IMX35 Series Data Sheet 35 Watt Quad-Output DC-DC Converters ® Features • RoHS lead-free-solder and lead-solder-exempted products are available. • Extremely wide input voltage ranges up to 150 VDC • 4 outputs up to 60 V • 1200 to 1800 VAC i/o electric strength test • Electrical isolation between outputs • Programmable input undervoltage lockout 63.5 2.5" • Shutdown/inhibit input 10.5 0.41" • Adjustable output voltages with flexible load distribution 76.2 3" • Frequency synchronization • Outputs no-load, overload, and short-circuit proof • Operating ambient temperature from – 40 to 85 °C • Thermal protection • Low profile: 10.5 mm or 8.9 mm with open frame • Basic insulation • Flexible output possibilities between 5 V and 60 V 47.8 1.88" Safety-approved to IEC/EN 60950 -1 and UL/CSA 60950 -1 2 nd Ed. 8.9 0.35" 72.8 2.87" Description The IMX35 Series of board-mountable, 35 Watt DC-DC converters has been designed according to the latest industry requirements and standards. The converters are particularly suitable for use in mobile or stationary applications in transport, railways, industry, or telecommunication, where variable input voltages or high transient voltages are prevalent. Covering a total input voltage range from 9 V up to 150 V with 4 different models, the converters are available with up to four electrically isolated outputs from 5 V to 60 V, externally adjustable and with flexible load distribution. A shutdown input allows remote converter on/off. Features include consistently high efficiency over the entire input voltage range, high reliability, and excellent dynamic response to load and line changes. The converters are designed and built according to the international safety standards IEC/EN/UL 60950, and Table of Contents approved by TÜV and CSA. The converters provide basic insulation. The circuit is comprised of 2 planar magnetics devices, and all components are automatically assembled and securly soldered onto a single PCB without any wire connection. Magnetic feedback ensures maximum reliability and repeatability in the control loop over all operating conditions. Careful considerations of possible thermal stresses ensure the absence of hot spots providing long life in environments, where temperature cycles are present. The thermal design without using any potting material allows operation at full load up to an ambient temperature of 71 °C in free air and operation up to 105 °C with airflow. For extremely high vibration environments the case has holes for screw mounting. Page Page Description ............................................................................. 1 Model Selection ..................................................................... 2 Functional Description ........................................................... 3 Electrical Input Data ............................................................... 4 Electrical Output Data ............................................................ 6 Auxiliary Functions ................................................................. 9 Electromagnetic Compatibility (EMC) .................................. 11 Immunity to Environmental Conditions ................................ 12 Mechanical Data .................................................................. 13 Safety and Installation Instructions ...................................... 14 Options ................................................................................. 15 BCD20009-G Rev AC, 06-May-2013 Page 1 of 15 IMX35 Series Data Sheet 35 Watt Quad-Output DC-DC Converters ® Model Selection Table 1: Model Selection Output 1 Io nom Vo nom [V] [A] 1 2 Output 2 Vo nom Io nom [V] [A] Output 3 Vo nom Io nom [V] [A] Output 4 Vo nom Io nom [V] [A] Input voltage Vi min to Vi max [V] Efficiency 1 ηtyp ηmin [%] [%] Model Opt. i Z G 5 5 5 5 1.35 1.4 1.4 1.4 5 5 5 5 1.35 1.4 1.4 1.4 5 5 5 5 1.35 1.4 1.4 1.4 5 5 5 5 1.35 1.4 1.4 1.4 9 to 36 18 to 75 40 to 121 60 to 150 2 82.5 82 83 82 86 87 86 86 20IMX35D05D05-8 40IMX35D05D05-8 70IMX35D05D05-8 110IMX35D05D05-8 12 12 12 12 0.65 0.7 0.7 0.7 12 12 12 12 0.65 0.7 0.7 0.7 12 12 12 12 0.65 0.7 0.7 0.7 12 12 12 12 0.65 0.7 0.7 0.7 9 to 36 18 to 75 40 to 121 60 to 150 2 83.7 83.7 85 84 86 88 88 88 20IMX35D12D12-8 40IMX35D12D12-8 70IMX35D12D12-8 110IMX35D12D12-8 15 15 15 15 