CS1501-9ER

S Series 100 Watt DC-DC and AC-DC Converters Features • RoHS lead-free-solder and lead-solder-exempted products available • 5 year warranty for RoHS compliant products with an extended temperature range • Compliant with EN 50155, EN 50121-3-2 • Compliant to EN 45545 (version V108 or later) • Class I equipment • Extremely wide input voltage ranges from 8 to 385 VDC, and 85 to 264 VAC, 47 to 440 Hz • Input over- and undervoltage lockout • Adjustable output voltage with remote on/off • 1 or 2 outputs: SELV, no load, overload, and short-circuit proof • Rectangular current limiting characteristic • PCBs protected by by lacquer • Very high reliability Safety-approved to the latest edition of IEC/EN 60950-1 and UL/CSA 60950-1 111 4.4" 3U 60 2.4" 12 TE 168 6.6" Table of Contents Description........................................................................................2 Model Selection.................................................................................2 Functional Description.......................................................................5 Electrical Input Data..........................................................................6 Electrical Output Data.......................................................................9 Auxiliary Functions..........................................................................13 Electromagnetic Compatibility (EMC)..............................................17 Immunity to Environmental Conditions............................................19 Mechanical Data..............................................................................20 Safety and Installation Instructions..................................................22 Description of Options.....................................................................26 Accessories.....................................................................................35 belfuse.com/power-solutions BCD20004-G Rev AF, 12-Jul-2018 S Series 100 W DC-DC and AC-DC Converters Description The S Series of DC-DC and AC-DC converters represents a broad and flexible range of power supplies for use in advanced electronic systems. Features include high efficiency, high reliability, low output voltage noise and excellent dynamic response to load/line changes. LS models can be powered by DC or AC with a wide-input frequency range (without PFC). The converter inputs are protected against surges and transients. An input over- and undervoltage lockout circuitry disables the outputs, if the input voltage is outside of the specified range. Certain types include an inrush current limiter preventing circuit breakers and fuses from tripping at switch-on. All outputs are open- and short-circuit proof, and are protected against overvoltages by means of built-in suppressor diodes. The output can be inhibited by a logic signal applied to pin 18 (i). If the inhibit function is not used, pin 18 must be connected with pin 14 to enable the outputs. LED indicators display the status of the converter and allow for visual monitoring of the system at any time. Full input-to-output, input-to-case, output-to-case, and output to output isolation is provided. The converters are designed, built, and safety-approved to the international safety standards IEC/EN 60950-1. They observe EN 50155 and EN 50121-3-2 and are particularly suitable for railway applications. The case design allows operation at nominal load up to 71 °C in a free-air ambient temperature. If forced cooling is provided, the ambient temperature may exceed 71 °C, but the case temperature must remain below 95 °C under all conditions. A temperature sensor generates an inhibit signal, which disables the outputs when the case temperature TC exceeds the limit. The outputs are automatically re-enabled, when the temperature drops below the limit. Various options are available to adapt the converters to individual applications. The converters may either be plugged into a 19” DIN-rack system according to IEC 60297-3, or mounted to a chassis. Important: For applications requiring compliance with IEC/EN 61000-3-2 (harmonic distortion), please use our LS4000 or LS5000 Series with incorporated power factor correction (PFC). Model Selection Non-standard input/output configurations or special customer adaptations are available on request. Table 1a: Models AS, BS Output 1 Output 2 Input Voltage Efficiency 1 Input Voltage Efficiency 1 Vi min – Vi max 14 - 70 VDC η min [%] Options 4 Vo nom [VDC] Io nom [A] Vo nom [VDC] Io nom [A] Vi min – Vi max 8 - 35 VDC η min [%] 5.1 16 - - AS1001-9RG 76 BS1001-9RG 77 -7, P, D, V ², T, B, B1, non-G 12 15 24 8 6.5 4.2 - - AS1301-9RG AS1501-9RG AS1601-9RG 81 83 84 BS1301-9RG BS1501-9RG BS1601-9RG 83 85 86 -7, P, D, T, B, B1, non-G 12 15 24 4 3.2 2 12 3 15 3 24 3 4 3.2 2 AS2320-9RG AS2540-9RG AS2660-9RG 79 80 80 BS2320-9RG BS2540-9RG BS2660-9RG 80 82 82 -7, P, D, T, B, B1, non-G Min. efficiency at Vi nom, Io nom and TA = 25 °C. Typical values are approximately 2% better. Option V is possible for 5.1 V output only and excludes option D. 3 Second output semi-regulated 4 Models FS, CS, DS, ES, LS are available as -7 or -9E. 1 2 NFND: Not for new designs. Preferred for new designs tech.support@psbel.com belfuse.com/power-solutions BCD20004-G Rev AF, 12-Jul-2018 © 2018 Bel Power Solutions & Protection Page 2 of 36 S Series 100 W DC-DC and AC-DC Converters Table 1b: Models FS, CS Output 1 Output 2 Input Voltage Efficiency 1 Input Voltage Efficiency 1 Options 4 Vo nom [VDC] Io nom [A] Vo nom [VDC] Io nom [A] Vi min – Vi max 20 - 100 VDC η min [%] Vi min – Vi max 28 - 140 VDC η min [%] 5.1 16 - - FS1001-9ERG 77 CS1001-9RG 77 -7, P, D, V ², T, B, B1, non-G 12 15 24 8 6.5 4.2 - - FS1301-9ERG FS1501-9ERG FS1601-9ERG 83 84 86 CS1301-9ERG CS1501-9ERG CS1601-9ERG 83 84 85 -7, P, D, T, B, B1, non-G 12 15 24 4 3.2 2 12 3 15 3 24 3 4 3.2 2 FS2320-9ERG FS2540-9ERG FS2660-9ERG 80 82 82 CS2320-9ERG CS2540-9ERG CS2660-9ERG 80 82 82 -7, P, D, T, B, B1, non-G Table 1c: Models DS, ES, LS Output 1 Output 2 Input Voltage Effic.1 Input Voltage Effic.1 Input Voltage Effic.1 Vo nom [VDC] Io nom [A] Vo nom [VDC] Io nom [A] Vi min – Vi max 44 - 220 VDC η min [%] Vi min – Vi max 67 - 385 VDC η min [%] Vi min – Vi max 88 - 372 VDC 85 - 264 VAC η min [%] 5.1 16 - - DS1001-9ERG 79 - - LS1001-9ERG 78 12 12.84 5 15 24 8 7.5 6.5 4.2 - - DS1301-9ERG 84 ES1301-9ERG LS1301-9ERG 83 DS1601-9ERG 86 86 ES1601-9ERG 83 84 86 LS1601-9ERG 84 85 12 15 24 4 3.2 2 12 15 3 24 3 4 3.2 2 DS2320-9ERG DS2540-9ERG DS2660-9ERG 81 82 83 ES2320-9ERG ES2540-9ERG ES2660-9ERG 81 83 83 LS2320-9ERG LS2540-9ERG LS2660-9ERG 80 81 81 25.68 6 1.8 25.68 3, 6 1.8 DS2740-9ERG 6 - - LS2740-9ERG 6 3 DS1740-9ERG 5 DS1501-9ERG ES1501-9ERG LS1740-9ERG 5 LS1501-9ERG Options 4 -7, P, D, V ², T, B, B1, non-G -7, P, D, T, B, B1, non-G -7, P, D, T, B, B1, non-G -7, T, B, B1, non-G Min. efficiency at Vi nom, Io nom and TA = 25 °C. Typical values are approximately 2% better. Option V is possible for 5.1 V output only and excludes option D. 3 Second output semi-regulated 4 Models FS, CS, DS, ES, LS are available as -7 or -9E. 5 Battery loader for 12 V batteries. Vo is controlled by the battery temperature sensor (see Accessories) within 12.62  – 14.12 V. Options P, D, V are not available. 6 Battery loader for 24 V (and 48 V batteries with series-connected outputs). Vo is controlled by the battery temperature sensor (see Accessories) within 25.25 – 28.25 V (50.5 – 56.5 V for 48 V batteries). Options P, D, and V are not available. 1 2 NFND: Not for new designs. Preferred for new designs tech.support@psbel.com belfuse.com/power-solutions BCD20004-G Rev AF, 12-Jul-2018 © 2018 Bel Power Solutions & Protection Page 3 of 36 S Series 100 W DC-DC and AC-DC Converters Part Number Description CS 2 5 40 -9 E  R D3  T B1 G Operating input voltage Vi: 8 – 35 VDC ................................................................ AS 14 – 70 VDC .............................................................. BS 20 – 100 VDC ............................................................ FS 28 – 140 VDC ............................................................CS 44 – 220 VDC ............................................................DS 67 – 385 VDC ............................................................ ES 100 – 264 VAC or 88 – 372 VDC .............................. LS Number of outputs.............................................................1, 2 Nominal voltage of output 1 (main output) Vo1 nom 5.1 V ......................................................................0, 1, 2 12 V ..............................................................................3 15 V ..........................................................................4, 5 24 V ..............................................................................6 Other voltages 1 ........................................................7, 8 Nominal voltage of output 2 Vo2 nom None (single-output models)........................................00 12 V, 12 V....................................................................20 15 V, 15 V.....................................................................40 24 V, 24 V.....................................................................60 Other specifications or additional features 1 ........ 21 – 99 Operational ambient temperature range TA: –25 to 71 °C................................................................. -7 – 40 to 71 °C..................................................................-9 Other 1 ................................................................ -0, -5, -6 Auxiliary functions and options: Inrush current limitation ...............................................E 2 Output voltage control input ...................................... R 3 Potentiometer (output voltage adjustment) ............... P ³ Undervoltage monitor (D0 – DD, to be specified)........ D 4 ACFAIL signal (V2, V3, to be specified)..................... V ⁴ Current share control......................................................T Cooling plate standard case.................................B or B1 Cooling plate for long case 220 mm 1 ........................B2 1 RoHS-compliant for all 6 substances ........................... G 3 4 1 2 Customer-specific models Option E is mandatory for all -9 models, except AS and BS. Feature R excludes option P and vice versa. Option P is not available for battery charger models. Option D excludes option V and vice versa; option V is only available for models with 5.1 V single output. Note: The sequence of options must follow the order above. This part number description is descriptive only; it is not intended for creating part numbers. Example: CS2540-9ERD3T B1G: DC-DC converter, operating input voltage range 28 – 140 VDC, 2 electrically isolated outputs, each providing 15 V, 3.2 A, input current limiter E, control input R to adjust the output voltages, undervoltage monitor D3, current share feature T, cooling plate B1, and RoHS-compliant for all six substances. Product Marking Basic type designation, applicable approval marks, CE mark, warnings, pin designation, patents and company logo, identification of LEDs, test sockets, and potentiometer. Specific type designation, input voltage range, nominal output voltages and currents, degree of protection, batch no., serial no., and data code including production site, modification status, and date of production. tech.support@psbel.com belfuse.com/power-solutions BCD20004-G Rev AF, 12-Jul-2018 © 2018 Bel Power Solutions & Protection Page 4 of 36 S Series 100 W DC-DC and AC-DC Converters Functional Description The input voltage is fed via an input fuse, an input filter, a bridge rectifier (LS models only), and an inrush current limiter to the input capacitor C1. This capacitor sources a single-transistor forward converter with a special clamping circuit and provides the power during the hold-up time. Each output is powered by a separate secondary winding of the main transformer. The resultant voltages are rectified and their ripple smoothed by a power choke and an output filter. The control logic senses the main output voltage Vo1 and generates, with respect to the maximum admissible output currents, the control signal for the switching transistor of the forward converter. The second output of double-output models is tracking to the main output, but has its own current limiting circuit. If the main output voltage drops due to current limitation, the second output voltage will fall as well and vice versa. 03057b 26 Vi+ 28 20 D/V CY 12 S+ 4 Vo+ 6 Output filter Forward converter (approx. 120 kHz) Bridge rectifier 4 3 22 T Control circuit Ci + 2 Fuse 4 18 i 4 1 L 16 R CY Input filter 4 N Opt. P 8 CY Vo– 10 30 Vi– 32 14 S– CY 24 1 2 3 4 – Transient suppressor (VDR) Suppressor diode (AS, BS, FS models) For CS, DS, ES, LS: Either NTC (-7 models only) or option E LS models only + Fig. 1 Block diagram of single-output converters 03058b Opt. P Ci + CY CY 12 Vo1+ Output 1 filter Forward converter (approx. 120 kHz) 22 T 14 Vo1– 4 CY 3 6 Output 2 filter Vi– 20 D 2 Fuse 4 18 i Control circuit 4 1 L 16 R CY Vi+ 28 Bridge rectifier 4 4 Input filter N 26 30 32 CY 24 1 2 3 4 8 CY 10 – Transient suppressor (VDR) Suppressor diode (AS, BS, FS models) For CS, DS, ES, LS: Either NTC (-7 models only) or option E LS models only Vo2+ Vo2– + Fig. 2 Block diagram of double-output models tech.support@psbel.com belfuse.com/power-solutions BCD20004-G Rev AF, 12-Jul-2018 © 2018 Bel Power Solutions & Protection Page 5 of 36 S Series 100 W DC-DC and AC-DC Converters Electrical Input Data General conditions: - TA = 25 °C, unless TC is specified. - Pin 18 connected to pin 14, Vo adjusted to Vo nom (if option P); R input not connected. - Sense line pins S+ and S– connected to Vo+ and Vo– respectively. Table 2a: Input data Model AS Characteristics Conditions min 8 BS typ max min 35 14 typ FS max min 70 20 typ Unit max Vi Operating input voltage Io = 0 – Io max Vi nom Nominal input voltage TC min – TC max 15 Ii Input current Vi nom, I o nom 1 7.5 Pi 0 No-load input power Vi min – Vi max 2.5 2.5 2.5 P i inh Idle input power Unit inhibited 1.5 1.5 1.5 Ri Input resistance RNTC NTC resistance 2 Ci Input capacitance Vi RFI Vi abs Conducted input RFI Radiated input RFI 300 370 1200 1500 A B A A A 0 40 0 84 0 W mΩ no NTC A VDC A 70 no NTC 1040 EN 55022, Vi nom, I o nom Input voltage limits without damage 2.6 100 no NTC 832 50 4.3 65 TC = 25 °C 100 30 µF 100 VDC Table 2b: Input data Model CS Characteristics Conditions min typ 28 DS max min 140 44 typ ES max min 220 67 typ LS max 385 min typ Unit max 88 372 85 4 264 4 Vi Operating input voltage Vi nom Nominal input voltage Ii Input current Vi nom, I o nom 1 Pi 0 No-load input power Vi min – Vi max 2.5 2.5 2.5 2.5 P i inh Idle input power Unit inhibited 1.5 1.5 1.5 4.5 Ri Input resistance RNTC NTC resistance Ci Input capacitance Vi RFI Vi abs 2 Conducted input RFI Radiated input RFI Input voltage limits without damage Io = 0 – Io max TC min – TC max TC = 25 °C 60 110 2.1 1.1 150 EN 55022, Vi nom, I o nom 0 264 330 216 270 216 270 B B B B A A A 0 400 3 0 400 -400 W mΩ 4000 B 154 A 480 4000 VAC VDC 0.37 180 2000 1200 310 0.55 170 1000 960 220 VDC µF 400 VDC Both outputs of double-output models are loaded with Io nom. Valid for -7 versions without option E (-9 versions exclude NTC). This is the nominal value at 25 °C and applies to cold converters at initial switch-on cycle. Subsequent switch-on/off cycles increase the inrush current peak value. 3 For 1 s max. 4 Nominal frequency range is 50 – 60 Hz. Operating frequency range is 47 – 440 Hz (440 Hz for 115 V mains). For frequencies ≥ 63 Hz, refer to Installation Instructions. 1 2 tech.support@psbel.com belfuse.com/power-solutions BCD20004-G Rev AF, 12-Jul-2018 © 2018 Bel Power Solutions & Protection Page 6 of 36 S Series 100 W DC-DC and AC-DC Converters Input Transient Protection A suppressor diode or a VDR (depending upon the input voltage range) together with the input fuse and a symmetrical input filter form an effective protection against high input transient voltages which, typically occur in most installations, but especially in battery-driven mobile applications. Standard nominal battery voltages are: 12, 24, 36, 48, 60, 72, 110, and 220 V. Railway batteries are specified with a tolerance of –30% to +25%, with short excursions up to ± 40%. In certain applications, additional surges according to RIA 12 are specified. The power supply must not switch off during these surges, and since their energy can practically not be absorbed, an extremely wide input range is required. The ES input range for 110 V batteries has been designed and tested to meet this requirement. Input Fuse A fuse mounted inside the converter protects against severe defects. This fuse may not fully protect the converter, when the input voltage exceeds 200 VDC. In applications, where the converters operate at source voltages above 200 VDC, an external fuse or a circuit breaker at system level should be installed. Table 3: Fuse Specification Model Fuse type Reference Rating AS fast-blow 1 Littlefuse 314 30 A, 125 V BS fast-blow 1 Littlefuse 314 25 A, 125 V FS slow-blow 2 Schurter SPT 16 A, 250 V CS slow-blow 2 Schurter SPT 12.5 A, 250 V DS slow-blow 2 Schurter SPT 8 A, 250 V ES slow-blow 2 Schurter SPT 4 A, 250 V LS slow-blow Schurter SPT 4 A, 250 V 1 2 Fuse size 6.3 × 32 mm 2 Fuse size 5 × 20 mm Inrush Current Limitation The FS, CS, DS, ES, LS models incorporate an NTC resistor in the input circuitry, which at initial turn-on reduces the peak inrush current value by a factor of 5 – 10 such protecting connectors and switching devices from damage. Subsequent switchon cycles within short periods will cause an increase of the peak inrush current value due to the warming-up of the NTC resistor. See also Option E. The inrush current peak value (initial switch-on cycle) can be determined by following calculation; see also fig. 3: Vi source Iinr p = ________________ (R +R +R ) s ext i NTC Ii inr [A] 04038a 150 100 05109a Rs ext CS ES, LS DS + 50 0 0.1 1 2 Iinr p Ri RNTC Ci int Vi source 3 t [ms] Fig. 3 Typical inrush current versus time at Vi max, Rext = 0 Ω. For AS, BS, FS, and for application-related values, use the formula in this section to get realistic results. Fig. 4 Equivalent input circuit tech.support@psbel.com belfuse.com/power-solutions BCD20004-G Rev AF, 12-Jul-2018 © 2018 Bel Power Solutions & Protection Page 7 of 36 S Series 100 W DC-DC and AC-DC Converters Static Input Current Characteristics Ii (A) 20 04037a 10 5 AS 2 BS 1 FS CS DS 0.5 ES 1 2 3 4 5 6 Vi Vi min LS (DC input) Fig. 5 Typical input current versus relative input voltage Reverse Polarity The converters (except LS models) are not protected against reverse polarity at the input to avoid unwanted power losses. In general, only the input fuse will trip. LS models are fully protected by the built-in bridge rectifier. Input Under-/Overvoltage Lockout If the input voltage remains below approx. 0.8 Vi min or exceeds approx. 1.1 Vi max, an internally generated inhibit signal disables the output(s). When checking this function, the absolute maximum input voltage V i abs should be observed. Between Vi min and the undervoltage lock-out level the output voltage may be below the value defined in table Electrical Output data. Hold-Up Time th [ms] 04041a ES CS FS DS 100 10 AS th [ms] 04049a 100 BS 10 1 0.30 1 2 3 4 5 6 Vi ––––– Vi min Fig. 6a Typical hold-up time t h versus relative DC input voltage. Vi/Vi min. DC-DC converters require an external series diode in the input path, if other loads are connected to the same input supply lines. 