Close up of ML466PJD
3D Model Datasheet

ML466PJD Series

Coupled Inductors for Critical Applications

ML466PJD coupled inductors for critical applications feature high inductance, high efficiency and excellent current handling. Can also be used as two single inductors connected in series or parallel or as a common mode choke.
  • Only 3 mm high and 5 mm square.
  • Ideal for use in flyback, multi-output buck and SEPIC applications.
  • Silver-palladium-platinum-glass frit terminations.

Looking for the commercial version of this part? See Coilcraft LPD5030 Series
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Specifications

Electrical specifications at 25°C.

For Flyback Applications

Part number 1 Inductance (µH) 2 Tolerance (%) DCR max (Ω) 3 Isolation
Voltage (V)
Leakage
Inductance (µH) 5
ML466PJD102NLZ 1.0 30 0.042 100 0.090
ML466PJD152MLZ 1.5 20 0.048 100 0.090
ML466PJD222MLZ 2.2 20 0.067 100 0.10
ML466PJD332MLZ 3.3 20 0.077 100 0.10
ML466PJD472MLZ 4.7 20 0.11 100 0.11
ML466PJD562MLZ 5.6 20 0.13 100 0.11
ML466PJD682MLZ 6.8 20 0.16 100 0.12
ML466PJD103MLZ 10 20 0.21 100 0.13
ML466PJD153MLZ 15 20 0.30 100 0.15
ML466PJD223MLZ 22 20 0.45 100 0.17
ML466PJD333MLZ 33 20 0.57 100 0.20
ML466PJD473MLZ 47 20 0.81 100 0.24
ML466PJD683MLZ 68 20 1.1 100 0.29
ML466PJD104MLZ 100 20 1.8 100 0.37
ML466PJD154MLZ 150 20 2.4 100 0.46
ML466PJD224MLZ 220 20 3.3 100 0.54
ML466PJD334MLZ 330 20 5.4 100 0.65
ML466PJD474MLZ 470 20 7.5 100 0.76
ML466PJD684MLZ 680 20 10.8 100 0.89
ML466PJD105MLZ 1000 20 16.5 100 1.2

