Provision for standby mode operation Partial Resonance Power Supply IC Module MR4000 Series Application Note Version 1.4 Shindengen Electric Manufacturing Co., Ltd. MR4000 Series Application Note Precautions Thank you for purchasing this product. When using this IC, please follow the warnings and cautions given below to ensure safety. Warning ! Improper handling may result in death, serious injury, or major property damage. Caution ! Improper handling may result in minor injury or property damage. ! ! We strive at all times to improve the quality and reliability of our products. However, a certain risk of malfunctions is inevitable with semiconductor products. You are responsible for producing a design that meets safety requirements (whether a redundant design, a design that prevents the spread of fire, or designs that minimize the possibility of malfunctions) necessary to avoid injury, fire, or damage to social credibility that may result should any of our products malfunction. The semiconductor product described in this document is not designed or manufactured for use in a device or a system required to demonstrate mission-critical reliability or safety, or whose malfunction may directly cause injuries or endanger human life. Contact us before using the product for any of the following special or specific applications: Warning Special applications Transport equipment (e.g., automobiles and ships), communications equipment for a backbone network, traffic signal equipment, disaster or crime prevention equipment, medical devices, various types of safety equipment, and other applications Specific applications Nuclear power control systems, aircraft equipment, aerospace equipment, submarine repeaters, medical equipment used in life-support, and other applications Even if the equipment is not designed for a special or specific application, please consult with us before using any of our IC products in equipment required to run continuously for extended periods. Caution ! Never attempt to repair or modify the product. Doing so may lead to serious accidents. <<Electric shock, destruction of property, fire, or malfunctions may result.>> ! In the event of a problem, an excessive voltage may arise at an output terminal, or the voltage may drop. Anticipate these fluctuations and any consequential malfunctions or destruction and provide adequate protection for equipment, such as overvoltage or overcurrent protection. ! Check the polarity of the input and output terminals. Make sure they are properly connected before turning on power. <<Failure to do so may lead to failure of the protective element or generate smoke or fire.>> ! Use only the specified input voltage. Deploy a protective element on the input line. <<Problems may result in smoke or fire.>> In the event of a malfunction or other anomaly, shut power off and contact us immediately. ! The contents of this document are subject to change without notice. Use of this product constitutes acceptance of the formal specifications. We have taken every possible measure to ensure the accuracy of the information in this document. However, we will not be held liable for any losses or damages incurred or infringements of patents or other rights resulting from use of this information. This document does not guarantee or license the execution of patent rights, intellectual property rights or any other rights of Shindengen or third parties. No part of this document may be reproduced in any form without prior consent from Shindengen. Shindengen Electric MFG.CO.,LTD -2- MR4000 Series Application Note 1. Overview 1.1 Introduction 1.2 Characteristics 1.3 Applications 1.14 Absolute maximum ratings and reference output capacities 1.5 Dimensions and equivalent circuit 1.6 Basic circuit 2. Block diagram 2.1 Block diagram 2.2 Pin function description 3. Operating principles 3.1 Startup circuit 3.2 3.3 3.4 On-trigger circuit Partial resonance Standby mode control (patent pending) 3.5 Output voltage control (normal operation) 3.6 Soft drive circuit (patent pending) 3.7 Circuit for load shorts 3.8 Collector pin (MR40XX Series) 3.9 Thermal shutdown circuit (TSD) 3.10 Overvoltage protection circuit (OVP) 3.11 Leading edge blank (LEB) 3.12 Malfunction prevention circuit (patent pending) 3.13 Overcurrent protection circuit 4. Design procedure 4.1 Design flow chart 4.2 Reference conditions for main transformer design 4.3 Reference formulas for main transformer design 4.4 Selecting constants for peripheral components 4.5 Selecting constants for droop circuit 4.6 Cooling design Contents … … … … 4 4 4 4 … 4 … 5 … … … … … … 5 6 6 6 7 7 … 8 … 8 … 9 … 10 … 10 6.5 … 11 … 6. Supplementary design information 6.1 Supplementary notes on design 6.2 Noise reduction 6.3 Supplemental information on surface mounting 6.4 Precautions for waveform measurements … 49 … 51 … 58 … 60 … 61 Notes on pattern design … 62 6.6 Application circuit examples … 64 11 6.7 Troubleshooting list … 67 … 11 6.8 Glossary … 69 … 11 … 11 … 12 … 12 … … 13 13 … 13 … 14 … 16 … 17 … 18 Shindengen Electric MFG.CO.,LTD -3- MR4000 Series Application Note 1. Overview 1.1 Introduction The MR4000 Series IC modules incorporate a burst-mode switching function at micro-loads. These are partial resonance modules consisting of a switching device optimized for 100 V, 200 V, and auto-sensing power supply input and a control IC. The IC modules are designed to provide the following power supply characteristics: 1.2 Characteristics 1. 2. 3. 4. 5. 6. 7. 8. High efficiency and low noise through partial resonance Second-generation high-speed IGBT with 900-V resistance simplifies design for auto-sensing power supply input. (MR40XX series) Burst mode helps reduce power consumption at micro-loads. Onboard startup circuit eliminates the need for startup resistors. Soft-drive circuit achieves low noise levels. Overcurrent protection function (ton limit and primary current limit), overvoltage protection, and thermal shutdown function Allow configuration of a power supply circuit with fewer external components. Full-mold package facilitates insulation design. 1.3 Applications Televisions, displays, printers, video recorders, DVD, STB, refrigerators, and other appliances; various automated business machines 1.4 Absolute maximum ratings and reference output capacities Main switching device 型 名 VDS/VCE [V] MR4500 MR4510 MR4520 MR4530 500 MOSFET MR4710 700 MR4720 MR4010 MR4020 MR4030 MR4040 Second– generation high-speed IGBT 900 Maximum output capacity Po[W] Input voltage range AC90 - 132V AC180 - 276V AC90 - 276V 12 (20) ― ― 25 (40) ― ― 50 (80) ― ― 80 (100) ― ― ― 25 (40) 12 (20) ― 50 (80) 25 (40) ― 65 45 ― 105 70 ― 135 90 ― 180 120 Maximum output capacity and input voltage range vary with design parameters. Output capacities in parentheses are peak values. Shindengen Electric MFG.CO.,LTD -4- 1. Overview 1.5 Dimensions and equivalent circuit ±0.20 +0.2 4.50 φ 3.2 -0.1 Equivalent Circuit ±0.20 ±0.2 2.70 10.0 Marking area ±0.20 2.70 +0.20 0.50 -0.10 +0.20 0.97±0.25 0.50 -0.10 1.94±0.30 3.88±0.30 1.94±0.30 (4.1) ±0.50 7.05 Terminal number 1.6 Basic circuit Shindengen Electric MFG.CO.,LTD -5- MR4000 Series Application Note 2. Block diagram 2.1 Block diagram 2.2 Pin function description Pin number Abbreviation Description 1 2 3 4 Z/C F/B GND Vcc Zero current detection pin Feedback signal input pin GND pin Vcc (IC power supply) pin MR45XX series Main switching device source and OCL (current detection) pin MR47XX series Main switching device emitter and OCL MR40XX series (current detection) pin ― Vin (startup) pin ― MR45XX series Main switching device drain pin MR47XX series MR40XX series Main switching device collector pin Source/OCL 5 Emitter/OCL 6 7 8 9 Vin Drain Collector Shindengen Electric MFG.CO.,LTD -6- MR4000 Series Application Note 3. Operating principles 3.1 Startup circuit [Conventional startup circuit] In a conventional startup circuit employing a startup resistor, an electric current continues to flow after the power supply starts, wasting power and reducing efficiency, especially during standby. See [Conventional startup circuit] in Fig. 3.1 Comparison of startup circuits. In the MR4000 Series startup circuit, the startup current is supplied from the input voltage and shut off when the power supply starts up. Startup current IC The startup current flows