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Vibration Evaluation Standard 11
C
C
B
B
7.1 4.5 3.5 2.8 2.3
A Rigid
Flexible
1.4
A Rigid
Flexible
Pumps > 15 kW radial, axial, mixed flow
Rigid
Flexible
0.71
Rigid
Flexible
Medium sized machines 15kW < Power ≤ 300 kW
Large machines 300 kW < Power < 50 MW
Integrated Driver
External Driver
Motor 160 mm ≤ H ≤ 315
Motor 315 mm ≤ H
GROUP 4
GROUP 3
GROUP 2
GROUP 1
Machinery Evaluation as per ISO 10816 Guide line: Zone A: Vibration of newly commissioned machines; Zone B: Machines considered acceptable for unrestricted long-term operation Zone C: Machines considered unsatisfactory for long-term continuous operation Zone D: Vibration values normally considered to be sufficient severity to cause damage to the machine
Guideline as per ISO 10816
18
D
VIBRATION : Velocity in mm/sec RMS
D
Foundation Support Machine Type GROUP
Measurement Frequency range: 10 Hz to 1000 Hz > 600 RPM* 2 Hz to 1000 Hz > 120 RPM* * Operating speed of machine
# Refer ISO 10816-1:1995 Standard on Mechanical vibration -- Evaluation of machine vibration by measurements on non-rotating parts. Visit: www.iso.ch # Refer ISO 13373-1:2002 for General Procedures for vibration measurement.
Note ISO 10816 precedes standards ISO 2372 and ISO 3945
© CENTER FOR MACHINERY DIAGNOSTICS, www.CMDGlobal.org / e-mail: [email protected]
Vibration Evaluation Standard – Reciprocating machine Vibration Severity Grade
1,1 1,8 2,8 4,5 7,1 11 18 28 45 71 112 180
Overall vibration measurement measured on the machine structure Displacement in lm – micron (rms)
Velocity In mm/sec (rms)
Acceleration meter / sec² (rms)
£ 17,8 £ 28,3 £ 44,8 £ 71,0 £ 113 £ 178 £ 283 £ 448 £ 710 £ 1125 £ 1784 > 1784
£ 1,12 £ 1,78 £ 2,82 £ 4,46 £ 7,07 £ 11,2 £ 17,8 £ 28,2 £ 44,6 £ 70,7 £ 112 > 112
£ 1,76 £ 2,79 £ 4,42 £ 7,01 £ 11,1 £ 17,6 £ 27,9 £ 44,2 £ 70,1 £ 111 £ 176 > 176
ISO 10816 – 6: 1995
Machine Class* 1 A / B
2 A / B
C
3
A / B
4
A / B
C
5
A / B
6
A / B
C
7
A / B
C D
D
C D
D
C D
D
C D
Zone A: Vibration of newly commissioned machines; Zone B: Machines considered acceptable for unrestricted long-term operation Zone C: Machines considered unsatisfactory for long-term continuous operation Zone D: Vibration values normally considered to be sufficient severity to cause damage to the machine * depends on size, construction, assembly and speed. Refer ISO 10816-6 for details
Machinery Evaluation as per ISO 10816 Guide line:
© CENTER FOR MACHINERY DIAGNOSTICS, www.CMDGlobal.org / e-mail: [email protected]
Iso

Iso 2372 Vibration Standard Chart

This paper provides the results of frequency analysis of measured vibration of these parts, compared with. ISO 2372 standard for evaluate vibrations impact. Broad band vibration measurement is the most widely used and cost-efficient method for the diagnosis of general machine condition. There are two ISO recommendations concerning machine condition monitoring by this type of measurement, the much used ISO 2372 and the more recent ISO 10816, which is a replacement of the older standard.

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Iso 2372 Pdf

ISO 2372 (10816) Standards provide guidance for evaluating vibration severity in machines operating in the 10 to 200 Hz (600 to 12,000 RPM) frequency range. Examples of these types of machines are small, direct-coupled, electric motors and pumps, production motors, medium motors, generators, steam and gas turbines, turbo-compressors, turbo-pumps and fans. Some of these machines can be coupled rigidly or flexibly, or connected through gears. The axis of the rotating shaft may be horizontal, vertical or inclined at any angle. Use the chart below combined with additional factors described in this manual to judge the overall vibration severity of your equipment.
