demonstration board for stdrive601 triple gate driver€¦ · – foc or 6-step algorithm •...
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Features
• High voltage rail up to 600V• Driver supply input voltage range 9V-20V• STGD6M65DF2 IGBTs power stage featuring:
– V(BR)CES = 650 V– VCE(sat) = 1.55 V @ IC = 6 A
• Dual footprint for IGBT/MOSFET package:– DPAK– PowerFlat 8x8
• Selectable single or 3-shunt current sensing topology:– Sensored or sensorless BEMF detection– FOC or 6-Step algorithm
• SmartShutdown overcurrent protection• Hall effect sensors connector• Bus voltage sensing• 450V bulk capacitor• Connector for interfacing with MCU• RoHS compliant
Application
• Three-phase motor drives• Fans• Pumps• Refrigerator compressors• Industrial inverters• Appliances
DescriptionThe EVALSTDRIVE601 demonstration board is a complete 3-phase inverter whichallows evaluating all of the STDRIVE601 features. The power stage featuresSTGD6M65DF2 IGBTs, but can be populated with any IGBT or power MOSFET inDPAK or powerFLAT 8x8 HV package. The board is designed to support a threeshunt or a single shunt current sensing topology.
A strip connector allows an easy interfacing with MCU control.
The STDRIVE601 is a 600V gate driver device manufactured with BCD6s offlinetechnology. It is a single-chip with three half-bridge gate drivers for N-channel powerMOSFETs or IGBTs suitable for 3-phase applications.The device integrates threebootstrap diodes and a smart shutdown feature able to detect very fast overcurrentcondition, minimizing the propagation delay between the overcurrent event and theoutput switch-off.
Product status link
EVALSTDRIVE601
Demonstration board for STDRIVE601 triple gate driver
EVALSTDRIVE601
Data brief
DB3896 - Rev 1 - May 2019For further information contact your local STMicroelectronics sales office.
www.st.com
1 Schematic diagram
Figure 1. EVALSTDRIVE601 schematic – Driver output stages
SGND
PGND
OD
CIN
TRIPLE SHUNT (default)
Overcurrent 5.5A VDD=3V3
GH
2
GL2
BOO
T1
BOO
T2
BOO
T3
CIN
GL3
GH
3
GH
1
GL1
BOO
T2
BOO
T3
BOO
T1
CIN
SENSE3
SENSE1
SENSE2
VCC
HV
VCC
HV
HV
VCC
VDD
VCC
OU
T2
HIN
1H
IN2
HIN
3
LIN
1LI
N2
LIN
3
FAU
LT
OU
T3
OU
T1
ENAB
LE
SEN
SE1
SEN
SE2
SEN
SE3
SEN
SE1_
REF
SEN
SE2_
REF
SEN
SE3_
REF
C13
N.M
.TP17
Q5
STGD6M65DF2
1
2 3
C7
N.M
.
R27
100k
R60
4k7
Q6
STGD6M65DF2
1
2 3
C2
220n
F/25
V
Q4
STGD6M65DF2
1
2 3
C35
33pF
/25V
R21
100R
R24
1k
R8
27R
JP3
OPE
N
R18
10k
R19
10R
Q1
STGD6M65DF2
1
2 3
D6
BAT5
4J
TP16
D1
BAT5
4J
TP18
TP9
Q2
STGD6M65DF2
1
2 3
TP8
TP29
TP30
R14
47k
R11
10R R26
100R
R23
100k
R9
100R
R25
10R
D9
BAT5
4J
R7
10R
D5
BAT5
4J
TP6
R5
27R
D2
N.M
.
+ -
U2B
TSV9
12IQ
2T5
76
R62
0R
TP7
R15
10RR12
100R
D3
N.M
.
R58220m/ 2W/ 1%
TP11R
6 0R
TP12
TP22
R22
1k
TP10 JP
2
OPE
N
D7
BAT5
4J
C6
470n
F/50
V
TP3
C10
47nF
/25V
R3
100R
Q3
STGD6M65DF2
1
2 3
R61
10k
C3
220n
F/25
V
C9
N.M
.
D8
BAT5
4J
R1
10R
R10
100k
R20
1k
TP21
C1
N.M
.
R16
100R
TP5
R30220m/ 2W/ 1%
TP13
C5
470n
F/50
V
R4
100k
R17
100k
R63
N.M
.
R2
27R
D4
N.M
.
C8
470n
F/50
V
R13
100k
C11
1nF/
25V
TP19
TP15
C4
N.M
.
