Allen-Bradley Power Supply - 12V, 10 A, 120 W, Single-phase Input Reference Manual
Allen-Bradley Power Supply - 12V, 10 A, 120 W, Single-phase Input is a cost-optimized power supply designed for industrial applications. It delivers 12V DC output with a current rating of 10 A and a power output of 120 W. The power supply boasts a variety of features, including high efficiency, active power factor correction, and robust protection mechanisms. It supports a wide input voltage range and operates within a broad temperature range. The device is compact and lightweight, making it suitable for various installations.
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Power Supply - 12V, 10 A, 120 W, Single-phase Input Catalog Number 1606-XLE120B Reference Manual Original Instructions Power Supply - 12V, 10 A, 120 W, Single-phase Input Reference Manual Important User Information Read this document and the documents listed in the additional resources section about installation, configuration, and operation of this equipment before you install, configure, operate, or maintain this product. Users are required to familiarize themselves with installation and wiring instructions in addition to requirements of all applicable codes, laws, and standards. Activities including installation, adjustments, putting into service, use, assembly, disassembly, and maintenance are required to be carried out by suitably trained personnel in accordance with applicable code of practice. If this equipment is used in a manner not specified by the manufacturer, the protection provided by the equipment may be impaired. In no event will Rockwell Automation, Inc. be responsible or liable for indirect or consequential damages resulting from the use or application of this equipment. The examples and diagrams in this manual are included solely for illustrative purposes. Because of the many variables and requirements associated with any particular installation, Rockwell Automation, Inc. cannot assume responsibility or liability for actual use based on the examples and diagrams. No patent liability is assumed by Rockwell Automation, Inc. with respect to use of information, circuits, equipment, or software described in this manual. Reproduction of the contents of this manual, in whole or in part, without written permission of Rockwell Automation, Inc., is prohibited. Throughout this manual, when necessary, we use notes to make you aware of safety considerations. WARNING: Identifies information about practices or circumstances that can cause an explosion in a hazardous environment, which may lead to personal injury or death, property damage, or economic loss. ATTENTION: Identifies information about practices or circumstances that can lead to personal injury or death, property damage, or economic loss. Attentions help you identify a hazard, avoid a hazard, and recognize the consequence. IMPORTANT Identifies information that is critical for successful application and understanding of the product. Labels may also be on or inside the equipment to provide specific precautions. SHOCK HAZARD: Labels may be on or inside the equipment, for example, a drive or motor, to alert people that dangerous voltage may be present. BURN HAZARD: Labels may be on or inside the equipment, for example, a drive or motor, to alert people that surfaces may reach dangerous temperatures. ARC FLASH HAZARD: Labels may be on or inside the equipment, for example, a motor control center, to alert people to potential Arc Flash. Arc Flash will cause severe injury or death. Wear proper Personal Protective Equipment (PPE). Follow ALL Regulatory requirements for safe work practices and for Personal Protective Equipment (PPE). 2 Rockwell Automation Publication 1606-RM109A-EN-P - August 2020 Table of Contents Product Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5 Specifications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6 Catalog Numbers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6 AC Input . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7 DC Input . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8 Input Inrush Current. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9 Output . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10 Hold up Time . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12 DC OK Relay Content . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12 Efficiency and Power Losses . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13 Functional Diagram . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 14 Front Side and User Elements . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 14 Connection Terminals . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15 Lifetime Expectancy. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16 Mean Time Between Failure. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16 Electromagnetic Capability . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17 Environment . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 18 Safety and Protection Features . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 19 Dielectric Strength . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 20 Certifications and Standards Compliance . . . . . . . . . . . . . . . . . . . . . . . . . 21 Approximate Dimensions. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 22 Accessories . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 23 Redundancy Module . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 24 Application Notes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 25 Additional Resources . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 31 Rockwell Automation Publication 1606-RM109A-EN-P - August 2020 3 Power Supply —12V, 10 A, 120 W, Single Phase Notes 4 Rockwell Automation Publication 1606-RM109A-EN-P - August 2020 Power Supply —12V, 10 A, 120 W, Single Phase Product Overview Bulletin 1606-XLE power supplies are cost optimized without compromising quality, reliability, and performance. The unit is compact with high efficiency, featuring electronic inrush current limitation, active power factor correction (PFC) and a wide operational temperature range. The device has a power reserve of 20% included, which may even be used continuously at temperatures up to 45 °C (113 °F). Additionally, it can deliver three times the nominal output current for 12 ms which helps to trip fuses on faulty output branches. The power supply features high immunity to transients, power surges and low electromagnetic emission, a DC OK signal contact for remote monitoring, and extensive approvals for a wide range of applications. • • • • • • 100…240V AC wide-range input Width 32 mm (1.26 in.) Efficiency up to 94.0% Excellent Partial Load Efficiency 20% Output Power Reserves Easy Fuse Breaking – 3 times nominal current for 12 ms • • • • • Safe HiccupPLUS Overload Mode Active Power Factor Correction (PFC) Minimal Inrush Current Surge Full Power Between -25… +60 °C (-13…+140 °F) DC OK Relay Contact Rockwell Automation Publication 1606-RM109A-EN-P - August 2020 5 Power Supply —12V, 10 A, 120 W, Single Phase Specifications Attribute Output Voltage Adjustment Range Value Notes 12V DC Nominal 12…15V Factory setting 12V 12…9.6 A Below 45 °C (113 °F) ambient 10…8 A At 60 °C (140 °F)ambient 7.5…6 A At 70 °C (158 °F) ambient Derate linearly between 45…70 °C (113…158 °F) 100…240V -15%/+10% 50…60 Hz ±6% 1.09/0.6 A At 120/230V AC 0.98/0.91 At 120/230V AC 110…150V DC ± 20% 1.21 A At 110/300V DC 4/4A At 120/230V AC 93.2/94% At 120/230V AC 8.8/7.7 W At 120/230V AC 35/35 ms At 120/230V AC -25…+70 °C (-13…+158 °F) — 32 x 124 x 102 mm Without DIN rail (1.26 x 4.88 x 4.02 in) 440 g (0.97 lb) — Output Current Input Voltage AC Frequency Input Current AC Power Factor Input Voltage DC Input Current DC AC Inrush current Efficiency Losses Hold-up time Temperature range Size (W x H x D) Weight Catalog Numbers Catalog Number 1606-XLE120B 6 Rockwell Automation Publication 1606-RM109A-EN-P - August 2020 Description 12V, 10 A, 120W Single-phase Power Supply Power Supply —12V, 10 A, 120 W, Single Phase AC Input The device is suitable to be supplied from TN, TT, or IT mains networks with AC voltage. For suitable DC supply voltages, see DC Input on page 8 . Attribute AC input Nom Min AC input range Min Allowed voltage L or N to earth Max Input frequency Nom Turn-on voltage Typ Shut-down voltage Typ External input protection — Value AC 100…240V 85…264V AC 264…300V AC 300V AC 50…60 Hz 80V AC 74V AC Notes — Continuous operation Occasionally for maximal 500 ms Continuous, according to IEC 606641 ±6% Steady-state value. See Figure 1. Steady-state value, See Figure 1. Input current Power factor Typ Typ AC 100V 1.30 A 0.99 AC 120V 1.09 A 0.98 AC 230V 0.60 A At 12V, 10ASee Figure 3 0.91 At 12V, 10 A See Figure 4, Crest factor Typ 1.7 1.8 2.2 Startup delay Typ 400 ms 350 ms 375 ms See Figure 2 At 12V, 10 A The crest factor is the mathematical ratio of the peak value to RMS value of the input current waveform. Typ 30 ms 30 ms 30 ms At 12V, 10 A const. current load, 0mF load capacitance. See Figure 2 Typ 50 ms 50 ms 50 ms At 12V, 10 A const. current load, 10mF load capacitance. See Figure 2 Turn-on overshoot Max 200 mV 200 mV 200 mV See Figure 2 Rise time Figure 1 - Input Voltage Range Figure 2 - Turn-on Behavior, Definitions Turn-on Shut-down Input Voltage max. 500 ms - 5% Output Voltage V IN 85V 264V Start-up delay Overshoot Rated input range P OUT Rise Time 300V AC Figure 3 - Input Current Versus Output Current at 12V Output Voltage Figure 4 - Power Factor Versus Output Current at 12V Output Voltage Power Factor, typ 1.0 Input Current, typ (a) 1.5 A (b) 1.25 a) 100V AC b) 120V AC c) 230V AC 1.0 0.75 0.95 (a) (b) 0.9 (c) 0.85 0.5 0.25 (a) 100V AC, (b) 120V AC, (c) 230V AC Output Current (c) 0.8 Output Current 0 0.75 1 2 4 6 8 10 12 A 2 4 Rockwell Automation Publication 1606-RM109A-EN-P - August 2020 6 8 10 12 A 7 Power Supply —12V, 10 A, 120 W, Single Phase DC Input The device is suitable to be supplied from a DC input voltage. Use a battery or a similar DC source. A supply from the intermediate DC-bus of a frequency converter is not recommended and can cause a malfunction or damage the unit. Connect +pole to L, –pole to N and the PE terminal to an earth wire or to the machine ground. Attribute DC input Nom DC input range Min DC input current Typ Allowed Voltage (+) or (-) input to Max Earth Value DC 110…150V 88…180V DC 1.21 A Notes ±20% Continuous operation At 110V DC 180V DC According to IEC 60664-1, continuous operation Turn-on voltage Shut-down voltage 74V DC 67V DC Steady state value Steady state value Typ Typ Figure 5 - Wiring for DC Input Battery + Power Supply AC L N PE + Load - DC 8 Rockwell Automation Publication 1606-RM109A-EN-P - August 2020 Power Supply —12V, 10 A, 120 W, Single Phase Input Inrush Current An active inrush limitation circuit (NTCs, which are bypassed by a relay contact) limits the input inrush current after turn-on of the input voltage. The charging current into EMI suppression capacitors is disregarded in the first microseconds after switch-on. Inrush current Inrush energy Figure 6 - Typical Turn-on Behavior at Nominal Load, 120V AC Input and 25 °C (77 °F) Ambient Input current 2A/DIV Input voltage 200V/DIV Output voltage 50ms/DIV 4A Max Typ Typ Max 100V AC 8 Apeak 5 Apeak 5 Apeak 0.4 A²s 120V AC 7 Apeak 4 Apeak 5 Apeak 0.5 A²s 230V AC 7Apeak 4Apeak 6Apeak 1A²s At 40 °C (104 °F), cold start At 25 °C (77 °F), cold start At 40 °C (104 °F), cold start At 40 °C (104 °F), cold start Figure 7 - Typical Turn-on Behavior at Nominal Load, 230V AC Input and 25 °C (77 °F) Ambient Input current 2A/DIV 4A 50ms/DIV Input voltage 200V/DIV Output voltage Rockwell Automation Publication 1606-RM109A-EN-P - August 2020 9 Power Supply —12V, 10 A, 120 W, Single Phase Output The output provides a SELV/PELV rated voltage, which is galvanically isolated from the input voltage. The device is designed to supply any kind of loads, including capacitive and inductive loads. If large capacitors, such as electric double layer capacitors (EDLCs) or “UltraCaps” with a capacitance > 0.3 F are connected to the output, the unit might charge the capacitor in an intermittent mode. The output is electronically helps protect against overload, no-load, and shortcircuits. If there is a protection event, audible noise occurs. Attribute Output voltage Adjustment range Value Nom 12V Min 12…15V Notes — Guaranteed value Max This is the maximum output voltage which can occur at the