PXB15-24D15/N

PXB15-24D15/N

  • 厂商:

    TDK(东电化)

  • 封装:

    插件,25.4x25.4mm

  • 描述:

    PXB15-24D15/N

  • 数据手册
  • 价格&库存
PXB15-24D15/N 数据手册
PXB15-xxDxx Dual Output 15 Watt DC/DC Converters The PXB15 series is approved to UL/CSA/EN/IEC 60950-1. Table of contents Absolute Maximum Rating Output Specification Input Specification General Specification Characteristic Curves Testing Configurations EMC Consideration Input Source Impedance Output Over Current Protection Output Over Voltage Protection Short Circuit Protection P2 P2 P3 P4 P5 P23 P24 P26 P26 P26 P27 Thermal Consideration Heat Sink Consideration Remote ON/OFF Control Mechanical Data Recommended Pad Layout Soldering Considerations Packaging Information Part Number Structure Safety and Installation Instruction MTBF and Reliability P27 P27 P28 P29 P30 P30 P31 P31 P32 P32 Data Sheet Jul. 20, 2010 15W, Dual Output Absolute Maximum Rating Parameter Model Input Voltage Continuous Min Max 12DXX 24DXX 48DXX 12DXX 24DXX 48DXX Transient (100mS) Input Voltage Variation (complies with ETS300 132 part 4.4) Operating Ambient Temperature (with derating) Operating Case Temperature Storage Temperature Unit 18 36 75 36 50 100 All All -40 All -55 VDC 5 V/mS 85 105 125 ºC ºC ºC Output Specification Parameter Output Voltage Range (Vin = Vin(nom) ; Full Load ; TA=25 ºC) Model Min Typ Max XXD05 4.95 5 5.05 XXD12 11.88 12 12.12 XXD15 14.85 15 15.15 All -0.5 +0.5 -1.0 +1.0 -5 5 Unit VDC Output Regulation Line (Vin(min) to Vin(max) at Full Load) Load (0% to 100% of Full Load) Cross Regulation Asymmetrical Load 25% / 100% of Full Load All % % Output Ripple & Noise(See Page 23) Peak-to-Peak (20MHz bandwidth) All 100 mVP-P (Measured with a 1uF M/C and a 10uF T/C ) Temperature Coefficient Output Voltage Overshoot (Vin(min) to Vin(max) ; Full Load ; TA=25 ºC) All -0.02 +0.02 %/ ºC 3 % VOUT All 0 All 200 mV All 250 μS Dynamic Load Response (Vin = Vin(nom) ; TA=25 ºC) Load step change from 75% to 100% or 100 to 75% of Full Load Peak Deviation Settling Time (VOUT<10% peak deviation) Output Current Output Over Voltage Protection (Voltage Clamped) XXD05 0 ±1500 XXD12 0 ±625 XXD15 0 ±500 XXD05 5.6 7.0 XXD12 13.5 19.6 XXD15 16.8 Output Over Current Protection All Output Short Circuit Protection All mA VDC 20.5 150 % FL. Hiccup, automatic recovery PXB15-xxDxx 2 Data Sheet Jul. 20, 2010 15W, Dual Output Input Specification Parameter Operating Input Voltage Input Current (Maximum value at Vin = Vin(nom); Full Load) Min Typ Max 12DXX Model 9 12 18 24DXX 18 24 36 48DXX 36 48 75 12D05 1543 12D12 1506 12D15 1488 24D05 772 24D12 744 24D15 744 48D05 386 48D12 368 48D15 Input Standby Current (Typical value at Vin = Vin(nom) ; No Load) Under Voltage Lockout Turn-on Threshold Under Voltage Lockout Turn-off Threshold Input Reflected Ripple Current (See Page 23) (5 to 20MHz, 12μH source impedance) Unit VDC mA 372 12D05 30 12D12 30 12D15 30 24D05 20 24D12 15 24D15 25 48D05 15 48D12 15 48D15 20 mA 12DXX 9 24DXX 18 48DXX 36 12DXX 8 24DXX 14.5 48DXX 30.5 VDC VDC All 30 mAP-P All 30 mS Start Up Time (Vin = Vin(nom) and constant resistive load) Power up Remote ON/OFF 30 Remote ON/OFF Control (See Page 28) (The ON/OFF pin voltage is referenced to -VIN) Negative Logic DC-DC ON(Short) DC-DC OFF(Open) Positive Logic All DC-DC ON(Open) DC-DC OFF(Short) 0 1.2 3 15 3 15 0 Remote Off Input Current All Input Current of Remote Control Pin All 1.2 2.5 -0.5 VDC mA 1.0 mA PXB15-xxDxx 3 Data Sheet Jul. 20, 2010 15W, Dual Output General Specification Parameter Efficiency(See Page 23) (Vin = Vin(nom) ; Full Load ; TA=25 ºC) Model Min Typ 12D05 85 12D12 87 12D15 88 24D05 85 24D12 88 24D15 88 48D05 85 48D12 89 48D15 88 Max Unit % Isolation Voltage Input to