P R O D U C T G U I D E SOFT FERRITE CORES

Transcript

1 P R O D U C T G U I D E SOFT FERRITE CORES

2 CONTENTS Material Grades Material Characterestics Graphs Cross Reference Table EE Cores EER, EEC, ETD Cores EI Cores EFD Cores EP Cores EPC and FQKT Cores PQ Cores RM Cores ESQ and USQ Cores Planar Cores UU and UI Cores Colur FBT Core Ferrite Bars Torroids Drum Cores Small rods

3 MATERIAL GRADES Ferrites are magnetic ceramic materials composed of metal oxides with Iron oxide as their main constituent. Ferrites have now been firmly established as one of the most important class of magnetic materials and are indispensable in Electrical, Electronics and Communication Engineering. Ferrites which exhibit temporary magnetic properties under the influence of an electrical field are called Soft Ferrites. Soft Ferrites allow easy magnetisation and also rapid reversal of the magnetisation in response to rapid alteration of energising field. MnZn Ferrite Material Characteristics Property Symbol Unit Test condition MSB-7C HP4 HP-38 HP-3 HPT-45 HPT-4 HB-4 HM-3 HM-4 HM-45 GQ5C HM-6 HM-7 HM- ** HT-8 HT-2 HT-35 HR-4 HR-4B HQ-23 Initial permeability (±25%) μi ----.mt, 25 o C A/m, 25 o C A/m, o C Relative loss factor (max) Relative loss factor (max) t anδ/ μi -6.25mT, khz, 25 o C mT, khz, o C Coercive Field (max) Hc A/m KHz, 25 o C Hysteris material Coefficient (max) ηb -6 /mt 25 o C Curie Temperature (min) Tc o C Density (min) d kg/ 3 m 25 o C Temperature Coeff. of permeability (max) αf -6 /K -4 to 8 o C ±3 ± Resistivity (min) ρ Ωm 25 o C kHz, 5mT, o C 4 khz, 2mT, 25 o C 5 4 Power loss (max) Pc mw /cc khz, 2mT, o C kHz, 2mT, 25 o C 8 4kHz, 2mT, o C 7 6 Application Power transformers grades Communication (Broad band filters) RFID Antenna Impeder cores Inductors Properties are measured on Toroid T 3 X 2 X mm. Properties on actual product may var y depends on its size and shape. **Properties are measured on T oroid T X 4 X6 mm. Properties on actual product may vary depends on its size and shape.

4 Flux density (mt) Relative core loss( mw/cc) Complex permeability Initial permeability MATERIAL GRADE: MSB - 7C MSB-7C : POWER TRANSFORMER GRADE Properties Symbol Unit Test condition Values Initial permeability (±25%) μi.mt, 25 o C 24 o 2A/m, 25 C 5 2A/m, o C 38 Coercive Field (max) Hc A/m KHz, 25 o C Hysteris material Coefficient (max) η B -6 /mt 25 o C.2 Curie Temperature (min) Tc o C 22 Density (min) d kg/m 3 25 o C 48 Temperature Coeff. of permeability (max) α F -6 /K -4 to 8 o C 4 Resisitivity (min) ρ Ωm 25 o C 5 Powerloss (max) Pc mw /cc khz, 2mT, o C 6 Complex permeability vs. Frequency Initial permeability vs Temperature μ' μ" 2 μ' μ" Flux density vs Temperature Relative core losses vs temperature H = 2 A/m khz/2mt All measurements made on Toroid OD = 3mm, ID=2mm Ht=mm.

5 Flux density (mt) Complex permeability MATERIAL GRADE: HP - 4 HP-4 : POWER TRANSFORMER GRADE Properties Symbol Unit Test condition Values Initial permeability (±25%) i.mt, 25 o C 22 o 2A/m, 25 C 5 2A/m, o C 4 Coercive Field (max) Hc A/m khz, 25 o C Hysteris material Coefficient (max) B -6 /mt 25 o C.2 Curie Temperature (min) Tc o C 2 Density (min) d kg/m 3 25 o C 485 Temperature Coeff. of permeability (max) F -6 /K -4 to 8 o C 4 Resisitivity (min) m 25 o C 5 Powerloss (max) Pc mw /cc khz, 2mT, o C 4 Complex permeability vs frequency Initial permeability vs temperature μ' μ" Flux density vs. temperature H=2A/m Rekative core loss ( mw/cc) Intial permeability μ' _--_-- μμ' " μ" Temperature (ºC) Relative core losses vs temperature khz/2mt All measurements madeon Toroid OD= 3mm, ID=2mm Ht=mm.

6 Relative core loss( mw/cc) Amplitude permeability Complex permeability MATERIAL GRADE: HP - 38 HP-38 : Power Transformer Grade Properties Symbol Unit Test condition Values Initial permeability (±25%) μi.mt, 25 o C 22 o 2A/m, 25 C 49 2A/m, o C 39 Coercive Field (max) Hc A/m khz, 25 o C Hysteris material Coefficient (max) ηb -6 /mt 25 o C Curie Temperature (min) Tc o C 2 Density (min) d kg/m 3 25 o C 485 Temperature Coeff. of permeability (max) αf -6 /K -4 to 8 o C 4 Resisitivity (min) ρ Ωm 25 o C 5 Powerloss (max) Pc mw /cc khz, 2mT, o C 38 HP-38: Complex permeability vs frequency HP-38: Initial permeability vs temperature μ' μ" HP-38: Amplitude permeability vs. AC field flux density 2 f = khz 2ºC ---- ºC Flux density (mt) HP38: Relative core losses vs AC field flux density 2ºC ºC Rekative core loss ( mw/cc) Flux density (mt) Intial permeability μ' _--_--_-_--_-_--_--μμ'" μ" Temperature (ºC) HP-38: Flux density vs. temperature f = khz H=2A/m 2 m T m T 5 m T 25 m T Relative core losses vs temperature khz/2mt B (mt) All measurements made on Toroid OD= 3mm, ID=2mm Ht=mm.