clockwise end position of the potentiometer due to tolerances. It is not a guaranteed value which can be achieved. Factory settings Typ Line regulation Max Load regulation Max Ripple and noise Max voltage Max Output current Fuse breaking current 16.0V 12.0V 10 mV 50 mV 50 mVpp 200 mVpp ±0.2%, at full load and cold unit Between 85… 300V AC Between 0A and 12A, static value Load >0.3A, Bandwidth 20 Hz to 20MHz, 50Ohm Load <0.3A, Bandwidth 20 Hz to 20MHz, 50Ohm (1) At 12V and an ambient temperatures below 45 °C (113 °F) 12 A 10 A At 12V and 60 °C (140 °F) ambient temperature 7.5 A At 12V and 70 °C (158 °F) ambient temperature Nom At 15V and an ambient temperatures below 45 °C (113 °F) 9.6 A(2) 8.0 A At 15V and 60 °C (140 °F) ambient temperature 6.0 A At 15V and 70 °C (158 °F) ambient temperature Derate linearly between 45 …70 °C (113…158 °F) Up to 12 ms once every five seconds, see Figure 9. The fuse braking current is an enhanced transient current which helps to trip fuses on faulty output branches. The output voltage stays above 10V. Typ 30 A Max Continuous Output voltage > 7V DC, see Figure 8. Intermittent Output voltage < 6V DC, see Figure 8. 14.2 A Continuous current, see Figure 8. Overload behavior Overload/ short- Typ circuit current 15 A Intermittent current peak value for typical 1 s Load impedance 50 mOhm, see Figure 10. Discharge current of output capacitors is not included. Max 5A Intermittent current average value (R.M.S.) Load impedance 50 mOhm, see Figure 10. Output Typ 2 700 μF Included inside the power supply Back-feeding loads Max 25V The unit is resistant and does not show malfunctioning when a load feeds back voltage to the power supply. It does not matter whether the power supply is on or off. The absorbing energy can be calculated according to the built-in large sized output capacitor. (1) This current is also available for temperatures up to +70 °C (158 °F)with a duty cycle of 10% and/ or not longer than 1 minute every 10 minutes. (2) At heavy overloads (when output voltage falls below 7V), the power supply delivers continuous output current for 1s. After this, the output is switched off for approx. 9s before a new start attempt is automatically performed. This cycle is repeated as long as the overload exists. If the overload has been cleared, the device will operate normally. See Figure 10. 10 Rockwell Automation Publication 1606-RM109A-EN-P - August 2020 Power Supply —12V, 10 A, 120 W, Single Phase Figure 8 - Output Voltage Versus Output Current, Typical Output Voltage Figure 9 - Dynamic Output Current Capability, Typical Output Voltage Adjustment Range 15V (dynamic behavior, < 12ms) 15V 12 12 A 10 Adjustment Range 10 8 8 6 6 B A: continuous current B: intermittent current 4 2 0 4 2 0 Output Current 0 2 4 6 8 10 1 2 14 16 1 8 20 A Output Current 0 5 10 15 20 25 30 35 40 45 50 A Figure 10 - Short-Circuit on Output, HiccupPLUS Mode, Typical Output Current Normal operation Normal operation Short -circuit 15A t 0 1s 9s 1s Rockwell Automation Publication 1606-RM109A-EN-P - August 2020 9s 1s 9s 11 Power Supply —12V, 10 A, 120 W, Single Phase Hold-up Time The hold-up time is the time during which a power supply’s output voltage remains within specification following the loss of input power. The hold-up time is output load dependent. At no load, the hold-up time can be up to several seconds. The green DC OK status indicator is also on during this time. Hold-up Time Typ Min Typ Min AC 100V 70 ms 55 ms 35 ms 27 ms Figure 11 - Hold-up Time Versus Input Voltage AC 120V 70 ms 55 ms 35 ms 27 ms AC 230V 70 ms 55 ms 35 ms 27 ms Notes At 12V, 5A, see Figure 11. At 12V, 5A, see Figure 11. At 12V, 10 A, see Figure 11. At 12V, 10 A, see Figure 11. Figure 12 - Shutdown Behavior, Definitions Hold-up Time 90 ms a) 12V 5 A Typ b) 12V 5 A Min Zero Transition c) 12V 10 A Typ d) 12V 10 A Min 75 Input Voltage a 60 b 45 c d 30 - 5% Output Voltage 15 Hold-up Time Input Voltage 0 90 120 155 DC OK Relay Content 190 230V AC This feature monitors the output voltage on the output terminals of a running power supply. Attribute Contact closes Value As soon as the output voltage reaches typical 90% of the adjusted output voltage As soon as the output voltage dips more than 10% below the adjusted output voltage. Contact opens Switching hysteresis Typically 0.4V Contact ratings Maximal 60V DC 0.3 A, 30V DC 1 A, 30V AC 0.5 A, resistive load Minimal permissible load: 1 mA at 5V DC Isolation voltage See Dielectric Strength on page 20. Figure 13 - DC OK Relay Contact Behavior V OUT = V ADJ 10% < 1 ms open 12 closed > 1 ms 0.9* V ADJ 100 ms open Rockwell Automation Publication 1606-RM109A-EN-P - August 2020 closed Power Supply —12V, 10 A, 120 W, Single Phase Efficiency and Power Losses Efficiency Typ AC 100V 92.6% 92.2% Average efficiency(1) Typ 91.6% 92.0% 92.3% Notes At 12V, 10 A At 12V, 12 A (Power Boost) 25% at 2.5 A, 25% at 5 A, 25% at 7.5 A. 25% at 10 A Typ 0.9 W 4.9 W 9.6 W 12.2 W 0.9 W 4.7 W 8.8 W 11.0 W 1.0 W 4.6 W 7.7 W 9.5 W At 12V, 0 A At 12V, 5 A At 12V, 10 A At 12V, 12 A (Power Boost) Power losses AC 120V 93.2% 92.9% AC 230V 94.0% 93.8% (1) The average efficiency is an assumption for a typical application where the power supply is loaded with 25% of the nominal load for 25% of the time, 50% of the nominal load for another 25% of the time, 75% of the nominal load for another 25% of the time and with 100% of the nominal load for the rest of the time. Figure 14 - Efficiency Versus Output Current at 12V Typical Figure 15 - Power Losses Versus Output Current at 12V Typical Power Losses Efficiency (a ) (b ) 12 W 94% 93 92 91 90 89 88 87 86 (c) (b ) (a) (a) 100V AC (b) 120V AC (c) 230V AC 10 (c) 8 6 (a) 100V AC (b) 120V AC (c) 230V AC 4 2 Output Current 2 4 6 8 10 12 A Figure 16 - Efficiency Versus Input Voltage at 12V, 10 A, Typical Output Current 0 0 2 4 6 8 10 12 A Figure 17 - Losses Versus Input Voltage at 12V, 10 A, Typical Efficiency Power Losses 95% 11 W 94 10 93 9 92 8 91 7 6 90 Input Voltage 89 100 120 180 Input Voltage 5 230 264V AC 100 120 Rockwell Automation Publication 1606-RM109A-EN-P - August 2020 180 230 264V AC 13 Power Supply —12V, 10 A, 120 W, Single Phase Functional Diagram L N Input Fuse Input Filter Input tÐÆĴðťÐr Inrush Current Limiter Temperature Shutdown Front Side and