BB PWS750-3U

®
PWS750
Isolated, Unregulated
DC/DC CONVERTER COMPONENTS
FEATURES
APPLICATIONS
● 100% TESTED FOR HIGH-VOLTAGE
BREAKDOWN
● COMPACT-SURFACE MOUNT
● MULTICHANNEL OPERATION
● INDUSTRIAL PROCESS CONTROL
EQUIPMENT
● GROUND-LOOP ELIMINATION
● PC-BASED DATA ACQUISITION
● 5V OR 15V INPUT OPTIONS
● FLEXIBLE USE WITH PWS740/PWS745
COMPONENTS
● VENDING MACHINES
The PWS750-2U and PWS750-4U are split-bobbin
wound isolation transformers using a ferrite core.
They are encapsulated in plastic packages, allowing a
high isolation voltage rating.
DESCRIPTION
The PWS750 consists of three building blocks for
building a low cost DC/DC converter. With them you
can optimize DC/DC converter PC board layout or
build a multichannel isolated DC/DC converter. All
parts are surface mount, requiring minimal space to
build the converter. The modular design minimizes the
cost of isolated power.
The PWS750-1U is a high-frequency (800kHz nominal) driver that can drive N-channel MOSFETs up to
the size of a 1.3A 2N7010. The recommended
MOSFET for individual transformer drivers is the
2N7008. The PWS750-1U is supplied in a 16-pin
double-wide SO package.
PWS750 SINGLE-CHANNEL CONNECTION
+V
10µH
Reference
Comparator
(3)
1
RS
VD 3
Driver
Input
Gnd
10Ω
2N7002 (2)
or
2N7008
D
G
Differential
Amplifier
TTLOUT
14
16
PWS750-3U
4
6
3
7
2
0.3µF
(3)
Soft
Start
Oscillator
12
PWS750-2U
5
3
4
6
1
S
T
11
0.3µF
One PWS750-1U can be used to drive up to four
channels (15V nominal operation). One PWS750-2U
and PWS750-3U and two 2N7002 (surface mount) or
2N7008 (TO-92) MOSFETs made by Siliconix are
used per isolated channel. When a PWS750-4U is
used as the transformer (5V input), then two TN0604s
made by Supertex must be used, due to the higher
currents of the primary (lower RDS on) and the lower
VGS threshold. With 5V operation only one channel
can be directly driven by the PWS750-1U (a simple
FET booster circuit can be used for multichannel
operation; see Figure 3).
(1)
PWS750-1U
+VIN 7
The PWS750-3U is a high-speed monolithic diode
bridge in a plastic 8-pin SO package.
D
10Ω
G
T
10
Enable
TTLIN
Typical Connection for
Internal Oscillator Operation
S
Output
(2)
2N7002
Ground
or
2N7008
Duplicate for multichannel
operation with PWS750-2U.
0.3µF
0.3µF
(1)
(1)
10Ω
10Ω
–VO
+VO
NOTES: (1) User option. (2) Use TN0604 for 5V to ±15V operation. (3) Multichannel Operation.
International Airport Industrial Park • Mailing Address: PO Box 11400, Tucson, AZ 85734 • Street Address: 6730 S. Tucson Blvd., Tucson, AZ 85706 • Tel: (520) 746-1111 • Twx: 910-952-1111
Internet: http://www.burr-brown.com/ • FAXLine: (800) 548-6133 (US/Canada Only) • Cable: BBRCORP • Telex: 066-6491 • FAX: (520) 889-1510 • Immediate Product Info: (800) 548-6132
®
©
1988 Burr-Brown Corporation
PDS-838F
1
PWS750
Printed in U.S.A. April, 1997
SPECIFICATIONS
ELECTRICAL
At TA = 25°C; +V IN = +15V; and IOUT = ±15mA balanced loads, unless otherwise noted.
