MITSUBISHI SEMICONDUCTOR
PS21993-4/-4A/-4C/-4W
TRANSFER-MOLD TYPE INSULATED TYPE
PS21993-4
INTEGRATED POWER FUNCTIONS
600V/10A low-loss CSTBT inverter bridge for three phase DC-to-AC power conversion
INTEGRATED DRIVE, PROTECTION AND SYSTEM CONTROL FUNCTIONS
• • • • • For P-side : Drive circuit, High voltage high-speed level shifting, Control supply under-voltage (UV) protection. For N-side : Drive circuit, Control supply under-voltage protection (UV), Short circuit protection (SC). Fault signaling : Corresponding to a SC fault (N-side IGBT), a UV fault (N-side supply). Input interface : 3~5V line (High Active). UL Recognized : Yellow Card No. E80276
APPLICATION AC100V~200V three-phase inverter drive for small power motor control.
Fig. 1 PACKAGE OUTLINES (PS21993-4)
38 ±0.5 20×1.778(=35.56) 35 ±0.3 A B TERMINAL CODE 3.5 16-0.5 1.5 ±0.05 1. 2. 3. 4. 5. 6. 7. 8. 9. 10. 11. 12. 13. 14. 15. 16. 17. 18. 19. 20. 21. 22. 23. 24. 25. (VNC) VUFB VVFB VWFB UP VP WP VP1 VNC * UN VN WN VN1 FO CIN VNC * NC NC NC N W V U P NC
Dimensions in mm
0.28 1.778 ±0.2
17
1
(1)
14.4 ±0.5
0.4
14.4 ±0.5
.6 R1 2-
QR Code
3 MIN
Type name Lot No.
29.2 ±0.5
24 ±0.5
(3.5)
0.8 HEAT SINK SIDE
12
18 0.28 2.54 ±0.2 14×2.54 (=35.56) 0.5 0.5 0.5
25
8-0.6
4-C1.2
(3.3)
2.5 MIN 0.5 (2.656)
(0~5°)
0.4
1.5 M
IN
9.5±0.5
5.5±0.5
(1.2) (2.756) DETAIL A
HEAT SINK SIDE
(1.2)
DETAIL B
*) Two VNC terminals (9 & 16 pin) are connected inside DIPIPM, please connect either one to the 15V power supply GND outside and leave another one open. Note : CSTBT is registered trademark of MITSUBISHI ELECTRIC CORPORATION in Japan.
Sep. 2008
MITSUBISHI SEMICONDUCTOR
PS21993-4/-4A/-4C/-4W
TRANSFER-MOLD TYPE INSULATED TYPE
Fig. 2 LONG TERMINAL TYPE PACKAGE OUTLINES (PS21993-4A)
38 20×1.778(=35.56) 35 ±0.3
±0.5
Dimensions in mm
A
B TERMINAL CODE 3.5 16-0.5
(1)
0.28 1.778 ±0.2
1.5 ±0.05
0.4
17
1
14.4 ±0.5
.6 R1 2-
QR Code
3 MIN
Type name Lot No.
0.8 HEAT SINK SIDE
18 0.28 2.54 ±0.2
25 8-0.6 14×2.54 (=35.56) 0.5 0.5 0.5 (2.656)
14±0.5
4-C1.2
1. 2. 3. 4. 5. 6. 7. 8. 9. 10. 11. 12. 13. 14. 15. 16. 17. 18. 19. 20. 21. 22. 23. 24. 25.
(VNC) VUFB VVFB VWFB UP VP WP VP1 VNC * UN VN WN VN1 FO CIN VNC * NC NC NC N W V U P NC
14.4 ±0.5
12
29.4 ±0.5
24 ±0.5
(3.5)
(3.3)
0.5
2.5 MIN
(0~5°)
5.5±0.5
(1.2) (2.756) DETAIL A
HEAT SINK SIDE
(1.2)
*) Two VNC terminals (9 & 16 pin) are connected inside DIPIPM, please connect either one to the 15V power supply GND outside and leave another one open.