7 Relative Coreloss (mw/cc) μi MATERIAL GRADE: HP - 3 HP-3 : Power Transformer Grade Properties Symbol Unit Test condition Values Initial permeability (±25%) i.mt, 25 o C 22 o 2A/m, 25 C 5 2A/m, o C 42 Coercive Field (max) Hc A/m khz, 25 o C Hysteris material Coefficient (max) B -6 /mt 25 o C Curie Temperature (min) Tc o C 2 Density (min) d kg/m 3 25 o C 485 Temperature Coeff. of permeability (max) F -6 /K -4 to 8 o C 4 Resisitivity (min) m 25 o C 8 Powerloss (max) Pc mw /cc khz, 2mT, o C 3 Complex permeability vs Frequency Initial permeability vs Temperature Flux density (mt) Complex permeability μ' μ" μ' μ" Flux density vs temperature H = 2 A/m Relative core losses vs temperature khz/2mt All measurements made on Toroid OD= 3mm, ID=2mm Ht=mm.

8 Relative core loss ( mw/cc) Initial permeability MATERIAL GRADE: HPT - 45 HPT - 45 : Power Transformer Grade Properties Symbol Unit Test condition Values Initial permeability (±25%) i.mt, 25 o C 24 o 2A/m, 25 C 5 2A/m, o C 4 Coercive Field (max) Hc A/m khz, 25 o C 8 Hysteris material Coefficient (max) B -6 /mt 25 o C. Curie Temperature (min) Tc o C 2 Density (min) d kg/m 3 25 o C 48 Temperature Coeff. of permeability (max) F -6 /K -4 to 8 o C 2.5 Resisitivity (min) m 25 o C 3 Powerloss (max) Pc mw/cc khz, 2mT, o C 45 Complex permeability vs frequency Initial permeability vs temperature 4 Flux density (mt) Complex permeability μ' μ" Flux density vs temperature Relative core losses vs temperature khz/2mt All measurements made on Toroid OD= 3mm, ID=2mm Ht=mm.

9 F lux dens ity (mt ) C om plex per me a bi li ty Initia l per mea bility MATERIAL GRADE: MSB - 5S MSB-5S : Wideband Transformer Grade Prope rties Sym bol Unit T est condi tion Va lues Initial permeability (±25%) μi.mt, 25 o C 3 o 2A/m, 25 C 48 2A/m, o C 33 Relative loss factor tan /μi (max) tan /μi -6.25mT, khz & 25 o C 6 Coercive Field (max) Hc A/m khz, 25 o C 5 Hysteris material Coefficient (max) B -6 /mt 25 o C.3 Curie Temperature (min) Tc o C 7 Density (min) d kg/m 3 25 o C 49 Temperature Coeff. of permeability (max) F -6 /K -4 to 8 o C.2 Resisitivity (min) m 25 o C Co m plex perm eabili ty vs fr equ ency Ini tial perm eabili ty vs tem perature μ' μ" f(khz) Tempe rature (ºC) Flux density vs tem perature Re lat ive loss f actor vs fr equ ency H = 2 A/m Tem perature(ºc) Frequ ency (khz ) All measurements made on Toroid OD= 3mm, ID=2mm Ht=mm.

10 Pc (mw/cc) Flux Density (mt) MATERIAL GRADE: HPT - 4 HPT - 4 : Power Transformer Grade Properties Symbol Unit Test condition Values Initial permeability (±25%) i.mt, 25 o C 3 Relative loss factor tan /μi x -6 khz, 25 o C 2 2A/m, 25 o C 5 2A/m, o C 39 Coercive Field (max) Hc A/m khz, 25 o C Curie Temperature (min) Tc o C 22 Density (min) d kg/m 3 25 o C 48 Temperature Coeff. of permeability (max) F -6 /K -4 to 8 o C.5 Resisitivity (min) m 25 o C 7 Powerloss (max) Pc mw/cc khz, 2mT, 25 o C 4 khz, 2mT, o C 4 HPT-4 : Initial Permeability Vs Temperature HPT-4 : Flux Density Vs Temperature Permeability Initial Permeability Temperature ( C) HPT-4 : Complex Permeability Vs Frequency Frequency (KHz) Temperature ( C) HPT-4 : Power Loss Vs Temperature Temperature ( C) All measurements made on Toroid OD=3mm, ID=2mm Ht=mm.

