VIPER100SP13TR STMicroelectronics, VIPER100SP13TR Datasheet

IC SWIT PWM SMPS CM POWERSO10

VIPER100SP13TR

Manufacturer Part Number
VIPER100SP13TR
Description
IC SWIT PWM SMPS CM POWERSO10
Manufacturer
STMicroelectronics
Series
VIPER™r
Datasheet

Specifications of VIPER100SP13TR

Output Isolation
Isolated
Frequency Range
90 ~ 200kHz
Voltage - Input
8 ~ 15 V
Voltage - Output
620V
Power (watts)
82W
Operating Temperature
25°C ~ 125°C
Package / Case
PowerSO-10 Exposed Bottom Pad
Number Of Outputs
1
Output Voltage
620 V
Output Current
3000 mA
Mounting Style
SMD/SMT
Switching Frequency
90 KHz to 110 KHz
Fall Time
100 ns
Rise Time
50 ns
Synchronous Pin
No
Lead Free Status / RoHS Status
Contains lead / RoHS non-compliant
Other names
497-3284-2
Table 1.
Figure 1.
June 2005
VIPer100A/ASP
ADJUSTABLE SWITCHING FREQUENCY UP
TO 200 kHz
CURRENT MODE CONTROL
SOFT START AND SHUTDOWN CONTROL
AUTOMATIC BURST MODE OPERATION IN
STAND-BY CONDITION ABLE TO MEET
“BLUE ANGEL” NORM (<1w TOTAL POWER
CONSUMPTION)
INTERNALLY TRIMMED ZENER
REFERENCE
UNDERVOLTAGE LOCK-OUT WITH
HYSTERESIS
INTEGRATED START-UP SUPPLY
OVER-TEMPERATURE PROTECTION
LOW STAND-BY CURRENT
ADJUSTABLE CURRENT LIMITATION
VIPer100/SP
Type
General Features
Block Diagram
V
DD
V
620V
700V
13 V
DSS
_
+
AMPLIFIER
ERROR
3 A
3 A
0.5 V
I
n
LOGIC
UVLO
ON/OFF
4.5 V
+
_
R
OVERTEMP.
2.5
2.8
DETECTOR
SECURITY
R/S
DS(on)
LATCH
DELAY
1.7 μ s
FF
S
Ω
Ω
Q
LATCH
PWM
OSCILLATOR
R1
R2 R3
COMP
OSC
FF
S
Figure 2.
DESCRIPTION
VIPer100™/100A, made using VIPower M0
Technology, combines on the same silicon chip a
state-of-the-art PWM circuit together with an
optimized, high voltage, Vertical Power MOSFET
(620V or 700V / 3A).
Typical applications cover offline power supplies
with a secondary power capability of 50 W in wide
range condition and 100W in single range or with
doubler configuration. It is compatible from both
primary or secondary regulation loop despite
using around 50% less components when
compared with a discrete solution. Burst mode
operation is an additional feature of this device,
offering the ability to operate in stand-by mode
without extra components.
Q
BLANKING
250 ns
PENTAWATT HV
Package
+
_
0.5V
+
SMPS PRIMARY I.C.
AMPLIFIER
_
CURRENT
VIPer100A/ASP
1 V/A
SOURCE
DRAIN
VIPer100/SP
PENTAWATT HV (022Y)
www.st.com
Rev 2
1/24
24

Related parts for VIPER100SP13TR

VIPER100SP13TR Summary of contents

Page 1

Table 1. General Features V Type DSS VIPer100/SP 620V VIPer100A/ASP 700V ADJUSTABLE SWITCHING FREQUENCY UP TO 200 kHz CURRENT MODE CONTROL SOFT START AND SHUTDOWN CONTROL AUTOMATIC BURST MODE OPERATION IN STAND-BY CONDITION ABLE TO MEET “BLUE ANGEL” NORM (<1w ...

Page 2

Table 2. Absolute Maximum Rating Symbol Continuous Drain-Source Voltage ( 125°C) V for VIPer100/SP DS for VIPer100A/ASP I Maximum Current D V Supply Voltage DD V Voltage Range Input OSC V Voltage Range Inpu COMP I Maximum ...

Page 3

VIPer100/SP - VIPer100A/ASP Table 5. Ordering Numbers PENTAWATT HV VIPer100 VIPer100A Pins Functional Description Drain Pin (Integrated Power MOSFET Drain): Integrated Power MOSFET drain pin. It provides internal bias current during start-up via an integrated high voltage current source which ...

Page 4

Table 6. Avalance Characteristics Symbol Avalanche Current, Repetitive or Not Repetitive (pulse width limited by TJ max; δ < 1%) I D(AR) for VIPer100/SP (see Figure 15) for VIPer100A/ASP (*) (see Figure 15) Single Pulse Avalanche Energy E (AR) (starting ...

Page 5

VIPer100/SP - VIPer100A/ASP Table 8. Supply Section Symbol Parameter I Start-Up Charging Current DDch I Operating Supply Current DD0 I DD1 Operating Supply Current V Undervoltage Shutdown DDoff V Undervoltage Reset DDon V Hysteresis Start-up DDhyst Table 9. Oscillator Section ...

