Superior Roughing Strategies from ZW3D QuickMill

23 May, 2012 - ZW3D is a well-known CAD/CAM solution for mold and die industry, and in the field of CAM (computer-aided manufacturing) ZW3D supplies a powerful processing module, QuickMill.

QuickMill provides several ways to apply its roughing functions, and we describe these here. Through detailed parameter control, users easily make optimal tool paths. Here is an overview of the roughing strategies provided by QuickMill in ZW3D.

1. Time Saving Rough Lace

To remove the excess materials quickly, we use a large diameter tool with a parallel tool path to machine work pieces that have large rough machining allowances. See figure 1 for the type of rough lace tool path generated by QuickMill.




Figure 1: Rough lace generated by ZW3D's QuickMill


Compared with other CAM software, ZW3D shows excellent performance in three specific areas:


(1) Auto Rounded Corners. During parallel cutting, higher cutting speeds and lower depths are permitted, and so machines can be damaged when the cutting direction changes suddenly when the tool runs into corners. The sudden turn of the x or y axis can generate a tremendous impact on the spindle and guideways of the machine, and so may damage it. Over time, the precision of the machine drops off, accompanied by an increased failure rate. See figure 2.
QuickMill's fillet processing function adds transitional arcs automatically to buffer the impact from corner cutting. This processing improves the safety of the machine significantly.



Figure 2: Rough lace problems generated by other CAM software


(2) Auto Optimized Cut Directions. In parallel rough machining, it is common for other CAM software programs to set the cut direction manually, with all tool paths going along the given direction, even in areas where these tactics are considered inappropriate. With its auto analysis system, QuickMill adjusts the cutting direction in different areas on its own. In this way, CAM programmers liberate themselves from spending unnecessary time in setting other kinds of procedures and different cutting directions to match the processing demands.


(3) Finish Cuts. CAM programs other than ZW3D use two methods to deal with the finish cut. One method is to process the parallel tool paths first, then to process the finish cut at the same level; the alternative method processes all level parallel tool paths first, ending off with the finish cut. Both methods have their weaknesses, especially when dealing with open contours; the methods make too many air cuts along tool paths. These useless air cuts reduce machining efficiency, and make the machining process discontinuous.


With its intelligent kernel, QuickMill combines the two methods, and so reduces the number of air cuts, thereby improving machining efficiency.

2. Reasonable-Rough Offset 2D Spiral cutting is the primary method used to process work pieces with complicated surfaces. It avoids many rapid movements, and does not engage dangerous tool paths in narrow areas otherwise caused by parallel cutting methods. The spiral cutting method is widely used in molds, dies, and so on.

Figure 3: Rough offset 2D from ZW3D's QuickMilll



Figure 4: Rough offset 2D produced by other CAM software programs



By comparing figure 3 with figure 4, you can see the QuickMill tool path is continuous, while the path generated by other CAM systems suffers from being discontinuous.

3. High Speed Machining - Rough Smoothflow
Nowadays, machine and cutting tools have an excellent performance, and so the demand for HSM (high speed machining) is high. ZW3D has been cooperating for many years with machine manufactures, thereby accumulating a lot of experience in HSM. QuickMill's rough smoothflow function effortlessly meets the needs of HSM during the actual production process.


Figure 5: Rough smoothflow of ZW3D's QuickMill


As figure 5 shows, QuickMill adds an extra cycloid tool path at each sharp corner to reduce the cutting tool load, thus making a constant cutting tool path.

Conclusion

ZW3D QuickMill provides three kinds of essential roughing methods, and so satisfies all the requirements of rough processing.

For further information about ZW3D QuickMill, please visit www.zwsoft.com or send you email to ZW3D@zwsoft.com.



Read the complete story ...


Review Article Be the first to review this article

SolidCAM - See For Yourself

Editorial
Latest Blog Posts
Sanjay GangalMCADCafe Lens
by Sanjay Gangal
NVIDIA GTC October 2020 Keynote
Jobs
Failure Analysis Engineer for Flextronics at Milpitas, California
Mechanical Engineer for Flextronics at Milpitas, California
3D Designer and Developer for Los Alamos National Laboratory at Los Alamos,, New Mexico
Structural Engineer 2 (Engineer 2) for Los Alamos National Laboratory at Los Alamos,, New Mexico
Structural Engineer for Kiewit at Lenexa, Kansas
Design Engineer (Engineer 1/2) for Los Alamos National Laboratory at Los Alamos,, New Mexico
Upcoming Events
DEVELOP 3D Live 2020 New Date November 3rd at Sheffield University ctagon and INOX Building, Durham Road Sheffield United Kingdom - Nov 3, 2020
Digital Twin 2020 - Now in November 2020 at Melbourne FL - Nov 4 - 5, 2020
Sensors Expo & Conference at McEnery Convention Center SAN JOSE CA - Nov 16 - 18, 2020
Spatial 3D Insider Summit - Free VR Event! at United States - Nov 16 - 17, 2020
Kenesto: 30 day trial



© 2020 Internet Business Systems, Inc.
670 Aberdeen Way, Milpitas, CA 95035
+1 (408) 882-6554 — Contact Us, or visit our other sites:
AECCafe - Architectural Design and Engineering EDACafe - Electronic Design Automation GISCafe - Geographical Information Services TechJobsCafe - Technical Jobs and Resumes ShareCG - Share Computer Graphic (CG) Animation, 3D Art and 3D Models
  Privacy PolicyAdvertise