Fig. 3 ZIGZAG TERMINAL TYPE PACKAGE OUTLINES (PS21993-4C)
38 ±0.5 20×1.778(=35.56) 35 ±0.3 A B 3.5 1.5 ±0.05 1. 2. 3. 4. 5. 6. 7. 8. 9. 10. 11. 12. 13. 14. 15. 16. 17. 18. 19. 20. 21. 22. 23. 24. 25.
0.4
1.5 M
IN
DETAIL B
Dimensions in mm
TERMINAL CODE (VNC) VUFB VVFB VWFB UP VP WP VP1 VNC * UN VN WN VN1 FO CIN VNC * NC NC NC N W V U P NC
17
1
(1)
18.9
±0.5
14.4 ±0.5
33.7±0.5
2-
14.4 ±0.5
12
R1
.6
QR Code
3 MIN
Type name Lot No.
29.2 ±0.5
24 ±0.5
(3.5)
0.8 HEAT SINK SIDE
0.4
0.4
0.28 1.778 ±0.2
16-0.5
18 0.28 2.54 ±0.2 14×2.54 (=35.56)
25 8-0.6 4-C1.2
0.5 0.5 0.5 (2.656)
(0~5°)
(0~5°)
0.4
1.5 M
IN
±0.5
5.5±0.5
(1.2) (2.756) DETAIL A
HEAT SINK SIDE
(1.2)
9.5
DETAIL B
*) Two VNC terminals (9 & 16 pin) are connected inside DIPIPM, please connect either one to the 15V power supply GND outside and leave another one open.
Sep. 2008 2
MITSUBISHI SEMICONDUCTOR
PS21993-4/-4A/-4C/-4W
TRANSFER-MOLD TYPE INSULATED TYPE
Fig. 4 BOTH SIDES ZIGZAG TERMINAL TYPE PACKAGE OUTLINES (PS21993-4W)
38 20×1.778(=35.56) 35 ±0.3
±0.5
Dimensions in mm
A
B 3.5 1.5 ±0.05 TERMINAL CODE 1. 2. 3. 4. 5. 6. 7. 8. 9. 10. 11. 12. 13. 14. 15. 16. 17. 18. 19. 20. 21. 22. 23. 24. 25. (VNC) VUFB VVFB VWFB UP VP WP VP1 VNC * UN VN WN VN1 FO CIN VNC * NC NC NC N W V U P NC
17
1
(1)
17.4 ±0.5 14.4 ±0.5
35.2 ±0.6
17.4 ±0.5 14.4 ±0.5
.6 R1 2-
QR Code
3 MIN
Type name Lot No.
29.2 ±0.5
24 ±0.5
(3.5)
0.8 HEAT SINK SIDE
12
(1.8)
14×2.54 (=35.56) 0.5 0.5 0.5
2.5 MIN
(0~5°)
0.28 2.54 ±0.25
7-0.6
4-C1.2
(0~5°)
18
25
0.4
0.4 0.4
0.4
0.28 1.778 ±0.25
16-0.5
1.5 M
(2.656)
IN
11±0.5
5.5±0.5
(1.2) (2.756) DETAIL A
HEAT SINK SIDE
(1.2)
DETAIL B
*) Two VNC terminals (9 & 16 pin) are connected inside DIPIPM, please connect either one to the 15V power supply GND outside and leave another one open. QR Code is registered trademark of DENSO WAVE INCORPORATED in JAPAN and other countries.