Output All Input (Output) to Case VDC 1600 1000 Isolation Resistance All 1 GΩ Isolation Capacitance All Switching Frequency All 400 KHz Weight All 15 g All 1.330×10 1000 pF MTBF(See Page 32) Bellcore TR-NWT-000332, TC=40 ºC MIL-STD-217F 6 hours 5 5.630×10 PXB15-xxDxx 4 Data Sheet Jul. 20, 2010 15W, Dual Output Characteristic Curves All test conditions are at 25 ºC. PXB15-12D05 Efficiency versus Output Current Typical Output Ripple and Noise. Vin = Vin(nom) ; Full Load Efficiency versus Input Voltage. Full Load Transient Response to Dynamic Load Change from 100% to 75% to 100% of Full Load ; Vin = Vin(nom) Derating OutputCurrentversus AmbientTemperature andAirflow Typical Input Start-Up and Output Rise Characteristic Vin = Vin(nom) Vin = Vin(nom) ; Full Load PXB15-xxDxx 5 Data Sheet Jul. 20, 2010 15W, Dual Output Characteristic Curves (Continued) All test conditions are at 25 ºC. PXB15-12D05 Conduction Emission of EN55022 Class A Using ON/OFF Voltage Start-Up and Vo Rise Characteristic Vin = Vin(nom) ; Full Load Vin = Vin(nom) ; Full Load Conduction Emission of EN55022 Class B Power Dissipation versus Output Current Vin = Vin(nom) ; Full Load Derating OutputCurrentVersusAmbientTemperature with Heat-Sink andAirflow,Vin = Vin(nom) PXB15-xxDxx 6 Data Sheet Jul. 20, 2010 15W, Dual Output Characteristic Curves (Continued) All test conditions are at 25 ºC. PXB15-12D12 Efficiency versus Output Current Typical Output Ripple and Noise. Vin = Vin(nom) ; Full Load Efficiency versus Input Voltage. Full Load Transient Response to Dynamic Load Change from 100% to 75% to 100% of Full Load ; Vin = Vin(nom) Derating OutputCurrentversus AmbientTemperature andAirflow Typical Input Start-Up and Output Rise Characteristic Vin = Vin(nom) Vin = Vin(nom) ; Full Load PXB15-xxDxx 7 Data Sheet Jul. 20, 2010 15W, Dual Output Characteristic Curves (Continued) All test conditions are at 25 ºC. PXB15-12D12 Conduction Emission of EN55022 Class A Using ON/OFF Voltage Start-Up and Vo Rise Characteristic Vin = Vin(nom) ; Full Load Vin = Vin(nom) ; Full Load Conduction Emission of EN55022 Class B Power Dissipation versus Output Current Vin = Vin(nom) ; Full Load Derating OutputCurrentVersusAmbientTemperature with Heat-Sink andAirflow,Vin = Vin(nom) PXB15-xxDxx 8 Data Sheet Jul. 20, 2010 15W, Dual Output Characteristic Curves (Continued) All test conditions are at 25 ºC. PXB15-12D15 Efficiency versus Output Current Typical Output Ripple and Noise. Vin = Vin(nom) ; Full Load Efficiency versus Input Voltage. Full Load Transient Response to Dynamic Load Change from 100% to 75% to 100% of Full Load ; Vin = Vin(nom) Derating OutputCurrentversus AmbientTemperature andAirflow Typical Input Start-Up and Output Rise Characteristic Vin = Vin(nom) Vin = Vin(nom) ; Full Load PXB15-xxDxx 9 Data Sheet Jul. 20, 2010 15W, Dual Output Characteristic Curves (Continued) All test conditions are at 25 ºC. PXB15-12D15 Conduction Emission of EN55022 Class A Using ON/OFF Voltage Start-Up and Vo Rise Characteristic Vin = Vin(nom) ; Full Load Vin = Vin(nom) ; Full Load Conduction Emission of EN55022 Class B Power Dissipation versus Output Current Vin = Vin(nom) ; Full Load Derating OutputCurrentVersusAmbientTemperature with Heat-Sink andAirflow,Vin = Vin(nom) PXB15-xxDxx 10 Data Sheet Jul. 20, 2010 15W, Dual Output Characteristic Curves (Continued) All test conditions are at 25 ºC. PXB15-24D05 Efficiency versus Output Current Typical Output Ripple and Noise. Vin = Vin(nom) ; Full Load Efficiency versus Input Voltage. Full Load Transient Response to Dynamic Load Change from 100% to 75% to 100% of Full Load ; Vin = Vin(nom) Derating OutputCurrentversus AmbientTemperature andAirflow Typical Input Start-Up and