even during steady-state operation, resulting in losses. [MR4000 startup circuit] The startup circuit supplies the Istartup current from the The startup current switches off after startup, eliminating the constant current source in the IC until the voltage at the VCC need for a startup resistor. Vin pin pin reaches VCC(start) = VCC(startup off). This current is consumed 7 internally in the IC and also used as the charging current for the capacitor connected externally between the VCC pin and GND. This design allows stable startup with minimal dependence on the input voltage. VCC pin When the voltage at the VCC pin reaches VCC(startup off) = 4 VCC(start), the startup circuit disconnects, and the startup Vcc (startup off)/Vcc (startup on) current is halted. As soon as it stops, oscillation begins. The current to be consumed in the IC is then supplied from Control coil the control coil. See [MR4000 startup circuit] in Fig. 3.1 Comparison of startup circuits. Fig. 3.1 Comparison of startup circuits In the case of an instantaneous power failure or a load short, oscillation stops when the voltage at the VCC pin reaches VCC(stop). When this voltage drops still further to VCC(startup on), the startup circuit begins to operate once again, and the voltage at the VCC pin begins to rise. See Fig. 3.2. Incorporating the functions above improves efficiency, particularly during standby, and eliminates the need for a startup resistor, thereby reducing the overall number of components. VCC (startup off) =VCC (Start) [Vin] VCC (stop) VCC (startup on) [VCC] [VDS(VCE)] [VOUT] Instantaneous power failure Load short Fig. 3.2 Startup circuit operation sequence Shindengen Electric MFG.CO.,LTD -7- 3. Operating principles 3.2 On-trigger circuit Approx. 0.3 V The MR4000 Series employs a current-critical operation system. When an energy burst to the secondary side of the main transformer is detected, the main switching device is turned on. [VZ/C] Energy discharge timing is detected at a negative edge of the control coil voltage waveform. The main switching device is turned on upon detection of the discharge to perform current-critical operations. See the point with approx. 0.3 V in Fig. 3.3 On-trigger operation sequence. [ID(IC)] [Secondary rectification diode current] The on-trigger detection voltage (approx. 0.3 V) features 50 mV hysteresis for improved noise resistance. [VDS(VCE)] [Control coil voltage] Fig. 3.3 On-trigger operation sequence 3.3 Partial resonance LP In a current-critical switching power supply (RCC), when the secondary current in the circuit with a resonating capacitor connected between the drain (collector) and GND of the main switching device as shown on the right reaches 0 A, damping begins at the resonance frequency determined by the primary inductance LP of the main transformer and the resonating capacitor Cq. Cq Drain (collector) pin Resonating capacitor 9 Z/C pin 5 Source/OCL (emitter/OCL) pin 1 R 3 GND pin C On-timing is delayed with CR time constant. The discharge current of the resonating capacitor Cq flows through the primary coil and returns energy to the input. Adjusting the CR time constant applied to the Z/C pin (see the diagram on the right) allows the main switching device to be turned on at the trough of the damping voltage waveform, reducing turn-on losses. Turn-on delay [VDS (VCE)] In a partial resonance circuit, the energy stored in the resonating capacitor Cq during the OFF period of the main switching device is returned to the input, reducing turn-on losses. This allows the connection of a high-capacity capacitor between the drain (collector) and GND of the main switching device, thereby reducing noise. Damping begins at the resonance frequency determined by LP and Cq. [ID (IC)] [Secondary rectification diode current] The use of partial resonance improves efficiency and reduces noise with simple circuit configurations. Fig. 3.4 Partial resonance Shindengen Electric MFG.CO.,LTD -8- 3. Operating principles 3.4 Standby mode control (patent pending) The MR4000 Series is capable of switching between two methods of output voltage control, normal operation mode and standby mode, in a single power supply. This IC uses the burst method for standby mode. Intermittent operation is performed under light loads to reduce the oscillation frequency and reduce switching losses. The burst method effectively reduces the standby input voltage under micro-loads. This IC uses a burst mode that performs intermittent operation without stopping IC control, thereby minimizing the output ripple. The Z/C pin is clamped to a voltage of VZ/C(burst) or less by an external signal to switch to standby mode control. To exit standby mode— i.e., to return to normal mode— the clamp of the Z/C pin voltage is released, and the VZ/C(burst) or higher voltage is applied to the pin. Fig. 3.5 Standby mode control In normal operation, the ON range of the main switching device is linearly controlled by voltage variations at the F/B pin. In standby mode, the current detection threshold of the Source/OCL (Emitter/OCL) pin switches from Vth(OCL) for normal mode to Vth(burst OCL) for standby mode, and the drain (collector) current is limited. The peak value of the drain (collector) current is set by the current detection threshold, and the burst mode is selected. In standby mode, oscillation occurs when the voltage Fig. 3.6 Standby mode control sequence at the F/B pin is VF/B(burst start) or higher. Oscillation stops when this voltage is VF/B(burst stop) or lower. Since the output voltage control in standby mode sets the peak value of the drain (collector) current for each oscillation cycle, the duty ratio of the oscillating and non-oscillating intervals varies to ensure a constant voltage. Fig. 3.7 Standby signal receiving sequence Shindengen Electric MFG.CO.,LTD -9- 3.5 Output voltage control (normal operation) 5Vref The MR4000 Series controls output voltage with an ON range proportional to voltage at the F/B pin. IF/B Controlled linearly, the ON range is ton(min) when the voltage at the F/B pin is 1.5 V and becomes ton(max) when the voltage is 4.5 V. A current of IF/B flows at the F/B pin. The impedance of the photocoupler transistor connected externally between the F/B pin and GND varies depending on the control signal from the secondary output detection circuits, which controls the ON range of the main switching device to produce a constant voltage. The output voltage is controlled by varying the impedance of the photocoupler. 2 F/B pin Output voltage error detection feedback signal Droop resistor ton (max) The maximum ON range is limited by setting the maximum value for the voltage at the F/B pin using a resistor connected externally between the F/B pin and GND. Thus, the droop point is determined. ton (min) 1.5 4.5 Feedback voltage VF/B [V] Fig. 3.8 Output voltage control 3.6 Soft drive circuit (patent pending) The MR4000 Series supplies the main switching device gate drive voltage from two separate drive circuits. A voltage exceeding the threshold for the main switching device is supplied from the first drive circuit at the leading edge of the drive voltage waveform to turn the main switching device on at the optimal timing. The drive voltage is then gradually supplied from the second drive circuit (see Fig. 3.9). The gradual supply of the drive voltage reduces drive losses and reduces noise due to the gate charge current and the current discharged when the resonating capacitor switches on. Fig. 3.9 Comparison of drive circuits Shindengen Electric MFG.CO.,LTD - 10 - 3. Operating principles 3.7 Circuit for load shorts The MR4000 Series is designed so that voltage droop occurs under excessive load, causing the output voltage to drop, and so that the control coil voltage drops proportionally. When the control coil voltage falls below VZ/C(burst), the control switches to standby mode, and the Source/OCL (Emitter/OCL) pin threshold changes from Vth(OCL) to Vth(burst OCL), thereby limiting the drain (collector) current to approximately 1/10 of its previous value. This design reduces the stress on the MR4000 Series IC in the case of a load short and controls the short-circuit current to the secondary diode and the load circuit. Fig. 3.10 Circuit for load shorts 3.8 Collector pin (MR40XX Series) The collector pin on the main switching device (Pin 7) The transformer must be designed and the resonating capacitor must be set to ensure that VCE(max) is less than 900 V. Depending on input conditions, the collector pin may be subject to reverse bias for a certain period during partial resonance. This IC uses the second-generation high-speed IGBT as the main switching device. Unlike MOSFETs, this device has no body diode structure and thus requires the connection of an external high-speed diode between the Collector and Emitter/OCL pins (see Fig. 3.12). 