safety analyzer
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Electrical topic about safety analyzerTRANSCRIPT
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Calibration and Electrical Safety of Medical Equipment
Dr Fadhl [email protected]
www.Fadhl-alakwa.weebly.com
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Why Test & Calibration
What you cannot measure you cannot control
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As components age and equipment undergoeschanges in temperature or humidity or sustains
mechanical stress, performance graduallydegrades.
This is called drift.
When this happens your test results become unreliable and both design and performance quality
suffer.
While drift cannot be eliminated, it can be detected and either corrected or compensated for through
the process of calibration.
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Definitions
• Calibration: process of comparing an unknown against a reference standard within defined limits, accuracies and Uncertainties
• Verification: process of comparing an unknown against a reference standard at usually one data point
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Requirements of Test & Calibration service
– Written Program
– Routine calibration or verification at suitable intervals
– Control of inspection, measuring and test equipment.
– Calibration procedures including specific directions and limits for accuracy and precision
– Deviation or discrepancies should be investigated
– Traceable Calibration Standards
– Calibration records
– Visible Calibration status
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What to TEST for?
• Performance Testing
• Safety Testing
When to test
• On newly acquired equipment prior to being accepted for use
• During routine planned preventative maintenance.
• After repairs have been carried out on equipment.
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Need for Medical Equipment Testing
• Medical device incidents resulting in patient injury and death• Ensure that the equipment is performing to the expected standards of accuracy, reliability, free of hysteresis and linear (as designed).• Safe and effective devices need to be available forpatient care– Downtime costs money• Regulations, accreditation requirements and standards.
Why do we do electrical safety?
• Ensure patient safety– Protect against macroshock– Protect against microshock
• Test for electrical internal breakdown / damage to power cord, AC mains feed, etc.
• Meet codes & standards– AAMI, IEC, UL, NFPA, etc.
• Protect against legal liability– In case of a patient incident
International Electrotechnical Commission
• The International Electrotechnical Commission[1] (IEC) is a non-profit, non-governmental international standards organization that prepares and publishes International Standards for all electrical, electronic and related technologies – collectively known as "electrotechnology".
International Electrotechnical Commission
• IEC standards cover a vast range of technologies from power generation, transmission and distribution to home appliances and office equipment, semiconductors, fibre optics, batteries, solar energy, nanotechnology and marine energy as well as many others.
• The IEC also manages three global conformity assessment systems that certify whether equipment, system or components conform to its International Standards.
International Electrotechnical Commission• Today, the IEC is the world's leading international
organization in its field, and its standards are adopted as national standards by its members. The work is done by some 10 000 electrical and electronics experts from industry, government, academia, test labs and others with an interest in the subject.
• They also first proposed a system of standards, the Giorgi System, which ultimately became the SI, or Système International d’unités (in English, the International System of Units).
IEC, ISO, ITU, IEEE• The IEC cooperates closely with the
International Organization for Standardization (ISO) and the International Telecommunication Union (ITU). In addition, it works with several major standards development organizations, including the IEEE with which it signed a cooperation agreement in 2002, which was amended in 2008 to include joint development work.
• Other standards developed in cooperation between IEC and ISO are assigned numbers in the 80000 series, such as IEC 82045-1.
List of IEC standards
• IEC standards have numbers in the range 60000–79999 and their titles take a form such as IEC 60417: Graphical symbols for use on equipment. The numbers of older IEC standards were converted in 1997 by adding 60000, for example IEC 27 became IEC 60027.
List of IEC standards• IEC 60027 Letter symbols to be used in electrical technology... • IEC 60034 Rotating electrical machinery• IEC 60038 IEC Standard Voltages • IEC 60044 Instrument transformers • IEC 60050 International Electrotechnical Vocabulary• IEC 60062 Marking codes for resistors and capacitors • IEC 60063 Preferred number series for resistors and capacitors• IEC 60065 Audio, video and similar electronic apparatus - Safety
requirements• IEC 60068 Environmental Testing • IEC 60071 Insulation Co-ordination • IEC 60073 Basic Safety principles for man-machine interface, marking and
identification
http://en.wikipedia.org/wiki/List_of_IEC_standards
List of IEC standards
• IEC 60601 Medical Electrical Equipment• IEC 62304 Medical Device Software -
Software Life Cycle Processes• IEC 62366 Medical devices—Application of
usability engineering to medical devices• IEC 62464 Magnetic resonance equipment
for medical imaging
http://en.wikipedia.org/wiki/List_of_IEC_standards
IEC 60601-x-xx
• – the IEC 60601-1-xx series of collateral standards for MEDICAL ELECTRICAL EQUIPMENT;
• – the IEC 60601-2-xx series of particular standards for particular types of MEDICAL
• ELECTRICAL EQUIPMENT; and• – the IEC 60601-3-xx series of performance
standards for particular types of MEDICAL ELECTRICAL EQUIPMENT.
