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Ferrite Core Manufacturing Process


Ferrite

Ferrite is a ceramic compound which contains mixture of iron oxides and one or some times more than one metal with ferrimagnetic properties.

More details on ferrite you can find in my previous blog;
"Ferrite, Ferrite structure and Ferrite properties".


Ferrite Core

A ferrite core is a kind of magnetic core, which is made up of ferrite. On ferrite cores the windings of switching transformers and other types of wound components like inductors are made. It is used because of its properties of high magnetic permeability, which is coupled with low electrical conductivity. This will helps to prevent eddy currents.

There are two extensive uses of ferrite cores according to size and frequency of operation;
  1. Signal transformers - These are of small size and supports high frequencies.
  2. Power transformers - These are of large size and supports lower frequencies.
Below picture shows different types and shapes of ferrite cores;

Ferrite Cores
Different Types and Shapes of Ferrite Cores

Ferrite Core Manufacturing Process

Below steps will clear in detail the ferrite core manufacturing process;
  • Normal ceramic methods are used for manufacturing of Ferrite, i.e. here processing deals with the composition of iron oxide mixed with oxides of manganese + zinc or nickel + zinc.
  • Different process involves; predefined molar ratio based raw material mix, calcination process to achieve constant physical properties, then milling process, pressing to the desired shape, sintering and final finishing.
  • Chemistry and development conditions affect the final properties of ferrite as, both conditions controls the microstructure formation, which deals with magnetic and mechanical properties of ferrite.
  • In simple words we can say that ferrite making process is same like most ceramic process technologies. We can divide Ferrite Core Manufacturing Process into four main tasks;
  1. Powder preparation
  2. Pressing 
  3. Sintering Process
  4. Ferrite finishing
Let explain these tasks in detail;

1. Powder preparation 

  • The first step in the manufacturing of powder starts with the chemical study of the raw materials i.e. study of the oxides or carbonates of the main ingredients. 
  • The pureness of these constituents adds a plus point directly to the quality of the finishing product and required to be controlled to guarantee a batch-to-batch steadiness.
  • The precise amount of the main constituents is weighed and carefully mixed into a homogeneous mixture.
  • This mixing can be done in a dry method, or water can be added to make slurry and then mixed in a ball mill.
  • When wet mixing is used, a drying method is necessary to decrease the moisture content before to calcining process.
  • Calcining is a pre-firing method in which the powder temperature is increased to about 1000°C in an air atmosphere.
  • During the calcining there is a little decomposition of the carbonates and oxides, evaporation of volatile impurities and a homogenation of the powder mixture.
  • There is a degree of spine1 conversion throughout calcining and this pre-firing step also decreases the shrinkage in the final sintering.
  • After calcining the powder is mixed with water and the slurry is milled to get small and constant particle sizes.
  • At this phase of the process, binders and lubricants are added. The nature of lubricant and binder is decided by the forming technology.
  • The last stage in the powder preparation is to spray dry the slurry in a spray dryer.

2. Forming or Pressing

  • It is the second stage in the ferrite processing technology and deals with the forming of the ferrite.
  • The mostly used method is “dry pressing” to convert powder into the core shape.
  • Other methods are “extruding” and “isostatic pressing”.
  • Dry pressing or compacting is done using a joint act of top and bottom punches in a cavity such that a part of uniform density is made.
  • As compacting is only along the vertical axis, the only size modification can be done at the press height.
  • Isostatic pressing generally uses flexible bowls, such as thick rubber molds, which have very simple shapes likes blocks, rods, discs, etc.
  • In Isostatic press the bowl is filled with non-bindered powder, sealed, and positioned inside a pressure chamber or vessel.
  • Then the pressure is increased to a particular level, usually 10K psi to 30K psi, and then decreased.
  • The bowl is then detached from the vessel, unsealed and the pressed form is taken out, which will further forward for sintering.
  • Organic binder is not used in this method because of the incompatibility between the rate at which the binder is burned out during sintering and the shrinkage that is arising at the same time.
  • This incompatibility results in the product breaking. Isostatic pressing produces material with fixed density, which is suitable for machining into difficult geometrical sizes.
  • This method is appreciated for prototype designing, in which no dry press moulds are available.
  • This method can also create geometrical size that cannot be formed using regular pressing methods such as big core volume or non-pressable difficult shapes.
  • Extruding method is normally used to form long, small cross section ferrite parts such as rods and tubes.
  • The spray dried powder is mixed with a nourishing plasticizer that permits the powder to be forced through the suitable extruding die.
  • In all of the above forming techniques the sizes of the forming tool or mould must be bigger than the final product sizes by a pre-calculated factor that permits for shrinkage while sintering.