VIBRATION SEVERITY PER ISO 10816
Vibration Velocity Vrms
Machine
Printed in the U.S.A. © Monarch Instrument 2002 all rights reserved
1071-4400-113
in/s
mm/s
0.01 0.02 0.03 0.04 0.07 0.11 0.18 0.28 0.44 0.70 0.71 1.10
0.28 0.45 0.71 1.12 1.80 2.80 4.50 7.10 11.2 18.0 28.0 45.0
Class I small machines
Class II medium machines
Class III large rigid foundation
Class IV large soft foundation
good
satisfactory unsatisfactory
unacceptable
EXAMINER 1000 SPECIFICATIONS Vibration Sensor: Piezoelectric accelerometer 100 mV/g with magnetic base, probe and 5 foot cable to BNC Display: LCD 3.5 digit , measurement, hold, low battery indicator Measurement Acceleration 0.01-19.99 g (RMS) Range: Velocity 0.01-19.99 in/sec., 0.1-199.9 mm/sec (RMS) Envelope 0.01-19.99 ge (peak) Frequency Range: Overall 10 Hz - 10 kHz Envelope 0.5 kHz-10 kHz Output: Sensor Excitation: 12 Vdc @ 2 mA (BNC) Audio Out: 3.5 mm mini plug; 250 mW into 8 ohms, 150 mW into 32 ohms; Adjustable volume control with off position Power: (2) “AA” cells Operating Time: 20 hours continuous without headphones Weight: Instrument: 7 oz. (0.19 kg); Complete Kit: 2.85 lb (1.30 kg) Dimensions: 6.3 x 3.3 x 1.25” (152 x 83 x 32 mm) Operating conditions: -14° to 122°F (-10° to 50°C)
TABLE OF CONTENTS OPERATING THE EXAMINER 1000 Overview ......................................
1
Controls and Functions.............. .............. 1 Rear Panel, Batteries and Connections ............... 2 Parts of the System .............................. 3 Overview of Data Collection Procedure............... 3 APPLYING THE EXAMINER 1000 What is Predictive Maintenance? .................... 4 Benefits of Predictive Maintenance .................. 4 Why Measure Vibration? .......................... 5 Selecting Machinery & Measurements................ 6 Selecting Measurement Types ...................... 7 Getting Started in your Plant........................ 8 Establishing a Data Collection Route................. 9 What are you Measuring? ......................... 10 Measurement Techniques ......................... 11 Evaluating overall Vibration Measurements ............12 Evaluating Acceleration Envelope Measurements........13 GLOSSARY ....................................14
OPERATING THE EXAMINER 1000
MONARCH INSTRUMENT Service Policy, Warranty, Disclaimer and Limit of Remedies Except for the limited warranty described below, there are no warranties, expressed or implied, including but not limited to, the implied warranties of merchantability and fitness for a particular purpose: all such warranties are expressly and specifically disclaimed. EXAMINER 1000 is guaranteed free from defects in material and workmanship. Mechanical components, transducers, and cable assemblies are guaranteed for a period of (90) days. Electronic components are guaranteed for a period of (12) months. The warranty period begins on the date the products are shipped from the Monarch Instrument factory or an Authorized Distributor. This warranty does not extend to units that have been misused, altered, or repaired without manufacturer’s authorization. Defects or failures experienced during the warranty period will be corrected at no charge at the manufacturer’s facility. If, upon examination, it is found that the defect is not within the scope of this warranty, an estimate of repair charges and a request for authorization to proceed with the repair will be submitted, along with a statement of the reasons the repairs are not considered to be covered by the warranty. This warranty does not extend to system components such as transducers, headphones and cable assemblies manufactured by others. Warranty for these components will be their manufacturer’s standard. Manufacturer’s liability under this warranty is limited to repair or replacement of any defective instrument at the discretion of the manufacturer. In the event that any of the above limitations are held unenforceable, our liability to you shall not exceed the purchase price paid for the product, regardless of the claim. Because of the diverse ways that the product can be used, you are advised to test the product for suitability of use for your purposes prior to relying on it.
Overview The EXAMINER 1000 is designed in conjunction with vibration limits established in ISO Standards 2372(10816)/3945 to help you detect signs of malfunction or changes in rotating machinery during operation. This is accomplished with overall vibration (ISO VIB) and envelope measurements. Problems with bearings occur when there is a microscopic crack or flaw or when there is a breakdown in lubrication which leads to metal-to-metal interaction. The EXAMINER 1000 is designed to detect flaws or a lack of lubrication in bearings and gears at an early stage by measuring the high-frequency impacts through acceleration envelope methods. Vibration measurements are made by pressing the accelerometer sensor against designated Measurement Points on your equipment with either the stringer probe or with the magnetic base.
Controls and Functions ON/SELECT Button - Press this button to turn power on. Power automatically turns off after ten minutes of non-use. After turning the EXAMINER “on”, press the ON/SELECT button again to select the measurement type. Pressing and holding the ON/SELECT button while collecting data will HOLD the display value, indicated by the word “HOLD” in the display. To release from HOLD mode, press the ON/ SELECT button again. DISPLAY- The digital display shows the numerical value of the measurement. An arrow indicates the measurement type selected. The units of vibration are automatically displayed as the type of measurement is selected. The user may work in either metric or imperial units in the V-velocity mode. Type of Measurement
MONARCH INSTRUMENT 15 Columbia Drive Amherst, NH 03031 USA Phone: 603-883-3390 Fax: 603-886-3300 www.monarchinstrument.com e-mail: [email protected]
Low Battery Indicator Hold Reading Indicator
1
Type of Measurement Indicator Value of Measurement
V A E
LoBat HOLD
0.09
Units of Measure
g GE in/s mm/s
REAR PANEL CONNECTIONS
GLOSSARY (for vibration purposes)
CONNECTIONS
1234 1234 E
X
1
A
M
0
I
0
N
0
E R
VIBRATION METER ELECTRONIC STETHOSCOPE REFER TO OPERATORS MANUAL FOR INSTRUCTIONS
CONNECTIONS
SENSOR IN AUDIO OUT
AUDIO OUT SENSOR IN
Measurement TypesUnits V velocity mm/s in/s A acceleration g E envelope ge Monarch Instrument 15 Columbia Drive Amherst, NH 03031 USA
VOLUME CONTROL
QUICK REFERENCE INSTRUCTION PANEL
PRODUCT SERIAL NUMBER
Piezoelectric A material in which electrical properties change when subjected to force. Process Measurements Variables such as temperature, pressure, speed and flow used to assess internal conditions of efficiency. Radial Direction perpendicular to the shaft centerline. Repeatability A measure of the deviation between successive measurements made under the same conditions. RMS Peak Vibration x .707. ( in/s or mm/s) Rolling Element Bearing A bearing consisting of balls or rollers operating between fixed and rotating races. Route A sequence of measurements arranged for convenience during acquisition. Sensitivity Used to describe a transducer’s electrical output for a unit variation of the mechanical quantity measured. Stress Force per unit area Synchronous Frequency components that are an integer multiple of running speed. Transducer A system consisting of a sensor and signal conditioner to convert a physical quantity into an output for display, monitoring and analysis. Transmission Path The path from source (excitation) to sensor. Trending The plot of a variable over time used as an indicator of change. Velocity A vector quantity of the time rate change of displacement. Vibration Conversions
BATTERY COMPARTMENT Contains two “AA” alkaline batteries.
