PHILIPS BY8114 Very fast high-voltage soft-recovery controlled avalanche rectifier Datasheet

DISCRETE SEMICONDUCTORS
DATA SHEET
handbook, 2 columns
M3D117
BY8100 series
Very fast high-voltage soft-recovery
controlled avalanche rectifiers
Product specification
Supersedes data of October 1994
1996 May 24
Philips Semiconductors
Product specification
Very fast high-voltage soft-recovery
controlled avalanche rectifiers
BY8100 series
FEATURES
DESCRIPTION
• Glass passivated
Rugged glass package, using a high
temperature alloyed construction.
• High maximum operating
temperature
This package is hermetically sealed
and fatigue free as coefficients of
• Low leakage current
expansion of all used parts are
matched.
The package is designed to be used
in an insulating medium such as
resin, oil or SF6 gas.
• Excellent stability
• Guaranteed avalanche energy
absorption capability
• Soft-recovery switching
characteristics
• Compact construction.
a
k
handbook, halfpage
APPLICATIONS
MAM163
• For colour television and monitors
up to 128 kHz
• High-voltage applications for:
– Multipliers
– Layer-wound diode-splittransformers where controlled
avalanche is required.
Fig.1 Simplified outline (SOD61) and symbol.
MARKING
Cathode band colour codes
TYPE NUMBER
PACKAGE CODE
INNER BAND
OUTER BAND
BY8104
SOD61AC
orange
black
BY8106
SOD61AD
orange
green
BY8108
SOD61AE
orange
red
BY8110
SOD61AF
orange
violet
BY8112
SOD61AH
orange
orange
BY8114
SOD61AI
orange
lilac
BY8116
SOD61AJ
orange
grey
1996 May 24
2
Philips Semiconductors
Product specification
Very fast high-voltage soft-recovery
controlled avalanche rectifiers
BY8100 series
LIMITING VALUES
In accordance with the Absolute Maximum Rating System (IEC 134).
SYMBOL
PARAMETER
VRRM
VRW
CONDITIONS
MAX.
UNIT
repetitive peak reverse voltage
BY8104
−
5
kV
BY8106
−
8
kV
BY8108
−
10
kV
BY8110
−
12
kV
BY8112
−
14
kV
BY8114
−
17
kV
BY8116
−
19
kV
−
4
kV
working reverse voltage
BY8104
IF(AV)
MIN.
BY8106
−
6
kV
BY8108
−
8
kV
BY8110
−
10
kV
BY8112
−
12
kV
BY8114
−
14
kV
BY8116
−
16
kV
−
20
mA
−
10
mA
average forward current
BY8104
BY8106
averaged over any
20 ms period;
see Figs 2 to 8
BY8108
−
5
mA
BY8110
−
5
mA
BY8112
−
5
mA
BY8114
−
5
mA
BY8116
−
3
mA
−
500
mA
IFRM
repetitive peak forward current
PRSM
non-repetitive peak reverse power dissipation t = 20 µs half sinewave;
Tj = Tj max prior to surge
BY8104
note 1
−
1.7
kW
BY8106
−
2.5
kW
BY8108
−
3.0
kW
BY8110
−
3.8
kW
BY8112
−
5.0
kW
BY8114
−
5.5
kW
6.5
kW
−
BY8116
Tstg
storage temperature
−65
+120
°C
Tj
junction temperature
−65
+120
°C
Note
1. Withstands peak currents during flash-over in a picture tube.
1996 May 24
3
Philips Semiconductors
Product specification
Very fast high-voltage soft-recovery
controlled avalanche rectifiers
BY8100 series
ELECTRICAL CHARACTERISTICS
Tj = 25 °C; unless otherwise specified.
SYMBOL
VF
PARAMETER
forward voltage
CONDITIONS
IF = 100 mA; Tj = Tj max;
see Figs 9 to 15
MIN.
TYP.
MAX.
