Amphenol CL-40 Ntc inrush current limiter Datasheet

NTC Inrush
Current Limiter
Thermometrics
Thermistors
Features
• UL Approval (UL 1434 File# E82830)
• Small physical size offers design-in benefits
over larger passive components
• Low cost, solid state device for inrush current
suppression
• Best-in-class capacitance ratings
• Low steady resistance and accompanying
power loss
Applications
• Excellent mechanical strength
Control of the inrush current in switching power
supplies, fluorescent lamp, inverters, motors, etc.
• Wide operating temperature range: -58°F to
347°F (-50°C to 175°C)
• Suitable for PCB mounting
• Available with kinked or straight leads and tape
and reel to EIS RS-468A for automatic insertion
Amphenol
Advanced Sensors
Inrush Current Limiters In Switching Power
Supplies
In the circuit above the maximum current at turn-on is the
peak line voltage divided by the value of R; for 120 V, it is
approximately 120 x √2/RI. Ideally, during turn-on RI should
be very large, and after the supply is operating, should be
reduced to zero. The NTC thermistor is ideally suited for this
application. It limits surge current by functioning as a power
resistor which drops from a high cold resistance to a low
hot resistance when heated by the current flowing through
it. Some of the factors to consider when designing NTC
thermistor as an inrush current limiter are:
• Maximum permissible surge current at turn-on
• Matching the thermistor to the size of the filter
capacitors
• Maximum value of steady state current
• Maximum ambient temperature
• Expected life of the power supply
Maximum Surge Current
The main purpose of limiting inrush current is to prevent
components in series with the input to the DC/DC convertor
from being damaged. Typically, inrush protection prevents
nuisance blowing of fuses or breakers as well as welding of
switch contacts. Since most thermistor materials are very
nearly ohmic at any given temperature, the minimum no-load
resistance of the thermistor is calculated by dividing the peak
input voltage by the maximum permissible surge current in
the power supply (Vpeak/Imax surge).
Energy Surge at Turn-On
At the moment the circuit is energized, the filter caps in a
switcher appear like a short circuit which, in a relatively
short period of time, will store an amount of energy equal
to 1/2CV2. All of the charge that the filter capacitors store
must flow through the thermistor. The net effect of this large
current surge is to increase the temperature of the thermistor
very rapidly during the period the capacitors are charging.
The amount of energy generated in the thermistor during
this capacitor-charging period is dependent on the voltage
waveform of the source charging the capacitors. However,
a good approximation for the energy generated by the
thermistor during this period is 1/2CV2 (energy stored in the
filter capacitor). The ability of the NTC thermistor to handle
this energy surge is largely a function of the mass of the
device. This logic can be seen in the energy balance equation
for a thermistor being self-heated:
~
DC/DC
Converter
The problem of current surges in switch-mode power supplies
is caused by the large filter capacitors used to smooth the
ripple in the rectified 60 Hz current prior to being chopped
at a high frequency. The diagram above illustrates a circuit
commonly used in switching power supplies.
Typical Power Supply Circuit
Input Energy = Energy Stored + Energy Dissipated
or in differential form:
Pdt = HdT + δ(T – TA)dt
where:
P = Power generated in the NTC
t = Time
H = Heat capacity of the thermistor
T = Temperature of the thermistor body
δ = Dissipation constant
TA = Ambient temperature
During the short time that the capacitors are charging
(usually less than 0.1 second), very little energy is
dissipated. Most of the input energy is stored as heat in
the thermistor body. In the table of standard inrush
limiters there is listed a recommended value of maximum
capacitance at 120 V and 240 V. This rating is not
intended to define the absolute capabilities of the
thermistors; instead, it is an experimentally determined
value beyond which there may be some reduction in the
life of the inrush current limiter.
Maximum Steady-State Current
The maximum steady-state current rating of a thermistor
is mainly determined by the acceptable life of the final
products for which the thermistor becomes a
component. In the steady-state condition, the energy
balance in the differential equation already given reduces
to the following heat balance formula:
Power = I2R = δ(T – TA)
As more current flows through the device, its
steady-state operating temperature will increase and its
resistance will decrease. The maximum current rating
correlates to a maximum allowable temperature.
In the table of standard inrush current limiters is a list of
values for resistance under load for each unit, as well as
a recommended maximum steady-state current. These
ratings are based upon standard PC board heat sinking,
with no air flow, at an ambient temperature of 77° (25°C).
However, most power supplies have some air flow, which
further enhances the safety margin that is already built
into the maximum current rating. To derate the
maximum steady state current for operation at elevated
ambient temperatures, use the following equation:
Iderated = √(1.1425–0.0057 x TA) x Imax @ 77°F (25°C)
Type CL Specifications
NTC discs for inrush current limiting
Description
Disc thermistor with uninsulated lead-wires.
Options
Data
• For kinked leads, add suffix “A”
• For tape and reel, add suffix “B”
• Other tolerances in the range 0.7 Ω to 120 Ω
• Other tolerances, tolerances at other temperatures
• Alternative lead lengths, lead materials, insulations
CxMax **
(μ Farads)
*maximum rating at 77°F (25ºC) or Iderated = √(1.1425–0.0057 x TA) x
Imax @ 77°F (25°C) for ambient temperatures other than 77°F (25ºC).
**maximum ratings
***R0=X1Y where X and Y are found in the table below
Equation Constants for resistance
under load ***
Resistance
@ 25°C (Ω)
±25%
*Max.
Steady
State
Current
(Amps
RMS)
CL-11
0.7
12
0.77
(19.56)
0.22
(5.59)
2700
675
19.44
0.5
CL-21
1.3
8
0.55
(13.97
0.21
(5.33)
800
200
5.76
CL-30
2.5
8
0.77
(19.56)
0.22
(5.59)
6000
1500
CL-40
5
6
0.77
(19.56)
0.22
(5.59)
5200
CL-50
7
5
0.77
(19.56)
0.26
(6.60)
CL-60
10
5
0.77
(19.56)
CL-70
16
4
CL-80
47
CL-90
Max.
Disc
Dia.
in
(mm)
Max.
Disc
Thick.
in
(mm)
Approximate Resistance Load at %
Maximum Rated
Max .
Current
Flow
@ 25°C
and 240
V Rms
(Amps)
100%
Dissip.
Constant
(mW/°C)
Time
Constant
(sec.)
0.04
0.03
25
100
457
0.11
0.06
0.04
15
60
246
0.34
0.14
0.09
0.06
25
100
128
1.5<1<6
0.65
0.27
0.16
0.11
25
100
64
-1.27
1.5<1<5
0.96
0.40
0.24
0.17
25
120
46
1.45
-1.3
1.2<1<5
1.08
0.44
0.26
0.18
25
100
32
36.00
1.55
-1.26
1<1<4
1.55
0.65
0.39
0.27
25
100
20
1250
36.00
2.03
-1.29
0.5<1<3
2.94
1.20
0.71
0.49
25
100
7
5000
1250
36.00
3.04
-1.36
0.5<1<2
7.80
3.04
1.75
1.18
30
120
3
0.22
(5.59)
4000
1000
28.80
0.44
-1.12
4<1<16
0.09
0.04
0.03
0.02
30
120
640
0.40
(10.16)
0.17
(4.32)
600
150
4.32
0.83
-1.29
0.7<1<3.2
1.11
0.45
0.27
0.19
8
30
32
1.7
0.40
(10.16)
0.17
(4.32)
600
150
4.32
0.61
-1.09
0.4<1<1.7
1.55
0.73
0.47
0.34
4
90
32
50
1.6
0.45
(11.43)
0.17
(4.32)
600
150
4.32
1.45
-1.38
0.4<1<1.6
5.13
1.97
1.13
0.76
8
30
6
CL-140
50
1.1
0.45
(11.43)
0.17
(4.32)
600
150
4.32
1.01
-1.28
0.2<1<1.1
5.27
2.17
1.29
0.89
4
90
6
CL-150
5
4.7
0.55
(13.97)
0.18
(4.57)
1600
400
11.52
0.81
-1.26
1<1<4.7
0.66
0.28
0.17
0.12
15
110
64
CL-160
5
2.8
0.55
(13.97)
0.18
(4.57)
1600
400
11.52
0.6
-1.05
0.8<1<2.8
0.87
0.42
0.28
0.20
9
130
64
CL-170
16
2.7
0.55
(13.97)
0.18
(4.57)
1600
400
11.52
1.18
-1.28
0.5<1<2.7
1.95
0.80
0.48
0.33
15
110
20
CL-180
16
1.7
0.55
(13.97)
0.18
(4.57)
1600
400
11.52
0.92
-1.18
0.4<1<1.7
2.53
1.11
0.69
0.49
9
130
20
CL-190
25
2.4
0.55
(13.97)
0.18
(4.57)
800
200
5.76
1.33
-1.34
0.5<1<2.4
2.64
1.04
0.61
0.41
15
110
13
CL-200
25
1.7
0.55
(13.97)
0.18
(4.57)
800
200
5.76
0.95
-1.24
0.4<1<1.7
2.74
1.16
0.70
0.49
9
130
13
CL-210
30
1.5
0.40
(10.16)
0.2
(5.08)
600
150
4.32
1.02
-1.35
0.3<1<1.5
3.83
1.50
0.87
0.59
8
30
11
@120
(VAC
Rms)
@240
(VAC
Rms)
Max.
Energy
(Joules)
Current Range
Min I Max I
25%
50%
75%
-1.18
4<1<12
0.14
0.06
0.6
-1.25
3<1<8
0.25
43.20
0.81
-1.25
2.5<1<8
1300
37.44
1.09
-1.27
5000
1250
36.00
1.28
0.22
(5.59)
5000
1250
36.00
0.77
(19.56)
0.22
(5.59)
5000
1250
3
0.77
(19.56)
0.22
(5.59)
5000
120
2
0.93
(23.62)
0.22
(5.59)
CL-101
0.5
16
0.93
(23.62)
CL-110
10
3.2
CL-120
10
CL-130
Type
X
Y
Selection Criteria for Thermometrics CL-Products
1.
I max - Thermometrics CLs are rated for maximum steady state current. The maximum steady current is mainly determined
by the acceptable life of the final products for which the thermistor becomes a component. The differential equation Pdt
= HdT + δ(T – TA)dt reduces to Power = I2R = δ(T – TA). An example in the case of a 100 watt power supply with an efficiency
rating of 80%, 100% load is calculated to be 125 watts. The maximum input current is calculated from the minimum
supply voltage. For a standard 120V supply, this could be rated as low at 110V. Therefore, input current would be
calculated by 125 watts/110 V = 1.14 Amps. Selection of the CL should have an I max rating of at least 1.14 Amps.
2.
The second step of selection of the CL is to understand the desired maximum inrush current allowable. This is generally
specificed by the components in line of the CL, such as the diode bridge. In the case of the diode bridge rated at 200 Amps,
one would should select a CL that would limit max surge current to 50% of the rating, therefore limit surge to a maximum
of 100 Amps. The listed maximum current flow is rated at 25°C, so derating is required if the ambient temperture is greater
than 25°C.
3.
The next selection of criteria for the CL is to understand the bulk Capacitance of the device to be protected. On power, the
bulk capacitance of the device appears as a short to the system. The designer needs to understand the bulk capacitance
at the RMS voltage rating of the system. Assuming the input capacitance is approximately 500 μFds, the selection of the
CL needs to be able to absorb input energy.
Using the above criteria, the selection of the CL provides multiple solutions. One would opt for the smallest size CL to achieve
the required protection. The selection criteria is as follows:
1. I max >1.14 Amps
2. Max allowable Inrush current 100 Amps
3. Bulk Capacitance listed as 500 μfd
4. Choose smallest physical size that will allow protection for the device.
Criteria indicates that either the CL-150 or CL-160 would be suitable for the application. In the case of the CL-150 less heat is
dissipated allowing the operating resistance to drop but at a higher temperature. This increases efficiency of the system but
may lead to shorter component life.
Amphenol
Advanced Sensors
www.amphenol-sensors.com
© 2014 Amphenol Corporation. All Rights Reserved. Specifications are subject to change without notice.
Other company names and product names used in this document are the registered trademarks or
trademarks of their respective owners.
AAS-920-325D-03/2014
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