Zener Diode. ZEN164V130A24LS Datasheet

ZEN164V130A24LS Diode. Datasheet pdf. Equivalent

ZEN164V130A24LS Datasheet
Recommendation ZEN164V130A24LS Datasheet
Part ZEN164V130A24LS
Description Polymer Protected Zener Diode
Feature ZEN164V130A24LS; POLYZEN DEVICES Polymer Protected Zener Diode PolyZen devices are polymer-enhanced, precision Zener.
Manufacture Littelfuse
Datasheet
Download ZEN164V130A24LS Datasheet




Littelfuse ZEN164V130A24LS
POLYZEN DEVICES
Polymer Protected Zener Diode
PolyZen devices are polymer-enhanced, precision Zener
diodes. They offer resettable protection against multi-Watt
fault events without the need for multi-Watt heat sinks.
The Zener diode used for voltage clamping a PolyZen
device was selected due to its relatively flat voltage
vs. current response. This helps improve output voltage
clamping, even when input voltage is high and diode
currents are large.
An advanced feature of the PolyZen device is that the
Zener diode is thermally coupled to a resistively non-
linear, PPTC (polymer positive temperature coefficient)
layer. This PPTC layer is fully integrated into the device
and is electrically in series between VIN and the diode
clamped VOUT.
This advanced PPTC layer responds to either extended
diode heating or overcurrent events by transitioning from a low to high resistance state, also known as “tripping.” A
tripped PPTC will limit current and generate voltage drop. It helps to protect both the Zener diode and the follow-on
electronics and effectively increases the diode’s power handling capability.
The polymer-enhanced Zener diode helps protect sensitive portable electronics from damage caused by inductive
voltage spikes, voltage transients, incorrect power supplies and reverse bias. These devices are particularly suitable for
portable electronics and other low-power DC devices.
BENEFITS
• Stable Zener diode helps shield downstream
electronics from overvoltage and reverse bias
• Trip events shut out overvoltage and reverse bias
sources
• Analog nature of trip events helps minimize damage
from upstream inductive spikes
• Minimal power dissipation requirements
• Single component placement
FEATURES
• Overvoltage transient suppression
• Stable VZ vs. fault current
• Time delayed, overvoltage trip
• Time delayed, reverse bias trip
APPLICATIONS
• DC power port protection in portable electronics
• DC power port protection for systems using barrel
jacks for power input
• Internal overvoltage and transient suppression
• DC output voltage regulation
• Tablet PCs and portable electronics
• Multi-Watt power handling capability
• Integrated device construction
• RoHS compliant
• Halogen free
(refers to: Br900ppm, Cl900ppm, Br+Cl1500ppm)
RoHS Compliant, ELV Compliant
Specifications subject to change without notice. ©2016 Littelfuse, Inc.
27



Littelfuse ZEN164V130A24LS
PolyZen Devices
Polymer Protected Zener Diode
Figure PZ1 —Typical Application Block Diagram
Power Supply
(External or Internal)
Protected Electronics
+
VIN
1
PolyZen
Device
2 GND
3 VOUT
Regulated
Output
RLOAD
Protected Downstream
Electronics
Table PZ1 — Electrical Characteristics
(Performance ratings @ 25°C unless otherwise specified)
VZ(V)