IEC 60601-x-xx
• IEC 60601-1-2, Medical electrical equipment – Part 1-2: General requirements for safety Collateral standard: Electromagnetic compatibility – Requirements and tests
• IEC 60601-1-3, Medical electrical equipment – Part 1: General requirements for safety – 3. Collateral standard: General requirements for radiation protection in diagnostic X-ray equipment
IEC 60601-x-xx
• IEC 60601-1-6, Medical electrical equipment – Part 1-6: General requirements for safety Collateral standard: Usability
• IEC 60601-1-8, Medical electrical equipment – Part 1-8: General requirements for safety Collateral standard: General requirements, tests and guidance for alarm systems in medical electrical equipment and medical electrical systems
Physiological Effects of Electricity
The human body can easily detect macroshock and violent reactions occur to high current flow level in the body…
Below 1 ma (1,000 µa), it is often much more difficult to detect the presence of a shock hazard from simple perception…
Classes and types of medical electrical equipment
• Equipment ClassI,II,III method of protection against electric shock
• Equipment TypeB,BF,CF degree of protection
Classes and types of medical electrical equipment
• All electrical equipment is categorised into classes according to the method of protection against electric shock that is used. For mains powered electrical equipment there are usually two levels of protection used, called "basic" and "supplementary" protection. The supplementary protection is intended to come into play in the event of failure of the basic protection.
Class I• Class I equipment has a protective earth. The basic means
of protection is the insulation between live parts and exposed conductive parts such as the metal enclosure.
• In the event of a fault that would otherwise cause an exposed conductive part to become live, the supplementary protection (i.e. the protective earth) comes into effect. A large fault current flows from the mains part to earth via the protective earth conductor, which causes a protective device (usually a fuse) in the mains circuit to disconnect the equipment from the supply.
Class I
Class I
• term referring to electrical equipment in which protection against electric shock does not rely on BASIC INSULATION only, but which includes an additional safety precaution in that means are provided for ACCESSIBLE PARTS of metal or internal parts of metal to be PROTECTIVELY EARTHED
CLASS II
• term referring to electrical equipment in which protection against electric shock does not rely on BASIC INSULATION only, but in which additional safety precautions such as DOUBLE INSULATION or REINFORCED INSULATION are provided, there being no provision for protective earthing or reliance upon installation conditions
Class II
Class III equipment• Class III equipment is defined in some
equipment standards as that in which protection against electric shock relies on the fact that no voltages higher than safety extra low voltage (SELV) are present. SELV is defined in turn in the relevant standard as a voltage not exceeding 25V ac or 60V dc. In practice such equipment is either battery operated or supplied by a SELV transformer.
• If battery operated equipment is capable of being operated when connected to the mains (for example, for battery charging) then it must be safety tested as either class I or class II equipment. Similarly, equipment powered from a SELV transformer should be tested in conjunction with the transformer as class I or class II equipment as appropriate.
• It is interesting to note that the current IEC standards relating to safety of medical electrical equipment do not recognise Class III equipment since limitation of voltage is not deemed sufficient to ensure safety of the patient. All medical electrical equipment that is capable of mains connection must be classified as class I or class II. Medical electrical equipment having no mains connection is simply referred to as "internally powered".
Equipments Type
different pieces of medical electrical equipment APPLIED PARTShave different areas of application and therefore different electrical safety requirements. For example, it would not be necessary to make a particular piece medical electrical equipment safe enough for direct cardiac connection if there is no possibility of this situation arising.
Normative Reference Page 371
• Current density and electrically induced ventricular fibrillation. Medical Instrumentation, January-February 1973, Vol. 7, No. 1.
• WATSON, AB. and WRIGHT, JS., Electrical thresholds for ventricular fibrillation in man. Medical Journal of Australia, June 16, 1973.