PARAMETER
CONDITIONS
MIN
TYP
MAX
UNITS
TTLIN = 0V
725
1
10
4.5
800
875
2.5
18
5.5
50
7
0.7
0.8
15
kHz
MHz
V
V
mApk
V
V
nA
µA
V
V
mA
1.5
Vrms
Vrms
Ω || pF
µArms
1.5
1.8
ns
V
µA
V
1.5
Vrms
Vrms
Ω || pF
µArms
+70
+85
+85
°C
°C
°C
PWS750-1U OSCILLATOR
Frequency: Internal OSC
External OSC
Supply: 15V Operation
5V Operation
T, T Drive Current
T, T Drive Voltage, High
Low
TTLIN, IIH
IIL
VIH
VIL
TTLOUT, IOL
15
5
3
10
–1
2
PWS750-2U +VIN TO ±VOUT ISOLATION TRANSFORMER
ISOLATION
Voltage Rated Continuous AC 60Hz
100% Test (1)
Barrier Impedance
Leakage Current at 60Hz
Winding Ratio
60Hz, 1s, <5pC PD
750
1200
1012 || 8
1
48/48
VISO = 240Vrms
Primary/Secondary
PWS750-3U DIODE BRIDGE
Reverse Recovery
Reverse Breakdown
Reverse Current
Forward Voltage
IF = I R = 50mA
IR = 100µA
VR = 40V
IF = 100mA
40
55
PWS750-4U +5VIN to ±15VOUT ISOLATION TRANSFORMER
ISOLATION
Voltage Rated Continuous AC 60Hz
100% Test (1)
Barrier Impedance
Leakage Current at 60Hz
Winding Ratio
60Hz, 1s, <5pC PD
750
1200
1012 || 8
1
24/70
VISO = 240Vrms
Primary/Secondary
TEMPERATURE RANGE
Specification
Operating
Storage
Derated performance
0
–40
–40
NOTES: (1) Tested at 1.6 x rated, fail on 5pC partial discharge leakage current on five successive pulses at 60Hz.
The information provided herein is believed to be reliable; however, BURR-BROWN assumes no responsibility for inaccuracies or omissions. BURR-BROWN assumes
no responsibility for the use of this information, and all use of such information shall be entirely at the user’s own risk. Prices and specifications are subject to change
without notice. No patent rights or licenses to any of the circuits described herein are implied or granted to any third party. BURR-BROWN does not authorize or warrant
any BURR-BROWN product for use in life support devices and/or systems.
®
PWS750
2
PIN CONFIGURATIONS
ABSOLUTE MAXIMUM RATINGS
PWS750-1U
T
VD
+VIN
PWS750-3U
1
16
2
15
3
14 TTL IN
4
13
5
12 TTLOUT
T
6
11 Gnd
7
10 Enable
8
9
16-Pin SO Double-Wide
Surface Mount
–V
1
8
2
7
AC
3
6 AC
+V
4
5
Supply Voltage ..................................................................................... 18V
Junction Temperature ...................................................................... 150°C
Storage Temperature ........................................................ –40°C to +85°C
Lead temperature (soldering, SOIC, 3s) ........................................ +260°C
Max Load, Sum of Both Outputs (PWS750-2U, 4U) ......................... 60mA
ORDERING INFORMATION
8-Pin SO
Surface Mount
PWS750-XU
Basic Model Number
Components
1U : High-Frequency Driver
2U, 4U : Isolation Transformer
3U : High-Speed Monolithic Diode Bridge
PWS750-2U
PWS750-4U
NC
1
8 NC
AC
2
7 TO
Gnd 3
6 VD
4
5 TO
AC
PACKAGE INFORMATION
PRODUCT
8-Pin DIP
Surface Mount
PWS750-1U
PWS750-2U
PWS750-3U
PWS750-4U
PACKAGE
PACKAGE DRAWING
NUMBER(1)
16-Pin SOIC
8-Pin Plastic
8-Pin SO
8-Pin Plastic
211
226
182
226
NOTE: (1) For detailed drawing and dimension table, please see end of data
sheet, or Appendix C of Burr-Brown IC Data Book.
