PE-53718T datasheet, PDF - EEWORLD Datasheet

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PE-53718T: DescriptionGeneral Purpose Inductor, 39.5uH, 20%, 2 Element, Amorphous Magnetic-Core, SMD, 5971, CHIP, 7159; CategoryPassive components inductor; File Size132KB，2 Pages; ManufacturerPulse Electronics

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PE-53718T Overview

General Purpose Inductor, 39.5uH, 20%, 2 Element, Amorphous Magnetic-Core, SMD, 5971, CHIP, 7159

PE-53718T Parametric

Parameter Name	Attribute value
Maker	Pulse Electronics
package instruction	5971
Reach Compliance Code	compliant
ECCN code	EAR99
uppercase and lowercase codes	5971
structure	Toroid
core material	AMORPHOUS MAGNETIC
DC Resistance	0.0905 Ω
Nominal inductance(L)	39.5 µH
Inductor Applications	POWER INDUCTOR
Inductor type	GENERAL PURPOSE INDUCTOR
Manufacturer's serial number	SLIC
Number of functions	2
Number of terminals	4
Maximum operating temperature	130 °C
Minimum operating temperature	-40 °C
Package height	9.91 mm
Package length	14.99 mm
Package form	SMT
Package width	18.16 mm
method of packing	TR
Maximum rated current	2.7 A
series	PE-53
Shape/Size Description	RECTANGULAR PACKAGE
shield	NO
surface mount	YES
Terminal location	DUAL IN-LINE
Terminal shape	WRAPAROUND
Tolerance	20%

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SMT POWER INDUCTORS

Toroid - SLIC Series

Fifteen package sizes

Current Rating:

up to 23.8A

Frequency Range:

up to 1MHz

Electrical Specifications @ 25°C — Operating Temperature -40°C to +130°C

Pulse

4,5

Inductance

Part

@ Irated

Number

(µH)

LCI-20

PE-53630

1.01

PE-53600

6.2

PE-53601

17.6

LCI-30

PE-53650

3.8

PE-53631

9.4

PE-53602

29.7

PE-53606

114

LCI-37

PE-53661

2.5

PE-53651

5.1

PE-53632

16.2

PE-53604

58.1

PE-53608

192

PE-53611

383

LCCI-37

PE-53717

43.6

LCI-44

PE-53662

4.9

PE-53652

PE-53633

29.1

PE-53613

645

HCI-37

PE-53690

0.81

PE-53680

1.32

LCCI-44

PE-53718

21.9

HCI-44

PE-53691*

1.68

PE-53681

2.5

LCI-50

PE-53663

9.3

PE-53653

16.1

PE-53634

PE-53614

1070

LCCI-50

PE-53719

4.025

HCI-50

PE-53692*

3.5

PE-53682

4.7

HCCI-44

PE-53361

0.53

HCCI-50

PE-53362

1.1

HCI-68

PE-53700*

5.2

PE-53683

9.4

HCCI-68

PE-53363

2.1

Irated

(A)

3.40

1.40

1.00

4.80

2.80

1.40

0.94

8.00

5.40

2.70

1.30

0.90

0.72

1.1

7.80

5.50

2.70

0.74

14.30

11.50

2.7

13.90

11.40

7.20

5.10

2.60

0.71

6.4

12.40

10.40

23.8

15.40

10.90

22.4

TYP

9.35

59.5

106.25

14.705

36.89

141.1

365

7.055

15.045

246.5

476

732.7

247.2

10.54

1062.5

2.125

3.4

72.4

3.06

4.59

15.895

27.2

113.05

1445

18.4

5.61

7.055

1.0

1.7

5.27

10.455

2.5

DCR (mΩ

)

MAX

125

17.3

43.4

166

405

8.3

17.7

290

560

862

309

12.4

100

1250

2.5

4.0

90.5

3.6

5.4

18.7

32.0

133

1700

6.6

8.3

2.5

6.2

12.3

3.4

Inductance

@ 0A

(µH)

1.1

22.7

5.2

12.3

35.3

167

3.8

7.5

21.9

292

672

7.9

40.5

1134

1.25

2.1

39.5

2.8

4.2

25.9

72.9

1950

6.575

6.5

8.4

0.88

2.1

10.5

17.6

Reference

(Volt-µsec)

0.53

1.33

2.4

1.76

2.7

4.6

1.77

2.51

4.29

7.83

15.7

23.5

7.83

3.04

4.06

6.9

36.5

1.035

1.33

6.9

1.83

2.23

4.92

6.27

10.5

54.4

3.135

3.1

3.58

1.75

5.21

6.84

3.25

Flux Density

Factor

(K1)

5.43

2.17

1.21

1.28

0.83

0.49

0.23

1.30

0.92

0.54

0.29

0.15

0.10

0.295

0.67

0.51

0.30

0.06

2.23

1.74

0.297

1.12

0.92

0.41

0.32

0.19

0.04

0.638

0.64

0.56

2.020

1.116

0.35

0.27

0.559

Core Loss

Factor

(K2)

3.29E-11

1.39E-10

1.87E-10

3.35E-10

1.87E-10

3.35E-10

4.52E-10

3.35E-10

4.52E-10

9.58E-10

Temp. Rise

Factor

(K3)

323.9

148.0

114.2

114.23

85.7

114.2

85.71

85.7

67.9

67.89

67.9

85.71

67.89

44.6

44.56

NOTES:

1. Reference values are for an inductor with a 55°C temperature rise.

The core loss is 10% of the copper loss at the ET listed and 500kHz.

2. Core does not saturate abruptly. The ET and DC current are limited by

the desired inductance and temperature rise.

3. In high volt-time applications, additional heating in the component can

occur due to core losses in the inductor which may necessitate derat-

ing the current in order to limit the temperature rise of the

component. In order to determine the approximate total losses

(or temperature rise) for a given application, both copper and core

losses should be taken into account.

Estimated Temperature Rise:

Trise = K3 * (Coreloss(W) + Copperloss(W)

.833

(C)

CopperLoss = Irms

* DCR_Typical (mΩ) / 1000

CoreLoss = K2 * (Freq_kHz)

1.26

* (ΔB)

2.11

ΔB

= K1 * Volt-µsec * 100

4. Optional Tape & Reel packaging can be ordered by adding a "T" suffix

to the part number (i.e. PE-53600 becomes PE-53600T). Pulse complies

to industry standard tape and reel specification EIA481.

5. To order RoHS compliant part, add the suffix “NL” to the part number (i.e.

PE-53600 becomes PE-53600NL and PE-53600T becomes PE-53600NLT).

6. The temperature of the component (ambient plus temperature rise) must be

within the stated operating temperature range.

USA 858 674 8100

•

Germany 49 7032 7806 0

•

Singapore 65 6287 8998

•

Shanghai

86 21 54643211 / 2

•

China 86 755 33966678

•

Taiwan 886 3 4641811

www.pulseeng.com

SPM2007 (7/07)

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