11 Flux density (mt) Complex permeability Initial permeability MATERIAL GRADE: HB - 4 HB - 4 : Wideband Transformer Grade Properties Symbol Unit Test condition Values Initial permeability (±25%) i.mt, 25 o C 38 2A/m, 25 o C 55 2A/m, o C 435 Relative loss factor tan / i (max) tan / i -6.25mT, khz & 25 o C 4 Coercive Field (max) Hc A/m khz, 25 o C 5 Hysteris material Coefficient (max) B -6 /mt 25 o C.3 Curie Temperature (min) Tc o C 25 Density (min) d kg/m 3 25 o C 49 Temperature Coeff. of permeability (max) F -6 /K -4 to 8 o C.2 Resisitivity (min) m 25 o C 2 HB-4: Complex permeability vs frequency HB-4: Initial permeability vs temperature 5 μ' μ" Temperature (ºC) Flux density vs temperature Relative loss factor vs frequency H= 2 A/m Frequency (khz) All measurements made on Toroid OD= 3mm, ID=2mm Ht=mm.

12 MATERIAL GRADE: HM - 3 μi HM 3 : Wideband Transformer Grade Properties Symbol Unit Test condition Values Initial permeability (±25%) i.mt, 25 o C 3 o 2A/m, 25 C 48 2A/m, o C 33 Relative loss factor tan / i (max) tan / i -6.25mT, khz & 25 o C 6 Coercive Field (max) Hc A/m khz, 25 o C 5 Hysteris material Coefficient (max) B -6 /mt 25 o C.3 Curie Temperature (min) Tc o C 8 Density (min) d kg/m 3 25 o C 49 Temperature Coeff. of permeability (max) F -6 /K -4 to 8 o C.2 Resisitivity (min) m 25 o C Complex permeability vs frequency Initial permeability vs temperature 7 6 Flux density (mt) Complex permeability μ' μ" f(khz) Flux density vs temperature H = 2 A/m Temperature (ºC) Relative loss factor vs frequency All measurements made on Toroid OD= 3mm, ID=2mm Ht=mm.

13 MATERIAL GRADE: HM - 4 Initail permeability HM - 4 : Wideband Transformer Grade Properties Symbol Unit Test condition Values Initial permeability (±25%) i.mt, 25 o C 4 o 2A/m, 25 C 47 2A/m, o C 33 Relative loss factor tan / i (max) tan / i -6.25mT, khz & 25 o C 3.25mT, khz & 25 o C Coercive Field (max) Hc A/m khz, 25 o C 3 Hysteris material Coefficient (max) B -6 /mt 25 o C.8 Curie Temperature (min) Tc o C 7 Density (min) d kg/m 3 25 o C 49 Temperature Coeff. of permeability (max) F -6 /K -4 to 8 o C 3 Resisitivity (min) m 25 o C HM-4: Complex permeability vs Frequency HM-4: Initial permeability vs Temperature Flux density (mt) Complex permeability μ' μ" HM-4: Flux density vs Temperature H= 2 A/m Temperature (ºC) HM4:Relative loss factor vs frequency All measurements made on Toroid OD= 3mm, ID=2mm Ht=mm.

14 Initial Permeability MATERIAL GRADE : HM - 45 HM - 45 : CFL Transformer Properties Symbol Unit Test condition Values Initial permeability (±25%) i.mt, 25 o C 45 2A/m, 25 o C 47 2A/m, o C 33.25mT, khz & 25 o C 3 Relative loss factor tan / i (max) tan / i -6.25mT, khz & 25 o C Coercive Field (max) Hc A/m khz, 25 o C 3 Curie Temperature (min) Tc o C 7 Density (min) d kg/m 3 25 o C 49 Temperature Coeff. of permeability (max) F -6 /K -4 to 8 o C 2.5 HM45: Complex permeability vs frequency HM45: Initial permeability vs temperature 4 Flux density (mt) Complex Permeability μ' -----μ" Frequency (khz) HM45: Flux density vs temperature Temperature (ºC) HM45:Relative loss factor vs frequency All measurements made on Toroid OD= 22mm, ID=4mm Ht=6mm.

15 Flux density(mt) Complex permeability Initial permeability MATERIAL GRADE: GQ - 5C GQ - 5C : Wideband Transformer Grade Properties Symbol Unit Test condition Values Initial permeability (±25%) i.mt, 25 o C 5 o 2A/m, 25 C 45 2A/m, o C 3 Relative loss factor tan / i (max) tan / i -6.25mT, khz & 25 o C 3.25mT, khz & 25 o C 5 Coercive Field (max) Hc A/m khz, 25 o C 3 Hysteris material Coefficient (max) B -6 /mt 25 o C.8 Curie Temperature (min) Tc o C 4 Density (min) d kg/m 3 25 o C 49 Temperature Coeff. of permeability (max) F -6 /K -4 to 8 o C 3 Resisitivity (min) m 25 o C Complex permeability vs Frequency Initial permeability vs Temperature μ' μ" Temperature (ºC) Flux density vs Temperature Relative loss factor vs frequency H = 2 A/m Temperature(degC) f(khz) All measurements made on Toroid OD= 3mm, ID=2mm Ht=mm.

16 Initial permeability MATERIAL GRADE: HM - 6 HM - 6 : Wideband Transformer Grade Properties Symbol Unit Test condition Values Initial permeability (±25%) i.mt, 25 o C 6 o 2A/m, 25 C 4 2A/m, o C 24 Relative loss factor tan / i (max) tan / i -6.25mT, khz & 25 o C 5.25mT, khz & 25 o C 4 Coercive Field (max) Hc A/m khz, 25 o C 5 Hysteris material Coefficient (max) B -6 /mt 25 o C.6 Curie Temperature (min) Tc o C 3 Density (min) d kg/m 3 25 o C 49 Temperature Coeff. of permeability (max) F -6 /K -4 to 8 o C 2 Resisitivity (min) m 25 o C.6 HM6: Complex permeability vs Frequency HM6: Initial permeability vs Temperature 2 Flux density (mt) Complex permeability μ' μ" HM6: Saturation flux density vs Temperature H= 2 A/m Temperature (ºC) HM-6: Relative loss factor vs frequency All measurements made on Toroid OD= 3mm, ID=2mm Ht=mm.