Fig. 5 INTERNAL FUNCTIONS BLOCK DIAGRAM (TYPICAL APPLICATION EXAMPLE)
C1 : Electrolytic type with good temperature and frequency characteristics. The capacitance also depends on the PWM control strategy of the application system. C2 : 0.22µ-2µF ceramic capacitor with good temperature, frequency and DC bias characteristics. D1 : Bootstrap diode (VRRM=600V or more. trr=100ns or less) D2 : Zener diode (24V/1W)
P-side input (PWM)
Input signal conditioning Level shift
UV lockout circuit
Input signal conditioning Level shift
Input signal conditioning Level shift
C2 C1 D2 D1
Inrush limiting circuit
P
Drive circuit
Drive circuit
Drive circuit
P-side IGBTS
DIPIPM
AC line input
U V W
M
AC output
Z
C VNC
N1
N
N-side IGBTS
CIN
Z : Surge absorber C : AC filter(ceramic capacitor 2.2n -6.5nF) (Common-mode noise filter)
Drive circuit
Input signal conditioning
Fo logic
Protection circuit (SC)
UV lockout circuit
N-side input (PWM)
FO FO output (5V line) VNC (15V line)
D2 C2 C1 VD
Sep. 2008 3
MITSUBISHI SEMICONDUCTOR
PS21993-4/-4A/-4C/-4W
TRANSFER-MOLD TYPE INSULATED TYPE
Fig. 6 EXTERNAL PART OF THE DIPIPM PROTECTION CIRCUIT
DIPIPM
Drive circuit
P
Short Circuit Protective Function (SC) : SC protection is achieved by sensing the N-side DC-Bus current (through the external shunt resistor) after allowing a suitable filtering time (defined by the RC circuit). When the sensed shunt voltage exceeds the SC trip-level, all the N-side IGBTs are turned OFF and a fault signal (Fo) is output. Since the SC fault may be repetitive, it is recommended to stop the system when the Fo signal is received and check the fault.
IC (A)
SC Protection Trip Level
P-side IGBTS
U V W
N-side IGBTS
External protection circuit N1
Shunt Resistor (Note 1)
A
N VNC CIN B
Drive circuit
Collector current waveform
CR
C
Protection circuit
(Note 2)
0 2 tw (µs)
Note1: In the recommended external protection circuit, please select the RC time constant in the range 1.5~2.0µs. 2: To prevent erroneous protection operation, the wiring of A, B, C should be as short as possible.
MAXIMUM RATINGS (Tj = 25°C, unless otherwise noted) INVERTER PART
Symbol VCC VCC(surge) VCES ±IC ±ICP PC Tj Parameter Supply voltage Supply voltage (surge) Collector-emitter voltage Each IGBT collector current Each IGBT collector current (peak) Collector dissipation Junction temperature Condition Applied between P-N Applied between P-N TC = 25°C TC = 25°C, less than 1ms TC = 25°C, per 1 chip (Note 1) Ratings 450 500 600 10 20 27.0 –20~+125 Unit V V V A A W °C
Note 1 : The maximum junction temperature rating of the power chips integrated within the DIPIPM is 150°C (@ TC ≤ 100°C). However, to ensure safe operation of the DIPIPM, the average junction temperature should be limited to Tj(ave) ≤ 125°C (@ TC ≤ 100°C).
CONTROL (PROTECTION) PART
Symbol VD VDB VIN VFO IFO VSC Parameter Control supply voltage Control supply voltage Input voltage Fault output supply voltage Fault output current Current sensing input voltage Condition Applied between VP1-VNC, VN1-VNC Applied between VUFB-U, VVFB-V, VWFB-W Applied between UP, VP, WP, UN, VN, WN-VNC Applied between FO-VNC Sink current at FO terminal Applied between CIN-VNC Ratings 20 20 –0.5~VD+0.5 –0.5~VD+0.5 1 –0.5~VD+0.5 Unit V V V V mA V
Sep. 2008 4
MITSUBISHI SEMICONDUCTOR
PS21993-4/-4A/-4C/-4W
TRANSFER-MOLD TYPE INSULATED TYPE
TOTAL SYSTEM
Parameter VCC(PROT) Self protection supply voltage limit (short circuit protection capability) Module case operation temperature TC Tstg Storage temperature Viso Isolation voltage Symbol Condition VD = 13.5~16.5V, Inverter part Tj = 125°C, non-repetitive, less than 2µs (Note 2) 60Hz, Sinusoidal, 1 minute, Between pins and heat sink plate Ratings 400 –20~+100 –40~+125 1500 Unit V °C °C Vrms
Note 2: TC measurement point
Control terminals
DIPIPM
11.6mm
3mm
IGBT chip position FWDi chip position Power terminals
TC point Heat sink side
THERMAL RESISTANCE
Symbol Rth(j-c)Q Rth(j-c)F Parameter Junction to case thermal resistance (Note 3) Condition Inverter IGBT part (per 1/6 module) Inverter FWDi part (per 1/6 module) Min. — — Limits Typ. — — Max. 3.7 4.5 Unit °C/W °C/W
Note 3 : Grease with good thermal conductivity and long-term quality should be applied evenly with +100µm~+200µm on the contacting surface of DIPIPM and heat sink. The contacting thermal resistance between case and heat sink (Rth(c-f)) is determined by the thickness and the thermal conductivity of the applied grease. For reference, Rth(c-f) (per 1/6 module) is about 0.3°C/W when the grease thickness is 20µm and the thermal conductivity is 1.0W/mK.
