1. DIELECTRIC HEATING KUMAR CHATURVEDULA

2. DIELECTRIC HEATING KUMAR CHATURVEDULA Dielectric heating, also known as electronic heating, RF heating, high-frequency heating and diathermy. Dielectric heating is a special way of transforming electric current into heat. By the method of dielectric heating, generally, foils, plates and profiles with a thickness of 0,1-2,0 mm is are welded. RF

3. DIELECTRIC HEATING KUMAR CHATURVEDULA We understand dielectric heating as the generation of thermal energy (heat) in a non-conducting material by the application of an electromagnetic force or field t it. This is the way a microwave oven heats things placed in it. Wasted energy appears as heat called dielectric loss. The non metallic material with poor thermal conductivity can be very effectively heated by dielectric heating. Dielectric loss is proportional to frequency and square of the supply voltage. Frequency can be selected between 10 to 30kHz and voltage about 20kV

4. . When a solid dielectric material (Insulating) is subjected to an alternating electric field, it is not supposed to carry any current. However, in practice some leakage current passes through it and power loss is takes place. This loss is called as dielectric loss and result into heating of dielectric material.

5. APPLICATION OF DIELECTRIC HEATING KUMAR CHATURVEDULA  Plywood Industry  Sand Core Baking  Plastic Industry  Tobacco Industry  Bakeries  Electronic Sawing  Dehydration of food  Electro medical application  Book Binding

6. Advantages of Dielectric heating KUMAR CHATURVEDULA 1) Heating is very quick 2) The efficiency is higher 3) Heating is uniform 4) Being free from smoke, dust, process is very clean 5) There are no flue gases, no risk of pollution 6) Heat is produced due to dielectric loss occurs in the material itself

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8. ARC HEATING KUMAR CHATURVEDULA One of the popular method of heating. Principle:- When voltage is applied between the two electrodes separated by small distance in air is increased, a stage is reached when the air gets ionized and air act like conductingmedium. Hence, current flows between the electrodes in the form of continuous spark called ARC. This self sustained discharge of electricity between 2 electrodes through air is known as “Electric ARC”.

9. An ARC drawn between 2 electrodes has a temperature between 3000°C to 3500°C depending upon the electrode material. ARC Heating Types:- 1) Direct ARC heating 2) Indirect ARC heating KUMAR CHATURVEDULA

10. Direct ARC Furnance KUMAR CHATURVEDULA

11.  Direct ARC :- ARC is established between the charge and the electrode. The heat is directly conducted to the charge which charge absorb. Hence, this method is called Direct ARC heating. This consist of Carbon or Graphite electrode. The power is controlled by adjusting the ARC length by moving the electrodes manually or automatically. KUMAR CHATURVEDULA

12. USE (Direct ARC) 1) Making of Alloy steels like stainless and high speed steel 2) Composition can be controlled during refining process. Direct ARC operates at 0.8 p.f. Lagging KUMAR CHATURVEDULA

13. INDIRECT ARC: KUMAR CHATURVEDULA

14. INDIRECT ARC: ARC is formed between two electrodes and heat is transmitted to the charge by radiation. Lower temperature than direct ARC. It Operates at 0.85 p.f. lagging have to provide rocking motion through a motor to distribute heat uniformly. USE:- melting non-ferrous metals. KUMAR CHATURVEDULA

15. Due to application of sufficiently high voltage across an air gap causes the air in the gap to get ionized and forms ARC ARC drawn between two electrodes develop high temperature (3000°C-3500°C)depending upon material ARC may be used in following ways: by striking between charge and electrodes- principle behind Direct ARC Furnace by striking between two electrodes principle behind Indirect ARC Furnace by striking between an electrode and the two metallic pieces to be joined - principle behind ARC welding KUMAR CHATURVEDULA

16. SUBMERGED ARC FURNACE KUMAR CHATURVEDULA

17. ARC is formed between carbon electrodes placed at top and earth electrode or the conducting earth itself. Number of electrodes depends on type of supply. Power is controlled by varying supply or varying distance between electrodes. Better mixing of Charge. P.f. is 0.8 Lagging USE:- Manufacturing of ferro-chrome and ferro- manganese KUMAR CHATURVEDULA

18. Principle of transformers In the transformer, supply is utilized by secondary.

19. Induction method is based on Principle of “Electromagnetic Induction” When alternating Current flows in a conductor it produces alternating flux. If any other conducting material is placed in this magnetic flux emf gets induced in it This induced emf drives eddy current in that piece and power loss due to eddy current appears as heat.

20. Factors for Induction heating:- 1) it is proportional to relative permeability. Heating produced in magnetic material is more than non magnetic material. 2) Heating is proportional to MMF. Force can be vary by changing current or number of turns. 3) Heating effect can be increased by employing high frequency supply.

21. DIRECT INDUCTION HEATING KUMAR CHATURVEDULA In this, currents are induced in the charge itself. This is usually used in furnaces for smelting (extraction of metal from ore), melting of metals etc. This requires very high frequency supply. They are classified as core and coreless type induction furnaces.

22. INDIRECT INDUCTION HEATING (Example :- Oven) In this, eddy currents are induced in the heating element. Thus heat produced by heating element is then transferred to the charge by radiation or convection. KUMAR CHATURVEDULA

23.  Secondary winding is metal container. Below part is situated in the oven chamber which is made up of special alloy which losses its magnetic property and regain when they cooled. KUMAR CHATURVEDULA

24. Operation When the primary winding is connected to the supply, the eddy currents gets induced in the metal container forming the walls of the oven. Due to eddy currents, metal container gets heated and then is transferred to the charge by radiation. ACTION OF SPECIAL ALLOY:- Oven reaches its critical temperature. Magnetic circuit looses its magnetic property. Due to this reluctance of the magnetic circuit becomes very high and inductive effect corrosponding decreases.

25. Advantages:- Limitations:- Applications:- KUMAR CHATURVEDULA 1)Simple and foolproof method of temperature control 2)No external temperature control equipments required 1)Poor Power factor 2)Complicated Construction It is used for general heat treatment of metallic and other charges.

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