Part Number
ZEN056V130A24LS
ZEN059V130A24LS
ZEN065V130A24LS
ZEN098V130A24LS
ZEN132V130A24LS
ZEN164V130A24LS
ZEN056V230A16LS
ZEN065V230A16LS
ZEN098V230A16LS
ZEN132V230A16LS
ZEN056V075A48LS
ZEN132V075A48LS
ZEN056V115A24LS
NEW ZEN056V130A16YM
NEW ZEN056V175A12YM
NEW ZEN132V130A16YM
NEW ZEN132V175A12YM
NEW ZEN056V130A24YC
NEW ZEN056V230A16YC
NEW ZEN056V260A16YC
NEW ZEN132V130A24YC
NEW ZEN132V230A16YC
NEW ZEN132V260A16YC
Min
5.45
5.80
6.35
9.60
13.20
16.10
5.45
6.35
9.60
13.20
5.45
13.20
5.45
5.35
5.35
13.20
13.20
5.35
5.35
5.35
13.20
13.20
13.20
Typ
5.60
5.90
6.50
9.80
13.40
16.40
5.60
6.50
9.80
13.40
5.60
13.40
5.60
5.60
5.60
13.40
13.40
5.60
5.60
5.60
13.40
13.40
13.40
Max
5.75
6.00
6.65
10.00
13.60
16.60
5.75
6.65
10.00
13.60
5.75
13.60
5.75
5.85
5.85
13.80
13.80
5.85
5.85
5.85
13.80
13.80
13.80
VINT MAX
IFLT MAX
IHOLD
Test
Test
IZt
@ 20°C
RTyp
R1MAX
VINT MAX
Current
IFLT MAX
Voltage
(A) (A) (Ω) (Ω) (V) (A) (A) (V)
0.10 1.30 0.12 0.16
24
3 +10/-40 +24/-16
0.10 1.30 0.12 0.15
24
3
+6/-40 +24/-16
0.10 1.30 0.12 0.16
24
3
+6/-40 +24/-16
0.10 1.30 0.12 0.16
24
3 +3.5/-40 +24/-16
0.10 1.30 0.12 0.16
24
3
+2/-40 +24/-16
0.10 1.30 0.12 0.16
24
3 +1.25/-40 +24/-16
0.10 2.30 0.04 0.06
16
5
+5/-40 +16/-12
0.10 2.30 0.04 0.06
16
5 +3.5/-40 +16/-12
0.10 2.30 0.04 0.06
16
5 +3.5/-40 +16/-12
0.10 2.30 0.04 0.06
16
5
+2/-40 +20/-12
0.10 0.75 0.28 0.45
48
3 +10/-40 +48/-16
0.10 0.75 0.28 0.45
48
3
+2/-40 +48/-16
0.10 1.15 0.15 0.18
24
3 +10/-40 +24/-16
0.10
1.30
0.110
0.160
14
3
+3/-40 +16/-12
0.10
1.75
0.050
0.095
12
4
+3/-40 +12/-12
0.10
1.30
0.110
0.160
14
3
+1/-40 +20/-12
0.10
1.75
0.050
0.095
12
4
+1/-40 +20/-12
0.10
1.30
0.110
0.170
24
3
+4/-40 +24/-16
0.10
2.30
0.040
0.070
16
5
+3/-40 +16/-12
0.10
2.60
0.040
0.055
16
5
+3/-40 +16/-12
0.10
1.30
0.110
0.170
24
3
+1/-40 +24/-16
0.10
2.30
0.040
0.070
16
5
+1/-40 +20/-12
0.10
2.60
0.040
0.055
16
5
+1/-40 +20/-12
LS module height is 1.7mm typical. YM module height is 1.2mm typical. YC module
Table PZ2 — Definition of Terms
VZ
IZT
IHOLD
RTyp
R1MAX
IFLT
IFLT MAX
VINT MAX
IPTC
IOUT
Trip Event
Zener clamping voltage measured at current IZT and 20°C.
Test current at which VZ is measured.
Maximum steady state current IPTC that will not generate a trip event at the specified temperature.
Ratings assume IFLT = 0A.
Typical resistance between VIN and VOUT pins when the device is at room temperature.
The maximum resistance between VIN and VOUT pins, at room temperature, one hour after first trip or
after reflow soldering.
Current flowing through the Zener diode.
Maximum RMS fault current the Zener diode component of the device can withstand and remain resettable;
testing is conducted at rated voltage with no load connected to VOUT.
The voltage (VIN - VOUT “post trip”) at which typical qualification devices (98% devices, 95% confidence) survived
at least 100 trip cycles and 24 hours trip endurance when “tripped” at the specified voltage and current (IPTC).
Current flowing through the PPTC portion of the circuit.
Current flowing out the VOUT pin of the device.
A condition where the PPTC transitions to a high resistance state, thereby limiting IPTC, and significantly
increasing the voltage drop between VIN and VOUT.