2 V 1 2 3 4 i _______ Vi min Fig. 6b Typical hold-up time t h versus relative AC input voltage (LS models) tech.support@psbel.com belfuse.com/power-solutions BCD20004-G Rev AF, 12-Jul-2018 © 2018 Bel Power Solutions & Protection Page 8 of 36 S Series 100 W DC-DC and AC-DC Converters Electrical Output Data General Conditions: – TA = 25 °C, unless TC is specified. – Pin 18 (i) connected to pin 14 (S– or Vo1–), R input not connected, Vo adjusted to Vo nom (option P), – Sense line pins 12 (S+) and 14 (S–) connected to pins 4 (Vo1+) and 8 (Vo1–), respectively. Table 5: Output data of single-output models Model AS – LS1001 AS – LS1301/1740 5 AS – LS1501 AS – LS1601 5.1 V 12 V / 12.84 V 5 15 V 24 V Nom. output voltage Characteristics Conditions min Vi nom, Io nom  5.07 Vo Output voltage  V o BR Output protection (suppressor diode) 7 Io nom Output current nom. 1 Vi min – Vi max TC min – TC max Io L Output current limit Vi min – Vi max Vo Output noise 3 Low frequency 8 Switching frequ. Total incl. spikes typ max min 5.13 11.93 6.0 Vi nom, Io nom BW = 20 MHz typ max 12.07 5 15.2/17.5 5 16 min 5 typ 14.91 min 15.09 23.86 19.6 6.5 8.2/7.7 5 max 24.14 V 4.2 6.7 5 typ 28.5 8/7.5 5 16.2 max Unit A 4.4 5 5 5 10 5 5 5 50 50 60 90 mVpp ∆Vo u Static line regulation with respect to Vi nom Vi min – Vi max Io nom ±15 ±20 ±25 ±30 ∆Vo l Static load regulation 10 Vi nom (0.1 – 1) Io nom -20 -25 -30 -40 Vo d Dynamic load regulation 3 td αvo Voltage deviation 6 Recovery time 6 Temperature coefficient of output voltage 4 Vi nom Io nom ↔ 0.5 Io nom Io nom TC min – TC max mV ±100 ±100 ±100 ±100 0.4 0.5 0.5 0.5 ms ±0.02 ±0.02 ±0.02 ±0.02 %/K If the output voltages are increased above Vo nom through R-input control, option P setting, remote sensing or option T, the output currents should be reduced accordingly so that Po nom is not exceeded. 2 See Output voltage regulation 3 Measured according to IEC/EN 61204 with a probe according to annex A 4 For battery charger applications, a defined negative temperature coefficient can be provided by using a temperature sensor (see Accessories), but we recommend choosing the special battery charger models. 5 Especially designed for battery charging using the temperature sensor (see Accessories). Vo is set to 12.84 V ±1% (R-input open) 6 See Dynamic load regulation 7 Breakdown voltage of the incorporated suppressor diode (1 mA; 10 mA for 5 V output). Exceeding Vo BR is dangerous for the suppressor diode. 8 LS models only (twice the input frequency) 1 tech.support@psbel.com belfuse.com/power-solutions BCD20004-G Rev AF, 12-Jul-2018 © 2018 Bel Power Solutions & Protection Page 9 of 36 S Series 100 W DC-DC and AC-DC Converters Table 6a: Output data of double-output models. General conditions as per table 5. Model (Nom. output voltage) Characteristics AS – LS2320 (2 x 12 V) Conditions typ min 12.07 11.82 typ Output 1 max min typ 12.18 14.91 min 15.09 14.78 typ V o BR 1 Output protection (suppressor diode) Io nom Output current nom. 2 Vi min – Vi max TC min – TC max Io L Output current limit 9 Vi min – Vi max Vo Output noise 3 ∆Vo u Static line regulation with respect to Vi nom Vi min – Vi max Io nom ±20 5 ±25 5 ∆Vo l Static load regulation Vi nom (0.1 – 1) Io nom -40 5 -50 5 Vo d Dynamic load regulation 15.2 Low frequency 8 Switching frequ. Total incl. spikes Voltage deviation 4 Recovery time 4 Temperature coefficient of output voltage 6 15.2 19.6 4 3.2 4.2 BW = 20 MHz Io nom TC min – TC max A 3.4 5 5 5 5 5 5 5 40 40 50 50 ±100 Vi nom Io1 nom ↔ 0.5 Io1 nom 0.5 Io2 nom V 3.2 3.4 5 Vi nom, Io nom max 15.22 19.6 4 4.2 Unit Output 2 max Output voltage  αvo 11.93 Output 2 max Vo td Vi nom, Io1 nom, Io2 nom  Output 1 min AS – LS2540 (2 x 15 V) ±150 ±100 mVpp mV ±150 0.2 0.2 ms ±0.02 ±0.02 %/K Table 6b: Output data of double-output models. General conditions as per table 5. Model (Nom. output voltage) Characteristics AS – LS2660 / 2740 (2 × 24 V / 2 × 25.68 V) 7 Conditions Vo Output voltage  Vi nom, Io1 nom, Io2 nom  V o BR 1 Output protection (suppressor diode) Io nom Output current nom. 2 Vi min – Vi max TC min – TC max Io L Output current limit Vi min – Vi max Output 1 min typ 23.86 7 max min 24.14 7 23.64 7 28.5/34 7 9 Low frequency 8 Vi nom, Io nom typ V 28.5/34 7 2/1.8 7 2.2/2.0 7 5 5 Output noise 3 ∆Vo u Static line regulation with respect to Vi nom Vi min – Vi max Io nom ±30 5 ∆Vo l Static load regulation Vi nom (0.1 – 1) Io nom -60 5 Vo d Dynamic load regulation td αvo Total incl. spikes Voltage deviation 4 Recovery time 4 Temperature coefficient of output voltage 6 BW = 20 MHz Vi nom Io1 nom ↔ 0.5 Io1 nom 0.5 Io2 nom Io nom TC min – TC max 5 5 50 80 ±100 A 7 Vo Switching frequ. max 24.36 7 2/1.8 7 2.2/2.0 Unit Output 2 mVpp mV ±150 0.2 ms ±0.02 %/K Breakdown voltage of the incorporated suppressor diodes (1 m A). Exceeding Vo BR is dangerous for the suppressor diodes. If the output voltages are increased above Vo nom via R-input control, option P setting, remote sensing, or option T, the output currents should be reduced accordingly, so that Po nom is not exceeded. 3 Measured according to IEC/EN 61204 with a probe annex A 4 See Dynamic Load Regulation 5 See Output Voltage Regulation of Double-Output Models 6 For battery charger applications, a defined negative temperature coefficient can be provided by using a temperature sensor; see Accessories. 7 Especially designed for battery charging using the battery temperature sensor; see Accessories. Vo1 is set to 25.68 V ±1% (R-input open-circuit). 8 LS models only (twice the input frequency) 9 Both outputs connected in series. 1 2 tech.support@psbel.com belfuse.com/power-solutions BCD20004-G Rev AF, 12-Jul-2018 © 2018 Bel Power Solutions & Protection Page 10 of 36 S Series 100 W DC-DC and AC-DC Converters Thermal Considerations If a converter is located in free, quasi-stationary 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 temperature measured at the Measuring point of case temperature TC (see Mechanical Data) will approach the indicated value TC max after the warm-up phase. However, the relationship between TA and TC depends heavily upon the conditions of operation and integration into a system. The thermal conditions are influenced by input voltage, output current, airflow, and temperature of surrounding components and surfaces. TA max is therefore, contrary to TC max, an indicative value only. Caution: The installer must ensure that under all operating conditions TC remains within the limits stated in the table Temperature specifications. Notes: Sufficient forced cooling or an additional heat sink allows TA to be higher than 71 °C (e.g., 85 °C), as long as TC max is not exceeded. Details are specified in fig.7. Io /Io nom 1.0 05089a 0.8 Forced cooling Convection cooling 0.6 TC max 0.4 0.2 0 TA min 50 60 70 80 90 100 TA [°C] Fig. 7 Output current derating versus temperature for -7 and -9 models. Thermal Protection A temperature sensor generates an internal inhibit signal, which disables the outputs, when the case temper­ature exceeds TC max. The outputs automatically recover, when the temperature drops below this limit. Continuous operation under simul­taneous extreme worst-case conditions of the following three parameters should be avoided: Minimum input voltage, maximum output power, and maximum temperature. Output Protection Each output is protected against overvoltages, which could occur due to a failure of the internal control circuit. Voltage suppressor diodes (which under worst case condition may become a short circuit) provide the required protection. The suppressor diodes are not designed to withstand externally applied overvoltages. Overload at any of the outputs will cause a shut-down of all outputs. A red LED indicates the overload condition. Note: Vo BR is specified in Electrical Output Data. If this voltage is exceeded, the suppressor diode generates losses and may become a short circuit. Parallel and Series Connection Single- or double-output models with equal output voltage can be connected in parallel using option T (current sharing). If the T pins are interconnected, all converters share the output current equally. Single-output models and/or main and second outputs of double-output models can be connected in series with any other (similar) output. Notes: – Parallel connection of double-output models should always include both, main and second output to maintain good regulation. – Not more than 5 converters should be connected in parallel. – Series connection of second outputs without involving their main outputs should be avoided, as regulation may be poor. – The maximum output current is limited by the output with the lowest current limitation, if several outputs are connected in series. tech.support@psbel.com belfuse.com/power-solutions BCD20004-G Rev AF, 12-Jul-2018 © 2018 Bel Power Solutions & Protection Page 11 of 36 S Series 100 W DC-DC and AC-DC Converters Vo/Vo nom 0.98 0.5 Io1 IoL 05098a 0 1.0 0.5 Io/Io nom Fig. 8 Output characteristic Vo versus Io (single-output models or double-output models with parallel-connected outputs). Output Voltage Regulation Figure 9 applies to single-output or double-output models with parallel-connected outputs. For independent configuration, output 1 is under normal con­ditions regulated to Vo nom, irrespective of the output currents. Vo2 depends upon the load distribution. If both outputs are loaded with more than 10% of Io nom, the deviation of Vo2 remains within ± 5% of Vo1. Fig. 10 to 12 show the regulation depending on load distribution. Two outputs of a double-output model connected in parallel behave like the output of a single-output model. Note: If output 2 is not used, connect it in parallel with output 1! This ensures good regulation and efficiency. Vo Vo2 [V] Vod Vo ±1 % td Vo ±1 % Io1 = 4.0 A Io1 = 3.1 A Io1 = 2.2 A Io1 = 1.3 A Io1 = 0.4 A 12.50 Vod 12.25 td t Io /Io nom 05136a 12.0 11.75 1 0.5 12.75 11.50 ≥ 10 µs ≥ 10 µs 0 05102c t Fig. 9 Typical dynamic load regulation of Vo. 11.25 0 1 2 3 4 5 Io2 [A] Fig. 10 Models with 2 outputs 12 V: Vo2 versus Io2 with various Io1 (typ) Vo2 [V] Vo2 [V] 16.0 Io1 = 3.2 A Io1 = 2.5 A Io1 = 1.7 A Io1 = 1.0 A Io1 = 0.3 A 15.75 15.5 05137a 05138a 26 Io1 = 2.00 A Io1 = 1.55 A Io1 = 1.10 A Io1 = 0.65 A Io1 = 0.20 A 25.5 25 15.25 24.5 15.0 24 14.75 23.5 14.5 14.25 0 1 2 3 4 23 Io2 [A] 0 Fig. 11 Models with 2 outputs 15 V: Vo2 versus Io2 with various Io1 (typ) 1 2 3 Io2 [A] Fig. 12 Models with 2 outputs 24 V: Vo2 versus Io2 with various Io1 (typ) tech.support@psbel.com belfuse.com/power-solutions BCD20004-G Rev AF, 12-Jul-2018 © 2018 Bel Power Solutions & Protection Page 12 of 36 S Series 100 W DC-DC and AC-DC Converters Auxiliary Functions Inhibit for Remote On/Off The outputs may be enabled or disabled by means of a logic signal (TTL, CMOS, etc.) applied between the inhibit input i (pin 18) and pin 14 (S– or Vo1–). In systems with several converters, this feature can be used to control the activation sequence of the converters. If the inhibit function is not required, connect the inhibit pin 18 with pin 14! Note: If pin 18 is not connected, the output is disabled. Table 7: Inhibit characteristics Characteristics 06031b Conditions Inhibit voltage  Iinh Inhibit current tr Rise time tf Fall time V o = on V o = off Vi min – Vi max typ max -50 0.8 2.4 50 V inh = 0 -400 30 Unit Vo+ V Input V inh min µA Vinh ms Depending on Io Iinh i 18 S–/Vo1– 14 Fig. 13 Definition of Vinh and Iinh. Iinh [mA] 2.0 Vinh = 2.4 V Vinh = 0.8 V Vo /Vo nom 1 06032a 1.6 1.2 0.1 0 0.8 Vo = on 0.4 Vo = off tf tr –0.4 t 0 –40 –20 0 20 t Inhibit 1 0 –0.8 06001 Vinh [V] 40 Fig. 14 Typical inhibit current I inh versus inhibit voltage Vinh Fig. 15 Output response as a function of inhibit control Sense Lines (Single-Output Models) Important: Sense lines must always be connected! Incorrectly connected sense lines may activate the overvoltage protection resulting in a permanent short-circuit of the output. This feature allows for compensation of voltage drops across the connector contacts and if necessary, across the load lines. We recommend connecting the sense lines directly at the female connector. To ensure correct operation, both sense lines (S+, S–) should be connected to their respective power outputs (Vo+ and Vo–), and the voltage difference between any sense line and its respective power output (as measured on the connector) should not exceed the following values: Table 7: Maximum voltage compensation allowed using sense lines Output voltage Total voltage difference between sense lines and their respective outputs Voltage difference between Vo– and S– 5.1 V < 0.5 V < 0.25 V 12 V, 15 V, 24 V < 1.0 V < 0.25 V tech.support@psbel.com belfuse.com/power-solutions BCD20004-G Rev AF, 12-Jul-2018 © 2018 Bel Power Solutions & Protection Page 13 of 36 S Series 100 W DC-DC and AC-DC Converters Programmable Output Voltage (R-Function) As a standard feature, the converters offer an adjustable output voltage, identified by letter R in the type designation. The control input R (pin 16) accepts either a control voltage Vext or a resistor Rext to adjust the desired output voltage. When input R is not connected, the output voltage is set to Vo nom. a) Adjustment by means of an external control voltage Vext between pin 16 (R) and pin 14 (S–): The control voltage range is 0 – 2.75 VDC and allows for an adjustment in the range of approximately 0 – 110% of Vo nom. Vo Vext ≈ –––––– • 2.5 V Vo nom b) Adjustment by means of an external resistor: Depending upon the value of the required output voltage, the resistor shall be connected either: Between pin 16 and pin 14 to achieve an output voltage adjustment range of approximately 0 – 100% of Vo nom. or: Between pin 16 and pin 12 to achieve an output voltage adjustment range of 100 – 110% of Vo nom. 05074a Vi+ R 16 14 S–/Vo1– + – Vext Vi– Vi+ 12 16 14 S+/Vo1+ R S–/Vo1– R'ext Vo2+ 4 Vo2+ 6 Vo2– 8 Vo2– 10 Vo1+ 12 Vo1– 14 R 16 + 06004a 24 V Vo1 30 V 48 V Co – R'ext Rext Rext Vi– Fig. 16 Output voltage control for single-output models Fig. 17 Double-output models: Wiring of the R-input for output voltages 24 V, 30 V, or 48 V with both outputs in series. A ceramic capacitor (Co ) across the load Warnings: – Vext shall never exceed 2.75 VDC. – The value of R’ext shall never be less than the lowest value as indicated in table R’ext (for V0 > V0 nom) to avoid damage to the converter! Notes: – The R-Function excludes option P (output voltage adjustment by potentiometer). If the output voltages are increased above Vo nom via R-input control, option P setting, remote sensing, or option T, the output currents should be reduced, so that Po nom is not exceeded. – With double-output models, the second output follows the voltage of the controlled main output. – In case of parallel connection the output voltages should be individually set within a tolerance of 1 – 2%. Test Sockets Test sockets (pin diameter 2 mm) for measuring the main output voltage Vo or Vo1 are located at the front of the converter. The positive test socket is protected by a series resistor (see: Functional Description, block diagrams). The voltage measured at the test jacks is slightly lower than the value at the output terminals. tech.support@psbel.com belfuse.com/power-solutions BCD20004-G Rev AF, 12-Jul-2018 © 2018 Bel Power Solutions & Protection Page 14 of 36 S Series 100 W DC-DC and AC-DC Converters Table 8a: Rext for Vo < Vo nom; approximate values (Vi nom, Io nom, series E 96 resistors); R’ext = not fitted Vo nom = 5.1 V Vo nom = 12 V Vo [V] R ext [kΩ] 0.5 1.0 1.5 2.0 2.5 3.0 3.5 4.0 4.5 5.0 0.432 0.976 1.65 2.61 3.83 5.76 8.66 14.7 30.1 200 Vo [V] 1 2 3 4 5 6 7 8 9 10 11 Vo nom = 15 V R ext [kΩ] 4 6 8 10 12 14 16 18 20 22 0.806 1.33 2 2.87 4.02 5.62 8.06 12.1 20 42.2 Vo [V] 1 2 4 6 8 9 10 11 12 13 14 Vo nom = 24 V R ext [kΩ] 4 8 12 16 18 20 22 24 26 28 0.619 1.47 2.67 4.53 6.04 8.06 11 16.2 26.1 56.2 Vo [V] 1 4 6 8 10 12 14 16 18 20 22 R ext [kΩ] 8 12 16 20 24 28 32 36 40 44 0.81 1.33 2.0 2.87 4.02 5.62 8.06 12.1 20 44.2 Table 8b: R’ext for Vo > Vo nom; approximate values (Vi nom, Io nom, series E 96 resistors); Rext = not fitted Vo nom = 5.1 V 1 Vo nom = 12 V Vo [V] R ’ext [kΩ] 5.15 5.20 5.25 5.30 5.35 5.40 5.45 5.50 432 215 147 110 88.7 75 64.9 57.6 Vo [V] 1 12.1 12.2 12.3 12.4 12.5 12.6 12.7 12.8 13.0 13.2 Vo nom = 15 V R ’ext [kΩ] 24.2 24.4 24.6 24.8 25.0 25.2 25.4 25.6 26.0 26.4 1820 931 619 475 383 316 274 243 196 169 Vo [V] 1 15.2 15.4 15.6 15.8 16.0 16.2 16.4 16.5 Vo nom = 24 V R ’ext [kΩ] 30.4 30.8 31.2 31.6 32.0 32.4 32.8 33.0 1500 768 523 392 316 267 232 221 Vo [V] 1 24.25 24.50 24.75 25.00 25.25 25.50 25.75 26.00 26.25 26.40 R ’ext [kΩ] 48.5 49.0 49.5 50.0 50.5 51.0 51.5 52.0 52.5 52.8 3320 1690 1130 845 698 590 511 442 402 383 First column: Vo or Vo1; second column: double-output models with series-connected outputs Display Status of LEDs Vo1 > 0.95 to 0.98Vo1 adj 06002_011106 OK i Io L Vi uv Vi min Vi max Vi ov Vo1 > 0.95 to 0.98Vo1 adj Vi Vi abs LEDs “OK ”, “i ” and “Io L” status versus input voltage Conditions: Io ≤ Io nom, TC ≤ TC max, Vinh ≤ 0.8 V Vi uv = undervoltage lock-out, Vi ov = overvoltage lock-out Vo1 < 0.95 to 0.98Vo1 adj OK Io L Io nom IoL Io LEDs “OK” and “Io L” status versus output current Conditions: Vi min – Vi max, TC ≤ TC max, Vinh ≤ 0.8 V TC LED “i ” versus case temperature Conditions: Vi min – Vi max , Io ≤ Io nom, Vinh ≤ 0.8 V Vi inh LED “i ” versus Vinh Conditions: Vi min – Vi max, Io ≤ Io nom, TC ≤ TC max i TC max TPTC threshold Vinh threshold i -50 V LED off +0.8 V +2.4 V LED Status undefined +50 V LED on Fig. 18 LED indicators tech.support@psbel.com belfuse.com/power-solutions BCD20004-G Rev AF, 12-Jul-2018 © 2018 Bel Power Solutions & Protection Page 15 of 36 S Series 100 W DC-DC and AC-DC Converters Battery Charging / Temperature Sensor All converters with an R-input are suitable for battery charger applications, but we recommend choosing the models especially designed for this application DS/LS1740 or DS/LS2740; see Model Selection. For optimal battery charging and life expectancy of the battery an external temperature sensor can be connected to the R-input. The sensor is mounted as close as possible to the battery and adjusts the output voltage according to the battery temperature. Depending upon cell voltage and the temperature coefficient of the battery, different sensor types are available, see Accessories. Cell voltage [V] 2.45 Input Power supply 03099d Vo+ Vo– Load R 06139b 2.40 2.35 2.30 2.25 + – Temperature sensor + Battery 2.20 2.15 Vo safe 2.10 –20 –10 0 10 VC = 2.27 V, –3 mV/K VC = 2.23 V, –3 mV/K Fig. 19 Connection of a temperature sensor 20 30 40 50 °C VC = 2.27 V, –3.5 mV/K VC = 2.23 V, –3.5 mV/K Fig. 20 Trickle charge voltage versus temperature for defined temp. coefficient. Vo nom is the output voltage with open R-input. tech.support@psbel.com belfuse.com/power-solutions BCD20004-G Rev AF, 12-Jul-2018 © 2018 Bel Power Solutions & Protection Page 16 of 36 S Series 100 W DC-DC and AC-DC Converters Electromagnetic Compatibility (EMC) A metal oxide VDR together with the input fuse and an input filter form an effective protection against high input transient voltages, which typically occur in most installations. The con­verters have been successfully tested to the following specifications: Electromagnetic Immunity Table 9: Electromagnetic immunity (type tests) Phenomenon Standard Supply related surge RIA 12 3 Level Value applied Waveform 3.5 VBat 2/20/2 ms 1.5 VBat 0.1/1/0.1 s C 960 Vp 10/100 μs D3 1800 Vp 5/50 μs 3600 Vp 0.5/5 μs 4800 Vp 0.1/1 μs 8400 Vp 0.05/0.1 μs 1800 Vp 5/50 μs 3600 Vp 0.5/5 μs 4800 Vp 0.1/1 μs 8400 Vp 0.05/0.1 μs A4 B Direct transients E Coupling mode 1 +i/–i +i/–i, –i/c F G