3.9 Thermal shutdown circuit (TSD) The MR4000 Series incorporates a thermal shutdown circuit. The onboard IC is latched at 150°C (typical), after which oscillation is halted. Unlatching is achieved by momentarily dropping the voltage at the VCC pin to VUL (unlatch voltage) or lower. 3.10 Overvoltage protection circuit (OVP) The MR4000 Series incorporates an overvoltage protection circuit (OVP). Latching occurs when the control coil voltage exceeds VOVP, providing indirect overvoltage protection for the secondary output. Unlatching is achieved in the same manner as for the overheat protection circuit. 3.11 Leading edge blank (LEB) The MR4000 Series has the leading edge blank function. This function improves the margin of noise by rejecting trigger signals from the drain current detection circuit for a certain time after the main switching device is turned on. This function prevents false detections due to the gate drive current produced the moment the main switching device is turned on or due to the discharge current of a resonating capacitor. Shindengen Electric MFG.CO.,LTD - 11 - 3. Operating principles 3.12 Malfunction prevention circuit (patent pending) On-trigger is disabled during this period. tondead The current-critical operation of the MR4000 Series ensures that the main transformer does not become saturated as long as the droop setting is optimized. At startup and in the event of a load short, the output voltage is significantly lower than the set voltage. Since the control coil voltage is proportional to the output voltage, it also drops significantly, and the on-trigger timing may be incorrectly detected due to the ringing voltage generated while the main switching device is OFF. The device may then be turned on before the current-critical point. To counter this problem, the MR4000 Series incorporates a circuit to prevent on-trigger error at startup or in the event of a load short. This function disables the on-trigger for a period, tondead, after the main switching device in the IC is turned off (On-dead time). This prevents false detection due to the ringing voltage while the device is OFF. This design permits detection of the transformer secondary current of 0 A to turn on the main switching device even at startup or in the event of a load short. This prevents the magnetic saturation of the transformer. Approx. 0.3 V [VZ/C] [IC(ID)] Enlarged view [Secondary rectification diode] [VZ/C] [ID(IC)] [Secondary rectification diode] [VDS(VCE)] [VOUT] Fig. 3.11 Malfunction prevention circuit 3.13 Overcurrent protection circuit A current detection resistor is connected between the Source/OCL (Emitter/OCL) pin and GND to detect currents between the source (emitter) of the main switching device and the source (emitter) current detection pin. During stable operation, the main switching device current is limited by pulse-by-pulse operation with the Vth(OCL) threshold. During standby, the threshold changes to Vth(burst OCL), and the oscillation noise from the transformer due to burst oscillation is reduced. Fig. 3.12 Current detection resistor Shindengen Electric MFG.CO.,LTD - 12 - MR4000 Series Application Note 4. Design procedure This design procedure provides an example of an electrical design procedure. Confirm that insulation materials, insulation configurations, and structures meet the safety standards specified by the relevant authorities. 4.1 Design flow chart Specifications determined Main transformer design Reexamination Selecting primary circuit components Cooling design Refer to: [4.2 Reference conditions for main transformer design] Refer to: [4.3 Reference formulas for main transformer design] P.13 P.14 Refer to: [4.4 Selecting constants for peripheral components] P.16 Refer to: [4.5 Selecting constants for droop circuit] P.17 Refer to: [4.6 Cooling design] P.18 Trial manufacture Operational checks Problem found No problems Completion 4.2 Reference conditions for main transformer design The values given below are provided for reference only. They should be adjusted to suit specific load conditions. Symbol Unit VAC(min) Vo Io Io(max) η V V A A Minimum oscillation frequency f(min) kHz ON duty ratio Control coil voltage Effective cross-sectional area of transformer core Magnetic flux density variation Coil current density D VNC Ae ΔB α V 2 mm mT 2 A/mm Minimum input voltage Rated output voltage Rated output current Maximum output current Efficiency Reference value MR47XX MR40XX Series Series ― ― ― ― 0.80 - 0.85 30k 25k 25k 50kHz 40kHz 50kHz 0.40~0.55 0.28~0.55 0.50~0.70 15 - 17V ― 250 - 320mT 2 4 - 6A/mm MR45XX Series Shindengen Electric MFG.CO.,LTD - 13 - 4. Design procedure 4.3 Reference formulas for main transformer design 1 Minimum DC input voltage VDC(min) 1.2 VAC(min) [V] 2 Maximum DC input voltage VDC(max) 2 VAC(max) [V] 3 Oscillation cycle T(max) 4 Maximum ON Period ton(max)1 D f(min) [s] 5 Maximum OFF period toff(max) N S1 VDC(min) ton(max)1 tq N P (VO1 VF1) [s] 6 Resonance period tq 1 [s] f(min) 2π LP C q 2 Resonance ( 共振周期 cycle 1 ) 2 [s] 7 Maximum load power PO(max) VO I O(max) [W] 8 Maximum output power (reference value) PL 1.3 PO(max) [W] 9 Peak drain (collector) current I DP(I CP) 10 Primary coil inductance LP 11 Number of turns in primary coil NP 12 Core gap lg 4π 10 2 PL η VDC(min) D VDC(min) ton(max)1 I DP(I CP) VDC(min) ton(max)1 10 9 ΔB A e Ae N P 2 LP [A] [H] [Turn] 10 [mm] The gap Ig is the center gap value. Review the transformer core size and oscillation frequency and redesign if Ig is 1 mm or greater. Shindengen Electric MFG.CO.,LTD - 14 - 4. Design procedure (VO1 VF1 ) N P ( 1 - ton(max)1 - tq ) f(min) VDC(min) ton(max)1 13 Number of turns in control output coil N S1 14 Number of turns in noncontrol output coil N S2 N S1 VO2 VF2 VO1 VF1 [Turn] 15 Number of turns in control coil N C N S1 VNC VFNC VO1 VF1 [Turn] [Turn] Consider the secondary diode forward voltage VF for each output when determining the number of turns in an output coil. VFNC is the control coil voltage rectification diode forward voltage. The reference value for determining the control coil voltage VNC(min) is 15 V to 17 V. If the VNC(min) is too small, startup characteristics may degrade, making startup difficult. If the VNC(min) is too large, the overvoltage latch stop voltage VOP may be reached relatively easily. Check the VNC(min) voltage within an actual circuit at the design stage to determine the optimal value. 16 Primary coil size ANP 17 Secondary coil size A NS 2 D PO 2 α 3 ηVDC(min) ton(max)1 f(min) 2 1 D (tq f(min) ) I O α 3 (toff(max) tq ) f(min) [mm ] 2 [mm ] ANC = 0.2 mm dia. is recommended for the NC coil to simplify calculations. Shindengen Electric MFG.CO.,LTD - 15 - 4. Design procedure 4.4 Selecting constants for peripheral components The table below gives constants for MR4000 peripheral components. Reference value MR45XX MR47XX MR40XX Series Series Series Component C112 C113 C114 C115 R113 R114 R115 R116 R117 R151 D111 DZ151 This capacitor determines the resonance frequency. Select the value based on noise, efficiency, and other factors. This is the power supply voltage rectification capacitor. If the value is small, operation at startup easily becomes intermittent. If this is too large, startup time will lengthen. This is the partial resonance adjustment capacitor. Adjust this capacitor with R115 so that turn-on occurs at the resonance trough. This capacitor is used to reduce noise at Pin 2. It is also beneficial for gain phase adjustments. If the value is too large, the frequency response may degrade. This is the current limiting damper resistor for C108. Select the value after considering noise, efficiency, and other factors. This is the overcurrent detection resistor. It determines the droop point. This resistor limits the Z/C pin current. This resistor limits the Z/C pin current. Adjust the value according to the droop characteristics. Set to a value slightly higher than the droop point set with R114. This resistor compensates for droop based on the input voltage. Adjust the value based on droop characteristics. 