0ZRR0160FF1A

Radial Leaded PTC 0ZRR Series 0ZRR Series RoHS Compliant Product Features - Low hold current, Solid state, Radial leaded product ideal for up to 60VDC - Full compliance with EU Directive 2011/65/EU and amending directive 2015/863 - AEC-Q Compliant - Meets Bel automotive qualification* * - Largely based on internal AEC-Q test plan Operating (Hold Current) Range 50mA - 3.75A Maximum Voltage 60VDC Temperature Range -40° C to 85° C Agency Approval TUV (Std. EN/IEC 60738-1-1 and EN/IEC 60730-1, Cert. R50102187) UL Recognized Component (Std. UL1434, File E305051) AEC-Q Compliant LEAD FREE = HALOGEN FREE = Electrical Characteristics (23 ) Max Time to Trip Current Time A Sec 0.25 5.0 Resistance Tolerance Agency Approvals Rmin R1max Ohms Ohms 7.30 20.00 Y Y 2.50 7.50 Y A 0ZRR0005FF1E Hold Current IH, A 0.05 Trip Current IT, A 0.10 Rated Voltage Vmax, Vdc 60 Max Current Imax, A 40 Typical Power Pd, W 0.26 B 0ZRR0010FF1E C 0ZRR0017FF1E 0.10 0.17 0.20 0.34 60 60 40 40 0.38 0.48 0.50 0.85 4.0 3.0 2.00 8.00 Y D 0ZRR0020FF1E E 0ZRR0025FF1E 0.20 0.25 0.40 0.50 60 60 40 40 0.41 0.45 1.00 1.25 2.2 2.5 1.83 1.25 4.40 3.00 Y Y F 0ZRR0030FF1E 0.30 0.60 60 40 0.49 1.50 3.0 0.88 2.10 Y G 0ZRR0040FF1E H 0ZRR0050FF1E 0.40 0.50 0.80 1.00 60 60 40 40 0.56 0.77 2.00 2.50 3.8 4.0 0.55 0.50 1.29 1.17 Y Y Y I 0ZRR0065FF1E J 0ZRR0075FF1E 0.65 0.75 1.30 1.50 60 60 40 40 0.88 0.92 3.25 3.75 5.3 6.3 0.31 0.25 0.72 0.60 Y Y Y Y K 0ZRR0090FF1E 0.90 1.80 60 40 0.99 4.50 7.2 0.20 0.47 Y Y L 0ZRR0110FF1A M 0ZRR0135FF1A 1.10 1.35 2.20 2.70 60 60 40 40 1.50 1.70 5.50 6.75 8.2 9.6 0.15 0.12 0.38 0.30 Y Y Y Y N 0ZRR0160FF1A O 0ZRR0185FF1A 1.60 1.85 3.20 3.70 60 60 40 40 1.90 2.10 8.00 9.25 11.4 12.6 0.09 0.08 0.22 0.19 Y Y Y Y P 0ZRR0250FF1A Q 0ZRR0300FF1A 2.50 3.00 5.00 6.00 60 60 40 40 2.50 2.80 12.50 15.00 15.6 19.8 0.05 0.04 0.13 0.10 Y Y Y Y R 0ZRR0375FF1A 3.75 7.50 60 40 3.20 18.75 24.0 0.03 0.08 Y Y Part Number (Bulk) Y Y Y Y Y IH Hold Current- The maximum current at which the device will not trip in still air at 23° C. IT Trip current- The minimum current at which the device will trip in still air at 23° C. Vmax Maximum voltage device can withstand at its rated current without suffering damage. Imax Maximum fault current device can withstand at rated voltage (Vmax) without damage. Pd Typical power dissipated by device when in tripped state in 23° C still air environment. Rmin Minimum device resistance at 23° C in initial un-soldered state. R1max Maximum device resistance at 23° C, 1 hour after initial device trip, or after being soldered to PCB in end application. Specifications subject to change without notice belfuse.com/circuit-protection Type 0ZRR Series 2/4 PTC’s – Basic Theory of Operation / “Tripped” Resistance Explanation A Bel PTC consists of a block of polymeric material containing conductive carbon granules which is sandwiched between two conductive metal plates. When this polymer block reaches approximately 125C, either due to current passing through it via conductive chains of carbon particles or due to an external heat source; it swells volumetrically. This expansion breaks apart a majority of the chains of carbon granules that run randomly between the two conductive plates. This