3. Sintering Process

  • This is the most critical stage in the manufacturing of ferrite cores.
  • In this process the product attains its final magnetic and mechanical features.
  • Sintering of manganese-zinc ferrites needs symmetry between time, temperature and atmosphere along each stage of the sintering cycle.
  • Sintering starts with a slow ramping up from room temperature to nearly 800°C where impurities, residual moisture, binders, and lubricants are burned out of the ferrite product.
  • In this part of the sintering cycle the atmosphere is air. The temperature is more increased to achieve the final sinter temperature of 1000°C - 1500°C, depending on the material type.
  • When the temperature is increasing, a non-oxidizing gas like nitrogen is introduced into the kiln to decrease the oxygen content of the kiln atmosphere.
  • A decrease of oxygen pressure is very critical during the cool-down cycle in obtaining high quality MnZn ferrite cores.
  • At lower temperatures of 1000°C-1200°C, the sintering of nickel-zinc ferrites occurs.
  • The nickel-zinc material can be sintered in an air atmosphere. During sintering the ferrite parts shrinks to required final dimensions.
  • Different material and processing methods results in change of the shrinkage of geometry size, but usual shrinkage ranges from 10% to 20% of the moulded sizes.
  • The final ferrite part size includes mechanical tolerances of +2% of the nominal part size.
Figure at below shows a usual manganese-zinc sintering cycle in a tunnel kiln.


4. Finishing

  • This is after sintering process. Most of the ferrite parts require some way of finishing process to meet customer requirements.
  • Although the basic magnetic characteristics are been set during sintering and cannot be change. Proper finishing methods can enhance the magnetic performance of ferrite cores. Below are some common processes;
Gapping
  • There are two known methods for specifying a gap in ferrite core. First one is by specifying an AL value and the second is to specify a mechanical gap length.
  • In simple words, less gap then less AL value.
Coating
  • To enhance dielectric resistance, to reduce edge chips, and to provide a smooth winding surface; coating of toroid is done. 
  • Nylon, epoxy paint and parylene are the types of coatings. 
  • The nylon and epoxy paint normally needs a minimum coating thickness of .005” to confirm uniform safety. Because of this, these coatings are used mainly on toroid’s that have outer diameters of .500” or more. 
  • Coating colour can be used for material identification instead of using any type of marking. 
  • Per .003” of coating the breakdown voltages is 500V to 1000V. 
  • Parylene used on toroid with outer diameter less than .500” because of the high cost of the raw material. Parylene is a colour less coating. 
  • Higher voltage breakdown of approximately 1000 volts per .001” is achievable with parylene. A thickness of .0005” also provides uniform protection. 
Lapping
  • Lapping is an extra production method used to decrease the results of an air gap on mated cores, typically done on mated cores with material permeability’s over 5000 to achieve the maximum AL value for a given material. 
  • This method includes polishing the mating surface of the core after grinding by using slurry media. 
  • By this a “mirror-like” finish will be formed on ferrite core. 
  • It is necessary for accurate control of flatness and appearance of the mating surface. 
Grinding
  • Grinding (machining) is done to obtain the specified dimensions by grinding the cores with a diamond wheel. 
  • In this process water is used as coolant to avoid cracks. 
  • Grinding wheel types : Silicon Carbide Grinding wheels, Diamond-impregnated metal-bonded grinding wheel, Diamond-impregnated resin-bonded grinding wheel, Resin and metal (resmet) bonded diamond-impregnated grinding wheel, Galvanic bonded diamond grinding wheel, Cubic boron nitride (cbn) grinding wheel. 

Below are the additional finishing operations which can be performed on ferrite cores;
  • To obtain tight mechanical tolerances surface grinding should be perform. 
  • Identification marking. 
  • Cementing wires for identification purpose. 
  • Gapping to Control AL value.
  • Cutting rods and tubes of beads on wire.
  • Shape grinding of threaded cores.
  • Packaging for automated assembly requirements.
  • In pot cores and RM cores to install tuner nuts.
Now as per above mentioned four main tasks, we can draw a flowchart which shows the Ferrite Core Manufacturing Process in detail;

Ferrite

Let understand each flowchart steps in detail;
1) Raw Materials  In required pureness and physical properties raw material is selected.