0.55 0.6 0.6 0.6 15 15 15 15 0.55 0.6 0.6 0.6 15 15 15 15 0.55 0.6 0.6 0.6 15 15 15 15 0.55 0.6 0.6 0.6 9 to 36 18 to 75 40 to 121 60 to 150 2 85 83.6 84.5 83 88 89 88 88 20IMX35D15D15-8 40IMX35D15D15-8 70IMX35D15D15-8 110IMX35D15D15-8 5 5 5 5 1.35 1.4 1.4 1.4 12 12 12 12 0.65 0.7 0.7 0.7 12 12 12 12 0.65 0.7 0.7 0.7 5 5 5 5 1.35 1.4 1.4 1.4 9 to 36 18 to 75 40 to 121 60 to 150 2 84 84 84 83.6 88 89 88 88 20IMX35D05D12-8 40IMX35D05D12-8 70IMX35D05D12-8 110IMX35D05D12-8 5 5 5 5 1.35 1.4 1.4 1.4 15 15 15 15 0.55 0.6 0.6 0.6 15 15 15 15 0.55 0.6 0.6 0.6 5 5 5 5 1.35 1.4 1.4 1.4 9 to 36 18 to 75 40 to 121 60 to 150 2 83.5 83.5 84 84 88 89 88 88 20IMX35D05D15-8 40IMX35D05D15-8 70IMX35D05D15-8 110IMX35D05D15-8 Efficiency at TA = 25 °C, Vo nom, Io nom 154 V for 2 s. Part Number Description 40 IMX35 D05 D05 -8 i Z G Input voltage range Vi 9 to 36 VDC 18 to 75 VDC 40 to 121 VDC 60 to 150 VDC ........................................... 20 ........................................... 40 ........................................... 70 ......................................... 110 Series ....................................................................... IMX35 Outputs 1 and 4 (1st power train) ............... D05, D12, D15 Outputs 2 and 3 (2nd power train) .............. D05, D12, D15 Operating ambient temperature range TA = – 40 to 85 °C ...................................... - 8 Options: 1 Inhibit ........................................................... -i Open frame ................................................. Z RoHS compliant for all six substances ........ G1 G is always placed at the end of the part number. Preferred for new designs Product Marking Converters without option Z are marked with type designation, input and output voltages and currents, applicable safety approval and recognition marks, company logo, production date, and serial no. BCD20009-G Rev AC, 06-May-2013 Page 2 of 15 IMX35 Series Data Sheet 35 Watt Quad-Output DC-DC Converters ® Functional Description The IMX35 converters are comprised of 2 feedback-controlled interleaved-switching flyback power trains using current mode PWM (pulse width modulation). Each converter consists of 4 electrically isolated outputs deriving from 2 power trains. Vo1, Vo4 derive from the first power train and Vo2, Vo3 from the second one. Thus each pair of outputs is independent from the other one. Voltage regulation for each pair of outputs is achieved with passive transformer feedback from the main transformer of the power train. Each pair of outputs has the same output voltage (i.e. D05, D12, etc.). If both power trains have the same output voltage (e.g. D12D12), all outputs may be simultaneously adjusted by the Trim input (pin 5). In case of different output voltages (e.g. D05D15), the Trim1 input influences only Vo1 and Vo4. Current limitation is provided by the primary circuit for each power train and limits the possible output power for each pair of outputs. In the case of an overload on either of the power trains, which causes the output voltage to fall less than typically 60% of Vo nom, the entire converter will shut down and automatically restart in short intervals (hiccup mode). The incorporated overtemperature protection shuts down the converter in excessive overload conditions with automatic restart. 03098a Vi+ 4 16 Vo1+ PUL 1 15 Vo1– Trim/Trim1 5 W 6 PWM 17 Vo4+ Ref 7 SD 8 18 Vo4– Vi– 2 n.c. 3 13 Vo2+ 14 Vo2– 12 Vo3+ 11 Vo3– 19 n.c. Fig. 1 Block diagram of quad-output models BCD20009-G Rev AC, 06-May-2013 Page 3 of 15 IMX35 Series Data Sheet 35 Watt Quad-Output DC-DC Converters ® Electrical Input Data General conditions: TA = 25 °C, unless specified Pins 8 (shutdown or i), 6 (W), 5 (Trim or Trim1), and 1 (PUL) left open-circuit (not connected), unless specified. Table 2: Input Data Input 20 IMX35 Characteristics min 92 Nominal input voltage TA min to TA max Io = 0 to Io nom Repetitive surge voltage Abs. max input (3 s) t start-up Converter Switch on start-up time 2 S ¯¯ D high Worst case condition at Vi min and full load t rise Rise time 3 Vi nom resist load 3 Io nom capac. load 6 Ii o No load input current Io = 0, Vi min to Vi max 70 50 mA Iirr Reflected ripple current Io = 0 to Io nom 30 30 mApp Iinr p Inrush peak current 4 Vi = Vi nom 8 9 A Ci Input capacitance for surge calculation V –– Shut down voltage Converter disabled Converter operating approx. 