behavior results in a sharp increase in resistance across the two plates which all but eliminates current flow through the device, allowing just enough residual current flow to maintain the block’s internal temperature at 125C. Once this “tripped” state current is cut off, the polymer brick cools and shrinks to its original size, thereby allowing its broken carbon chains to reestablish themselves and permit the part to return to its low resistance state. Once cooled to room ambient, the PTC will once again exhibit a resistance less than its “R1max” rating. At currents below the device IHOLD rating, AND at temperatures below 100C, the PTC maintains a resistance value below its R1 MAX rating. The catalog data for each device specifies a "Typical Power" value. This is the power required to exactly match the heat lost by the tripped device to its ambient surroundings at 23C. By Ohm's Law, power can be stated as: W = E²/R. Thus the approximate resistance of a “Tripped” PTC can be determined by: R = E²/W, where "E" is the voltage appearing across the PTC (usually the supply's open circuit voltage), and "W" is the Typical Power value for the particular PTC. Since the PPTC acts to maintain a constant internal temperature, its apparent resistance will change based upon applied voltage and, to a lesser degree, ambient conditions. Consider the following example.... A PTC with a Typical Power of 1 watt protecting a circuit using a 60V supply will demonstrate an apparent, tripped resistance "R" of: R = 60²/1 = 3,600 ohms This same tripped device when used to protect a 12V circuit would now present an apparent resistance of: R = 12²/1 = 144 ohms The value for Typical Power is "typical" because any physical factors that affect heat loss (such as ambient temperature or air convection) will somewhat alter the level of power that the PTC needs to maintain its internal temperature. In short, PTCs do not exhibit a constant, quantifiable tripped resistance value. Average Time Current Characteristic Curve at 23°C The Average Time Current Characteristic Curve and Temperature Rerating Curve are affected by a number of variables and these curves are provided for guidance only. Specifications subject to change without notice Bel Fuse Inc. 206 Van Vorst Street Jersey City, NJ 07302 USA +1 201.432.0463 Bel.US.CS@belf.com belfuse.com/circuit-protection © 2023 Bel Fuse, Inc. Rev. 0ZRR Apr2023 Type 0ZRR Series 3/4 Physical Specifications Lead material: Matte tin plated copper, size / diameter as shown in Drawings and Table under Product Dimensions. Soldering charactcristics MIL-STD-202, Method 208H. Insulating coating Flame retardant epoxy, meets UL-94-V-0 requirements. PTC Marking All dimensions in mm. “bel” or “b”, , IH code and “RR” . Product Dimensions Temperature Derating Table Fig. A Max B Max C Typical D Min E Max F Typical 0ZRR0005FF 0ZRR0025FF 1 7.4 12.7 5.1 7.6 3.1 1.1 0ZRR0030FF 1 7.4 13.0 5.1 7.6 3.1 1.1 0ZRR0040FF 1 7.6 13.5 5.1 7.6 3.1 1.1 0ZRR0050FF 1 7.9 13.7 5.1 7.6 3.1 1.1 0ZRR0065FF 1 9.7 14.5 5.1 7.6 3.1 1.1 0ZRR0075FF 1 10.4 15.2 5.1 7.6 3.1 1.1 0ZRR0090FF 1 11.7 15.8 5.1 7.6 3.1 1.1 0ZRR0110FF 2 13.0 18.0 5.1 7.6 3.1 1.4 0ZRR0135FF 2 14.5 19.6 5.1 7.6 3.1 1.4 0ZRR0160FF 2 16.3 