Terminology and definitions
• http://www.601help.com/Disclaimer/glossary.html#ProtectiveEarthTerminal
Terminology and definitions
• L1 Hot• L2 Neutral• Earth Ground• Mains Line Voltage• Applied Parts Patient Leads• Enclosure/Case Chassis• Protective Earth Ground Wire• Earth Leakage Current Leakage in Ground Wire
Terminology and definitions
• Enclosure Leakage Chassis Leakage• Patient Leakage Lead Leakage• Patient Auxiliary Leakage between Patient
Leads• Mains on Applied Parts Lead Isolation• Insulation Resistance Dielectric Strength or
Insulation Resistance between Hot and Neutral to Ground
• Earth Resistance Ground Wire Resistance
R.M.S and Peak to PeakVrms is the value indicated by the vast majority of AC voltmeters.
The RMS value of an alternating voltage or current is the same as the level of direct voltage or current that would be needed to produce the same effect in an equal load.For example, 1 V applied across a 1 Ω resistor produces 1 W of heat. A 1 Vrms square wave applied across a 1 Ω resistor also produces 1 W of heat. That 1 Vrms square wave has a peak voltage of 1 V, and a peak-to-peak voltage of 2 V.
Calculate RMS
≈ 0.707 Vpk
• RMS is a sort of average and peak is the top level• A peak is an instant reading - RMS is an "average"
reading. RMS means to take the root of the mean and square it.
• RMS value is the DC equivalent value to an AC stream.• The RMS value of an alternating voltage or current is
the same as the level of direct voltage or current that would be needed to produce the same effect in an equal load.
Crest Factor
• The Crest Factor is equal to the peak amplitude of a waveform divided by the RMS value.
• Electrical engineering — for describing the quality of an AC power waveform
Applied Part
tableNo applied part
Parts that contact PATIENTS
Applied PartA part of the equipment which in normal use: necessarily comes into physical contact with the patient for the equipment to perform its function; or can be brought into contact with the patient; or needs to be touched by the patient
Accessible Part
• Part of equipment which can be touched without the use of a tool.
• EXAMPLE 1 Illuminated push-buttons• EXAMPLE 2 Indicator lamps• EXAMPLE 3 Recorder pens• EXAMPLE 4 Parts of plug-in modules• EXAMPLE 5 Batteries•
Leakage currents
• Current that is not functional.• several different leakage currents are defined
according to the paths that the currents take. • Earth Leakage Current • Enclosure Leakage Current • Patient Leakage Current• Patient auxiliary current
Causes of Leakage currents
• If any conductor is raised to a potential above that of earth, some current is bound to flow from that conductor to earth.
• The amount of current that flows depends on: 1- the voltage on the conductor.
2- the capacitive reactance between the conductor and earth.
3-the resistance between the conductor and earth.
EARTH LEAKAGE CURRENT
• current flowing from the MAINS PART through or across the insulation into the PROTECTIVE EARTH CONDUCTOR
EARTH LEAKAGE CURRENT• Under normal conditions, a person who is in contact with
the earthed metal enclosure of the equipment and with another earthed object would suffer no adverse effects even if a fairly large earth leakage current were to flow. This is because the impedance to earth from the enclosure is much lower through the protective earth conductor than it is through the person. However, if the protective earth conductor becomes open circuited, then the situation changes. Now, if the impedance between the transformer primary and the enclosure is of the same order of magnitude as the impedance between the enclosure and earth through the person, a shock hazard exists.
EARTH LEAKAGE CURRENT Measurement
Measurement of earth leakage current
Enclosure leakage current /touch current
• LEAKAGE CURRENT flowing from the ENCLOSURE to earth or to another part of the ENCLOSURE through a conductor other than the protective earth conductor.
Enclosure leakage current/touch current
Measurement of enclosure leakage current
Patient leakage current
• Patient leakage current is the leakage current that flows through a patient connected to an applied part or parts.
• It can either flow from the applied parts via the patient to earth or from an external source of high potential via the patient and the applied parts to earth.
Patient leakage current
Measurement of patient leakage current
Measurement of patient leakage current
Patient auxiliary current
• The patient auxiliary current is defined as the current that normally flows between parts of the applied part through the patient, which is not intended to produce a physiological effect
Patient auxiliary current
Measurement of patient auxiliary current.
