KCUT software adopts graph recognition technology, it is easy to lean functions of
how to create edit cutting programs. The manual explains functions of editing cutting
path program and parameter setting with different chapters.
Pro/ENGINEER is feature-based, associative solid modeling software that runs on the Microsoft Windows platform. It provides capabilities for solid modeling, assembly modeling, drafting, finite element analysis, and NC and tooling functions for mechanical engineers. Creo Elements/Pro is the updated name for Pro/ENGINEER. The document then provides brief descriptions of computer-aided design (CAD) and computer-aided manufacturing (CAM). CAD is used by engineers to create 2D and 3D drawings, while CAM uses computer control for manufacturing objects from those drawings.
The document provides information on various commands in AutoCAD for drafting and modeling. It discusses commands for drawing basic geometry like lines, circles, arcs and polygons. It also covers modifying objects using commands like copy, move, rotate, mirror, offset, and array. Additional commands covered include trimming, extending, breaking, filleting, chamfering, and dimensioning. The document provides brief descriptions and procedures for using each command.
Sketchup basic course by Eng. Khalid A. Mterkhalid mter
This document provides an overview and learning objectives for a course on building 3D models in Google SketchUp. It will teach students how to use SketchUp's tools to create and modify 2D and 3D geometry, including the line, circle, rectangle, arc, and polygon tools. It will also cover more advanced tools like push/pull to add volume, follow me to create paths, and array/rotate tools to duplicate objects. The document includes step-by-step examples of creating a simple doghouse model and modifying geometry. Upon completing the course, students will be able to proficiently use SketchUp's modeling tools.
This document provides an overview of computer-aided design (CAD) and commonly used CAD software. It discusses CAD, specifications sets, and designing software such as AutoCAD, SolidWorks, Pro-E, CATIA, ANSYS, and Solid Edge. For AutoCAD and SolidWorks, it provides more details on their history, capabilities, and differences. It also explains CAD modeling concepts and tools like sketches, features, dimensions, reference geometry, lofting, and assemblies. Basic commands for drawing and modifying designs are listed. The document uses examples to demonstrate how to create a 3D model using sketches, features, and reference geometry in SolidWorks.
This document provides an overview of computer-aided design (CAD) and commonly used CAD software. It discusses CAD, specifications sets, and designing software such as AutoCAD, SolidWorks, Pro-E, CATIA, ANSYS and Solid Edge. For AutoCAD and SolidWorks, it provides more details on their history, capabilities, and differences. It also covers the basics of 2D sketching, modifying, dimensioning, features like extrude and sweep, reference geometry, and assembling in SolidWorks.
This document provides instructions on creating a 3D wireframe model in AutoCAD 2013 using the box method. It first describes wireframe modeling and its advantages and limitations. It then walks through starting a new file in AutoCAD, setting up the appropriate settings, and constructing a basic 3x4.5" rectangular base. Next it describes copying this base at a height of 2.5" to form a 3D box boundary. The box is completed by using the line command to connect the corners. Finally, it discusses object snapping tools to aid in geometric construction.
EMA3100A Target Motion Simulator User Guide - Chap7-GraphPanel and GraphicsEngin Gul
GraphPanel is a plot panel that presents outputs from motion modeling and target tracking projects. There are three types of GraphPanels: 2D Cartesian, 3D Cartesian, and polar coordinates. The GraphPanel contains selection tools to choose items to plot like true motion, sensor measurements, and target. It also allows selecting plot type as static, animated, or target motion. The GraphPanel toolbar provides zooming, panning, rotation (for 3D plots), and animation playback functionality. Plots can be exported as image files.
The document is a chapter from a textbook on AutoCAD 2013 3D modeling. It discusses 3D wireframe modeling techniques including:
1. Creating a wireframe model using the box method by constructing a base rectangle and copying it to create a 3D box boundary.
2. Using object snaps and relative coordinate input to locate points and construct additional edges of the model.
3. Applying the copy command to efficiently create multiple edges.
4. Using the trim command to precisely shorten objects at selected boundary edges of the model.
Pro/ENGINEER is feature-based, associative solid modeling software that runs on the Microsoft Windows platform. It provides capabilities for solid modeling, assembly modeling, drafting, finite element analysis, and NC and tooling functions for mechanical engineers. Creo Elements/Pro is the updated name for Pro/ENGINEER. The document then provides brief descriptions of computer-aided design (CAD) and computer-aided manufacturing (CAM). CAD is used by engineers to create 2D and 3D drawings, while CAM uses computer control for manufacturing objects from those drawings.
The document provides information on various commands in AutoCAD for drafting and modeling. It discusses commands for drawing basic geometry like lines, circles, arcs and polygons. It also covers modifying objects using commands like copy, move, rotate, mirror, offset, and array. Additional commands covered include trimming, extending, breaking, filleting, chamfering, and dimensioning. The document provides brief descriptions and procedures for using each command.
Sketchup basic course by Eng. Khalid A. Mterkhalid mter
This document provides an overview and learning objectives for a course on building 3D models in Google SketchUp. It will teach students how to use SketchUp's tools to create and modify 2D and 3D geometry, including the line, circle, rectangle, arc, and polygon tools. It will also cover more advanced tools like push/pull to add volume, follow me to create paths, and array/rotate tools to duplicate objects. The document includes step-by-step examples of creating a simple doghouse model and modifying geometry. Upon completing the course, students will be able to proficiently use SketchUp's modeling tools.
This document provides an overview of computer-aided design (CAD) and commonly used CAD software. It discusses CAD, specifications sets, and designing software such as AutoCAD, SolidWorks, Pro-E, CATIA, ANSYS, and Solid Edge. For AutoCAD and SolidWorks, it provides more details on their history, capabilities, and differences. It also explains CAD modeling concepts and tools like sketches, features, dimensions, reference geometry, lofting, and assemblies. Basic commands for drawing and modifying designs are listed. The document uses examples to demonstrate how to create a 3D model using sketches, features, and reference geometry in SolidWorks.
This document provides an overview of computer-aided design (CAD) and commonly used CAD software. It discusses CAD, specifications sets, and designing software such as AutoCAD, SolidWorks, Pro-E, CATIA, ANSYS and Solid Edge. For AutoCAD and SolidWorks, it provides more details on their history, capabilities, and differences. It also covers the basics of 2D sketching, modifying, dimensioning, features like extrude and sweep, reference geometry, and assembling in SolidWorks.
This document provides instructions on creating a 3D wireframe model in AutoCAD 2013 using the box method. It first describes wireframe modeling and its advantages and limitations. It then walks through starting a new file in AutoCAD, setting up the appropriate settings, and constructing a basic 3x4.5" rectangular base. Next it describes copying this base at a height of 2.5" to form a 3D box boundary. The box is completed by using the line command to connect the corners. Finally, it discusses object snapping tools to aid in geometric construction.
EMA3100A Target Motion Simulator User Guide - Chap7-GraphPanel and GraphicsEngin Gul
GraphPanel is a plot panel that presents outputs from motion modeling and target tracking projects. There are three types of GraphPanels: 2D Cartesian, 3D Cartesian, and polar coordinates. The GraphPanel contains selection tools to choose items to plot like true motion, sensor measurements, and target. It also allows selecting plot type as static, animated, or target motion. The GraphPanel toolbar provides zooming, panning, rotation (for 3D plots), and animation playback functionality. Plots can be exported as image files.
The document is a chapter from a textbook on AutoCAD 2013 3D modeling. It discusses 3D wireframe modeling techniques including:
1. Creating a wireframe model using the box method by constructing a base rectangle and copying it to create a 3D box boundary.
2. Using object snaps and relative coordinate input to locate points and construct additional edges of the model.
3. Applying the copy command to efficiently create multiple edges.
4. Using the trim command to precisely shorten objects at selected boundary edges of the model.
The whole manual is divided into three part: Beginning, Intermediate and Expert. Under Beginning part the Basic Geometry- co-ordinate system, loading, supporting, defining and Analysis will be shown for various types of structure; when under Intermediate part both analysis and design will be shown for various types of structure in static linear method. Under Expert part dynamic analysis method will be discussed with sequence. Remember one thing that learning a StaadPro analysis software is a practice work whereas this manual will act as a guideline.
Engr. Yousuf Dinar
Assistant Structural Engineer, Tropical Limited
Lecturer, ATI Training and Consultants
Email: Yousufdinar2012@gmail.com,
Cell: 01675585448.. for inquiry and training service
Computer-aided design (CAD) involves using computer software to design and model objects. The main benefits of CAD include increased accuracy, faster design iterations, easier collaboration, and integration with computer-aided manufacturing.
This document describes how to perform a static structural analysis of a simply supported beam using finite element analysis in ANSYS Workbench. It involves creating the beam geometry, applying material properties, generating a mesh, applying boundary conditions like supports and loads, solving for results, and reviewing outputs such as deformation, internal forces, stresses, and reactions. The analysis is carried out to determine the beam's maximum deflection, internal force variations, maximum normal stress, and reactions at the supports.
This document provides instructions for using various commands in AutoCAD to create different geometric shapes and perform editing functions. It begins with an introduction to AutoCAD and descriptions of the screen components. It then explains how to use commands like LINE, CIRCLE, RECTANGLE, COPY, MIRROR and ERASE to draw and modify objects. Examples are provided for each command's prompt sequence. The document aims to teach the fundamentals of using geometric drawing tools in AutoCAD.
This document provides a guide to using the medical imaging software OsiriX. It discusses how to open and view DICOM images, perform multi-planar reconstruction, volume rendering, image fusion, and other functions. Key points covered include how to customize windows and toolbars, use navigational shortcuts, perform measurements and create regions of interest, synchronize views, and adjust rendering settings such as shading and color lookup tables. The guide provides an overview of the software's main viewing and post-processing capabilities in 3 sentences or less.
Fast shoes design grading software manual Trinity Hu
FAST shoe pattern software is all Chinese interface. It is easy to operate and learn. Its high function enables various shoes to be graded. So it is extensively used for many plants that make shoes, tree sole of shoe, tool model, shoe- pattern design and grade.
Skype: trinityhu
MSN: trinityhu@hotmail.com
http://www.packagingmachiney.com/
The document provides instructions for basic drawing, dimensioning, and symbol usage in ZWCAD MECHANICAL. It covers how to set up a drawing frame, draw contours of parts including holes, shafts, and chamfers. It also explains how to add dimensions, including intelligent, leader, and symbol dimensions. Finally, it demonstrates how to add section lines and views to a drawing. The key steps covered include setting the drawing scale, using tools for shapes, offsetting, breaking and mirroring lines, and setting up dimensions in various formats like diameter, radius, and surface text symbols.
This document provides an overview of the AutoCAD 3D interface and basic 3D modeling tools. It covers setting up a 3D workspace, entering 3D coordinates, visualizing and rendering 3D models using techniques like hiding lines and applying visual styles, and manipulating objects in 3D space including moving and drawing in the Z direction. The tutorial is divided into multiple chapters that progress from basic interface setup to more advanced visualization and coordinate input skills.
