International Rectifier • 233 Kansas Street, El Segundo, CA 90245 USA IGBT Protection in AC or BLDC Motor Drives by Toshio Takahashi The new IR2137 IGBT Gate Driver IC integrates Ground Fault and Over-Current Protection with Soft Shutdown, thus providing a compact and comprehensive IGBT protection scheme. 1. INTRODUCTION In the last decade, industrial AC drives have become more advanced in performance and more compact in size. This is largely due to the rapid development of power silicon technology, including the enhancement of IGBTs and of High Voltage Integrated Circuits. Additionally, this technological growth has been particularly accelerated for low horsepower (< 5 Hp) AC Drives. Yet the ground fault protection, a feature sought increasingly in motor drives of all power levels, is available widely only in the high-end models due to the sensors and other circuitry involved. The market, however, continues to demand a fully protected, yet inexpensive, system. To meet this demand, International Rectifier has introduced the IR2137: a new generation 3-phase IGBT gate driver, featuring full IGBT protection and advanced soft shutdown features. To understand traditional methods of IGBT protection, read Section 2. To understand the working of the IR2137 skip to Section 3. 2. TRADITIONAL METHODS OF IGBT PROTECTION 2-1 Background Theory for Protecting Against Failure One of the most common, and fatal, AC drive faults for IGBTs is the Over-Current condition. Table 1 outlines the causes for the three most common Over-Current modes. Over-Current Mode Line-to-Line Short Ground Fault Shoot Through Potential Causes Mis-wiring, Motor leads shorting, Motor phase-to-phase insulation breaking down Motor phase-to-phase insulation breaking down False IGBT turn-on Table 1: Potential Causes of Over-Current www.irf.com 1 In order to protect IGBT devices effectively during an Over-Current condition, one needs to focus on two factors. First, one needs to detect the type of Over-Current mode and shut the system down. In both Line-toLine and Shoot Through mode, the short-circuit current flows from and to the DC bus capacitors (Figures 1 and 3). Therefore, a shunt resistor in the ground path can detect these Over-Current conditions. However in the Ground Fault mode, the current flows from the AC line input, through the positive DC bus and high side IGBT, to the earth ground (Figure 2). Therefore, the Ground Fault condition has to be detected either with a shunt resistor on the positive bus line or by detecting the current in the output lines. Second, one needs to look at the AC drive architecture. Protection circuitry needs to be built in a manner that does not disrupt the drive system. For instance, Figure 4 shows a typical Floating Ground Reference Architecture in which the micro-controller (µC) is on the Floating Ground reference. Therefore, any Over-Current detection circuit needs to be isolated. Alternate architecture may require reduced or no isolation. 2-2 Traditional Methods of Over-Current Detection Method 1 One can detect the Line-to-Line Short and Shoot Through currents by inserting a Hall Effect sensor or a linear opto isolator across the shunt resistor. The device should be in series with the negative DC bus line. For Ground Fault protection, an additional Hall Effect leakage current sensor could be placed either on the AC line input or on the DC bus. The protection circuit is then implemented by using fast comparators. The output of these comparators is ‘OR’d with the micro-controller or PWM generator to initiate the shutdown of the gate signals. Method 2 If located in the motor phase output, each Hall Effect sensor uses 2 comparators. This is done because both positive and negative current polarities flow during a Line-to-Line Short condition. Another important consideration is the total propagation delay for shutdown. The delay time associated with the optical isolators in the gate drive and the Hall Effect sensor is typically more than 2 microseconds. Therefore, regardless of protection circuitry implementation, this delay should be added to the circuit delay, before matching it with the IGBT short circuit duration time. As shown in Figure 4, the configuration requires 2 Hall Effect sensors and/or opto isolators in addition to the protection circuit. The protection circuitry comprises of comparators (2), voltage references, capacitors, and resistors. Method 3 Another protection method is to use an IGBT de-saturation circuit. This discrete circuit can be constructed in the secondary side of the opto gate driver. (Opto isolated devices with in-built de-saturation circuits can also be found in the market). This circuit detects voltage build-up across the collector and emitter while the device is fully on. If the voltage exceeds a specified limit, the associated gate signal is shut off. A discrete circuit would require a comparator with voltage reference, a high voltage diode, and various resistors and capacitors. 