F A S T H IG H
T h
g e
p o
d e
d e
tra
d v
b e
e s e M O S F E T
n e r a l h ig h v o lta
w e r e le c tr o n ic s
fle c tio n - a n d a c
s c r ib e d h e r e a r
n s itio n tim e , h ig
/d t im m u n ity a g a
u s e d in a ll h a r d
V O L T A G E
T R A N S IS T O R
s w itc h in g m o d u le s h a v e b e e n d e s ig n e d fo r
g e s w itc h in g a p p lic a tio n s s u c h a s in d u s tr ia l
, H V
te s t in s tr u m e n ts , p u ls e g e n e r a to r s ,
c le r a tio n g r id d r iv e r s . T h e s w itc h in g m o d u le s
e d is tin g u is h e d a b o v e a ll b y th e ir v e r y s h o r t
h s w itc h in g fr e q u e n c y a n d e x tr a o r d in a r y h ig h
in s t H V tr a n s ie n ts . T h e s w itc h e s c a n th e r e fo r e
s w itc h in g a p p lic a tio n s w ith o u t lim ita tio n s .
H T S
H T S
H T S
S W IT C H E S
1 6 1 -0 6
2 2 1 -0 6
3 3 1 -0 6
1 6 k V / 6 0 A
2 2 k V / 6 0 A
3 3 k V / 6 0 A
M O S F E T
T h e s w itc h in g m o d u le s in c o r p o r a te a ll fe a tu r e s o f th e w e ll k n o w n
H T S s w itc h fa m ily : E a s y h a n d lin g , h ig h r e lia b ility , lo w jitte r a n d
r e p r o d u c ib le s w itc h in g b e h a v io u r .
T h
a m
c o
v a
T h e m o d
o p e ra te d
fo r H V
s u ffic ie n t
d e ta ile d
in s tr u c tio
u le s c a n b e in
u n d e r a ir c o n d
c o n n e c tio n ) is
c r e e p a g e d is ta
d e s ig n r e c o m m
n s fo r u s e .
s ta
itio
re
n c e
e n
lle
n s
c o
a
d a
d
o n
, th e
m m e
c c o rd
tio n s
a
p r in
u s e o
n d e d ,
in g to
p le a s
te d
f o
in
in d
e
c ir c u it b o
p tio n P T - H
o rd e r to
u s tr ia l s ta n
re fe r to th
a rd ,
V (p
e n s
d a rd
e g
b u t if
ig ta ils
u re a
s . F o r
e n e ra l
B a s ic C ir c u its
+ H V
V C C
T T L
G N D
+ H V
-H V
-H V
+
-
H T S
R
H T S
L
L
-
V a r ia b le O n -T im e
H ig h S w itc h in g F r e q u e n c y
+ H V In p u t
+
S ig n a l In p u t
G ro u n d (L o g
+ 5 .0 0 V D C /
F a u lt S ig n a l
G N D / E a rth
(3 -6 V
ic G N
4 0 0 m
O u tp u
1
)
2
D )
A
t
3
4
5
6
7
O p tio n H F S : + 3 5 0 V D C
8
-
N O T E
P in s 6 ,7 ,8 a r e u s e d in
c o n ju n c tio n w ith o p tio n
H F B o r H F S o n ly .
C 2 = 1 to 1 0 0 µ F / 2 5 V
C 3 = 1 to 1 0 0 µ F / 3 5 0 V
T h e c a p a c ita n c e d e p e n d s
o n th e n u m b e r o f p u ls e s
p e r b u rs t (C ~ 0 .1 µ F x N )
C 1
C 2
1 0 µ
1 )
+
+
R
C 3
R
1 )
S
C
B
L
T h is a r e a fo r p o w e r e le c tr o n ic s o n ly
O (m a x )
= 3 3 k V D C
IP
- H IG H
(m a x )
V O L T A G E
= 6 0 A (p k )
F A S T H IG H V O L T A G E
T R A N S IS T O R S W IT C H
+
1
V
b e h lk e .d e
H T S 3 3 1 -0 6
B E H L K E
+
6 1 4 7 6 K r o n b e r g , G e r m a n y , T e l. + 4 9 ( 0 ) 6 1 7 3 9 2 9 0 - 2 0 , F a x - 3 0 , e m a il in fo @
D A N G E R
I n p u t c o n n e c t io n o v e r lo n g d is ta n c e
r e q u ir e s s h ie ld e d c a b le s w it h t e r m in a tio n !
D O N O T T O U C H M O D U L E
C e n tra l g ro u n d &
e a r th c o n n e c to r
(S ta r-ty p e G N D )
G N D
F o r is o la te d a tta c h m e n t o n ly !