U1
STD
RIV
E601
D
EN10
VCC
1
FAU
LT8
PGN
D13
BOO
T128
OU
T126
BOO
T224
OD
11C
IN9
HIN
12
SGN
D12
LVG
314
HVG
127
HVG
223
OU
T222
BOO
T320
HVG
319
OU
T318
HIN
23
HIN
34
LIN
15
LIN
26
LIN
37
LVG
215
LVG
116
TP1
TP20
R57220m/ 2W/ 1%
C12
N.M
.
TP4
TP14
EVALSTDRIVE601Schematic diagram
DB3896 - Rev 1 page 2/10
Figure 2. EVALSTDRIVE601 schematic – feedback network
HIGH VOLTAGE
SECTION
VCC_E
min
9V m
ax 2
0V
VCC_E
VDD_E
SGND
OUT3
OUT2
OUT1
HV PGND
VDD_E
3V3
PWM_HIN1
PWM_LIN1
PWM_HIN2
PWM_LIN2
PWM_HIN3
PWM_LIN3
SENSE_3
SENSE_2
SENSE_1
FAULT
ENABLE
VDD
6ste
p R45,R50,R55
D.N.M.
DEFAULT
CONFIGURATION
F.O.C. 3
shunt
VCC=
15
JP3
closed (VDD=3V3)
VBUS
A+/H1
B+/H2
Z+/H3
Udd
GND
HALL power
Pha
seV
_H
Pha
seV
_L
Pha
seW
_H
Pha
seW
_L
Pha
seU
_L
Pha
seU
_H
SE
NS
E_2
SE
NS
E_3
SE
NS
E_1
SE
NS
E_O
UT2
SE
NS
E_O
UT3
SE
NS
E_O
UT1
SE
NS
E_O
UT1
SE
NS
E_O
UT2
SE
NS
E_O
UT3
VB
US
_fdb
k
FAU
LTP
hase
U_H
Pha
seU
_LP
hase
V_H
Pha
seV
_LP
hase
W_H
Pha
seW
_LS
EN
SE
_1S
EN
SE
_2S
EN
SE
_3
EN
C_H
ALL
_C
HAL
L_BE
MF_
AH
ALL_
BEM
F_B
HAL
L_BE
MF_
C
EN
C_H
ALL
_B
EN
C_H
ALL
_A
HAL
L_BE
MF_
A
BE
MF_
C
EN
C_H
ALL
_A
EN
C_H
ALL
_B
HA
LL_B
EM
F_B
EN
C_H
ALL
_C
HA
LL_B
EM
F_C
BE
MF_
B
BE
MF_
A
BE
MF_
C
E5V
GPI
O_B
EMF
GP
IO_B
EM
F
BE
MF_
A
BE
MF_
B
GP
IO_B
EM
F
GP
IO_B
EM
F
SE
NS
E_O
UT2
CP
OU
T
CPO
UT
CU
RR
ENT_
REF
CU
RR
ENT_
REF
E5V
VC
C
VD
D
VD
D
VD
DV
DD
VD
D
VD
DV
DD
VD
D
HV
HV
VD
D
VD
D
VD
D
VD
D
VC
C
VD
D
VD
D
VD
D
VD
D
VD
D
HIN
1
LIN
1
HIN
2
LIN
2
HIN
3
LIN
3
OU
T1
OU
T2
OU
T3
FAU
LT
EN
AB
LE
SE
NS
E3
SE
NS
E2
SE
NS
E1
SE
NS
E1_
RE
F
SE
NS
E3_
RE
F
SE
NS
E2_
RE
F
OU
T1
OU
T2
OU
T3
R35 1k
+C
2110
uF/2
5VD
10B
ZT52
C3V
3
R69
20k
R76
1k8
R94
180k
R54
1k8
C36
N.M
.
TP31
TP26
R98
180k
R80
10k
C47
100n
F/25
V
D21
BA
T54J
R83
N.M
.
J61 2 3 4 5
D26
DA
2JF8
100L
R45
20k
J2
123
C31
100n
F/25
V
C22
33pF
/25V
R71
3R3
R85
0R
C18
33pF
/25V
C45
4.7p
F/50
V
R49 1k
8
R88
180k
TP23
C46
4.7p
F/50
V
J31 2 3
R41
1k8
JP20
CLO
SE
D 1
-2
13
2
R65
470k
JP17
CLO
SE
D
C37
N.M
.
R32 1k
R42
10k
R55
20k
C16
33nF
/630
V
C34
68uF
/450
V
R11
4
33k
R39 47
k
TP32
C42
100n
F/25
V
R70
20k
R77
1k8
R37 1k
+ -U
2A
TSV
912I
Q2T
31
48
2
C44
4.7p
F/50
V
+ -U
3A
TSV
912I
Q2T
31
48
2
TP27
D11
BA
T54J
C38
N.M
.
