DIODES ZXBM200XX10TC

ZXBM2001
ZXBM2002 ZXBM2003
VARIABLE SPEED 2-PHASE FAN MOTOR CONTROLLER
DESCRIPTION
The ZXBM200x is a series of 2-phase, DC brushless motor pre-drivers with PWM
variable speed control suitable for fan and blower motors.
FEATURES
· Built in lock detect protection, rotational speed sensing and automatic recovery
· Built in Hall amplifier allows direct connection to Hall element
· PWM Speed control via
- External voltage
- Thermistor input
- External PWM source
· Speed (FG) pulse output – ZXBM2003
· Rotor lock output – ZXBM2002
· Combined Rotor Lock (RD) and Speed (FG) signal – ZXBM2001
· Up to 18V input voltage (60V with external regulator)
· MSOP10 package
APPLICATIONS
· Mainframe and Personal Computer Fans and Blowers
· Instrumentation Fans
· Central Heating Blowers
· Automotive climate control
ORDERING INFORMATION
DEVICE
REEL SIZE
TAPE WIDTH
QUANTITY PER REEL
ZXBM200xX10TA
7” (180mm)
12mm
1,000
ZXBM200xX10TC
13” (330mm)
12mm
4,000
Example: ZXBM2001X10TA
DEVICE MARKING
ZXBM2001 or BM21
ZXBM2002 or BM22
ZXBM2003 or BM23
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SEMICONDUCTORS
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Absolute maximum ratings
Parameter
Symbol
Limits
Unit
Supply Voltage
V CCmax
-0.6 to 20
V
Input Current
I CCmax
200
mA
Power Dissipation 25°C
P Dmax
500
mW
Operating Temp.
T OPR
-40 to 85
⬚C
Storage Temp.
T STG
-55 to 150
⬚C
Power Dissipation
1) Maximum allowable Power Dissipation, PD,
is shown plotted against Ambient Temperature,
TA, in the accompanying Power Derating Curve,
indicating the Safe Operating Area for the device.
2) Power consumed by the device, PT, can be
calculated from the equation:
PT = PQ + PPh
where
PQ is power dissipated under quiescent
current conditions, given by:
PQ = VCC x ICC
where VCC is the application
device Supply Voltage
and
ICC is the maximum Supply
Current given in the Electrical
Characteristics
and
PPh is power generated due to either one of
the phase outputs Ph1 or Ph2 being
active, given by:
PPh = IOL x VOL
where
and
IOL is the application Ph1 and Ph2
output currents
VOL is the maximum Low Level
Output Voltage for the Ph1 and
Ph2 outputs given in the Electrical
Characteristics
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Electrical Characteristics (at Tamb = 25°C & VCC = 12V)
Parameter
Symbol
Min
Supply Voltage
V CC
4.5
Supply Current
I CC
Hall Amp Input Voltage
Typ
2.2
Max
Unit
18
V
3.25
mA
No Load 1
mV
diff p-p
40
Conditions
Hall Amp Common Mode Voltage
V CM
Hall Amp Input Offset
V OFS
±7
mV
Hall Amp Bias Current
V BS
-350
nA
PH1, PH2 Output High
V OH
V CC -1.8
V
PH1, PH2 Output Off Leakage
Current
I OFF
⫾10
␮A
PH1, PH2 Output Current High
I OH
-80
mA
Lock/FG Maximum Collector
Voltage
V OH
V CC
V
Lock/FG Sink Current
I OL
5
mA
Lock/FG Low Level O/P Voltage
V OL
0.5
V
I OL = 5mA
␮A
V in = 1.5V
␮A
V in = 1.5V
C LCK Charge Current
I LCKC
C LCK Discharge Current
I LCKD
Lock condition On:Off ratio
0.5
V CC -2.2
0.5V CC
0.3
-1.8
-2.8
0.28
1:7
V CC -1.5
0.35
V
I OH = 80mA
1:10
C LCK High Threshold Voltage
V THH
2.0
V
C LCK Low Threshold Voltage
V THL
1.0
V
C PWM Charge Current
I PWMC
3.6
4.3
5.0
␮A
V in = 1.5V
C PWM Discharge Current
I PWMD
50
62
75
␮A
V in = 1.5V
PWM Frequency
F PWM
24
34
kHz
kHz
C PWM = 150pF
C PWM = 100pF
C PWM High Threshold Voltage
V THH
2.0
V
C PWM Low Threshold Voltage
V THL
1.0
V
SPD Voltage Control Range
V SPD
1
SPD Open Circuit Voltage
2
1.5
V
2
V
3
Notes:
1
Measured with pins H+, H-, CLCK and CPWM = 0V and all other signal pins open circuit.
