ETC ECN3021SPR

HIGH-VOLTAGE MONOLITHIC IC
ECN3021
ECN3021 is a single chip three-phase bridge inverter IC which has 6 IGBTs in the circuit.
Especially, it is very suitable for controlling the speed of 3-phase DC brushless motors to which
converted AC200~230V power supplies are applied. Fig. 1 shows the internal block diagram.
Functions
∗
∗
∗
∗
∗
∗
Integrated charge pump circuit
Integrated free wheel diodes
Integrated PWM circuit
Integrated FG circuit
Integrated over current protection circuit
Integrated rotating direction monitor circuit
Features
∗ Speed control for a 3-phase DC brushless motor is available with an external microprocessor.
∗ Bottom arm circuits can be operated in 20kHz chopping frequency of PWM.
RU
CB
+
C2
+ -
RW
C0
VCC
VS
D1
D2
RV
VCC(15V)
HU
HV
HW
C+
-
C1
VS1
CL
C-
VS2
VB
VB supply
Clock
Charge Pump
FG
FG
DM
Microprocessor
Analog
output
Comparator
VSP
Hall ICs
Top Arm
Driver
Rotating
Direction
Monitor
MU
MV
3-Phase
Distributor
MW
+
CMP
-
Bottom Arm
Driver
SAW wave
Generator
Over Current Sense
+
Clock
CR
VTR
Motor
GL
Vref
0.5V
RS
GH1
GH2
RTR
CTR
RS
Fig. 1 Block diagram
PDE-3021-0
ECN3021
1.
2.
General
(1) Type
(2) Application
(3) Structure
(4) Package
ECN3021
3-phase DC Brushless Motor
Monolithic IC
SP-23T
Maximum Allowable Ratings (Ta=25°C)
No.
Items
Symbols
1 Output Device
VSM
Breakdown Voltage
2 Supply Voltage
VCC
3 Input Voltage
VIN
4
5
6
Terminal
VS1,VS2
MU,MV,MW
VCC
VSP,RS
HU,HV,HW
MU,MV,MW
MU,MV,MW
MU,MV,MW
Ratings
500
Unit
V
18
-0.5 ~ VB+0.5
V
V
Condition
Output Current
IMDC
0.7
A
Peak Output Current
IMP
1.0
A
Note
Output Current in Start
IOM
1.0
A
Note
Up and Accelerating
Note
7 Operating Junction
Tjop
°C
-20 ~ +135
Temperature
8 Storage Temperature
Tstg
°C
-40 ~ +150
Note 1. Please note that acumulated duty of a period exceeding 0.7A has to be less than 5% of
flowing period.
Note 2. Thermal Resistance
Rj-c = 4°C/W
Rj-a = 40°C/W
3.
1
1
2
total current
Recommended Operating Conditions
No.
Items
Symbols Terminal
MIN
TYP
MAX
Unit
Condition
1 Supply Voltage
VS
VS1,2
50
325
370
V
2
VCC
VCC
13.5
15
16.5
V
Note. Recommended Safe Operating Area(SOA)
It is recommended that this IC should be used within the SOA as shown below, where IM and VM are
the current and the voltage at the terminals connected to motor coils when the phase is changed (turned
off).
1.0
Safe
Operating Area
IM
(A)
0
370
0
VM (V)
PDE-3021-0
ECN3021
4.
Electrical Characteristics (Ta=25°C)
Unless otherwise specified, VCC=15V, VS=325V
Suffix T; Top arm
No.
