ETC ECN3030F

P1/7
HIGH-VOLTAGE MONOLITHIC IC
ECN3030F/3031F
ECN3030F/3031F is a driver IC for a three-phase bridge inverter which has MOSFETs or IGBTs
for the outputs. Especially, it is very suitable for controlling the speed of three-phase DC
brushless motors to which converted AC100~115V power supplies are applied. The internal block
diagram is shown in Fig. 1.
Functions
*
*
*
*
*
*
Package
Integrated charge pump circuit
Integrated 3-phase distributor circuit
Integrated PWM circuit
Integrated over current protection circuit
Integrated rotating direction sense circuit
Integrated FG circuit
FP-28DJ(JEDEC)
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.
D1
VCC
RW RV RU
C0
CB
VCC
D2
Hall ICs
(15V)
HU
HV
HW
+
C1
-
C2
+ -
CL
C+
Vs
VS
VB
VB
Supply
(7.5V)
PGU
Charge Pump
CB
CLOCK
RM
FG
MonoMulti
PGV
PGW
Edge-
Top arm
Driver
FG
Trigger
MCR
MU
3-phase
Distributer
CM
RWD
MV
MW
VSP
+
CMP
SAW Wave
Generator
Motor
NGV
NGW
OC detection
+
CMP
-
CLOCK
Vref
Note.1
CR
NGU
Bottom arm
Driver
-
VTR
Filter
RS
GND
RTR
Note.1
CTR
ECN3030F:Vref=0.50V
Rs
ECN3031F:Vref=1.23V
Fig.1
Block diagram
PDE-3030F/31F-0
P2/7
ECN3030F/3031F
1.
2.
General
(1) Type
(2) Application
(3) Structure
(4) Package
ECN3030F, ECN3031F
3-Phase DC Brushless Motor
Monolithic IC
FP-28DJ(JEDEC)
Maximum Allowable Ratings (Ta=25°C)
No.
Items
Symbols
1 Output Device
VSM
Breakdown Voltage
2 Supply Voltage
VCC
3 Input Voltage
VIN
4
Operating Junction
Temperature
Storage Temperature
Terminal
VS
MU,MV,MW
VCC
VSP,RS,RWD
HU,HV,HW
Ratings
250
Unit
V
18
~ VB+0.5
V
V
~ +125
°C
-0.5
Tjop
-20
Condition
Note 1
°C
-40 ~ +150
Note1. Thermal resistance (Rj-a) is approximately 100°C/W. (When ICs are installed on a print board.)
The value of this resistance is determined by the result of the trial product.
5
3.
Tstg
Recommended Operating Conditions
No.
Items
Symbols Terminal
1 Supply Voltage
VS
VS
2
VCC
VCC
MIN
10
TYP
141
MAX
185
Unit
V
13.5
15
16.5
V
Condition
Within allowable
rating at Tjop
PDE-3030F/31F-0
P3/7
ECN3030F/3031F
4.
Electrical Characteristics (Ta=25°C)
Unless otherwise specified, VCC=15V, VS=141V
Suffix T; Top arm
B; Bottom arm
Suffix *;U,V,W Phase
No.