2
The 1V minimum represents 100% PWM drive and 2V represents 0% PWM drive.
3
This voltage is determined by an internal resistor network of 52.5k⍀ from the pin to Gnd and 19.5k⍀ from the pin to a 2V reference. Whilst both
resistors track each other the absolute values are subject to a ±20% manufacturing tolerance
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SEMICONDUCTORS
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Block Diagram (ZXBM2001):
Pin Assignments
Top View
Pin Functional Descriptions
1. VCC
- Applied voltage
2. H+
3. H-
This is the device supply voltage. For 5V to 12V fans this
can be supplied directly from the Fan Motor supply. For
fans likely to run in excess of the 18V maximum rating
for the device this will be supplied from an external
regulator such as a zener diode.
- Hall input
- Hall input
The rotor position of the Fan Motor is detected by a Hall
sensor whose output is applied to these pins. This
sensor can be either a 4 pin ‘naked’ Hall device or a 3
pin buffered switching type. For a 4 pin device the
differential Hall output signal is connected to the H+
and H- pins. For a 3 pin buffered Hall sensor the Hall
device output is attached to the H+ pin whilst the H- pin
has an external potential divider attached to hold the
pin at half VCC. When H+ is high in relation to H- Ph2 is
the active drive.
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4. SPD
On the ZXBM2001 the Lock/FG pin is designed to be a
dual function pin to provide an indication of the Fans
rotational speed together with an indication of when
the Fan has failed rotating for whatever reason (Rotor
Locked condition). Under correct operating conditions,
and with the external pull-up in place, this pin will
provide an output signal whose frequency will be twice
that of the rotational frequency of the fan. Should the
fan itself stop rotating for any reason, i.e. an
obstruction in the fan blade or a seized bearing, then
the device will enter a Rotor Locked condition. In this
condition the Lock/FG pin will go high (regardless of
the state of the Hall sensor) when the CLCK pin reaches
the VTHH threshold and will remain high until the fan
blades start rotating again.
- Speed control voltage input
This pin provides control over the Fan Motor speed by
varying the Pulse Width Modulated (PWM) drive ratio
at the Ph1 and Ph2 outputs. This control signal can take
the form of either a voltage input of nominal range 2V
to 1V, representing 0% to 100% drive respectively, or
alternatively a thermistor can be attached to this pin to
control the voltage. A third method of speed control is
available by the application of an externally derived
PWM signal and this will be discussed under the CPWM
pin.
This pin has an internal potential divider between an
internal 2.0V reference and Gnd (see Block Diagram)
designed to hold the pin at approximately 1.5V. This
will represent a drive of nominally 50% PWM. For
thermal speed control a 100k NTC thermistor is
connected between the SPD and ground will provide a
drive nominally 70% at 25°C and 100% at 50°C. As the
thermistor is connected in parallel with the internal
resistor the non-linearity of an NTC thermistor is
largely taken out. A linearity of typically ±2.5% is
achievable.
On the ZXBM2002 variant this pin is Lock. During
normal operation the signal will be low and during a
Locked Rotor condition the pin will go high when the
CLCK pin reaches the VTHH threshold.
For the ZXBM2003 variant this pin is FG. This signal is a
buffered and inverted output of the Hall signal and
therefore provides an output signal whose frequency
will be twice that of the rotational frequency of the fan.
Lower values of thermistor can be used if needed and
in this situation an external potential divider will be
needed to set the speed range. This will take the form of
a resistor from the SPD pint to Vcc and a resistor from
the SPD pin to Gnd. Full details are given in the
ZXBM200x series Application Note.
7. CLCK
When in a Locked Rotor condition as described above
the Ph1 and Ph2 drive outputs go into a safe drive mode
to protect the external drive devices and the motor
windings. This condition consists of driving the motor
for a short period then waiting for a longer period
before trying again. The frequency at which this takes
place is determined by the size of the capacitor applied
to this CLCK pin. For a 12V supply a value of 1.0uF will
typically provide an ‘On’ (drive) period of 0.33s and an
‘Off’ (wait) period of 4.0s, giving an On:Off ratio of 1:12.
If speed control is not required this pin is can be left
open circuit for 50% drive or tied to ground by a 10k⍀
resistor to provide 100% drive.
If required this pin can also be used as an enable pin.