10 approx. 10 Input voltage range 1 Vi nom Vi sur SD R S–D– Shutdown input resistance I S–D– Input current during shutdown Vi fs Switching frequency min 36 18 2 typ VDC 40 40 0.25 100 0.5 0.25 0.5 0.1 s 0.1 3 12 ms 6 2 12 1.3 µF –10 to 0.7 –10 to 0.7 V open circuit or 2 to 20 open circuit or 2 to 20 min to Vi max 12 Vi min to Vi max, Io = 0 to Io nom 220 240 220 70 IMX35 Characteristics max 75 20 Input Conditions min typ 40 2 Vi Input voltage range 1 Vi nom Nominal input voltage TA min to TA max Io = 0 to Io nom Vi sur Repetitive surge voltage Abs. max input (3 s) t start-up Converter Switch on start-up time 2 S ¯¯ D high Worst case condition at Vi min and full load Rise time 3 Vi nom resist load 3 Io nom capac. load 6 t rise max Unit Conditions Vi typ 40 IMX35 kΩ 6 mA 240 kHz 110 IMX35 max min 121 60 2 70 typ Unit max 150 5 VDC 110 150 0.25 0.5 170 0.4 0.7 0.1 3 12 s 0.1 ms 6 12 Ii o No load input current Io = 0, Vi min to Vi max 30 20 mA Iirr Reflected ripple current Io = 0 to Io nom 30 30 mApp Iinr p Inrush peak current 4 Vi = Vi nom 7 7 A Ci Input capacitance for surge calculation 0.5 0.5 µF VS–D– Shut down voltage Converter disabled –10 to 0.7 –10 to 0.7 V Converter operating open circuit or 2 to 20 open circuit or 2 to 20 R S–D– Shutdown input resistance approx. 10 approx. 10 I S–D– Input current during shutdown Vi fs Switching frequency Vi min to Vi max, Io = 0 to Io nom 1 2 min to Vi max Vi min will not be as stated, if Vo is increased above Vo nom by use of Trim input. If the output voltage is set to a higher value, Vi min will be proportionately increased. Input undervoltage lockout at typ. 85% of Vi min. BCD20009-G Rev AC, 06-May-2013 5 220 3 4 5 240 220 kΩ 5 mA 240 kHz Measured with resistive and max. admissible capacitive load. Source impedance according to ETS 300132-2, version 4.3. 154 V during 2 s Page 4 of 15 IMX35 Series Data Sheet 35 Watt Quad-Output DC-DC Converters ® Inrush Current Input Transient Voltage Protection The inrush current has been kept as low as possible by choosing a very small input capacitance. A series resistor may be installed in the input line in order to further reduce this current. A built-in suppressor diode provides effective protection against input transients, which may be generated for example by short-circuits across the input lines, where the network inductance may cause high energy pulses. Table 4: Built-in transient voltage suppressor A 04022b 4 Model 3 Breakdown voltage VBr nom [V] Peak power at 1 ms Ω] Pp [Ω Peak pulse current I pp [A] 22 2 20IMX35 39 1500 1 40IMX35 100 1500 9.7 70IMX35 151 600 2.9 110IMX35 176 600 2.5 0 20 40 60 80 t 100 µs Fig. 2 Typical inrush current at Vi nom, Po nom versus time (40IMX35). Source impedance according to ETS 300132-2 at Vi nom . Vo Vo nom trise For very high energy transients as for example to achieve IEC/EN 61000-4-5 compliance (as per table Electromagnetic Immunity) an external inductor and capacitor are required. The components should have similar characteristics as listed in table below. Table 5: Components for external circuitry for IEC/EN 61000-4-5, level 2 04008b Model t tstartup Fig. 3 Converter start-up and rise time (see table 2) Inductor (L) Capacitor (C) Diode (D) 20IMX35 22 µH /5 A 470 µF / 40 V 1.5 k E47A 40IMX35 68 µH / 2.7 A 2 x 100 µF /100 V - 70IMX35 100 µH / 1 A 2 x 82 µF /200 V - 110IMX35 150 µH /0.8 A 2 x 82 µF / 200 V - Reverse Polarity Protection Vi+ The built-in suppressor diode also provides for reverse polarity protection at the input by conducting current in the reverse direction. An external fuse is required to limit this current. Table 3: Recommended external fuses in the non-earthed input line Converter model 04036a L Fuse type 20IMX35 F8.0 A 40IMX35 F4.0A 70IMX35 F2.0A 110IMX35 F1.5A BCD20009-G Rev AC, 06-May-2013 C + D Vi– Fig. 4 Example for external circuitry to comply with IEC/EN 610004-5; the diode D is only necessary for 20IMX35 models. Page 5 of 15 IMX35 Series Data Sheet 35 Watt Quad-Output DC-DC Converters ® Electrical Output Data General conditions: – TA = 25 °C, unless TC is specified – Pins 8 (shutdown or i), 6 (W), 5 (Trim or Trim1), and 1 (PUL) left open-circuit (not connected), unless specified. Table 6: Output data per double-output power train (Vo1/Vo4 or Vo2/Vo3; each power train has 2 outputs) Output 2x5V Conditions min Vo1 Vo2 Output voltage Vi nom Io = 0.5 Io nom 4.95 4.94 Io nom Output current 20IMX Vi min to Vi max 2 × 1.35 2 × 0.65 2 × 0.55 40IMX 2 × 1.4 2 × 0.70 2 × 0.60 Current limit 1 max min 5.05 5.06 11.88 11.86 typ 2 x 15 V Characteristics IoL typ 2 x 12 V max min 12.12 12.14 14.85 14.82 typ max 15.15 15.18 70IMX 2 × 1.4 2 × 0.70 2 × 0.60 110IMX 2 × 1.4 2 × 0.70 2 × 0.60 3.5 1.8 1.5 3.8 2.0 1.7 20IMX Vi nom, TC = 25 °C Vo = 93% Vo nom 40IMX Unit 70IMX 3.8 2.0 1.7 110IMX 3.8 2.0 1.7 A ∆Vo Line regulation Vi min to Vi max, Io nom ±1 ±1 ±1 ∆Vo l Load regulation Vi nom I o = (0.1 to 1) Io nom ±3 ±3 ±3 Vo1/2 Output voltage noise Vi min to Vi max I o = Io nom 2 80 120 150 3 40 60 70 limit. 4 Vo L Output overvoltage Co ext Admissible capacitive load per power train 5 produced after 2011 Vo d Dynamic load regulation Vi nom Io nom ↔ 1/2 Io nom ±250 Vi min to Vi max I o = (0.1 to 1) Io nom td αVo 1 2 3 4 5 Voltage deviat. Recovery time Temperature coefficient ∆Vo /∆T C Min. load 1% VDC % mVpp 115 130 115 130 115 130 % 0 6000 0 680 0 470 µF ± 480 ±520 mV 0.75 0.75 0.75 ms ±0.02 ±0.02 ±0.02 %/K Both outputs of each power train connected in parallel. The current limit is primary side controlled. In the event of a sustained overload condition, the thermal protection may cause the converter to shut down (restart on cool-down). BW = 20 MHz, measured with an external capacitor of 1 µF across the output pins. Measured with a probe according to EN 61204 The overvoltage protection is via a primary side second regulation loop, not tracking with Trim control. Sum of the capacities on both outputs of each power train BCD20009-G Rev AC, 06-May-2013 Page 6 of 15 IMX35 Series Data Sheet 35 Watt Quad-Output DC-DC Converters ® Thermal Considerations Vo [%] If a converter, mounted on a PCB, is located in free, quasistationary air (convection cooling) at the indicated maximum ambient temperature TA max (see table Temperature specifications) and is operated at its nominal input voltage and output power, the case temperature TC (TC Z with option Z) measured at the measuring point of case temperature (see Mechanical Data) will approach the indicated value TC max after the warmup phase. However, the relationship between TA and TC depends heavily on the conditions of operation and integration into a system. The thermal conditions are influenced by input voltage, output current, airflow, temperature of surrounding components and the surfaces and properties of the printed circuit board. TA max is therefore only an indicative value, and under practical operating conditions, the ambient temperature TA may be higher or lower than this value. Caution: The case temperature TC (or TC Z) measured at the measuring point of case temperature (see Mechanical Data) may under no circumstances exceed the specified maximum value. The installer must ensure that under all operating conditions TC (or TC Z) remains within the limits stated in the table Temperature specifications. The converters provide the specified output power with free air convection cooling. In the upper temperature range the output power derating below should be observed. Po /Po max overload short-circuit condition 100 switch-off 05041b 70 0 0.3 s t Fig. 6 Overload switch off (hiccup mode), typical values. Series and Parallel Connection The outputs of one or several double-output power trains may be connected in series respecting the current limitation. Both outputs of the same power train can always be connected in parallel in will behave like a single output. Several outputs of the same converter with equal output voltage (e.g. 5 V / 5 V) can be connected in parallel and will share their output currents almost equally. If outputs of the same converter are being parallel and seriesconnected, it is recommended that outputs from the same power trains are parallel-connected first. This applies for instance, if 24 V shall be generated by a converter with four 12 V outputs; see fig. 7. 11047-X35a 1.0 JM138 IMX35D12D12-9 0.8 Vi+ 4 0.5 m/s = 100 LFM 16 Vo1+ 0.6 PUL 1 natural cooling 0.4 W 0.2 0 15 Trim 5 6 PWM 17 Vo1– Vo4+ Ref 7 20 40 60 80 100 °C TA Fig. 5 SD 8 18 Vo4– –24V Vo2+ +24V Vi– 2 n.c. 3 Maximum allowed output power versus ambient temperature. 