R51
1k8
R50
20k
JP4
OP
EN
C17
33pF
/25V
C33
100n
F/25
V
C25
33pF
/25V
C40
10pF
/25V
J4
MO
TOR
CO
NN
.1 3 5 7 9 11 13 15 17 19 21 23 25
2 4 6 8 10 12 14 16 18 20 22 24 2627 29 31 33
28 30 32 34
C19
33pF
/25V
C29
33pF
/25V
TP24
D24
DA
2JF8
100L
R72
1K
R44
1k8
R59
3R3
R46
1k8
JP18
CLO
SE
D 1
-2
13
2
C48
4.7u
F/10
V
D20
BA
T54J
R40 1k
R52
10k
R67
1k
R11
510
M
R91
3.3k
R78
10k
R36
1K8
C15
N.M
.
D16
BA
T54J
+C
23
4u7F
/25V
C27
33pF
/25V
J11 2
R82
N.M
.
D17
BA
T54J
R34 1k
D25
DA
2JF8
100L
D18
BA
T54J
R73
1K
C50
100n
F/25
V
C23
A
N.M
.
D15
BA
T54J
R47
10k
TP28
C39
10pF
/25V
C24
33pF
/25V
D22
BA
T54J
R92
180k
C49
100n
F/25
V
R96
180k
C26
2.2p
F/25
V
R11
20R
C32
47nF
/25V
TP25
D23
BA
T54J
JP21
CLO
SE
D 2
-4
1 3
24
C21
AN
.M.
JP19
CLO
SE
D 1
-2
13
2R
84N
.M.
R68
20k
R75
1k8
R31 1k
R74
1K
JP1
CLO
SE
D
R79
10k
R66
6.49
kR
8618
0k
C30
2.2p
F/25
V
C20
33pF
/25V
J51 2 3 4 5 6 7 8 9 10 11 12 13
V+
+ -V-
U4
TS30
21IL
T
R93
1k
R97
1k
R95
3.3k
R64
470k
R99
3.3k
R11
30R
C41
10pF
/25V
+ -U3B
TSV
912I
Q2T
57
6
R38
47k
R11
7
0R
D19
BA
T54J
C28
2.2p
F/25
V
C14
33pF
/25V
R33 1k
C51
N.M
.
R87
1k
EVALSTDRIVE601Schematic diagram
DB3896 - Rev 1 page 3/10
2 Bill of material
Table 1. Bill of material – components common to all device variants
Reference Part Value Part Description Package
C1,C4,C7,C9,C12,C13,C36,C37,C38,C51 N.M. SMT ceramic capacitor Size 0603
C2,C3 220nF/25V SMT ceramic capacitor Size 0603
C5,C6,C8 470nF/50V SMT ceramic capacitor Size 0805
C10,C32 47nF/25V SMT ceramic capacitor Size 0603
C11 1nF/25V SMT ceramic capacitor Size 0603
C14,C17,C18,C19,C20,C22,C24,C25,C27,C29,C35 33pF/25V SMT ceramic capacitor Size 0603
C15 N.M. Film capacitor 4x13 mm, Pitch 10mm
C16 33nF/630V SMT multilayer capacitor Size 1210
C21A N.M. SMT ceramic capacitor Size 1206
C21 10uF/25V SMD aluminum elect.capacitor Size C
C23A N.M. SMT ceramic capacitor Size 0805
C23 4u7F/25V SMD auminum elect.capacitor Dim. 3.3x3.3 mm
C26,C28,C30 2.2pF/25V SMT ceramic capacitor Size 0603
C31,C33,C42,C47,C49,C50 100nF/25V SMT ceramic capacitor Size 0603
C34 68uF/450V THT electrolytic capacitor,radial p7.5 d18h25
Diam. 18 mm, pitch7.5 mm
C39,C40,C41 10pF/25V SMT ceramic capacitor Size 0603
C44,C45,C46 4.7pF/50V SMT ceramic capacitor Size 0603
C48 4.7uF/10V SMT ceramic capacitor Size 0805
D1,D5,D6,D7,D8,D9,D11,D15,D16,D17,D18,D19,D20,D21,D22,D23 BAT54J 40V, 300mA small signal
Schottky SMT Diode SOD-323
D2,D3,D4 N.M. Turbo 2 ultrafast high-voltagerectifier SMA
D10 BZT52C3V3 Zener diode 3.3 V SOD-123
D24,D25,D26 DA2JF8100L 800V fast recovery diode SC-90A (SMini2-F5-B)
JP1,JP17 CLOSED SMT jumper Soldering pad
JP2,JP3 OPEN SMT jumper Size 0805
JP4 OPEN SMT jumper Soldering pad
JP18,JP19,JP20 CLOSED 1-2 SMT jumper Soldering pad
JP21 CLOSED 2-4 SMT jumper Soldering pads
J1 MORSV-508-2P_screw