User Elements Output OverVoltage Protection Output Power Manager Figure 18 - Front Side Power Converter PFC Converter Output Voltage Regulator V OUT DC Ok Status Indicator DC OK Relay DC OK Contact Input Terminals 1 N, L N, L Line Input 3 PE (Protective Earth) Input 4 Output Terminals Two identical + poles and two identical - poles 5 2 14 + + - User Elements 2 1 Output Voltage Monitor Output Filter + Positive Output - Negative (return) Output 3 Output Voltage Potentiometer 4 DC OK Status Indicator (green) On, when the output voltage is >90% of the adjusted output voltage 5 DC OK Relay Contact The DC OK relay contact is synchronized with the DC OK status indicator. See DC OK Relay Content on page 12. Rockwell Automation Publication 1606-RM109A-EN-P - August 2020 Power Supply —12V, 10 A, 120 W, Single Phase Connection Terminals The terminals are IP20 Finger safe constructed and suitable for field- and factory wiring. Input Screw termination Terminal Type Solid wire, Max 6 mm2 Stranded wire, Max 4 mm2 American Wire Gauge AWG 20…10 Max wire diameter (including ferrules) 2.8mm (0.11 in.) Recommended tightening torque 1 N•m (9 lb•in) Wire stripping length 7 mm (0.28 in.) Screwdriver Output Screw termination DC OK Signal Push-in termination 6 mm2 4 mm2 AWG 20…10 2.8 mm (0.11 in.) 1 N•m (9 lb•in) 7 mm (0.28 in.) 3.5 mm (.137 in.) slotted 3.5 mm (.137 in.) slotted or cross- head No 2 or cross- head No 2 1.5 mm2 1.5 mm2 AWG 24…16 1.6 mm (0.06 in.) 7 mm (0.28 in.) 3.5 mm (.137 in.) slotted to open the spring Daisy Chaining Daisy chaining (jumping from one power supply output to the next) is allowed as long as the average output current through one terminal pin does not exceed 25 A. If the current is higher, use a separate distribution terminal block as shown in Figure 20. Figure 19 - Daisy Chaining of Outputs Power Supply + + - - Output Figure 20 - Using Distribution Terminals Distribution Terminals Power Supply + + - - Output Power Supply Load + + + - - - Output Power Supply + + - - Output Load + - Max 25 A continuous Rockwell Automation Publication 1606-RM109A-EN-P - August 2020 15 Power Supply —12V, 10 A, 120 W, Single Phase Lifetime Expectancy The Lifetime expectancy shown in the table indicates the minimum operating hours (service life) and is determined by the lifetime expectancy of the built-in electrolytic capacitors. Lifetime expectancy is specified in operational hours and is calculated according to the capacitor’s manufacturer specification. The manufacturer of the electrolytic capacitors only guarantees a maximum life of up to 15 years (131,400 hr). Any number exceeding this value is a calculated theoretical lifetime which can be used to compare devices. Lifetime Expectancy Mean Time Between Failure AC 100V 284,000 hr 804,000 hr 88,000 hr 248,000 hr 44,000 hr 126,000 hr AC 120V 297,000 hr 839,000 hr 94,000 hr 267,000 hr 51,000 hr 143,000 hr AC 230V 294,000 hr 833,000 hr 110,000 hr 311,000 hr 61,000 hr 171,000 hr Notes At 12V, 5 A and 40 °C (104 °F) At 12V, 5 A and 25 °C (77 °F) At 12V, 10 A and 40°C (104 °F) At 12V, 10 A and 25 °C (77 °F) At 12V, 12 A and 40 °C (104 °F) At 12V, 12 A and 25 °C (77 °F) Mean Time Between Failure (MTBF), is calculated according to statistical device failures, and indicates reliability of a device. It is the statistical representation of the likelihood of a unit to fail and does not necessarily represent the life of a product. An MTBF figure such as, 1,000,000 hr means that statistically one unit will fail every 100 hours if 10,000 units are installed in the field. However, it can not be determined if the failed unit has been running for 50,000 hr or only for 100 hr. For these types of units the MTTF (Mean Time To Failure) value is the same value as the MTBF value. AC 100V 682,000 hr MTBF SN 29500, IEC 61709 1,212,000 hr AC 120V 687,000 hr 1,221,000 hr AC 230V 732,000 hr 1,294,000 hr 287,000 hr 290,000 hr 308,000 hr Notes At 12V, 10 A and 40 °C (104 °F) At 12V, 10 A and 25°C (77 °F) At 12V, 10 A and 40 °C (104 °F); Ground Benign GB40 417,000 hr 421,000 hr 447,000 hr At 12V, 10 A and 25 °C (77 °F); Ground Benign GB25 68,000 hr 69,000 hr 73,000 hr At 12V, 10 A and 40 °C (104 °F); Ground Fixed GF40 91,000 hr 93,000 hr 99,000 hr At 12V, 10 A and 25 °C (77 °F); Ground Fixed GF25 MTBF MIL HDBK 217F 16 Rockwell Automation Publication 1606-RM109A-EN-P - August 2020 Power Supply —12V, 10 A, 120 W, Single Phase Electromagnetic Compatibility The electromagnetic compatibility (EMC) behavior of the device is designed for applications in industrial, residential, commercial, and light industry environments. The device is investigated according to EN 61000-6-1, EN 61000-6-2, EN 61000-6-3 and EN 61000-6-4. EMC Immunity Electrostatic discharge EN 61000-4-2 Criterion A(1) Criterion A Criterion A Contact discharge Air discharge 8 kV 15 kV Electromagnetic RF EN 61000-4-3 80 MHz…2.7 GHz Fast transients (Burst) EN 61000-4-4 Input lines Output lines DC OK signal (coupling clamp) 20V/m 4 kV 2 kV 2 kV Surge voltage on input EN 61000-4-5 L N L PE, N PE 4 kV 2 kV Criterion A Criterion A Surge voltage on output EN 61000-4-5 + + / - PE 1 kV 2 kV Criterion A Criterion A Surge voltage on Conducted EN 61000-4-5 EN 61000-4-6 DC OK signal PE 0.15…80 MHz 1 kV 20V Criterion A Criterion A Mains voltage dips EN 61000-4-11 0% of 100V AC 40% of 100V AC 70% of 100V AC 0% of 200V AC 40% of 200V AC 40% of 200V AC 70% of 200V AC 0V AC, 20 ms 40V AC, 200 ms 70V AC, 500 ms 0V AC, 20 ms 80V AC, 200 ms <8 A 80V AC, 200 ms >8 A 140V AC, 500 ms Criterion A Criterion C Criterion A Criterion A Criterion A Criterion C Criterion A Voltage EN 61000-4-11 Powerful transients VDE 0160 0% of 200V AC (=0V) Over entire load range 5000 ms 750V, 0.3 ms Criterion C Criterion A Criterion A Criterion A Criterion A (1) Performance Criteria: A: The device shows normal operation behavior within the defined limits. C: Temporary loss of function is possible. The device may shut-down and restarts by itself. No damage or hazards for the device will occur. EMC Emission 55011, EN 55022, FCC Part 15, Conducted emission input lines EN CISPR 11, CISPR 22 Class B Conducted emission output lines IEC/CISPR 16-1-2, IEC/CISPR 16-2-1 Limits for local DC power networks fulfilled Radiated emission Harmonic input current (PFC) EN 