28 Specifications subject to change without notice. ©2016 Littelfuse, Inc.
Polymer PTC
VIN
Zener
Diode
VOUT
GND
IPTC
VIN
IFLT
IOUT
VOUT
GND
RoHS Compliant, ELV Compliant



Littelfuse ZEN164V130A24LS
PolyZen Devices
Polymer Protected Zener Diode
Figures PZ2-PZ9 —Typical Performance Curves for PolyZen Devices - LS Series
Figure PZ2
222.0.0
2222002..00..00
12218008..00..00
11116886..00..00
11114646..00..00
11112424..00..00
11110220..00..00
18108.0.00..00
6868..00..00
4646..00..00
2424..00..00
22.00.00
0000
00
VVVVOOOOUUUUTTTTPPPPeeeeaaaakkkkvvvvssss....IIFFIIFFLLTTLLTTRRRRMMMMSSSS((II((OOIIOOUUUUTTTT====0000))))
AA==ZZEENN005566VV11yyyAA2244LLSS
FF BABA===ZZZEEENNN0005559696VVV1113y3y0y0AAAA22224444LLLLSSSS
FF CBCB===ZZZEEENNN0006565959VVV111333000AAA222444LLLSSS
EE DCDC===ZZZEEENNN00096968585VVV111333000AAA222444LLLSSS
EE EDED===ZZZEEENNN101039392828VVV111333000AAA222444LLLSSS
FEFE===ZZZEEENNN11163634242VVV111333000AAA222444LLLSSS
DD FF==ZZEENN116644VV113300AA2244LLSS
DD
CC
CC
BB
BB
AA
AA
11 22 33 44 55 66 77 88 99 1100
11 22 33 44IIFFIILLFFTTLLTTRRRRMM5MM5SSSS((AA((AA))))66 77 88 99 1100
Figure PZ3
1100
1100
11
11
00.1.1
00.1.1
00.0.011
00.0.01100
00
TTTTiimmiimmeeee--tt--ttoooo--TT--TTrrrriippiippvvvvssss....IIFFIIFFLLTTLLTTRRRRMMMMSSSS((II((OOIIOOUUUUTTTT====0000))))
AA==ZZEENN005566VV11yyyAA2244LLSS
BAAB===ZZZEEENNN0005559669VVV1113yy30y0AAAA22224444LLLLSSSS
CBBC===ZZZEEENNN0006556995VVV111333000AAA222444LLLSSS
DCCD===ZZZEEENNN00096698558VVV111333000AAA222444LLLSSS
EDDE===ZZZEEENNN100139932882VVV111333000AAA222444LLLSSS
FEEF===ZZZEEENNN11163364224VVV111333000AAA222444LLLSSS
FF==ZZEENN116644VV113300AA2244LLSS
FF
FF
EE
EE
DD CC
DD CC
BB
BB
AA
AA
11 22 33 44 55 66 77 88 99 1100
11 22 33 44IIFFIILLFFTTLLTTRRRRMM5MM5SSSS((AA((AA))))66 77 88 99 1100
Figure PZ4
222.0.0
2222002..00..00
12218008..00..00
11116886..00..00
11114646..00..00
11112424..00..00
11110220..00..00
18108.0.00..00
6868..00..00
4646..00..00
2424..00..00
22.00.00
0000
00
11
11
0.00.0
Figure PZ6
-0-.02.2
0.00.0
-0-.04.4
-0-.02.2
-0-.06.6
-0-.04.4
VVVVOOOOUUUUTTTTPPPPeeeeaaaakkkkvvvvssss....IIFFIIFFLLTTLLTTRRRRMMMMSSSS((II((OOIIOOUUUUTTTT====0000))))
AA==ZZEENN005566VV223300AA1166LLSS
BABA===ZZZEEENNN0006565656VVV222333000AAA111666LLLSSS
DD
DD
CBCB===ZZZEEENNN00096968585VVV222333000AAA111666LLLSSS
DCDC===ZZZEEENNN010193938282VVV222333000AAA111666LLLSSS
DD==ZZEENN113322VV223300AA1166LLSS
CC
CC
BB
BB
AA
AA
22 33 44 55 66 77 88 99
22VVOOUUT3T3PPeeaakk44vIIFFvIIsLLFFTsT.LLTT.RIRFRRIMMLF5MMTL5SSTRSSR((MAA((MAA))S))6S6(I(OIOUUT7T7==00) ) 88
99
AA==ZEZENNxxxVxV1y1yAyA242L4SLS
VVOOUUTTPPeeaakkvvss. .IFILFTLTRRMMSS(BI(BOI=OU=ZUTEZT=EN=Nx0x0)xV)xV23203A0A161L6SLS
CC==ZEZENNxxxVxV07057A5A484L8SLS
AA==ZEZNENxxxxxVx1Vy1yyAyA242L4SLS
BB==ZEZNENxxxxxVx2V3203A0A161L6SLS