2) Weighing  To get the required chemical properties, weighing to be done in proportion to the mole ratio.

3) Mixing  To achieve the uniformity mixing should be properly done, which will result in effective chemical reaction.

4) Calcination – Calcination is done to get the required ferrite formation by adjusting the furnace condition.

5) Crushing – Crushing is done to suit further milling. It is done by crushing the calcined material.

6) Additives – This process is for altering magnetic properties.

7) Milling – This process is done to get fine particle to control shrinkage and microstructure.

8) Binder/Lubricant Addition - To get sufficient mechanical strength to the green body a binder or a lubricant is added. Binder should to be add in proper amount in the material.

9) Granulation – This process is for achieving free flowing of powder. By this the powder can easily flow in to die or mould part.

10) Pressing – Pressing is done to get the required size and shape as per specification. The size is adjusted again and again at the time of green core pressing in accordance to the shrinkage of powder.

11) Sintering – As per desired specifications sintering is done to attain the required magnetic, electrical and mechanical properties of the ferrite core.

12) Grinding and Polishing – Surface grinding is done to control the dimensions of ferrite core to match the close tolerance. Polishing is done to takeout unwanted materials from ferrite core surface and to give a shining surface.

13) Marking and Packaging – These are final processes. Marking is done for identification of ferrite types, manufacturing details and other important details. After this ferrites are packed properly and are ready for dispatch.


Conclusion

Ferrites are most important part of an electronic circuit. Manufacturers produce ferrite cores with different types of materials and in a variety of shapes or geometrical sizes according to the applications. Ferrite Core Manufacturing Process includes many methods to achieve uniform magnetic and mechanical characteristics. With the enhancement of manufacturing technology and cost reduction factor forcing manufacturers to adopt various methods to ease the ferrite manufacturing process, but the main components of manufacturing will remain same as mentioned in this article.

11 Comments

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Sachin dave
AUTHOR
May 23, 2019 at 9:51 PM delete

Hi...
I wanna know about ferrite core CT and core manufacturing . Plz help me in this

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Admin
AUTHOR
June 11, 2019 at 3:12 AM delete

Thanks for comment. This article "Ferrite Core Manufacturing Process" on my website, "www.powerelectronicstalks.com" you can refer for ferrite core manufacturing. Each and every detail is given in this article.

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Unknown
AUTHOR
May 29, 2020 at 2:56 AM delete

Great article, this helps me a lot!!

For my understanding; the milling step is applied to compensate for material shrinking? I am looking to manufacture round ferrite cores with a gap (in which I can place a hall sensor to measure current). As I understand from the article the gap should be added by means of machining after the sintering process? Am I correct?

Thanks again!

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Unknown
AUTHOR
May 29, 2020 at 3:00 AM delete

Addition;
The tolerance of the gap is quite narrow, 0.02mm. Is that tolerance feasible by sintering process, or shall the rings be machined anyway to obtain this level of detail?

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Admin
AUTHOR
June 4, 2020 at 2:38 AM delete

Yes you are correct, after sintering the gap creation takes place. It's not possible before sintering i.e. at green core stage because at sintering process the core will shrink so, your core gap length will vary.

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Unknown
AUTHOR
June 6, 2020 at 7:12 PM delete

Thanks for your reply, Best!

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Admin
AUTHOR
July 1, 2020 at 10:02 PM delete

Even for achieving small gap, proceed for grinding after sintering.

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Unknown
AUTHOR
February 13, 2021 at 8:06 AM delete

How we can reduce the bending in small geometry

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Admin
AUTHOR
February 23, 2021 at 2:28 AM delete

You can control bending by controlling the sintering temperature.

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May 19, 2021 at 11:52 PM delete

Why do both diameters and height usually have relatively high tolerances?
(e.g. outer diameter 42+/-0.8mm ; inner diameter 26.0 +/-0.5mm ; height 18.0 +/-0.5mm)
Sintered steel parts reach much lower tolerances.
What tolerances can be achieved within reasonable cost?

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Admin
AUTHOR
May 25, 2021 at 11:54 PM delete

Dear Christian,
Tolerance totally depends upon sintering profile and on materials. Here in soft ferrites, granules are made up of MnZn and NiZn. While making material powder, the dimensions of granules are not even that's why tolerance range is high. Even at final sintering the temperature is not constant, which also affects tolerance.

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