EDM is a machining method primarily used for hard metals or those that would be impossible to machine with traditional techniques. One critical limitation, however, is that EDM only works with materials that are electrically conductive. EDM or Electrical Discharge Machining, is especially well-suited for cutting intricate contours or delicate cavities that would be difficult to produce with a grinder, an end mill or other cutting tools. Metals that can be machined with EDM include hastalloy, hardened tool-steel, titanium, carbide, inconel and kovar.
EDM is sometimes called "spark machining" because it removes metal by producing a rapid series of repetitive electrical discharges. These electrical discharges are passed between an electrode and the piece of metal being machined. The small amount of material that is removed from the workpiece is flushed away with a continuously flowing fluid. The repetitive discharges create a set of successively deeper craters in the work piece until the final shape is produced.
There are two primary EDM methods: ram EDM and wire EDM. The primary difference between the two involves the electrode that is used to perform the machining. In a typical ram EDM application, a graphite electrode is machined with traditional tools. The now specially-shaped electrode is connected to the power source, attached to a ram, and slowly fed into the workpiece. The entire machining operation is usually performed while submerged in a fluid bath. The fluid serves the following three purposes:
- flushes material away
- serves as a coolant to minimize the heat affected zone (thereby preventing potential damage to the workpiece)
- acts as a conductor for the current to pass between the electrode and the workpiece.
In wire EDM a very thin wire serves as the electrode. Special brass wires are typically used; the wire is slowly fed through the material and the electrical discharges actually cut the workpiece. Wire EDM is usually performed in a bath of water.
If you were to observe the wire EDM process under a microscope, you would discover that the wire itself does not actually touch the metal to be cut; the electrical discharges actually remove small amounts of material and allow the wire to be moved through the workpiece. The path of the wire is typically controlled by a computer, which allows extremely complex shapes to be produced.
Perhaps the best way to explain wire EDM is to use an analogy. Imagine stretching a thin metal wire between your hands and sliding it though a block of cheese cutting any shape you want. You can alter the positions of your hands on either side of the cheese to define complex and curved shapes. Wire EDM works in a similar fashion, except electrical discharge machining can handle some of the hardest materials used in industry. Also note, that in dragging a wire through cheese, the wire is actually displacing the cheese as it cuts, but in EDM a thin kerf is created by removing tiny particles of metal.
Electrical discharge machining is frequently used to make dies and molds. It has recently become a standard method of producing prototypes and some production parts, particularly in low volume applications. For more details regarding a typical application, you can read about a custom bronze branding-iron that was made with EDM.
CLASSIFICATION
1. Contact initiated discharge 2. Spark initiated discharge 3. Electrolytic discharge ADVANTAGES
1. The process can be applied to all electrically conducting metal and alloyes irrespectives of their melting points, hardness, toughness, or brittleness 2. Any complicated shape that can be made on the tool can be produced on the work piece 3. Time of machining is less than conventional machining process DISADVANTAGES
1. Power required for machining in E.D.M is very high compared to conventional process. 2. Reproduction of sharp corners is the limitation of the process. 3. Surface cracking takesplace in some materials.