®
3
PWS750
TYPICAL PERFORMANCE CURVES
TA = +25°C, VIN = 15VDC, ILOAD = ±15mA unless otherwise noted.
PWS750-4U LINE REGULATION
PWR750-2U LINE REGULATION
5.4
18
5.3
16
5.2
Input (V)
Input (V)
5.1
5
4.9
14
12
4.8
4.7
4.6
10
13
14
15
16
17
18
10
12
14
±V OUT (V)
16
18
±V OUT (V)
PWR750-2U AND PWS70-4U LOAD LINES
OUTPUT RIPPLE VOLTAGE
50
Ripple Voltage (mVp-p)
±VOUT (V)
20
PWS750-2U
15
40
Ripple Frequency =
Oscillator Frequency
30
20
10
PWS750-4U
10
0
0
5
10
15
20
25
30
0.1
Load (mA)
0.2
0.4
0.6
0.8
1
Filter Capacitance (µF)
TTL IN SIGNAL DUTY CYCLE
EFFICIENCY/LOAD CURVE
80
100
PWS750-4U
Acceptable
Duty
Cycle
75
% Duty Cycle
Efficiency (%)
70
60
4 Channel
PWS750-1U
50
PWS750-2U
tH
tL
50
DC =
tH
%
t H + tL
25
40
Nominal Operating
Frequency
0
30
0
5
10
15
20
25
30
1
Load Current (±mA)
®
PWS750
1.5
2
Synchronization Frequency (MHz)
(= Twice the FET Drive Frequency)
4
2.5
TYPICAL PERFORMANCE CURVES (CONT)
TA = +25°C, VIN = 15VDC, ILOAD = ±15mA unless otherwise noted.
THE OUTPUT VOLTAGE CAN BE ADJUSTED
±3% BY VARYING THE DRIVER FREQUENCY
15.5
16
15.25
15.5
±VOUT (V)
VOUT (V)
OUTPUT VOLTAGE DRIFT WITH A ±15mA LOAD
15
15
14.5
14.75
14
14.5
–25
0
25
50
75
1
100
1.5
1.6
2
TTLIN Frequency (MHz)
Temperature (°C)
THEORY OF OPERATION
The PWS750 components are basic building blocks to be
used with other standard components to build an isolated
push-pull DC/DC converter. The oscillator runs at 800kHz
nominal, making it possible to reduce the size of the transformer and lower the output ripple voltage.
During overload conditions the output drive shuts off for
approximately 80µs, then turns back on for 20µs, resulting
in a 25% power up duty cycle. If the overload condition still
exists, then the output will shut off again. When the fault or
the excessive load is removed, the converter resumes normal
operation.
PWS750-1U OSCILLATOR PIN FUNCTIONS
The T and T pins are the complementary FET drive outputs
and are tied directly to the corresponding FET gate. The
connection must be as short as possible. For multiple channel operation they cannot be located above any ground or
power planes, because capacitive loading will not allow fast
enough charging of the FET gate.
TTLIN is used to control the driver frequency with an
external TTL level frequency source. The input frequency
must be twice the desired driver frequency, since there is an
internal divide-by-2 circuit to produce a 50% duty cycle
output. The input duty cycle can vary from 12% to 95% (see
Typical Performance Curves). When in the free running
mode, the TTLIN pin must be tied to ground.
PWS750-2U AND PWS750-4U
TRANSFORMER PIN FUNCTIONS
TTLOUT is used when it is desired to synchronize the outputs
of multiple PWS750-1Us to minimize beat frequency problems. A standard open collector output is provided, therefore
a 330Ω to 3.3kΩ pull-up resistor will be necessary depending on stray capacitance on the sync line. A maximum of
eight PWS750-1Us can be connected without the use of an
external TTL buffer.