2 www.irf.com 2-3 Traditional Methods of Over-Current Shutdown For shutting down an IGBT when an Over-Current condition is detected, a soft turn-off is preferred because it reduces a high voltage spike across the collector and emitter of the IGBT device at fault. Thus it provides a wider margin for the RBSOA limit during a short-circuit condition, allowing the snubber circuit to be significantly minimized or even eliminated. When implemented in the discrete circuit based on the floating ground reference architecture, a soft turn-off circuit can get very complex. Each IGBT gate drive circuit requires an additional fast opto isolator and soft turn-off circuit with the dedicated totem pole buffer transistors. Given circuit costs and complexities, a snubber circuit is preferred to the discrete soft shutdown circuit. For low Hp devices, the snubber circuit can be implemented with a high frequency type capacitor across the DC bus, near the IGBTs. 2-4 Problems with the Traditional Method A. Circuit Control Problems In a soft shutdown scheme, simultaneous shutdown of all 6 IGBTs is required to prevent a potential false turn-on while the IGBTs are in the soft shutdown mode. If a high side IGBT is turned off softly while the other IGBTs are in the middle of a switching transition within a PWM period, that IGBT can unintentionally be turned back on. It is extremely difficult to synchronize simultaneous shutdown using traditional architecture. B. Part Count, Size, and Cost Problems If the system requires full IGBT protection, including Ground Fault protection, and if it is based on the floating ground reference architecture, then the gate drive and protection circuit require the following major components (even without the soft shutdown feature): • 6 fast opto isolators • 2 fast Hall Effect sensors or fast linear opto isolators • 2 comparators • 4 floating 15V power supplies Hall Effect sensors and opto isolators are relatively large and bulky, and require a lot more space than a monolithic IC. In addition, if the system requires a soft shutdown function, 6 additional opto isolators and 6 buffer circuits (with a provision for soft turn off capability) are required. Thus, whereas low Hp AC drive systems are today moving toward smaller sizes, the above solutions provide neither the simplicity nor the integration of the gate drive and protection circuitry that is needed. The total cost, including assembly of the inverter system, is large due to the large number and bulkiness of components. Furthermore, components such as the Hall Effect sensors are still subject to manual assembly. To circumvent these issues, a small, integrated IC device that is capable of performing all the above functions is a necessity. www.irf.com 3 IR2137: 3-PHASE GATE DRIVER WITH INTEGRATED IGBT PROTECTION International Rectifier has now introduced the IR2137 to the AC drives market. This latest High Voltage Integrated Circuit provides a monolithic solution to driving all six IGBT gate drivers, while simultaneously providing full IGBT protection and soft shutdown. In contrast to the Floating Ground Reference architecture discussed in the previous section, the IR2137 circuit enables a simple structure. The differences between the two architectures are summarized in Table 2. Gate Drive IGBT Protection Additional Circuits Floating Ground System Six Fast Optical Isolators Two Hall Effect sensors and Two comparators Four floating power supplies Snubber circuit or discrete soft shutdown circuits Brake IGBT drive circuit with an optical isolator IR2137 solution IR2137 IR2137 integrated function with a shunt resistor and a comparator Eliminated (boot strap power) Eliminated by integrated soft shutdown function Eliminated by integrated brake IGBT driver circuit Table 2: Solution Comparison of Gate Drive and IGBT Protection For the IR2137 circuit, as shown in Figure 5, the IR2137 and a micro-controller (µC) share the same ground potential – the negative DC bus potential. (This architecture is