13 14 12 Vo2– Vo3+ Overtemperature Protection The converter is protected against possible overheating by means of an internal temperature monitoring circuit. It shuts down the converter above the internal temperature limit and attempts to automatically restart. This feature prevents excessive internal temperature building up which could occur under heavy overload conditions. Short Circuit Behavior The current limit characteristic shuts down the converter whenever a short circuit is applied to an output. It acts selfprotecting and automatically recovers after removal of the overload condition (hiccup mode). BCD20009-G Rev AC, 06-May-2013 11 Vo3– 19 n.c. Fig. 7 Generating 24 V with an IMX35D12D12-9 Note: Parallel operation of several converters may cause startup problems. This becomes noticable in applications, where one converter is not able to deliver allone the full resistive and capacitive load current, as it is required in true redundant systems. Page 7 of 15 IMX35 Series Data Sheet 35 Watt Quad-Output DC-DC Converters ® η [%] Typical Performance Curves 90 General conditions: – TA = 25°C, unless TC is specified. – Shut down and Trim pin left open-circuit. 05153a Vi min 80 Vo [V] Vi nom 05020-X35 13 70 12 11 60 25 10 9 50 75 Po 100 % Po total Fig. 11 8 0 0.5 1.5 1 2 A Io total Efficiency versus input voltage and load. Typical values (20IMX35D12D12-8) Fig. 8 Vo versus Io (typ.) of double-output power trains, with both outputs in parallel (e.g., Vo1/4 of a 40IMX35D12D12) η [%] 90 05152a Vi min Vi nom Vo4 [V] 80 05164b 13.5 13 12.5 12 Io4 = 0.035 A 70 Io4 = 0.35 A 60 25 11.5 Io1 0.06 0.1 0.2 0.3 0.4 0.5 0.6 0.7 A 50 75 Po 100 % Po total Fig. 12 Efficiency versus input voltage and load. Typical values (40IMX35D12D12-8) Fig. 9 Cross load regulation (typ.) on power train 1. Vo4 versus Io1 Vo1, Vo4 [V] 05039b 14 13 Vo4 12 Vo1 11 10 0 0.25 0.5 0.75 1 1.25 1.5 Io1/Io1 nom Fig. 10 Flexible load distribution (typ.) on power train 1 of a 40IMX35D12D12-8: Vo1 versus Io1, Io4 = 0.5 Io4 nom BCD20009-G Rev AC, 06-May-2013 Page 8 of 15 IMX35 Series Data Sheet 35 Watt Quad-Output DC-DC Converters ® Auxiliary Functions Table 8: Vo versus Vext for Vo = 85 to 105% Vo nom; typical values (Vi nom, Io = 0.5 Io nom) Adjustable Output Voltage Vo [% Vo nom] As a standard feature, the IMX35 offer adjustable output voltages in the range of 85 to 105% of Vo nom. Fig. 12 shows the schematic diagram for the adjustment of quad-output models. >105 102 100 95 90 85 All models with equal output voltages have a Trim input at pin 5 referenced to the primary side, influencing all outputs simultaneously. Models with different output voltages exhibit a Trim1 input, influencing only the first power train (Vo1 and Vo4). Vext [V] Trim [V] Trim1 [V] 0 1.8 2.5 4.3 6.2 8 0 1.5 2.5 4.25 6.2 8 Adjustment by means of an external resistor Rext: Synchronization (W) 06137c Vi+ Trim 4 16 5 15 + Vext – Control circuit Vref = 2.5 V Rext Vi– 13 2 14 Vo1+ Vo1– Vo2+ Vo2– Fig. 13 Adjustment of the output voltage by means of an external resistor Rext is possible within the range of 100 to 105% of Vo nom. Rext should be connected between Trim (pin 5) and Vi– (pin 2). The following table indicates suitable resistor values for typical output voltages under nominal conditions (Vi nom, Io = 0.5 Io nom). Note: Connection of Rext to Vi+ may damage the converter. Adjustment by means of an external voltage source Vext Table 7: Rext for Vo > Vo nom; approximate values (Vi nom, Io = 0.5 Io nom) Ω] Rext [kΩ Tr i m Trim1 0 10 62 0 17 110 105 to 108 (107 typically) 105 102 100 ∞ This logic input W can be used to synchronize the oscillator to an external frequency source. This signal is edge-triggered with TTL thresholds and requires a source frequency of 490 to 540 kHz (duty cycle 10 to 90%). The external source frequency is internally divided by 2 to define the switching frequency of the converter. If unused, this pin can be connected to V1– (pin 2) or left open-circuit. Reference Output (Ref) Output voltage control by means of the Trim input Vo [% Vo nom] It is possible to synchronize the switching frequency of one or more converters to an external clock signal. The converter provides a stable 5 V (±0.1 V) reference signal on pin 7 (Ref). The output is protected by a 1 kΩ resistor. The signal may be used also in conjunction