17 Flux density (mt) Complex permeability Initial permeability MATERIAL GRADE: HM - 7 HM - 7 : Wideband Transformer Grade Properties Symbol Unit Test condition Values Initial permeability (±25%) i.mt, 25 o C 7 o 2A/m, 25 C 4 2A/m, o C 24 Relative loss factor tan / i (max) tan / i -6.25mT, khz & 25 o C 5.25mT, khz & 25 o C 6 Coercive Field (max) Hc A/m khz, 25 o C 4 Hysteris material Coefficient (max) B -6 /mt 25 o C.5 Curie Temperature (min) Tc o C 2 Density (min) d kg/m 3 25 o C 49 Temperature Coeff. of permeability (max) F -6 /K -4 to 8 o C 2 Resisitivity (min) m 25 o C.5 HM7: Complex permeability vs Frequency HM7: Initial permeability vs Temperature μ' μ" Temperature (ºC) HM7: Flux density vs Temperature HM-7: Relative loss factor vs frequency H=2A/m All measurements made on Toroid OD= 3mm, ID=2mm Ht=mm.

18 Flux density (mt) Complex permeability Initial permeability MATERIAL GRADE: HM - HM - : For Wideband Transformer Application Properties Symbol Unit Test condition Values Initial permeability (±25%) i.mt, 25 o C 2A/m, 25 o C 43 2A/m, o C 24.25mT, khz & 25 o C 3 Relative loss factor tan / i (max) tan / i -6.25mT, khz & 25 o C 2 Curie Temperature (min) Tc o C 2 Density (min) d kg/m 3 25 o C 49 Temperature Coeff. of permeability (max) F -6 /K -4 to 8 o C 2 Resisitivity (min) m 25 o C.5 Complex permeability vs frequency Initial permeability vs temperature μ' μ" Temperature (ºC) Saturation flux density vs temperature Relative loss factor vs frequency All measurements made on Toroid OD= mm, ID=6mm Ht=4mm 6mm Typical Dimension OD = +/-.6mm ID = 6+/-.4mm Ht = 4+/-.2mm 4mm Typical Inductance factor (AL) = 4 +/- % nh mm

19 Flux density (mt) Complex Permeability Initial Permeability MATERIAL GRADE: HT - 8 HT - 8 : Properties Symbol Unit Test condition Values Initial permeability (±25%) i.mt, 25 o C 8 o 2A/m, 25 C 43 2A/m, o C 32 Relative loss factor tan / i (max) tan / i -6.25mT, khz & 25 o C.25mT, khz & 25 o C Coercive Field (max) Hc A/m khz, 25 o C 2 Curie Temperature (min) Tc o C 9 Density (min) d kg/m 3 25 o C 485 Temperature Coeff. of permeability (max) F -6 /K -4 to 8 o C ±3 Resisitivity (min) m 25 o C HT-8: Complex permeability vs frequency HT-8: Initial permeability vs temperature μ' -----μ" Temperature (ºC) HT-8: Flux density vs temperature HT-8: Relative loss factor vs frequency H = 2 A/m All measurements made on Toroid OD= 3mm, ID=2mm Ht=mm.

20 Initial permeability MATERIAL GRADE: HT - 2 HT - 2 : RFID antenna grade Properties Symbol Unit Test condition Values Initial permeability (±25%) i.mt, 25 o C 2 o 2A/m, 25 C 47 2A/m, o C 33 Relative loss factor tan / i (max) tan / i -6.25mT, khz & 25 o C 6.25mT, khz & 25 o C Coercive Field (max) Hc A/m khz, 25 o C 4 Hysteris material Coefficient (max) B -6 /mt 25 o C 2 Curie Temperature (min) Tc o C 7 Density (min) d kg/m 3 25 o C 485 Temperature Coeff. of permeability (max) F -6 /K -4 to 8 o C ±.4 Resisitivity (min) m 25 o C HT-2: Complex permeability vs frequency HT-2: Initial permeability vs temperature 4 Flux density (Bs) Complex permeability 3 2 μ' μ" HT-2: Flux density vs temperature H= 2 A/m Temperature (ºC) HT-2: Relative loss factor vs frequency Temperature (ºC) Frequency (khz) All measurements made on Toroid OD= 3mm, ID=2mm Ht=mm.

21 Permeability Initial Permeability Flux Density (mt) MATERIAL GRADE: HT - 35 HT - 35 : RFID antenna grade Properties Symbol Unit Test condition Values Initial permeability (±25%) i.mt, 25 o C 34 o 2A/m, 25 C 5 2A/m, o C 39 Relative loss factor tan / i (max) tan / i -6.25mT, khz & 25 o C 3 Permanent flux density Br mt 25 o C 9 Coercive force Hc A/m 25 o C Curie Temperature (min) Tc o C 5 Density (min) d kg/m 3 25 o C 48 Temperature Coeff. of permeability (max) F -6 /K -4 to 8 o C 2 Resisitivity (min) m 25 o C HT-35 : Initial Permeability Vs Temperature HT-35 : Flux Density Vs Temperature Temperature ( C) Temperature ( C) HT-35: Complex Permeability Vs Frequency Frequency (KHz) All measurements made on Toroid OD= 3mm, ID=2mm Ht=mm.