The application of a voltage of 2.0V to VCC will to force
the PWM drive fully off, in effect disabling the drive.
5. GND
- Ground
The C LCK timing periods are determined by the
following equations:
This is the device supply ground return pin and will
generally be the most negative supply pin to the fan.
6. LOCK/FG
- Locked Rotor timing capacitor
Tlock =
- Locked Rotor error output /
Frequency Generator (speed) output
V THH × C LCK
ILCKC
(V THH − V THL) × C LCK
ILCKD
(V THH − V THL) × C LCK
Ton =
ILCKC
Toff =
Where VTHH and VTHL are the CLCK pin threshold
voltages and ILCKC and ILCKD are the charge and
discharge currents.
This pin is an open collector output and so will require
an external pull up resistor for correct operation.
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SEMICONDUCTORS
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Locked Rotor timing capacitor (CONT).
TPWM =
The CPWM pin can also be used as in input for an
externally derived PWM signal to control the motor
speed. The signal should have a VOL <1V and a VOH
>2V. A standard TTL or CMOS digital signal is ideal.
When driving from an external PWM source no
capacitor should be attached to the CPWM pin and the
SPD pin should be left open circuit.
As these threshold voltages are nominally set to
VTHH=2V and VTHL=1V the equations can be simplified
as follows:
Tlock =
8. CPWM
2 × C LCK
ILCKC
Ton =
C LCK
ILCKC
Toff =
C LCK
ILCKD
- Sets PWM frequency
- external PWM input
9. PH2
10. PH1
This pin has an external capacitor attached to set the
PWM frequency for the Phase drive outputs. A
capacitor value of 0.15nF will provide a PWM
frequency of typically 24kHz.
- External transistor driver
- External transistor driver
These are the Phase drive outputs and are open
darlington emitter followers designed to provide up to
80mA of drive to external transistors as shown in the
Application circuits following. The external transistors
in turn drive the fan motor windings.
The CLCK timing period (Tpwm) is determined by the
following equation:
Tlock =
C
C
+
IPWMC IPWMD
(V THH - V THL) × C (V THH − V THL) × C
+
IPWMC
IPWMD
Where TPWM is in ␮s
C = CPWM +15 in pF
IPWM & IPWMD are in ␮A
Where VTHH and VTHL are the CPWM pin threshold
voltages and IPWMC and IPWMD are the charge and
discharge currents.
As these threshold voltages are nominally set to
VTHH=2V and VTHL=1V the equations can be simplified
as follows:
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Lock & FG Timing Waveform:
Lock Timing Example:
Using the equation previously described and to be
found under the CLCK pin description:
Tlock =
2 × C LCK
ILCKC
Ton =
C LCK
ILCKC
Toff =
C LCK
ILCKD
Using a value of CLCK = 1.0uF together with the values
of I LCKC and I LCKD to be found in the Electrical
Characteristics we can derive the following timings for
operation at 12V and 25°C.
Tlock =
2 × 1.0␮F
1.0␮F
= 0.714s
= 3.6s
Toff =
2.8␮A
0.28␮A
2 × 1.0␮F
= 0.36s
Ton =
2.8␮A
Figure 2
TYPICAL APPLICATION (ZXBM2001) using MOSFET power transistors
Figure 1
TYPICAL APPLICATION (ZXBM2001) using Bipolar power transistors
Graph 1
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SEMICONDUCTORS
ZXBM2001
ZXBM2002 ZXBM2003
APPLICATION INFORMATION
Also illustrated in the two Applications circuits above
are the methods of connection for both a ‘naked’ Hall
device, as seen in the bipolar circuit in Figure 1, and a
buffered Hall device, as in the MOSFET circuit in Figure
2. In this latter circuit R5 & R6 bias the H- pin at a voltage
equivalent to half the swing of the Hall device. R7 will
be needed if the buffered Hall device does not have its
own internal pull-up.
This section gives a brief insight into applications using
the ZXBM200x series. More complete data is available
in the ZXBM200x Series Applications Note, visit
www.zetex.com/zxbm or contact your nearest Zetex
office for full details.
The ZXBM200x series of 2-phase DC brushless motor
pre-drivers are capable of driving both Bipolar or
MOSFET power transistors.
Graph 1 below, illustrates the PWM drive waveform
taken from and application using the MOSFET circuit in
Figure 2. This shows the waveforms to be found at the
Ph1 output and at the drain/Winding node.
For smaller fans and blowers it is likely that bipolar
power transistors would be used as shown in the
following Applications circuit.