Page 6

Table 11. PWM Comparator Section Symbol Parameter ΔV / Δ COMP DPEAK V V Offset COMPoff COMP I Peak Current Limitation Dpeak Current Sense Delay to Turn Off t Blanking Time b t Minimum On Time ...

Page 7

VIPer100/SP - VIPer100A/ASP Figure 4. V Regulation Point Slope = A/V COM COM PLO V DDreg Figure 6. Transition Time I D 10% Ipeak V DS 90% ...

Page 8

Figure 10. Start-Up Waveforms Figure 11. Over-temperature Protection T tsd 8/ yst off VIPer100/SP - VIPer100A/ASP ...

Page 9

VIPer100/SP - VIPer100A/ASP Figure 12. Oscillator VDD Rt OSC 22nF 15nF 1,000 Ct = 1.5 nF 500 300 Ct = 4.7 nF 200 100 CLK FC00050 Forbidden area Ct(nF) = Forbidden area 40kHz Oscillator ...

Page 10

Figure 13. Error Amplifier frequency Response 60 RCOMP = +∞ RCOMP = 270k 40 RCOMP = 82k RCOMP = 27k RCOMP = 12k 20 0 (20) 0.001 Figure 14. Error Amplifier Phase Response 200 150 100 50 0 (50) 0.001 ...

Page 11

VIPer100/SP - VIPer100A/ASP Figure 15. Avalanche Test Circuit 1 OSC 13V C1 U1 BT2 VIPer100 47uF 12V 16V 1mH 2 3 VDD DRAIN - + COMP SOURCE 100 STHV102FI in parallel ...

Page 12

Figure 16. Offline Power Supply With Auxiliary Supply Feedback F1 TR2 Figure 17. Offline Power Supply With Optocoupler Feedback F1 TR2 12/24 BR1 ...

Page 13

VIPer100/SP - VIPer100A/ASP Operation Description: Current Mode Topology: The current mode control method, like the one integrated in the VIPer100/100A, uses two control loops - an inner current control loop and an outer loop for voltage control. When the Power ...

Page 14

High Voltage Start-up Current Suorce An integrated high voltage current source provides a bias current from the DRAIN pin during the start-up phase. This current is partially absorbed by internal control circuits which are placed into a standby mode with ...

Page 15

VIPer100/SP - VIPer100A/ASP Figure 18. Behaviour of the high voltage current source at start-up VDD VDDon VDDoff VDD VDD Ref. UNDERVOLTAGE Auxiliary primary LOCK OUT LOGIC winding VIPer100 Start up ...

Page 16

Transconductance Error Amplifier The VIPer100/100A includes a transconductance error amplifier. Transconductance Gm is the change in output current (I ) versus change in input voltage (V COMP The output impedance Z COMP This last equation shows that the open loop ...

Page 17

VIPer100/SP - VIPer100A/ASP Over-Temperature Protection Over-temperature protection is based on chip temperature sensing. The minimum junction temperature at which over-temperature cut-out occurs is 140ºC, while the typical value is 170ºC. The device is automatically restarted when the junction temperature decreases ...

Page 18

Figure 25. Input Voltage Surges Protection C2 C1 Bulk capacitor 22nF Electrical Over Stress Ruggedness The VIPer may be submitted to electrical over-stress, caused by violent input voltage surges or lightning. Following the Layout Considerations is sufficient to prevent catastrophic ...

Page 19

VIPer100/SP - VIPer100A/ASP Figure 26. Recommended Layout R1 C1 From input diodes bridge C2 Layout Considerations Some simple rules insure a correct running of switching power supplies. They may be classified into two categories: - Minimizing power loops: The switched ...

Page 20

Dim Min. A 4.30 C 1.17 D 2.40 E 0.35 F 0.60 G1 4.91 G2 7. 10.05 L 15.60 L1 14.60 L2 21.20 L3 22.20 L5 2.60 L6 15. 2.50 M1 4.50 R ...

Page 21

VIPer100/SP - VIPer100A/ASP Pentawatt HV 022Y ( Vertical High Pitch ) Mechanical Data Dim Min. A 4.30 C 1.17 D 2.40 E 0.35 F 0.60 G1 4.91 G2 7. 10.05 L 16.42 L1 14.60 L3 20.52 ...

Page 22

Figure 27. Pentawatt HV Tube Shipment ( no suffix ) 22/24 VIPer100/SP - VIPer100A/ASP Base Q.ty 50 1000 Bulk Q.ty Tube length ( ± 0.5 ) 532 33 ± 0 All dimensions are ...

Page 23

VIPer100/SP - VIPer100A/ASP Table 13. Revision history Date Revision 02-May-2005 08-JUn-2005 1 Initial release. 2 Update without PowerSO-10 Changes TM 23/24 ...

Page 24

... No license is granted by implication or otherwise under any patent or patent rights of STMicroelectronics. Specifications mentioned in this publication are subject to change without notice. This publication supersedes and replaces all information previously supplied. STMicroelectronics products are not authorized for use as critical components in life support devices or systems without express written approval of STMicroelectronics ...

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