This document provides an overview of 3D modeling in AutoCAD, including tutorials on the 3D interface, thickness and elevation, visualizing models, working with z-coordinates, and using the user coordinate system (UCS). The tutorials cover topics such as launching AutoCAD, using the 3D modeling workspace, setting thickness and elevation, visual styles, entering 3D coordinates, moving and filtering in the z-direction, creating helices, and manipulating the UCS using options like named views and the 3 point method. The document is intended to teach basic 3D modeling functions and concepts in AutoCAD.
This document provides an overview of the AutoCAD 3D interface and basic 3D modeling tools. It covers topics such as launching AutoCAD and setting the 3D modeling workspace, using viewports and visual styles to view 3D models, entering 3D coordinates, and manipulating objects in the Z-axis. The document is formatted as a tutorial with sections numbered 1-4 and subsections detailing steps to practice 3D modeling techniques in AutoCAD.
This document provides an overview of 3D modeling in AutoCAD, including tutorials on the 3D interface, thickness and elevation, visualizing models, working with z-coordinates, and using the user coordinate system (UCS). The tutorials cover topics such as launching AutoCAD, using the 3D modeling workspace, setting thickness and elevation, visual styles, entering 3D coordinates, moving and filtering in the z-direction, creating helices, and manipulating the UCS using options like named views and the 3 point method. The document is intended to teach essential 3D concepts and skills for users of AutoCAD.
The document discusses 3D graphics in GeoGebra, including how to customize the 3D graphics view, find the intersection of a plane and line, calculate the distance between two lines, graph functions of two variables, and use commands. It provides examples of constructing various geometric objects in the 3D view and exploring their relationships, as well as tips for navigating commands in GeoGebra.
This document provides a 3-page summary of a 6-week training course on AutoCAD 2D and 3D modeling software. It includes an introduction to AutoCAD and descriptions of the graphical user interface, common commands like line, circle, and erase, and exercises in 2D and 3D modeling. The summary describes the key components of the AutoCAD interface and how to use basic drawing and editing tools.
The document describes two options for adding point data from a different coordinate system into a Civil 3D drawing:
Option 1 imports the points as a point cloud, which references rather than imports the points to keep file sizes smaller. It transforms both the coordinates and elevations.
Option 2 imports the points directly by first creating a new point file format that defines the source coordinate system. This transforms just the coordinates, not elevations, but adds the points directly to the drawing.
Both options have advantages and disadvantages regarding file size and what data is transformed. The best option depends on the specific data and needs of the project.
This document describes NetCDF Extractor V2.1, which allows users to create contour and heat map graphs from NetCDF data in addition to extracting data. It provides step-by-step instructions for using the tool to extract data, generate 2D graphs by selecting variables and domains, and customize graph settings like colors, text size and styles. Key features include generating contour plots with labeled lines and heat maps with customizable color ranges.
This document is intended to my personal reference when delivering training.
I thankful to Siemens Digital Industries Software.
This document is incomplete. Will update in sometime.
CutViewer Mill V3.1 is a program that graphically displays material removal for milling/drilling operations. It requires Windows 95/98/ME/NT/2000/XP, a Pentium processor, 64 MB RAM, 100 MB disk space, and a 2 MB graphics card. It can open G-code files and customize tools and stock. Key features include editing files, multiple viewing angles, and measuring finished parts.
Microsoft mathmatics step-by-step_guideAnang Anang
The document provides an overview of the key features and tools available in Microsoft Mathematics, including:
1) The calculator pad, worksheet tab for computations, and graphing tab for plotting graphs. Additional math tools include an equation solver, formulas library, and triangle solver.
2) Instructions for using the graphing calculator to evaluate expressions, solve equations either with buttons or ink input, and view step-by-step solutions.
3) Details on how to create graphs including plotting lines and functions, animating parameters, and creating 3D surface graphs which can be rotated to view from different angles.
This document provides an overview of computer-aided design (CAD) software and the basics of using AutoCAD. It discusses what CAD is, the benefits of using CAD like accuracy and productivity. It then describes the main parts of the AutoCAD interface and basic drawing tools. The document outlines how to set up a drawing by choosing units, scale, and limits. It provides step-by-step instructions for basic drawing techniques like drawing a box using lines and offsets. It also covers modifying drawings using commands like trim, extend, and fillet. Finally, it discusses strategies for laying out a basic floor plan and dividing it into sections. In summary, the document serves as an introduction to the CAD software AutoCAD and provides found
The document is an AutoCAD 3D tutorial that covers the 3D interface and tools. It discusses launching AutoCAD 3D, the 3D dashboard, viewports, named views, the steering wheel for navigation, defining views using VPOINT and DDVPOINT, and working with the plan view. It also covers thickness and elevation settings, visualizing models using hide, visual styles, and the adaptive grid, entering coordinates and moving in the Z-direction, and using the user coordinate system including setting a new 3-point UCS and working in the plan view of that UCS.
[To download this presentation, visit:
https://www.oeconsulting.com.sg/training-presentations]
This presentation is a curated compilation of PowerPoint diagrams and templates designed to illustrate 20 different digital transformation frameworks and models. These frameworks are based on recent industry trends and best practices, ensuring that the content remains relevant and up-to-date.
Key highlights include Microsoft's Digital Transformation Framework, which focuses on driving innovation and efficiency, and McKinsey's Ten Guiding Principles, which provide strategic insights for successful digital transformation. Additionally, Forrester's framework emphasizes enhancing customer experiences and modernizing IT infrastructure, while IDC's MaturityScape helps assess and develop organizational digital maturity. MIT's framework explores cutting-edge strategies for achieving digital success.
These materials are perfect for enhancing your business or classroom presentations, offering visual aids to supplement your insights. Please note that while comprehensive, these slides are intended as supplementary resources and may not be complete for standalone instructional purposes.