Mains on applied parts
Protective Earth Continuity
• The resistance of the protective earth conductor is measured between the earth pin on the mains plug and a protectively earthed point on the equipment enclosure (see figure 6). The reading should not normally exceed 0.2Ω at any such point. The test is obviously only applicable to class I equipment.
Protective Earth Continuity
• In IEC60601, the test is conducted using a 50Hz current between 10A and 25A for a period of at least 5 seconds. Although this is a type test, some medical equipment safety testers mimic this method. Damage to equipment can occur if high currents are passed to points that are not protectively earthed, for example, functional earths.
• Applicable to Class I, all types • Limit: 0.2Ω • DB9801 recommended?: Yes, at 1A or less. • HEI 95 recommended?: Yes, at 1A or less.
Notes: Ensure probe is on a protectively earthed point
Insulation Tests Class I
• HEI 95 and DB9801 recommended that for class I equipment the insulation resistance be measured at the mains plug between the live and neutral pins connected together and the earth pin. Whereas HEI 95 recommended using a 500V DC insulation tester, DB 9801 recommended the use of 350V DC as the test voltage.
• Applicable to Class I, all types• Limits: Not less than 50MΩ • DB9801 recommended?: Yes • HEI 95 recommended?: Yes • Notes: Equipment containing mineral
insulated heaters may give values down to 1MΩ. Check equipment is switched on.
Insulation Tests Class II
• HEI 95 further recommended for class II equipment that the insulation resistance be measured between all applied parts connected together and any accessible conductive parts of the equipment. The value should not normally be less than 50MΩ (see figure 10).
Leakage current summary
• The following table summarises the leakage current limits (in mA) specified by IEC60601-1 (second edition) for the most commonly performed tests. Most equipment currently in use in hospitals today is likely to have been designed to conform to this standard, but note that the allowable values of earth leakage current have been increased in the third edition of the standard as discussed above.
Leakage current summary
• The following table summarises the leakage current limits (in mA) specified by IEC60601-1 (second edition)
http://www.ebme.co.uk/arts/safety/part6.htm
Limitation of voltage, current or energy(87)
Electrical Safety Tests• Available electrical safety tests include:• Mains Voltage• Dual Lead Voltage• Dual Lead Leakage• Current Consumption• Insulation Resistance• Protective Earth Resistance• Earth Leakage Current• Enclosure Leakage Current• Patient Leakage Current• Mains on Applied Part Leakage• Patient Auxiliary Current• Accessible Voltage• Accessible Leakage• Equivalent Device Leakage• Equivalent Patient Leakage
How to measure resistance?
The 2-terminal method is less accurate due to the effects of test
lead resistance, especially with long leads and low resistance value
measurements. The much preferred 4-terminal “Kelvin” technique
negates the effects of test lead resistance and gives more accurate
readings…
Proper grounding is the best defense against macroshock & microshock!
Electrical Shock Hazard An
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• A common experience due to electric shock• Associated with equipments • Electric current can flow through the human
body either– Accidentally or Intentionally
• Other reasons of electric shock include– Careless use of electricity– Usage of faulty cords and appliances– Lack of concept/Faulty design– Relied upon life support devices (Pace maker/
respirators)
Electrical Shock Hazard • Use of medical equipments in
conjunction with other instruments and equipments
• Environmental conditions• Patient/Operator not realizing
potential hazards• 2 situations account hazards
from electric shock– Gross shock– Micro - current shock
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Gross shock• Experienced by the subject
by an accidental contact with electric wiring at any point on the surface of the body
• Current flows through the body of the subject (ex. from arm to arm)
• Body acts as a volume conductor at the mains frequency
• Degree of simulation varies from individual to individual
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Micro - current shock• Current passes directly through
the heart wall• Thresholds of sensation of
electric currents differ widely • Greater % of current may flow
via the arterial system directly through the heart
• Requires much less currents to produce ventricular fibrillation– EX. Catheter laboratory or
operating room where patient connected to catheter in the heart
• Here patients have very little resistance to electric currents
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Physiological Effects of Electricity
Tissue Resistance
• Skin - 5000 ohms/cm2• Blood - 100 ohms/cm2• Muscle - 200-400 ohms/cm2• Fat - 2000-3000 ohms/cm2• Bone - 3000+ ohms/cm2Current goes to the path of least resistance
Leakage Current• Inherent flow of non functional
current from live electric parts of instrument to accessible metal parts
• Usually flow through 3rd wire connection to ground
• Magnitude of leakage current is determined by the value of the capacitance present
• Originates due to capacitive coupling from the power transformer primary to other parts of the transformer (or instruments)
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Types of Leakage Current• Enclosure leakage current: Current flows in
normal condition from the enclosure (or part of enclosure) through a person in contact with an accessible part of enclosure to earth (or another part of the enclosure)
• Earth leakage current: Current flows in normal condition to earth from main parts of apparatus via earth conductor
• Patient leakage current: Current flows through patient from or to applied parts of the patient circuits
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Effects of Electric Current on Human Body• Threshold of perception of
electric shock is about 1mA• Tingling sensation is felt when
contacted with electrified object through intact of skin
• As magnitude of alternating current is increased – Tingling sensation leads to
contraction of muscles– Muscular contraction increases– Finally value of current is
reached where grip of current cannot be released
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Effects of Electric Current on Human Body• Let -go- current: the max. current at which the subject is
still capable of releasing a conductor by using muscles– Here individual can withstand with no serious effects– Average let go current for males- 16mA, females-10.5mA, approx.