22 Flux density (mt) m',m" MATERIAL GRADE: HR - 4 HR - 4 : Ferrite Impeder Grade Properties Symbol Unit Test condition Values Initial permeability (±25%) i.mt, 25 o C 2 2A/m, 25 o C 44 2A/m, o C 35 Coercive Field (max) Hc A/m khz, 25 o C Curie Temperature (min) Tc o C 24 Density (min) d kg/m 3 25 o C 48 Resisitivity (min) m 25 o C 4 Powerloss (max) Pc mw /cc 4kHz/2mT/25 C 4kHz/2mT/ C 7 HR4: Complex permeability vs Frequency Initial permeabiltiy vs temperature 3 μ' μ" Saturation flux density vs temperature H= 2 A/m Relative core loss ( mw/cc) μi Temperature (ºC) Relative core losses vs temperature kHz / 2mT All measurements made on Toroid OD= 3mm, ID=2mm Ht=mm.

23 Flux density (mt) Complex permeability Relative core loss (mw/cc) Initial permeability MATERIAL GRADE: HR - 4B HR - 4B : Ferrite Impeder Grade Properties Symbol Unit Test condition Values Initial permeability (±25%) i.mt, 25 o C 2 2A/m, 25 o C 5 2A/m, o C 4 Coercive Field (max) Hc A/m khz, 25 o C Curie Temperature (min) Tc o C 2 Density (min) d kg/m 3 25 o C 48 Resisitivity (min) m 25 o C 4 Powerloss (max) Pc mw /cc 4kHz/2mT/25 C 8 4kHz/2mT/ C 6 HR4B: Complex permeability vs frequency HR-4B: Initial permeability vs temperature 5 4 μ' μ" f(khz) Temperature (ºC) HR4B: Saturation flux density vs temperature HR4B: Relative core losses vs Temperature H= 2 A/m kHz / 2mT All measurements made on Toroid OD= 3mm, ID=2mm Ht=mm.

24 Initial Permeability MATERIALGRADE: HQ - 23 HQ - 23 : High Q Inductors Properties Symbol Unit Test condition Values Initial permeability (±25%) i.mt, 25 o C 23 o 2A/m, 25 C 42 2A/m, o C 29 Relative loss factor tan / i (max) tan / i -6.25mT, khz & 25 o C 4.25mT, khz & 25 o C 6 Coercive Field (max) Hc A/m khz, 25 o C 25 Curie Temperature (min) Tc o C 7 Density (min) d kg/m 3 25 o C 47 Temperature Coeff. of permeability (max) F -6 /K -4 to 8 o C 3 HQ-23: Complex permeability vs frequency HQ-23: Initial permeability vs temperature Flux density (mt) Complex Permeability μ' -----μ" HQ-23: Flux density vs temperature Temperature (ºC) HQ-23: Relative loss factor vs frequency All measurements made on Toroid OD= 3mm, ID=2mm Ht=mm.

25 E E CORES Application of EE Cores Small E Core Impedance matching tranformer For Miniature Tranformers SMD Tranformers Large E Core Commom mode choke and broadband transformers For SMPS Energy storage chokes B F E D A C DIMENSIONS Le Ae Ve AL VALUE ( ±25%) Almin Approx wt Type A(mm) B(mm) C(mm) D(mm) E (mm) F (mm) mm mm 2 mm 3 MSB-5S MSB-7C MGQ5C HP 4 gms/pair E/6/ EE8/38/2 8. ± ± ± Min 9.8 ± ± EE7/33/ ± EE 65X33X EE 65X33X EE 55X27X EE 42X2X EE 42X2X EE 42X2X EE 4X7X EE 36XX ± EE 35X4X ±.7 4.5± ± ± ±.25.± EE 33X6X3 33.± min EE33X4X3 33.± min EE33X5X7 3.5± min EE 25X3X ± EE 25X6X min EE 25X3X EE 25X9X ± EE2XX5 2.5± EE2XX5-M EE 9X8X5 9.3 ± ± ± ± EE6X2X5 6. ± ± ± ±.3.4 ± EE6X8X EE `± ± ±