D = 19.10 x 103 x (V/F) D = 70.4 x 106 x (A/F2)
12345 12345 12345 12345 12345 AUDIO OUT 1/8” (3.5 mm) stereo mini plug
TOP VIEW
V = 52.36 x 10-6 x D x F V = 3.68 x 103 x (A/f) A = 14.2 x 10-9 x D x F2 A = 0.27 x 10-3 x V x F
SENSOR INPUT BNC Connector output 12 vdc @ 2 mA
where:
2
15
D = Displacement (mils peak-to-peak) V = Velocity (in/s zero-to-peak) A = Acceleration (in/s2 zero-to-peak) F = Frequency (cpm)
Parts of the System
GLOSSARY (for vibration purposes) Acceleration A scalar quantity that specifies time rate of change of velocity. Expressed in either g’s or m/sec2 where 1 g = 386.1 in/sec2 and 9.8066 m/sec2. Acceleration Enveloping A high-frequency, filtered data collection method expressed in ge. Accelerometer A transducer which converts acceleration motion in to an electrical output. Amplitude The magnitude of vibratory motion. Can be measured as peak-topeak, zero-to-peak, or RMS. Axial The direction parallel to the axis of rotation. Baseline Recorded values taken when a machine is known to be good. The standard which all additional readings will be compared to. CPM Unit of frequency measurement-cycles per minute. Displacement A scalar quantity specifying the change of position of a body measured from the resting position. Dynamic Force A force that varies with time. Force Energy applied to a mass producing a deflection (static force) or motion (dynamic force). Frequency The repetition rate of a periodic event, expressed in cycles per second (Hz), CPM, RPM, or multiples of running speed (orders). g’s Units of acceleration referenced against the force of gravity. (1g=32.1739 ft./sec/sec; 1g=9.8066 m/sec/sec) Gear Mesh Frequency A frequency generated by a gear. Defined as the number of gear teeth on a gear times its shaft-rotating frequency. Hertz (Hz) A unit of frequency measurement, cycles per second. High-pass Filter A filter that allows only those components above a selected frequency to pass. Integration The time-based process of converting acceleration and velocity to velocity or displacement. in/sec, ips Abbreviations for inches per second, a measure of velocity. Mass The measure of body resistance to acceleration. Proportional to, but not equal to, weight (mass = weight/gravity). Measurement Point A location on a machine or component where all subsequent measurements should be made for accurate comparison. Mechanical Impedance Ratio of applied force to resulting velocity during simple harmonic excitation. Overall The amplitude of vibration within a specified frequency range. Peak Value The absolute value zero to the maximum excursion on a dynamic waveform. Also true peak and zero-to-peak. Periodic Monitoring Measurements recorded at intervals of time.
14
EXAMINER 1000 METER
ON-TIME SOFTWARE AND OWNERS MANUAL (optional)
HEAD PHONES
HOLSTER
ACCELEROMETER WITH CABLE MAGNETIC BASE STINGER PROBE
Overview of Data Collection Procedure 1. Press the ON/SELECT button. 2. Press the ON/SELECT button again to select the desired measurement type. Place the accelerometer sensor on the machinery Measurement Point (use proper probe technique as discussed on the following pages). 3. Wait for the reading to stabilize, then press and hold the ON/SELECT button to “HOLD” the measurement. Indicated by HOLD in the display. 4. Adjust headphones volume level and listen for any distinct patterns or noises. 5. Record the measurement value in your Machinery Data Worksheet. 6. To release the HOLD function, press ON/SELECT again. 7. Repeat the above steps for each Measurement Point.
3
What Is Predictive Maintenance? Predictive Maintenance can be defined as collecting information from machines as they operate to aid in making decisions about their health, repair and possible improvements in order to reach maximum runability, before any unplanned breakdown. Machinery maintenance has evolved because of the demands to become more profitable through reduced maintenance costs. Below is the progression of these maintenance philosophies: • Break Down Maintenance • Preventive Maintenance • Predictive Maintenance Break Down Maintenance occurs when repair action is not taken on a problem until the problem results in the machines failure. Run to failure problems often cause costly secondary damage along with expenses resulting from unplanned downtime and unplanned maintenance. Preventive Maintenance occurs when a machine, or parts of a machine, are overhauled on a regular basis regardless of the condition of the parts. While better than run to failure, preventive maintenance results in excessive downtime due to unnecessary overhauls and the excessive costs of replacing good parts along with worn parts. Predictive Maintenance is the process of determining the condition of machinery as it operates, to predict and schedule the most efficient repair of problem components prior to failure. Predictive Maintenance not only helps plant personnel eliminate unplanned downtime and the possibility of catastrophic failure, but allows them effectively order parts, schedule manpower, and plan multiple repairs during scheduled downtime. Benefits of Predictive Maintenance Documented experience proves that plants which establish a predictive maintenance program are able to: • Improve Machinery Reliability-reduced “unplanned failures” • Reduce Maintenance Costs-knowing the exact problem to fix • Increase Production-optimize machinery capabilities • Lower Energy Consumption- less vibration usually means less friction • Extend Bearing Service Life- reduce vibration and lubrication failures • Improve Product Quality- where less vibration improves finish The benefits are numerous and will vary depending upon the implementation of your Predictive Maintenance Program.