ELECTRICAL CHARACTERISTICS (Tj = 25°C, unless otherwise noted) INVERTER PART
Symbol VCE(sat) VEC ton trr tc(on) toff tc(off) ICES Parameter Collector-emitter saturation voltage FWDi forward voltage Condition IC = 10A, Tj = 25°C VD = VDB = 15V VIN = 5V IC = 10A, Tj = 125°C Tj = 25°C, –IC = 10A, VIN = 0V VCC = 300V, VD = VDB = 15V IC = 10A, Tj = 125°C, VIN = 0 ↔ 5V Inductive load (upper-lower arm) Collector-emitter cut-off current Tj = 25°C Tj = 125°C Min. — — — 0.60 — — — — — — Limits Typ. 1.60 1.70 1.70 1.10 0.30 0.40 1.50 0.40 — — Max. 2.10 2.20 2.20 1.70 — 0.60 2.35 1.00 1 10 Unit V V µs µs µs µs µs mA
Switching times
VCE = VCES
Sep. 2008 5
MITSUBISHI SEMICONDUCTOR
PS21993-4/-4A/-4C/-4W
TRANSFER-MOLD TYPE INSULATED TYPE
CONTROL (PROTECTION) PART
Symbol Parameter VD = VDB = 15V VIN = 5V VD = VDB = 15V VIN = 0V Condition Total of VP1-VNC, VN1-VNC VUFB-U, VVFB-V, VWFB-W Total of VP1-VNC, VN1-VNC VUFB-U, VVFB-V, VWFB-W VSC = 0V, FO terminal pull-up to 5V by 10kΩ VSC = 1V, IFO = 1mA VD = 15V (Note 4) VIN = 5V Trip level Reset level Tj ≤ 125°C Trip level Reset level (Note 5) Min. — — — — 4.9 — 0.43 0.70 10.0 10.5 10.3 10.8 20 — 0.8 0.35 Limits Typ. — — — — — — 0.48 1.00 — — — — — 2.1 1.3 0.65 Max. 2.80 0.55 2.80 0.55 — 0.95 0.53 1.50 12.0 12.5 12.5 13.0 — 2.6 — — Unit mA mA mA mA V V V mA V V V V µs V V V
ID
Circuit current
VFOH VFOL VSC(ref) IIN UVDBt UVDBr UVDt UVDr tFO Vth(on) Vth(off) Vth(hys)
Fault output voltage Short circuit trip level Input current Control supply under-voltage protection Fault output pulse width ON threshold voltage OFF threshold voltage ON/OFF threshold hysteresis voltage
Applied between UP, VP, WP, UN, VN, WN-VNC
Note 4 : Short circuit protection works only for the N-side. Please select the external shunt resistance such that the SC trip-level is up to 1.7 times of the current rating. 5 : Fault signal is asserted only corresponding to a SC or a UV failure at N-side, and the Fo pulse width is different for each failure modes. For SC failure, Fo output is with a fixed width of 20µs(min), but for UV failure, Fo outputs continuously during the whole UV period, however, the minimum Fo pulse width is 20µs(min) for very short UV period less than 20µs.
MECHANICAL CHARACTERISTICS AND RATINGS
Parameter Mounting torque Condition Mounting screw : M3 Recommended : 0.69 N·m (Note 6) (Note 7) Min. 0.59 — –50 Limits Typ. — 10 — Max. 0.78 — 100 Unit N·m g µm
Weight Heat-sink flatness Note 6 : Plain washers (ISO 7089~7094) are recommended.
