SANKEN SI

Unipolar Driver ICs
SI-7115B
■ Characteristics
(Ta = 25°C)
Parameter
Type No.
Absolute maximum rating
Applied
voltage
Output
current
Junction
temperature
Vsurge(V)
Io(A/ø)
Tj(°C)
SI-7115B
40
1.7
125
Electrical characteristics
Operating
Storage
Supply
Output
Input
ambient
temperature
voltage
current current
temperature
Vcc(V)
Io(A) Iin(mA)
Top(°C)
Tstg(°C)
min typ max min max min max
–20 to +80
–30 to +100
20 24 30 0.2 1.5
Phase switching signal input
Oscillation
frequency Output
f (kHz) current
min max (A/ø)
5.0 19 24
ON
OFF
Input
Input
Input
voltage current voltage
(V)min (mA)min (V)max
0.2
2.7
1.0
0.5
3.1
1.2
1.0
3.6
1.4
1.5
4.5
2.0
0.8
■ Block diagram
VCC
Reference
voltage
Oscillator
circuit
Comparator
amplifier
Current
controller
M
Rx
Counter EMF
canceller
Output current fine
adjustment resistor
Excitation signal (4-phase)
Current detection
resistor
Excitation signal
amplifier
SI-7115B
■ Equivalent circuit diagram
■ External connection diagram
18
6
9
7
10
VCC
Q2
Q1
D4
D5
D1
D3
D2
D6
17
14
16
13
15
8
Q3
Q4
Q5
Q6
RS1
RS2
12
11
1
Excitation
signal
input
Active
High
µF
2.2
10V
+
+
–
–
Stepper motor
18
A
B
A
B
8
13
10
15
1
+
a
–
Rx
b
17
6
SI-7115B
2
4
5
3 11
7
9
14
16
A
A
B
B
12
5
Oscillator
circuit
4
2
3
33
SI-7115B
■ External dimensions
(Unit: mm)
Plastic package
Dimensions of SI-7115B pins
9.0±0.6
71.7±0.5
60.3±0.4
39.6±0.5
11.5±1
Type No.
Lot No.
8.0
4.0
0.4
4
Aluminum
plate
φ 3.4
11.5±1
0.5
P=2.54
43.2
1 2 3
18
Application Note
■ Determining the output current Io (motor coil current)
Fig. A SI-7115B External resistor vs. Output current
1.5
Output current IO (A/φ )
The output current Io can be set to any value by connecting
an external resistor RX across pin 3 and all of pins 2, 4 and
5. Fig. A, B and C show the relationship between the
external resistor and the output current, the supply voltage
and the output current, and the output current and the
temperature, respectively.
Output current IO
Output current IO
RX
0.31 to 0.39 (A/ø)
200 (Ω)
0.95 to 1.05 (A/ø)
1.4 (kΩ)
Condition VCC = 24V, Ta = 25°C
2-phase excitation
Holding mode
Motor: 23PM-C109
1.0
0.5
VCC
24(V)
Rt
3.6(Ω)
Motor : 23PM-C109
0
0
3
4
External resistor Rx (kΩ)
Fig. B SI-711B Supply voltage vs. Output current
Fig. C SI-7511B Output current vs. Temperature
1.5
Motor : 23PM-C109
Rx
1.5
Motor : 103G-775-1240
VCC = 24V
Output current IO (A/φ )
Output current IO (A/φ )
3.9kΩ
2kΩ
1.0
1kΩ
600Ω
300Ω
0.5
RX = 1.4kΩ
1.0
RX = 560Ω
0.5
100Ω
0
0
20
22
24
26
28
Supply voltage VCC (V)
34
30
0
0
20
40
60
80
100
Case (aluminium base plate) temperature Tc (°C)
SI-7115B
Application Note
■ Power down mode
■ Thermal design
The SI-7115B can be operated in power down mode. The
circuit is shown below.
As shown in the figure,
Power down circuit
when the power down tran2
sistor is switched on, (Ry
4
is power down resistor)
RY
RX/RY becomes a current
5
fixing resistance and the
R
X
SI-7115B
current during power down
mode can be obtained by
3
substituting this resistance
to RX in the previous Fig. Power down Transistor TR
A.
In SI-7115B, the avalanche diode of the phase-switching
transistor is operated in breakdown condition and the energy built up in the inductance of the motor coil is dissipated
as heat of the transistor. Hence, when the motor rotates,
the internal heat dissipation increases compared with when
the motor is stopped.
Therefore, the internal heat dissipation of 7115B can be
computed from the data taken with actual load through the
following procedures.