26 EER, EC, ETD, EED, EEH CORES Application of EER,EC, ETD, EED, EEH For High inductance and low height Compact Transformers Compact winding design with low leakage currents A E D Flyback converter for TV and monitors Switch mode power supplies Constant area of cross section along the magnetic path F B C DIMENSIONS Type A(mm) B(mm) C(mm) D(mm) E (mm) F (mm) EC ± ±.3.3 ± /-.3 ± ±.3 EC4A 4. ± ± ± /- 3.3 ± ±.3 EC4B 4. ± ± ± /- 3.3 ± ±.3 EC4C 4. ± ± ± /- 3.3 ± ±.3 EC ± / ± Min / ±.3 EC9 9. ± ±. 7. ±.5 3. ±. 35. ±.5 EC2 2. ± ±.5 3. ±.5 9. Min 3. ± ±.5 EER ± ±. 4.9 ±. 7.5 Min 3.4 ±..675 ±.5 EER5.85 ± ±. 5.9 ± ± ± ±. EER ± ±.2 5. ± ± ± ±.5 EER ±.5. ± ± Min 7.5 ± ±.2 EER28-A / /-.6.4 ± /- 9.9 ± /- EER28-B 28.5 ± /-.6.4 ± /- 9.9 ± /- EER28-C / /-.4 ± /- 9.9 ± /- EER39 3. ± ±.2.3 ± Min.3 ±.2.8 ±.3 EER42X ± ± ± ± ± ±.5/ EER42X / ± ± ± ± ±.2 ETD / / / / / /- ETD / /-.4. +/ /-. +/ /- ETD / / / / / /- ETD / / / / / ±.5 ETD ± ± ± ± ± ±.4 ETD / / / ±.8/ 6.7 +/ /-. ETD ± / ± ±. 8.9 ± ±.4 ETD ± / / / / /- EEH ±.3.2 ±.2.9 ± Min 8.5 ± ±. EEH ± ±.2.6 ± Min 8.4 ±.2.5 ±.2 EEH ±.3.5 ±.2 3 ± Min.5 ± ±.5 EE ± ± ± Min 4.8 ± ±.3

27 EER, EC, ETD, EED, EEH CORES Type Wt (gm) Le (mm) Ae (mm 2 ) Ve (mm 3 ) AL± 25% EC EC4A EC4B EC4 C EC EC EC EER EER EER EER EER28-A EER28-B EER28-C EER EER42X EER42X ETD ETD ETD ETD ETD ETD ETD ETD EEH EEH EEH EER42/

28 EI CORES Application od EI cores Transformers for SMPS Impedance matching Transformers Miniature and SMD transformers B E D A F G C DIMENSIONS Type A(mm) B(mm) C(mm) D(mm) E (mm) F (mm) G(mm) EI64 6 ± ± Min 3.8 ±.2.4 ±.2 2 ±.2 EI ± Min 5. +/-.5.5 ± ±.2 EI ±.6 9 ± Min 6. +/-.5 ±.3 4. ±.3 EI ± Min 6.5 ± ±.3 EI ± Min ±.3 EI282 A 28. ± ± Min ± ±.3 EI ±.2 EI ± ± Min ±.3 EI Min ± EI ± ±.3 EI ± ± ± ±.25 EI ± ±. 9.5 ±.5 5. ± ± ±.5.5 ±.5

29 EI CORES EFFECTIVE PARAMETERS Type Wt set Le Ae Ve AL± 25% Gm mm mm 2 mm 3 MSB7C MSB5S EI EI EI EI EI EI282 A min InMGQ5C EI EI EI EI EI EI AL Values : nh ±25% KHz.V Ts

30 EFD CORES Application of EFD cores For DC- DC Converter For flat transformers of Lower center leg Optimized cross section of Legs Good thermal response in case of Flat type EFD due optimised distribution of Cross section E D A G F B C DIMENSIONS Type A(mm) B(mm) C(mm) D(mm) E (mm) F (mm) G(mm) EFD.5 ± ±. 2.7 ± ± ± ±.5.45 ±.5 EFD22 25 ±. 6.2 ±. 3.5 ±. 9. ± ± ±.5 2. ±. EFD55 5. ± ± ±.5. ± ± ± ±. EFD22 2 ±.55. ± ± ± ± ± ±.5 EFD ± ±.5 9. ± ±.6.4 ± ± ±.5 EFD33 3. ±.8 5. ±.2 9. ± ± ±.25.2 ± ±.5 EFD ±.8 5. ±.5 8. ± ±.6 6. ±.3. ±.5 5. ±.5 EFFECTIVE PARAMETERS Type Wt set gm Le mm Ae mm 2 Ve mm 3 AL± 25% HP4 EFD EFD EFD EFD EFD EFD EFD AL Values : nh ± 25% KHz.V Ts SOFT FERRITE CORE PRODUCT GUIDE 3

31 EP CORES Application od EP cores For power application Excellent properties for broadband transformers For Transformers featuring high Inductance and Low height Excellent magnetic sheilding B C E D A F DIMENSIONS Type A(mm) B(mm) C(mm) D(mm) E (mm) F (mm) EP5 6. ± ± ±. 4.4 ±.5.7 ±. 2 ±. EP ± EP.5 ±.3 5. ±. 7.6 ± ± ± ±. EP EP7 8. ± ± ± ± ±.5 EP2 24. ±.5.7 ±. 5. ± ± ± ±.5 EFFECTIVE PARAMETERS Type Wt set gm Le mm Ae mm 2 Ve AL± 25% mm 3 HP4 EP EP EP EP EP EP AL Values : nh ± 25% KHz.V Ts SOFT FERRITE CORE PRODUCT GUIDE 32

32 EPC CORES Application od EPC cores For DC- DC Converter For flat transformers of Lower center leg A E D Optimized cros section of Legs EMI Suppression Chokes Good thermal response F B C DIMENSIONS Type A(mm) B(mm C(mm) D(mm) E(mm) (mm) EPC ± ± ± Min 5.6 ± ±.2 EPC ± ±.2 6. ±.2 2 ± ± ±.2 EPC92 9. ± ±.2 6. ±.5 3. Min 8.5 ± /-. EPC ± ± ± Min 9.5 ±.5.55 ±.5 EPC ± ± ± ± Min.55 ±.5 EPC ± ±.25 FQKT ±.3 2. ±.2 8. ± ± ±.4.5 ± ± ±. 9. ± /-. FQT ±.3.8 ±. FQKT8 8. ±.3.8 ± ± ± ±.5. ± ± ±.5.8 ± ±.5 EFFECTIVE PARAMETERS Type Wt / set Le Ae Ve Al± 25% gm mm mm 2 mm 3 Hp4 EPC EPC EPC EPC EPC EPC FQKT FQKT FQKT AL Values : nh ± 25% KHz.V Ts SOFT FERRITE CORE PRODUCT GUIDE 33