8
+
7 0 °
7
R : = Z o f c a b le , e . g . 1 0 0 O h m
C : 1 0 ...1 0 0 0 µ F / 1 0 V D C
5
6
L
B u rs t o p tio n o n ly :
6
7
8
6 - + 1 5 V = > b u ffe r
+
+
7 - + 2 5 0 V = > b u ffe r
8 - R e tu rn (G N D )
C ~ 0 .1 µ F x n u m b e r o f p u ls e s /b u r s t
R
Q
5
B
H IG H -T E C H IN H IG H V O L T A G E
C
4
B
3
B e h lk e E le c tr o n ic G m b H ,
C
L
2
-
R
B E H L K E
1
B
B e h lk e E le c t r o n ic G m b H , F a x + 4 9 ( 0 ) 6 9 - 7 3 3 1 7 9 . P a t e n t e d - M a d e i n G e r m a n y .
C
H T S
+
K e e p th e w ir in g a s s h o r t a s p o s s ib le a n d a v o id la r g e in d u c tio n lo o p a r e a s o f th e p e a k c u r r e n t
c a r r y in g lin e s ; th e fo r w a r d a n d r e tu r n lin e s s h o u ld b e in s ta lle d a s c lo s e ly a s p o s s ib le to g e th e r .
C o n tr o l a n d p o w e r c ir c u it m u s t n o t b e m ix e d . A lw a y s k e e p th e tr a n s fo r m e r p r in c ip le in m in d !
U s e s h ie ld e d le a d s a t th e c o n tr o l s id e to m in im iz e n o is e in d u c tio n . L o w im p e d a n c e d r iv e r s
w ith 5 V o lt o u tp u t s w in g ( in to 5 0 O h m ) a r e r e q u ir e d fo r d r iv in g lo n g p u ls e tr a n s m is s io n lin e s .
S ig n a l tr a n s m is s io n lin e s m u s t b e te r m in a te d p r o p e r ly ( e .g . b y 5 0 O h m ) . T h e a u x ilia r y p o w e r
s u p p ly m u s t b e w e ll d e c o u p le d b y a s u ffic ie n t b u ffe r c a p a c ito r .
T h is h ig h s p e e d s w it c h in g m o d u le c a n g e n e r a t e e x t r e m e d i/ d t 's a n d d v / d t 's . T h e r f o r e it is n o t
u s e fu l to o p e r a te th e s w itc h a n d its p e r ip h e r ic c o m p o n e n ts w ith o u t a s h ie ld e d h o u s in g . O th e r
e le c tr o n ic s in c lu d in g p o w e r s u p p lie s ( !) m a y b e d is tu r b e d . P le a s e n o te y o u r lo c a l E M C / E M I
r e g u la tio n s . P le a s e a ls o s e e o u r o p tio n o ffe r s fo r p o s s ib le E M C / E M I r e le v a n t m o d ific a tio n s .
In th is a r e a in p u t w ir in g &
c o n tr o l e le c tr o n ic s o n ly
H T S
B
T e k tr o n ix T D S 3 0 5 4
T e s t C ir c u it (H ig h -S id e S w itc h )
1 - C o n tro l In p u t (3 ~ 1 0 V )
2 - G N D ( L o g ic g r o u n d o n ly )
3 - + 5 .0 0 V D C (± 5 % )
4 - F a u lt S ig n a l O u t p u t ( T T L )
5 - G N D ( L o g ic /
/ e a rth )
+
C
- P a te n te d M a d e in G e r m a n y
-H V
Im p o r ta n t E M C D e s ig n H in ts
+ H V
R
w it h o p t io n s
C F , C F -D R ,
H F B & H F S
P ro b e P 6 0 1 5 A
D u e to th e h ig h g a lv a n ic is o la tio n th e s w itc h e s m a y s im p ly b e
o p e r a t e d a ls o in f lo a t in g s e t - u p 's o r in h ig h - s id e c ir c u it s . S e v e r a l
h o u s in g o p tio n s a r e a v a ila b le to m e e t in d iv id u a l c o n s tr u c tio n a l
a n d p o w e r r e q u ir e m e n ts . T h e s ta n d a r d p la s tic h o u s in g is u s e d in
lo w fr e q u e n c y a p p lic a tio n s w ith lo w a v e r a g e p o w e r d is s ip a tio n .
T h e p la s tic m o d u le s c a n a d d itio n a lly b e fitte d w ith n o n - is o la te d
c o o lin g fin s ( a v a ila b le a s o p tio n s C F , C F - X 2 a n d C F - X 3 ) , w h ic h
im p r o v e s t h e m a x . C o n t in u o u s P o w e r D is s ip a t io n P d (m a x ) b y
a p p r o x . fa c to r 1 0 w ith fo r c e d a ir ( > 4 m /s ) o r b y fa c to r 5 0 , if th e
s w itc h in g m o d u le s a r e im m e r s e d in is o la tin g c o o lin g liq u id s ( e .g .