Items
Symbols
Terminal
MIN TYP MAX Unit
1 Standby Current
IS
VS1,2
2.5
5.0
mA
2
ICC
VCC
10
20
mA
3 Output device FVD
VFT
MU,MV,MW
4.0
6.0
V
4
VFB
MU,MV,MW
4.0
6.0
V
5 Turn On
TdONT
MU,MV,MW
0.5
3.0
µs
6 Delay Time
TdONB
MU,MV,MW
0.5
3.0
µs
7 Turn Off
TdOFFT
MU,MV,MW
3.0
6.0
µs
8 Delay Time
TdOFFB
MU,MV,MW
1.0
3.0
µs
9 Free Wheel
VFDT
MU,MV,MW
4.0
6.0
V
10 Diode FVD
VFDB
MU,MV,MW
4.0
6.0
V
11 Output Resistance
RVTR
VTR
200 400
Ω
12 H or L Level of
VSAWH
CR
4.9
5.4
6.1
V
13 SAW wave
VSAWL
CR
1.7
2.1
2.5
V
14 Amplitude of
VSAWW
CR
2.8
3.3
3.8
V
SAW wave
15 Reference Voltage
Vref
RS
0.45 0.5 0.55
V
16 Hall signal
VIH
HU,HV,HW
3.5
V
17 Input Voltage
VIL
HU,HV,HW
1.5
V
18 Hall signal
IIL
HU,HV,HW
-100
µA
Input Current
B; Bottom arm
Condition
VSP=0V
I=0.35A
I=0.35A
I=0.35A
Resistance Load
I=0.35A
Note 2
Note 3
HU,HV,HW=0V
Note 1
Pull Up Resistance
19 VSP Input Current
IVSPH
VSP
-
-
100
µA
VSP=5.0V
Note 1
Pull Down Resistance
20 VB Output Voltage
VB
CB
6.8
7.5
8.2
V
21 VB Output Current
IB
CB
25
mA
22 FG,DM
VOL
FG,DM
1.0
V
Output Voltage
23 FG,DM
ROL
FG,DM
200 400
Ω
Output Resistance
24 LVSD Output Voltage LVSDON Vcc,MU,
10.0 11.5 12.9
V
25 LVSD recover Voltage LVSDOFF MV,MW
10.1 12.0 13.0
V
26 LVSD reset hysterisis Vrh
0.1
0.5
0.9
V
Note 1. Pull Up Resistance and Pull Down Resistance are typically 200 kΩ.
Note 2. Please see Note 2 in item 6 for determining the frequency of SAW wave.
Note 3. The amplitude of SAW(VSAWW) is determined by the following equation,
VSAWW=VSAWH-VSAWL (V)
Note 4. The equivalent circuit around FG and DM terminal is shown in Fig. 2
Note 5. LVSD: Low Voltage Shut Down
delta Vload=0.1V
IOL=-5mA
Note 4
Note.5
VCC
FG or DM
Fig.2 Equivalent circuit around FG or DM
PDE-3021-0
ECN3021
5. Function
5.1
Truth Table
Input
HV
L
L
H
H
H
L
L
H
HU
H
H
H
L
L
L
L
H
5.2
MU
HW
H
L
L
L
H
H
L
H
Top
OFF
OFF
OFF
ON
ON
OFF
OFF
OFF
MV
Bottom
ON
ON
OFF
OFF
OFF
OFF
OFF
OFF
Top
ON
OFF
OFF
OFF
OFF
ON
OFF
OFF
MW
Bottom
OFF
OFF
ON
ON
OFF
OFF
OFF
OFF
Top
OFF
ON
ON
OFF
OFF
OFF
OFF
OFF
Bottom
OFF
OFF
OFF
OFF
ON
ON
OFF
OFF
Timing Chart
HU
Input
HV
HW
MU Output
MV Output
MW Output
FG Output
PDE-3021-0
ECN3021
5.3 PWM Operation
The PWM signal is produced by comparing the input voltage at VSP terminal with the voltage from the
internal SAW wave. The duty of the PWM signal can be changed by the triangular wave amplitude level,
from the minimum point of VSAWL to the maximum point of VSAWH, and when the level is under
VSAWL, the duty becomes 0%, and when the level is over VSAWH, the duty becomes 100%. In addition,
chopping with the PWM signal is operated in the bottom arm circuit.