9-6 mA for both.
• Hold-on-type: A current level higher than let go current, the subject looses ability to control his own muscle action and unable to release grip on the conductor– Such currents are very painful and hard to bear– Physical injury is caused b currents in range of 20-100mA
• A very high currents (6 amperes and above) lead to– Temporary respiratory paralysis– Serious burns
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Recommendations of IEC• International Electrotechnical
Commission (IEC)• Continuous medical equipment
current should not exceed 100 uA
• Should be with in a frequency range of 0 to 1kHz
• In abnormal situations recommended max. current is 500 uA
• Should be in a frequency upto 1 kHz
• Above 1 kHz max increases is proportionally with frequency
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Precautions• Use apparatus or appliances with
three wire power cord• Provide isolated input circuits on
monitoring equipment• Have periodic checks of ground
wire continuity• No other equipment to be
connected when patient monitoring equipment is connected
• Clearly mark functional controls• Take care of adapter plugs that do
not ensure proper grounding circuit• Direct operating instructions to the
operators• Maintaining voltage differencesAn In
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Macroshock and Microshock
History
• The expansion of technology was unregulated, and unexplained deaths in hospitals were attributed by some to electrical shocks• Studies showed that electrical shock risks were the greatest when the patient had conductors internal to
the body• If a conductive catheter is placed in the heart, 100
micro amps at 60 Hz can cause fibrillation of heart and death
Automated Electrical Safety Analyzer 601PRO Series XL – Fluke Biomedical
Standard Features• The most advanced Electrical Safety Analyzer
on the market• EN60601-1, EN601010-1, and AAMI & ESI
test loads (user selectable) into one device• The One-Touch-Testing user interface• Allows user to perform rapid tests on various
medical devices• Multiple enclosure-leakage points • Multiple patient-applied-part types
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Standard Features• Power ON/OFF delay • DC only for patient- and auxiliary-leakage tests • User-programmable test sequences • Offers manual, auto, step, and computer-
control mode operations• ASCII data transfer • Memory for up to 1000 device-information
records• Conducts electrical safety testing in accordance
with IEC 601-1, VDE 751, VDE 701, HEI 95, IEC 1010, AAMI, and AS/NZS 3551 requirements
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Standard Features• Flags failures, and simulates
performance, ECG, and arrhythmia, waveforms.
• Results automatically analyzed and saved in non-volatile memory
• Accepts device information that is input using an – External keyboard, – Integrated keypad, – Barcode keyboard wedge
Optional Feature • Onboard thermal printing
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SpecificationsVoltage Range: 0 to 300 V True RMS (single and dual lead)
Accuracy: DC - 100 Hz ± 1.5 % of reading ± 1 LSD
Insulation Resistance Range: 0.5 to 400.0 MΩ
Accuracy: ± 5 % of reading ± 2 LSD
Current Consumption Range: 0 to 15 A ac True RMS
Accuracy: ± 5 % of reading ± 2 LSD
Mains on Applied Part Applied Voltage:≥ 110 % of mains voltage
Accuracy: ± 2 % of reading ± 6 µA
Protective Earth Resistance Range: 0.000 to 2.999 Ω
Accuracy:± 5 % of reading ± 4 mΩ (1 A, 10 A, and 25 A test currents) (Refer to Operator’s Manual for additional specs qualifying the effects on accuracy of variations in load inductance and phase angle.)