Note 7: Flatness measurement position
Measurement position
+–
17.5mm 4.6mm
Heat sink side
– +
Heat sink side
Sep. 2008 6
MITSUBISHI SEMICONDUCTOR
PS21993-4/-4A/-4C/-4W
TRANSFER-MOLD TYPE INSULATED TYPE
RECOMMENDED OPERATION CONDITIONS
Symbol VCC VD VDB ∆VD, ∆VDB tdead fPWM IO Parameter Supply voltage Control supply voltage Control supply voltage Control supply variation Arm shoot-through blocking time PWM input frequency Allowable rms current Condition Applied between P-N Applied between VP1-VNC, VN1-VNC Applied between VUFB-U, VVFB-V, VWFB-W For each input signal, TC ≤ 100°C TC ≤ 100°C, Tj ≤ 125°C VCC = 300V, VD = VDB = 15V, fPWM = 5kHz P.F = 0.8, sinusoidal PWM, (Note 8) fPWM = 15kHz Tj ≤ 125°C, TC ≤ 100°C (Note 9) Min. 0 13.5 13.0 –1 1.5 — — — 0.5 0.5 –5.0 Limits Typ. 300 15.0 15.0 — — — — — — — — Max. 400 16.5 18.5 1 — 20 5.5 Arms 3.5 — — 5.0 µs V Unit V V V V/µs µs kHz
PWIN(on) Allowable minimum input PWIN(off) pulse width
VNC variation VNC Between VNC-N (including surge) Note 8 : The allowable rms current value depends on the actual application conditions. 9 : IPM might not make response if the input signal pulse width is less than the recommended minimum value.
Fig. 7 THE DIPIPM INTERNAL CIRCUIT
VUFB
HVIC P
VUB
VP1 UP VNC
VCC
IGBT1
Di1
UP
COM
UOUT
VUS
U
VVFB VP
VVB VP
IGBT2
VOUT VVS
Di2
V
VWFB WP
VWB WP
IGBT3
WOUT VWS
Di3
W IGBT4 Di4
LVIC
UOUT
VN1
VCC
IGBT5
VOUT
Di5
UN VN WN
Fo
UN VN WN Fo WOUT CIN VNO
IGBT6
Di6
VNC
GND
N
CIN
Sep. 2008 7
MITSUBISHI SEMICONDUCTOR
PS21993-4/-4A/-4C/-4W
TRANSFER-MOLD TYPE INSULATED TYPE
Fig. 8 TIMING CHART OF THE PROTECTIVE FUNCTIONS [A] Short-Circuit Protection (N-side only with the external shunt resistor and RC filter)
a1. Normal operation : IGBT ON and carrying current. a2. Short circuit is detected (SC trigger). a3. All N-side IGBTs’ gates are hard interrupted. a4. All N-side IGBTs turn OFF. a5. FO is output (tFO(min) = 20µs). a6. Input “L”. a7. Input “H”. But IGBT is still OFF state during outputting FO. a8. IGBT turns ON when L→H signal is input after FO is reset.
N-side control input Protection circuit state SET
a6
a7
RESET
Internal IGBT gate a2 SC
a3
a1 Output current Ic
a4 SC reference voltage
a8
Sense voltage of the shunt resistor Fault output Fo a5 RC circuit time constant delay
[B] Under-Voltage Protection (N-side, UVD)
b1. Control supply voltage VD rises : After VD level rises over under voltage reset level (UVDr), the circuits start to operate when next input is applied. b2. Normal operation : IGBT ON and carrying current. b3. VD level dips to under voltage trip level. (UVDt). b4. All N-side IGBTs turn OFF in spite of control input condition. b5. FO is output. (tFO ≥ 20µs and FO outputs continuously during UV period). b6. VD level rises over UVDr. b7. Normal operation : IGBT ON and carrying current.
Control input
Protection circuit state UVDr
RESET
SET
RESET b6
Control supply voltage VD
b1
UVDt
b3 b4 b7
b2 Output current Ic
Error output Fo
b5
Sep. 2008 8
MITSUBISHI SEMICONDUCTOR
PS21993-4/-4A/-4C/-4W
TRANSFER-MOLD TYPE INSULATED TYPE
[C] Under-Voltage Protection (P-side, UVDB)
c1. Control supply voltage VDB rises : After VDB level rises over under voltage reset level (UVDBr), the circuits start to operate when next input is applied. c2. Normal operation : IGBT ON and carrying current. c3. VDB level dips to under voltage trip level. (UVDBt). c4. P-side IGBT turns OFF in spite of control input signal level, but there is no FO signal output. c5. VDB level rises over UVDBr. c6. Normal operation : IGBT ON and carrying current.
