Agilent Technologies 6010a, 6011A, 6012B, 6015A service manual Constant Current CC Tests

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200Vdc (6010A) 20.0Vdc (6011A) 60.0Vdc (6012B) 500Vdc (6015A) as read on the DVM.

e.After 30 minutes stabilization, record the temperature to the nearest 0.1°C. Record the output voltage on the DVM.

f.Set oven temperature to 50°C.

g.After 30 minutes stabilization, record the temperature to the nearest 0.1°C. Record output voltage.

h.Check that the magnitude of the output voltage change is no greater than 620mV.(6010A)

80mV (6011A) 176mV (6012B) 1.6V (6015A)

Drift (Stability). Drift is the change in output voltage beginning after a 30-minute warm-up during 8 hours operation with constant ac input line voltage, constant load resistance and constant ambient temperature. Use a DVM and record the output at intervals, or use a strip-chart recorder to provide a continuous record. Check that the DVM's or recorder's specified drift during the 8 hours will be no more than 0.001%. Place the unit in a location with constant air temperature preferably a large forced-air oven set to 30°C and verify that the ambient temperature does not change by monitoring with a thermometer near the unit. Typically the drift during 30 minute warm-up exceeds the drift during the 8-hour test. To measure offset drift, repeat the procedure with output voltage set to 0.10Vdc.

a.Connect DVM between + S and - S.

b.Turn the unit's power-on and turn up current setting to full output.

c.Turn up output voltage to: 200Vdc (6010A)

20Vdc (6011A) 60.0Vdc (6012B) 500Vdc (6015A)

as read on the digital voltmeter.

d.After a 30 minute warmup, note reading on DVM.

e.The output voltage should not deviate more than 77mV (6010A)

9mV (6011A) 23mV (6012B) 190mV (6015A)

from the reading obtained in step d over a period of 8 hours.

Constant Current (CC) Tests

CCSetup. Constant-current tests are analogous to constant-voltage tests, with the unit's output short circuited and the voltage set to full output to assure CC operation. Follow the general setup instructions on Page 16.

Load Effect (Load Regulation). Constant current load effect is the change in dc output current (Io) resulting from a load-resistance change from short-circuit to full-load, or full-load to short-circuit. Full-load is the resistance which develops the maximum rated output voltage at current Io. Proceed as follows:

a.Connect the test equipment as shown in Figure 2-3. Operate the load in constant resistance mode (Amps/Volt) and set resistance to minimum.

b.Turn the unit's power-on, and turn up voltage setting to full output.

c.Turn up output current to:

5.0Adc (0.050Vdc across Rm) (6010A) Check that the AMPS display reads about 5 amps. 50Adc (0.25Vdc across Rm) (6010A) Check that the AMPS display reads about 50 amps.

