STMICROELECTRONICS CLP30

CLP30-200B1
ASD (Application Specific Devices)
Overvoltage and overcurrent protection for telecom line
Features
■
■
■
■
Dual bidirectional protection device
High peak pulse current:
– IPP = 40 A (5/310 µs surge)
– IPP = 30 A (10/1000 µs surge)
Max. voltage at switching-on: 290 V
Min. current at switching-off: 150 mA
SO-8
Description
The CLP30-200B1 is designed to protect
telecommunication equipment. It provides both a
transient overvoltage protection and an
overcurrent protection.
The external components (balanced resistors,
ring relays contact, ...) needed by the CLP30200B1 protection concept require very low power
rating. This results in a very cost effective
protection solution.
Order code
Part Number
Marking
CLP30-200B1RL
CLP30
Figure 1.
CLP30-200B1 schematic diagram
TIPL
Main applications
Any telecom equipment submitted to transient
overvoltages and lightning strikes such as :
■ Analog and ISDN line cards
■ PABX
1
TIPS
GND
GND
GND
GND
RINGL
RINGS
Benefits
■
■
■
■
Voltage and current controlled suppression
Surface Mounting with SO-8 package
Very low power rating of external components
on line card: balanced resistors, ring relay, low
voltage SLIC protection
TRISILs™ are not subject to ageing and
provide a fail safe mode in short circuit for a
better level of protection. Trisils are used to
ensure equipment meets various standards
such as UL60950, IEC950 / CSA C22.2,
UL1459 and FCC part 68. Trisils have UL94 V0
approved resin (Trisils are UL497B approved
[file: E136224]).
TM: TRISIL is a trademark of STMicroelectronics
August 2006
Rev 1
1/15
www.st.com
15
CLP30-200B1
Figure 2.
Block diagram
TIPL
TIPS
Overcurrent
detector
Overvoltage
detector
OR
Overvoltage
reference
(> 200 V)
SW1
GND
SW2
Overvoltage
detector
OR
Overvoltage
reference
(> 200 V)
Overcurrent
detector
RINGL
2/15
RINGS
Pin
Symbol
Description
1
TIPL
TIP (line side)
2/3/6/7
GND
Groung
4
RINGL
RING (line side)
5
RINGS
RING ( SLIC side)
8
TIPS
TIP (SLIC side
CLP30-200B1
1
Characteristics
Characteristics
Table 1.
Standards compliance
Peak
surge
voltage
(V)
Voltage
waveform
Required
peak
current
(A)
Current
waveform
Minimum serial
resistor to meet
standard (Ω)
GR-1089 Core First level
2500
1000
2/10 µs
10/1000 µs
500
100
2/10 µs
10/1000 µs
12
24
GR-1089 Core
Second level
5000
2/10 µs
500
2/10 µs
24
GR-1089 Core
Intra-building
1500
2/10 µs
100
2/10 µs
0
ITU-T-K20/K21
6000
1500
10/700 µs
150
37.5
5/310 µs
110
0
ITU-T-K20 (IEC 61000-4-2)
8000
15000
1/60 ns
VDE0433
4000
2000
10/700 µs
100
50
5/310 µs
60
10
VDE0878
4000
2000
1.2/50 µs
100
50
1/20 µs
0
0
IEC61000-4-5
4000
4000
10/700 µs
1.2/50 µs
100
100
5/310 µs
8/20 µs
60
0
FCC Part 68,
lightning surge type A
1500
800
10/160 µs
10/560 µs
200
100
10/160 µs
10/560 µs
22.5
15
FCC Part 68,
lightning surge type B
1000
9/720 µs
25
5/320 µs
0
Standard
Table 2.
0
0
Thermal resistance
Symbol
Rth(j-a)
ESD contact discharge
ESD air discharge
Paramete
Junction to ambient
Value
Unit
170
° C/W
3/15
Characteristics
CLP30-200B1
Table 3.
Absolute maximum ratings (RSENSE = 3 Ω, Tamb = 25° C)
Symbol
IPP
Parameter
Non repetitive surge peak on-state current
F = 50 Hz
Tstg
Tj
Storage temperature range
Maximum junction temperature
Table 4.
Symbol
Unit
30
40
A
Line to GND peak pulse current
– 10/1000 µs (open circuit voltage wave shape 10/1000 µs)
– 5/310 µs (open circuit voltage wave shape 10/700 µs)
ITSM
TL
Value
tp = 10 ms
tp = 200 ms
tp = 1 s
8.5
4.5
3.5
A
-40 to
+150
150
°C
260
°C
Lead temperature for soldering during 10 s.
Electrical characteristics (RSENSE = 3 Ω, Tamb = 25° C)
Parameter
Test condtions
Min
VLG = 200 V
Measured between TIP
(or RING) and GND
Max
Unit
10
µA
ILGL
Line to GND leakage current
VLG
Line to GND operating voltage
200
V
VSWON
Line to GND voltage at SW1 or Measured at 50 Hz between TIPL
SW2 switching-on
(or RINGL) and GND,one cycle
290
V
ISWOFF
Line to GND negative current
at SW1 or SW2 switching-off
Refer to test circuit fig 9
150
ISWON
Line current at SW1 or SW2
switching-on
Positive surge
Negative surge
220
280
Line to GND capacitance
VLG = 0 V
VOSC = 200 mVRMS F = 1MHz
C
Figure 3.
mA
320
380
mA
100
pF
Test circuit for ISWOFF parameter: GO-NO GO test
TIPL or RINGL
R
-VP
D.U.T
VBAT = -48 V
GND
Surge generator
This is a GO-NO GO test which allows to confirm the holding current (IH) level in a functional test circuit.
TEST PROCEDURE:
- Adjust the current level at the IH value by short circuiting the D.U.T.
- Fire the D.U.T. with a surge current: IPP = 10A, 10/1000 µs
- The D.U.T. will come back to the off-state within a duration of 50 ms max.
4/15
CLP30-200B1
Figure 4.
Characteristics
Figure 5.
Typical variation of switching-on
current (positive or negative)
versus RSENSE resistor and
junction temperature (see test
condition figure 6)
Variation of switching-on current
versus RSENSE at 25° C
ISWON @ 25° C (mA)
ISWON (mA)
500
600
500
ISWON @ 0° C
ISWON @ 25° C
ISWON min
negative
ISWON @ 70° C
400
ISWON max
negative
ISWON min
positive
ISWON max
positive
300
300
200
200
100
RSENSE ( Ω )
100
2
3
4
RSENSE ( Ω )
5
6
7
8
9
10
3
Figure 7.
Figure 6.
ISWON MEASUREMENT:
– ISWON = l1 when the CLP30-200B1 switches
on (l1 is progressively increased using R)
– Both TIP and RING sides of the CLP30200B1 are checked
– RL = 10 Ω
RSENSE
1.4
I1
RL
5
7
9
11
Relative variation of switching-off
current versus junction
temperature (for RSENSE between 3
and 10 Ω)
ISWOFF [Tj° C] / ISWOFF [25° C]
1.2
±48 V
TIPL
TIPS
DUT
GND
1
R
0.8
0.6
Temperature (° C)
RINGL RINGS
0.4
0
20
40
60
80
5/15
Characteristics
Figure 8.
CLP30-200B1
Relative variation of switching-off
current versus RSENSE (between 3
and 10 Ω)
ISWOFF [RSENSE] / ISWOFF [4 Ω]
Figure 9.
Relative variation of switching-on
voltage versus dV/dt with an
external resistor of 3 Ω
VSWON / VREF
1.6
1.12
1.4
1.10
1.08
1.2
1.06
1.0
1.04
0.8
1.02
0.6
RSENSE ( Ω )
1.00
0.98
0.1
0.4
6
4
8
10
Figure 10. Relative variation of internal
reference voltage versus junction
temperature (ILG =1 mA)
dV/dt (V/µs)
0.3
1
3
10
30
100
300
1000
Figure 11. Capacitance (TIP/GND) versus
applied voltage (typical values)
C (pF)
70
VREF [Tj° C] / VREF [25° C]
1.10
50
1.05
1.00
30
0.95
20
0.90
Tj (° C)
0.85
-40
-20
0
20
40
VR (V)
60
10
Figure 12. Surge peak current versus overload
duration (maximum values)
ITSM (A)
10
8
6
4
2
t (S)
0
0.01
6/15
0.1
1
10
100
1000
1
2
3
5
10
20
30
50
100
CLP30-200B1
Technical information
2
Technical information
2.1
Introduction
The aim of this section is to show the behavior of our new telecom line protection device.
