Introducing NCD’s Long Range IoT Wireless AC Current Monitor Sensor, boasting up to a 28 Mile range using a wireless mesh networking architecture. This Long Range IoT Wireless AC Current Monitor Sensor works together with a split core current sensor. It samples current at a high data rate and calculates the current RMS value during that time. This process is repeated at user defined intervals while sleeping in between to minimize power consumption.
It has an additional feature of detecting change in current at user defined detection time intervals and sending out data if the current change is greater than user defined detection change percentage. This change detection feature can be enabled or disabled by user. To minimize power consumption, it sleeps during the time it is not checking for change. Both of these features work in parallel to support multiple application areas in one package.
Powered by just 2 AA batteries and an operational lifetime of 500,000 wireless transmissions, a 10 years battery life can be expected depending on environmental conditions and the data transmission interval. Optionally, this sensor may be externally powered.
With an open communication protocol this sensor can be integrated with just about any control system or gateway. Data can be transmitted to a PC, a Raspberry Pi, to Microsoft Azure® IoT, or Arduino. Sensor parameters and wireless transmission settings can be changed on the go using the open communication protocol providing maximum configurability depending on the intended application.
The long range, price, accuracy, battery life and security features of Long Range IoT Wireless Current Monitor makes it an affordable choice which exceeds the requirements for most of the industrial as well as consumer market applications.
Note: To measure the low current (below 1.5 Amps) pass the wire through the sensor 5 times and divide the current readings by 5.
This IoT Long Range IoT Wireless AC Current Monitor Sensor device sends data periodically, based on user-preset timing intervals and on Certain % change on the inputs. Data transmissions include battery level, signal strength, payload, firmware version, sensor type, and device serial number. Please see the Resources section to see detailed information on the data structure of this device. This wireless transmitter needs a receiver. There are many options available for receiving data from NCD transmitters. We highly recommend using our USB Modem (available during purchase) so you can monitor this device and use our LabVIEW software for changing device settings. Using our long-range USB wireless modem, users can expect easy operation over a virtual COM port at 115.2K baud. Optionally, we offer a Wireless receiver that operates over ethernet. Data from NCD sensors will appear over TCP/IP on port 2101. Simply open a TCP/IP socket, port 2101, to the IP address of the Ethernet modem and see your data stream in to your local area network. We take software samples seriously! Be sure to to check out the resources section of our web site to see code samples for Raspberry Pi, Visual Studio, LabVIEW, Arduino, Python, and more.
We’ve been working with Microsoft engineers to post data from our sensors to Azure®. If you need help integrating this sensor into Azure®, please let us know and we will work with you to get you connected!
We take software samples seriously! Be sure to to check out the resources section of our web site to see code samples for Raspberry Pi, Visual Studio, LabVIEW, Arduino, Python, and more. We can help you post data to your Azure IoT account with some of our tutorials!
Industrial Current Monitoring
Pump, Motor,Generators Electrical Behavior Analysis
Current Abnormality detection
Handheld Current monitoring equipment
Key component of predictive maintenance
Current Measurement To Cloud Like AWS/Azure
Long-Range Wireless Mesh networking is our favorite of all wireless communication technologies. This communication module will hop data from one location to another to reach its intended destination. Data hopping is a integrated feature of this communication technology, users do not need to do anything other than make sure wireless modules stay within hopping range of each other. We use the Digi 900HP-S3B module in our products, as this is the best the industry has to offer. With a 2 mile range between modules and up to 8 hops, it is possible to cover 16 miles of wireless territory using this technology. Using high-gain antennas, this module is capable of communicating to a remote module up to 28 miles away.