21.3 5.1 7.6 3.1 1.4 0ZRR0185FF 2 17.8 22.9 5.1 7.6 3.1 1.4 0ZRR0250FF 2 21.3 26.4 10.2 7.6 3.1 1.4 0ZRR0300FF 2 24.9 30.0 10.2 7.6 3.1 1.4 0ZRR0375FF 2 28.5 33.5 10.2 7.6 3.1 1.4 Part Number Temperature Derating I Hold Value -40 -20 0 23 30 40 50 60 70 85 0005 and 0010 170% 148% 127% 100% 92% 80% 69% 57% 46% 28% 0017 thru 0375 150% 134% 117% 100% 94% 87% 75% 63% 53% 38% Thermal Derating Curve Cautionary Notes Temperature Derating Curve 180% Percent of Hold and Trip Current 160% 140% 120% 100% 80% 60% 40% 20% 0% -40 -20 0 20 40 60 Temperature(° C) 0005 and 0010 0017 thru 0375 80 1. Operation beyond the specified maximum ratings or improper use may result in damage and possible electrical arcing and/or flame. 2. These Polymer PTC (PPTC) devices are intended for protection against occasional overcurrent/overtemperature fault conditions and may not be suitable for use in applications where repeated and/or prolonged fault conditions are anticipated. 3. Avoid contact of PTC device with chemical solvent. Prolonged contact may adversely impact the PTC performance. 4. These PTC devices may not be suitable for use in circuits with a large inductance, as the PTC trip can generate circuit voltage spikes above the PTC rated voltage. 5. These devices may be used in both DC and AC circuits provided that peak-to-peak line voltage when carrying AC does not exceed the PTC’s Vmax rating. As PTCs are essentially thermal devices, the RMS value of AC current carried by a PTC will produce tripping parameters and times-to-trip similar to those of a DC voltage of the same magnitude. 6. If potting is mandated, avoid rigid potting compounds as they will encase the PTC and prevent it from volumetrically expanding to properly respond to a trip event. Specifications subject to change without notice Bel Fuse Inc. 206 Van Vorst Street Jersey City, NJ 07302 USA +1 201.432.0463 Bel.US.CS@belf.com belfuse.com/circuit-protection © 2023 Bel Fuse, Inc. Rev. 0ZRR Apr2023 Type 0ZRR Series 4/4 Environmental Specifications Temperature cycling JESD22 Method JA-104 Biased humidity MIL-STD-202 Method 103 Operational life MIL-STD-202 Method 108 Terminal strength AEC-Q200-004 Resistance to solvents MIL-STD-202 Method 215 Mechanical shock MIL-STD-202 Method 213 Vibration MIL-STD-202 Method 204 Resistance to soldering heat MIL-STD-202 Method 210 Thermal shock MIL-STD-202 Method 107 Solderability ANSI/J-STD-002 Soldering Parameters Lead-free Wave Soldering Profile Wave Solder Parameter Average ramp-up rate 200° C / second typical 1 - 2° C / second Max 4° C / second within 125° C of soldering temperature Heating rate during preheat Final preheat temperature Peak temperature Tp 260° C Time within +0° C / -5° C of actual peak temperature 10 seconds Ramp-down rate 5° C / second max. Standard Packaging P/N Explanation and Ordering Information Bulk Reel/Tape Part Number Pcs/Box P/N Code Pcs/Reel 0ZRR0005FF 0ZRR0090FF 0ZRR0110FF 0ZRR0185FF 0ZRR0250FF 0ZRR0375FF P/N Code 3000 1E 3000 2E 1000 1A 1500 2B 1000 1A 1000 2A Specifications subject to change without notice Bel Fuse Inc. 206 Van Vorst Street Jersey City, NJ 07302 USA +1 201.432.0463 Bel.US.CS@belf.com belfuse.com/circuit-protection © 2023 Bel Fuse, Inc. Rev. 0ZRR Apr2023