Frameworks/Models included:
Microsoft’s Digital Transformation Framework
McKinsey’s Ten Guiding Principles of Digital Transformation
Forrester’s Digital Transformation Framework
IDC’s Digital Transformation MaturityScape
MIT’s Digital Transformation Framework
Gartner’s Digital Transformation Framework
Accenture’s Digital Strategy & Enterprise Frameworks
Deloitte’s Digital Industrial Transformation Framework
Capgemini’s Digital Transformation Framework
PwC’s Digital Transformation Framework
Cisco’s Digital Transformation Framework
Cognizant’s Digital Transformation Framework
DXC Technology’s Digital Transformation Framework
The BCG Strategy Palette
McKinsey’s Digital Transformation Framework
Digital Transformation Compass
Four Levels of Digital Maturity
Design Thinking Framework
Business Model Canvas
Customer Journey Map
The whole manual is divided into three part: Beginning, Intermediate and Expert. Under Beginning part the Basic Geometry- co-ordinate system, loading, supporting, defining and Analysis will be shown for various types of structure; when under Intermediate part both analysis and design will be shown for various types of structure in static linear method. Under Expert part dynamic analysis method will be discussed with sequence. Remember one thing that learning a StaadPro analysis software is a practice work whereas this manual will act as a guideline.
Engr. Yousuf Dinar
Assistant Structural Engineer, Tropical Limited
Lecturer, ATI Training and Consultants
Email: Yousufdinar2012@gmail.com,
Cell: 01675585448.. for inquiry and training service
Computer-aided design (CAD) involves using computer software to design and model objects. The main benefits of CAD include increased accuracy, faster design iterations, easier collaboration, and integration with computer-aided manufacturing.
This document describes how to perform a static structural analysis of a simply supported beam using finite element analysis in ANSYS Workbench. It involves creating the beam geometry, applying material properties, generating a mesh, applying boundary conditions like supports and loads, solving for results, and reviewing outputs such as deformation, internal forces, stresses, and reactions. The analysis is carried out to determine the beam's maximum deflection, internal force variations, maximum normal stress, and reactions at the supports.
This document provides instructions for using various commands in AutoCAD to create different geometric shapes and perform editing functions. It begins with an introduction to AutoCAD and descriptions of the screen components. It then explains how to use commands like LINE, CIRCLE, RECTANGLE, COPY, MIRROR and ERASE to draw and modify objects. Examples are provided for each command's prompt sequence. The document aims to teach the fundamentals of using geometric drawing tools in AutoCAD.
This document provides a guide to using the medical imaging software OsiriX. It discusses how to open and view DICOM images, perform multi-planar reconstruction, volume rendering, image fusion, and other functions. Key points covered include how to customize windows and toolbars, use navigational shortcuts, perform measurements and create regions of interest, synchronize views, and adjust rendering settings such as shading and color lookup tables. The guide provides an overview of the software's main viewing and post-processing capabilities in 3 sentences or less.
Fast shoes design grading software manual Trinity Hu
FAST shoe pattern software is all Chinese interface. It is easy to operate and learn. Its high function enables various shoes to be graded. So it is extensively used for many plants that make shoes, tree sole of shoe, tool model, shoe- pattern design and grade.
Skype: trinityhu
MSN: trinityhu@hotmail.com
http://www.packagingmachiney.com/
The document provides instructions for basic drawing, dimensioning, and symbol usage in ZWCAD MECHANICAL. It covers how to set up a drawing frame, draw contours of parts including holes, shafts, and chamfers. It also explains how to add dimensions, including intelligent, leader, and symbol dimensions. Finally, it demonstrates how to add section lines and views to a drawing. The key steps covered include setting the drawing scale, using tools for shapes, offsetting, breaking and mirroring lines, and setting up dimensions in various formats like diameter, radius, and surface text symbols.
This document provides an overview of the AutoCAD 3D interface and basic 3D modeling tools. It covers setting up a 3D workspace, entering 3D coordinates, visualizing and rendering 3D models using techniques like hiding lines and applying visual styles, and manipulating objects in 3D space including moving and drawing in the Z direction. The tutorial is divided into multiple chapters that progress from basic interface setup to more advanced visualization and coordinate input skills.
This document provides an overview of 3D modeling in AutoCAD, including tutorials on the 3D interface, thickness and elevation, visualizing models, working with z-coordinates, and using the user coordinate system (UCS). The tutorials cover topics such as launching AutoCAD, using the 3D modeling workspace, setting thickness and elevation, visual styles, entering 3D coordinates, moving and filtering in the z-direction, creating helices, and manipulating the UCS using options like named views and the 3 point method. The document is intended to teach basic 3D modeling functions and concepts in AutoCAD.
This document provides an overview of the AutoCAD 3D interface and basic 3D modeling tools. It covers topics such as launching AutoCAD and setting the 3D modeling workspace, using viewports and visual styles to view 3D models, entering 3D coordinates, and manipulating objects in the Z-axis. The document is formatted as a tutorial with sections numbered 1-4 and subsections detailing steps to practice 3D modeling techniques in AutoCAD.
This document provides an overview of 3D modeling in AutoCAD, including tutorials on the 3D interface, thickness and elevation, visualizing models, working with z-coordinates, and using the user coordinate system (UCS). The tutorials cover topics such as launching AutoCAD, using the 3D modeling workspace, setting thickness and elevation, visual styles, entering 3D coordinates, moving and filtering in the z-direction, creating helices, and manipulating the UCS using options like named views and the 3 point method. The document is intended to teach essential 3D concepts and skills for users of AutoCAD.