G A L D E N H T 2 0 0 , flo w r a te > 0 .1 m /s , s ta n d a r d c o o lin g fin s ) .
A n o th e r c o o lin g m e th o d is g iv e n b y th e u s e o f th e g r o u n d e d
c o o lin g fla n g e ( o p tio n G C F a n d G C F - X 2 ) . In c o n ju n c tio n w ith a n
o p tio n a l w a te r c o o lin g p la te o r a n y o th e r h ig h p e r fo r m a n c e
h e a ts in k , m a x im u m p o w e r d is s ip a tio n s in th e r a n g e o f 1 to 4 k W
a r e p o s s ib le , w ith c u s to m iz e d c o o lin g fla n g e s e v e n u p to 1 0 k W .
H TS 3 3 1 -0 6
5 0
e s w itc h is tu r n e d o n b y a p o s itiv e g o in g s ig n a l o f 3 to 6 v o lts
p litu d e , p r o v id e d th e a u x ilia r y p o w e r s u p p ly is p e r m a n e n tly
n n e c te d to th e + 5 .0 0 V D C in p u t. T h e o n - tim e m a y s im p ly b e
r ie d b e tw e e n 1 5 0 n s a n d in fin ity b y th e in p u t c o n tr o l p u ls e
w id th . A n
in te r fe r e n c e - p r o o f d r iv e r c ir c u it p r o v id e s s ig n a l
c o n d itio n in g , a u x ilia r y v o lta g e m o n ito r in g , fr e q u e n c y lim ita tio n
a n d te m p e r a tu r e p r o te c tio n . In c a s e o f a n y fa ls e o p e r a tin g
c o n d itio n th e s w itc h e s tu r n o ff im m e d ia te ly a n d a fa u lt s ig n a l is
g e n e r a te d ( T T L le v e l) . T h e h ig h fr e q u e n c y b u r s t o p e r a tio n ( > 1 0
p u ls e s /1 0 0 µ s ) r e q u ir e s th e o p tio n H F B ( c o n n e c tio n o f e x te r n a l
b u ffe r c a p a c ito r s a t th e d r iv e r ) . F o r o p e r a tio n a t h ig h e r
f r e q u e n c ie s t h a n s p e c if ie d u n d e r f (m a x ) t h e o p t io n H F S m u s t b e
u s e d . In th a t c a s e a n in te r n a l D C /D C
c o n v e rte r m u s t b e
s u p p o r te d b y a n e x te r n a l s u p p ly o f + 2 5 0 V D C ( ± 5 % , a p p r o x . 2 1 0 W a tts d e p e n d in g o n s w itc h in g fr e q u e n c y ) .
T E C H N O L O G Y
TECHNICAL DATA
Specification
Symb. Condition / Comment
Maximum Operating Voltage
Minimum Operating Voltage
Typical Breakdown Voltage
Galvanic Isolation
VO(max)
VO(min)
Vbr
VI
Maximum Peak Current
IP(max)
HTS:
Ioff < 60 PADC
Increased tr(on) and tr(off) below 0.1x VO(max)
Ioff > 1mADC, Tcase = 75 °C
Continuously Standard housing / PCB attachment
Option PT-HV, pigtails for HV
Option PT-HV + Option ISO-80 1)
Tcase = 25°C
tp < 100 µs, duty cycle <1%
Tfin = 75°C*
tp < 1 ms, duty cycle <10%
*measured at base tp < 10 ms, duty cycle <10%
161-06
221-06
331-06
Unit
16
22
0
24
25
40
80
33
kVDC
kVDC
kVDC
18
25
40
80
36
40
40
80
kVDC
60
49
36
ADC
0.69
0.77
2.5
2.5
5.2
5.2
ADC
6.6
6.6
Static On-Resistance
Rstat
22
33
55
83
:
Maximum Off-State Current
Ioff
50
PADC
Turn-On Delay Time
td(on)
170
180
200
ns
10
9
Typical Turn-On Rise Time
tr(on)
9
13
12
12
16
15
13
ns
28
24
18
Typical Turn-Off Rise Time
tr(off)
25
ns
Minimum On-Time
ton(min)
200
ns
Maximum On-Time
ton(max)
∞
Switch Recovery Time
trc
500
ns
Typical Turn-On Jitter
tj(on)
1
ns
Max. Switching Frequency
f(max)
6
5
4
max. 50
max. 50
max. 50
kHz
Maximum Burst Frequency
fb(max)
2
MHz
40
33
28
Maximum Continuous Power Pd(max)
540
360
270
Dissipation
2250
1500
1120
Watts
3600
2400
1800
0.8
0.66
0.56
Linear Derating
8.64
7.2
6
36
30
25
W/K
72
60
50
Operating Temperature Range TO
-40...75
°C
Storage Temperature Range TST
-50...90
°C
Natural Capacitance
CN