Figure 13. Suscriber line protection topology
"PRIMARY PROTECTION"
Telecommunication
"SECONDARY PROTECTION"
CLP30200B1
line
MDF
VOLTAGE
REFERENCE
SLIC
LINE CARD
EXCHANGE
Figure 13. is a simplified block diagram of a subscriber line protection that is mainly used so
far. This shows two different things:
■
A “primary protection” located on the Main Distribution Frame (MDF) eliminates coarsely
the high energy environmental disturbances (lightning transients and AC power mains
disturbances) for which the ITU-T-K20 requires a 4 kV 10/700 µs test. This can be
assumed either by gas-tubes or silicon protection such as the TLPxxM.
■
A “secondary protection” located on the line card eliminates finely the remaining
transients that have not been totally suppressed by the first stage. The ITU-T-K20
requires a 1 kV 10/700 µs test. At this stage, the protection is managed by the CLP30200B1.
The explanations which follow are basically covering the line card application.
2.2
STMicroelectronics CLP30-200B1 concept
2.2.1
Evolution of the SLIC protection
Over the years, the performances of the SLICs considerably increased and therefore the
need of the protection has also evolved.
The CLP30-200B1 is especially designed for the protection of this new generation of SLIC.
For this, it is based on both overvoltage and overcurrent protection modes.
7/15
Technical information
CLP30-200B1
Figure 14. Line card protection
I
Programmable thanks to
any external voltage reference
Programmable thanks to
an external resistor
+ ISWON
- VSWON
V
+ VSWON
- ISWON
Line Card operating conditions
Figure 14. summarises the performance of the CLP30-200B1 which basically holds the
SLIC inside its correct voltage and current values.
2.2.2
Application circuit
Figure 15. CLP30-200B1 in line card
PTC
I
TIP
RSENSE
RS
- VBAT
1
TIPS
TIPL
Rp
Overcurrent
detector
2
OR
Overvoltage
detector
Overvoltage
reference
(> 200 V)
OR
Overvoltage
detector
Overvoltage
reference
(> 200 V)
SW1
TIP
- VBAT
External
voltage
reference
SLIC
1
GND
SW2
Rp
RING
2
Overcurrent
detector
RINGL
RINGS
Ring
Generator
PTC
RSENSE
RING
RS
The Figure 15. above shows the topology of a protected analog subscriber line at the line
card side.
■
8/15
A first stage based on CLP30-200B1 manages the high power issued from the external
surges. When used in ringing mode, the CLP30-200B1 operates in voltage mode and
provides a symmetrical and bidirectional overvoltage protection above 200 V on both TIP
and RING lines. When used in speech mode, the CLP30-200B1 operates in current mode
and the activation current of the CLP30-200B1 is adjusted by RSENSE.
CLP30-200B1
■
2.2.3
Technical information
A second stage which is the external voltage reference device defines the firing threshold
voltage during the speech mode and also assumes a residual power overvoltage
suppression. This stage can be either a fixed or programmable device such as
LCP1511D.
Ringing mode
Figure 16. Switching by voltage during ringing mode
ILG
A1
ILG
TIP
RSENSE
TIPS
TIPL
1
2
1/2 CLP200M
Overcurrent
detector
1
- 200
VLG
2
+ 200
1
OR
SW1
Overvoltage
detector
Overvoltage
reference
(> 200 V)
VLG
3
GND
In ringing mode (ring relay in position 2), the only protection device involved is the CLP30200B1.
In normal conditions, the CLP30-200B1 operates in region 1 of A1 curve, and is idle.
If an overvoltage occurring between TIP (or RING) and GND reaches the internal
overvoltage reference (+/- 200 V), the CLP30-200B1 acts and the line is short-circuited to
GND. At this time the operating point moves to region 2 for positive surges (region 3 for
negative surges). Once the surge current disappears, the device returns to its initial state
(region 1).
For surges occurring between TIP and RING, the CLP30-200B1 acts in the same way. This
means that the CLP30-200B1 ensures a tripolar protection.
When used alone, the CLP30-200B1 acts at the internal overvoltage reference level
(+/- 200V). Furthermore, it is possible to adjust this threshold level to a lower voltage by
using up to 4 fixed external voltage reference (VZ1 to VZ4) (see Figure 17.).