55011, EN 55022 EN 61000-3-2 Class B Fulfilled for Class A equipment Voltage fluctuations, flicker EN 61000-3-3 Fulfilled, tested with constant current loads, non pulsing This device complies with FCC Part 15 rules. Operation is subjected to following two conditions: (1) this device may not cause harmful interference, and (2) this device must accept any interference received, including interference that may cause undesired operation. Switching Frequencies PFC converter 30 kHz…140 kHz Main converter 60 kHz…140 kHz Auxiliary converter 30 kHz…60 kHz Input voltage and output power dependent Output load dependent Output load dependent Rockwell Automation Publication 1606-RM109A-EN-P - August 2020 17 Power Supply —12V, 10 A, 120 W, Single Phase Environment Attribute Value Notes Operational temperature -25 …+70°C (-13…+158°F) Operational temperature is the same as the ambient or surrounding temperature and is defined as the air temperature 2 cm (0.98 in.) below the unit. Storage temperature -40…+85°C (-40…+185°F) For storage and transportation Output de-rating 1.6 W/°C 3 W/°C 0.67 A/1000 m or 5 °C/1000 m Between +45…60 °C (113…140°F) Between +60 …70°C (140…158°F) For altitudes >2000 m (6560 ft), see Figure 22. The de-rating is not hardware controlled. The user has to take care by himself to stay below the de-rated current limits in order not to overload the unit. Humidity Atmospheric pressure Altitude 5…95% r.h. 110…54 kPa Up to 5000 m (16,400 ft) According to IEC 60068-2-30 See Figure 22 for details See Figure 22 for details III According to IEC 60664-1 for altitudes up to 2000 m (6560 ft) II According to IEC 60664-1, for altitudes above 2000 m (6560 ft) 2 2…17.8 Hz: ±1.6 mm; 17.8…500 Hz: 2 g According to IEC 62477-1, not conductive Over-voltage category Degree of pollution Vibration sinusoidal According to IEC 60068-2-6 30 g 6 ms, 20 g 11 ms 3 bumps/direction, 18 bumps in total Shock According to IEC 60068-2-27 Shock and vibration is tested in combination with DIN rails according to EN 60715 with a height of 15mm and a thickness of 1.3mm and standard orientation. LABS compatibility As a rule, only non-silicon precipitating materials are used. The unit conforms to the LABS criteria and is suitable for use in paint shops. Corrosive gases Tested according to ISA-71.04-1985, Severity Level G3 and IEC 60068-2-60 Test Ke Method 4 for a service life of minimum 10years in these environments. Audible noise Some audible noise may be emitted from the power supply during no load, overload or short circuit. Figure 21 - Output Current Versus Ambient Temperature Figure 22 - Output Current Versus Altitude Allowed Output Current at 12V Allowed Output Current at 12V 12 A B 12 A 10 A 10 A A 7.5 A A ... T a m b < 6 0 °C B ... T a m b < 4 5 °C C ... Sh o rt t e rm 0 -25 0 A 8A A... 85 to 264V AC, continuous B... short term 45 60 70 °C Ambient Temperature 18 C B Rockwell Automation Publication 1606-RM109A-EN-P - August 2020 0m Altitude AP *) 110 kPa *) Atmospheric pressure 2000 m 80 kPa 5000 m 54 kPa Power Supply —12V, 10 A, 120 W, Single Phase Safety and Protection Features Attribute Value Notes Min 500 MΩ At delivered condition between input and output, measured with 500V DC Min 500 MΩ At delivered condition between input and PE measured with 500V DC Min 500 MΩ At delivered condition between output and PE, measured with 500V DC Min 500 MΩ At delivered condition between output and DC OK contacts, measured with 500V DC. PE resistance Max 0.1 Ω Resistance between PE terminal and the housing in the area of the DIN rail mounting bracket. Output over-voltage protection Typ Max 16.2V DC 17V DC — — Isolation resistance In case of an internal defect, a redundant circuit limits the maximum output voltage. The output shuts down and performs three restart attempts. If the failure continues, the output shuts down. Cycle input power to reset. Class of protection I According to IEC 61140 A PE (Protective Earth) connection is required Degree of protection IP 20 According to EN/IEC 60529 Over-temperature protection Included Output shut-down with automatic restart. Temperature sensors are installed on critical components inside the unit and turn the unit off in safety critical situations, which can happen for example, when ambient temperature is too high, ventilation is obstructed or the de-rating requirements are not followed. There is no correlation between the operating temperature and turnoff temperature since this is dependent on input voltage, load and installation methods. Input transient protection Metal Oxide Varistor (MOV) For protection values, see Electromagnetic Compatibility on page 17. Internal input fuse Included Not user replaceable slow-blow high-braking capacity fuse 0.10 mA/0.27 mA 0.13 mA/0.38 mA 0.20 mA/0.60 mA 0.13 mA/0.35 mA 0.17 mA/0.51 mA 0.27 mA/0.81 mA At 100V AC, 50 Hz, TN-,TT-mains/IT-mains At 120V AC, 60 Hz, TN-,TT-mains/IT-mains At 230V AC, 50 Hz, TN-,TT-mains/IT-mains At 110V AC, 50 Hz, TN-,TT-mains/IT-mains At 132V AC, 60 Hz, TN-,TT-mains/IT-mains At 264V AC, 50 Hz, TN-,TT-mains/IT-mains Typ Touch current (leakage current) Max Rockwell Automation Publication 1606-RM109A-EN-P - August 2020 19 Power Supply —12V, 10 A, 120 W, Single Phase Dielectric Strength The output voltage is floating and has no ohmic connection to the ground. The output is insulated to the input by a double or reinforced insulation. Type and routine tests are conducted by the manufacturer. Field tests may be conducted in the field using the appropriate test equipment which applies the voltage with a slow ramp (2 s up and 2 s down). Connect all input- terminals together and all output poles before conducting the test. When testing, set the cut-off current settings to the value in the table below. IMPORTANT Connect either the + pole or the – pole to the protective earth system. This helps to avoid situations in which a load starts unexpectedly or can not be switched off when unnoticed earth faults occur. Figure 23 - Dialectic Strength Input DC OK 1 B L N D B A Output Earth, PE C + - Type test 60 s A 2500V AC Routine test 5s 2500V AC 2500V AC 500V AC 500V AC Field test 5s 2000V AC 2000V AC 500V AC 500V AC > 10 mA > 10 mA > 20 mA > 1 mA Field tests cut-off current settings B 3000V AC C 1000V AC D 500V AC (1) B: When