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5 DIFFERENCES THAT MATTER BETWEEN SWISS-TYPE & CONVENTIONAL CNC TURNING


Small mechanical parts are pervasive in applications across Electronics, Medical, Automotive, and Aerospace Industries. Be it inner micro parts for injection pumps, electrical probes, or implants for surgery; these parts are now lighter, more compact, and more efficient thanks to the precise turning processes performed by the new generation of Swiss-type lathes.Get more news about Swiss-type Lathe Machining,you can vist our website!

With the latest advancements in materials science and motion control technology, Swiss-type machines have become the industry standard for the machining of cost-effective miniature parts with very high accuracy and repeatability.
GUIDE BUSHING
In Swiss-type lathes, the guide bushing supports the part at a distance from the collet.
(Fig.1)
During machining, the bar material is clamped in a collet that can slide along the headstock behind the guide bushing. In this configuration, cutting tool operates very near the guide bushing.
2. FASTER CYCLE TIMES FOR COMPLEX PARTS
Modern Swiss-type lathes such as the Cincom Citizen L12 are capable of performing simultaneous machining with 5-axis control, which drastically reduces cycle-time and higher throughput.
3. MACHINING IN SEGMENTS
Because the Swiss-style lathe provides high rigidity during machining due to the mechanical configuration of sliding headstock and guide bushing, the workpiece always needs to be machined near the guide bushing.
4. COOLANT TYPE
: Swiss-type lathes usually require oil as a coolant liquid, while conventional lathes, water.
The heat capacity of oil is lower than that of water. This means that the machining oil will heat up faster than water during the machining. Hence, heat gets transferred away from the cutting edge of the tools more easily. This is what helps Swiss-type lathe achieve better tolerance because of reduced dimensional change from thermal expansion.
5. REVERSED OFFSET
In conventional type lathes, the turning tool can move in both (X) and (Z) direction to make contact with the part. The bar stock extends out by a specified length and the face of the workpiece looking away from the collet is classified as 'zero' of (Z) direction. The direction along the part toward the collet is in the '-ve' (Z) direction.

On the other hand, the stock moves in the (Z) direction in Swiss-type lathe, and the tool comes into contact with the feed from (X) direction to realize the turning. The face of the part looking away from the guide busing is considered as 'zero' of the (Z) axis. The direction along the workpiece towards the guide bushing is now viewed as '+ve' (Z) direction.
Swiss-type lathe allows for the machining of intricate designs utilizing drilling, turning, milling, knurling, and other unique processes on a single machine. Parts machined on them usually find their place in connectors and contacts used in the electronics industry, medical devices and implants, watch parts, and miniature shafts. These are usually small, long, and complicated mechanical parts.