Output Rise Characteristic Vin = Vin(nom) Vin = Vin(nom); Full Load PXB15-xxDxx 11 Data Sheet Jul. 20, 2010 15W, Dual Output Characteristic Curves (Continued) All test conditions are at 25 ºC. PXB15-24D05 Conduction Emission of EN55022 Class A Using ON/OFF Voltage Start-Up and Vo Rise Characteristic Vin = Vin(nom) ; Full Load Vin = Vin(nom) ; Full Load Conduction Emission of EN55022 Class B Power Dissipation versus Output Current Vin = Vin(nom) ; Full Load Derating OutputCurrentVersusAmbientTemperature with Heat-Sink andAirflow,Vin = Vin(nom) PXB15-xxDxx 12 Data Sheet Jul. 20, 2010 15W, Dual Output Characteristic Curves (Continued) All test conditions are at 25 ºC. PXB15-24D12 Efficiency versus Output Current Typical Output Ripple and Noise. Vin = Vin(nom) ; Full Load Efficiency versus Input Voltage. Full Load Transient Response to Dynamic Load Change from 100% to 75% to 100% of Full Load ; Vin = Vin(nom) Derating OutputCurrentversus AmbientTemperature andAirflow Typical Input Start-Up and Output Rise Characteristic Vin = Vin(nom) Vin = Vin(nom) ; Full Load PXB15-xxDxx 13 Data Sheet Jul. 20, 2010 15W, Dual Output Characteristic Curves (Continued) All test conditions are at 25 ºC. PXB15-24D12 Conduction Emission of EN55022 Class A Using ON/OFF Voltage Start-Up and Vo Rise Characteristic Vin = Vin(nom) ; Full Load Vin = Vin(nom); Full Load Conduction Emission of EN55022 Class B Power Dissipation versus Output Current Vin = Vin(nom) ; Full Load Derating OutputCurrentVersusAmbientTemperature with Heat-Sink andAirflow,Vin = Vin(nom) PXB15-xxDxx 14 Data Sheet Jul. 20, 2010 15W, Dual Output Characteristic Curves (Continued) All test conditions are at 25 ºC. PXB15-24D15 Efficiency versus Output Current Typical Output Ripple and Noise. Vin = Vin(nom) ; Full Load Efficiency versus Input Voltage. Full Load Transient Response to Dynamic Load Change from 100% to 75% to 100% of Full Load ; Vin = Vin(nom) Derating OutputCurrentversus AmbientTemperature andAirflow Typical Input Start-Up and Output Rise Characteristic Vin = Vin(nom) Vin = Vin(nom) ; Full Load PXB15-xxDxx 15 Data Sheet Jul. 20, 2010 15W, Dual Output Characteristic Curves (Continued) All test conditions are at 25 ºC. PXB15-24D15 Conduction Emission of EN55022 Class A Using ON/OFF Voltage Start-Up and Vo Rise Characteristic Vin = Vin(nom) ; Full Load Vin = Vin(nom) ; Full Load Conduction Emission of EN55022 Class B Power Dissipation versus Output Current Vin = Vin(nom) ; Full Load Derating OutputCurrentVersusAmbientTemperature with Heat-Sink andAirflow,Vin = Vin(nom) PXB15-xxDxx 16 Data Sheet Jul. 20, 2010 15W, Dual Output Characteristic Curves (Continued) All test conditions are at 25 ºC. PXB15-48D05 Efficiency versus Output Current Typical Output Ripple and Noise. Vin = Vin(nom) ; Full Load Efficiency versus Input Voltage. Full Load Transient Response to Dynamic Load Change from 100% to 75% to 100% of Full Load ; Vin = Vin(nom) Derating OutputCurrentversus AmbientTemperature andAirflow Typical Input Start-Up and Output Rise Characteristic Vin = Vin(nom) Vin = Vin(nom) ; Full Load PXB15-xxDxx 17 Data Sheet Jul. 20, 2010 15W, Dual Output Characteristic Curves (Continued) All test conditions are at 25 ºC. PXB15-48D05 Conduction Emission of EN55022 Class A Using ON/OFF Voltage Start-Up and Vo Rise Characteristic Vin = Vin(nom) ; Full Load Vin = Vin(nom); Full Load Conduction Emission of EN55022 Class B Power Dissipation versus Output Current Vin = Vin(nom) ; Full Load Derating OutputCurrentVersusAmbientTemperature with Heat-Sink andAirflow,Vin = Vin(nom) PXB15-xxDxx 18 Data Sheet Jul. 20, 2010 15W, Dual Output Characteristic Curves (Continued) All test conditions are at 25 ºC. PXB15-48D12 Efficiency