testing input to DC OK ensure that the maximal voltage between DC OK and the output is not exceeded (column D). We recommend connecting DC OK pins and the output pins together when performing the test. 20 Rockwell Automation Publication 1606-RM109A-EN-P - August 2020 Power Supply —12V, 10 A, 120 W, Single Phase Certifications and Standards Compliance IEC 61010 CB Scheme Certificate IEC 61010-2-201 Electrical Equipment for Measurement, Control and Laboratory Use - Particular requirements for control equipment IEC 62368 CB Scheme Certificate IEC 62368-1 Audio/video, information and communication technology equipment - Safety requirements Output safety level: ES1 UL 61010-2-201 (former UL 508) UL Certificate Listed equipment for category NMTR - UL 61010-2-201 Electrical Equipment for Measurement, Control and Laboratory Use Particular requirements for control equipment Applicable for US and Canada E-File: E56639 Ind. Cont. Eq. CE EU Declaration of Conformity Trade conformity assessment for Europe The CE mark indicates conformance with the European - RoHS directive, - EMC directive and the - Low-voltage directive (LVD) Reach Directive Manufacturer's Statement EU-Regulation regarding the Registration, Evaluation, Authorization and Restriction of Chemicals WEEE Directive Manufacturer's Statement EU-Directive on Waste Electrical and Electronic Equipment RoHS (China RoHS 2) Manufacturer's Statement Administrative Measures for the Restriction of the Use of Hazardous Substances in Electrical and Electronic Products 25 years EAC EAC Certificate EAC EurAsian Conformity - Registration Russia, Kazakhstan and Belarus Rockwell Automation Publication 1606-RM109A-EN-P - August 2020 21 Power Supply —12V, 10 A, 120 W, Single Phase Approximate Dimensions Attribute Width Height Value 32 mm (1.26 in.) 124 mm (4.88 in.) Depth 102 mm (4.02 in.) The DIN rail height must be added to the unit depth to calculate the total required installation depth. Weight DIN rail 440 g (0.97 lb) Use 35 mm DIN rails according to EN 60715 or EN 50022 with a height of 7.5 mm (.30 in.) or 15 mm (.60 in.) Housing material Body: Aluminum alloy Cover: Zinc-plated steel Installation clearances Keep the following installation clearances: 40 mm (1.57 in.) on top, 20 mm (0.79 in.) on the bottom, 5 mm (.20 in.) on the left and right sides are recommended when the device is loaded permanently with more than 50% of the rated power. Increase this clearance to 15 mm (.60 in.) in case the adjacent device is a heat source (Example: another power supply). Penetration protection Small parts like screws with a diameter larger than 5 mm (.20 in.) Figure 24 - Front view Figure 25 - Side view All dimensions in mm 22 Rockwell Automation Publication 1606-RM109A-EN-P - August 2020 Power Supply —12V, 10 A, 120 W, Single Phase Accessories Wall and Panel Mount Bracket This bracket is used to mount the devices on a wall/panel without utilizing a DIN rail. The bracket can be mounted without detaching the DIN rail brackets. All dimensions in the following figures are in millimeters. Figure 26 - Isometric Views Figure 27 - Wall/panel Mounting, Front View Figure 28 - Hole Pattern for Wall Mounting Rockwell Automation Publication 1606-RM109A-EN-P - August 2020 Figure 29 - Wall/panel Mounting, Side View 23 Power Supply —12V, 10 A, 120 W, Single Phase Redundancy Module The 1606-XLERED20 is a dual redundancy module, which can be used to build 1+1 or N+1 redundant systems. The device is equipped with two input channels, each rated for 20A for ambient temperatures up to +70 °C (158 °F) and are individually decoupled by utilizing MOSFET technology. The inputs can also be operated up to 24A when the ambient temperature does not exceed 45 °C (113 °F). The output can be loaded with nominal 20A at +70 °C (158 °F) or 24A at 45 °C (113 °F) continuous current. Using MOSFETSs instead of diodes reduces heat generation, losses and voltage drop between input and output. Due to these advantages, the unit is very narrow and only requires 32 mm width on the DIN rail. The device does not require an additional auxiliary voltage and is self-powered even in case of a short circuit across the output. 24 Rockwell Automation Publication 1606-RM109A-EN-P - August 2020 Power Supply —12V, 10 A, 120 W, Single Phase Application Notes Peak Current Capability The unit can deliver peak currents (up to several milliseconds) which are higher than the specified short term currents. This helps to start current demanding loads. Solenoids, contactors and pneumatic modules often have a steady state coil and a pick-up coil. The inrush current demand of the pick-up coil is several times higher than the steadystate current and usually exceeds the nominal output current. The same situation applies when starting a capacitive load. The peak current capability also ensures the safe operation of subsequent circuit breakers of load circuits. The load branches are often individually protected with circuit breakers or fuses. In case of a short or an overload in one branch circuit, the fuse or circuit breaker need a certain amount of overcurrent to open in a timely manner. This avoids voltage loss in adjacent circuits. The extra current (peak current) is supplied by the power converter and the built-in large sized output capacitors of the power supply. The capacitors get discharged during such an event, which causes a voltage dip on the output. The following two examples show typical voltage dips for resistive loads: Figure 30 - 20 A Peak Current for 50 ms , Typical (2x the Nominal Current) Figure 32 - 50 A Peak Current for 5 ms , Typical (5x the Nominal Current) Figure 31 - 30 A Peak Current for 12 ms , Typical (3x the Nominal Current) Peak current voltage dips Typically from 12-5.9V Typically from 12-6V Typically from 12-5.6V At 20 A for 50 ms, resistive load At 50 A for 2 ms, resistive load At 50 A for 5 ms, resistive load Rockwell Automation Publication 1606-RM109A-EN-P - August 2020 25 Power Supply —12V, 10 A, 120 W, Single Phase Charging of Batteries The power supply can be used to charge lead-acid or maintenance free VRLA batteries. Instructions for charging batteries: • • • • • Ensure that the ambient temperature of the power supply is below 40 °C (104 °F). Use a 15 A or 16 A circuit breaker or a