1000 Series www.murata-ps.com Pulse Transformers 1 SELECTION GUIDE Turns Order Ratio Code 2% mH Vs H pF Vrms 1001C 1:1 3.0 200 32 23 1.2 1.0 - 2000 A 2 1002C 1:1:1 3.0 200 30 51 1.4 1.3 1.7 2000 B 1 FEATURES 1003C 2:1:1 12 400 62 58 5.0 2.0 3.0 2000 B 1 RoHS compliant 1007C 1:1:1 7.4 310 20 55 2.9 2.5 3.4 2000 B 1 UL 94V-0 Package Material 1009C 1:1:1 22 550 85 71 13.4 11 15.8 2000 B 1 Isolation to 4kVrms 1013C 1:1:1 3.0 200 3 585 2.0 2.0 2.0 500VDC B1 Compact Footprint 1016C 1:1 3.0 200 22 23 1.2 1.0 - 3500 A 2 PCB Mounting 1017C 1:1 0.8 130 4 20 0.4 0.3 - 4000 A 2 Backward compatible with 1024C 1.2CT:1CT 8.8 340 60 25 2.5 2.5 - 2000 C 1 Sn/Pb soldering systems 1025C 2:1:1 24 570 90 83 8.7 3.5 5.2 2000 B 1 DESCRIPTION 1026C 1:1:1 6.0 285 30 62 4.0 4.0 4.9 2000 B 1 The 1000 series are intended for wideband and 1082C 100:1 6.1 280 - 6 1.1 0.1 - 2000 A 2 pulse operations. They are also suitable for signal isolation and use in small isolated power supplies. ABSOLUTE MAXIMUM RATINGS The compact footprint makes them ideal for applications where space is at a premium. Operating free air temperature range 0C to 70C Storage temperature range -60C to 125C 1 SOLDERING INFORMATION Peak wave solder temperature 300C for 10 seconds Matte tin Pin nish 1 For further information, please visit www.murata-ps.com/rohs All specications typical at T =25C. A TUBE DIMENSIONS 0.600.15 (0.0240.006) 17.00 8.00 (0.315) (0.669) 7.00 (0.276) All dimensions in mm (inches). Tube length: 4802mm (18.90.08) 24.00 (0.945) Tube quantity: 30 For full details go to www.murata-ps.com/rohs www.murata-ps.com/support KMP 1000C C01 Page 1 of 2 Min. Primary Inductance Min. Primary Constant, ET Max. Leakage Inductance Max. Interwinding Capacitance Max. DC Resistance Primary Winding Max. DC Resistance Secondary 1 winding Max. DC Resistance Secondary 2 winding Isolation Voltage Pin Connection Style Mechanical Dimensions1000 Series Pulse Transformers PIN CONNECTIONS (TOP VIEW) MECHANICAL DIMENSIONS 15.06 (0.593) 15.06 (0.593) 12 2 1 Pri A 15.06 15.06 (0.593) (0.593) Sec 1003C 1001C 6 5 YYWW YYWW 2 1 Pri 15.750.50 15.750.50 (0.6200.02) (0.6200.02) 4 3 B 20.5 20.5 (0.807) (0.807) S2 S1 6 5 0.710.05 0.710.05 (0.0280.002) (0.0280.002) 2 1 Sec Pri 5.08 (0.20) 4 3 C 10.16 (0.40) 5.08 (0.20) 6 5 10.16 (0.40) 10.16 (0.40) All dimensions in mm (inches). Package weight: 8.0g Typ. TECHNICAL NOTES ISOLATION VOLTAGE REPEATED HIGH-VOLTAGE ISOLATION TESTING Hi Pot Test, Flash Tested, Withstand Voltage, Proof Voltage, Dielectric Withstand Voltage & Isola- It is well known that repeated high-voltage isolation testing of a barrier tion Test Voltage are all terms that relate to the same thing, a test voltage, applied for a specied time, component can actually degrade isolation capability, to a lesser or great- across a component designed to provide electrical isolation, to verify the integrity of that isolation. er degree depending on materials, construction and environment. While parts can be expected to withstand several times the stated test voltage, All products in this series are 100% production tested at their stated isolation voltage. the isolation capability does depend on the insulative materials used. A question commonly asked is, What is the continuous voltage that can be applied across the part in Such materials are susceptible to chemical degradation when subject normal operation to very high applied voltages. We therefore strongly advise against For a part holding no specic agency approvals both input and output should normally be maintained repeated high voltage isolation testing, but if it is absolutely required, within SELV limits i.e. less than 42.4V peak, or 60VDC. The isolation test voltage represents a measure that the voltage be reduced by 20% from specied test voltage. of immunity to transient voltages and the part should never be used as an element of a safety isolation This consideration equally applies to agency recognized parts rated for system. The part could be expected to function correctly with several hundred volts offset applied better than functional isolation where wire enamel insulation is always continuously across the isolation barrier but then the circuitry on both sides of the barrier must be supplemented by a further insulation system of physical spacing or regarded as operating at an unsafe voltage and further isolation/insulation systems must form a barrier barriers. between these circuits and any user-accessible circuitry according to safety standard requirements. This product is subject to the following operating requirements and the Life and Safety Critical Application Sales Policy: Refer to: