MITSUBISHI PS22056

MITSUBISHI
MITSUBISHI
SEMICONDUCTOR
SEMICONDUCTOR
<Dual-In-Line
<Dual-In-Line
Package
Package
Intelligent
Intelligent
Power
Power
Module>
Module>
PS22056
PS22056
TRANSFER-MOLD
TRANSFER-MOLD
TYPE
TYPE
INSULATED
INSULATED
TYPE
TYPE
PS22056
INTEGRATED POWER FUNCTIONS
1200V/25A low-loss 4 th generation IGBT inverter bridge
for 3 phase DC-to-AC power conversion
INTEGRATED DRIVE, PROTECTION AND SYSTEM CONTROL FUNCTIONS
•
•
•
•
For upper-leg IGBTS :Drive circuit, High voltage high-speed level shifting, Control supply under-voltage (UV) protection.
For lower-leg IGBTS : Drive circuit, Control supply under-voltage protection (UV), Short circuit protection (SC).
Fault signaling : Corresponding to an SC fault (Lower-side IGBT) or a UV fault (Lower-side supply).
Input interface : 5V line CMOS/TTL compatible (High active logic).
APPLICATION
AC400V 0.2kW~3.7kW inverter drive for small power motor control.
Fig. 1 PACKAGE OUTLINES
Dimensions in mm
30✕2.54(=76.2)
2.54±0.3
Heat sink side
9 10
11 12 13 14 15 16 17 18 19 20 21
22
8±0.3
23
24
25
18.5±0.5
QR
Code
2-φ4.5±0.2
20.4±0.5
44±0.5
Type name , Lot No.
26
27
42.6±0.5
7 8
27.4±0.5
5 6
34±0.5
3 4
48.6±0.6
1 2
28
A
10.16±0.3
67±0.3
Heat sink side
(0.3)
(1.7)
(2)
(0.3)
(2.5)
8.2±0.5
16.1±0.3
79±0.5
1. VUFS
2. VUFB
3. VP1
4. UP
5. VVFS
6. VVFB
7. VP1
8. VP
9. VWFS
10. VWFB
11. VP1
12. VPC
13. WP
14. VN1
15. VNC
16. CIN
17. CFO
18. FO
19. UN
20. VN
21. WN
22. P
23. U
24. V
25. W
26. NU
27. NV
28. NW
(2)
Detail : A
All external terminals are treated with lead free solder (ingredient : Sn-Cu) plating.
May 2005
MITSUBISHI SEMICONDUCTOR <Dual-In-Line Package Intelligent Power Module>
PS22056
TRANSFER-MOLD TYPE
INSULATED TYPE
Fig. 2 INTERNAL FUNCTIONS BLOCK DIAGRAM (TYPICAL APPLICATION EXAMPLE)
CBW–
CBW+
CBU+
CBV+
CBV–
CBU–
High-side input (PWM)
(5V line) (Note 1,2)
C1 : Tight tolerance, temp-compensated electrolytic type
(Note : The capacitance depends on the PWM control
scheme used in the applied system.)
C2 : 0.22~2µF R-category ceramic capacitor for noise filtering
C2
C1
Input signal Input signal Input signal
conditioning conditioning conditioning
Level shifter Level shifter Level shifter
Protection
circuit (UV)
Protection
circuit (UV)
(Note 6)
Protection
circuit (UV)
DIP-IPM
Drive circuit Drive circuit Drive circuit
Inrush current
limiter circuit
P
AC line input
H-side IGBTS
U
V
(Note 4)
M
W
C
AC line output
Z
(Note 8)
N1
VNC
NU
NV
NW
L-side IGBTS
CIN
Drive circuit
Z : ZNR (Surge absorber)
C : AC filter (Ceramic capacitor 2.2~6.5nF)
(Protection against common-mode noise)
Input signal conditioning
Fo logic
Protection
circuit
Control supply
Under-Voltage
protection (UV)
(Note 7)
FO CFO
Low-side input (PWM)
(5V line)
(Note 1, 2) Fault output (5V line)
(Note 3, 5)
VNC
VD
(15V line)
Note1:
2:
3:
4:
5:
6:
7:
8:
To prevent input signals oscillation, an RC coupling at each input terminal is recommended.
By virtue of integrating HVIC inside the module, direct coupling to MCU terminals without any opto-coupler or transformer isolation is possible.
Fo output is open drain type. The signal line should be pulled up to the positive side of a 5V supply with an approximate 10kΩ resistor.
The wiring between the power DC-link capacitor and the P/N1 terminals should be as short as possible to protect DIP-IPM against catastrophic high
surge voltage. For extra precaution, a small film type snubber capacitor (0.1~0.22µF, high voltage type) is recommended to mount closely to the
P and N1 terminals.
Fo output pulse width (t FO) should be determined by connecting external capacitor between CFO and VNC terminals. (Example : t FO=2.4ms(typ.)
at CFO=22nF)
High voltage (1200V or more) and fast recovery type (less than 100ns) diodes should be used for the bootstrap circuit.
It is recommended to insert a Zener diode (24V/1W) between each pair of control supply terminals to prevent surge destruction.
To prevent LVIC from surge destruction, it is recommended to mount a fast recovery type diode between VNC and NU, NV, NW terminals.
Fig. 3 EXTERNAL PART OF THE DIP-IPM PROTECTION CIRCUIT
DIP-IPM
Drive circuit
IC (A)
P
SC protection
trip level
H-side IGBTS
L-side IGBTS
External protection circuit
Shunt
resistor
N1
NU
NV
NW
A
(Note 1)
C
U
V
W
Collector current
waveform
0
R
Drive circuit
B
CIN
C
VNC
Protection circuit
(Note 2)
Note1:
2:
In the recommended external protection circuit, please select the RC time
constant in the range 1.5~2.0µs.
To prevent erroneous protection operation, the wiring of A, B, C should be
as short as possible.
2
tw (µs)
Short Circuit Protective Function (SC) :
SC protection is achieved by sensing the L-side DC-Bus current (through the external
shunt resistor) with a suitable filtering time (defined by the RC circuit).
When the sensed shunt voltage exceeds the SC trip-level, all the L-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 and check the fault,
when the Fo signal is received.
May 2005
MITSUBISHI SEMICONDUCTOR <Dual-In-Line Package Intelligent Power Module>
PS22056
TRANSFER-MOLD TYPE
INSULATED TYPE
MAXIMUM RATINGS (Tj = 25°C, unless otherwise noted)
INVERTER PART
Symbol
VCC
VCC(surge)
VCES
±IC
±ICP
PC
Tj
Parameter
Condition
Applied between P-NU, NV, NW
Supply voltage
Supply voltage (surge)
Collector-emitter voltage
Each IGBT collector current
Each IGBT collector current (peak)
Collector dissipation
Junction temperature
Ratings
Applied between P-NU, NV, NW
TC = 25°C
TC = 25°C, less than 1ms
TC = 25°C, per 1 chip
(Note 1)
900
1000
1200
25
50
78.1
–20~+125
Unit
V
V
V
A
A
W
°C
Note 1 : The maximum junction temperature rating of the power chips integrated within the DIP-IPM is 150°C (@ T C ≤ 100°C) however, to ensure safe operation of the DIP-IPM, the average junction temperature should be limited to Tj(ave) ≤ 125°C (@ TC ≤ 100°C).