The document discusses 3D graphics in GeoGebra, including how to customize the 3D graphics view, find the intersection of a plane and line, calculate the distance between two lines, graph functions of two variables, and use commands. It provides examples of constructing various geometric objects in the 3D view and exploring their relationships, as well as tips for navigating commands in GeoGebra.
This document provides a 3-page summary of a 6-week training course on AutoCAD 2D and 3D modeling software. It includes an introduction to AutoCAD and descriptions of the graphical user interface, common commands like line, circle, and erase, and exercises in 2D and 3D modeling. The summary describes the key components of the AutoCAD interface and how to use basic drawing and editing tools.
The document describes two options for adding point data from a different coordinate system into a Civil 3D drawing:
Option 1 imports the points as a point cloud, which references rather than imports the points to keep file sizes smaller. It transforms both the coordinates and elevations.
Option 2 imports the points directly by first creating a new point file format that defines the source coordinate system. This transforms just the coordinates, not elevations, but adds the points directly to the drawing.
Both options have advantages and disadvantages regarding file size and what data is transformed. The best option depends on the specific data and needs of the project.
This document describes NetCDF Extractor V2.1, which allows users to create contour and heat map graphs from NetCDF data in addition to extracting data. It provides step-by-step instructions for using the tool to extract data, generate 2D graphs by selecting variables and domains, and customize graph settings like colors, text size and styles. Key features include generating contour plots with labeled lines and heat maps with customizable color ranges.
This document is intended to my personal reference when delivering training.
I thankful to Siemens Digital Industries Software.
This document is incomplete. Will update in sometime.
CutViewer Mill V3.1 is a program that graphically displays material removal for milling/drilling operations. It requires Windows 95/98/ME/NT/2000/XP, a Pentium processor, 64 MB RAM, 100 MB disk space, and a 2 MB graphics card. It can open G-code files and customize tools and stock. Key features include editing files, multiple viewing angles, and measuring finished parts.
Microsoft mathmatics step-by-step_guideAnang Anang
The document provides an overview of the key features and tools available in Microsoft Mathematics, including:
1) The calculator pad, worksheet tab for computations, and graphing tab for plotting graphs. Additional math tools include an equation solver, formulas library, and triangle solver.
2) Instructions for using the graphing calculator to evaluate expressions, solve equations either with buttons or ink input, and view step-by-step solutions.
3) Details on how to create graphs including plotting lines and functions, animating parameters, and creating 3D surface graphs which can be rotated to view from different angles.
This document provides an overview of computer-aided design (CAD) software and the basics of using AutoCAD. It discusses what CAD is, the benefits of using CAD like accuracy and productivity. It then describes the main parts of the AutoCAD interface and basic drawing tools. The document outlines how to set up a drawing by choosing units, scale, and limits. It provides step-by-step instructions for basic drawing techniques like drawing a box using lines and offsets. It also covers modifying drawings using commands like trim, extend, and fillet. Finally, it discusses strategies for laying out a basic floor plan and dividing it into sections. In summary, the document serves as an introduction to the CAD software AutoCAD and provides found
The document is an AutoCAD 3D tutorial that covers the 3D interface and tools. It discusses launching AutoCAD 3D, the 3D dashboard, viewports, named views, the steering wheel for navigation, defining views using VPOINT and DDVPOINT, and working with the plan view. It also covers thickness and elevation settings, visualizing models using hide, visual styles, and the adaptive grid, entering coordinates and moving in the Z-direction, and using the user coordinate system including setting a new 3-point UCS and working in the plan view of that UCS.
Similar to cnc-wire-cut-edm-kcut-programming-instruction.pdf (20)
[To download this presentation, visit:
https://www.oeconsulting.com.sg/training-presentations]
This presentation is a curated compilation of PowerPoint diagrams and templates designed to illustrate 20 different digital transformation frameworks and models. These frameworks are based on recent industry trends and best practices, ensuring that the content remains relevant and up-to-date.
Key highlights include Microsoft's Digital Transformation Framework, which focuses on driving innovation and efficiency, and McKinsey's Ten Guiding Principles, which provide strategic insights for successful digital transformation. Additionally, Forrester's framework emphasizes enhancing customer experiences and modernizing IT infrastructure, while IDC's MaturityScape helps assess and develop organizational digital maturity. MIT's framework explores cutting-edge strategies for achieving digital success.
These materials are perfect for enhancing your business or classroom presentations, offering visual aids to supplement your insights. Please note that while comprehensive, these slides are intended as supplementary resources and may not be complete for standalone instructional purposes.
Frameworks/Models included:
Microsoft’s Digital Transformation Framework
McKinsey’s Ten Guiding Principles of Digital Transformation
Forrester’s Digital Transformation Framework
IDC’s Digital Transformation MaturityScape
MIT’s Digital Transformation Framework
Gartner’s Digital Transformation Framework
Accenture’s Digital Strategy & Enterprise Frameworks
Deloitte’s Digital Industrial Transformation Framework
Capgemini’s Digital Transformation Framework
PwC’s Digital Transformation Framework
Cisco’s Digital Transformation Framework
Cognizant’s Digital Transformation Framework
DXC Technology’s Digital Transformation Framework
The BCG Strategy Palette
McKinsey’s Digital Transformation Framework
Digital Transformation Compass
Four Levels of Digital Maturity
Design Thinking Framework
Business Model Canvas
Customer Journey Map
Company Valuation webinar series - Tuesday, 4 June 2024FelixPerez547899
This session provided an update as to the latest valuation data in the UK and then delved into a discussion on the upcoming election and the impacts on valuation. We finished, as always with a Q&A
Understanding User Needs and Satisfying ThemAggregage
https://www.productmanagementtoday.com/frs/26903918/understanding-user-needs-and-satisfying-them
We know we want to create products which our customers find to be valuable. Whether we label it as customer-centric or product-led depends on how long we've been doing product management. There are three challenges we face when doing this. The obvious challenge is figuring out what our users need; the non-obvious challenges are in creating a shared understanding of those needs and in sensing if what we're doing is meeting those needs.