4
Trend Comparison The most efficient and reliable method of evaluating vibration severity is to compare the most recent reading against previous readings for the same measurement Point, allowing you to see how the Point’s vibration values are “trending” over time. This trend comparison between present and past readings is easier to analyze when the values are plotted in a “trend plot”. A trend plot displays current and past values plotted over time. Measurement records should also include a baseline (known good) reading. The baseline value may be acquired after an overhaul or when other indicators show that the machine is running well. Subsequent measurements are compared to the baseline to determine machinery changes. Comparison with Other Machinery When several similar machines are used under the same operating conditions, evaluation can be carried out by measuring all machines at the same Points and comparing the results.
Evaluating Acceleration Envelope Measurements Use the same techniques of comparison as for Overall Vibration readings. Remember, acceleration envelope is an advanced “early warning” of a developing problem. High values do not necessarily indicate bearing failure. They can also indicate: A. Lack of lubrication or decreasing oil viscosity due to high bearing temperature caused by overload or external heat source. B. Breaking of the lubricant film by excessive imbalance, misalignment, or housing deformation. Loss of boundary lubrication. C. A rubbing seal or cover. D. Gear mesh interaction (bad lubrication, defects) E. Dirt or particles in the lubricant, or a seal or filter problem. Use trend Comparison similar to overall vibration to establish severity levels. Accelerating Envelope readings tend to decrease as Overall Vibrations readings increase. This happens when the defect in the bearing is becoming more severe and the frequency it generates becomes lower which makes it better read with the Velocity-type readings. Audio Comparison with Other Bearings on the Same Machinery When several bearings are used under the same operating conditions, evaluation can be carried out by listening to the audio signals to determine changes. This method will help to locate the defective bearing quickly. Measure all machines at the same Points and compare the results. Listen for increases in signal and for “clicking” patterns which indicate wear.
13
Evaluating the Overall Vibration Measurements
Why Measure Vibration?
Three general principles are commonly used to evaluate your vibration measurement values: ISO 2372 (10816) Standard Comparison - Compare values to the limits established in the ISO 2372 (10816) Standard. Trend Comparison - Compare current values with values of Baseline for the same Points over a period of time. Comparison with Other Machinery - Measure several machines of a similar type under the same conditions and judge the results by mutual comparison.
Vibration is considered the best operating parameter to judge dynamic conditions such as balance (overall vibration), bearing defects (enveloping) and stress applied to components. Many machinery problems show themselves as excessive vibration. Rotor imbalance, misalignment, mechanical looseness, structural resonance, soft foundation, and gearmesh defects are some of the defects that can be measured by vibration. Measuring the “overall” vibration of a machine, a rotor in relation to a machine or the structure of a machine, and comparing the measurement to its normal value (norm) indicates the current health of the machine.
If possible, you should use all three comparisons to evaluate your machinery’s condition. ISO 2372 (10816) and trend comparisons should always be used.
The EXAMINER 1000 measures the vibration of a machine while it is operating. Trending these measurements shows how a machine’s condition changes over a period of time. Analyzing these, along with other measurements, provide insight into the condition of the machine and which components may be wearing or failing. How to best monitor a machine’s condition requires one to know which measurements to take and where and how to take them. Sensors are placed at strategic Points on the machinery to monitor the machine’s condition.