CONTROL (PROTECTION) PART
Symbol
VD
Parameter
Control supply voltage
Condition
Applied between V P1-VPC, V N1-VNC
VDB
Control supply voltage
VIN
Input voltage
VFO
Fault output supply voltage
Fault output current
Current sensing input voltage
Applied between V UFB-VUFS, VVFB -VVFS,
VWFB-VWFS
Applied between UP, VP, WP-VPC,
UN, V N, WN-VNC
Applied between FO-VNC
Sink current at F O terminal
Applied between CIN-V NC
IFO
VSC
Ratings
20
Unit
V
20
V
–0.5~VD+0.5
V
–0.5~VD+0.5
1
–0.5~VD+0.5
V
mA
V
Ratings
Unit
800
V
–20~+100
–40~+125
°C
°C
2500
Vrms
TOTAL SYSTEM
Symbol
Parameter
VCC(PROT) Self protection supply voltage limit
(short circuit protection capability)
Module case operation temperature
TC
Tstg
Storage temperature
Viso
Condition
VD = 13.5~16.5V, Inverter part
Tj = 125°C, non-repetitive, less than 2 µs
(Note 2)
60Hz, Sinusoidal, AC 1 minute, connection
pins to heat-sink plate
Isolation voltage
Note 2 : TC MEASUREMENT POINT
Control terminals
Heat sink boundary
Heat-sink
Power terminals
TC
TC
May 2005
MITSUBISHI SEMICONDUCTOR <Dual-In-Line Package Intelligent Power Module>
PS22056
TRANSFER-MOLD TYPE
INSULATED TYPE
THERMAL RESISTANCE
Symbol
Parameter
Rth(j-c)Q
Rth(j-c)F
Junction to case thermal
resistance
(Note 3)
Rth(c-f)
Contact thermal resistance
Condition
Inverter IGBT part (per 1/6 module)
Inverter FWDi part (per 1/6 module)
Case to fin, (per 1 module) thermal grease applied
Limits
Unit
Min.
Typ.
Max.
—
—
—
—
1.28
1.70
°C/W
°C/W
—
—
0.047
°C/W
Note 3: Grease with good thermal conductivity and long-term endurance should be applied evenly with about +100µm~+200µm on the contacting surface of DIP-IPM and heat-sink.
ELECTRICAL CHARACTERISTICS (Tj = 25°C, unless otherwise noted)
INVERTER PART
Symbol
VCE(sat)
Condition
Parameter
Collector-emitter saturation
voltage
VEC
ton
trr
tc(on)
toff
tc(off)
FWDi forward voltage
ICES
Collector-emitter cut-off
current
Switching times
VD = VDB = 15V
VIN = 5V, I C = 25A
–I C = 25A, V IN = 0V
Tj = 25°C
Tj = 125°C
VCC = 600V, VD = VDB = 15V
IC = 25A, Tj = 125°C, VIN = 0 ↔ 5V
Inductive load (upper-lower arm)
VCE = VCES
Tj = 25°C
Tj = 125°C
Min.
—
—
—
Limits
Typ.
0.8
—
—
—
—
—
—
2.7
2.5
2.5
1.5
0.3
0.6
2.8
0.6
—
—
Min.
—
—
—
—
4.9
—
0.43
0.7
10.0
10.5
10.3
10.8
1.6
2.0
0.8
Limits
Typ.
—
—
—
—
—
—
0.48
1.5
—
—
—
—
2.4
3.0
1.4
Max.
3.4
3.2
3.0
2.2
—
0.9
3.8
0.9
1
10
Unit
V
V
µs
µs
µs
µs
µs
mA
CONTROL (PROTECTION) PART
Symbol
ID
Parameter
Circuit current
Condition
VD = VDB = 15V
VIN = 5V
VD = VDB = 15V
VIN = 0V
Total of V P1-VPC, VN1-VNC
VUFB-VUFS, VVFB-VVFS, VWFB-VWFS
Total of V P1-VPC, VN1-VNC
VUFB-VUFS, VVFB-VVFS, VWFB-VWFS
VSC = 0V, F O circuit pull-up to 5V with 10kΩ
VSC = 1V, I FO = 1mA
(Note 4)
T j = 25°C, VD = 15V
VIN = 5V
Trip level
Reset level
T j ≤ 125°C
Trip level
Reset level
(Note 5)
CFO = 22nF
Max.