Indirect couples transients 3 H J K +o/c, –o/c L Electrostatic discharge (to case) IEC/EN 61000-4-2 Electromagnetic field  IEC/EN 61000-4-3 45 x6 contact discharge ±8000 Vp air discharge ±15000 Vp antenna 20 V/m 1/50 ns AM 80% / 1 kHz Source imped. Test procedure In oper. Perf. crit. 2 0.2 Ω 1 positive surge yes A 5 pos. & 5 neg. yes B 10 pos. & 10 neg. discharges yes A 80 – 1000 MHz yes A yes A 60 s positive 60 s negative transients per coupling mode yes A 2Ω 5 pos. & 5 neg. surges per coupling mode yes A 150 Ω 0.15 – 80 MHz yes A 5Ω 100 Ω 330 Ω 150 pF N/A 20 V/m 800 – 1000 MHz 10 V/m 1400 – 2000 MHz 7 antenna 3 capacitive, o/c ±2000 Vp 48 ±i/c, +i/–i direct ±4000 Vp ±i/c ±2000 Vp +i/– i ±1000 Vp 5 V/m AM 80% / 1 kHz N/A 3 V/m Electrical fast transients / burst Surges Conducted disturbances IEC/EN 61000-4-4 IEC/EN 61000-4-5 IEC/EN 61000-4-6 39 3 10 i, o, signal wires 10 VAC (140 dBµV) 2000 – 2500 MHz 5100 – 6000 MHz bursts of 5/50 ns; 2.5 / 5 kHz over 15 ms; burst period: 300 ms 1.2 / 50 µs AM 80% / 1 kHz 50 Ω 12 Ω i = input, o = output, c = case A = normal operation, no deviation from specs.; B = temporary loss of function or deviation from specs possible 3 RIA 12 covers or exceeds IEC 60571-1 and EN 50155:2017. Surge D corresponds to EN 50155:2017, waveform A; surge G corres­ponds to EN 50155:2001, waveform B 4 Only met with extended input voltage range of CS (for 48 V battery) and ES (for 110 V battery) model types. Such CS models are available on customer’s request. Standard DS models types (on 110 V battery) will shut down during the surge and recover automatically. 5 Exceeds EN 50121-3-2:2015 table 6.3 and EN 50121-4:2016 table 2.4. 6 Corresponds to EN 50121-3-2:2015 table 6.1 and exceeds EN 50121-4:2016 table 2.1. 7 Corresponds to EN 50121-3-2:2015 table 6.2 and EN 50121-4:2016 table 2.2 (compliance with digital communication devices). 8 Corresponds or exceeds EN 50121-3-2:2015 table 4.2 and EN 50121-4:2016 table 4.2. 9 Covers or exceeds EN 50121-3-2:2015 table 4.3 and EN 50121-4:2016 table 4.3. 10 Corresponds to EN 50121-3-2:2015 table 4.1 and EN 50121-4:2016 table 4.1 (radio frequency common mode). 1 2 tech.support@psbel.com belfuse.com/power-solutions BCD20004-G Rev AF, 12-Jul-2018 © 2018 Bel Power Solutions & Protection Page 17 of 36 S Series 100 W DC-DC and AC-DC Converters Electromagnetic Emissions dBµV 80 dBµV 80 CS1601-7R, Peak Vi+, Conducted 0,15 ÷ 30 MHz, Divina, 2006-10-01 70 70 EN 55022 B 60 50 40 40 30 30 20 20 10 10 0.2 0.5 1 2 5 10 20 MHz Fig. 21a Typical conducted emissions (peak) at the positive input according to EN 55011/32, measured at Vi nom and Io nom (CS1601-7R) dBµV/m 50 EN 55022 B 60 50 0 LS1301-7R, Peak Vi+, Conducted 0,15 ÷ 30 MHz, Divina, 2006-11-01 0 0.2 1 2 5 10 20 MHz Fig. 21b Typical conducted emissions (peak) at the positive input according to EN 55 011/32, measured at Vi nom and Io nom (LS1301-7R). dBµV/m TÜV-Divina, Testdistance 10 m, 2006-10-01 CS1601-7R U i =110 V, U o =12 V I o = 8 A 0.5 TÜV-Divina, QP, 2006-11-01 Testdistance 10 m, LS1301-7R, U 50 o =12 V I o = 8 A EN 55011 A JM061 40 EN 55022 B 30 30 20 20 10 10 0 30 50 100 200 500 1000 MHz Fig. 22a Radiated emissions according to EN 55011/32, antenna 10 m distance, measured at Vi nom and Io nom (CS1601-7R) 0 30 JM057 40 50 100 200 500 1000 MHz Fig. 22b Radiated emissions according to EN 55011/32, antenna 10 m distance, measured at Vi nom and Io nom (LS1301-7R) tech.support@psbel.com belfuse.com/power-solutions BCD20004-G Rev AF, 12-Jul-2018 © 2018 Bel Power Solutions & Protection Page 18 of 36 S Series 100 W DC-DC and AC-DC Converters Immunity to Environmental Conditions Table 10: Mechanical and climatic stress Test method Standard Test Conditions Cab Damp heat steady state IEC/EN 60068-2-78 MIL-STD-810D section 507.2 Temperature: 40 °C Relative humidity: 93 +2/-3 % Duration: 56 days Salt mist, cyclic sodium chloride (NaCl) solution IEC/EN 60068-2-52 Concentration: 5% (30 °C) for 2 h Storage: 40 °C, 93% rel. humidity Duration: 3 cycles of 22 h Vibration (sinusoidal) IEC/EN 60068-2-6 MIL-STD-810D section 514.3 Acceleration amplitude: 0.35 mm (10 – 60 Hz) Kb Fc Fh Ea - - Converter not operating Converter not operating 5 gn = 49 m/s2 (60 - 2000 Hz) Frequency (1 Oct/min): 10 – 2000 Hz Test duration: 7.5 h (2.5 h in each axis) Acceleration spectral density: 0.05 gn2/Hz Frequency band: 8 – 500 Hz Acceleration magnitude: 4.9 gn rms Random vibration broad band (digital control) & guidance IEC/EN 60068-2-64 Test duration: 1.5 h (0.5 h in each axis) Shock (half-sinusoidal) IEC/EN 60068-2-27 MIL-STD-810D section 516.3 Acceleration amplitude: 50 gn = 490 m/s2 Bump duration: 11 ms Number of bumps: 18 (3 in each direction) Shock EN 50155:2007 clause 12.2.11, EN 61373 sect. 10, class B, body mounted 1 Acceleration amplitude: 5.1 gn Bump duration: 30 ms Number of bumps: 18 (3 in each direction) EN 50155:2007 clause 12.2.11, EN 61373 sect. 8 and 9, class B, body mounted 1 Acceleration spectral density: 0.02 g n2/Hz Frequency band: 5 – 150 Hz Acceleration magnitude: 0.8 g n r ms Test duration: 15 h (5 h in each axis) Simulated long life testing at increased random vibration levels 1 Status ±2 Converter operating Converter operating Converter operating Converter operating Converter operating Body mounted = chassis of a railway coach Temperatures Table 11: Temperature specifications, valid for an air pressure of 800 – 1200 hPa (800 – 1200 mbar) Model -5 2 Characteristics TA Ambient temperature TC Case temperature 1 TS Storage temperature 1 2 Conditions min Converter operating Not operating -6 2 max min - 25 50 - 25 85 1 - 40 85 -7 (option) max min - 25 60 - 25 90 1 - 40 85 -9 Unit max min max - 25 71 - 40 71 - 25 95 1 - 40 95 1 - 40 85 - 55 85 °C Overtemperature lockout at TC > 95 °C Customer-specific models Reliability and Device Hours Table 12: MTBF calculated according to MIL-HDBK 217F Ratings at specified Model case temperature MTBF 1 AS – LS Device hours 2 AS – LS Ground benign Ground fixed Ground mobile 40 °C 40 °C 70 °C 50 °C 500 000 150 000 80 000 50 000 500 000 Unit h Calculated according to MIL-HDBK-217F-N2 Statistic values, based on an average of 4300 working hours per year, over 3 years in general field use. 1 2 tech.support@psbel.com belfuse.com/power-solutions BCD20004-G Rev AF, 12-Jul-2018 © 2018 Bel Power Solutions & Protection Page 19 of 36 S Series 100 W DC-DC and AC-DC Converters Mechanical Data Dimensions in mm. The converters are designed to be inserted into a 19” rack, 160 mm long, according to IEC 60297-3. 7 TE 5 M4 09004f 7.0 10.3 12.1 20.3 30.3 (171.0 to 171.9) 50 5 TE 3.27 29.9 19.7 Option P (Vo) Option D (Vto) Option D (Vti ) LED i (red) 9.5 4.5 LED OK (green) LED IoL (red) = Ø 3.5 = Ø 4.1 51.5 Measuring point of case temperature TC 111 (3U) 100 Test sockets (+/–) 5 d 8 152 8 60 Front plate Main face 168.5 Back plate Ø 5 x 90° 25.9 Ø 2.8 0.2 11.8 = Ø 4.1 = Ø 3.5 Screw holes of the frontplate European Projection Fig. 23 Aluminum case S02 with heat sink; black finish (EP powder coated); weight approx. 1.25 kg Notes: – d ≥ 15 mm, recommended minimum distance to next part in order to ensure proper air circulation at full output power. – free air location: the converter should be moun­ted with fins in a vertical position to achieve maximum airflow through the heat sink. tech.support@psbel.com belfuse.com/power-solutions BCD20004-G Rev AF, 12-Jul-2018 © 2018 Bel Power Solutions & Protection Page 20 of 36 S Series 100 W DC-DC and AC-DC Converters 7 TE 50 38.5 5 11.8 5 158 4 TE 3.27 09003b 101 111 (3U) M4 Measuring point of case temperature TC 17.3 5 47.2 133.4 168 (171.0 ... 171.9) 47.2 6.5 6.5 5 38.5 11027 11.2 Fig. 24 Option B1: Aluminum case S02 with small cooling plate; black finish (EP powder coated). Suitable for mounting with access from the backside. Total weight approx. 1.2 kg. 13 140 127 11.8 17.3 133.4 ±0.2 168 30 European Projection Fig. 25 Option B: Aluminum case S02 with large cooling plate; black finish (EP powder coated). Suitable for front mounting. Total weight approx. 1.3 kg Note: Long case with option B2, elongated by 60 mm for 220 mm rack depth, is available on request (no LEDs, no test sockets). tech.support@psbel.com belfuse.com/power-solutions BCD20004-G Rev AF, 12-Jul-2018 © 2018 Bel Power Solutions & Protection Page 21 of 36 S Series 100 W DC-DC and AC-DC Converters Safety and Installation Instructions Connector Pin Allocation The connector pin allocation table defines the electrical potentials and the physical pin positions on the H15 connector. The protective earth is connected by a leading pin (no. 24), ensuring that it makes contact with the female connector first. 