UNIT
−
−
26
V
BY8106
−
−
36
V
BY8108
−
−
44.5
V
BY8104
BY8110
−
−
54.5
V
BY8112
−
−
75
V
BY8114
−
−
82.5
V
−
−
94
V
IR
reverse current
VR = VRWmax; Tj = 120 °C
−
−
3
µA
Qr
recovery charge
when switched from IF = 100 mA to
VR ≥ 100 V and dIF/dt = −200 mA/µs;
see Fig.16
−
−
0.4
nC
tf
fall time
when switched from IF = 100 mA to
VR ≥ 100 V and dIF/dt = −200 mA/µs;
see Fig.16
40
−
−
ns
trr
reverse recovery time
when switched from IF = 2 mA to
IR = 4 mA; measured at IR = 1 mA;
see Fig.17
−
−
60
ns
Cd
diode capacitance
VR = 0 V; f = 1 MHz
BY8104
−
0.90
−
pF
BY8106
−
0.65
−
pF
BY8108
−
0.55
−
pF
BY8110
−
0.45
−
pF
BY8112
−
0.35
−
pF
BY8114
−
0.30
−
pF
BY8116
−
0.25
−
pF
BY8116
1996 May 24
4
Philips Semiconductors
Product specification
Very fast high-voltage soft-recovery
controlled avalanche rectifiers
BY8100 series
GRAPHICAL DATA
MLB915
20
I F(AV)
(mA)
handbook, halfpage
I F(AV)
(mA)
a = 1.57
a = 1.57
16
8
12
6
8
MLB917
10
handbook, halfpage
4
a = 6.32
4
a = 6.32
2
0
0
100
0
T amb ( oC)
200
100
0
T amb ( oC)
BY8104.
a = IF(RMS)/IF(AV); VR = VRWmax; Rth j-a ≤ 120 K/W.
a = 1.57: half sinewave.
a = 6.32: line output transformer application; see Fig.18.
BY8106.
a = IF(RMS)/IF(AV); VR = VRWmax; Rth j-a ≤ 120 K/W.
a = 1.57: half sinewave.
a = 6.32: line output transformer application; see Fig.18.
Fig.2
Fig.3
Maximum permissible average forward
current as a function of ambient temperature.
MLB919
5
Maximum permissible average forward
current as a function of ambient temperature.
MLB921
5
handbook, halfpage
handbook, halfpage
I F(AV)
(mA)
200
a = 6.32
I F(AV)
(mA)
a = 1.57
a = 6.32
4
4
3
3
2
2
1
1
0
a = 1.57
0
0
100
T amb ( oC)
200
0
100
T amb ( oC)
BY8108.
a = IF(RMS)/IF(AV); VR = VRWmax; Rth j-a ≤ 120 K/W.
BY8110.
a = IF(RMS)/IF(AV); VR = VRWmax; Rth j-a ≤ 120 K/W.
a = 1.57: half sinewave.
a = 6.32: line output transformer application; see Fig.18.
a = 1.57: half sinewave.
a = 6.32: line output transformer application; see Fig.18.
Fig.4
Fig.5
Maximum permissible average forward
current as a function of ambient temperature.
1996 May 24
5
200
Maximum permissible average forward
current as a function of ambient temperature.
Philips Semiconductors
Product specification
Very fast high-voltage soft-recovery
controlled avalanche rectifiers
BY8100 series
MLB923
5
I F(AV)
(mA)
MLB925
5
handbook, halfpage
handbook, halfpage
a = 6.32
I F(AV)
(mA)
a = 1.57
a = 6.32
4
4
3
3
2
2
1
1
a = 1.57
0
0
100
0
T amb ( oC)
100
0
200
T amb ( oC)
BY8112.
a = IF(RMS)/IF(AV); VR = VRWmax; Rth j-a ≤ 120 K/W.
a = 1.57: half sinewave.
a = 6.32: line output transformer application; see Fig.18.
BY8114.
a = IF(RMS)/IF(AV); VR = VRWmax; Rth j-a ≤ 120 K/W.
a = 1.57: half sinewave.
a = 6.32: line output transformer application; see Fig.18.
Fig.6
Fig.7
Maximum permissible average forward
current as a function of ambient temperature.
MLB927
5
Maximum permissible average forward
current as a function of ambient temperature.
MLB914
200
IF
handbook, halfpage
handbook, halfpage
I F(AV)
(mA)
4
(mA)
160
3
120
a = 6.32
a = 1.57
2
80
1
40
0
0
0
100
T amb ( oC)
0
200
BY8116.
a = IF(RMS)/IF(AV); VR = VRWmax; Rth j-a ≤ 120 K/W.
Maximum permissible average forward
current as a function of ambient temperature.
1996 May 24
10
20
30
40
50
60
V F (V)
BY8104.
Dotted line: Tj = 120 °C.
Solid line: Tj = 25 °C.
a = 1.57: half sinewave.
a = 6.32: line output transformer application; see Fig.18.
Fig.8
200
Fig.9
6
Forward current as a function of maximum
forward voltage.
