1. Vibration & Temperature Sensor

2. Contents ■ Why monitor vibration? ■ Health degradation curve ■ Predictive maintenance monitoring ■ Monitor a wide range of machines ■ Vibration measurement overview ■ Set alarm levels ■ Mounting options ■ Select a Node ■ Select thresholds ■ Battery life ■ Models ■ Specifications ■ Predictive maintenance monitoring examples

3. Why Monitor Vibration ? ■ Monitoring vibration reduces downtime –Use predictive maintenance programs –Plan maintenance more efficiently –Monitor machine run time ■ Vibration is often the result of components that are: –Imbalanced –Misaligned –Worn –Loose –Improperly driven Detecting increased vibration early helps reduce machine damage and avoid failures

4. Condition Time Preventive Maintenance Predictive Maintenance Operator Care Run to Failure Vibration analysis Low risk Alarm High risk With Predictive Maintenance Program Oil analysis Temperature rise Audible noise Too hot to touch Mechanically loose Catastrophic failure Health Degradation Curve

5. Predictive Maintenance Monitoring Local Indication ((( Send threshold signal to a central location Send vibration & temp data via the gateway to the control system for collection & trending Vibration & temperature data is generated to provide health status of machines

6. Monitor a Wide Variety of Equipment MotorsPumps FansBlowers Compressors Gear boxes

7. Vibration Measurement Overview ■ To monitor vibration velocity, acceleration and displacement can be measured –Velocity = speed of movement Most uniform response over wide range of machine frequencies Considered universal measure of machine integrity in relation to alignment and balance –Acceleration = rate of change in speed Useful in high frequency measurements High frequency monitoring above 2 KHz is used to detect bearing and gearing vibration –Displacement = distance moved Useful below 5 Hz Structural vibration (buildings, bridges, earthquakes, etc.)

8. Vibration Measurement Overview ■ Velocity is the best measure of vibration because it mutes frequency dependent effects Displacement is used for measuring low frequencies: low RPM Acceleration is used for measuring high frequencies: bearing frequencies Velocity is best over a wide frequency range

9. Vibration Measurement Overview ■ The Banner QM42VT1 sensor uses an FFT (Fast Fourier Transform) to convert the vibration signal from a time domain to a frequency domain in order to calculate the velocity Time & Frequency Domain Time Domain waveform shown as many different frequencies & amplitudes

10. Vibration Measurement Overview RMS Velocity ■ RMS (root-mean-square) is in essence an averaging operation that conveys the effective energy within a signal ■ RMS velocity is the most common and effective measure of machine vibration severity in rotating equipment. –It is an indication of the vibration energy produced by the machine –It is expressed in inches per second (in/s) or millimeters per second (mm/s)

11. ■ The Banner QM42VT1 uses a MEMS based accelerometer as its core sensing element for vibration ■ It uses advanced signal processing techniques to output a digital signal that represents a true RMS velocity between 10 and 1,000 Hz. ■ Vibration RMS velocity and temperature data can be trended so that the user can set thresholds and alarms based on machine history ■ The ISO 10816 Vibration Severity Chart can be used as guidance to set threshold levels. Vibration Measurement Overview

12. Set Alarm Levels ■ The ISO 10816 vibration severity chart is a well established standard that is based on historical machine vibration data. ■ It defines acceptable limits of vibration severity, using RMS velocity, and can be used to set vibration alarm levels. ■ Absolute levels of vibration will vary based on many factors including type of machine, mounting, etc. ■ Temperature alarms can be set up to 80°C

13. ((( Example in/s The LCD readout for input 1 is 970 970 ÷ 10,000 =.097 RMS velocity in/s =.097 Set Alarm Levels How to convert the holding register representation into RMS velocity: Example mm/s The LCD readout for input 2 is 2,490 2,490 ÷ 1,000 = 2.49 RMS velocity mm/s = 2.49 Vibration alarm levels can also be set by establishing a vibration baseline for a machine: Use LCD display on DX80 Gateways and P6 Nodes to calculate RMS velocity (see below) Trend RMS velocity over time to establish baseline Set alarm level at 1 ½ - 2 times the baseline vibration level P6 Node

14. Mounting Options BWA-BK-002 Standard bracket ¼” – 28 cap screw included (ships with sensor) BWA-BK-001 Magnetic bracket BWA-HW-057 Two sided thermal transfer mounting tape (ships with sensor)

15. Mounting

16. Select Node* *Vibration sensor must be paired with a Banner Wireless Node Q45 Easily connect to vibration sensor using the 5-pin M12 Euro connector Set thresholds using DIP switches Built in LED light is pre-mapped to illuminate amber when the vibration threshold has been exceeded and red when the temperature threshold has been exceeded Typically 1 to 6 sensors/nodes Two 3.6V AA lithium batteries 2.4 GHz P6 Performance Easily connect to vibration sensor using the 5-pin M12 Euro connector LCD display Star topology allows for up to 47 sensors/nodes One 3.6V D-cell lithium battery Available in 900 MHz (1 Watt) and 2.4 GHz H6 Multihop Easily connect to vibration sensor using the 5-pin M12 Euro connector LCD display Tree topology allows for multiple hops to cover longer distances and circumvent obstacles 50+ sensor/nodes per master radio One 3.6V D-cell lithium battery Available in 900 MHz (1 Watt) and 2.4 GHz

17. Select Vibration Threshold ■ Vibration thresholds are DIP switch selectable on the Q45 ■ Use UCT to set the temperature threshold and vibration thresholds for the P6 and H6* *Use the MultiHop configuration tool for the H6

18. Battery Life Q45:P6 and H6: 3+ years at 5 minute sample rate on the Q45 & P6/H6 at 250 Mw 2 ½ years at 5 minute sample rate for the P6/H6 at 1 Watt Default sample rate is 5 minutes For the first 15 minutes after power up, the node goes into fast sample mode, sampling every second To take it out of fast sample mode prior to 15 minutes, click the button 5 times (button 1 on the P6 & H6) Fast sample mode will expire after 15 minutes, to put the node back into fast sample mode single click the button again

19. Sensor and Node Models 1- Wire Serial Sensor 1- Wire Serial Nodes

20. QM42VT1 Sensor Specifications

21. Predictive maintenance monitoring examples ((( Simple point-to-point, local indication system ModelDescriptionQty QM42VT1Vibration & temperature sensor1 DX80N2Q45VTQ45 Vibration & temperature node1 DX80G2M6S-PM2PM2 Gateway – 4 DI, 4DO, 2AI, 2AO1 PM2 Gateway is pre- mapped to support up to two nodes

22. Predictive maintenance monitoring examples ((( Point-to-multipoint, and send signal to central location ModelDescriptionQty QM42VT1Vibration & temperature sensor3 DX80N9X1S-P6P6 1-wire serial Performance Node3 DX80G9M6S-P2Performance Gateway – 4 DI, 4DO, 2AI, 2AO1 TL70DXN9YYYQTL70 Wireless Tower Light1 ((( Each machine is mapped to a light segment Performance Gateway

23. Predictive maintenance monitoring examples ((( Point-to-multipoint, and send data to Gateway for collection ModelDescriptionQty QM42VT1Vibration & temperature sensor4 DX80N9X1S-P6P6 1-wire serial Performance Node4 DX80P9T6S-PGatewayPro – Modbus/TCP to Ethernet/IP1 ((( GatewayPro converts Modbus register values to Ethernet/IP for collection and trending