(1) Vary the rotation speed of the motor within the actual
operating range in a circuit under actual load conditions
and measure the supply current ICC and the corresponding output current IO1 and IO2.
Method for measuring current
(circuit under actual load conditions)
■ Example of Frequency vs.
Torque characteristics
The following two graphs show the relationship between
frequency (pps) and pull-out torque (kg - cm) of SI-7115B
when used with two types of motor.
VCC
A
ICC
15
Excitation
signals
SI-7115B
Pull-out torque (kg-cm)
2.0
Torque characteristics
8
13
10
15
1
2-p
1-2 phase excitation
A
B
A
B
has
e ex
µF
2.2
10V
cita
tion
a
+
–
Rx
b
Stepper motor
IO1
A
17
A
6
IO2
SI-7115B
2
4
5
3 11
A
7
9
14
16
A
B
B
12
1.0
(2) Obtain the internal power dissipation Pdiss (4-phase) of
7115B through the following formula.
Motor
103G–775–1240
VCC=24V
IO = 1.0A/φ
Pdiss = VCC•I CC – (IO12 + I O22)•R L
The figure below shows the relationship between frequency
(PPS) and I CC, Pdiss, and case temperature TC.
0
50
100
500
1000
5000
Frequency (PPS)
SI-7115B Frequency vs. Supply current, Internal power
dissipation and Case temperature (Example)
SI-7115B
Torque characteristics
ICC
ICC Supply current
A
Pdiss = VCC • ICC
VCC
2
2
-RL (IO1 + IO2 )
TC Temperature of heatsink
adjacent to SI-7115B
2-phase excitation
4.0
A
SI
7115B
I01
A I02
M
Motor : 23 PM-C109 no load
VCC = 24V
IO = 1.0A/ φ
2-phase excitation
Heatsink 100 x 100 x 2A
Ta = 25°C
ABAB
2p
1-
2
20
100
s
ha
PD (W)
10
Pdiss
n
tio
ita
xc
1
TC (°C)
TC
ICC (A)
3.0
ee
1.0
0
50
100
500
1000
Frequency (PPS)
5000
0
0
50
Case temperature
Motor KP6M2-001
VCC=24V
IO = 1.0A/φ
Supply current
2.0
Internal heat
dissipation
Pull-out torque (kg-cm)
5.0
max
ICC
0
0
500
1000
1500
Frequency (PPS)
35
SI-7115B
Application Note
(3) Obtain the heatsink area corresponding to the ambient
temperature Ta from the derating curve.
SI-7115B Derating curve
24
0×
20
20
0×
2(
3.4
0×
°C
10
)
/W
15
16
0×
2
(3
.75
°C
10
/W
0×
1
12
)
00
×2
(4.
7°C
/W
)
8
No he
atsink
4
0
0
20
40
60
Ambient temperature Ta (°C)
36
(4) Verify that the temperature of the aluminum base plate
of 7115B or adjacent heatsinks is below 85°C (equivalent to max. ambient temperature) when operating under actual load conditions.
SI-7115B
Aluminum heatsink
Using silicone grease
Unit : mm
10
Internal power dissipation PD (W) (2-phase)
28
80
SI-7200M, SI-7230M, SI-7115B, SI-7300A,
SI-7330A, SI-7500A and SI-7502
Handling Precautions
(Note: The SI-7502 is applicable for item (2) only.)
For details, refer to the relevant product specifications.
(1) Tightening torque:
The torque to be applied in tightening screws when mounting the IC on a
heatsink should be below 49N•m.
(2) Solvent:
Do not use the following solvents:
Substances that
Chlorine-based solvents
: Trichloroethylene,
dissolve the package
Trichloroethane, etc.
Aromatic hydrogen compounds : Benzene, Toluene,
Xylene, etc.
Ketone and Acetone group solvents
Substances that
weaken the package
Gasoline, Benzine and Kerosene
(3) Silicone grease:
The silicone grease to be used between the aluminum base plate of the hybrid
IC and the heatsink should be any of the following:
• G-746
SHINETSU CHEMICAL INDUSTRIES CO., LTD.
• YG6260
TOSHIBA SILICONE CO., LTD.
• SC102
DOW CORNING TORAY SILICONE CO., LTD.
Please pay sufficient attention in selecting silicone grease since oil in some
grease may penetrate the product, which will result in an extremely short
product life.
Others
• Resistance against radiation
Resistance against radiation was not considered in the development of these ICs
because it is assumed that they will be used in ordinary environment.
54