10090a Fixtures for connector retention clips V (see Accessories) 32 4 Type H15 Fig. 26 View of the connector (male contacts) Table 13: H15 connector pin allocation Pin No. Connector type H15 single-output models double-output models 4 Vo+ Vo2+ 6 Vo+ VoVo- 12 S+ Positive Sense Vo1+ Positive Output 1 14 S- Negative Sense Vo1- Negative Output 1 16 R Control of Vo R Control of Vo1 18 i Inhibit i Inhibit D3 Save data T5 Current sharing D 1 3 28 30 32 3 4 5 Save data V3 ACFAIL T5 Current sharing 24 2 26 Negative Output 1 Vo2- Positive Output 2 8 22 2 Vo2+ 10 20 1 Positive Output 1 Vo2- 1 Protective earth Vi+ N ~ 4 Vi- L~ 4 Positive Input Neutral line 4 Negative Input Phase line 4 Negative Output 2 Protective earth Vi+ N ~ 4 Vi- L~ 4 Positive Input Neutral line 4 Negative Input Phase line 4 Not connected, if option P is fitted. Leading pin (pre-connecting) Option D excludes option V and vice versa. Pin 20 is not connected, unless option D or V is fitted. LS models Only connected, if option T is fitted. Installation Instructions Note: These converters have no power factor correction (PFC). The LS4000/5000 models are intended to replace the LS1000 and LS2000 converters in AC applications to comply with IEC/EN 61000-3-2. The converters are components, intended exclusively for inclusion within other equipment by an industrial assembly operation or by professional installers. Installation 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. Connection to the system shall be made via the female connector H15; see Accessories. Other installation methods may not meet the safety requirements. tech.support@psbel.com belfuse.com/power-solutions BCD20004-G Rev AF, 12-Jul-2018 © 2018 Bel Power Solutions & Protection Page 22 of 36 S Series 100 W DC-DC and AC-DC Converters Pin no. 24 ( ) is connected with the case. For safety reasons it is essential to connect this pin reliably to protective earth. The input pins 30/32 (Vi– or L~) are connected via a built-in fuse, which is designed to protect in the case of a converter failure. An additional external fuse, suitable for the application, might be necessary in the wiring to the other input 26 /28 (Vi+ or N~) or even to pins 30/32, particularly if: • Local requirements demand an individual fuse in each source line • Phase and neutral of the AC mains are not defined or cannot be assigned to the corresponding terminals. • Neutral and earth impedance is high or undefined. Notes: – If the inhibit function is not used, pin no. 18 (i) shall be connected with pin no. 14 to enable the output(s). – Do not open the converter, or warranty will be invalidated. – Due to high current values, the converters provide two internally parallel connected contacts for certain paths (pins 4/6, 8/10, 26/28 and 30/32). It is recommended to connect both female connector pins of each path in order to keep the voltage drop low and avoid excessive connector currents. – If the second output of double-output models is not used, connect it parallel with the main output. Make sure that there is sufficient airflow available for convection cooling and verify it by measuring the case temperature TC , when the converter is installed and operated in the end-use application; see Thermal Consider­ations. Ensure that a converter failure (e.g., an internal short-­circuit) does not result in a hazardous condition. Standards and Approvals The converters are safety-approved according to the latest edition of IEC/EN 60950-1 and UL/CSA 60950-1. The converters correspond to Class I equipment and have been evaluated for: • Building-in • Basic insulation between input and case based on 250 VAC, and double or reinforced insulation between input and output(s) • Functional insulation between outputs • Overvoltage category II • Pollution degree 2 environment • Max. altitude: 2000 m • The converters fulfil the requirements of a fire enclosure. The converters are subject to manufacturing surveillance in accordance with the above mentioned standards and ISO 9001:2015. A CB-scheme is available. Railway Applications and Fire Protection The converters have been designed by observing the railway standards EN 50155, EN 50121-3-2, and EN 50121-4. All boards are coated with a protective lacquer. The converters with version V108 (or later) comply with NF-F16 (I2/F1). They also comply with EN 45545-1, EN 45545-2 (2016), if installed in a technical compartment or cabinet. Protection Degree and Cleaning Liquids Condition: Female connector fitted to the converter. • IP 30: All models except those with option P, and except those with option D or V including a potentiometer. • IP 20: All models fitted with option P, or with option D or V with potentiometer. In order to avoid damage, any penetration of cleaning fluids has to be prevented, since the power supplies are not hermetically sealed. Isolation and Protective Earth The electric strength test is performed in the factory as routine test according to EN 50514 and IEC/EN 60950 and should not be repeated in the field. The company will not honor warranty claims resulting from incorrectly executed electric strength tests. The resistance of the earth connection to the case (300 >300 Creepage distances ≥ 3.2 3 --- Electric strength test >100 kVAC MΩ 2 --- mm According to EN 50514 and IEC/EN 60950, subassemblies connecting input to output are pre-tested with 5.6 kVDC or 4 kVAC. Tested at 150 VDC 3 Input to outputs: 6.­­4 mm 1 2 Leakage Currents Leakage currents flow due to internal leakage capacitances and Y-capacitors. The current values are proportional to the supply voltage and are specified in the table below. Table 15: Earth leakage currents for LS models Characteristics Class I Max. leakage current Permissible accord. to IEC/EN 60950 3.5 Typ. value at 264 V, 50 Hz 1.43 Unit mA LS Models Operated at Greater than 63 Hz Above 63 Hz, the earth leakage current may exceed 3.5 mA, the maximum value allowed in IEC 60950. Frequencies ≥ 350 Hz are only permitted with Vi ≤ 200 VAC. The built-in Y-caps are approved for ≤100 Hz. Safety approvals and CB scheme cover only 50 – 60 Hz. Safety of Operator-Accessible Output Circuits If the output circuit of a DC-DC converter is operator-accessible, it shall be an SELV circuit according to the standard IEC 60950-1. The following table shows some possible installation configurations, compliance with which causes the output circuit of the converter to be an SELV circuit according to IEC 60950-1 up to a configured output voltage (sum of nominal voltages if in series or +/– configuration) of 36 V. However, it is the sole responsibility of the installer to assure the compliance with the applicable safety regulations. ≤150 VAC or VDC for AS, BS ≤250 VAC or VDC for CS, DS, ES, FS, LS Mains AC-DC front end + 10044a Fuse Battery Fuse + DC-DC converter SELV – ≤150 VAC or VDC for AS, BS ≤250 VAC or VDC for CS, DS, ES, FS, LS Earth connection Fig. 27 Schematic safety concept. Use earth connections as per the table below. tech.support@psbel.com belfuse.com/power-solutions BCD20004-G Rev AF, 12-Jul-2018 © 2018 Bel Power Solutions & Protection Page 24 of 36 S Series 100 W DC-DC and AC-DC Converters Table 16: Safety concept leading to an SELV output circuit Conditions Front end DC-DC converter Result Nominal supply voltage Minimum required grade of insulation, to be provided by the AC-DC front end, including mains supplied battery charger Nominal DC output voltage from the front end Minimum required safety status of the front end output circuit Types Measures to achieve the specified safety status of the output circuit Safety status of the DC-DC converter output circuit Mains ≤150 VAC Functional (i.e. there is no need for electrical insulation between the mains supply voltage and the DC-DC converter input voltage) ≤ 100 V (The nominal voltage between any input pin and earth can be up to 150 VAC or DC) Primary circuit AS BS Double or reinforced insulation, based on the mains voltage and 2 (provided by the DC-DC converter) and earthed case 3 SELV circuit Basic ≤ 400 V Mains ≤ 250 VAC ≤ 400 V (The nominal voltage between any input pin and earth can be up to 250 VAC or 400 VDC) CS DS ES FS Unearthed hazardous voltage secondary circuit Earthed hazardous voltage secondary circuit Double or reinforced 3 4 1 2 AS BS CS DS ES FS Supplementary insulation, based on 250 VAC and double or reinforced insulation 2 (provided by DC-DC converter) and earthed case 3. Double or reinforced insulation 2 (provided by the DC-DC converter) earthed case 3 ≤ 60 V SELV circuit Functional insulation (provided by the DC-DC converter) earthed case 4 ≤ 120 V TNV-3 circuit Basic insulation (provided by the DC-DC converter) 4 The front end output voltage should match the specified input voltage range of the DC-DC converter. Based on the maximum nominal output voltage from the front end. The earth connection has to be provided by the installer according to the relevant safety standard, e.g. IEC/EN 60950-1. Earthing of the case is recommended, but not mandatory. If the output circuit of an AC-DC converter is operator-accessible, it shall be an SELV circuit accord. to IEC 60950-1. The following table shows some possible installation configurations, compliance with which causes the output circuit of LS models to be SELV according to IEC 60950-1 up to a configured output voltage (sum of nominal voltages if in series or +/– configuration) of 36 V. If the LS converter is used as DC-DC converter, refer to the previous section. Mains ~ ~ Fuse Fuse Earth connection 10021a + AC-DC converter SELV – Fig. 28 Schematic safety concept. Use earth connection as per table 17. Use fuses if required by the application; see also Install. Instructions. Table 17: Safety concept leading to an SELV output circuit Conditions AC-DC converter Installation Result Nominal voltage Grade of insulation between input and output provided by the AC-DC converter Measures to achieve the resulting safety status of the output circuit Safety status of the AC-DC converter output circuit Mains ≤ 250 VAC Double or reinforced Earthed case1 and installation according to the applicable standards SELV circuit 1 The earth connection has to be provided by the installer according to the relevant safety standards, e.g. IEC/EN 60950. tech.support@psbel.com belfuse.com/power-solutions BCD20004-G Rev AF, 12-Jul-2018 © 2018 Bel Power Solutions & Protection Page 25 of 36 S Series 100 W DC-DC and AC-DC Converters Description of Options Table 18: Survey of options Option Function of option Characteristics -7 Extended operational ambient temperature range TA = – 25 to 71 °C E Electronic inrush current limitation circuitry Active inrush current limitation P Potentiometer for fine adjustment of output voltage Adjustment range +10/– 60% of Vo nom, excludes R-input D1 Input and/or output undervoltage monitoring circuitry Safe data signal output (D0 – DD) V Input and/or output undervoltage monitoring circuitry ACFAIL signal according to VME specifications (V0, V2, V3) Current sharing Interconnect T-pins for parallel connection (max 5 converters) Cooling plate (160 or 220 mm long) Replaces the standard heat sink, allowing direct chassis-mounting RoHS-compliant for 5 substances Tin-lead solder 2 1 T B, B1, B2 non-G Option D excludes option V and vice versa; option V only for 5.1 V outputs. Option P is not available for battery charger models. 