Items
Symbols Terminal
1 Standby Current
IS
VS
2
ICC
VCC
3 Output Source Current IO+T
PG*
4
IO+B
NG*
5 Output Sink Current
IO-T
PG*
6
IO-B
NG*
7 High Level Output
VOHT C+,PG*
Voltage
8
VOHB VCC,NG*
9
Low Level Output
Voltage
MIN
30
130
130
130
-
TYP
2.0
3.0
50
200
200
200
4.5
MAX
4.0
6.0
100
300
300
300
6.0
Unit
mA
mA
mA
mA
mA
mA
V
Condition
VSP<VSAWL
HU=L
-
-
0.2
V
Between VCC and
NG* Voltage
20V between C+ and PG*
10V between VCC and NG*
10V between PG* and M*
10V between NG* and GND
VOLT
PG*,M*
-
-
0.2
V
Between PG* and
M* Voltage
10
VOLB
NG*,GND
-
-
0.2
V
Between NG* and
GND Voltage
11 Output Resistance at
VTR terminal
12 Amplitude Level of
13 SAW wave
14 Amplitude of
SAW wave
15 Reference Voltage for
Over Current detection
16 Input Voltage
17
18 Input Current
RVTR
VTR
-
200
400
W
IVTR=1mA
4.9
1.7
2.8
5.4
2.1
3.3
6.1
2.5
3.8
V
V
V
Note 2
0.45
1.107
3.5
-
0.5
1.230
-
0.55
1.353
1.5
50
V
V
V
V
mA
-100
-
-
mA
VSAWH CR
VSAWL CR
VSAWW CR
Vref
RS
VIH
VIL
IIH
HU,HV,HW
RWD
VSP
IIL
HU,HV,HW
RWD
CB
CB
FG
IO=
0A
Between C+ and
PG* Voltage
Note.5
only for ECN3030F
only for ECN3031F
VSP=5.0V Note 1
Pull Down Resistance
19
HU,HV,HW,RWD=0V
Note 1 Pull Up Resistance
V IB=0mA
mA delta VB£0.2V
W Note 3
IFG=1mA
V Note 4
20 VB Output Voltage
VB
6.8
7.5
8.2
21 VB Output Current
IB
25
22 Output Resistance at
RFG
250
400
FG terminal
23 Reference Voltage for Vref2
MCR
VB´2/3 VB´2/3 VB´2/3
FG pulse
´0.95
´1.05
24 Charge Pump Voltage VCP
C+,VS
13.0
14.5
V
Note1. The pull up resistance and the pull down resistance are
typically 200 kW.
Note2. Please see Note 2 in item 6 for determining the frequency of
SAW wave.
Note3. The equivalent circuit at FG terminal is shown in Fig. 2
Note4. Please see Note 3 in item 6 for determining the FG output
pulse width.
Note5. The amplitude of SAW(VSAWW) is determined by the
following equation,
VSAWW=VSAWH-VSAWL
(V)
Note6. The charge pump voltage (VCP) is determined by the voltage
Fig. 2
between C+ and VS.
At stand-by
Note 6
VB
FG
Equivalent circuit
around FG
PDE-3030F/31F-0
P4/7
ECN3030F/3031F
5.
Function
5.1
Truth Table
Input
U Phase
V Phase
W Phase
RWD
HU
HV
HW
Top
Bottom
Top
Bottom
Top
Bottom
H
H
L
H
L
H
H
L
L
L
H
H
L
L
L
H
L
L
H
L
H
H
H
L
L
L
L
H
H
L
H
L
H
L
H
L
L
H
L
L
H
L
H
H
H
L
L
L
L
H
H
L
L
H
L
L
H
L
L
H
L
H
H
L
L
L
H
L
L
H
L
H
L
L
H
L
L
L
L
H
L
H
L
H
H
L
L
H
L
L
L
L
L
H
L
L
L
H
H
L
L
L
H
H
L
H
L
L
H
L
L
L
H
L
L
H
H
L
L
L
-
L
L
L
L
L
L
L
L
L
H
H
H
L
L
L
L
L
L
Note1. Top arm
: Output voltage for between PG* and M*.
Bottom arm : Output voltage for between NG* and GND.
Note2. It is possible to change the rotation direction of the motor by putting a signal into RWD terminal.
A method of using is shown in item 5.7.
5.2
Timing Chart
( RWD = H )
HU
Input
HV
HW
Output Voltage
PGU-M U
NGU-GND
PGV-M V
NGV-GND
PGW -M W
NGW -GND
FG
tM
PDE-3030F/31F-0
P5/7
ECN3030F/3031F
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 linearly 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 PWM signal.
5.5 FG operation
One shot pulse is put out at this terminal synchronized with the rising edge of the synthesized signal of the
hole signal HU, HV, HW. The pulse width tM is decided by the constant number which is determined by R
and C at MCR terminal(See No.6 Standard Application.). One shot pulse is produced in a mono-multi circuit.
This circuit has a retrigger feature which keeps the output signal high when a trigger is input during high
signal of FG output.
FG synthesized
wave
Triggered
pulse
Vref2
MCR voltage
FG output
voltage
tM
tM
tM
Usual operation
Retriggered operation
5.6 VCC Under Voltage Detection Operation
When VCC becomes lower than the determined voltage, all arms
operation and the charge pump operation are forced to stop.