33 EPC CORES Application od PQ cores Compact Transformers Low distortion broadband transmission at low signal DC/DC Converters E D A F C B DIMENSIONS Type A(mm) B(mm) C(mm) D(mm) E (mm) F (mm) PQ ±.4. ±. 4. ±.4 8. ± ± ±.2 PQ ± ± ± ± ± ±.5 PQ ± ± ± ± ± ±.25 PQ ±.5.55 ± ± ± ± ±.2 PQ ± ± ± ± ± ±.2 PQ ± ± ±.5 32 ± ± ±.5 PQ ±.9 2. ± ± ± ± ±.2 PQ55 5. ±.7 25 ± ± ±.7 2. ± ±.3 EFFECTIVE PARAMETERS Type Wt / set Le Ae Ve AL gm mm mm 2 mm 3 HP4 PQ PQ PQ PQ322D PQ323D PQ PQ PQ SOFT FERRITE CORE PRODUCT GUIDE 34

34 RM CORES Application of RM cores Compact design Low distortion broadband transmission at low signal DC/DC Converters D A C E F B Type A(mm) B(mm) C(mm) D(mm) E (mm) F (mm) RM ±.5 RM5 4.9 max 5.2 ±.5 RM6 RM8 RM RM2 RM ± ± ± ± ± EFFECTIVE PARAMETERS Type Wt set Le Ae Ve AL gm mm mm 2 mm 3 HP4 RM RM RM RM RM RM RM AL Values : nh ± 25% KHz.V Ts SOFT FERRITE CORE PRODUCT GUIDE 35

35 PLANNER CORES Application of Planar cores Low profile core High AL Value High core surface to volume ratio Excellent thermal performance High output currents at low output voltage Good EMC characteristics A D E F C G B DIMENSIONS Type A(mm) B(mm) C(mm) D(mm) E (mm) F (mm) G(mm) PEE47 4. ± ±. 5. ±.. ± ±.5 2. ±. --- PEE88 8. ± ±.2 4. ±.3 4. ±. 2. ±. --- PEE ± ±. 5.8 ± ±.4 5. ±. 3.2 ±. --- PEI45 4. ± ±. 5. ±.. ± ±.5 2. ±..5 ±.5 PEI86 8. ± ±.. ±.2 4. ±.3 4. ±. 2. ±. 2. ±.5 PEI ± ±. 5.8 ± ±.4 5. ±. 3.2 ±. 2.5 ±.5 PEE ±.3.2± ± ±..2 ±.2 5. ± EFFECTIVE PARAMETERS Type Wt set Le Ae Ve AL±25% gm mm mm 2 mm 3 HP4 PEE PEE PEE PEI PEI PEI PEE AL Values : nh ± 25% KHz.V Ts SOFT FERRITE CORE PRODUCT GUIDE 36

36 UU AND UI CORES Application of U Cores Pulse and High Voltage Transformer Line Deflection transformers Energy storage chokes common chokes Suppression for Line Filter DIMENSIONS Type A(mm) B(mm) C(mm) D(mm) E (mm) UU. ± ± / / ±.6 UU.5.5 ± ± ± /-..6 ±.3 UU 44 4 ± ± ± Ref 8.4 ±.4 UU ± / / ± /- UU 6 6. ± ±.6 6. ± ±.3 2. ±.7 UU 2 2. ± ±.5 6. ±.2 8. ± ±.5 UU 2 2. ± / ± ± UU ± / ± ± UU ± 79 ±.5 28 ± min 5 ±. UU ±.6 98 ±. 2 ±.5 4 ±.8 58 ±. UU 93X6 93. ± ±. 6. ± ± ±.8 UU 93X3 93. ± ±. 3. ± ± ±.8 UU.6 ± ± ± ± ±.5 UU ± ±. 2. ±.6 7. ±. 62. Min I X ± ± ± I 93X3 93. ± ±.5 3. ± I ± ±.5 2. ± EFFECTIVE PARAMETERS Type Le Ae Ve AL±25% Wt cm cm 2 cm 3 MSB5S MGQ5C MSB7C UU UU min --- UU UU min --- UU min --- UU min --- UU min --- UU UU UU mm UU 93X UU 93X UU UU I x I 93x I SOFT FERRITE CORE PRODUCT GUIDE 37

