NAME: MOHAMMAD UMAIR ANSARI

1. NAME: MOHAMMAD UMAIR ANSARI • TOPIC: ELECTRO CHEMICAL MACHINING • BRANCH: MECHANICAL • SUBJECT: UCMP • YEAR : 4-1 UMAIR ANSARI

2. ELECTRO CHEMICAL MACHINING UMAIR ANSARI

3. As the name indicates it is the combination of electrical and chemical energy used for machining. • It works on the faraday’s law of electrolysis. Need for ECM • hard & difficult to shape metals cannot be easily machined by conventional methods. UMAIR ANSARI

4. It is characterized as reverse electroplating process • It removes material instead of depositing it. • ECM process makes use of an electrolyte & high electric current to ionize & remove metal atoms UMAIR ANSARI

5. Elements or parts of ECM Process • The equipment mainly consist of following parts. • Cathode tool (-ve terminal) • Anode work piece (+ve terminal) • DC power & Control system • Electrolyte UMAIR ANSARI

6. Cathode tool(-ve): the shape of the tool should be similar to the shape desired in the work piece. A round shaped tool will produce a round hole in the work piece, a square shaped tool produces a square hole & so on. • Since a small gap has to be left between the work piece & the tool for the electrolyte to flow • A standard overcut includes 0.76mm over all active surfaces UMAIR ANSARI

7. The material selected for the tool should be easily machinable,exhibit good stiffness to resist high electrolyte pressures, resist chemical action, & good electrical and thermal conductor • The material that find wide applications in the manufacture of tools are Aluminium,brass, bronze,copper,carbon,stainless steel, titanium etc. UMAIR ANSARI

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9. Anode workpiece(+ve): there is no restriction in the workpiece material except that it must be good conductor of electricity. • The chemical characteristics of the electrolytes effects the metal removal rate. • The fixtures for holding the work are made of some insulating materials, like epoxy resins or glass fibers. UMAIR ANSARI

10. DC power & Control system: the process needs low voltage of the order of 2 to 20V,or 30V in rare cases Normal current requirements are as high as 800 amp/cm2 Three phase ,440V,A.C power is converted to low voltage D.C by a step down transformer & a rectifier UMAIR ANSARI

11. Electrolyte: An electrolyte is an substance containing free ions that make the substance elctrically conductive. • Electrolysis : Electrolysis is an electrochemical process in which direct current is passed through an electrolyte resulting an chemical reactions at the electrodes & electrolyte. UMAIR ANSARI

12. Electrolyte performs following functions • Completes the electric circuit between the tool & the workpiece. • Acts as a conductor to carry current • Remove heat generated during the chemical reactions UMAIR ANSARI

13. Properties of electrolyte and selection • High electrical conductivity • Low viscosity & high specific heat • Chemical stability • Non-corrosive & non-toxic • Inexpensive &readily available UMAIR ANSARI

14. Sodium chloride(Nacl),potassium chloride(Kcl), sodium nitrate(NaNO3),potassium nitrate(‎KNO3),sodium sulphate(Na2SO4),sodium chromate(Na2CrO4),sodium hydroxide(‎NaOH),sodium flouride(‎NaF‎), are use as electroytes In most application Nacl in water has been found to be satisfactory,but as with most electrolytes,its corrosiveness presents a problem. UMAIR ANSARI

15. Sodium nitrate solution is also extensively used. it has all the desirable characteristics & is less corrosive in nature then sodium chloride. sometimes sulphuric acid (Hcl) is used in some cases to produce good surface finish UMAIR ANSARI

16. Theory of ECM UMAIR ANSARI

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19. The basic chemical reactions taking place for say Nacl as electrolyte & iron as workpiece Nacl Na+ + cl- H2O H+ + OH- Hydrogen ions(H+) takes away electrons from the cathode(tool) & forms hydrogen gas 2H+ + 2e- H2 at cathode UMAIR ANSARI

20. The iron atoms come out of anode(w/p) as Fe Fe ++ + 2e- iron ions combine with the chloride ions to form ion chloride & sodium ions combine with hydroxyl ions to form sodium hydroxide Na+ + OH- NaoH • Fe ++ + 2OH- Fe(OH)2 • Fe ++ + 2cl- Fecl2 UMAIR ANSARI

21. ECM Operation: In operation, the tool having a shape, similar to that desired in the work piece is fed towards the work piece maintaining a small gap of approximately 0.25mm between them. This is accomplished by utilizing a servo-drive on the tool feed axis. A high-current, low voltage DC power supply is connected between the tool and the workpiece. The tool is connected to the negative terminal(cathode) & the workpiece to the positive terminal(anode). UMAIR ANSARI

22. The electrolyte is pumped at a high-pressure through the small gap between the tool & the workpiece,thus providing the necessary path for electrolysis. • When the current is passed, dissolution of the work piece(anode) occurs. Meanwhile, the flowing electrolyte washes the metal ions away from the work piece before they have a chance to plate on the tool. UMAIR ANSARI