In this webinar, we won't focus on the research methods for discovering user-needs. We will focus on synthesis of the needs we discover, communication and alignment tools, and how we operationalize addressing those needs.
Industry expert Scott Sehlhorst will:
• Introduce a taxonomy for user goals with real world examples
• Present the Onion Diagram, a tool for contextualizing task-level goals
• Illustrate how customer journey maps capture activity-level and task-level goals
• Demonstrate the best approach to selection and prioritization of user-goals to address
• Highlight the crucial benchmarks, observable changes, in ensuring fulfillment of customer needs
Anny Serafina Love - Letter of Recommendation by Kellen Harkins, MS.AnnySerafinaLove
This letter, written by Kellen Harkins, Course Director at Full Sail University, commends Anny Love's exemplary performance in the Video Sharing Platforms class. It highlights her dedication, willingness to challenge herself, and exceptional skills in production, editing, and marketing across various video platforms like YouTube, TikTok, and Instagram.
Best practices for project execution and deliveryCLIVE MINCHIN
A select set of project management best practices to keep your project on-track, on-cost and aligned to scope. Many firms have don't have the necessary skills, diligence, methods and oversight of their projects; this leads to slippage, higher costs and longer timeframes. Often firms have a history of projects that simply failed to move the needle. These best practices will help your firm avoid these pitfalls but they require fortitude to apply.
How to Implement a Real Estate CRM SoftwareSalesTown
To implement a CRM for real estate, set clear goals, choose a CRM with key real estate features, and customize it to your needs. Migrate your data, train your team, and use automation to save time. Monitor performance, ensure data security, and use the CRM to enhance marketing. Regularly check its effectiveness to improve your business.
At Techbox Square, in Singapore, we're not just creative web designers and developers, we're the driving force behind your brand identity. Contact us today.
Event Report - SAP Sapphire 2024 Orlando - lots of innovation and old challengesHolger Mueller
Holger Mueller of Constellation Research shares his key takeaways from SAP's Sapphire confernece, held in Orlando, June 3rd till 5th 2024, in the Orange Convention Center.
IMPACT Silver is a pure silver zinc producer with over $260 million in revenue since 2008 and a large 100% owned 210km Mexico land package - 2024 catalysts includes new 14% grade zinc Plomosas mine and 20,000m of fully funded exploration drilling.
Building Your Employer Brand with Social MediaLuanWise
Presented at The Global HR Summit, 6th June 2024
In this keynote, Luan Wise will provide invaluable insights to elevate your employer brand on social media platforms including LinkedIn, Facebook, Instagram, X (formerly Twitter) and TikTok. You'll learn how compelling content can authentically showcase your company culture, values, and employee experiences to support your talent acquisition and retention objectives. Additionally, you'll understand the power of employee advocacy to amplify reach and engagement – helping to position your organization as an employer of choice in today's competitive talent landscape.
[To download this presentation, visit:
https://www.oeconsulting.com.sg/training-presentations]
This PowerPoint compilation offers a comprehensive overview of 20 leading innovation management frameworks and methodologies, selected for their broad applicability across various industries and organizational contexts. These frameworks are valuable resources for a wide range of users, including business professionals, educators, and consultants.
Each framework is presented with visually engaging diagrams and templates, ensuring the content is both informative and appealing. While this compilation is thorough, please note that the slides are intended as supplementary resources and may not be sufficient for standalone instructional purposes.
This compilation is ideal for anyone looking to enhance their understanding of innovation management and drive meaningful change within their organization. Whether you aim to improve product development processes, enhance customer experiences, or drive digital transformation, these frameworks offer valuable insights and tools to help you achieve your goals.
INCLUDED FRAMEWORKS/MODELS:
1. Stanford’s Design Thinking
2. IDEO’s Human-Centered Design
3. Strategyzer’s Business Model Innovation
4. Lean Startup Methodology
5. Agile Innovation Framework
6. Doblin’s Ten Types of Innovation
7. McKinsey’s Three Horizons of Growth
8. Customer Journey Map
9. Christensen’s Disruptive Innovation Theory
10. Blue Ocean Strategy
11. Strategyn’s Jobs-To-Be-Done (JTBD) Framework with Job Map
12. Design Sprint Framework
13. The Double Diamond
14. Lean Six Sigma DMAIC
15. TRIZ Problem-Solving Framework
16. Edward de Bono’s Six Thinking Hats
17. Stage-Gate Model
18. Toyota’s Six Steps of Kaizen
19. Microsoft’s Digital Transformation Framework
20. Design for Six Sigma (DFSS)
To download this presentation, visit:
https://www.oeconsulting.com.sg/training-presentations
Zodiac Signs and Food Preferences_ What Your Sign Says About Your Tastemy Pandit
Know what your zodiac sign says about your taste in food! Explore how the 12 zodiac signs influence your culinary preferences with insights from MyPandit. Dive into astrology and flavors!
B2B payments are rapidly changing. Find out the 5 key questions you need to be asking yourself to be sure you are mastering B2B payments today. Learn more at www.BlueSnap.com.