1 2 -7  Temperature Range Option -7 designates converters with an operational ambient temperature range of – 25 to 71 °C. Not for new designs. E  Inrush Current Limitation CS/DS/ES/FS/LS models may be supplemented by an electronic circuit (option E) replacing the standard built-in NTC resistor) in order to achieve an enhanced inrush current limiting function. Option E is not available with AS/BS models, but mandatory for all CS/DS/ES/FS/LS models with option -9. The figure below shows two consecutive peaks of the inrush current, the first one is caused by Vi /Rv and the second one by the rising current across the FET. The shape of the curve depends on model, but the tables below show the higher of both peaks. CS models fitted with option E and option D6 (input voltage monitor) meet the standard ETS 300132-2 for 48 VDC supplies. Option D6 is necessary to disable the converter at low input voltage, such avoiding an excessive input current. Connect output D (pin 20) with inhibit (pin 18). Option D6 should be adjusted with the potentiometer to a threshold of 36 – 40.5 V for 48 V batteries and to 44 – 50 V for 60 V batteries. Refer also to the description of option D. Note: Subsequent switch-on cycles at start-up are limited to max. 10 cycles during the first 20 seconds (cold converter) and then to max. 1 cycle every 8 s. LS models powered by 230 VAC / 50 Hz exhibit an inrush current as per the fig. below, when switched on at the peak of Vi. In this case, the inrush current I inr p is 21.7 A and its duration tinr is 5 ms. This is the worst case. If the LS converter is switched on in a different moment, Iinr p is much lower, but tinr rises up to 10 ms. JM060 Capacitor Ci fully charged Vi /Rv Control + FET RS Ri Fig. 29 Block diagram of option E Current limiting resistance Rv = RS + Ri = 15 Ω Ci Normal operation (FET fully conducting) Converter Input Filter LS models Iinr [A] Ii = Pi /Vi 0 11039a tinr 0 t [ms] Fig. 30 Inrush current with option E (DC supply) 2 different wafe shapes depending on model tech.support@psbel.com belfuse.com/power-solutions BCD20004-G Rev AF, 12-Jul-2018 © 2018 Bel Power Solutions & Protection Page 26 of 36 S Series 100 W DC-DC and AC-DC Converters Table 19 a: Inrush current at Vi nom (DC supply) and I o nom Characteristics FS CS DS Table 19 b: Inrush current at Vi max (DC supply) and I o nom ES LS Unit Characteristics FS CS DS ES LS Unit V Input voltage 50 60 110 220 310 V Vo max Input voltage 100 140 220 385 372 Iinr p Peak inrush current 7.5 6.5 7.4 14.6 21 A Iinr p Peak inrush current 10 9 14.5 25.7 24.8 A tinr Inrush current duration 20 25 14 16 12 ms tinr Inrush current duration 26 30 14 12 16 ms Vo nom Ii [A] 20 15 Capacitor Ci fully charged 10 Normal operation (FET fully conducting) 5 0 –5 –10 tinr –15 0 20 40 10065a 60 t [ms] 80 Fig. 31 Inrush current for LS models with option E (AC supply), Vi = 230 VAC, f i = 50 Hz, Po = Po nom P Potentiometer A potentiometer provides an output voltage adjustment range of +10/– 60% of Vo nom. It is accessible through a hole in the front cover. Option P is not available for battery charger models and is not recommended for converters connected in parallel. Option P excludes the R-function. With double-output models, both outputs are influenced by the potentiometer setting (doubling the voltage, if the outputs are in series). Note: If the output voltages are increased above Vo nom via R input control, option P setting, remote sensing, or option T, the output current(s) should be reduced, so that Po nom is not exceeded. T  Current Sharing This option ensures that the output currents are approximately shared between all parallel-connected converters, hence increasing system reliability. To use this facility, simply interconnect the T pins of all converters and make sure that the reference for the T signal, pin 14 (S– or Vo1–), are also connected together. The load lines should have equal length and cross section to ensure equal voltage drops. Not more than 5 converters should be connected in parallel. The R pins should be left open-circuit. If not, the output voltages must be individually adjusted prior to paralleling within 1 to 2% or the R pins should be con­­nected together. Note: Parallel connection of con­verters with option P is not recom­men­ded. tech.support@psbel.com belfuse.com/power-solutions BCD20004-G Rev AF, 12-Jul-2018 © 2018 Bel Power Solutions & Protection Page 27 of 36 S Series 100 W DC-DC and AC-DC Converters Vo+ 11003a Load Vo– Vo+ Vo– Vo+ Vo– Fig.32 Example of poor wiring for parallel connection (unequal length of load lines) 11036b Vo+ 2 1 S+ Converter 11037b T Vo2+ 1 Vo2– S– T Converter Vo– Vo1+ Vo1– Load Vo+ 2 Load S+ Converter T Vo2+ 1 Vo2– S– Vo– Power bus + – T Converter 1 Vo1+ Vo1– Max. 5 converters in parallel connection 1 Lead lines should have equal length and cross section, and should run in the same cable loom. Max. 5 converters in parallel connection 2 Diodes recommended in redundant operation only Fig. 33 Parallel connection of single-output models using option T with the sense lines connected at the load Fig. 34 Parallel connection of double-output models with the outputs connected in series, using option T. The signal at the T pins is referenced to Vo1–. D Undervoltage Monitor The input and/or output undervoltage monitor operates in­dependently of the built-in input undervoltage lockout circuit. A logic “low” signal (output with self-conducting JFET) or “high” signal (NPN open-collector output) is generated at the D output (pin 20), when one of the monitored voltages drops below the preselected threshold level V t. This signal is referenced to S– / Vo1–. The D output recovers, when the monitored voltages exceed Vt + Vh. The threshold levels Vti and Vto are either adjusted by a potentio­meter, accessible through a hole in the front cover, or adjusted in the factory to a fixed value specified by the customer. Option D exists in various versions D0 – DD, as shown in table 21. D0 and D9 are adjusted according to customer’s request and receive a customer-specific model number. tech.support@psbel.com belfuse.com/power-solutions BCD20004-G Rev AF, 12-Jul-2018 © 2018 Bel Power Solutions & Protection Page 28 of 36 S Series 100 W DC-DC and AC-DC Converters Output type Monitoring Minimum adjustment range of threshold level Vt Typ. hysteresis Vho [% of Vt ] for Vt min – Vt max Number of potentiometers JFET NPN Vi Vo or Vo1 Vt i Vt o Vhi Vho D1 D5 no yes --- 3.5 V – Vo BR 1 --- 2.5 – 0.6 V 1 D2 D6 yes no Vi min – Vi max D3 D7 yes yes Vi min – Vi max 1 D4 D8 no yes --- D0 5 D9 5 no yes --- yes no Vi min – Vi max yes yes Vi min – Vi max 3, 4 yes yes Vi min – Vi max 3, 4 yes yes --- DD --- 3.4 – 0.4 V --- 1 (0.95 – 0.985 Vo) 2 3.4 – 0.4 V “0” 1 (0.95 – 0.985 Vo) 1 Vi min – Vi max “0” --- --- 2.5 – 0.6 V --- --- 3.4 – 0.4 V --- 3.5 V – Vo BR 3, 4 3.4 – 0.4 V 2.5 – 0.6 V (0.95 – 0.985 Vo) 2 3.4 – 0.4 V “0” 3.5 V – Vo BR 1 3.4 – 0.4 V 2.5 – 0.6 V 3, 4 1 --- 3.5 V – Vo BR 3 2 2 Threshold level adjustable by potentiometer; see Electrical Output Data for Vo BR. Fixed value. Tracking if Vo/Vo1 is adjusted via R-input, option P, or sense lines. 3 The threshold level permanently adjusted according to customer specification ±2% at 25 °C. Any value within the specified range is basically possible, but causes a special type designation in addition to the standard option designations (D0/D9). See Electrical Output Data for Vo BR. 4 Adjustment at Io nom. 5 Customer-specific part number 1 2 JFET output (D0 – D4): Pin D is internally connected via the drain-source path of a JFET (self-conducting type) to the negative potential of output 1. VD ≤ 0.4 V (logic low) corresponds to a monitored voltage level (Vi and/or Vo1)  Vt + Vh. The current ID through the open collector should not exceed 20 mA. The NPN output is not protected against external overvoltages. VD should not exceed 40 V. Table 21: JFET output (D0 – D4) Table 22: NPN output (D5 – DD) Vb, Vo1 status D output, VD Vb, Vo1 status D output, VD Vb or Vo1 < Vt low, L, VD ≤ 0.4 V at I D = 2.5 mA Vb or Vo1 < Vt high, H, I D ≤ 25 µA at VD = 40 V Vb and Vo1 > Vt + Vh high, H, ID ≤ 25 µA at VD = 5.25 V Vb and Vo1 > Vt + Vh low, L, VD ≤ 0.4 V at ID = 20 mA 11007a 11006a Vo+/Vo1+ Vo+/Vo1+ Self-conducting junction FET 20 D VD 14 Rp NPN open collector 20 D VD 14 S–/Vo1– Fig. 35 Option D0 – D4: JFET output, I D ≤ 2.5 mA Rp ID Input Input ID S–/Vo1– Fig. 36 Option D5 – DD: NPN output, Vo ≤ 40, ID ≤ 2.5 mA Threshold tolerances and hysteresis: If Vi is monitored, the internal input voltage after the input filter is measured. Consequently this voltage differs from the voltage at the connector pins by the voltage drop ∆V ti across the input filter. The threshold levels of the D0 and D9 options are factory adjusted at nominal output current Io nom and TA = 25 °C. The value of ∆V ti depends upon input voltage range (CK, DK, ..), threshold level Vt, temperature, and input current. The input current is a function of the input voltage and the output power. tech.support@psbel.com belfuse.com/power-solutions BCD20004-G Rev AF, 12-Jul-2018 © 2018 Bel Power Solutions & Protection Page 29 of 36 S Series 100 W DC-DC and AC-DC Converters VD ∆Vti Vhi 11021a Po = Po nom Po = 0 Po = 0 Po = Po nom VD high VD low Vi Vti Fig. 37 Definition of Vti, ∆Vt i and ∆Vhi (JFET output) Table 23: D-output logic signals Version of D Vi < Vt or Vo < Vt Vi > Vt + Vh or Vo > Vt Configuration D1, D2, D3, D4, D0 low high JFET D5, D6, D7, D8, D9, DD high low NPN tech.support@psbel.com belfuse.com/power-solutions BCD20004-G