versus Output Current Typical Output Ripple and Noise. Vin = Vin(nom) ; Full Load Efficiency versus Input Voltage. Full Load Transient Response to Dynamic Load Change from 100% to 75% to 100% of Full Load ; Vin = Vin(nom) Derating OutputCurrentversus AmbientTemperature andAirflow Typical Input Start-Up and Output Rise Characteristic Vin = Vin(nom) Vin = Vin(nom) ; Full Load PXB15-xxDxx 19 Data Sheet Jul. 20, 2010 15W, Dual Output Characteristic Curves (Continued) All test conditions are at 25 ºC. PXB15-48D12 Conduction Emission of EN55022 Class A Using ON/OFF Voltage Start-Up and Vo Rise Characteristic Vin = Vin(nom) ; Full Load Vin = Vin(nom) ; Full Load Conduction Emission of EN55022 Class B Power Dissipation versus Output Current Vin = Vin(nom) ; Full Load Derating OutputCurrentVersusAmbientTemperature with Heat-Sink andAirflow,Vin = Vin(nom) PXB15-xxDxx 20 Data Sheet Jul. 20, 2010 15W, Dual Output Characteristic Curves (Continued) All test conditions are at 25 ºC. PXB15-48D15 Efficiency versus Output Current Typical Output Ripple and Noise. Vin = Vin(nom) ; Full Load Efficiency versus Input Voltage. Full Load Transient Response to Dynamic Load Change from 100% to 75% to 100% of Full Load ; Vin = Vin(nom) Derating OutputCurrentversus AmbientTemperature andAirflow Typical Input Start-Up and Output Rise Characteristic Vin = Vin(nom) Vin = Vin(nom); Full Load PXB15-xxDxx 21 Data Sheet Jul. 20, 2010 15W, Dual Output Characteristic Curves (Continued) All test conditions are at 25 ºC. PXB15-48D15 Conduction Emission of EN55022 Class A Using ON/OFF Voltage Start-Up and Vo Rise Characteristic Vin = Vin(nom) ; Full Load Vin = Vin(nom) ; Full Load Conduction Emission of EN55022 Class B Power Dissipation versus Output Current Vin = Vin(nom) ; Full Load Derating OutputCurrentVersusAmbientTemperature with Heat-Sink andAirflow,Vin = Vin(nom) PXB15-xxDxx 22 Data Sheet Jul. 20, 2010 15W, Dual Output Testing Configurations Input reflected-ripple current measurement CURRENT PROBEMEASURE POINT +Vin L + BATTERY C1 + C2 -Vin Component L C1 C2 Value 12μH 10μF 10μF Voltage ---100V 100V Reference ---Aluminum Electrolytic Capacitor Aluminum Electrolytic Capacitor Peak-to-peak output ripple & noise measurement Output voltage and efficiency measurement Note: All measurements are taken at the module terminals.  V  Io Efficiency   o  Vin  I in    100%  PXB15-xxDxx 23 Data Sheet Jul. 20, 2010 15W, Dual Output EMC considerations Suggested schematic for EN55022 conducted emission Class A limits Recommended layout with input filter To meet conducted emissions EN55022 CLASS A , the following components are needed: Component C1 C2 C3,C4 Value 10uF ---470pF Voltage 25V ---2KV Component C1 C2 C3,C4 Value 6.8uF 6.8uF 470pF Voltage 50V 50V 2KV Component C1 C2 C3,C4 Value 2.2uF 2.2uF 470pF Voltage 100V 100V 2KV PXB15-12DXX Reference 1812 MLCC ---1808 MLCC PXB15-24DXX Reference 1812 MLCC 1812 MLCC 1808 MLCC PXB15-48DXX Reference 1812 MLCC 1812 MLCC 1808 MLCC PXB15-xxDxx 24 Data Sheet Jul. 20, 2010 15W, Dual Output EMC considerations (Continued) Suggested schematic for EN55022 conducted emission Class B limits Recommended layout with input filter To meet conducted emissions EN55022 CLASS B, the following components are needed: PXB15-12DXX Component Value C1,C3 10μF C2 ---C4,C5 470pF L1 145μH Voltage 25V ---2KV ---- Reference 1812 MLCC ---1808 MLCC Common Choke PXB15-24DXX Component Value C1,C3 6.8μF C2 ---C4,C5 470pF L1 325μH Voltage 50V ---2KV ---- Reference 1812 MLCC ---1808 MLCC Common Choke PXB15-48DXX Component Value C1,C3 2.2μF C2 2.2μF C4,C5 1000pF L1 325μH Voltage 100V 100V 2KV ---- Reference 1812 MLCC 1812 MLCC 1808 MLCC Common Choke PXB15-xxDxx 25 Data Sheet Jul. 20, 2010 