Digital Marketing with a Focus on Sustainabilitysssourabhsharma
Digital Marketing best practices including influencer marketing, content creators, and omnichannel marketing for Sustainable Brands at the Sustainable Cosmetics Summit 2024 in New York
2. CONTENT
Chapter 1 overview of cutting path programming………………………………………….…..2
1.1 brief introduction…………………………………………………………………...…...2
Chapter 2 files management……………………………………………………………………....3
2.1 files management…………………………………………………………………………3
Chapter 3 pre-planning of cutting path………………………………………………….............4
3.1 pre-planning………………………………………………………………………………4
3.2 pre-planning of graph with known lead-in line…………………………………..…….4
3.3 pre-planning of equilateral polygon………………………………….
3.4 pre-planning of graph with wire threading positions that marked with small circle
or equilateral polygon………………………………………..
3.5 path programming setting of pre-planning…………………
3.6 one path pre-planning………….
3.7 multiple paths pre-planning
3.8 equal taper pre-planning
3.9 variable taper pre-planning
3.10 abnormity taper pre-planning
3.11 taper and straight combined pre-planning
Chapter 4 cutting path programming
4.1 one path, multiple paths, equal taper programing
4.2 non-closed graph programming
4.3 variable taper programming: single graph
4.4 abnormity programming: single graph
4.5 taper and straight combined programming: single graph
Chapter 5 setting of programming path
5.1 modify parameters of the path
5.2 clear corner setting
5.3 array copy
5.4 appoint cutting sequence
Chapter 6 cutting parameters setting
6.1 cutting parameters setting of one path
6.2 cutting parameters setting of multiple paths
6.3 allowance setting explanation
6.4 taper parameters setting
6.5 taper and straight combined parameters setting
3. Chapter overview of cutting programming
1.1 brief introduction
KCUT software adopts graph recognition technology, it is easy to lean functions of
how to create edit cutting programs. The manual explains functions of editing cutting
path program and parameter setting with different chapters.
2nd
chapter introduces files management
3rd
chapter introduces pre-planning functions of cut path
4th
chapter introduces programming of one path, multiple paths, equal path, variable
taper, and abnormity taper.
5th
chapter introduces functions of clearing corner setting, how to edit path parameters,
array copy, appoint cutting sequence
6th
chapter introduces parameters adjustment during cutting process, includes
parameters setting of one path, multiple paths, allowance, parameters of taper and so
on.
4. Chapter 2 files management
2.1 files management
Left click “File” in main interface to enter files management interface, refer to image
2-1.
Open file: select the graph to cut, for the moment, it supports DXF and PTH file
generated by KCUT.
Delete: remove data of cut path
Path plan: start to create path for present selected graph
Path modify: modify the path data of selected graph
Add wait:
View wait:
Select graph: select present cutting file that already been edited.
image 2-1
5. Chapter 3 pre-planning of cutting path
Click “Path Plan” to enter next page of path programming, refer to image 3-1.
image 3-1
Image 3-1-1
3.1 pre-planning
Once enter interface of pre-planning, it is at pre-planning by default. Pre-planning can
select and set cut in point, cut direction and direction of offset.
6. Pre-planning can only be done for following types of graphs, refer to image 3-1-1.
Graph 1 with preset lead-in line; graph 2 and 3, regular polygons and circles, KCUT
can recognize center of circle and regular polygon by itself; graph 4 and graph 5 or
profiles with preset cutting start point.
For graphs like graph 6 and graph 7 without preset start point or non-closed profile,
pre-planning can’t be used.
3.2 Pre-planning of graph with known lead-in line
Do pre-planning for the graph with start lead-in line that already known, refer to
image 3-2.
Step 1: select the graph, left click the mouse to choose wire threading point or graph
itself, after selection, graph turns to red color, 1 and 2 of image 3-2 explain the
difference.
Step 2: right click the mouse to confirm wire threading point. Then select the cut-in
point(now there is a default straight lead-in line), click any un-planned graph, there
would be a line connects wire threading point and cut-in point (lead-in line), the line
turns to red, 3 of image 3-2 shows how it looks like.
Step 3: right click the mouse to confirm the lead-in line, then start to select cutting
direction, move the mouse to left or right and then left click the mouse to confirm
cutting direction, 4 of image 3-2 shows how it looks like.
Step 4: select direction of offset, move mouse to select, left click the mouse to
confirm the direction, 5 of image 3-2 shows how it looks like.
Step 5: after confirmation of offset direction, pre-planning is done. The graph turns to
blue with arrows of cutting direction and offset direction, 6 of image 3-2 shows how it
looks like.
Note:
(1) key “Delete” of keyboard can delete finished or unfinish path.
(2) Lead-in line is orthogonal by default, “O” of keyboard can turn on/off orthogonal
function.
Image 3-2
7. 3.3 Pre-planning of equilateral polygon
Pre-planning of equilateral polygon or circle refers to image 3-3.
Step 1: select the graph, left click the equilateral polygon or circle to get the center of
the graph, after selection, the graph turns to red, 1 and 2 of image 3-3 shows how it
looks like.
Step 2: right click to decide wire threading point(center of the graph), then select
cut-in point(there is a default straight lead-line), click any position on the graph, the
line between lead-in line and wire threading point, and graph turns to red, 3 of image
3-3 shows how it looks like.
Step 3: right click the mouse to confirm lead-line line, then select cutting direction,
move mouse to select and left click the mouse to confirm. 4 of image 3-2 shows how
it looks like.
Step 4: select direction of offset, move mouse to select, left click the mouse to
confirm the direction, 5 of image 3-2 shows how it looks like.
Step 5: after confirmation of offset direction, pre-planning is done. The graph turns to
blue with arrows of cutting direction and offset direction, 6 of image 3-2 shows how it
looks like.
Image 3-3
3.4 pre-planning of graph with wire threading position that
marked with small circle or equilateral polygon
Refer to image 3-4。
Step 1: select the positioning circle, same as first step of 3.3
Step 2: right click to decide wire threading point(center of the graph), then select
cut-in point(there is a default straight lead-line), click any position on the graph, the
8. line between lead-in line and wire threading point, and graph turns to red, 3 of image
3-4 shows how it looks like.
