GE Industrial Solutions LC-LW015-Series User Manual
Options, Features, Applications
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Table of contents
Document Outline
- Options
- Features
- Applications
- Description
- Absolute Maximum Ratings
- Electrical Specifications
- Characteristic Curves
- Figure 1. LC010 Input Current vs. Input Voltage at IO = IO, max and TC = 25 °C
- Figure 2. LC015 Input Current vs. Input Voltage at IO = IO, max and TC = 25 °C
- Figure 3. LW010 Input Current vs. Input Voltage at IO = IO, max and TC = 25 °C
- Figure 4. LW015 Input Current vs. Input Voltage at IO = IO, max and TC = 25 °C
- Figure 5. Lx010x/Lx015x Single-Output Load Regulation, Normalized Output Voltage vs. Normalized Output Current at TC = 25 °C
- Figure 6. Lx010AJ Typical Load Regulation of Output1 with Fixed IO2 = 0.5 A at TC = 25 °C
- Figure 7. Lx010AJ Typical Cross Regulation, VO1 vs. IO2 with Fixed IO1 = 0.1 A at TC = 25 °C
- Figure 8. Lx010AJ Typical Cross Regulation, VO1 vs. IO2 with Fixed IO1 = 1.0 A at TC = 25 °C
- Figure 9. Lx010BK, CL Load Regulation of Output1 with Fixed IO2 = 0.5 * IO, max at TC = 25 °C, Normalized VO1 vs. Normalized Current IO1
- Figure 10. Lx010BK, CL Typical Cross Regulation, Normalized VO1 vs. Normalized IO2 with Fixed IO1 = IO, min at TC = 25 °C
- Figure 11. Lx010BK, CL Typical Cross Regulation, Normalized VO1 vs. Normalized IO2 with Fixed IO1 = IO, max at TC = 25 °C
- Figure 12. Lx010x/Lx015x Single-Output Normalized Output Current vs. Normalized Output Voltage at TC = 25 °C
- Figure 13. Lx010xx Dual-Output Normalized Output Current vs. Normalized Output Voltage at TC = 25 °C with Other Output at IO, min
- Figure 14. Lx010xx Dual-Output Normalized Output Current vs. Normalized Output Voltage at TC = 25 °C with Other Output at IO = IO, max
- Figure 15. LC015A Typical Efficiency vs. Output Current at TC = 25 °C
- Figure 16. LC015B, C Typical Efficiency vs. Normalized Output Current at TC = 25 °C
- Figure 17. LC010D and LC015D Typical Efficiency vs. Output Current at TC = 25 °C
- Figure 18. LC015F Typical Efficiency vs. Output Current at TC = 25 °C
- Figure 19. LC010A, B, C Typical Efficiency vs. Normalized Output Current at TC = 25 °C
- Figure 20. LC010F Typical Efficiency vs. Output Current at TC = 25 °C
- Figure 21. LC010AJ, BK, CL Typical Efficiency vs. Normalized Output Current at TC = 25 °C
- Figure 22. LW015A Typical Efficiency vs. Output Current at TC = 25 °C
- Figure 23. LW015B, C Typical Efficiency vs. Normalized Output Current at TC = 25 °C
- Figure 24. LW010D, 015D Typical Efficiency vs. Output Current at TC = 25 °C
- Figure 25. LW015F Typical Efficiency vs. Output Current at TC = 25 °C
- Figure 26. LW010A, B, C Typical Efficiency vs. Normalized Output Current at TC = 25 °C
- Figure 27. LW010F Typical Efficiency vs. Output Current at TC = 25 °C
- Figure 28. LW010AJ, BK, CL Typical Efficiency vs. Normalized Output Current at TC = 25 °C
- Figure 29. Single-Output Typical Output Voltage for Step Load Change from 50% to 75% of IO = IO, max
- Figure 30. Single-Output Typical Output Voltage for Step Load Change from 50% to 25% of IO = IO, max
- Figure 31. Typical Output Voltage Start-Up when Input Voltage Is Applied; IO = 80% of IO, max, VI = Nominal Line
- Figure 32. Typical Output Voltage Start-Up when Signal Is applied to Remote On/Off; IO = 80% of IO, max
- Test Configurations
- Figure 33. Input Reflected-Ripple Test Setup
- Figure 34. Peak-to-Peak Output Noise Measurement Test Setup for Single Outputs
- Figure 35. Output Voltage and Efficiency Measurement Test Setup for Single Outputs
- Figure 36. Peak-to-Peak Output Noise Measurement Test Setup for Dual Outputs
- Figure 37. Output Voltage and Efficiency Measurement Test Setup for Dual Outputs
- Design Considerations
- Safety Considerations
- Feature Descriptions
- Thermal Considerations
- Figure 41. LW010 and LC010 Case Temperature Measurement Location
- Figure 42. LW015 and LC015 Case Temperature Measurement Location
- Heat Transfer Characteristics
- Figure 43. LW010/LC010 Forced Convection Power Derating; Either Orientation
- Figure 44. LC015 Forced Convection Power Derating; Either Orientation
- Figure 45. LW015 Forced Convection Power Derating; Either Orientation
- Figure 46. LC015A Power Dissipation at Maximum Case Temperature
- Figure 47. LC015B, C Typical Power Dissipation vs. Normalized Output Current at TC = 25 °C
- Figure 48. LC010D, 015D Typical Power Dissipation vs. Output Current at TC = 25 °C
- Figure 49. LC015F Typical Power Dissipation vs. Output Current at Maximum Case Temperature
- Figure 50. LC010A, B, C Typical Power Dissipation vs. Normalized Output Current at TC = 25 °C
- Figure 51. LC010F Typical Power Dissipation vs. Output Current at TC = 25 °C
- Figure 52. LC010AJ, BK, CL Typical Power Dissipation vs. Normalized Output Current at TC = 25 °C
- Figure 53. LW015A Power Dissipation at Maximum Case Temperature
- Figure 54. LW015B, C Typical Power Dissipation vs. Normalized Output Current at TC = 25 °C
- Figure 55. LW010D, LW015D Typical Power Dissipation vs. Output Current at TC = 25 °C
- Figure 56. LW010D9 Typical Power Dissipation vs. Output Current at TC = 25 °C with Output Voltage Trimmed Up to 2.5 V
- Figure 57. LW015F Power Dissipation at Maximum Case Temperature
- Figure 58. LW010A, B, C Typical Power Dissipation vs. Normalized Output Current at TC = 25 °C
- Figure 59. LW010F Typical Power Dissipation vs. Output Current at TC = 25 °C
- Figure 60. LW010AJ, BK, CL Typical Power Dissipation vs. Normalized Output Current at TC = 25 °C
- Module Derating
- Layout Considerations
- Outline Diagram
- Recommended Hole Pattern
- Ordering Information