimer
This document provides all information about the product, does not grant any license to intellectual property, does not express or imply, and prohibits any other means of granting any intellectual property rights, such as the statement of sales terms and conditions of this product, other issues. No liability is assumed. Furthermore, our company makes no warranties, express or implied, regarding the sale and use of this product, including the suitability specifications and product descriptions, may be modified at any time without notice.
Contact Us
-
Company: Shanghai Sonbest Industrial Co., Ltd KLHA Brand Division
-
Address: Building 8, No.215 Northeast road, Baoshan District, Shanghai, China
-
Web: http://www.klha.com
-
Web: http://www.klha.com
SKYPE: soobuu -
Email: sale@sonbest.com
-
Tel: 86 021 51083595 / 66862055 / 66862075 / 66861077
References
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