In Figure 1, R1 & R2 have their value selected to provide
suitable base current in keeping with the winding
current and gain of the power transistors Q1 & Q2. R3 &
R4 have their value selected to provide efficient
switch-off of Q1 & Q2. The Zener diodes ZD1 & ZD2
provide active clamping in conjunction with Q1 & Q2.
It is also recommended that the supply de-coupling
capacitor C3 is positioned as close as is practical to the
ZXBM device pins.
In the case of higher power fans and blowers it may be
more applicable to use MOSFET devices to switch the
windings as illustrated in the second applications
circuit shown in Figure 2.
In Figure 2, the Resistor ratio of R1 to R3 and R2 to R4
provide the required Gate turn-on voltage whilst the
absolute values will be chosen to provide sufficient
gate switching currents.
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SEMICONDUCTORS
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When driving fans with bipolar transistors, at higher
voltages it may be necessary to provide extra noise
protection by the addition of a diode from the driver
collector to Gnd on each phase. This prevents negative
voltage excursions from the windings affecting
operation. See Figure 3 right, showing the placement
of these diodes. It should be noted that these are not
required for the MOSFET solution in Figure 2 as the
diodes are inherent in the MOSFET structure.
Zetex provide a variety of suitable power transistors for
using with the ZXBM200x series of 2-phase DC
brushless motor pre-drivers and suitable devices
sufficient for a range of applications are given in the
following table.
Figure 3
TYPICAL APPLICATION (ZXBM2001) illustrating addition of Clamp
diodes.
SUMMARY TABLE OF SUITABLE DEVICES
Bipolar Types
V CEO (V)
I C (A)
min H FE @ I C
V CE(sat) max(mV)
Package
@ IC & IB
FZT1053A
75
4.5
300 @ 0.5A
200 @ 1A, 10mA
FZT851
60
6
100 @ 2A
100 @ 1A, 10mA
SOT223
FZT853
100
6
100 @ 2A
175 @ 1A, 100mA
SOT223
FZT855
150
4
100 @ 1A
65 @ 0.5A, 50mA
SOT223
ZXT13N50DE6
50
4
300 @ 1A
100 @ 1A, 10mA
SOT23-6
MOSFET Types
BV DSS (V)
I D (A)
I PEAK (A)
R DS(on) max(m )
Package
(Pulsed)
@ V GS
ZXMN3A04DN8
ZXMN6A09DN8
ZXMN6A11Z
2 3
30
7.6
25
20 @ 10V
2 3
60
5
17.6
45 @ 10V
SO8
60
3.8
10
140 @ 10V
SOT89
60
3.8
10
140 @ 10V
SOT223
100
1.9
5.9
600 @ 10V
SOT223
1
ZXMN6A11G
ZXMN10A11G
SOT223
2 4
SO8
Notes:
1
Contact your nearest Zetex office for further details and technical enquiries.
2
Dual device
3
Provisional information
4
Advanced information
ISSUE 4 - OCTOBER 2004
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SEMICONDUCTORS
ZXBM2001
ZXBM2002 ZXBM2003
PACKAGE OUTLINE
PACKAGE DIMENSIONS
DIM
MILLIMETERS
INCHES
MIN.
MAX.
MIN.
A
ᎏ
1.10
ᎏ
MAX.
0.43
A1
ᎏ
0.15
ᎏ
0.006
A2
0.75
0.95
0.0295
0.037
D
3.00 BSC
0.118 BSC
E
4.90 BSC
0.1929 BSC
E1
3.00 BSC
0.118 BSC
b
0.17
0.27
0.0066
0.0106
c
0.08
0.23
0.003
0.009
e
0.50 BSC
0.0196 BSC
⍜
0⬚
15⬚
0⬚
15⬚
L
0.40
0.80
0.015
0.031
L1
0.95 BSC
0.037 BSC
Conforms to JEDEC MO-187 VARIATION BA
CONTROLING DIMENSIONS IN METRIC
APPROX. DIMENSION IN INCHES
© Zetex Semiconductors plc 2004
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Telephone (44) 161 622 4444
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These offices are supported by agents and distributors in major countries world-wide.
This publication is issued to provide outline information only which (unless agreed by the Company in writing) may not be used, applied or reproduced
for any purpose or form part of any order or contract or be regarded as a representation relating to the products or services concerned. The Company
reserves the right to alter without notice the specification, design, price or conditions of supply of any product or service.
For the latest product information, log on to www.zetex.com
ISSUE 4 - OCTOBER 2004
SEMICONDUCTORS
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