1200p - 3300pF - 330pF 820pF - 2200pF 47 - 100μF 10p - 330pF 4700pF 100p - 2200pF 0 to several ohms See [4.5 Selecting constants for droop circuit]. Approximately 20 kΩ Approximately 10 kΩ Select a high-speed diode in the 900 V and 1A class. This zener diode compensates for droop based on the input voltage. Tens of kΩ Not required Not required Not required Approximately 50 kΩ High-speed diode, 900 V and 1 A class See Section 4.5. L101 R101 C103 F101 T101 L201 Vin C101 D201 C104 C201 C106 D101 C204 VO R266 C105 C112 R114 C262 D111 R113 9 7 5 C115 PH111 PH111 C113 R201 D112 4 IC111 2 R261 R116 R115 1 R202 R262 C261 3 PH141 D151 Q241 DZ151 IC261 R117 SW241 R248 D141 R265 R151 R241 PH141 R247 R263 C114 Fig. 4.1 MR4000 Series reference power supply circuit R151, D151 and DZ151 are additional components for auto-sensing input specifications. Shindengen Electric MFG.CO.,LTD - 16 - 4. Design procedure 4.5 Selecting constants for droop circuit The following are methods of determining the constant of a droop circuit. They are recommended for the MR4000 Series standard power supplies. 4.5.1 MR45XX Series The following is the method recommended for the MR45XX Series standard circuit. (1) Apply the following formula to calculate the overcurrent detection resistance R114: R114 Vth(OCL) [Ω] I DP (I CP) 5 MR4000 3 Vth(OCL) Overcurrent limit threshold voltage IDP(ICP) Drain (Collector) peak current at maximum output power 2 D112 4 R117 R114 C115 (2) Adjust R117 on an actual board. Set a droop point slightly higher than that set with R114. This value will be on the order of several tens of kΩ. PH111 Fig. 4.2 MR45XX Series droop circuit 4.5.2 MR40XX Series The following method is recommended for the MR40XX Series standard circuit. (1) Apply the following formula to calculate the overcurrent detection resistance R114: R114 Vth(OCL) [Ω] I DP (I CP) 5 MR4000 3 Vth(OCL) Overcurrent limit threshold voltage IDP(ICP) Drain (Collector) peak current at maximum output power 2 D112 4 DZ151 R117 R151 D151 R114 C115 (2) Adjust R117 on an actual board. Set a droop point slightly higher than that set with R114. This value will be on the order of several tens of kΩ. PH111 Fig. 4.3 MR40XX Series droop circuit (3) Select the voltage for DZ151, a zener diode that compensates for droop based on the input voltage. Apply the following formula to calculate the zener voltage: The compensation beginning voltage is assumed to be 150 V. Zener ツェナ電圧 1.3 150 voltage NC [V] NP (4) Adjust R151, a resistor that compensates for droop based on the input voltage, on an actual board. The value of R151 is approximately 50 Ω. (5) Set C115 at about 2200 pF. Shindengen Electric MFG.CO.,LTD - 17 - 4. Design procedure 4.6 Cooling design Tj(max) for the MR4000 Series is 150°C. Since the operation of the MR4000 Series is accompanied by an increase in temperature associated with power losses, you must carefully consider the type of heat sink needed. Additionally, if the design must ensure that Tj(max) is not exceeded, you must also consider the thermal shutdown function (TSD = 150°C (typical)). The extent to which Tj is derated in a design is critical for improving reliability. 4.6.1 Junction temperature and power losses Most power losses that occur while the devices in the MR Series operate are associated with the internal MOSFET. If most power losses are considered ON losses, they may be expressed as follows: PD =VDS ×ID The temperature increase ΔTj attributable to power losses PD is expressed as follows: ΔTj +Ta ≦Tj(max) If TSD(min) is assumed to be 120°C, considering TSD = 150°C (typical), PD is constrained to satisfy the following equation: ΔTj+Ta≦TSD(min) 4.6.2 Junction temperature and thermal resistance Tj may be calculated as follows using thermal resistance θja. Tj =( PD ×θja) +Ta Junction-to-ambient thermal resistance Junction-to-case thermal resistance Case-to-fin thermal resistance (contact thermal resistance) Fin-to-ambient thermal resistance (fin thermal resistance) θja, the junction-to-ambient thermal resistance, is expressed as follows: θja =θjc +θcf +θfa Symbol Unit θja °C /W θjc °C /W θcf °C /W θfa °C /W 4.6.3 Cautions for cooling design The thermal shutdown (TSD) protective function stops and latches operation at 150°C in the event of abnormal heat buildup in the MR Series. This means circuit design must incorporate a cooling design whereby the temperature is sufficiently derated. Shindengen recommends setting a cooling design target so that the case temperature will not exceed 100°C. Shindengen Electric MFG.CO.,LTD - 18 - MR4000 Series Application Note 6. Supplementary design information This chapter provides supplementary information for MR4000 Series power supply circuits. Use this information when designing or evaluating MR4000 Series power supply circuits. Supplementary design information: Contents 6. Supplementary design information 51 6.1.1 VCC control 51 (1) Increasing the damper resistance 51 (2) NC coil winding method (3) Adding a dummy resistor 6.1.2 Ringing voltage at turn-off of main switching device 52 (1) Transformer leakage inductance 52 (2) Clamp circuit 6.1.3 Resonating capacitor 54 Selecting the resonating capacitor 54 (2) Capacity of resonating capacitor 6.1.4 Constants of components around Z/C pin in the circuit 55 (1) Partial resonance capacitor C114 55 (2) Partial resonance resistor R115 (3) Z/C pin current limiting resistor R116 6.1.5 Enhancing the peak surge current of VCC pin 56 6.1.6 Phase correction 57 (1) Insert C and R between the cathode and REF of the shunt regulator. (2) Insert C and R between the front of the secondary LC filter and REF of the shunt regulator. (3) Insert C and R between the rear of the secondary LC filter and REF of the shunt regulator. (4) Place the power supply side of the photocoupler in front of the LC filter. 6.2 Noise reduction 57 58 6.2.1 Redesigning the transformer 58 6.2.2 Changing Y capacitor 58 6.2.3 Using a snubber circuit 58 6.2.4 Connecting a capacitor to a secondary diode in parallel 59 6.2.5 Capacitive coupling 59 6.2.6 Other measures 59 6.3 Supplemental information on surface mounting 60 6.3.1 Greasing 60 6.3.2 Screws 60 6.3.3 Radiation fin 60 Shindengen Electric MFG.CO.,LTD - 49 - 6. Supplementary design information 6.4 Precautions for waveform measurements 61 6.4.1 Isolating the AC line 61 6.4.2 Simultaneous measurement of primary and secondary sides 61 61 6.5 Notes on pattern design 62 6.5.1 Pattern design for primary side 62 6.5.2 Pattern design around Nc coil 62 6.5.3 Pattern design for secondary side 62 6.5.4 Pattern design around GND pin 62 6.5.5 Connecting a capacitor 62 6.5.6 Pattern of C114 62 6.5.7 Pattern of R116 63 6.5.8 Location of OCL resistor 63 6.6 Application circuit examples 64 6.6.1 Indirect control 64 6.6.2 Oscillation stop circuit in case of low voltage input 65 6.6.3 Remote ON/OFF circuit for MR4000 Series 65 6.6.4 OVP latch circuit by secondary side detection using auxiliary coil 66 6.7 Troubleshooting list 67 6.8 Glossary 69 6.8.1 Power supply operation 69 6.8.2 Transformer design 70 6.8.3 IC functions 70 6.8.4 Other 72 Shindengen Electric MFG.CO.,LTD - 50 - 6. Supplementary design information 6.1 Supplementary notes on design 6.1.1 VCC control Since the IC control current is very low, VCC can be significantly affected by the ringing voltage caused by transformer leakage inductance. This will increase the VCC voltage of the MR4000 Series beyond the design value. Under certain load conditions, the IC may be latched and stopped or the VCC may become too low. The ringing voltage caused by the transformer leakage inductance is reduced with a DCR snubber circuit. Several other solutions are also available, as shown below. (1) Increasing the damper resistance Increasing this resistance reduces voltage variations. Increasing the resistance will affect VCC. Make sure the design accounts for possible stoppage of MR4000 Series products due to a fall in VCC. Set the resistance on an actual board between several ohms and tens of ohms. Note that a light load may decrease efficiency under certain circumstances. 