ISO 2372 (10816) Standard Comparison The ISO 2372 (10816) Standards provide guidance for evaluating vibration severity in machines operating in the 10 to 200 Hz (600 to 12,000 RPM) frequency range. Examples of these types of machines are small, direct-coupled, electric motors and pumps, production motors, medium motors, generators, steam and gas turbines, turbo-compressors, turbo-pumps and fans. Some of these machines can be coupled rigidly or flexibly, or connected through gears. The axis of the rotating shaft may be horizontal, vertical or inclined at any angle. Machinery class designations are: Class l Individual parts of engines and machines, integrally connected with the complete machine in its normal operating condition. (Production electrical motors of up to 20 HP (15 kW) are typical examples of machines in this category.) Class ll Medium-sized machines typically, electric motors with 20 to 75 HP (15-75 kW) without special foundations, rigidly mounted engines, or machines on special foundations up to 400 HP (300 kW). Class lll Large prime movers and other large machines with rotating masses mounted on rigid and heavy foundations which are relatively stiff in the direction of vibration measurement. Class lV Large prime movers and other large machines with rotating masses mounted on foundations which are relatively soft in the direction of vibration measurement (for example, turbo-generator sets, especially those with lightweight ub-structures). Note: These ISO 2372 (10816) Standard classes do not apply to prime movers or driven equipment in which the major working components have a reciprocating motion.
12
The EXAMINER 1000 processes the accelerometer’s mechanical vibration energy into an electrical signal and displays the measurement value in numerical form for evaluation. Commonly measured physical characteristics in Predictive Maintenance are: • Vibration (as explained above) • Temperature • Oil Analysis Temperature As a bearing fails, friction causes its temperature (or its lubricant’s temperature) to rise. While trending a bearing if the temperature rises followed by a vibration increase, then it is safe to conclude their was a loss of lubrication which induced the mechanical failure. If vibration increased first, followed by increased temperature readings then a mechanical defect caused the lubrication failure. Lube Oil Analysis (Ferrography) Monitoring oil condition warns of an increase in foreign substances, such as water, which can degrade the lubricating properties of the oil and cause bearing failures. It also detects the presence of metallic particles carried into the oil stream. These metallic particles are analyzed to determine which part of the machine is wearing and how fast. Lubrication analysis is the earliest warning of a developing problem. Lube oil testing results can be trended with On-Time software.
5
Selecting Machinery and Measurements
Measurement Techniques
Maintenance personnel have always made visual and hands-on inspections of their machinery on a periodic basis. Systematic data collection and trending allows for recall and comparison of events over time but is not a replacement for good maintenance practices. Collecting machinery data is an aid to the maintenance professional, which is used in addition to good maintenance practices.
In general, vibration of anti-friction bearings is best monitored in the load zone of the bearing. Equipment design often limits the ability to collect data in this zone. Simply select the measurement Point which gives the best signal. Avoid painted surfaces, unloaded bearing zones, housing splits, and structural gaps. When measuring vibration with a hand-held sensor, it is very important to collect consistent readings, paying close attention to the sensor’s position on the machinery, the sensor’s angle to the machinery, and the contact pressure with which the sensor is held on the machinery. • Location - always collect at the same point on the machine. Mark locations. • Position - Vibration should be measured in three directions: A axial direction H horizontal direction V vertical direction • Angle Always perpendicular to the surface (90o +10o). • Pressure - Even, consistent hand pressure must be used (firm, but not so firm as to dampen the vibration signal). For best results use the magnetic base. If using the stinger/probe is the only method available to collect data, it is best to use a punch to mark the location for the probe-tip to ensure a consistent coupling to the housing.