5.4 Over Current Limiting Operation
This IC detects over current by checking the voltage drop at the external resistance RS. When the input
voltage at RS terminal exceeds the internal reference voltage(Vref), this IC turns off the output of the bottom
arm circuit. After over current detection, reset operation is done at every period of the inner clock signal
(VTR terminal).
5.5
Rotating Direction Sense Operation
The rotation direction of the motor is detected by the signal at DM terminal. Table 1 shows the output signal
for the rotation direction.
Table 1.
Output signal for the rotation direction
Rotating Direction
Output (DM terminal)
U-V-W
L
U-W-V
H
5.6 Vcc under voltrage Detection
When Vcc supply voltage becomes below LVSDON(11.5V typ), all of the IGBTs shut off.
This condition is recovered when Vcc supply voltage becomes greater than LVSDOFF(12.0V typ).
PDE-3021-0
ECN3021
6.
Standard Application
Component
Recommended Value
C0
More than 0.22 µF
C1,C2
D1,D2
Rs
Usage
for inner power
supply(VB).
for charge pump
0.5 µF ± 20%
Hitachi DFG1C6(glass mold) for charge pump
Hitachi DFM1F6(resin mold)
or equivalent parts
Note 1.
for current limiting
Remark
stress voltage is VB
stress voltage is VCC
600V/1.0A
trr≤100ns
CTR
for PWM
Note 2.
1800 pF ± 5%
RTR
for PWM
Note 2.
22 kΩ ± 5%
Note 1. Start up current is limited by the following equation.
IO = Vref / Rs
(A)
Note 2. PWM frequency is approximately determined by the following equation.
fPWM = -1 / (2C*R*Ln(1-3.5/5.5))
; Ln is natural logarithm
= 0.494 / (C*R)
(Hz)
Note 3. It is recommended that RU,RV,RW should be 5.6 kΩ ± 5%.
RU
+
C2
+ -
RW
C0
CB
D1
D2
RV
VCC(15V)
HU
HV
HW
C+
-
VS
C1
CL
C-
VS1
VS2
VB
VCC
VB supply
Clock
Charge Pump
FG
FG
DM
Rotating
Direction
Monitor
Microprocessor
Analog
output
Comparator
VSP
Hall ICs
Top Arm
Driver
MV
3-Phase
Distributor
MW
+
CMP
-
Bottom Arm
Driver
SAW wave
Generator
VTR
Motor
Over Current Sense
+
Clock
CR
MU
GL
Vref
0.5V
RS
GH1
GH2
RTR
CTR
RS
Fig 3. Block diagram and external elements
PDE-3021-0
ECN3021
7.
Terminal
23
22
21
20
19
18
17
16
15
14
13
12
11
10
9
8
7
6
5
4
MV
VS1
MU
GH1
RS
HU
HV
HW
DM
FG
VSP
VTR
CR
CB
CL
CC+
GL
VCC
GH2
3
2
1
MW
VS2
(Marking side)
Fig.4 Pin Connection
8.
Package
Outline
ECN3021SP
ECN3021SPV
ECN3021SPR
PDE-3021-0
ECN3021
8.
Package Dimensions
(1) ECN3021SP
(2) ECN3021SPV
PDE-3021-0
ECN3021
(3) ECN3021SPR
31MAX
(30)
28
±0.3
20
±0.2
3.5 ±0.3
φ3.6
1.26
±0.24
23
±0.25
0.6 ±0.1
1.27
±0.5
2.54
±0.5
2.54
+10°
0°
−0°
0.25 typ
1.8 typ
7.1±0.5
4.9±0.5
23.97±0.3
+10°
0°
−0°
2.2±0.3
(9)
(7.7)
1
1.23
12.3±0.5
3.6
4.1 ±0.3
11.2 ±0.3
14.7MAX
±0.2
0.5 ±0.2
±0.2
±0.5
PDE-3021-0