15W, Dual Output Input Source Impedance The power module should be connected to a low impedance input source. Highly inductive source impedance can affect the stability of the power module. The addition of an external C-L-C filter is recommended to minimize input reflected ripple current. The inductor is simulated source impedance of 12μH and capacitor is Nippon chemi-con KZE series 10μF/100V&10μF/100V. The capacitor must be located as close as possible to the input terminals of the power module for lower impedance. Output Over Current Protection When excessive output currents occur in the system, circuit protection is required on all power supplies. Normally, overload current is maintained at approximately 150 percent of rated current for PXB15 dual output series. Hiccup-mode is a method of operation in a power supply whose purpose is to protect the power supply from being damaged during an over-current fault condition. It also allows the power supply to restart when the fault is removed. One of the problems resulting from over current is that excessive heat may be generated in power devices; especially MOSFET and Schottky diodes and the temperature of those devices may exceed their specified limits. A protection mechanism has to be used to prevent those power devices from being damaged. Output Over Voltage Protection The output over-voltage protection consists of a Zener diode that monitors the output voltage on the feedback loop. If the voltage on the output terminals exceeds the over-voltage protection threshold, then the Zener diode will send a signal to the control IC to limit the output voltage. PXB15-xxDxx 26 Data Sheet Jul. 20, 2010 15W, Dual Output Short Circuit Protection Continuous, hiccup and auto-recovery mode. During a short circuit condition the converter will shut down. The average current during this condition will be very low and damage to this device should not occur. Thermal Consideration The power module operates in a variety of thermal environments. However, sufficient cooling should be provided to help ensure reliable operation of the unit. Heat is removed by conduction, convection, and radiation to the surrounding Environment. Proper cooling can be verified by measuring the point as shown in the figure below. The temperature at this location should not exceed 105 ºC. When Operating, adequate cooling must be provided to maintain the test point temperature at or below 105 ºC. Although the maximum point Temperature of the power modules is 105 ºC, maintaining a lower operating temperature will increase the reliability of this device. Temperature Measurement Point Heat Sink Consideration The addition of a heat sink may be needed to decrease the temperature of the module; thus increasing its reliability. 7G-0047C-F All dimensions in millimeters PXB15-xxDxx 27 Data Sheet Jul. 20, 2010 15W, Dual Output Remote ON/OFF Control The Remote ON/OFF Pin is used t o turn the DC/DC power module on and off. The user must connect a switch between the on/off pin and the Vi (-) pin. The switch can be an open collector transistor, FET, or Photo-Coupler. The switch must be capable of sinking up to 1 mA when using a low logic level voltage. When using a high logic level, the maximum signal voltage is 15V and the maximum allowable leakage current of the switch is 50 uA. Remote ON/OFF Implementation Circuits Isolated-Closure Remote ON/OFF Level Control Using TTL Output Level Control Using Line Voltage There are two remote control options available, positive logic and negative logic. a. Positive logic - The DC/DC module is turned on when the ON/OFF pin is at a high logic level. A low logic signal is needed to turn off the device. When PXB15 module