4 MR4000 3 Increase this resistance. Fig. 6.1 Damper resistance (2) NC coil winding method Bring the NC coil into closer contact with a secondary coil that has limited contact with the primary coil. Doing so will reduce the ringing generated in the NC coil. This is our recommended winding method. Fig. 6.2 Transformer winding to improve contact (3) Adding a dummy resistor If using a dummy resistor increases power consumption and decreases efficiency, this circuit will improve these performance somewhat. If the VCC voltage exceeds the level determined by the zener diode, the dummy resistor will control the voltage increase. We recommend a zener diode for 16 V or higher. Fig. 6.3 Adding a dummy resistor Shindengen Electric MFG.CO.,LTD - 51 - 6. Supplementary design information 6.1.2 Ringing voltage at turn-off of main switching device A significant voltage surge component is generated in the main switch if the transformer leakage inductance is too large or if a relatively high current is output. The most effective way to reduce the voltage surge component is to reduce the leakage inductance. The voltage surge component can be also reduced by a clamp circuit. Reducing the voltage surge component protects the main switch. In the case of a multi-output power supply, it also improves cross regulation in the outputs. (1) Transformer leakage inductance When the main switching device is turned off, a ringing voltage is added to the voltage, as shown in Fig. 6.4, due to the leakage inductance of the transformer primary coil. The voltage applied to the main switching device must be designed to accommodate the ringing voltage. The leakage inductance of the primary coil is measured as shown in Fig. 6.4. Fig. 6.4 Leakage inductance (2) Clamp circuit A clamp circuit may be required if the withstand voltage limit of the main switching device is exceeded due to load or other conditions or if the design margin is insufficient due to a ringing voltage caused by the leakage inductance. We recommend a DCR snubber circuit as a clamp circuit. See the next page for DCR snubber circuit design procedures. 3 5 9 MR4000 Fig. 6.5 DCR snubber circuit Shindengen Electric MFG.CO.,LTD - 52 - 6. Supplementary design information Design of DCR snubber circuit Use the following formulas to estimate the constants for a DCR snubber circuit: If all the energy of the leakage inductance LI is assumed to be consumed in the snubber circuit, the following formula holds true: 1 1 2 L l I DP (I CP ) C S 1.2V NP VNP 2 2 2 …(1) Energy of leakage inductance LI = Energy of snubber capacitor CS R S I S 1.2 VNP …(2) Voltage of snubber resistor RS = Charging voltage of snubber capacitor CS R S I S 2 1 L l 2 I DP (I CP ) 2 f …(3) 2 Power consumption of snubber resistor RS = Power of leakage inductance LI If we assume that LI is 2.5% of the primary inductance LP and that the charging voltage of snubber capacitor CS is 1.2 times VNP, CS is given as follows: From formula (1), C S 0.625 L P I DP (I CP ) 2 VNP 2 [F] From formulas (1) and (3), we obtain formula (4). R S I S Formula (2) is equivalent to formula (5). I S 1.2 2 1 2 2 RS 2 f …(4) …(5) We substitute CS into formula (6) to obtain RS. R S 115.2 2 VNP When we substitute formula (5) into formula (4), we obtain formula (6). PRS, power consumption in RS is: PRS R S I S C S 1.2V NP V NP 1 RS VNP 2 f L P I DP (I CP ) 2 1 72 CS f …(6) [Ω] [W] These values assume that LI is 2.5% of the primary inductance LP and that the charging voltage of snubber capacitor CS is 1.2 times the value of VNP. Adjustments must be made on an actual board. Ll IDP(ICP) CS LP VNP RS IS f Leakage inductance Peak current of main switching device Snubber capacitor Primary inductance of transformer Flyback voltage generated with primary inductance LP Snubber resistor Current flowing to snubber resistor Oscillation frequency of power supply * Calculation example When oscillation frequency f = 25 kHz, LP = 0.5 mH, IDP = 5 A and VNP = 200V; CS = 0.2 uF, RS = 14.7 kΩ and PRS = 3.9 W. Fig. 6.6 Design of DCR snubber circuit Shindengen Electric MFG.CO.,LTD - 53 - 6. Supplementary design information 6.1.3 Resonating capacitor (1) Selecting the resonating capacitor The resonating capacitor must have the following characteristics: 1) The withstand voltage is significantly greater than that of the main switching device. 2) Tangent of loss angle tan δ is small. 3) The upper temperature limit is high. Ideally, use a mica or polypropylene capacitor. A low-loss ceramic capacitor should also be adequate. Consult with the manufacturer before using this capacitor type. (2) Capacity of resonating capacitor Noise is reduced by the resonance determined by the resonating capacitor and the primary coil inductance. This has both favorable and adverse effects, as shown in the table below. Consider these effects when setting the capacity of the capacitor. Item Efficiency during standby Heat buildup in the transformer Ringing voltage at turn-off of main switching device Noise Operating frequency Small ← Capacitor capacity → Large Increases Decreases Decreases Increases Increases Decreases Increases Decreases Increases Decreases Shindengen Electric MFG.CO.,LTD - 54 - 6. Supplementary design information 6.1.4 Constants of components around Z/C pin in the circuit D112 MR4000 4 At the design stage, keep in mind the following aspects of the constants for the components around the Z/C pin (Pin 1) in the circuit. 3 1 R115 C114 PH141 Fig. 6.7 Circuit around Z/C pin (1) Partial resonance capacitor C114 The capacity of C114 capacitor should be around 100 pF. Since the Z/C pin (Pin 1) is susceptible to noise, the capacity should not be lower. (2) Partial resonance resistor R115 Keep in mind the following when determining the value for R115: Trough 1) VCC Vin N C 5mA and 5mA R 115 R 115 N P The absolute maximum rating for the Z/C pin (Pin 1) is ±5 mA. Current flowing to the pin cannot exceed this level. (Vin represents the input capacitor voltage when the maximum input voltage is applied.) Small Large R115 Fig. 6.8 Adjusting the resonance trough 2) Determine R115 so that the main switching device is turned on at the trough of its partial resonance. (3) Z/C pin current limiting resistor R116 If requirements 1) and 2) of Section (2) above cannot be met simultaneously, add R116 as shown in Fig. 6.9. R116 should be around 10 kΩ. D112 MR4000 4 3 1 R115 is used to set the partial resonance trough of the main switching device. Set in the same way as described in Section (2) above. R115 R116 C114 PH141 Fig. 6.9 Addition of R116 Shindengen Electric MFG.CO.,LTD - 55 - 6. Supplementary design information 6.1.5 Enhancing the peak surge current of VCC pin This measure helps enhance resistance against surge currents applied from external sources. Add a capacitor between the VCC pin (Pin 4) and GND pin (Pin 3). Use a capacitor with good frequency characteristics. Place the capacitor as close as possible to the VCC and GND pins (Pins 4 and 3). Fig. 6.10 Capacitor between VCC pin and GND pin Shindengen Electric MFG.CO.,LTD - 56 - 6. Supplementary design information 6.1.6 Phase correction In an RCC circuit, delays in the phase of the photocoupler, capacitor, or coil may result in hunting. If so, oscillations may become audible or output voltage ripples may become very large. The following countermeasures are available: (1) Insert C and R between the cathode and REF of the shunt regulator. (2) Output (3) Insert C and R between the front of the secondary LC filter and REF of the shunt regulator. Output Insert C and R between the rear of the secondary LC filter and REF of the shunt regulator. (4) Output Place the power supply side of the photocoupler in front of the LC filter. Output If the oscillation tends to be intermittent under light load, one solution is to lower the feedback gain. Insert a resistor as shown in Fig. 6.11. Set the resistor to 2.2 kΩ or less. D112 MR4000 4 3 2 R117 C115 PH111 Fig. 6.11 Lowering feedback gain Shindengen Electric MFG.CO.,LTD - 57 - 6. Supplementary design information 6.2 Noise reduction This section describes noise reduction methods for the MR4000. Check these methods on an actual board to determine the best combination of methods. 