Today we will learn about electrochemical machining
principle, working, equipment’s, application, advantages and disadvantages with its diagram.
Electrochemical Machining is a non-traditional machining process in which metal
removed by electrochemical dissolution. Now days this process widely used in
many industries due to its advantageous operation. This process can take as inverse of
electroplating process.
Electrochemical Machining (ECM):
Principle of Electrochemical Machining:
Electrochemical machining works on the Faraday law of
electrolysis which state that if two electrode are placed in a container which
is filled with a conductive liquid or electrolyte and high ampere DC voltage
applied across them, metal can be depleted form the anode (Positive terminal)
and plated on the cathode (Negative terminal). This is the basic principle of
electrochemical machining. In this machining process, tool is connected with
the negative terminal of battery (work as cathode) and work-piece is connected
with the positive terminal of battery (work as anode). They both are placed in a
electrolyte solution with a small distance. When the DC current supplied to the
electrode, metal removed from work-piece. This is basic fundamental of
electrochemical machining.
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| Diagram of Electrochemical Welding |
Equipment:
Power supply:
In electrochemical machining process, a high value of direct current
around 40000A and low value of potential difference around 10-25V is desirable.
The electrodes are place at a inter electro gap witch is desirable for machining.
If the inter electro gap not too small witch can generate arc or not too high
witch is not suitable for machining. It is about 1mm. This high values DC
current is form by convert three phase AC current into DC current by using
Silicon Controlled Rectifier.
Electrolyte supply and cleaning system:
It consist piping system, storage tank, pump, control valve,
pressure gauge, heating or cooling coil etc. in the electrochemical process,
the metal removed from work-piece form sludge which should be remove form
electrolyte. This system control the flow and cleaning of electrolyte solution
into the container. Piping system is made of SS steel, Glass fiber reinforced
plastic, plastic lined MS or similar other anti-corrosive material. The tank
capacity is about 500 gallon for per 10000A of current.
Tool and Tool feed system:
Tool is made by an anti-corrosive material because it has to
withstand in corrosive environment for long time. It should also have high
thermal conductivity and easily machinable. The dimension accuracy and surface
finish of work piece is directly depends on tool dimension. Those part of the tool, which is not required for machining, should be properly insulated because lack
of insulation tends to unwanted machining which give dimensional inaccuracy.
Work piece and work holding system:
In this process, work piece should be well electric
conductive. Only electric conductive material can be machined by this method.
Work piece take as anode in this process. The work holding devices should have
non-conductive property.
Working of Electrochemical Machining:
Electrochemical machining works inverse as electroplating
process. Metal is removed form anode into electrolyte and convert into slag
form by reacting opposite ions available in electrolyte. This process works as
follow.
- In ECM, the electrolyte is so chosen that there is no plating on tool and shape of tool remain unchanged. Generally NaCl into water takes as electrolyte.
- The tool is connected to negative terminal and work is connected to positive terminal.
- When the current passes through electrode, reaction occur at anode or workpiece and at the cathode or tool. To understand proper working let’s take an example or machining low carbon steel.
- Due to potential difference ionic dissociation take place in electrolyte.
NaCl ↔ Na+ + Cl-
H2O ↔ H+ +
OH-
- When the potential difference applied between the work piece and tool, positive ions move towards the tool and negative ions towards the work piece.
- Thus the hydrogen ion moves towards tool. As the hydrogen reaches to the tool, it takes some electron from it and converts into gas form. This gas goes into environment.
- When the hydrogen ions take electron from tool, it creates lack of electron in mixture. To compensate it, a ferrous ions created at the work piece (anode) which gives equal amount of electron in mixture.
2H+ + 2e-
= H2 ↑ at Cathode
Fe = Fe+ +
+ 2e- at Anode
- These Ferrous ions react with opposite chlorine ions or hydroxyl ions and get precipitate in form of sludge.
Iron (Fe) ↔ Fe++ +
2e-
Fe++ + 2Cl-
↔ FeCl2
Fe++ + 2(OH)- ↔
Fe(OH)
Fecl2 + 2(OH)- ↔
Fe(OH)2 + 2Cl
- This will give ferrous or iron into electrolyte and complete the machining process. This machining process gives higher surface finish because machining is done atom by atom.
For better understanding watch following video.
Application:
- ECM is used to machining disk or turbine rotor blade.
- It can be used for slotting very thin walled collets.
- ECM can be used to generate internal profile of internal cam.
- Production of satellite rings and connecting rod, machining of gears and long profile etc.
Advantages and Disadvantages:
Advantages:
- It can machine very complicated surface.
- A single tool can be used to machining large number of work-piece. Theoretically no tool wear occur.
- Machining of metal is independent on strength and hardness of tool.
- ECM gives very high surface finish.
Disadvantages:
- High initial cost of machine.
- Design and tooling system is complex.
- Fatigue property of machined surface may reduce.
- Nonconductive material cannot be machined.
- Blind hole cannot be machined form ECM.
- Space and floor area requirement is high compare to conventional machining.
This is all about electrochemical machining principle,
working, equipment’s, application, advantages and disadvantages. If you have
any query regarding this article, ask by commenting. If you like this article,
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