On the primary side the VD pin of the PWS750-2U is tied
directly to the VD pin of the PWS750-1U. Remember to
place a 0.1µF capacitor as close to the PWS750-2U VD pin
as possible. The TO and TO pins are connected to the drains
of the corresponding FETs, whose sources are connected to
ground. On the secondary side of the transformer, the Gnd
pin is tied directly to the isolated ground. AC pins are
800kHz square wave signals at twice the output voltage, and
are connected directly to the corresponding pin on the
PWS750-3U. Pins 2 and 4 can be interchanged for ease of
hook up. The connection to the diode bridge must be as
direct as possible to minimize radiated noise.
An Enable pin is provided so that the driver (T, T) can be
shut down to minimize power use if required. A TTL low
applied to the pin will shut down the driver within one cycle.
A TTL high will enable the driver within one cycle. The
TTLOUT will still have an 800kHz signal when a master
driver is disabled, so other synchronized drivers will not be
shut down. The pin can be left open for normal operation.
The winding ratio for the PWS750-2U is 1:1. This means
that the output would normally be less than the input due to
voltage drops in the FETs, transformer and diode bridge.
Since the DC/DC converter is operating at 800kHz, the
transformer is starting to operate close to the resonant
frequency, which causes the output to increase in magnitude.
The +VIN pin supplies power to the oscillator. The VD pin
connects the power to the transformer through the internal
overcurrent sense resistor. The other end of the overcurrent
sense resistor is tied to +VIN. A 0.3µF bypass capacitor must
be connected to the VD pin to reduce the ripple current
through the shunt resistor; otherwise false current limit
conditions can occur due to ripple voltage peaks.
®
5
PWS750
+VIN
FIGURE 1. Sample PC Board Layout, 4:1.
®
PWS750
6
MULTIPLE CHANNEL OPERATION
The oscillator can drive up to four-channels (eight FETs)
directly when operating at 10-18V. A 10Ω resistor must be
placed in series with T and T to stabilize the FET gate
charging. For more than four-channel operation, or 5Vmultiple-channel operation, the driver circuit needs a FET
booster circuit, as shown in Figure 2. Large gate drive surge
currents (>100mA) are needed to turn on the gates.
PWS750-3U HIGH SPEED
DIODE BRIDGE PIN FUNCTIONS
The AC pins are tied directly to the AC pins of the PWS7502U. The +V and –V pins are rectified output voltages. The
filter capacitors must be located as close as possible to these
pins to minimize series inductance and therefore noise.
Bypass capacitors will be needed at each device in the
circuit.
If the total output current drawn by all the channels exceeds
250mA, then it will be necessary to circumvent the current
limit circuit by leaving the VD pin of the PWS750-1U open,
and connect the VD pin of the PWS750-2U directly to the
supply.
BASIC OPERATION
SINGLE CHANNEL OPERATION,
PC BOARD LAYOUT CONSIDERATIONS
A simple two-layer board can be used on single channel
applications to create a DC/DC converter with low radiated
noise. A ground plane should be located directly under both
the input and the output components for optimum ground
return paths. The surface mount components make it easy to
design with a ground plane. The output filter capacitors
should be located as close to the PWS750-3U as possible. A
sample layout is shown in Figure 1.
5V OPERATION
With 5V operation, the transformer winding current ratio is
3:1, therefore generating much greater currents in the primary. The input ripple voltage will be larger, so an input pi
filter will be necessary to isolate the converter noise from the
rest of the circuit. For example, when the output is ±15mA
the input current will be at least 120mA.
For multiple channel applications, T and T traces must have
minimum capacitive loading. Therefore, there should be no
ground plane (or power plane) under these two traces. The
driver signal is a 4-6V low current 800kHz signal, which
will generate little radiated noise if the traces are kept short.
MOSFET
MAX DRIVE CURRENT
PACKAGE
BREAKDOWN
4A
115mA
500mA
1.3A
1.2A
TO-92
SO-T23
TO-92
TO-237
4-Pin DIP
40V
60V
60V
60V
60V
TN0604
2N7002
2N7008
2N7010
2N7012
TABLE I. MOSFET Selector Guide.