6.2.1 Redesigning the transformer Redesign the transformer to reduce noise, considering the following factors. Proceed carefully with respect to the withstand voltage, operating frequency, and other relevant parameters of the main switching device. (1) Improve coil contact. That will reduce ringing at turn-off and reduce noise. (2) Increase the ON duty ratio. Taking full advantage of the partial resonance function will reduce surge currents at turn-on and reduce noise. (3) Decrease the operating frequency. That will reduce noise attributable to fundamental waves or harmonics thereof. 6.2.2 Changing Y capacitor We can reduce noise not only by changing the location of a Y capacitor or adding a Y capacitor, but by also changing the capacity. The effect varies with PCB patterns. Check carefully with an actual board. (1) Try changing the location of the Y capacitor at the filter. (2) Connect to ground from the negative side of the input capacitor. (3) Connect to ground from the positive side of the input capacitor. ① AC in ③ ② Fig. 6.12 Considerations for Y capacitor 6.2.3 Using a snubber circuit (1) Add a DCR snubber. That will lower the peak of a ringing voltage at turn-off and reduce noise. (2) Add a damping resistor. Connect to the resonating capacitor in series. This will advance the damping of a ringing voltage at turn-off and reduce noise. (3) Connect a capacitor in parallel to the DCR snubber diode. This will reduce noise from the diode handling switching. Ideally, use a mica or polypropylene capacitor as the capacitors in (2) and (3). A lowloss ceramic capacitor should also prove adequate. Consult with the manufacturer before using this type of capacitor. ① ③ ② 3 5 MR4000 9 Fig. 6.13 Snubber circuit Shindengen Electric MFG.CO.,LTD - 58 - 6. Supplementary design information 6.2.4 Connecting a capacitor to a secondary diode in parallel The secondary diode handles switching. Add a capacitor to reduce noise. Try the diodes on an actual board to determine which is most effective. It may help to connect a damping resistor to this capacitor in series. NS1 Ideally, use a mica or polypropylene capacitor. A low-loss ceramic capacitor should also prove adequate. Consult with the manufacturer before using this type of capacitor. NS2 Fig. 6.14 Adding a capacitor to the secondary side 6.2.5 Capacitive coupling You can also couple the primary GND and the secondary GND with a capacitor. Take great care to consider the leakage current between the primary and secondary and the safety standards. NP NS1 NC NS2 Fig. 6.15 Capacitive coupling 6.2.6 Other measures (1) Place bead cores around the drain (collector) pin (Pin 9). (2) Place bead cores around the secondary diode. Shindengen Electric MFG.CO.,LTD - 59 - 6. Supplementary design information 6.3 Supplemental information on surface mounting 6.3.1 Greasing When using a radiation fin (heat sink), apply a thin uniform film of silicon grease between the MR4000 Series and the fin. This will reduce contact thermal resistance and enhance the heat radiation effect. 6.3.2 Screws Use M3 round head, pan head, binding head, or fillister head screws. Avoid countersunk head screws. Use plain washers and spring washers to keep the screws tight. Use small, plain 3-mm washers. Do not use washers that are 3.5 mm or larger or washers with one polished side. 6.3.3 Radiation fin The mounting surface of the radiation fin for the MR4000 series must be flat and free of any unevenness, torsion, or warping to protect the device from excessive stress and to avoid impairing radiation effects. Make sure the edge of the mounting hole is free of burrs. Use a long fin positioned laterally. This shape results in more effective radiation than other shapes. Fig. 6.16 Mounting the radiation fin Shindengen Electric MFG.CO.,LTD - 60 - 6. Supplementary design information 6.4 Precautions for waveform measurements 6.4.1 Isolating the AC line When measuring the MR4000 Series or a peripheral circuit using an oscilloscope or other such instrument, isolate the AC line between the circuit to be measured and the measuring instrument to prevent electric shock and leakage. Fig. 6.17 Isolating the AC line 6.4.2 Simultaneous measurement of primary and secondary sides In the case of a power supply using the MR4000 Series, the AC input (primary) side and the DC output (secondary) side are isolated from each other by a transformer. Do not use a measuring instrument on the primary and secondary sides simultaneously. Otherwise, GNDs of different potentials may be connected; this can affect the operation of the power supply or measurement results. (Example of method to avoid: Measure the primary and secondary waveforms simultaneously using the voltage probe of an oscilloscope.) To check both the primary and secondary waveforms simultaneously, use a differential probe for one of the two. MR Do not measure simultaneously. Measurement GND Fig. 6.18 Simultaneous measurement of primary and secondary sides Shindengen Electric MFG.CO.,LTD - 61 - 6. Supplementary design information 6.5 Notes on pattern design Patterns must be as short as possible to make the loops as small as possible. Keep the following in mind at the design stage: 6.5.1 Pattern design for primary side C106 6.5.2 Pattern design around Nc coil D112 C112 4 R114 3 MR4000 5 9 3 MR4000 C113 A high-speed switching current flows through the loop. Reducing the loop area will reduce noise. Make the loop connecting the transformer, D112, and C113 thick and short. 6.5.3 Pattern design for secondary side 6.5.4 Pattern design around GND pin Short D201 L201 C201 C202 Short Place as close to the output pin as possible. Make the loop connecting the transformer, rectification diode, and output capacitor thick and short. Place the capacitor at the rear of the output choke coil as close to the output pin as possible. Connect the GND pin (Pin 3) directly to the negative side of C106. Do not connect any other component. Do not place the end of the control circuit inside R114 (closer to GND pin). 6.5.5 Connecting a capacitor 6.5.6 Pattern of C114 Make sure the pattern passes through the capacitor pads. The Z/C pin (Pin 1) is susceptible to noise. Connect the pattern near the Z/C pin (Pin 1) and GND pin (Pin 3). Shindengen Electric MFG.CO.,LTD - 62 - 6. Supplementary design information 6.5.7 Pattern of R116 6.5.8 Location of OCL resistor 9 MR4000 5 3 C112 R114 Place close to Pins 3 and 5. For patterns incorporating R116, make the pattern short as shown in the diagram above. Place the current detection resistor as close as possible to the OCL pin (Pin 5) and GND pin (Pin 3). The OCL detection level is low and readily affected by the inductance or resistance component of the current detection loop wire. Placing R114 close to Pins 3 and 5 will help prevent errors due to noise and increase detection accuracy. Shindengen Electric MFG.CO.,LTD - 63 - 6. Supplementary design information 6.6 Application circuit examples 6.6.1 Indirect control If output voltage precision is not an issue, a constant voltage control can be provided at the primary side without using a photocoupler. Figure 6.19 shows an example of 12 V output design. (1) Circuit configuration The circuit consists of a transistor and a current control resistor that control the F/B pin (Pin 2) and a zener diode that detects voltage. In cases where an increase in voltage under light load is an issue, add a dummy resistor on the secondary side. (2) Circuit operation The zener diode in the additional component for indirect control surrounded in a frame in the diagram detects the output voltage of the control coil. The detection signal controls the F/B pin (Pin 2) directly via the transistor. (3) Problem A ringing voltage attributable to transformer leakage inductance can result in significant variations in voltage precision. This can also increase the output voltage under a light load. Fig. 6.19 Indirect control Shindengen Electric MFG.CO.,LTD - 64 - 6. Supplementary design information 6.6.2 Oscillation stop circuit in case of low voltage input This protection circuit prevents input from a 100 V group power source to a 200 V group power supply. The circuit monitors input voltages. On detecting an input of 100 V, the circuit stops the oscillation of the MR4000 series. On detecting an input of 200 V, the circuit allows regular oscillation. C106 9 NP IC111 C113 4 D112 (1) Circuit configuration The circuit consists of a transistor Q1 that short-circuits NC R1 2SC945 the input voltage detection resistor and the F/B pin (Pin 2), 2 62kΩ 360kΩ a transistor Q2 that turns Q1 off, and a zener diode that 3 Q1 2SC945 corrects for variations in VBE of Q2 and temperature 360kΩ Q2 characteristics. 