IIOT
Leverage sensors, devices, and other industrial resources to connect to the Internet to enable data collection,
monitoring, and analysis in industrial environments.
Through IIoT, enterprises can achieve more efficient production,
better resource utilization, and more flexible operations.
Portable instrument
With the help of patented condition monitoring technology, gear and bearing faults can be detected at an early stage, and the fault sources identified. The process is simple and efficient, with precise measurements and detailed spectra. Even in the most complex industrial applications, in-depth bearing and vibration analysis can be conducted. Multiple measurement tasks can be performed with just the press of a button, including real-time condition assessment, alarm generation, historical data, and trends—all displayed directly on the screen.
Online devices
Our online condition monitoring equipment uses vibration or shockwave measurements to continuously and automatically monitor critical condition parameters, alerting maintenance personnel before issues escalate into failures. This maximizes plant availability and performance levels. The equipment is available in various versions, making it ideal for remote monitoring or industrial environments with multiple measurement points.
Condition Monitoring Analysis Platform
Comprehensive analysis, diagnostics, and troubleshooting software is compatible with all iCMS online systems and portable condition monitoring instruments. This feature-rich software boasts a user-friendly interface and powerful graphical capabilities, enabling users to easily navigate from an overview to detailed condition data.
Transducers and transmitters
There are a variety of models to choose from depending on the operating environment. The correct sensor is critical to measurement accuracy. Any field data is only as good as the sensor used to measure it.
Sound And Vibration Advance Algorithm
The algorithm can detect gear and bearing failures at an early stage of the damage process, allowing for close monitoring of the entire phase's progression. It also enables high-definition shock wave monitoring across a very wide RPM range, even in ultra-low-speed applications (0.1 - 20,000 RPM).