3
+V
+V IN
VD
7
16
T
Input
Gnd
D
G
S
PWS750-1U
56Ω
1
11
0.3µF
2N7002
14
12
TTLOUT TTLIN
10
2N7002
T
G
D
S
EN
56Ω
10µH
2N7002 D
User Option
G
5
2
3
S
2N7002 D
G
+VO
0.3µF
PWS750-2U
0.3µF
4
PWS750-3U
6
3
7
4
0.3µF
6
1
–VO
Output
Gnd
S
Duplicate for Up to 8 Channels
FIGURE 2. MOSFET Driver Booster Circuits.
®
7
PWS750
OUTPUT CURRENT RATING
The PWS750-1U oscillator contains soft start circuitry to
protect the FETs from high inrush currents during turn on.
The internal input current limit is 250mA peak to prevent
thermal overload of the MOSFETs. The maximum output
rating is ±30mA. Total current, which can be drawn from
each isolation channel, is the total of the power being drawn
from both the +V and –V outputs. For example, if one output
is not used, then maximum current can be drawn from the
other output. In all cases the maximum current that can be
drawn from any individual channel is:
When multiple channel operation is used, the maximum
current of all channels must be reduced to prevent the
overcurrent limit to trip. Alternately, bypass the overcurrent
by leaving the VD pin of the PWS750-1U open and connecting the VD pin of the PWS750-2U directly to the supply.
HIGH VOLTAGE TESTING
Burr-Brown Corporation has adopted a partial discharge test
criterion that conforms to the German VDE0884 optocoupler standard. This method requires that less than 5pC partial
discharge crosses the isolation barrier with 1200Vrms 60Hz
applied. This criterion confirms transient overvoltage (1.5 x
750Vrms) protection without damage to the PWS750-2U or
PWS750-4U. Life test results verify the absence of high
voltage breakdown under continuous rated voltage and maximum temperature.
|+IOUT| + |–IOUT| < 60mA
It should be noted that many analog circuit functions do not
simultaneously draw equal current from both the positive
and negative supplies.
PWS750-1U
11
+VIN
7
14
0.33µF
16 1 3
ISO122P
ISO122P
16
16
+VIN
8
8
15
7
VOUT
15
7
VOUT
9
10
10µH
9
2
1
2
1
1µF
4
1
3
+VIN
10
PWS750-2U
2
7
PWS750-2U
7
2
3
6
6
3
4
5
5
4
1 4
3
PWS750-3U
PWS750-3U
6
6
2N7008, 8ea.
4
1
3
PWS750-2U
2
7
PWS750-2U
7
2
3
6
6
3
4
5
5
4
1 4
3
PWS750-3U
PWS750-3U
6
4
6
1 4
1
1µF
1
1
2
2
9
+VIN
15
10 7
10
VOUT
VOUT
8
9
15
7
8
16
16
ISO122P
ISO122P
FIGURE 3. Four-Channels of ±10V Signal Isolation with Channel-to-Channel Isolation.
®
PWS750
8
+VIN
The minimum AC barrier voltage that initiates partial discharge above 5pC is defined as the “inception voltage.”
Decreasing the barrier voltage to a lower level is required
before partial discharge ceases; this is known as “extinction
voltage.” We have developed a package insulation system to
yield an inception voltage greater than 1200Vrms so that
transient voltages below this level will not damage the
isolation barrier. The extinction voltage is above 750Vrms
so that even overvoltage-induced partial discharge will cease
once the barrier voltage is reduced to the rated value.
Previous high voltage test methods relied on applying a
large enough overvoltage (above rating) to break down
marginal units, but not so high as to permanently damage
good ones. Our partial discharge testing gives us more
confidence in barrier reliability than breakdown/no breakdown criteria.