8.2V (2) Circuit operation The transistor Q1 short-circuits the F/B pin (Pin 2) of the 39kΩ MR4000 Series until the input voltage Vin exceeds 138 0.033μ F 10kΩ V (a maximum voltage in the 100 V group), thereby Fig. 6.20 Oscillation stop circuit in case of low keeping the MR from oscillating. When Vin reaches 170 voltage input V (a minimum voltage in the 200 V group), Q2 is turned on, turning Q1 off. The MR4000 Series begins oscillating. (3) Problem Efficiency is reduced during standby. Standby characteristics are decreased due to the current required for the input voltage detection circuit and the current flowing to Q1 and Q2. If the resistor R1 is set to 56 kΩ or less, the IC can not start up. (4) Precautions If resistor R1 is set to 56 kΩ or less, the IC may not start up. Carefully consider the startup characteristics if a resistor or any other component is connected to the VCC pin (Pin 4) of the MR4000 Series for other purposes. 6.6.3 Remote ON/OFF circuit for MR4000 Series The oscillation of MR4000 Series devices can be turned on and off with an external ON/OFF signal. (1) Circuit configuration The circuit consists of a transistor that short-circuits the F/B pin (Pin 2) and an external ON/OFF signal on the primary side. The external signal can be input from the secondary side using a photocoupler instead of the transistor. (2) Circuit operation Fig. 6.21 MR4000 Series ON/OFF Upon receipt of the external signal, the transistor is turned on, shortcircuit circuiting the F/B pin (Pin 2) and halting the power supply. When a low external signal is input, the transistor is turned off, and oscillation resumes. (3) Problem If the power supply has been turned off by the external signal, the built-in startup circuit will continue charging and discharging the VCC, resulting in losses. Shindengen Electric MFG.CO.,LTD - 65 - 6. Supplementary design information 6.6.4 OVP latch circuit by secondary side detection using auxiliary coil R1 100Ω PC1 PS2501 4 3 C113 35V 100μF D1 D1NL20U C1 0.047μF D201 L201 +12V Nc2 D112 Nc1 D1NL20U Ns1 C201 C202 C205 ZD2 15V,B2 470Ω GND PC1 PS2501 Fig. 6.22 OVP circuit using auxiliary coil (1) Circuit configuration This circuit consists of NC2, an auxiliary coil; PC1, a photocoupler for OVP; R1; C1; D1; and ZD2, a zener diode for secondary output detection. (2) Circuit operation Set the NC2 coil voltage to 22 V (VCC(OVP) x 1.1) or greater. If the output voltage exceeds the zener voltage, as the F/B pin is opened, the photocoupler will activate. As a result, the NC2 coil voltage is applied to the VCC pin (Pin 4) of the MR4000 Series, the VCC voltage exceeds 20 V, and the IC is latched and stopped for OVP. (3) Precautions Take steps to ensure the circuit does not exceed 21 V, the absolute maximum rating for the withstand voltage of the IC. Proceed carefully while referring to the constants of the components in the diagram above. Shindengen Electric MFG.CO.,LTD - 66 - 6. Supplementary design information 6.7 Troubleshooting list The table below shows common problems with power supply designs using the MR4000 Series, possible causes, and solutions. Problem Possible cause The polarity of the transformer is incorrect. Solution Check winding directions for NP, NS, and NC. The droop compensation circuit is inadequate. Adjust the droop compensation circuit. The ON range setting (resistance between the F/B pin and GND pin) is small. A constant current load or constant power load is used. Change to a constant resistance load. Adjust the number of turns in the NC coil. Review the transformer coil structure. The overvoltage latch is on. Combine a zener diode and a resistor to clamp VCC. Insert a resistor between the NC coil and rectification diode. The input to the Z/C pin is incorrect. Review the circuit around the Z/C pin. The IC is activated under a heavy Startup under a light load is recommended for the MR4000 load. Series. Ton(max) has reached the limit value. Review the transformer design. There are too few turns in the NC coil. Adjust the number of turns in the NC coil. The transformer is causing magnetic Review the core ΔB. saturation. Adjust the resistance between the F/B pin and GND pin. The droop compensation circuit is Adjust the droop compensation circuit. MR4000 Series is 2 inadequate. Adjust the resistance between the F/B pin and GND pin. defective. Provide a snubber circuit. The voltage exceeded the withstand Review the transformer design. level of the main switching device. Review the transformer coil structure. Adjust the current limiting resistance Adjust the current limiting resistance of the photodiode. A control output 3 voltage rises. of the photodiode. 1 Does not start up. A non-control 4 output voltage rises. Add a dummy resistor or damper resistor at the output Peak charging to the output capacitor end. due to a surge voltage Review the transformer design. The constants for the output voltage Reexamine the output voltage detection resistance. The output voltage detection circuit are inappropriate. or current does not The droop compensation circuit is Adjust the resistance between the F/B pin and GND pin. 5 reach the desired inadequate. Adjust the OCL resistance. level. Increase the oscillation frequency. Ton(max) has reached the limit value. Set the ON duty ratio lower. The heat sink is too small or missing. Provide a heat sink or replace with a larger one. Reduce the oscillation frequency. The switching loss is large. Use a smaller resonating capacitor. MR4000 Series The tightening torque is insufficient. Tighten at the torque recommended by Shindengen. 6 generate Apply silicone grease. Contact with the heat sink is poor. excessive heat. Insert a radiation sheet. Timing for partial resonance is Adjust the delay setting for partial resonance. incorrect. The partial resonance trough is high. Increase the ON duty ratio. The oscillation frequency is high. Reduce the oscillation frequency. The phase compensation circuit is Adjust the circuit around the shunt regulator. Intermittent inadequate. 7 oscillation occurs Increase the current limiting resistance on the diode side of under a light load. the photocoupler. The feedback gain is high. Connect a resistor in series with the transistor side of the photocoupler. Shindengen Electric MFG.CO.,LTD - 67 - 6. Supplementary design information Problem Possible cause Abnormal oscillation 8 during steady-state The phase has shifted. operation This results in hunting. 9 10 11 12 13 14 15 16 Solution Place the secondary F/B pin in front of L. Adjust the circuit around the shunt regulator. Adjust the circuit around the photocoupler. The droop operation is The droop circuit is inadequate. ineffective. Adjust the OCL resistance. Adjust the resistance between the F/B pin and GND pin. Redesign ON duty ratio. Review the transformer coil structure. The ON duty ratio is large. The transformer coupling is poor. The ratio of numbers of turns in coils is Review the transformer design. inappropriate. VDS or VCE exceeds the Adjust the resonating capacitor. withstand level. Provide a snubber circuit. The surge is large. Add a power clamper. Connect a resistor in series with the resonating capacitor. Adjust the current-limiting resistance of the The current to the photodiode is too low. photodiode. The IC cannot enter Increase the capacity of the capacitor between the standby mode. Noise is superimposed on the Z/C pin. Z/C pin and GND pin. Improve the PCB pattern. Adjust the number of turns in the NC coil. The oscillation halts Review the transformer coil structure. when the output load is The overvoltage latch is on. Combine a zener diode and a resistor to clamp VCC. increased. Add a damper resistor for VCC. The transformer Reinforce impregnation (e.g., double impregnation, generates an oscillating Transformer vibrations use of adhesive) tone in standby mode. Optimize the load. Increase the capacity of the capacitor between the Noise is superimposed on the Z/C pin. Z/C pin and GND pin. The input power is large in the case of a load Increase the current rating of the diode. The VF of the secondary diode is large. short. Use a Schottky diode. The transformer coupling is poor. Review the transformer coil structure. The resistor between the F/B pin and Make sure the voltage droops only with the OCL pin The droop point varies. GND pin is operating. resistance. The tan δ of the resonating capacitor is Use a capacitor with a smaller tan δ. large. The standby power is Adjust the resonating capacitor (carefully monitor large. The capacity of the resonating capacitor VDS or VCE to ensure that the withstand level is not is large. exceeded.) Shindengen Electric MFG.CO.,LTD - 68 - 6. Supplementary design information 6.8 Glossary This section provides a glossary of terms used in the MR Series Application Note, power supply reference data, and other technical materials. It provides various definitions for technical use, such as power supply design and IC functions. 