Control input
Protection circuit state UVDBr Control supply voltage VDB
RESET
SET
RESET
c1
UVDBt
c5 c3 c4 c6
c2 Output current Ic High-level (no fault output) Error output Fo
Fig. 9 AN INSTANCE OF INTERFACE CIRCUIT
5V line
10kΩ
DIPIPM
UP,VP,WP,UN,VN,WN
MCU
Fo VNC(Logic)
Note : The setting of RC coupling at each input (parts shown dotted) depends on the PWM control scheme and the wiring impedance of the printed circuit board. Input circuit integrates a 3.3kΩ (min) pull-down resistor. Therefore, when using an external filtering resistor, pay attention to the turn-on threshold voltage.
3.3kΩ (min)
Fig. 10 WIRING CONNECTION OF SHUNT RESISTOR
DIPIPM
Wiring inductance should be less than 10nH. Equivalent to the inductance of a copper pattern in dimension of width=3mm, thickness=100µm, length=17mm
VNC N
Shunt resistor Please connect GND wiring from VNC terminal to the shunt resistor terminal as close as possible.
Sep. 2008 9
MITSUBISHI SEMICONDUCTOR
PS21993-4/-4A/-4C/-4W
TRANSFER-MOLD TYPE INSULATED TYPE
Fig. 11 AN EXAMPLE OF TYPICAL DIPIPM APPLICATION CIRCUIT
C2 C1 C2 C1 C2 C1
VUFB HVIC VP1
C3 VCC UP VUB UOUT VUS
VVFB
VWFB P
Bootstrap negative electrodes should be connected to U, V, W terminals directly and separated from the main output wires.
UP
U
VVB
VP
VP
VOUT VVS
V
M
VWB
WP VNC
WP
WOUT
Note 1 : Input drive is High-active type. There is a 3.3kΩ (Min.) pull-down resistor in the input circuit of IC. To prevent malfunction, the wiring of each input should be as short as possible. When using RC coupling circuit, make sure the input signal level meet the turn-on and turnoff threshold voltage. 2 : Thanks to HVIC inside the module, direct coupling to MCU without any opto-coupler or transformer isolation is possible. 3 : Fo output is open drain type. It should be pulled up to the MCU or control power supply (e.g. 5V, 15V) by a resistor that makes IFo up to 1mA. 4 : To prevent erroneous protection, the wiring of A, B, C should be as short as possible. 5 : The time constant R1C4 of the protection circuit should be selected in the range of 1.5-2µs. SC interrupting time might vary with the wiring pattern. Tight tolerance, temp-compensated type is recommended for R1, C4 6 : All capacitors should be mounted as close to the terminals of DIPIPM as possible. (C1: good temperature, frequency characteristic electrolytic type, and C2, C3 (0.22~2µF) : good temperature, frequency and DC bias characteristic ceramic type are recommended.) 7 : To prevent surge destruction, the wiring between the smoothing capacitor and the P, N1 terminals should be as short as possible. Generally a 0.1-0.22µF snubber between the P-N1 terminals is recommended. 8 : Two VNC terminals (9 & 16 pin) are connected inside DIPIPM, please connect either one to the 15V power supply GND and leave the other open. 9 : It is recommended to insert a Zener diode (24V/1W) between each pair of control supply terminals to prevent surge destruction. 10 : If control GND is connected with power GND by common broad pattern, it may cause malfunction by power GND fluctuation. It is recommended to connect control GND and power GND at only a point N1. 11 : High voltage (VRRM =600V or more) and fast recovery type (trr=100ns or less) diodes should be used in the bootstrap circuit.
MCU
5V line C3 15V line
COM VWS
W
LVIC
UOUT
VN1
VCC
VOUT
UN VN WN Fo
UN VN WN Fo WOUT
Long wiring here might cause short-circuit.
N
VNC
GND
C CIN
Long GND wiring here might generate noise to input and cause IGBT malfunction.
B C4 A
R1
Shunt resistor
N1
Long wiring here might cause SC level fluctuation and malfunction.
Sep. 2008 10