blocking diode between the power supply and the battery. Ensure that the output current of the power supply is below the allowed charging current of the battery. The return current to the power supply is typically 8mA. This return current can discharge the battery when the power supply is switched off except in case a blocking diode is utilized. Set the output voltage, measured at no load and at the battery end of the cable, very precisely to the end-of- charge voltage. Set the output voltage, measured at no load and at the battery end of the cable, very precisely to the end-of-charge voltage. The voltage should be set to: - 13.9V at 10°C(50 °F) ambient temperature - 13.75V at 20°C (68 °F)ambient temperature - 13.6V at 30°C (86 °F) ambient temperature - 13.4V at 40 °C (104 °F) ambient temperature Series Operation Devices of the same type can be connected in series for higher output voltages. It is possible to connect as many units in series as needed, providing the sum of the output voltage does not exceed 150V DC. Voltages with a potential above 60V DC must be installed with a protection against touching. Avoid return voltage (for example, from a decelerating motor or battery) which is applied to the output terminals. Keep an installation clearance of 15 mm (.60 in.) (left / right) between two power supplies and avoid installing the power supplies on top of each other. Do not use power supplies in series in mounting orientations other than the standard mounting orientation. Pay attention that leakage current, EMI, inrush current, harmonics will increase when using multiple devices. 26 Rockwell Automation Publication 1606-RM109A-EN-P - August 2020 Power Supply —12V, 10 A, 120 W, Single Phase Parallel Use to Increase Output Power Devices can be paralleled to increase the output power. The output voltage shall be adjusted to the same value (±100 mV) with the same load conditions on all devices, or the devices can be left with the factory settings. The ambient temperature is not allowed to exceed 40 °C (104 °F) If more than three devices are connected in parallel, a fuse or circuit breaker with a rating of 15 A or 16 A is required on each output. Alternatively, a diode or redundancy module can also be utilized. Energize all devices at the same time. It also might be necessary to cycle the input power (turn-off for at least five seconds), if the output was in overload or short circuits and the required output current is higher than the current of one unit. Keep an installation clearance of 15 mm (left/right) between two devices and avoid installing devices on top of each other. Do not use devices in parallel in mounting orientations other than the standard mounting orientation or in any other condition where a reduction of the output current is required ( for example, altitude). Leakage current, EMI, inrush current will increase when using multiple devices. Parallel Use for Redundancy 1+1 Redundancy Devices can be paralleled for redundancy to gain higher system availability. Redundant systems require a certain amount of extra power to support the load in case one device fails. The simplest way is to put two devices in parallel. This is called a 1+1 redundancy. In case one device fails, the other one is automatically able to support the load current without any interruption. It is essential to use a redundancy module to decouple devices from each other. This prevents an event in which that the defective unit becomes a load for the other device and the output voltage cannot be maintained. 1+1 redundancy allows ambient temperatures up to 70°C (158 °F). Pay attention that leakage current, EMI, inrush current, and harmonics will increase when using multiple devices. Recommendations for building redundant power systems: • • • • Use separate input fuses for each device. Use separate mains systems for each device whenever it is possible. Monitor the individual devices. Therefore, use the DC OK signal of the device. It is desirable to set the output voltages of all devices to the same value (± 100 mV) or leave it at the factory setting. Rockwell Automation Publication 1606-RM109A-EN-P - August 2020 27 Power Supply —12V, 10 A, 120 W, Single Phase N+1 Redundancy Redundant systems for a higher power demand are usually built in a N+1 method. For example, four devices, each rated for 10 A are paralleled to build a 30 A redundant system. Leakage current, EMI, inrush current, harmonics will increase when using multiple devices. Keep an installation clearance of 15mm (left / right) between two devices and avoid installing the devices on top of each other. Do not use devices in parallel in mounting orientations other than the standard mounting orientation or in any other condition, where a reduction of the output current is required. For N+1 redundancy the ambient temperature is not allowed to exceed 40 °C (104 °F). Wiring Examples Figure 33 - 1+1 Redundant Configuration for 10 A Load Current with a Dual Redundancy Module Figure 34 - N+1 Redundant Configuration for 30 A Load Current with Multiple Power Supplies and Redundancy Modules Failure Monitor Failure Monitor + + ȿ Output 12V, 10 A DC OK Power Supply + - + - Input 1 Input 2 + + o o DC OK Redundancy Module + + ȿ Output 12V, 10 A ȿ Output 12V, 10 A DC OK o o Power Supply Power Supply + - + - Input 1 Input 2 DC OK Redundancy Module L N PE optional - + o o DC OK Power Supply Input Input L N PE L N PE + - + - Input 1 Input 2 + + I I ȿ Output 12V, 10 A o o DC OK Redundancy Module o o Power Supply Output Input - + L N PE 30 A Load I L L N N PE PE 28 ȿ Output 12V, 10 A L N PE 10 A Load I + + Power Supply Output L N PE Input + optional Output ȿ Output 12V, 10 A o o Input Input + + Rockwell Automation Publication 1606-RM109A-EN-P - August 2020 I I Power Supply —12V, 10 A, 120 W, Single Phase Operation in Two Phases The power supply can also be used on two-phases of a threephase- system. Such a phaseto-phase connection is allowed as long as the supplying voltage is below 240V+10%. Ensure that the wire, which is connected to the N-terminal, is appropriately fused. The maximum allowed voltage between a Phase and the PE must be below 300V AC. Use in a Tightly Sealed Enclosure When the device is installed in a tightly sealed enclosure, the temperature