Supply Voltage90 to 265 Vac, auto switching
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Specifications60
1PRO
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XL
IEC601-1 and AAMI Leakage Currents Range: 0 to 8000 µA True RMS
Accuracy:
(per IEC601-1 or AAMI filter), -DC - 1 kHz ± 1 % of -reading ± 1 µA-1 to 100 kHz ± 2 % of reading ± 1 µA- 100 kHz to 1 MHz ± 5 % of reading ± 1 µA
DC-Only Frequency Response: DC - 5 Hz (approx)
ECG Simulation and Performance Testing ECG Complex: 30, 60, 120, 180, 240 BPM
Performance
Pulse: 30, 60 BPM, 63 ms pulse width
600 to 700 µs rise and fall timeSine Waves: 10, 40, 50, 60, 100 Hz
Square Wave: 0.125, 2.000 Hz (50 % duty cycle)
Triangle Wave: 2 Hz, 2 mV
Dimensions 16.62 in L x 11.75 in W x 5.56 in H
Weight 17lb / 7.7kg
Available electrical safety tests Mains Voltage Dual Lead Voltage Dual Lead Leakage Current Consumption Insulation Resistance Protective Earth
Resistance Earth Leakage Current Enclosure Leakage
Current Patient Leakage
Current
Mains on Applied Part Leakage
Patient Auxiliary Current
Accessible Voltage Accessible Leakage Equivalent Device
Leakage Equivalent Patient
Leakage
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Accessories• Probe/Safety Lead, Red - 1• Probe/Safety Lead, Black - 1• Adapter, Banana/Alligator - 5• Operators Manual - 1• Large Clamp, Red - 1 • Warranty Card - 1• Printer Paper Roll (original) - 1• Printer Paper Roll (new style) - 1
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Optional Accessories• Carry Case• RS232 Cable (9M-9F)• Printer Cable• Barcode, Keyboard, Wedge• Adapter, Banana, ECG• Keyboard English• Powercord Set Australian• Powercord Set Schuko • Powercord Set US 120 V• Powercord Set UK
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System Characteristics• Keys grouped by color and functionality• Red keys -used to access menu options
– Include previous key, the four SOFT KEYS, and the enter key
• Black keys -gain access to additional functions– Include the esc/stop key, the view present
settings key, the print header key, and the print data key.
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Setting Up the 601PRO
1. Using Factory Default Settings2. Selecting the Test Standard3. Selecting the Printer Output4. Selecting the RS232 Baud Rate5. Activating the Beeper6. Setting the Time and Date
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Setting Up the 601PRO7. Configuring the Enclosure Leakage for the
Auto mode Sequence8. Selecting Language Options9. Selecting the DC Option10.Selecting the Auto/Step Tests: Controlled
Power Sequences or 601CE Conventional Test
11.Sequences enabling Stop on Failure 12.Configuring for Device Records or
Templates
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Manual Mode
1. Connecting the Device Under Test2. The Power-Up Sequence3. Selecting the Test Standard4. Selecting the Class/Type5. Saving Standard, Class, Type and Test
Current6. Using View Present Settings7. Manual Operation
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Auto/Step Modes
1. Selecting Auto or Step Mode Testing2. Executing Auto and Step Mode Tests3. Creating/Editing a Device Record or
Template
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Test Records
1. Sending Test Results from the 601PRO to the Host
2. Computer3. Test Data Record: Serial Output4. Printing Test Records5. Deleting Test Records
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Device Records and Templates
1. Connecting the 601PRO and the Host Computer
2. Sending Device Information Records from the 601PRO to the Host Computer
3. Receiving Device Information Records from the Host computer
4. Device Information Record: Definition of Fields
5. Device Information Record Format6. Deleting Device Records and Templates
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Testing Devices
1. Permanently Wired Devices2. Portable Devices3. Portable Devices in Isolated Power
Systems4. Testing Three-Phase Portable Devices5. Testing Conductive Surfaces6. Detachable Power Supply Cable7. Battery-Powered Equipment
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Standards and Principles
1. Accessing System Setup2. Selecting the Test Standard3. Referring to Test Limits for the
Selected Standard
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