3.70
1.30
3.50
1.30
—
1.10
0.53
2.0
12.0
12.5
12.5
13.0
—
4.2
2.0
Unit
mA
mA
mA
mA
V
V
V
mA
V
V
V
V
ms
V
V
VFOH
Fault output voltage
VFOL
Short circuit trip level
VSC(ref)
Input current
I IN
UVDBt
Supply circuit under-voltage
UVDBr
protection
UVDt
UVDr
Fault output pulse width
t FO
ON threshold voltage
Vth(on)
Applied between UP, VP, WP-VPC, UN, VN, WN-VNC
OFF threshold voltage
Vth(off)
Note 4 : Short circuit protection is functioning only at the low-arms. Please select the value of the external shunt resistor such that the SC triplevel is less than 1.7 times device current rating.
5 : Fault signal is output when the low-arms short circuit or control supply under-voltage protective functions operate. The fault output pulsewidth tFO depends on the capacitance value of CFO according to the following approximate equation : CFO = 9.3 ✕ 10-6 ✕ tFO [F].
May 2005
MITSUBISHI SEMICONDUCTOR <Dual-In-Line Package Intelligent Power Module>
PS22056
TRANSFER-MOLD TYPE
INSULATED TYPE
MECHANICAL CHARACTERISTICS AND RATINGS
Condition
Parameter
Mounting torque
Weight
Heat-sink flatness
Mounting screw : M4
Recommended 1.18 N·m
(Note 6)
Min.
0.98
—
–50
Limits
Typ.
—
77
—
Max.
1.47
—
100
Unit
N·m
g
µm
Note 6: Measurement point of heat-sink flatness
+ –
Measurement location
3.25mm
Heat-sink side
–
+
Heat-sink side
RECOMMENDED OPERATION CONDITIONS
Symbol
Parameter
VCC
VD
VDB
∆VD, ∆VDB
tdead
fPWM
Supply voltage
Control supply voltage
Control supply voltage
Control supply variation
Arm shoot-through blocking time
PWM input frequency
IO
Allowable r.m.s. current
Applied between P-NU, NV, NW
Applied between V P1-VPC, V N1-VNC
Applied between V UFB-VUFS, VVFB -VVFS, V WFB-VWFS
For each input signal, TC ≤ 100°C
T C ≤ 100°C, Tj ≤ 125°C
VCC = 600V, VD = 15V, fC = 15kHz
P.F = 0.8, sinusoidal PWM
T j ≤ 125°C, TC ≤ 100°C
PWIN(on)
Minimum input pulse width
PWIN(off)
Limits
Condition
350 ≤ VCC ≤ 800V,
13.5 ≤ VD ≤ 16.5V,
13.5 ≤ VDB ≤ 16.5V,
–20°C ≤ TC ≤ 100°C,
N line wiring inductance less than
10nH
(Note 9)
(Note 7)
(Note 8)
Ic ≤ 25A
Unit
Min.
Typ.
Max.
350
13.5
13.5
–1
3.3
—
600
15.0
15.0
—
—
—
800
16.5
16.5
1
—
15
V
V
V
V/µs
µs
kHz
—
—
9.2
Arms
1.5
—
—
2.1
—
—
µs
25 < Ic ≤ 42.5A
—
—
—
VNC variation
VNC
Between VNC-NU, NV, NW (including surge)
–5.0
Note 7 : The output r.m.s. current value depends on the actual application conditions.
8 : DIP-IPM might not make response to the input on signal with pulse width less than PWIN (on).
9 : DIP-IPM might not make response or work properly if the input off signal pulse width is less than PWIN (off).