The detection voltage is typically 11.5V, and it also has a
hysterisis of 0.5V. However, there may be a case when the
operation is canceled under 2V of VCC.
5.7 Rotating Direction of the Motor
The rotating direction of the motor can be changed
by inputting “H” or “L” signal to RWD terminal.
Please do not change this signal at operation. This
may cause short through of the output Device.
However, it is OK if the VSP input voltage is below
VSAWL(1.7V typ.) before RWD input voltage
change so that the short through is avoided.
*;U/V/W
NG*,
PG*-M*,
CL
(V)
recover
operation
0
hysterisis
VCC (V)
Fig 3. Protection operation for VCC
under voltage
PDE-3030F/31F-0
P6/7
ECN3030F/3031F
6.
Standard Application
6.1 External Parts
Component
Recommended Value
C0
More than 0.22 mF
Usage
Remark
for smoothing Internal
stress voltage is VB
Power Supply(VB).
C1,C2
for charge pump
stress voltage is VCC
1.0 mF ± 20%
D1,D2
Hitachi DFG1C4(glass mold) for charge pump
400V/1.0A
Hitachi DFM1F4(resin mold)
trr£100ns
or equivalent parts
Rs
Note 1
for current limiting
CTR
for PWM
Note 2
1800 pF ± 5%
RTR
22 kW ± 5%
RU,RV,RW 5.6 kW ± 5%
pull up resistance
CM
More than 1000pF
for Output Pulse width at Note 3
RM
FG terminal
More than 10 kW
Note1. The start up current is limited by the following equation.
IO = Vref / Rs
(A)
Note2. The PWM frequency is approximately determined by the following equation. At the recommended
Value of CR, the error factor of IC is about 10%.
fPWM = -1 / (2C´R´Ln(1-3.5/5.5))
; Ln is natural logarithm
= 0.494 / (C´R)
(Hz)
Note3. The FG output pulse width is determined approximately by the following equation.
tM³10ms should be necessary.
tM = -(CM´RM´Ln(1-VB´2/3/VB))
= 1.1´CM´RM
(s)
D1
VCC
RW RV RU
C0
CB
VCC
D2
Hall ICs
(15V)
HU
HV
HW
+
C1
-
C2
+ -
CL
C+
Vs
VS
VB
VB
Supply
(7.5V)
PGU
Charge Pump
CB
CLOCK
RM
FG
MonoMulti
PGV
PGW
Edge-
Top arm
Driver
FG
Trigger
MCR
MU
3-phase
Distributer
CM
RWD
MV
MW
VSP
+
CMP
Bottom arm
Driver
-
SAW Wave
Generator
Motor
NGV
NGW
OC detection
+
CMP
-
CLOCK
Vref
Note.1
CR
NGU
VTR
RTR
CTR
Filter
RS
GND
Note.1
ECN3030F:Vref=0.50V
Rs
ECN3031F:Vref=1.23V
Fig.4
Block diagram with external parts
6.2 Supply Voltage Sequence
The order for turning on power supplies should be (1)Vcc, VS (2)VSP. The order for turning off should be
(1)VSP (2)VS, Vcc. When the order is mistaken, there may be a case when the external bridge circuit is broken.
PDE-3030F/31F-0
P7/7
ECN3030F/3031F
7.
Terminal
1
2
3
4
5
6
7
8
9
10
11
12
13
14
FG
M CR
CR
VTR
HU
HV
HW
VSP
RWD
RS
CB
NGU
NGV
NGW
MU
PGU
N .C
MV
PGV
N .C
MW
PGW
N .C
C+
VS
CL
VCC
GND
28
27
26
25
24
23
22
21
20
19
18
17
16
15
(M ark in g sid e)
F ig. 5
8.
P in co n n ectio n
Package Dimensions
15
1
14
7.52±0.10
28
10.31±0.20
18.13MAX
0.22±0.05
0.15
0.53±0.20
0.15
+0.05
-0.10
2.59MAX
1.27 ±0.10
+0.10
0.41 -0.05
PDE-3030F/31F-0