Philips Semiconductors
Product specification
Very fast high-voltage soft-recovery
controlled avalanche rectifiers
BY8100 series
MLB918
200
MLB916
200
handbook, halfpage
IF
handbook, halfpage
IF
(mA)
160
(mA)
160
120
120
80
80
40
40
0
0
20
0
0
40
60
V F (V)
20
40
80
BY8106.
Dotted line: Tj = 120 °C.
Solid line: Tj = 25 °C.
60
80
100
V F (V)
BY8108.
Dotted line: Tj = 120 °C.
Solid line: Tj = 25 °C.
Fig.10 Forward current as a function of maximum
forward voltage.
Fig.11 Forward current as a function of maximum
forward voltage.
MLB920
200
MLB922
200
handbook, halfpage
handbook, halfpage
IF
(mA)
160
IF
(mA)
160
120
120
80
80
40
40
0
0
0
40
80
120
160
200
V F (V)
0
BY8110.
Dotted line: Tj = 120 °C.
Solid line: Tj = 25 °C.
80
120
160
200
V F (V)
BY8112.
Dotted line: Tj = 120 °C.
Solid line: Tj = 25 °C.
Fig.12 Forward current as a function of maximum
forward voltage.
1996 May 24
40
Fig.13 Forward current as a function of maximum
forward voltage.
7
Philips Semiconductors
Product specification
Very fast high-voltage soft-recovery
controlled avalanche rectifiers
BY8100 series
MLB924
200
MLB926
200
handbook, halfpage
handbook, halfpage
IF
(mA)
160
IF
(mA)
160
120
120
80
80
40
40
0
0
40
0
80
120
160
200
V F (V)
0
BY8114.
Dotted line: Tj = 120 °C.
Solid line: Tj = 25 °C.
120
160
200
V F (V)
Fig.15 Forward current as a function of maximum
forward voltage.
handbook,
halfpage
I
F
dI F
dt
10% t
Qr
90%
tf
MRC129 - 1
Fig.16 Reverse recovery definitions.
1996 May 24
80
BY8116.
Dotted line: Tj = 120 °C.
Solid line: Tj = 25 °C.
Fig.14 Forward current as a function of maximum
forward voltage.
IR
40
8
Philips Semiconductors
Product specification
Very fast high-voltage soft-recovery
controlled avalanche rectifiers
handbook, full pagewidth
BY8100 series
MBH420
IF
(mA)
2
0.1 µF
trr
2 mA
50 Ω
0
t
1
IR
(mA)
4
Rise time oscilloscope: tr < 7 ns.
Generator pulse width: 1.0 µs.
Fig.17 Test circuit and reverse recovery time waveform and definition.
APPLICATION INFORMATION
VR
handbook, full pagewidth
DUT
VI
V
R
Io
Vo
VRW
T
nom
Fig.18 Typical operation circuit and voltage waveform.
1996 May 24
9
VRRM
t
MAM105 - 1
Philips Semiconductors
Product specification
Very fast high-voltage soft-recovery
controlled avalanche rectifiers
BY8100 series
PACKAGE OUTLINE
5 max
handbook, full pagewidth
k
a
0.6
3
max
2.5
max
L
G
L
MBC899 - 1
Dimensions in mm.
Fig.19 SOD61.
SOD61 package specification
TYPE
NUMBER
PACKAGE
CODE
Lmin
(mm)
BY8104
SOD61AC
30.4
8.3
BY8106
SOD61AD
30.2
8.7
BY8108
SOD61AE
30.0
9.1
BY8110
SOD61AF
29.8
9.5
BY8112
SOD61AH
29.3
10.5
BY8114
SOD61AI
28.8
11.5
BY8116
SOD61AJ
28.3
12.5
Gmax
(mm)
DEFINITIONS
Data Sheet Status
Objective specification
This data sheet contains target or goal specifications for product development.
Preliminary specification
This data sheet contains preliminary data; supplementary data may be published later.
Product specification
This data sheet contains final product specifications.
Limiting values
Limiting values given are in accordance with the Absolute Maximum Rating System (IEC 134). Stress above one or
more of the limiting values may cause permanent damage to the device. These are stress ratings only and operation
of the device at these or at any other conditions above those given in the Characteristics sections of the specification
is not implied. Exposure to limiting values for extended periods may affect device reliability.
Application information
Where application information is given, it is advisory and does not form part of the specification.
LIFE SUPPORT APPLICATIONS
These products are not designed for use in life support appliances, devices, or systems where malfunction of these
products can reasonably be expected to result in personal injury. Philips customers using or selling these products for
use in such applications do so at their own risk and agree to fully indemnify Philips for any damages resulting from such
improper use or sale.
1996 May 24
10
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