Vibration Monitoring Overview
Application Architecture of the Vibration Products
Applications Suitability Table
Application | Description | Solution |
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Periodically Inspection | Built with a vibration monitoring system, fixed sensing points, integrate measurement information, and vibration signals can be measured online automatically. The purpose of reducing labor costs can also be achieved by storing the original data to file records. | iWSN Series AR-200/400 series iSN series |
Measurement Analysis | The vibration eigenvalues value measured in real time is used to determine which mechanical part is abnormal. System management personnel can repair damaged components and reduce costs. | iWSN Series AR-200/400 Series iSN Series |
Device Diagnosis & Predictive Maintenance | Using the eigenvalues of vibration caused by mechanical operation, frequency and amplitude, to show the operating status of device. When there is an unplanned change in vibration signal, it means that device is in an abnormal state during operation and needs to be maintained in advance. | AR-200/400 Series AXP/ALX-9K Series |
Vibration Severity
The three parameters commonly used to describe vibrational responses are displacement, velocity, and acceleration. In general, the vibration intensity at low frequency is measured by the displacement value; the vibration intensity at medium frequency is measured by the velocity value; the vibration intensity at high frequency is measured by the acceleration value. For most machines, velocity is the best indicator, which is one reason why many standards use this parameter. The absolute value evaluation of vibration intensity based on ISO 10816-1 (as figure below) is one of the ways to judge whether a machine is in good or bad status according to the vibration value. In addition, based on normal time vibration values, relative judgment methods are also common, where 2 to 3 times are used as warning values and 5 to 6 times are used as abnormal values.
FFT Analysis
Based on the analysis of displacement, velocity, and acceleration of the time domain signal, the trend of the machine failure can be known, however, the cause of the machine failure maynot be known. FFT (Fast Fourier Transform) is a mathematical operation that converts time-domain signals into frequency-domain spectral graphs. The vibration spectrum can effectively analyze the cause of machine failures. Our products can provide up to 10 sets of spectral values (amplitude/ frequency), and by measuring the radial and axial spectral information of the equipment, the root cause and severity problem of the equipment can be estimated. The faults that may be identified are as follows:Solution Types
Selection Guide
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Accelerometer
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ItemA | Cable Length | Sensor Type | Rate | Measuring Range |
Sensitivity | Base Voltage | Input Range |
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iSN-701-F15-L030 | 3M | 1-Axis (IEPE) |
0.5~15kHz | ±80g | 100mV/g | 10~14VDC | 18~30VDC, 2~10mA |
iSN-701-F15-L060 | 6M | 1-Axis (IEPE) |
0.5~15kHz | ±80g | 100mV/g | 10~14VDC | 18~30VDC, 2~10mA |
iSN-703-F1-L015 | 1.5M | 3-Axis | 10~1kHz | ±18g | 400mV/g per axis |
10±0.5VDC | 22~26VDC, 3mA |
Note: iSN-701-MBase01 is a Magnetic Base for iSN-701 series |
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Vibration Monitoring
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Model | Channel | Sampling Rate | Connector | Sensor Type | Interface | Analog Output | IP Code |
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iSN-701X-mA | 1 | up to 200KHz | BNC | External IEPE accelerometer | Ethernet/ RS-485 |
0 ~ 20 mA 4 ~ 20 mA |
- |
iSN-701X | 1 | up to 200KHz | BNC | External IEPE accelerometer | Ethernet RS-485 |
N/A | - |
iSN-711-MRTU | 1 | up to 1KHz | 4 Pin Terminals | Built-in MEMS | RS-485 | N/A | IP30 |
iSN-713-MRTU | 3 | up to 1KHz | 4 Pin Terminals | Built-in MEMS | RS-485 | N/A | IP30 |
iSN-711-MRTU-IP68 | 1 | up to 1KHz | 4 Pin Terminals | Built-in MEMS | RS-485 | N/A | IP68 |
iSN-713-MRTU-IP68 | 3 | up to 1KHz | 4 Pin Terminals | Built-in MEMS | RS-485 | N/A | IP68 |
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Signal Conditioning
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Model | Input for Accelerometer | Output | |||||
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Channel | Signal | Excitation | Bandwidth | Supported Accelerometer |
Channel | Signal | |
SG-3037-G | 3 | Voltage (0 ~ 24 VDC) |
24 VDC | 50 kHz | iSN-703-BALT-F1-L015 (3-axis) |
3 | ±10 VDC |
SG-3227 | 2 | IEPE (0 ~ 28 VDC) |
2/4/6/10 mA | x1, x10 Gain: 80 kHz x100 Gain: 50 kHz |
iSN-701-BALT-F15-L030 (1-axis) |
2 | ±10 VDC |
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Data Logger
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Model | vibration | Temperature | |||||
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Type | Channel | Sample Rate(kHz) | Range | Type | Channel | Range | |
AR-200 | IEPE | 2 | 5, 10, 20, 50, 100, 200 | Voltage: ±10 V Current: 3 mA |
- | - | - |
AR-300-T | 3 | 5, 10, 20, 50, 100, 125 | Thermistor | 1 | 0 °C ~ +80 °C | ||
AR-400
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4 | - | - | - | |||
Note: When using IEPE sensors. The capacitance of the cable, output level of the sensor, and amount of IEPE current supplied to IEPE sensors are variables which determine the frequency response. AR Series allow maximum cable length is 30 meters. |
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High Speed Data Acquisition
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Model | Channel | Sampling Rate | Resolution | Range | Interface | Sensor Type |
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PET-AR400 |
4
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128 kS/s (1 Channel) 32 kS/s (4 Channel) |
24-bit | ±10 V | Ethernet | IEPE |