Selecting and Classifying Machinery Setting up an effective Predictive Maintenance Program requires a careful study of the needs of the plant. It is necessary to know each machine and its response to change. The following is an example of machinery classification: CRITICAL ESSENTIAL REDUNDANT
Critical Machines expensive premium equipment, generally >500 HP. Usually less than 5% of all plant equipment. Maintenance dollars per horsepower per year average $11.00. This category of equipment is very well maintained and monitored. Continuous monitoring systems are better suited for this type of equipment. Essential Machines medium size equipment, 100-500 HP. This group may be 3040% of all the equipment in the plant. Maintenance costs can average $22.00 per horsepower per year. Less attention is paid to these machines even though their repair costs can be as high as critical machines. Select some of these machines for your Predictive Maintenance Program. Redundant Machines small redundant equipment usually < 100 HP. This group can be as much as 50% of all machines in a plant and yet they are usually neglected. By far the most expensive to maintain at $49.00/HP/year, this group will benefit the most from Predictive Maintenance practices. At many facilities, this group consumes 80% of the annual maintenance budget. If you want to have an immediate impact begin with these machines. Also include machines with known problems or a history of problems. Personnel Safety is always the first priority in selecting machinery to monitor.
6
Optimum Measurement Conditions Perform measurements with the machine operating under normal conditions. For example, when the rotor, housing, and main bearings have reached their normal steady operating temperatures and with the machine running under its normal rated condition (for example, at rated voltage, flow, pressure and load). On machines with varying speeds or loads, perform measurements at all extreme rating conditions in addition to selected conditions within these limits. The maximum measured value represents the vibration severity. Stinger Mounted Vibration Sensor
Magnetically Mounted Vibration Sensor
load zone
11
What are you Measuring?
Selecting Measurements
Vibration is the behavior of a machine’s mechanical components as they react to internal or external forces. Since most rotating machinery problems show themselves as excessive vibration, we use vibration signals as an indication of a machine’s mechanical condition. Also, each mechanical problem or defect generates vibration in its own unique way. We therefore analyze the “type” of vibration to identify its cause and take appropriate repair action. With overall vibration monitoring (VIB ISO) using the Examiner 1000, analysis of the cause of excess vibration relates to the monitoring equipment’s probe position; either horizontal, vertical, or axial.
Establish measurement types that most accurately reflect the condition of the equipment. Different causes or “mechanisms” are acting on the machine; various types of measurements have been developed to measure each type of mechanism. Those mechanisms are: Stress A force on the machine or components which deflects the part. Best measured in Displacement. The Examiner 1000 does not measure Displacement as it is a very low vibration frequency, below 10 Hz (600 RPM).
Horizontal - Typically, unbalanced shafts tend to cause excess radial (horizontal and vertical) vibrations, depending on the machine support design. Vertical - Excessive vertical vibration can indicate mechanical looseness as well as imbalance. Axial - Excessive axial vibration is a strong indicator of misalignment. It’s important to note that these are general guidelines and that knowledge of your machinery and proper hand-held probe techniques are necessary to accurately analyze the cause of excessive vibration.
Fatigue Repeated cycles of stress on a component. If you bend a part back and forth enough times it will fatigue. As a general rule, fatigue failures result from vibration frequencies 10 -2000 Hz and Velocity measurements are used. Velocity will be the primary measurement taken. Force
Mass x acceleration. Measured in Acceleration. Acceleration is the rate of change of velocity. Acceleration is used for high frequencies above 2000 Hz (120,000 RPM). Bearing defects and gearmesh frequencies are usually found in this range.
Multi-Parameter Monitoring Using different measurement types to monitor your machinery for changes. This allows for early detection of specific machinery problems that may not show under normal overall vibration monitoring. For example, if a rolling element bearing has a defect on its outer race, each roller will strike the defect as it goes by and cause a small, repetitive vibration signal. However, this vibration signal is of such low amplitude that under normal overall vibration monitoring, it is lost in the machine’s rotational and structural vibration signals. Acceleration Enveloping can measure these signals better than overall readings. Use both measurement types for bearings and gearboxes. As ENV values begin to decrease, rely on VEL readings. Overall Vibration Monitoring -Monitors normal, low frequency machine vibration. Detects rotational and structural problems like imbalance, misalignment, and mechanical looseness. Enveloping - Amplifies high-frequency, repetitive bearing and gear mesh vibration signals for early detection of bearing problems, but does not detect non-repetitive rotational or structural events like imbalance, misalignment, and looseness. Provides earliest detection of high frequency metal-to-metal contact or poor lubrication in problem bearings.