CC==ZEZNENxxxxxVx0V7057A5A484L8SLS
1100
1100
-0-.08.8
-0-.06.6
-1-.10.0
-0-.08.8
-1-.12.2
-1-.10-.50-050
-1-.12.2
-5-050
AA
BB
A-A4-040
BB
-4-040
CC
-3-030
-2-020
ICFICLFTLTRRMMSS(A(A) )
-3-030
-2-020
-1-010
-1-010
00
00
IFILFTLTRRMMSS(A(A) )
Figure PZ5
11000
11000
1100
1100
TTTTiimmiimmeeee--tt--ttoooo--TT--TTrrrriippiippvvvvssss....IIFFIIFFLLTTLLTTRRRRMMMMSSSS((II((OOIIOOUUUUTTTT====0000))))
AA==ZZEENN005566VV223300AA1166LLSS
BAAB===ZZZEEENNN0006556665VVV222333000AAA111666LLLSSS
CBBC===ZZZEEENNN00096698558VVV222333000AAA111666LLLSSS
DCCD===ZZZEEENNN010193938282VVV222333000AAA111666LLLSSS
DD==ZZEENN113322VV223300AA1166LLSS
11
11
BB
00.1.1
00.1.1
DD CBCB
DD CC
AA
AA
00.0.011
00.0.01100
00
1010 0
Figure PZ7
1011000100
110110
0.011.11
00.00.0.110.11
00.00..000.110011-5-050
0.00.00101
-5-050
11 22 33 44 55 66 77 88 99
11 2T2Timimee-3t-3oto-T-Trirp4i4pIIFFvIILLFFvTTsLLTTs.RRRR.IMMF5MMIL5FSSTLSST(R(AA((RAAM))M))6S6S(I(OIOU7UT7T==00) )88 99
AA==ZEZENNxxxVxV1y1yAyA242L4SLS
TTimimee-t-oto-T-Trirpipvvss. .IFILFTLTRRBMBM=S=ZSEZ(IEN(OINxOUxUTxVTx=V2=320030)A0)A161L6SLS
CC==ZEZENNxxxVxV07057A5A484L8SLS
AA==ZEZNENxxxxxVx1Vy1yyAyA242L4SLS
BB==ZEZNENxxxxxVx2V3203A0A161L6SLS
CC==ZEZNENxxxxxVx0V7057A5A484L8SLS
BB
AA
CBCB
-4-040
AA
CC
-4-040
-3-030
-2-020
IFILFTLTRRMMSS(A(A) )
-3-030
-2-020
IFILFTLTRRMMSS(A(A) )
-1-010
-1-010
1100
1100
00
00
Figure PZ8
TTeemmppeeraratuturereEEfffefeccttoonnIHIHOOLDLD(I(FILFTLT==00) )
Figure PZ9
TTimimee-t-oto-T-Trirpipvvss. .IPITPCTCRRMMSS(I(FILFTLT==00) )
3.35.5
3.30.0
3.35.5
2.25.5
3.30.0
2.20.0
2.25.5
1.15.5
2.20.0
1.10.0
1.15.5
0.05.5
1.10.0
0.00.0
0.05.-54-040
0.00.0
-4-040
AA==ZEZENNxxxVxV13103A0A242L4SLS
TTeemBmBppeeraratuturereEEfffefecct toonnIHIHOBOLBDL=D=(ZI(FEZILEFNTLNxT=xx=0VxV02)32)03A0A161L6SLS
CC==ZEZENNxxxVxV07057A5A484L8SLS
ADAD====ZZEEZZNEENNNxxxxxxxxVVxx1VV13110531AA05AA224422LL44SSLLSS
AA BB
BB==ZEZNENxxxxxVx2V3203A0A161L6SLS
CC==ZEZNENxxxxxVx0V7057A5A484L8SLS
DD==ZEZNENxxxxxVx1V151A5A242L4SLS
DD
ACAC
DD
CC
-2-020 00 2020 4040 6060 8080 10100
AAmmbbieiennt tTeTemmppeeraratuturere(˚(C˚C) )
-2-020 0 0 2020 4040 6060 8080 101000
1010
AA==ZEZENNxxxVxV1y1yAyA242L4SLS
TTimimee-t-oto-T-Trirpipvvss. .IPITPCTCRRMMSBSB(=I(=FZILFEZTLENT=Nx=x0x0)Vx)V23203A0A161L6SLS
10101 CC==ZEZENNxxxVxV07057A5A484L8SLS
AA==ZEZNENxxxxxVx1Vy1yyAyA242L4SLS
BB==ZEZNENxxxxxVx2V3203A0A161L6SLS
0.01.11 CC==ZEZNENxxxxxVx0V7057A5A484L8SLS
00.00.0.10.11
00.00.0.00.10011
00
0.00.00101
00
BB
CC AA
55 1010 1515 2020 2525 3030 3535 404B0B
IPITPCTCRRMMSS(A(A) )
CC AA
5 5 1010 1515 2020 2525 3030 3535 4040
AAmmbbieinent tTeTmemppereartauturere(˚(C˚C) )
RoHS Compliant, ELV Compliant
Specifications subject to change without notice. ©2016 LitItPeITPlCTfCuRsRMeMS,SI(nA(Ac) .)
4545
4545
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