already the industry standard in the micro AC inverter drive segment). Unlike its traditional counterpart, the IR2137 circuit requires a single shunt resistor and associated comparator. With this, it can perform all modes of IGBT short circuit protection. Additionally, the IR2137 contains IGBT de-saturation logic in the circuit of each high-side gate drive, as shown in figures 6 and 7. In the event of a Ground Fault condition, the DESAT pin is activated, and the fault signal is transferred to the low side fault logic circuit. The low side fault logic then initiates the simultaneous soft shutdown of all 6 IGBTs. When the soft shutdown signal is transferred back to the high side, the active PMOS/NMOS transistor buffer goes into a high impedance mode and another weak NMOS transistor becomes active to slowly drive the gate pin low. The shutdown softness can be programmed by adding an external resistor to the SSD pin – thus allowing the user to optimize softness for the specific gate charge of the IGBT. To eliminate the dv/dt induced false triggering of the DESAT pin, there is a blanking filter delay of 2 microseconds at each high-side gate turn-on transition. Figure 8 shows the oscillogram of the ground fault protection feature in the IR2137. In this measurement, a size 4 IGBT, IRG4BC40KD, was used in conjunction with a turn-on resistor, Rg = 33Ω, turnoff resistor, Rg = 16Ω, and soft turn off resistor, RSSD = 500Ω. The top trace in Figure 8 is the IGBT gate signal (10V/div), while the middle trace is the VCE voltage (100V/div), and the bottom trace is the IGBT short circuit current (40A/div). No snubber circuit was used for this test. One can see that the de-saturation protection activates quickly and the soft shutdown feature virtually eliminates the overshoot voltage across the collector and the emitter. 4 www.irf.com For contrast, the oscillogram of a ‘hard’ shutdown is shown in Figure 9. The same IGBT, IRG4BC40KD, and the same PCB pattern were used as in the example shown in Figure 8. The top trace is the IGBT short circuit current and the bottom trace is the IGBT V voltage (100V/div). As can be seen in CE Figure 9, the overshoot voltage reaches approximately 100V above the normal V voltage during CE the turn-off transition. In summary, the IR2137, a monolithic IC, provides excellent protection and soft shutdown features in an extremely compact and cost-effective package. Motor Figure 1: Current Flow during Line-to-Line Short Motor Figure 2: Current Flow during Ground Fault www.irf.com 5 Motor Figure 3: Current Flow during Shoot Through Mode M o to r O P TO O P TO O P TO O P TO O P TO O P TO uP Figure 4: Overcurrent Protection in Floating Ground Reference System 6 www.irf.com M oto r uP or DSP IR2137 3Phase G ate Driver with IGBT protection Figure 5: IR2137 Gate Driver with IGBT Overcurrent Protection VB HO P PR E D RIVE R H ig h S id e G a te LO P 2 us ec B lan king SSD D E S AT D e s a t F a ult 3 50 ns ec F ilt er VS S o ft Sh utd o w n S o ft Sh utd o w n Im p e d e n ce = 500 ohm s Figure 6: IR2137 High Side Circuit www.irf.com 7 VB1 HIN1 LIN1 SCHMIT T TR IGGER IN PU T & SHOOT THR OUGH PREVENTION H IN 1 2 0 0 n s ec D e ad tim e LEV E L S H IF T E R S LATC H HOP1 SOFT SHUT DO W N SOFT SHU TDOW N SOFT SHUT DO W N D R IV E R HO N1 DESAT DE TECTION HS SD1 DESAT VS1 UV DE T EC T DESAT1 VB2 H IN 2 SCHMIT T TR IGGER INPUT & SHOOT THR OUGH PREVENTION HIN2 LIN2 2 0 0 n s ec D e ad tim e LEV E L S H IF T E R S SOFT SHU TDOW N DESAT LATC H HOP2 SOFT SHUT DO W N SOFT SHUT DO W N D R IV E R HO N2 DESAT DE TECTION HS SD2 UV DE T EC T VS2 DESAT2 VB3 HIN3 LIN3 SCHMIT T TR IGGER IN PU T & SHOOT THR OUGH PREVENTION 2 0 0 n s ec D e ad tim e LEV E L S H IF T E R S H IN 3 LATC H SOFT SHU TDOW N SOFT SHUT DO W N DESAT HOP3 SOFT SHUT DO W N D R IV E R HO N3 DESAT DE TECTION HS SD3 UV DE T EC T VS3 DESAT3 LOP1 SOFT SHU TDOW N SD D R IV E R LON1 SCHMIT T TR IGGER LSSD1 LS1 LOP2 D R IV E R LON2 SCHMIT T TR IGGER IT RIP LS2 F AUL T LO G IC FLTC LR LSSD2 SCHMIT T TR IGGER LOP3 D R IV E R FAULT LON3 LS3 VC C LSSD3 BRIN VSS UV D ETE CT B R AK E D R IV E R BR COM Figure 7: IR2137 Block Diagram 8 www.irf.com Figure 8: IR2137 Soft Shutdown Figure 9: Hard Shutdown IR WORLD HEADQUARTERS: 233 Kansas St., El Segundo, California 90245 Tel: (310) 252-7105 IR EUROPEAN REGIONAL CENTRE: 439/445 Godstone Rd, Whyteleafe, Surrey CR3 0BL, United Kingdom Tel: ++44 (0) 20 8645 8000 Data and specifications subject to change without notice. www.irf.com 2/28/2000 9