9/15
Technical information
CLP30-200B1
Figure 17. Method to adjust the reference voltage
1
TIP
RSENSE
2
TIPS
TIPL
VZ1
Overcurrent
detector
VZ2
OR
Overvoltage
detector
Overvoltage
reference
(> 200 V)
OR
Overvoltage
detector
Overvoltage
reference
(> 200 V)
SW1
GND
GND
SW2
VZ3
Overcurrent
detector
RINGL
VZ4
RINGS
1
RSENSE
RING
2
2.2.4
Speech mode
Figure 18. Switching by current during speech mode
ILG
TIP
ILG
RSENSE
TIPS
TIPL
1
Overcurrent
detector
2
OR
SW1
Overvoltage
detector
Overvoltage
reference
(> 200 V)
Rp
- VBAT
6
External
voltage
reference
- VBAT
4
VLG
VLG
5
GND
In speech mode (ring relay in position 1), the protection is provided by the combination of
both CLP30-200B1 and the external voltage reference device (for example LCP1511D).
In normal conditions, the working point of this circuit is located in region 4 of A2 curve: the
CLP30-200B1 is idle.
When a surge occurs on the line, the external voltage reference device clamps at GND or VBAT respectively for positive and negative surges. This generates a current which is
detected by RSENSE and causes the protection to act: the line is short-circuited to GND. The
operating point moves to region 6 for positive surges or region 5 for negative surges.
10/15
CLP30-200B1
Technical information
Once the surge current falls below the switching-off current ISWOFF, the CLP30-200B1
returns to its initial state (region 4).
Furthermore, the CLP30-200B1 switches when an overvoltage, either positive or negative,
occurs either:
■
simultaneously on both TIP and RING lines versus GND
■
between TIP and RING
■
on TIP (or RING) versus GND
The choice of the switching-on current is function of the RSENSE resistors.
Figure 19. Switching-on current versus
RSENSE: relative variation of ISWON
versus RSENSE at various
temperature
Figure 20. Switching-on current versus
RSENSE: relative variation of ISWON
versus RSENSE at Tamb = 25° C
ISWON @ 25° C (mA)
ISWON (mA)
500
600
500
ISWON @ 0° C
ISWON @ 25° C
ISWON min
negative
ISWON @ 70° C
400
ISWON max
negative
ISWON min
positive
ISWON max
positive
300
300
200
200
100
RSENSE ( Ω )
100
2
3
4
5
RSENSE ( Ω )
6
7
8
9
10
3
5
7
9
11
This current (typically above 150 mA) should not activate the protection device CLP30200B1.
Therefore the level of activation is to be chosen just below this limit (typically 200 mA). This
level is adjusted through RSENSE.
Figures 7a and 7b enable the designers to choose the right RSENSE value.
Example
The choice of RSENSE = 3 Ω ensures a negative triggering of -280 mA min and -380 mA
maximum.
In this case, the positive triggering will be 220 mA min and 320 mA max.
Thanks to the CLP30-200B1 topology, the surge current in the line is reduced after it.
Because the remaining surge energy is low, the power ratings of RP, the relay contacts and
the external voltage reference device may be kept low.
This results in a significant cost reduction for the whole system.
11/15
Ordering information scheme
3
CLP30-200B1
Ordering information scheme
CLP
Current Limiting Protection
Peak Pulse Current
30 = 30 A
Minimum operating voltage
200 = 200 V
Package
B1 = SO-8
Packing
RL = Tape and reel
12/15
30
-
200
B1
RL
CLP30-200B1
4
Package information
Package information
Table 5.
SO-8 dimensions
Dimensions
Ref.
Millimeters
Min.
Typ.
A
C
(Seating
Plane)
ccc C
A2
0.25mm
(Gage Plane)
C
k
D
5
E1
1
4
Min.
Typ.
1.75
Max.
0.069
h x 45°
L1
8
Max.
A1
0.1
A2
1.25
0.25
0.004
0.010
0.049
L
A1
e
b
A
Inches
E
b
0.28
0.48
0.011
0.019
C
0.17
0.23
0.007
0.009
D
4.80
4.90
5.00
0.189 0.193 0.197
E
5.80
6.00
6.20
0.228 0.236 0.244
E1
3.80
3.90
4.00
0.150 0.154 0.157
e
1.27
0.050
h
0.25
0.50
0.010
0.020
L
0.40
1.27
0.016
0.050
8
0
L1
k°
ccc
1.04
0
0.041
0.10
8
0.004
Figure 21. SO-8 footprint (dimensions in mm)
13/15
Ordering information
5
6
14/15
CLP30-200B1
Ordering information
Part Number
Marking
Package
Weight
Base qty
Delivery mode
CLP30-200B1RL
CLP30
SO-8
0.11 g
2500
Tape and reel
Revision history
Date
Revision
28-Aug-2006
1
Description of Changes
First issue.
CLP30-200B1
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15/15