is turned off at When PXB15 module is turned on at Low logic level High logic level b. Negative logic – The DC/DC module is turned on when the ON/OFF pin is at low logic level. Ahigh logic level signal is needed to turn off the device. When PXB15 module is turned on at When PXB15 module is turned off at Low logic level High logic level PXB15-xxDxx 28 Data Sheet Jul. 20, 2010 15W, Dual Output Mechanical Data PIN CONNECTION PIN 1 2 3 4 5 6 PXB15D Series + INPUT - INPUT ON/OFF +VOUT COMMON -VOUT OPTIONS Suffix Description P N T Positive Logic Negative Logic Trim 1.All dimensions in inches(mm) 2.Tolerance : x.xx±0.02(x.x±0.5) x.xxx±0.010(x.xx±0.25) 3.Pin pitch tolerance ±0.014(0.35) -NT as standard, Delete suffix if not required PXB15-xxDxx 29 Data Sheet Jul. 20, 2010 15W, Dual Output Recommended Pad Layout Soldering Considerations Lead free wave solder profile for PXB15-SERIES Zone Preheat zone Actual heating Reference Parameter. Rise temp. speed: 3 ºC /sec max. Preheat temp.: 100~130ºC Peak temp.: 250~260ºC Peak time(T1+T2 time): 4~6 sec Reference Solder: Sn-Ag-Cu; Sn-Cu Hand Welding: Soldering iron: Power 90W Welding Time: 2~4 sec Temp.: 380 ~400 ºC PXB15-xxDxx 30 Data Sheet Jul. 20, 2010 15W, Dual Output Packaging Information 300 26.5 19 6 All dimensions in millimeters 10 PCS per TUBE Part Number Structure PXB 15 – 48 D 05 -A Total Output power 15 Watt Input Voltage Range 12xxx : 9~18V 24xxx : 18~36V 48xxx : 36~75V Model Number Option Suffix Output Voltage 05 : ±5V 12 : ±12V 15 : ±15V Dual Output Input Range Output Voltage PXB15-12D05 9 - 18 VDC ±5VDC PXB15-12D12 9 - 18 VDC ±12VDC PXB15-12D15 9 - 18 VDC ±15VDC PXB15-24D05 18 - 36 VDC ±5VDC PXB15-12D12 18 - 36 VDC ±12VDC PXB15-24D15 18 - 36 VDC ±15VDC PXB15-48D05 36 - 75 VDC ±5VDC PXB15-48D12 36 - 75 VDC ±12VDC PXB15-48D15 36 - 75 VDC ±15VDC Note 1. Maximum value at nominal input voltage and full load. Note 2. Typical value at nominal input voltage and full load. (2) Output Current Full Load Input Current (1) Full Load Eff (%) ±1500mA ±625mA ±500mA ±1500mA ±625mA ±500mA ±1500mA ±625mA ±500mA 1543mA 1506mA 1488mA 772mA 744mA 744mA 386mA 368mA 372mA 85 87 88 85 88 88 85 89 88 PXB15-xxDxx 31 Data Sheet Jul. 20, 2010 15W, Dual Output Safety and Installation Instruction Fusing Consideration Caution: This power module is not internally fused. An input line fuse must always be used. This encapsulated power module can be used in a wide variety of applications, ranging from simple stand-alone operation to an integrated part of sophisticated power architecture. For maximum flexibility, internal fusing is not included; however, to achieve maximum safety and system protection, always use an input line fuse. The safety agencies require a normal-blow fuse with maximum rating of 3A for PXB15-12DXX modules and 1.5A for PXB15-24DXX modules and 1A for PXB15-48DXX modules. Based on the information provided in this data sheet on Inrush energy and maximum DC input current; the same type of fuse with lower rating can be used. Refer to the fuse manufacturer’s data for further information. MTBF and Reliability The MTBF of PXB15D SERIES of DC/DC converters has been calculated using Bellcore TR-NWT-000332 Case I: 50% stress, Operating Temperature at 40 ºC (Ground fixed and controlled 6 environment ). The resulting figure for MTBF is 1.330×10 hours. MIL-HDBK 217F NOTICE2 FULL LOAD, Operating Temperature at 25 ºC . The resulting figure for MTBF is 5 5.630×10 hours. PXB15-xxDxx 32
PXB15-24D15/N 价格&库存

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PXB15-24D15/N
  •  国内价格 香港价格
  • 1+597.920911+77.24672
  • 10+566.3012410+73.16171
  • 25+554.1550625+71.59252
  • 50+545.1268050+70.42614
  • 100+536.23679100+69.27762

库存:1