inside the enclosure will be higher than outside. In such situations, the inside temperature defines the ambient temperature for the device. In the following test setup, the device is placed in the middle of the box, no other heat producing items are inside the box. The load is placed outside the box. The temperature sensor inside the box is placed in the middle of the right side of the power supply with a distance of 1 cm. The following measurement results can be used as a reference to estimate the temperature rise inside the enclosure. Attribute Value Case A Case B Enclosure size 110 x 180 x 165 mm Rittal Typ IP66 Box PK 9516 100, plastic 110 x 180 x 165 mm Rittal Typ IP66 Box PK 9516 100, plastic Input voltage Load Temperature inside the box Temperature outside the box Temperature rise 230V AC 12V, 8 A; (=80%) 40.7 °C (105.3 °F) 27.9°C (82.2 °F) 12.8 K 230V AC 12V, 10 A; (=100%) 43.2°C (109.8 °F) 28.0°C (82.4 °F) 15.2 K Rockwell Automation Publication 1606-RM109A-EN-P - August 2020 29 Power Supply —12V, 10 A, 120 W, Single Phase Mounting Orientations Mounting orientations other than input terminals on the bottom and output on the top require a reduction in continuous output power or a limitation in the maximum allowed ambient temperature. The listed lifetime and MTBF values from this datasheet apply only for the standard mounting orientation. The following curves give an indication for allowed output currents for altitudes up to 2000 m (6560 ft). Allowed Output Current at 12V Figure 35 - Mounting Orientation A (Standard orientation) OUTPUT 12 A 10 A Power Supply 7.5 A 0 INPUT +45 +60 +70 °C Ambient Temperature Allowed Output Current at 12V INPUT Figure 36 - Mounting Orientation B (Upside down) 12 A 7.5 A Power Supply 0 OUTPUT +30 +60 +70 °C Ambient Temperature Allowed Output Current at 12V 12 A Figure 37 - Mounting Orientation C (Table-top mounting)) 6.5 A 0 +25 +60 +70 °C Ambient Temperature Allowed Output Current at 12V 12 A OUTPUT Power Supply INPUT Figure 38 - Mounting Orientation D (Horizontal CW - Input on the Left) 6.5 A 0 +25 +60 +70 °C Ambient Temperature Allowed Output Current at 12V INPUT Power Supply Figure 39 - Mounting Orientation E (Horizontal CCW - Input on the Right) OUTPUT 12 A 6.5 A 0 +25 +60 Ambient Temperature 30 Rockwell Automation Publication 1606-RM109A-EN-P - August 2020 +70 °C 12V, 10 A, 120 W, Single-phase Power Supply Reference Manual Additional Resources These documents contain additional information concerning related products from Rockwell Automation. Resource Power Supply Technical Data, publication 1606-TD002. Industrial Components Preventive Maintenance, Enclosures, and Contact Ratings Specifications, publication IC-TD002 Description Provides product selection, specifications, and dimensions information. Provides a quick reference tool for Allen-Bradley industrial automation controls and assemblies. Designed to harmonize with NEMA Standards Publication No. ICS 1.1-1987 and provides general guidelines for the application, installation, and maintenance of solid-state control in Safety Guidelines for the Application, Installation, and Maintenance of the form of individual devices or packaged assemblies incorporating solid-state Solid-state Control, publication SGI-1.1 components. Industrial Automation Wiring and Grounding Guidelines, publication 1770-4.1 Provides general guidelines for installing a Rockwell Automation industrial system. Provides declarations of conformity, certificates, and other certification details. Product Certifications website, rok.auto/certifications. You can view or download publications at rok.auto/literature. Rockwell Automation Publication 1606-RM109A-EN-P - August 2020 31 Rockwell Automation Support Use these resources to access support information. Technical Support Center Knowledgebase Local Technical Support Phone Numbers Literature Library Product Compatibility and Download Center (PCDC) Find help with how-to videos, FAQs, chat, user forums, and product notification updates. Access Knowledgebase articles. Locate the telephone number for your country. Find installation instructions, manuals, brochures, and technical data publications. Download firmware, associated files (such as AOP, EDS, and DTM), and access product release notes. rok.auto/support rok.auto/knowledgebase rok.auto/phonesupport rok.auto/literature rok.auto/pcdc Documentation Feedback Your comments help us serve your documentation needs better. If you have any suggestions on how to improve our content, complete the form at rok.auto/docfeedback. Waste Electrical and Electronic Equipment (WEEE) At the end of life, this equipment should be collected separately from any unsorted municipal waste. Rockwell Automation maintains current product environmental information on its website at rok.auto/pec. Allen-Bradley, expanding human possibility, FactoryTalk, and Rockwell Automation are trademarks of Rockwell Automation, Inc. EtherNet/IP is a trademark of ODVA, Inc. Trademarks not belonging to Rockwell Automation are property of their respective companies. Rockwell Otomasyon Ticaret A.Ş. Kar Plaza İş Merkezi E Blok Kat:6 34752, İçerenkÖy, İstanbul, Tel: +90 (216) 5698400 EEE YÖnetmeliğine Uygundur Publication 1606-RM109A-EN-P - August 2020 Copyright © 2020 Rockwell Automation, Inc. All rights reserved. Printed in the U.S.A. ">
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Key features
- 12V, 10A, 120W Output
- High Efficiency
- Active PFC
- Wide Input Voltage
- Compact Design
- Overload Protection
- Short-Circuit Protection
- Temperature Protection
- DC OK Relay
Frequently asked questions
The output voltage is 12V DC with a nominal output current of 10A. The maximum output current varies with ambient temperature and can reach up to 12A at temperatures below 45°C (113°F).
The input voltage range is 100…240V AC with a frequency of 50…60 Hz.
This power supply features overload protection, short-circuit protection, and temperature protection. These features ensure the safety of the device and connected equipment.
The hold-up time is the time the output voltage remains within specification after losing input power. It is load dependent and can be up to 70 ms at 12V, 5A.
The efficiency of this power supply can reach up to 94% at 12V, 10A and 230V AC input.