10
Impact forces The result of fatigue. Impact forces are cyclical events which can be detected with Acceleration Enveloping. These are high frequency-low amplitude events and a filter in the EXAMINER 1000 is set at 10-30 kHz to measure them.
Types of Measurements in the EXAMINER 1000 Velocity- Good for frequency ranges 10-2000 Hz (600-120,000 RPM). Acceleration-used for higher frequencies or speeds above 2000 Hz (120,000 CPM). Acceleration Enveloping-uses a high pass filter to measure high-frequency, repetitive bearing and gearmesh vibration signals. Used for early detection of developing bearing or lubrication problems. Use this type in combination with the other types to detect changes in machinery. Select Measurement Intervals Based on the classification of the machine, its repair history and the amount of data required for a detailed trend analysis. At the beginning of a Predictive Maintenance Program, collect data frequently to build a rapid history of each machine. Adjust your program as you go. If measurement results are indicating signs of change, measurements should be performed more frequently.
7
Getting Started in Your Plant
Establishing a Data Collection Route
Planning your work is very important to achieve success. The EXAMINER 1000 is an overall vibration meter and electronic stethoscope. It can be used as a stand alone device for the collection of vibration data for the purposes of trending or as a diagnostic instrument used to troubleshoot machinery defects. In order to setup a trending program you must collect data on the same point with the same measurement type at a defined interval. The Machinery Data Worksheet allows for record keeping of collected data. The EXAMINER may be used with the On-Time software to store data and perform trend analysis. REPEATABILITY IS REQUIRED FOR ACCURATE TRENDING.
The Machinery Data Worksheet helps organize data for routine data collection. Vibration readings are taken on the Points (bearings) established in your route and recorded using your naming convention on the worksheet. Vibration, speed, temperature, pressure or any process data may be recorded using this type of systematic approach.
Establish a standard naming convention so you can communicate your results to the rest of maintenance. Vibration readings are taken on the bearing caps or as close to the bearings as possible. Always collect data the same way, at the same point on the machine each time.
Direction for placing the Sensor
Steps for Route collection 1. Determine the machines which require data collection. 2. Define each measurement type for data collection Points on each Machine. Several Points will have numerous readings i.e. VEL and ENV and Temp. 3. Establish a Route with the Machines grouped by physical location. 4. Walk the Route, collecting and recording data for each Point. 5. Transfer data values to your On-Time Trending software.
Recording Data for a Machine
Vertical
For Vertical and Horizontal readings, the sensor is placed in a radial position.
Axial
Also establish a starting point for each machine. Begin from the OUTBOARD END of the DRIVE UNIT, calling this point A. Proceed to label Points (bearings) as needed until you have reached the outboard end of the driven unit. POINT 1234 1234 A 123456B C D
MOTOR
1234 1234 1234 1234 1234 1234 1234 1234
Point AVV is taken on the outboard end of the motor, in the vertical position with a velocity type reading. AHV -Point A in the horizontal position with a Velocity type.
PUMP
8
C
123456 123456 123456 123456 123456 123456
D
MOTOR
1234 1234 1234 1234 1234 1234 1234 1234 1234 PUMP
example of Machinery Data Worksheet
Horizontal
123456 123456 123456 123456 123456 123456 123456
A123456B
The vibration sensor is placed on each data collection Point. The Point, direction of the sensor and the value are recorded on the Machinery Data Worksheet.
9
Machine Identification Water Pump #707 Machine Description AC motor 1800 RPM, flexible coupling, 3 vane pump. CAUTION HOT WATER!!!
Date Jan Jan Jan Jan Jan Jan
2 2 2 2 2 2
Point Direction Type Value 1999 1999 1999 1999 1999 1999
A A A B B B
V H X V H V
V V V V V Env
0.06 in/s 0.04 in/s 0.03 in/s 0.07 in/s 0.05 in/s 0.001 ge

Some standards classify the status of machines based on vibration analysis. Former standards like ISO 2372:1974 Mechanical vibration of machines with.