23. The downward movement of the tool causes the work piece to take the same shape ass that of the tool. • It is important to maintain a uniform gap between the tool & the work piece. • Any physical contact of the tool & the work piece results in arcing & serious damage to both the members UMAIR ANSARI

24. Process parameters : The following are the critical parameters which affect the metal removal rate and surface finish in ECM • Current density • Gap between workpiece & tool • Type of electrolyte • Velocity of electrolyte flow UMAIR ANSARI

25. Current density: current density is simple the current that can be passed into a square inch of work area. At low current densities,MRR is small. The ECM used maintain a current density of 50-1500A/in2 MRR 12 8 4 1000 2000 3000 4000 Current density UMAIR ANSARI

26. Gap between workpiece & tool: the tool & the workpiece are positioned as close together to encourage efficient electrical transmission. • Small gap results in high current densities & hence, more metal removal rate. • The gap size may vary from 0.25-0.76mm. a gap size of 0.25mm is often used. UMAIR ANSARI

27. Type of electrolyte: the type of electrolyte depends on the tool & the workpiece material. UMAIR ANSARI

28. Velocity of electrolyte flow: electrolyte flow may be between 15-60m/sec. If electrolyte flow is too low, the heat & by-products of the electrolytic reaction(hydrogen gas bubbles & sludge etc) build in the gap causing non-uniform metal. • Too high velocity will cause cavitation,also promoting non-uniform metal removal. UMAIR ANSARI

29. There are a number of factors which govern the accuracy of the parts produced by ECM. • Machining voltage • Feed rate of electrode (tool) • Temperature of electrolyte • Concentration of electrolyte UMAIR ANSARI

30. Machining voltage: machining voltage variations severely affect the overcut. • A higher voltage brings about a larger overcut and a lower voltage a smaller cut • Final size of the part is made by controlling the voltage. • The ECM power supply system attempts to rigidly maintain a constant pre-set voltage for varying voltage and current. UMAIR ANSARI

31. Feed rate of electrode (tool):the feed rate of tool must be maintained under varying conditions of load & machining voltage, otherwise accuracy will be lost. An increase in fed rate, other parameters remaining constant, decreases the overcut and vice versa. UMAIR ANSARI

32. Temperature of electrolyte: Electrolyte temperature seriously affects the overcut. • The power loss in the electrolyte reaction gives rise to an increase in the temperature of the electrolyte • In general there is no appreciable change in the mechanical properties, such as tensile strength, yield strength, hardness, ductility, etc of the material of the parts due to ECM. UMAIR ANSARI

33. Material removal rate: • Material removal rate (MRR) is an important characteristic to evaluate efficiency of a non-traditional machining process. • In ECM, material removal takes place due to atomic dissolution of work material which is governed by Faraday’s laws of Electrolysis. MRR = = where m = ItA/Fv = mass of material dissolve I = current ; A = Atomic weight ; v = valency F = Faraday’s constant = 96500 coulumbs ρ = density of the material IA m tρ Fρν UMAIR ANSARI

34. ECONOMIC ASPECTS • Fixed costs of ECM installations are quite high as compared to its operating cost • Overhead costs are the same as for other conventional machining methods • ECM needs power of high current capacity, in localities where power is sufficiently cheap, this factor can be overlooked. • Electrode or tooling cost is a fixed cost. UMAIR ANSARI

35. Electrolyte is not as costly as one might think it to be. • The most widely used electrolyte is sodium chloride(salt) & it is quite cheap • Cost of work piece fixtures are not very high. UMAIR ANSARI

36. Advantages • One of the main advantage of ECM its ability to machine complex three-dimensional curved surfaces without the striation marks left by milling cutters. • This process is capable of machining metals & alloys irrespective of their strength & hardness. • There is little or no tool wear of the tool in this process. UMAIR ANSARI

37. Because of no tool wear a large number of components can be machined without the tool having to be replaced. • Accurate shape with good surface finish can be obtained. UMAIR ANSARI

38. Dis-advantages • The main limitations of this process is that non-conductive materials cannot be machined • Inability to machine sharp interior edges & corners (< 0.2mm radius)because of very high current densities at those points • Corrosion & rust of the ECM machine can be a hazard. • High electrical power consumption. • High floor area is required. • Limited to mass production. UMAIR ANSARI

39. Applications • Fragile parts, which are otherwise not easily machinable,can be shaped by ECM • Gas & steam turbine blades are now machined by this method • Use in die making industries, automotive, aerospace, power generation, oil and gas industries • Specific application include facing and turning complex 3dimensional surfaces UMAIR ANSARI

40. Applicable in multiple hole drilling, milling deburring,grinding,honing,oddshape contouring etc. UMAIR ANSARI

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