6.8.1 Power supply operation [Resonating capacitor] A capacitor for a damper snubber circuit in a power supply circuit using partial resonance → Damper snubber [Clamper snubber] A snubber circuit consisting of diode, capacitor, and resistor at the primary coil end (DCR snubber) or a snubber circuit using a power zener diode → Snubber circuit [Gain and phase] Important parameters for a feedback control circuit. [Conducted emissions] Conducted noise fed back to the input side; also called input feedback noise [Output ripple voltage] Output voltage is not completely DC and has various superimposed frequency components. General ripple voltage components result from commercial and switching frequencies. [Droop characteristics] Output characteristics when an overcurrent protection function activates [Droop compensation circuit] A compensation circuit used to minimize the dependence of the droop function on input voltage [Snubber circuit] A circuit used to reduce stress on a switching device. Snubber circuits are divided into clamper snubber and damper snubber. [Damper snubber] A CR snubber circuit consisting of a resistor and a capacitor between the drain and the source or between the collector and the emitter of a main switching device. In a partial resonance power supply circuit, C represents a resonating capacitor and R a damper resistor. → Snubber circuit [Current-critical system] A power supply control system for an isolated flyback transformer in which the main switching device activates when the secondary diode is turned off [Input feedback noise] Conducted noise fed back to the input side; also called conducted emissions [Burst mode] Control mode for a switching power supply using intermittent oscillation With the MR Series, the drain current peak value during intermittent oscillation is limited to IDP(burst limit). Shindengen Electric MFG.CO.,LTD - 69 - 6. Supplementary design information [Hunting] A situation in which the gain or phase in a feedback control system is not adequate, resulting in abnormal oscillations [Feedback] Signal fed back to the primary control circuit upon detection of the output voltage Feedback is used for constant voltage control. [Radiated emissions] Disturbance field strengths released into the air; also called radiated noise [Partial resonance] A soft-switching method or technology used in a circuit that reduces switching losses at startup of the main switching device in a switching power supply [Radiated noise] Disturbance field strengths broadcast into the air; also called radiated emissions [Ringing voltage] In this application note, it refers in particular to the oscillation voltage immediately after the main switching device is turned off. 6.8.2 Transformer design [Duty ratio] A ratio of the ON range to the oscillation period; sometimes referred to as D. [TON-T ratio] The same as duty ratio [ON duty ratio] The same as duty ratio [Core gap] A gap in a transformer core In a flyback power supply, this gap is used to adjust inductance. [Control coil] A coil used to supply the source voltage to the internal IC of the MR Series and to output the Z/C signal. [Magnetic saturation] State in which the maximum magnetic flux density of a transformer is exceeded If magnetic saturation occurs, the inductor will not function; a sudden excessive current may flow and damage the power supply. [Magnetic flux density] The magnetic flux per unit area generated at the core by an excitation current 6.8.3 IC functions 【LEB】 See Leading edge blank. Shindengen Electric MFG.CO.,LTD - 70 - 6. Supplementary design information [OCP] See overcurrent protection. [OVP] See overvoltage protection. [TSD] See thermal shutdown. [Under voltage lock out] A function that incorporates several volts of hysteresis into startup characteristics. This function stabilizes startup characteristics; sometimes referred to as UVLO. [UVLO] See Under voltage lock out. [On-dead timer] A function that disables the main switching device for a certain period to prevent unintended operation due to the ringing voltage when turned off [On-trigger] With the MR Series, the Z/C pin (Pin 2) detects a falling edge of the control coil signal and uses it as a trigger signal to turn on the main switching device. [On-trigger disabled period] In switching operations, this refers to a period during which the turn-on signal is not accepted to prevent unintended operations due to ringing voltage when turned off. [Overvoltage protection] A function that limits the output voltage to prevent damage to the power supply sometimes referred to as OVP [Overcurrent protection] A function that limits the output current to prevent damage to the power supply; sometimes referred to as OCP [Thermal shutdown] A function that limits the IC junction temperature to prevent damage to the IC. If the temperature exceeds a certain level, the IC is latched and stopped; sometimes referred to as TSD; also referred to as overheat protection. → Latch stop [Soft drive] A drive system of the main switching device of a switching power supply that reduces noise and enhances efficiency under a light load. Shindengen has applied for a patent on this technology. [Negative edge] A falling edge of a rectangular wave [Latch stop] One of IC’s stop modes following activation of a protection function; in this mode, the IC will not restart unless power is applied again. Shindengen Electric MFG.CO.,LTD - 71 - 6. Supplementary design information [Leading edge blank] A function that prevents the main switching device from being turned off for a certain period to prevent unintended operations due to a surge voltage at turn-on; sometimes referred to as LEB [Restart timer] The MR Series re-oscillates in standby mode or at startup if it does not receive a trigger signal for a certain period of time. The restart timer determines this duration. 6.8.4 Other [Ultra fast IGBT] A switching device developed by Shindengen that offers sufficient speed characteristics for switching power supplies; employed as the main switching device in the MR2900 Series, MR40XX Series, and MR5000 Series. Shindengen Electric MFG.CO.,LTD - 72 - MR4000 Series Application Note Guides for MR Series Applications We offer various applications that make it easier to design power supply circuits using the MR Series. We will continue to update and add new data and know-how. Please contact our sales department to order reference materials or to inquire about the latest editions. Selection guide Lists the line-up of MR Series and provides product overviews. (We are currently working to include the MR4000 Series.) Application note MR1000 Series MR2000 Series MR4000 Series MR5000 Series Presents MR1000 Series operating principles, design procedures for power supply circuits, and supplemental design information. Presents MR2000 Series operating principles, design procedures for power supply circuits, and supplemental design information. Presents MR4000 Series operating principles, design procedures for power supply circuits, and supplemental design information. Presents MR5000 Series operating principles, design procedures for power supply circuits, and supplemental design information. Power supply reference data MR1000 Series MR2000 Series MR4000 Series MR5000 Series Provides power supply reference data for MR1000 Series and abnormal test tables. Provides power supply reference data for MR2000 Series and abnormal test tables. In preparation In preparation Shindengen Electric MFG.CO.,LTD - 73 -