with the Trim input (pin 5) as a limited external voltage reference. It is recommended to connect a filter capacitor (0 .1 µF) between Ref and Vi–, if Ref is used. Shutdown The outputs of the converters may be enabled or disabled by means of a logic signal (TTL, CMOS, etc.) applied to shutdown (pin 8). If the shutdown function is not required, pin 8 should be left open-circuit: Converter operating: 2.0 to 20 V Converter disabled: –10 to 0 .7 V ∞ For external output voltage adjustment in the range 85 to 105% of Vo nom a voltage source Vext (0 to 20 V) is required, connected to Trim or Trim1 (pin 5) and Vi–. The table below indicates typical values Vo versus Vext. Applying a control voltage of 15 to 20 V will set the converter into the hiccup mode. Direct paralleling of the Trim pins of converters of the same type connected in parallel is feasible. BCD20009-G Rev AC, 06-May-2013 Page 9 of 15 IMX35 Series Data Sheet 35 Watt Quad-Output DC-DC Converters ® Progr. Input Undervoltage Lockout PUL A special feature of the converters (with Rev. BA or later) is the adjustable undervoltage lockout protection, which protects the converter (and the system) from high current caused by operation at low input voltages. This ensures easier start-up in distributed power systems. The table below shows the band of switch on/off and the hysteresis. Table 9: Trigger level and hysteresis (pin 1 left open) Model Trigger level Hysteresis Unit 20IMX35 7 to 8 <0.5 V 40IMX35 14 to 15.5 <1 70IMX35 31 to 34 <3 110IMX35 42 to 50 <8 The undervoltage lockout levels may be programmed by using an external resistor R PUL between PUL and Vi – to increase the preset levels as specified in table 10. Table 10: Typical values for R PUL and the respective lockout voltage for input voltage. 20 IMX35 40 IMX35 R PUL [kW] Vi min [V] R PUL [kW] Vi min [V] ∞ ≤8 ∞ ≤ 15.5 39 10 43 22 19 12 16 26 13 14 10 28 9.1 16 0 32 70 IMX35 110 IMX35 R PUL [kW] Vi min [V] R PUL [kW] Vi min [V] ∞ 31 ∞ 42 270 40 270 50 110 50 120 60 80 55 51 75 BCD20009-G Rev AC, 06-May-2013 Page 10 of 15 IMX35 Series Data Sheet 35 Watt Quad-Output DC-DC Converters ® Electromagnetic Compatibility (EMC) A suppressor diode together with an input filter form an effective protection against high input transient voltages which typically occur in many installations, but especially in batterydriven mobile applications. Electromagnetic Immunity Table 11: Immunity type tests Phenomenon Standard Class Level Coupling mode 1 Value applied Waveform Source imped. Test procedure In oper. Perfcrit.2 Electrostatic discharge to case IEC/EN 61000-4-2 2 contact discharge (Trim pin open) 4000 Vp 1/50 ns 330 Ω yes B 3 air discharge (Trim pin open) 8000 Vp 10 positive and 10 negative discharges Electromagnetic field IEC/EN 61000-4-3 33 antenna 10 V/m AM 80% 1 kHz n.a. 80 to 1000 MHz yes A ENV 50204 3 antenna 10 V/m PM, 50% duty cycle, 200 Hz repetition frequ. n.a. 900 MHz yes A Electrical fast transients/burst IEC/EN 61000-4-4 4 direct +i/–i ±4000 Vp bursts of 5/50 ns 2.5/5 kHz over 15 ms, burst period 300 ms 50 Ω 60 s positive, 60 s negative transients per coupling mode yes B Surges IEC/EN 61000-4-5 34 +i/ – i ±2000 Vp 1.2/50 µs 2Ω 5 pos. and 5 neg. surges yes B EN 50155: 2001 A5 +i/ c, – i/c ±1800 Vp 5/50 µs 100 Ω yes B B6 +i/ c, – i/c 8400 Vp 0.05/ 0.1 µs 100 Ω IEC/EN 61000-4-6 3 +i/ – i 10 VAC (140 dBµV) AM modulated 80%, 1 k Hz 50 Ω RF Conducted immunity 1 2 3 4 5 6 0.15 to 80 MHz 150 Ω yes B yes A i = input, o = output, c = case (not with option Z) A = normal operation, no deviation from specification, B = temporary deviation from specs. possible. Corresponds to EN 50121-3-2:2000, table 9.1 External components required; see fig. 4 Corresponds to EN 50155:1995, waveform D Corresponds to EN 50155:1995, waveform G Electromagnetic Emissions PMM 8000 PLUS: Peak, conducted Vi+, QP + AV, 2006-10-01, 2x 1.1 mH, 110IMX35D05D12, Ui=110 V, Uo1=Uo4=5 V, Io1=Uo4=1.4 A, Uo2=Uo3=12 V Io2=Uo3=0.6 A dBµV 80 JM072 EN 55022 A QP EN 55022 A AV 60 40 20 0 0.2 0.5 1 2 5 10 20 MHz Fig. 14 Typ. disturbances (quasi-peak and average) at the input according to EN 55011/ 22, measured at Vi nom and Io nom (110IMX35D05D12-8 with input choke 2× 1.1 mH). BCD20009-G Rev AC, 06-May-2013 Page 11 of 15 IMX35 Series Data Sheet 35 Watt Quad-Output DC-DC Converters ® Conducted emission according to EN 55011/55022, class A, can be achieved by adding an external common mode choke and an additional ceramic capacitor. The filter components should be placed as close as possible to the input of the converter; see figure 15. 