Rev AF, 12-Jul-2018 © 2018 Bel Power Solutions & Protection Page 30 of 36 S Series 100 W DC-DC and AC-DC Converters Input voltage monitoring NPN VD VD high 11008a 3 VD low 3 3 3 t 0 ID ID high ID low 0 t JFET VD VD high VD low 0 th1 Vo1 Vo1 nom 1 0.95 t tlow min4 tlow min4 tlow min4 thigh min th1 0 t Vi [VDC] Vti+Vhi Vti 0 Input voltage failure Input voltage sag Switch-on cycle t Switch-on cycle and subsequent input voltage failure Output voltage monitoring NPN VD VD high 2 3 3 VD low t 0 ID 1 Hold-up time see Electrical Input Data 2 With output voltage monitoring, hold-up time t = 0 h ID high 3 The signal remains high, if the D output is connected ID low 0 t to an external source 4 t l ow min = 100 – 170 ms, typ. 130 ms JFET VD VD high VD low 0 t tlow min4 Vo1 Vo1 nom Vto+Vho Vto t 0 Output voltage failure Fig. 38 Relationship between Vi, Vo, V D, Vo /Vo nom versus time Table 24: Option V: Factory potentiometer setting of Vti with resulting hold-up time Model AK BK FK CK DK EK LK Unit Vt i 9.5 19.5 39 39 61 97 120 VDC th 0.1 0.1 3.4 1.1 1.1 2.7 4.2 ms tech.support@psbel.com belfuse.com/power-solutions BCD20004-G Rev AF, 12-Jul-2018 © 2018 Bel Power Solutions & Protection Page 31 of 36 S Series 100 W DC-DC and AC-DC Converters V ACFAIL signal (VME) Available for units with Vo nom = 5.1 V only. This option defines an undervoltage monitoring circuit for the input or for the input and main output voltage ( 5.1 V) similar to option D and generates an ACFAIL signal (V signal), which conforms to the VME standard. The low state level of the ACFAIL signal is specified at a sink current of I V ≤ 48 mA to VV ≤ 0.6 V (open-collector output of an NPN transistor). The pull-up resistor feeding the open-collector output should be placed on the VME back plane. After the ACFAIL signal has gone low, the VME standard requires a hold-up time t h of at least 4 ms, before the 5.1 V output drops to 4.875 V, when the output is fully loaded. This hold-up time th is provided by the internal input capacitance. Consequently the working input voltage and the threshold level Vti should be adequately above Vi min of the converter, so that enough energy is remaining in the input capacitance. If V i is below the required level, an external hold-up capacitor (Ci ext) should be added; refer to the formulas below:    Vt i = √ where as: C i min = C i ext = Po = η = t h = V i min = V ti = 2 • Po • (t h + 0.3 ms) • 100 _______________________ + Vi min2 Ci min • η 2 • Po • (t h + 0.3 ms) • 100   Ci ext = –––––––––––––––––––––– – Ci min η • (Vti 2 – Vi min2 ) 1 internal input capacitance [mF]; see table 2 external input capacitance [mF] output power [W] efficiency [%] hold-up time [ms] minimum input voltage [V] 1 threshold level [V] V i min see Electrical Input Data. For output voltages Vo > Vo nom, Vi min increases proportionally to Vo/Vo nom. Note: Option V2 and V3 can be adjusted by the potentiometer to a threshold level between Vi min and Vi max. A decoupling diode should be connected in series with the input of AK – FK converters to avoid the input capacitance discharging through other loads connected to the same source voltage. Table 25: Undervoltage monitor functions Option Monitoring Minimum adjustment range of threshold level Vt Typical hysteresis Vh [% of Vt ] for Vt min – Vt max Vi Vo or Vo1 Vt i Vt o Vhi Vho V2 yes no Vi min – Vi max 1 --- 3.4 – 0.4 V --- V3 yes yes Vi min – Vi max 3.4 – 0.4 V “0” V0 yes no Vi min – Vi max 3, 4 yes yes Vi min – Vi max 3, 4 1 0.95 – 0.985 Vo1 2 --0.95 – 0.985 Vo1 2 3.4 – 0.4 V --- 3.4 – 0.4 V “0” Threshold level adjustable by potentiometer.  Fixed value between 95% and 98.5% of Vo1 (tracking).  3 Adjusted at Io nom. 4 Fixed value, resistor-adjusted (±2% at 25°C) accord. to customer’s specification; individual type number is determined by the company. 1 2 Option V operates independently of the built-in input under­ voltage lockout circuit. A logic “low” signal is generated at pin 20, as soon as one of the monitored voltages drops below the pre­ selected threshold level V t. The return for this signal is S–. The V output recovers, when the monitored voltages exceed V t + Vh. The threshold level Vt i is either adjustable by a potentiometer, accessible through a hole in the front cover, or adjusted in the factory to a determined customer-specific value. Refer to table 26. V output (V0, V2, V3): Pin V is internally connected to the open collector of an NPN transistor. The emitter is connected to S–. V V ≤ 0.6 V (logic low) corresponds to a monitored voltage level (Vi and/or Vo) Vt + Vh high, H, IV ≤ 25 µA at VV = 5.1 V tech.support@psbel.com belfuse.com/power-solutions BCD20004-G Rev AF, 12-Jul-2018 © 2018 Bel Power Solutions & Protection Page 32 of 36 S Series 100 W DC-DC and AC-DC Converters VV high Vi Vti Fig. 40 Definition of Vti, ∆Vti and Vhi tlow min 2 tlow min 2 tlow min 2 3 Po = Po nom VV low S– Input voltage monitoring VV Po = 0 V Fig. 39 Output configuration of options V0, V2 and V3 V2 11023a VV 14 Vhi Po = 0 Input 20 ∆Vti VV high Rp IV NPN open collector VV 11009a Po = Po nom Vo+ 3 3 11010a 4 4 2 2 VV low t 0 V3 tlow min VV VV high 3 tlow min 3 3 VV low t 0 th Vo 5.1 V 4.875 V th 1 1 2.0 V 0 t Vi [VDC] Vti + Vhi Vti 0 Input voltage failure Input voltage sag Switch-on cycle Switch-on cycle and subsequent input voltage failure Output voltage monitoring V2 VV VV high 4 VV low 4 t 0 V3 t VV VV high tlow min 2 3 1 3 4 2 3 VV low 0 t Vo 5.1 V 4.875 V 2.0 V 0 4 VME request: minimum 4 ms t low min = 40 – 200 ms, typ 80 ms VV level not defined at Vo < 2.0 V The V signal drops simultaneously with Vo, if the pull-up resistor R P is connected to Vo+; the V signal remains high if R P is connected to an external source. t Vi Vti + Vhi Vti 0 Output voltage failure t Fig. 41 Relationship between Vb, Vo, VD, Vo /Vo nom versus time tech.support@psbel.com belfuse.com/power-solutions BCD20004-G Rev AF, 12-Jul-2018 © 2018 Bel Power Solutions & Protection Page 33 of 36 S Series 100 W DC-DC and AC-DC Converters K Standard H15 Connector Option K is available only for 5.1 V output models in order to avoid the connector with high current contacts. Efficiency is approx. 1.5% worse. B, B1, B2  Cooling Plate Where a cooling surface is available, we recommend the use of a cooling plate instead of the standard heat sink. The mounting system should ensure that the maximum case temperature TC max is not exceeded. The cooling capacity is calculated by (η see Model Selection): (100% – η) PLoss = –––––––––– • Vo • Io η For the dimensions of the cooling plates, see Mechanical Data. Option B2 is for customer-specific models with elongated case (for 220 mm DIN-rack depth). G RoHS RoHS-compliant for all six substances. tech.support@psbel.com belfuse.com/power-solutions BCD20004-G Rev AF, 12-Jul-2018 © 2018 Bel Power Solutions & Protection Page 34 of 36 S Series 100 W DC-DC and AC-DC Converters Accessories A variety of electrical and mechanical accessories are available including: – Front panels for 19” DIN-rack: Schroff or Intermas, 12 TE / 3U; see fig. 42. – Mating H15 connectors with screw, solder, faston, or press-fit terminals, code key system and coding wedges HZZ00202-G; see fig. 43. – Pair of connector retention clips HZZ01209-G; see fig. 44 – Connector retention brackets HZZ01216-G; see fig. 45 – Cage clamp adapter HZZ00144-G; see fig. 46 – Different cable hoods for H15 connectors (fig. 47): - HZZ00141-G, screw version - HZZ00142-G, use with retention brackets HZZ01218-G - HZZ00143-G, metallic version providing fire protection – Chassis or wall-mounting plate K02 (HZZ01213-G) for models with option B1. Mating connector (HZZ00107-G) with screw terminals; see fig. 48 – DIN-rail mounting assembly HZZ0615-G (DMB-K/S); see fig. 49 – Additional external input and output filters – Different battery sensors S-KSMH... for using the converter as a battery charger. Different cell characteristics can be selected; see fig. 50, table 27, and Battery Charging / Temperature Sensors. For additional accessory product information, see the accessory data sheets listed with each product series or individual model at our web site. Fig. 43 Different mating connectors Fig. 42 Different front panels Fig.44 Connector retention clips to fasten the H15 connector to the rear plate; see fig. 24. HZZ01209-G consists of 2 clips. 20 to 30 Ncm Fig. 45 Connector retention brackets HZZ01216-G (CRB-HKMS) Fig. 46 Cage clamp adapter HZZ00144-G tech.support@psbel.com belfuse.com/power-solutions BCD20004-G Rev AF, 12-Jul-2018 © 2018 Bel Power Solutions & Protection Page 35 of 36 S Series 100 W DC-DC and AC-DC Converters Fig. 47 Different cable hoods Fig. 48 Chassis- or wall-mounting plate HZZ01213-G (Mounting plate K02) European Projection 9.8 (0.4") 26 (1.02") 09125a L 56 (2.2") L = 2 m (standard length) other cable lengths on request Fig. 49 DIN-rail mounting assembly HZZ00615-G (DMB-K/S) adhesive tape Fig. 50 Battery temperature sensor Table 27: Battery temperature sensors Battery voltage nom. [V] Sensor type Cell voltage [V] Cell temp. coefficient [mV/K] Cable length [m] 12 S-KSMH12-2.27-30-2 2.27 –3.0 2 12 S-KSMH12-2.27-35-2 2.27 –3.5 2 24 S-KSMH24-2.27-30-2 2.27 –3.0 2 24 S-KSMH24-2.27-35-2 2.27 –3.5 2 24 S-KSMH24-2.31-35-0 2.31 –3.5 4.5 24 S-KSMH24-2.31-35-2 2.31 –3.5 2 24 S-KSMH24-2.35-35-2 2.35 –3.5 2 48 S-KSMH48-2.27-30-2 2.27 –3.0 2 48 S-KSMH48-2-27-35-2 2.27 –3.5 2 Note: Other temperature coefficients and cable lengths are available on request. NUCLEAR AND MEDICAL APPLICATIONS - These products are not designed or intended for use as critical components in life support systems, equipment used in hazardous environments, or nuclear control systems. 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. tech.support@psbel.com belfuse.com/power-solutions BCD20004-G Rev AF, 12-Jul-2018 © 2018 Bel Power Solutions & Protection Page 36 of 36