Connector terminal block T.H.2 positions 5.08 mm Pitch 5.08 mm
J2 MORSV-508-3P_screw
Terminal block T.H. 3positions, 5.08 mm Pitch 5.08 mm
J3 MORSV-350-3P_screw
Terminal block T.H. 3positions, 3.5 mm Pitch 3.5 mm
EVALSTDRIVE601Bill of material
DB3896 - Rev 1 page 4/10
Reference Part Value Part Description Package
J4 MOTOR CONN. Header Vertical Connector2x17 poles, pitch 2.54 mm 2x17 pins
J5 STRIP 1x13 Strip connector 13 pos, 2.54mm 1x13 pins
J6 STRIP 1x5 Strip connector 5 pos, 2.54mm 1x5 pins
Q1,Q2,Q3,Q4,Q5,Q6STGD6M65DF2 Trench gate field-stop IGBT,
M series 650V, 6A low loss DPAK
Alternative P.N D.N.M. equivalentPowerFLAT 8x8
R1,R7,R11,R15,R19,R25 10R SMT resistor Size 0805
R2,R5,R8 27R SMT resistor Size 0805
R3,R9,R12,R16,R21,R26 100R SMT resistor Size 0805
R4,R10,R13,R17,R23,R27 100k SMT resistor Size 0603
R6,R62,R85,R112,R113,R117 0R SMT resistor Size 0603
R14,R38,R39 47k SMT resistor Size 0603
R18,R42,R47,R52,R61,R78,R79,R80 10k SMT resistor Size 0603
R20,R22,R24,R31,R32,R33,R34,R35,R37,R40,R72,R73,R74 1K SMT resistor Size 0603
R30,R57,R58 220m/ 2W/ 1% SMT resistor Size 1210/2512
R36 1K8 SMT resistor Size 1206
R41,R44,R46,R49,R51,R54,R75,R76,R77 1k8 SMT resistor Size 0603
R45,R50,R55,R68,R69,R70 20k SMT resistor Size 0603
R59,R71 3R3 SMT resistor Size 0603
R60 4k7 SMT resistor Size 0603
R63,R82,R83,R84 N.M. SMT resistor Size 0603
R64,R65 470k SMT resistor Size 1206
R66 6.49k SMT resistor Size 0805
R67,R87,R93,R97 1k SMT resistor Size 0805
R86,R88,R92,R94,R96,R98 180k SMT resistor Size 1206
R91,R95,R99 3.3k SMT resistor Size 0603
R114 33k SMT resistor Size 0603
R115 10M SMT resistor Size 0603
TP1,TP3,TP4,TP5,TP6,TP7,TP8,TP9,TP10,TP11,TP12,TP13,TP14,TP15,TP16,TP17,TP18,TP19,TP20,TP21,TP22,TP23,TP24,TP25,TP26,TP27,TP28,TP31,TP32
TP for probe Diam. 1.27, Hole0.8mm
TP29 TP-ANELLO_1mm-ROSSO
Red bead terminal, diam.1.02mm
Diam. 2,54 , Hole1mm
TP30 TP-ANELLO_1mm-NERO
Black bead terminal, diam.1.02mm
Diam. 2,54 , Hole1mm
U2,U3 TSV912IQ2T Dual rail-to rail input/output 8MHz operational amplifiers DFN8 2x2
EVALSTDRIVE601Bill of material
DB3896 - Rev 1 page 5/10
3 Layout and component placements
Figure 3. EVALSTDRIVE601 – layout (component placement top view)
EVALSTDRIVE601Layout and component placements
DB3896 - Rev 1 page 6/10
Figure 4. EVALSTDRIVE601 – layout (top layer)
EVALSTDRIVE601Layout and component placements
DB3896 - Rev 1 page 7/10
Figure 5. EVALSTDRIVE601 – layout (bottom layer)
EVALSTDRIVE601Layout and component placements
DB3896 - Rev 1 page 8/10
Revision history
Table 2. Document revision history
Date Version Changes
29-May-2019 1 Initial release.
EVALSTDRIVE601
DB3896 - Rev 1 page 9/10
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EVALSTDRIVE601
DB3896 - Rev 1 page 10/10
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