07114c + Ci Table 12: Input filter components Model 20IMX35 40IMX35 70IMX35 110IMX35 Vi+ Li Converter – Common mode choke L1 (Murata) Ceramic cap C1 70 µH / 3.6 A, PLH10AN7003R6P2 160 µH / 2.1 A, PLH10AN1612R1P2 290 µH / 1.2 A, PLH10AN2911R2P2 370 µH / 1.0 A, PLH10AN3711R0P2 4.7 µF / 50 V 2.2 µF / 100 V 1 µF / 200 V 1 µF / 200 V Vi– Fig. 15 External filter circuitry Immunity to Environmental Conditions Table 13: Mechanical and climatic stress Test method Standard Test conditions Status Damp heat steady state IEC/EN 60068-2-78 MIL-STD-810D section 507.2 Temperature: Relative humidity: Duration: 40 ±2 °C -- Salt mist test sodium chloride (NaCl) solution 2 EN 50155:2007 sect. 12.2.10 class ST3 2 Temperature: Duration: 35 ±2 °C 48 h Converter not operating Eb Bump (half-sinusoidal) IEC/EN 60068-2-29 MIL-STD-810D section 516.3 Acceleration amplitude: Bump duration: Number of bumps: 25 g n = 245 m/s2 6 ms 6000 (1000 in each direction) Converter operating Fc Vibration (sinusoidal) IEC/EN 60068-2-6 MIL-STD-810D section 514.3 Acceleration amplitude: Converter operating Frequency (1 Oct/min): Test duration: 0.35 mm (10 – 60 Hz) 5 g n = 49 m/s2 (60 - 2000 Hz) 10 – 2000 Hz 7.5 h (2.5 h in each axis) Cab Converter not operating 93 +2/-3 % 56 days Fh Random vibration broad-band (digital control) and guidance IEC/EN 60068-2-64 Acceleration spectral density: Frequency band: Acceleration magnitude: Test duration: 0.05 gn2 /Hz 8 – 500 Hz 4.9 g rms 1.5 h (0.5 h in each axis) Converter operating Ea Shock (half-sinusoidal) IEC/EN 60068-2-27 MIL-STD-810D section 516.3 Acceleration amplitude: Bump duration: Number of bumps: 50 gn = 490 m/s2 11 ms 18 (3 in each direction) Converter operating -- Shock EN 50155:2007 sect. 12.2.11 EN 61373 sect. 10, class B, body mounted 1 Acceleration amplitude: Bump duration: Number of bumps: 5.1 gn 30 ms 18 (3 in each direction) Converter operating -- Simulated long life testing at increased random vibration levels EN 50155:2007 sect. 12.2.11 EN 61373 sect. 8 and 9, Body mounted 1 Acceleration spectral density: Frequency band: Acceleration magnitude: Test duration: 0.02 gn2 /Hz 5 – 150 Hz 0.8 g n rm s 15 h (5 h in each axis) Converter operating 1 2 Body mounted = chassis of a railway coach Models without option Z BCD20009-G Rev AC, 06-May-2013 Page 12 of 15 IMX35 Series Data Sheet 35 Watt Quad-Output DC-DC Converters ® Temperatures Table 14: Temperature specifications, valid for air pressure of 800 to 1200 hPa (800 to 1200 mbar) Temperature -8 Unit Characteristics Conditions min max TA TC Ambient temperature Case temperature (without opt. Z) 2 Operational 1 –40 3 –40 3 85 1 105 2 TC Z Component temp. with opt. Z 2 –40 3 110 2 TS Storage temperature – 55 105 1 Non operational °C See Thermal Considerations Temperature measurment point; see Mechanical Data Start-up at – 55 °C 2 3 Reliability Table 15: MTBF at nom. load Model Ground benign 40 °C Ground fixed 40 °C 70 °C Ground mobile 50 °C Device hours1 Unit 396 000 h 40IMX35 (MIL-HDBK-217F, TC) 336 000 141 000 86 000 110 000 110IMX35 (Bellcore, TA) 1445 000 529 000 294 000 144 000 1 The device hours are based upon the IMX35 series field failure rate recorded between 2000 and 2005 Mechanical Data Dimensions in mm. European Projection 4 threads M3 09121c 09123c 0.8 x 0.8 TC Z 47.8 5.08 56.9 5.08 Bottom view 63.5 thread M3 0.8 x 0.8 Bottom view TC Z 63.5 63.5 72.8 69.6 Fig. 16 6.4 ±0.3 5 ±0.3 10.5 ±0.3 Cores Fig. 17 Case IMX35 (Standard) Case IMX35 open frame (option Z) Material: Zinc; weight: approx. 67 g Weight: approx. 