10µH
TNO604
D
+VIN
PWS750-4U
1
7
5V
PWS750-1U
TNO604
D
0.3µF
3
16
VD 11
4
6
3
7
2
3
PWS750-3U
6
S
T
0.3µF
5
S
T
TN0604 PWS750-4U
D
4
5
S
14
Input
Gnd
TN0604
D
6
3
7
2
1 4
0.3µF
0.3µF
PWS750-3U
6
S
0.3µF
Power for
output
circuitry
Power for
input signal
conditioning
circuitry
3
1
4
16
0.3µF
10
V OUT
7
2
1
9
8
V IN ±10V
15
±10V
ISO122P
FIGURE 4. A Complete ±10V Signal Acquisition System Operating From a Single 5V Supply.
H7F
TO7-14-3.5
1µF
180mA
3 Turns
–VO
TNO604
+5V
7
1
VD
PWS750-1U
16
14
4
1
15
30
32
D
–
T
G
S
PWS726
3
11
0.3µF
19
14
Gnd
TTL In
+VO
47pF
FIGURE 5. A PWS750 Driver Can Be Used to Boost the Input Voltage to 15V to Power a PWS726 From a 5V Supply.
®
9
PWS750
Power for input signal
conditioning circuits
–V +V
2
1
3
4
11
10
VOUT ±10V
22
ISO103
V IN ±10V
12
16
24
14
21
0.3µF
10µH
+VIN
0.3µF
TN0604 PWS750-4U
D
5
4
G
S
1
7
5V
PWS750-1U
VD
3
16
11
4
6
3
7
2
6
1
TN0604 PWS750-4U
D
5
4
S
3
4
TN0604
D
G
S
0.3µF
3
+VO
PWS750-3U
–VO
0.3µF
14
Input
Gnd
G
TN0604
D
G
S
0.3µF
6
3
7
2
PWS750-3U
6
1
FIGURE 6. Powering the Internally Powered ISO103 Isolation Buffer From a Single 5V Supply. Two Power Channels Are
Necessary to Provide the 80mA Nominal for the +V of the ISO103.
10µH
1
7
+VIN
T
PWS750-1U
3
VD 11
16
PWS740-2
2N7008 D
G
S
0.3µF
2N7008 D
G
S
4
3
5
2
6
1
3
6
+VO
0.3µF
PWS750-3U
1
–VO
0.3µF
14
Input
Gnd
Output
Gnd
FIGURE 7. 1500VAC Isolation Using PWS740-2 Transformer.
®
PWS750
4
10
2N7010
+VIN
S
PWS750-1U
VD
3
T
11
1
D
G
T
16
7
2N7010
G
D
S
14
0.3µF
Duplicate for up to 8 Channels
PWS750-2U
Input
Gnd
10µH
5
3
4
4
+VO
0.3µF
6
3
7
2
PWS750-3U
0.3µF
6
1
–VO
Output
Gnd
FIGURE 8. FET Pair Driving Up to Eight-Channels.
23
10 11
9
VOUT1
VIN1
ISO120
16
23
10 11
VOUT2
12
21
15
4
V–
–VS1
VIN2
ISO120
16
12
21
15
4
22
Ext
3 Osc
+VS1
24
V+
9
V–
22
Ext
3 Osc
+VS2
24
V+
0.3µF 0.3µF
0.3µF 0.3µF
20pF
Gnd1
VIN
1
V–
PWS740-3
PWS750-3
20kΩ
20kΩ
AC
AC
AC
6
3
6
GND
AC
PWS745-2
PWS740-2
PWS750-2
TO
T
8
PWS740-3
PWS750-3
AC
V+
5
4
V+
3
AC
4
20pF
4
V+
Gnd2
1
V–
VD
TO
AC
GND
AC
TO
VD
TO
PWS745-2
PWS740-2
PWS750-2
2, 3
5V
0.3µF
6, 7
PWS745-1
T
TTLIN
11
12
13
16
1
Up to 6
more
channels
20µH
14, 15
10µF
0.3µF
0.3µF
FIGURE 9. Synchronized-Multichannel Isolation System.
®
11
PWS750