5.0
2.3
V
May 2005
MITSUBISHI SEMICONDUCTOR <Dual-In-Line Package Intelligent Power Module>
PS22056
TRANSFER-MOLD TYPE
INSULATED TYPE
Fig. 4 THE DIP-IPM INTERNAL CIRCUIT
DIP-IPM
VUFB
VUFS
VP1
UP
P
HVIC1
VB
VCC
IGBT1
Di1
HO
IN
VS
COM
U
VVFB
VVFS
VP1
VP
HVIC2
VB
VCC
IGBT2
Di2
HO
IN
VS
COM
V
VWFB
VWFS
HVIC3
VP1
VCC
WP
IN
VPC
COM
VB
IGBT3
Di3
HO
VS
W
IGBT4
LVIC
Di4
UOUT
VN1
VCC
UVNO
NU
IGBT5
Di5
VOUT
VVNO
UN
UN
VN
VN
WN
WN
Fo
Fo
NV
IGBT6
Di6
WOUT
NW
WVNO
CIN
VNC
GND
CFO
CFO
CIN
May 2005
MITSUBISHI SEMICONDUCTOR <Dual-In-Line Package Intelligent Power Module>
PS22056
TRANSFER-MOLD TYPE
INSULATED TYPE
Fig. 5 TIMING CHARTS OF THE DIP-IPM PROTECTIVE FUNCTIONS
[A] Short-Circuit Protection (Lower-arms only with the external shunt resistor and CR filter)
a1. Normal operation : IGBT ON and carrying current.
a2. Short circuit current detection (SC trigger).
a3. IGBT gate hard interruption.
a4. IGBT turns OFF.
a5. FO output with a fixed pulse width determined by the external capacitor C FO.
a6. Input = “L ” : IGBT OFF
a7. Input = “H” :
a8. IGBT OFF state in spite of input “H”.
Lower-arms control
input
a6 a7
Protection circuit state
SET
Internal IGBT gate
RESET
a3
a2
SC
a1
a4
Output current Ic
a8
SC reference voltage
Sense voltage of the
shunt resistor
CR circuit time
constant DELAY
Error output Fo
a5
[B] Under-Voltage Protection (Lower-arm, UVD)
b1. Control supply voltage rising : After the voltage level reaches UVDr, the circuits start to operate when next input is applied.
b2. Normal operation : IGBT ON and carrying current.
b3. Under voltage trip (UVDt).
b4. IGBT OFF in spite of control input condition.
b5. FO keeps output during the UV period, however, F O pulse is not less than the fixed width for very short UV interval.
b6. Under voltage reset (UVDr).
b7. Normal operation : IGBT ON and carrying current.
Control input
Protection circuit state
Control supply voltage VD
RESET
UVDr
b1
SET
UVDt
b2
RESET
b6
b3
b4
b7
Output current Ic
Error output Fo
b5
May 2005
MITSUBISHI SEMICONDUCTOR <Dual-In-Line Package Intelligent Power Module>
PS22056
TRANSFER-MOLD TYPE
INSULATED TYPE
[C] Under-Voltage Protection (Upper-side, UVDB)
c1. Control supply voltage rises : After the voltage reaches UVDBr, the circuits start to operate when next input is applied.
c2. Normal operation : IGBT ON and carrying current.
c3. Under voltage trip (UVDBt).
c4. IGBT OFF in spite of control input signal level, but there is no FO signal output.
c5. Under voltage reset (UVDBr).
c6. Normal operation : IGBT ON and carrying current.
Control input
Protection circuit state
RESET
SET
RESET
UVDBr
Control supply voltage VDB
c1
UVDBt
c2
c5
c3
c4
c6
Output current Ic
High-level (no fault output)
Error output Fo
Fig. 6 MCU I/O INTERFACE CIRCUIT
5V line
DIP-IPM
10kΩ
UP,VP,WP,UN,VN,WN
MCU
Fo
VNC(Logic)
Note : RC coupling at each input (parts shown dotted) may change depending on the PWM control scheme used in
the application and the wiring impedance of the application’s printed circuit board.
The DIP-IPM input signal section integrates a 2.5kΩ(min) pull-down resistor. Therefore, when using a external
filtering resistor, pay attention to the turn-on threshold voltage requirement.
Fig. 7 WIRING CONNECTION WITH 1 SHUNT RESISTOR
Using low inductance chip resistor and reducing
wiring length to minimize the wiring inductance.
DIP-IPM
NU
Shunt resistor
NV
VNC
NW
Please insert fast
recovery type diode
between VNC and
NU, NV, NW terminals.
Please make the wiring connection
of shunt resistor to GND as short as
possible.
For 3 shunt resistors connection, please refer to Fig.9.