43 g BCD20009-G Rev AC, 06-May-2013 8.9 ±0.2 TC Z 76.2 TC Page 13 of 15 IMX35 Series Data Sheet 35 Watt Quad-Output DC-DC Converters ® Safety and Installation Instructions Installation Instructions Installation of the converters must strictly follow the national safety regulations in compliance with the enclosure, mounting, creepage, clearance, casualty, markings, and segregation requirements of the end-use application. Pin allocation Table 16: Pin allocation Pin No. Quadruple output 1 PUL 2 Vi– 3 n.c. 4 Vi+ 5 Trim or Trim1 6 W 7 Ref 8 SD or i 11 Vo3– 12 Vo3+ 13 Vo2+ Standards and Approvals 14 Vo2– 15 Vo1– All converters are safety-approved to IEC/EN 60950 -1 and UL/CSA 60950-1 2nd Ed. 16 Vo1+ 17 Vo4+ 18 Vo4– 19 n.c. Connection to the system shall be made via a printed circuit board with hole diameters of 1.5 mm for the pins. The converters should be connected to a secondary circuit. Do not open the converter. Ensure that a converter failure (e.g., by an internal shortcircuit) does not result in a hazardous condition. Input Fuse To prevent excessive current flowing through the input supply line in case of a short-circuit in the converter, an external fuse should be installed in the non-earthed input line. We recommend a fast acting fuse specified in table 3. The converters have been evaluated for: • Building-in • Basic insulation input to output, based on their maximum input voltage • Pollution degree 2 (not option Z) • Connecting the input to a secondary circuit, which is subject to a maximum transient rating of 1500 V. The converters are subject to manufacturing surveillance in accordance with the above mentioned standards. 09122a 1 2 3 4 5 6 7 8 Bottom view 11 12 13 14 15 16 17 18 19 CB scheme is available. Railway Applications To comply with Railway standards, all components are coated with a protective lacquer (except for option Z). Protection Degree The protection degree is IP 30 (not for option Z). Cleaning Liquids Fig. 18 Footprint. The holes in the PCB should have a diameter of 1.5 mm. In order to avoid possible damage, any penetration of cleaning fluids should be prevented, since the converters are not hermetically sealed. However, open-frame models (option Z) leave the factory unlacquered; they may be lacquered by the customer, for instance together with the mother board. Cleaning liquids are not permitted – except washing at room temperature with isopropyl alcohol and de-inonized/destilled water (1 : 1) . Note: Cleaning liquids may damage the adhesive joints of the ferrite cores. BCD20009-G Rev AC, 06-May-2013 Page 14 of 15 IMX35 Series Data Sheet 35 Watt Quad-Output DC-DC Converters ® Table 17: Electric strength test voltages Characteristic Input to (outputs+case) 20/40IMX35 1 Factory test >1 s 1.2 Equivalent DC voltage Insulation resistance Input to (outputs+case) 70/110IMX35 1 Outputs to case all models 1 Between outputs all models Unit 1.8 0.5 0.15 2 kVAC 1.5 2.5 0.7 0.2 2 kVDC >100 >100 – – MΩ at 500 VDC 1 2 For open-frame models (option Z), only the insulation input to outputs is tested. The test voltage between outputs is not applied as routine test. Isolation The electric strength test is performed in the factory as a routine test in accordance with EN 50116, EN 60950, and UL 60950 and should not be repeated in the field. Power-One will not honor any warranty claims resulting from electric strength field tests. Options should be connected to Vi– to enable the output (active low logic, fail safe). i: Inhibit (Negative Shutdown Logic) Voltage at pin 8: The outputs of the converter may be enabled or disabled by means of a logic signal (TTL, CMOS, etc.) applied to the inhibit pin 8. If the inhibit function is not required the inhibit (pin 8) 06138a 4 Vi+ 8 i 2 Vi – Converter operating: –10 V to 0.8 V Converter disabled: 2.4 V to 20 V or left open-circuit Z: Open Frame For applications, where the protection by a housing is not necessary or in the case that the motherboard should be lacquered after fitting the converter. Note: The converters shall not be exposed to cleaning processes, as this will damage the glue of the ferrite cores. G: RoHS-6 Fig. 19 If the inhibit pin is not used, connect it to Vi–. Converters with a type designation ending by G are RoHScompliant for all six substances. NUCLEAR AND MEDICAL APPLICATIONS - Power-One products are not designed, intended for use in, or authorized for use as critical components in life support systems, equipment used in hazardous environments, or nuclear control systems without the express written consent of the respective divisional president of Power-One, Inc. TECHNICAL REVISIONS - The appearance of products, including safety agency certifications pictured on labels, may change depending on the date manufactured. Specifications are subject to change without notice. BCD20009-G Rev AC, 06-May-2013 Page 15 of 15