For SEPIC Applications

Part number 1 Inductance (µH) 2 Tolerance (%) DCR max (Ω) 3 SRF Typ (MHz) 4 Coupling coefficient Leakage
Inductance (µH) 5
Isat (A) 6 Irms (A)
10% drop 20% drop 30% drop both windings 7 one winding 8
ML466PJD102NLZ 1.0 30 0.042 153 0.95 0.090 4.30 4.49 4.67 2.20 3.11
ML466PJD152MLZ 1.5 20 0.048 118 0.97 0.090 3.90 4.20 4.30 2.05 2.90
ML466PJD222MLZ 2.2 20 0.067 87.0 0.98 0.10 2.80 2.98 3.07 1.95 2.76
ML466PJD332MLZ 3.3 20 0.077 61.0 0.98 0.10 2.50 2.70 2.80 1.70 2.40
ML466PJD472MLZ 4.7 20 0.11 49.0 0.99 0.11 2.10 2.20 2.20 1.40 1.98
ML466PJD562MLZ 5.6 20 0.13 44.0 0.99 0.11 1.80 1.80 1.89 1.35 1.91
ML466PJD682MLZ 6.8 20 0.16 40.0 0.99 0.12 1.40 1.48 1.48 1.20 1.70
ML466PJD103MLZ 10 20 0.21 28.0 0.99 0.13 1.20 1.20 1.20 1.05 1.48
ML466PJD153MLZ 15 20 0.30 23.0 0.99 0.15 1.00 1.17 1.17 0.85 1.20
ML466PJD223MLZ 22 20 0.45 17.0 >0.99 0.17 0.89 0.98 0.98 0.70 0.99
ML466PJD333MLZ 33 20 0.57 16.0 >0.99 0.20 0.73 0.77 0.78 0.60 0.85
ML466PJD473MLZ 47 20 0.81 12.0 >0.99 0.24 0.59 0.63 0.65 0.50 0.71
ML466PJD683MLZ 68 20 1.1 9.0 >0.99 0.29 0.50 0.54 0.55 0.43 0.61
ML466PJD104MLZ 100 20 1.8 8.4 >0.99 0.37 0.47 0.54 0.56 0.33 0.47
ML466PJD154MLZ 150 20 2.4 6.7 >0.99 0.46 0.38 0.43 0.45 0.28 0.40
ML466PJD224MLZ 220 20 3.3 5.5 >0.99 0.54 0.31 0.35 0.36 0.24 0.34
ML466PJD334MLZ 330 20 5.4 4.2 >0.99 0.65 0.25 0.25 0.32 0.18 0.25
ML466PJD474MLZ 470 20 7.5 3.5 >0.99 0.76 0.21 0.24 0.26 0.15 0.21
ML466PJD684MLZ 680 20 10.8 2.9 >0.99 0.89 0.17 0.20 0.21 0.13 0.18
ML466PJD105MLZ 1000 20 16.5 2.3 >0.99 1.2 0.15 0.17 0.17 0.10 0.14
Notes
  1. When ordering, please specify termination and screening codes: ML466PJD105MLZ.
  2. Inductance shown for each winding, measured at 100 kHz, 0.1 Vrms, 0 Adc on an Agilent/HP 4284A LCR meter or equivalent. When leads are connected in parallel, inductance is the same value. When leads are connected in series, inductance is four times the value.
  3. DCR is for each winding. When leads are connected in parallel, DCR is half the value. When leads are connected in series, DCR is twice the value.
  4. SRF measured using an Agilent/HP 4191A or equivalent. When leads are connected in parallel, SRF is the same value.
  5. Leakage Inductance is for L1 and is measured with L2 shorted.
  6. DC current, at which the inductance drops the specified amount from its value without current. It is the sum of the current flowing in both windings.
  7. Equal current when applied to each winding simultaneously that causes a 40°C temperature rise from 25°C ambient. Calculate temperature rise.
  8. Maximum current when applied to one winding that causes a 40°C temperature rise from 25°C ambient. This information is for reference only and does not represent absolute maximum ratings. Calculate temperature rise.

Termination:

  • L = Silver-palladium-platinum-glass frit.
  • R = Matte tin over nickel over silver.

Screening:

  • Z = Unscreened
  • Y = Unscreened (SLDC Option A)
  • W = Unscreened (SLDC Option B)
  • H = Coilcraft CP-SA-10001 Group A
  • G = Coilcraft CP-SA-10001 Group A (SLDC Option A)
  • D = Coilcraft CP-SA-10001 Group A (SLDC Option B)
  • Screening performed to the document’s latest revision.
  • Custom testing also available.
  • Country of origin restrictions available; prefix option G.
Environmental
Ambient temperature range:
–55°C to +105°C with Irms current.
Storage temperature range:
Component: –55°C to +155°C.
Packaging: –55°C to +80°C.
Maximum part temperature:
+155°C (ambient + temp rise).
Failures in Time (FIT) / Mean Time Between Failures (MTBF):

Performance curves

L vs Frequency

L vs Current

Schematics

ml466pjd_schematic.PNG

Physical characteristics

ml466pjdd.gif

Dimensions are in  inchesmm

General specification

Core Material:
Ferrite
Weight:
210 – 300 mg
Packaging:
750 per 7″ reel Plastic tape: 12 mm wide, 0.32 mm thick, 8 mm pocket spacing, 3.1 mm pocket depth
Winding to Winding Isolation:
100 V

Soldering/Washing

Moisture Sensitivity Level (MSL):
1 (unlimited floor life at <30°C / 85% relative humidity)
Resistance to soldering heat:
Max three 40 second reflows at +260°C, parts cooled to room temperature between cycles
Refer to Soldering Coilcraft Components before soldering.
Recommended Pick & Place Nozzle:
OD: 5 mm; ID: ≤ 2.5 mm