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Contents Autoranging DC Power Supply Agilent Models 6010A, 6011A Certification Safety Summary Safety Symbol Definitions Table of Contents Replaceable Parts Troubleshooting Circuit DiagramsSafety Considerations ScopeManual Revisions Item DescriptionCalibration Procedure IntroductionTest Equipment Required Operation Verification TestsType Required Characteristics USE Recommended Model Test Equipment Required4KVA Initial Setup Calibration ProcedureMON Display Settings VoutIout Common Mode Setup Performance Tests Measurement TechniquesCR4 Current-Monitoring Resistor Setup Basic Test Setup Constant Voltage CV TestsPage RMS Measurement Test Setup, CV Pard Test Peak-To-Peak Measurement Test Setup, CV Pard Test 6010A 6011A Not Applicable6012B 6015A Load Transient Recovery Waveform 6010A 6011A 6012B 6015AConstant Current CC Tests Page CC Pard Test Setup Troubleshooting Initial Troubleshooting ProceduresControl Board Test Connector, A2J7 VdcRepair and Replacement Electrostatic ProtectionA2 Control Board Removal A4 FET Board RemovalA5 Diode Board Removal A3 Front Panel Board RemovalA1 Main Board Removal Overall Troubleshooting Procedure A1 Designator Wire color A3S1 Position Rear ViewA3 Front Panel Assembly Rear View Using the Tables Main Troubleshooting SetupMain Troubleshooting Setup Modified Mains Cord Set For Troubleshooting Troubleshooting No-Output Failures Front Panel TroubleshootingA2J7-26 A2J7-25 Troubleshooting Bias Supplies A3 Front Panel Board Failure SymptomsPerformance Failure Symptoms Node + Node + N0DEPower Section Blocks Troubleshooting AC-Turn-on CircuitsTroubleshooting PWM & Clock AC FaultRelay Enable + OUTTroubleshooting DC-To-DC Converter Troubleshooting Down ProgrammerPWM-ON PWM-OFFWaveforms Troubleshooting CV Circuit Troubleshooting CC CircuitON/OFF OFFTroubleshooting OVP Circuit SET Voltage Setup MeasurementPage Autoranging Power OverviewSystem Description Regulation & Control Subsystem A and 6015A Simplified Schematic A and 6012B Simplified Schematic Quick Reference Guide to Major Circuits Major Function OperationInput from Output to PWM DP DP PWMInput Power Subsystem Protection SubsystemDC Power Conversion Subsystem Output SubsystemFront Panel Board Page Simplified Front Panel Schematic Replaceable Parts Reference DesignatorsOrdering Information Description AbbreviationsMain Board Assembly CB1 CR1CR2 CR5VR1 A1 Mechanical6010A C37 6010A, 6011A, 6015A Not Used Not Used Not Used Page Not Used VR2 VR5VR6 TB1 TB2Not Used VR1 VR2 Agilent ModelTS1 Drvr TTL NOR DualCR3 CR6FET N-CHAN A5 Mechanical A6 Mechanical Chassis Electrical Not Used Component Location and Circuit Diagrams Schematic Diagram NotesIndicate number of paths represented by the line Top View, Top Covers Removed Main Board A1 and Filter Board A6 Component Location Control Board A2 Component Location Front Panel Board A3 Component Location FET Board A4 Component Location Diode Board A5 Component Location Page Page Page Page Specifications General InformationOption 002 Hardware Table A-1. Specifications, Option Remote Programming Input Compliance Voltage ± Current Programming EnableStatus Indicators AccuracyRemote Trip and Remote Reset Timing Power-on PresetMaximum Output Voltage logic high + On State logic lowTable A-1. Specifications, Option Pulse Timing Bias Supplies DC Output Ratings 25C ±Short Circuit Output Current Pard TypicalInstallation Connector Assembly ProcedureFigure A-1. Mating Connector Assembly OperationLocal/Remote Programming Resistance Voltage or Current Remote Resistance Programming Figure A-4. Calculating Value of Series Dropping ResistorFigure A-5. Remote Resistance Programming Remote Monitoring 101Status Indicators Remote Control102 Remote Reset Overvoltage103 Power-On Preset 104AC Dropout Buffer Circuit Multiple Supply System Shutdown105 Maintenance Bias Supplies106 Troubleshooting Resistance and Voltage Programming Troubleshooting Current Programming107 Figure A-11. Troubleshooting Current Programming of CV Mode 108Figure A-13. Troubleshooting Status Indicators 109110 Table A-3. Replacement Parts 111112 VR9 113Logic Symbols and Definitions Indicator and Qualifier Symbols114 Schematic Diagram Notes 115Schematic Notes Figure A-15. Option 002 Board, Component Location 116Figure A-16. Option 002 Board, Schematic Diagram 117 Page Model 6010A Change Model 6011A Change119 Model 6012B Change Model 6015A Change120 Delete 121122 123 124 DS5 125126
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6015A, 6012B, 6011A, 6010a specifications

Agilent Technologies, a leader in the field of measurement and analysis, offers a suite of instruments within its 6010 and 6011 series, specifically the 6010A, 6011A, 6012B, and 6015A models. These devices are designed to meet the needs of various industries, including healthcare, environmental monitoring, and materials testing.

The Agilent 6010A is a high-performance spectrometer known for its precision and versatility. It utilizes advanced optical technologies to provide exceptional wavelength accuracy and resolution. This model is particularly useful in laboratories where reliable data is critical, offering a wide spectral range and effective noise reduction features. Its user-friendly interface simplifies complex analyses, making it suitable for both seasoned professionals and newcomers.

Following closely, the Agilent 6011A is recognized for its robust capabilities in laboratory environments. This device incorporates advanced signal processing techniques, enabling high-throughput measurements without compromising on quality. The 6011A is ideal for real-time monitoring applications, ensuring that users can make informed decisions based on accurate, timely data. Its comprehensive software suite is designed to enhance data analysis, allowing for seamless integration with existing laboratory workflows.

The 6012B variant enhances the functionality further by introducing additional features tailored for specific applications. With a focus on flexibility, the 6012B supports multiple measurement modes, including direct and differential detection. This model excels in complex measurements, allowing for greater analytical depth and insights. The built-in calibration options ensure consistent performance, making it a reliable choice for various research and development tasks.

Lastly, the Agilent 6015A model stands out with its leading-edge technology, designed for the most demanding applications. It boasts enhanced sensitivity and an improved dynamic range, making it perfect for trace analysis in challenging environmental samples. The 6015A’s advanced reporting tools provide detailed analytics, helping scientists and researchers interpret results efficiently. Its compact design also makes it suitable for laboratory spaces with limited room, without sacrificing performance.

Together, these models showcase Agilent Technologies' commitment to delivering high-quality, innovative solutions that empower users to achieve their analytical goals effectively and efficiently. Whether in a research, clinical, or industrial setting, the 6010A, 6011A, 6012B, and 6015A continue to set standards in precision instrumentation.
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