37 COLOUR F B T CORES Application of FBT Storage choke Interference suppression component High saturation reponse, low loss and high Tc A D F E C B DIMENSIONS PART NO. A(mm) B(mm) C(mm) D(mm) E (mm) F (mm) Le Ae Ve Approx. wt. Cm Cm 2 Cm 3 gms / pair FUT ± ± min 25.5 ± ± FUT ±.3.9 min 35. ±.6. ± FUT ± ± min 48. ± ± FUT ± min 5. ± ± FUT ± ± min 37. ±.6.5 ± FUT ± min 42.6 ±.6.7 ± mm Ø -.3 FUT ± ± min 4.7 ±.5.5 ± mm Ø -.3 FUT ± ±.5 4. ± min 5. ±.5.3 ± FUT ± ± ± min 34.4 ±.6.5 ± FUT ± ± min 4.2 ±.6.5 ± FUT ±.6 4. ± min 4. ±.6.5 nom FUT ±.6 4. ± min nom FUT ±.6 4. ± min ± FUT ± ±.6 5. ± min 52. ±.6 2. nom FUT ± ±.6 3. ±.3 3. min 3. ± ± FUT ± ± ±.3 5. min 5. ± ± These cores are available in MSB 7C & MSB 5F(H) grade. SOFT FERRITE CORE PRODUCT GUIDE 38

38 FERRITE BAR Application of Ferrite Bars For Induction Heating For Tyre pressure and Keyless Entry application For EMI Absorption A C A B B E D C DIMENSIONS Type A(mm) B(mm) C(mm) D(mm) E (mm) WT/ set Fbar 79/23/4 79 ± ±.5 4 ± Fbar 79/23/4 79 ±.8 9 ±.4 4 ± Fbar 64// ± ± ± Fbar 64/23/ ± ± ± Fbar 62/3/4 62. ±.6 3. ±.5 4. ± Fbar 6/23/4 6. ± ±.4 4. ± Fbar 55/23/4 55. ± ± ± Fbar 42/23/4 42. ± ± ± Fbar 36/28/4 36. ±.6 28 ±.5 4. ± Fbar 32/26/4 32. ± ± CFbar 88/44/4 88. ± ±.6 4. ± ±.6 3. ± CFbar 62/3/4 62. ±.7 3. ±.5 4. ±.2 6. ±.3 8. ± SOFT FERRITE CORE PRODUCT GUIDE 39

39 TOROID Application of Toroid Common mode choke Interference suppression for line filter Signal transformer Highest permeabilty for volume Gapped Torroid A C DIMENSIONS TYPE ØA(mm) ØB(mm) C(mm) Le Ae Ve AL (± 25%) AL min Approx wt. Cm 2 Cm 2 Cm 2 Cm 2 MSB-5S MGQ5C gms/pc T.. ±.6 6. ±.2 3. ± T.. ±.6 6. ±.2 4. ± T ± ±.4 5. ± T ± ± ± T ± ± ± T ±.4. ± ± T ±.6.5 ±.4 8. ± T ±.5. ±.4 8. ± T ±.5 3. ± ± T ±.6 5. ±.5. ± T ±.6 5. ±.5 2. ± T ± ± ± T ± ± ± T ±. 9. ± ± T ± ±.5 7. ± T ±. 23. ±.6 5. ± T ± ±.8. ± T 5 5. ±. 3. ±.8 2. ± T ±. 4.8 ± ± T ±.3 38 ± ± Note : Epoxy coated Toroids in above types also can be made available. SOFT FERRITE CORE PRODUCT GUIDE 4

40 DRUM CORES - OWD Application of Small Rods Crossover network Filters B E D A C C DIMENSIONS TYPE A(mm) B(mm) C(mm) D(mm) E(mm) OWD 22X5 22. ±. 6.4 ± ± OWD 22X2 22. ±. 2.4 ± ± OWD 28X2 28. ±. 2.7 ± ± OWD 28X ± ± ± OWD 35X ± ± ± OWD 4X25 4. ±. 26. ± OWD 4X ±. 36. ± ± ± OWD 56X ± ± ± SOFT FERRITE CORE PRODUCT GUIDE 4

41 SMALL RODS AND TUBE / BEADS Application of Small Rods Application of Small Rods For Antennae For Choke and Filter For small Signal Transformers A B DIMENSIONS Type OD(mm) Length(mm) 3x ± ±.5 3.8X ± ±.5 3.2X9 3.2 ±.3 9. ± X ± ± X ±.3 5. ±.5 5x2 5. ±.3 2. ±.5 5x 5. ±.3 ±.5 6x2 6. ±.3 2 ± X ± ± X ± ± X ± ± X ± ± X ± ± X ± ±.5 DIMENSIONS Type OD(mm) ID(mm) Length(mm) 4X2X2 4 ±.2 2. ±.2 2. ±.5 5X2.5X2 5 ± ±.3 2. ±.5 6X3X2 6 ±.3 3. ±.2 2. ±.5 7X3X2 7 ±.3 3. ±.2 2. ±.5 8X3X2 8 ±.3 3. ±.2 2. ±.5 X5X2 ±.4 5. ±.3 2. ±.5 7.9X ± ±.5 9.5X ± ± X ± ± X2 2.7 ±.4 2. ±. 2.7X5 2.7 ±.4 5. ±. 2.7X ± ±.5 2.7X ±.4.6 ± O.5 2.7X ± ±.5 2.7X ± ±.5 5.9X ± ±.5 9.5x ± ±. SOFT FERRITE CORE PRODUCT GUIDE 42

42 Distributor Parker Electronics Pvt. Ltd; A - 26, Lane No. 2, Shakarpur, Vikas Marg, Delhi - 92 (INDIA) Phone No: , Corp. Office:- 59//, Industrial Area, Site - IV, Sahibabad, Distt. Ghaziabad, U.P.(INDIA) Phone: Fax : SOFT FERRITE CORE PRODUCT GUIDE 43