Capacitance between switch poles at VO(max)
66
50
33
pF
Coupling Capacitance
CC
HV side to
Standard devices
21
30
48
control / GND Opt. GCF, grounded cooling flange
165
222
336
pF
Diode Reverse Recovery Time trrc
IF= 10 A, Tcase = 25°C
MOSFET parasitic diode
500
ns
Diode Forward Voltage Drop VF
IF= 10 A, Tcase = 25°C
MOSFET parasitic diode
28
37
56
VDC
Auxiliary Supply Voltage
Vaux
Stabilized to r 2%, safety turn-off below 4.75 VDC
5.0
VDC
Auxiliary Supply Current
Iaux
@ fmax
600
mADC
Control Signal Voltage
Vtr
> 3VDC recommended
2-6
VDC
Fault Signal Output
TTL, short circuit proof, L=Fault (=safety turn-off)
H= 4 V, L= 0.5 V
VDC
263x70x35
200x70x35
171x70x28
Dimensions
LxWxH Standard plastic case
263x70x19
200x70x19
171x70x19
Option FC, flat case
263x70x70
200x70x70
171x70x70
Option CF, non-isolated cooling fins, standard size
mm3
252x120x45 252x120x45 312x120x45
Option GCF, grounded cooling flange 2)
750
Weight
Standard plastic case
1020
1050
440
Option FC, flat case
590
610
1125
Option CF, non-isolated cooling fins, standard size
1560
1590
2700
g
Option GCF, grounded cooling flange 2)
3420
3450
Notes: 1) Not available in connection with Option GCF. 2) Also available in other sizes for higher or lower Pd(max). Please consult factory.
Maximum Continuous Load
Current
IL
Tcase = 25°C
Tflange =25°C
Tfin = 75°C*
Standard plastic case
Option CF, fins in air >4m/s
Option CF, in Galden“ >0.1m/s
*measured at base Opt. GCF, grounded cooling flange
Tcase = 25°C
0.1 x IP(max)
1.0 x IP(max)
0.8xVO, Tcase=75°C, <5PA leakage optionally available
@ IP(max)
0.1 x VO, 0.1 x IP(max)
0.5 x VO, 0.1 x IP(max)
0.8 x VO, 0.1 x IP(max)
0.8 x VO, 1.0 x IP(max)
0.8 x VO, 0.1x IP(max), resistive load, 10-90%
Lower ton(min) on request
Please note possible Pd(max) limitations
trc = minimum pulse spacing
Vaux / Vtr = 5.0 VDC, fixed switching frequency
Tcase = 25°C
Standard, safety turn-off @1.5x f(max)
Option HFS, please consult factory
Use option HFB for >5 pulses within100 µs
Tcase = 25°C
Standard plastic case incl. option
Tflange =25°C
FC Option CF, fins in air >4m/s
Option CF, in Galden“ >0.1m/s
Tfin = 75°C*
*measured at base Opt. GCF, grounded cooling flange
Tcase = 25°C
Standard plastic case incl. option
Tflange =25°C
FC Option CF, fins in air >4m/s
Option CF, in Galden“ >0.1m/s
Tfin = 75°C*
*measured at base Opt. GCF, grounded cooling flange
Extended range on request, safety turn-off @ 77°C
Ordering Information
HTS 161-06
Transistor switch, 16 kVDC, 60 Amps.
HTS 221-06
Transistor switch, 22 kVDC, 60 Amps.
HTS 331-06
Transistor switch, 33 kVDC, 60 Amps.
Option HFB
High frequency burst
Option HSF
High switching frequency (pls. consult factory)
Option LP
Low pass filter at control input
Option S-TT
Soft transition time for simplified EMC design
Option ISO-80
Option SPT-C
Option PT-HV
Option UL-94
Option FC
Option CF
Option GCF
0.81
2.5
5.2
6.6
17
42
Increased isolation voltage, 80 kVDC isolation
Shielded pigtail for control connection (LEMO miniature plug)
Pigtails for HV connection (instead of bottom screw terminals)
Flame-retardant casting resin according to UL94-V0
Flat plastic case, module height reduced to 19 mm
Non-isolated cooling fins, standard size, 35 mm height
Grounded cooling flange, direct attachment to heat sink
Further data and mechanical drawings are available on request. All data and specifications subject to change without notice.
331-06-TB-10-01