May 2005
MITSUBISHI SEMICONDUCTOR <Dual-In-Line Package Intelligent Power Module>
PS22056
TRANSFER-MOLD TYPE
INSULATED TYPE
Fig. 8 AN EXAMPLE OF TYPICAL DIP-IPM APPLICATION CIRCUT WITH 1 SHUNT RESISTOR
C1:Tight tolerance temp-compensated electrolytic type
C2,C3: 0.1~0.22µF R-category ceramic capacitor for noise filtering.
(Note: The capacitance value depends on the PWM control used in the applied system.)
C2
VUFB
C1
VUFS
DIP-IPM
P
HVIC1
VP1
C3
UP
C2
VVFB
C1
VVFS
VP
VWFB
C1
VWFS
WP
MCU
IN
HO
COM
VS
U
VCC
VB
IN
HO
COM
VS
V
M
HVIC3
VP1
C3
VB
HVIC2
VP1
C3
C2
VCC
VPC
VCC
VB
IN
HO
COM
W
VS
LVIC
UOUT
UVNO
VN1
NU
VCC
C3
5V line
VOUT
VVNO
UN
NV
UN
VN
WN
Fo
VN
WOUT
WN
WVNO
If this wiring is too
long, short circuit
might be caused.
NW
Fo
CIN
VNC
GND
CFO
C
CIN
CFO
C4(CFO )
R1
15V line
A
If this wiring is too long, the SC level fluctuation
might be larger and cause SC malfunction.
The long wiring of GND might generate noise
on input and cause IGBT to be malfunction.
Note 1 :
2:
3:
4:
5:
6:
7:
8:
9:
10:
11:
B
Shunt
resistor
N1
C5
To avoid malfunction, the wiring of each input should be as short as possible. (less than 2-3cm)
By virtue of integrating HVIC inside the module, direct coupling to MCU terminals without any opto-coupler or transformer isolation is possible.
Fo output is open drain type. The signal line should be pulled up to the positive side of a 5V supply with an approximate 10kΩ resistor.
Fo output pulse width (tFO) should be determined by connecting external capacitor C4 between CFO and VNC terminals. (Example :
tFO=2.4ms(typ.) at CFO=22nF)
Input signal is High-Active type. There is a 2.5kΩ (Min.) resistor inside IC to pull down each input signal line to GND.
When employing RC coupling circuits at each input, set up RC couple such that input signal agree with turn-off/turn-on threshold voltage.
To prevent errors of the protection function, the wiring of A, B, C should be as short as possible.
The time constant R5C1 of the protection circuit should be selected in the range of 1.5~2µs. SC interrupting time might vary with the
wiring pattern.
All capacitors should be mounted as close to the terminals of the DIP-IPM as possible.
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.
It is recommended to insert a Zener diode (24V/1W) between each pair of control supply terminals to prevent surge destruction.
To prevent LVIC from surge destruction, it is recommended to mount a fast recovery type diode between VNC and NU, NV, NW
terminals.
Fig. 9 EXAMPLE OF EXTERNAL PROTECTION CIRCUIT WITH 3 SHUNT RESISTORS
DIP-IPM
The time constant RC of external comparator should be selected in the range
of 1.5~2µs. SC interrupting time might vary with the wiring pattern.
The threshold voltage Vref should be set up the same rating of short circuit
trip level (VSC(ref) typ. 0.48V).
• Please select the external shunt resistance such that the SC trip-level is less
than 1.7 times of the current rating.
• To avoid malfunction, the wiring of each input should be as short as possible.
• OR circuit output level should be set up the rating of short circuit trip level
(VSC(ref) typ. 0.48V).
• For extra precaution, please refer to Fig.8
•
Drive circuit
•
P
H-side IGBTS
U
V
W
L-side IGBTS
External protection circuit
R
Drive circuit
VNC
NW
NV
NU
+
C
Vref
R
C
Protection circuit
CIN
Vref
R
Shunt
resistor
–
OR logic
circuit
+
–
+
C
Vref
–
Comparator
May 2005