Step 3: right click the mouse to confirm lead-line line, then select cutting direction,
move mouse to select and left click the mouse to confirm. 4 of image 3-4 shows how
it looks like.
Step 4: select direction of offset, move mouse to select, left click the mouse to
confirm the direction, 5 of image 3-4 shows how it looks like.
Step 5: after confirmation of offset direction, pre-planning is done. The graph turns to
blue with arrows of cutting direction and offset direction, 6 of image 3-4 shows how it
looks like.
Note: the steps of non-closed graph is same as above steps, the last point of
non-closed graph is the end of the cutting program.
image 3-4
9. 3.5 Programming setting of pre-planning
After pre-planning is done, the graph is in blue color, refers to image 3-5.
Step 1: click “select graph(S)” or use “S” of keyboard to select the pre-planned graph
Step 2: right click the mouse or use “W” of keyboard to select all pre-planned graphs,
or use mouse to left click one by one to select all graphs, the selected graphs are in
cyan color, 2 and 3 of image 3-5 shows how it looks like.
Step 3: for selected graphs, there are many options we can do, single path, multiple
path, equal cone(taper), variable cone, abnormity, cylinder-cone(straight and taper
combined), click the button of what is needed.
image 3-5
10. 3.6 One path programming of pre-planned graph
refer to image 3-6, after selected the pre-planned graph (1 of image 3-6), click “one
path” to set path parameters and cutting parameters(2 of image 3-6), then generated
the path program (3 of 3-6).
image 3-6
11. 3.7 Multiple paths programming of pre-planned graph
Refer to image 3-7, after selected the pre-planned graph (1 of image 3-7), click “one
path” to set path parameters and cutting parameters(2 of image 3-7), then generated
the path program (3 of 3-7).
image 3-7
3.8 Equal cone(taper) path programming of pre-planned graph
It is same as steps of multiple paths.
12. 3.9 Variable cone(taper) path programming
Select the graph, click “variable cone”, after setting path parameters and cutting
parameters, enter the interface of variable cone setting (1 of image 3-8).
Step 1: set taper parameters, for each segment of graph, the default angle is 0°
. Click
the segment to input the expected degrees (2 of image 3-8).
Step 2: after set degrees of all segments, click “generate” to confirm all degrees(3 of
image 3-8).
Step 3: click “OK” to create path (4 of image 3-8), before this, it is necessary to set
some data of angle cutting, for example workpiece height, distance between up and
down guides, etc..
image 3-8
13. 3.10 Abnormity(taper) path programming
Abnormity taper is a kind of angle cutting with upper profile different to lower profile,
it is more accurate to get accuracy of both upper and lower profile.
Select the upper and lower profile, click “abnormity”, set path parameters of upper
and lower profile. Confirm to enter interface of abnormity setting(1 of page 3-9).
Step 1: first select the lower profile of abnormity (2 of image 3-9).
Step 2: right click the mouse or click “OK” in the software to confirm lower profile;
then select upper profile (3 of image 3-9).
Step 3: right click the mouse or click “OK” in the software to confirm upper profile.
Software automatically combines both profiles and generate the path of abnormity
(upper and lower different profiles). Before this step, it’s necessary to measure and
input workpiece height, each segment correspondence or perimeter correspondence.
If there are many different program paths, repeat the same steps of single program
path.
image 3-9
14. 3.11 Cylinder-cone path programming
For practical application of male and female die, female has upper part with straight
and lower part with taper, which is for part to drop down easily. KCUT has function to
make one program with two separated cutting paths, one straight cutting and one
angle cutting, refer to image 3-10.
Select the graph and then click “cylinder-cone”, input parameters of straight cutting
and angle cutting, there are two options to select straight first or angle first, then click
“OK” to generate the path program. There would be two separated cuts.
image 3-10
15. Chapter 4 cutting path programming
According to different machining requirement, KCUT provides different types
solution: one path cutting, multiple paths cutting, equal cone(taper) cutting, variable
cone cutting, abnormity programming. Customers can select according to practical
tasks to enter different path programming interface.
4.1 one path, multiple paths, equal cone(taper)
One path function is for making one cut straight cutting program. Multiple paths
function is for making multiple cuts cutting program. Equal cone function is for
making equal cone cutting program.
These three types are similar, take multiple cuts function for instance.
Step 1: click “Multi path” (1 of image 4-1), to enter multiple cuts interface (2 of
image 4-1).
Step 2: select cut-in point in the graph (2 of image 4-1). Cut-in point is the position
start to cut of graph.
Step 3: right click the mouse to confirm cut-in point, then edit lead-in line, initially, a
lead-in line is generated based on the "lead-in length L", and the current mouse
location, as 3 of image 4-1 shows. The lead-in line can be adjusted by using mouse to
drag and rotate the lead-in line, the line halts at 0°
, 45°
, 90°
, 135°
, 180°
, 225°
, 270°
,
315°
.
Step 4: right click the mouse to confirm the lead-in line, then select cutting direction,
move mouse to left or right to decide direction, left click the mouse to confirm cutting
direction, as shown in 4 of image 4-1.
Step 5: select offset direction, move mouse up and down and then left click to confirm
the direction, as shown in 5 of image 4-1.
Step 6: right click the mouse or click “OK” to set path parameters, shown in 6 and 7
of image 4-1.
Step 7: set cutting parameters, then after confirmation, path programming is done, 8
of image 4-1.
Repeat above steps for other graphs if there are extra graphs to do programming.
Remark:
Coordinate of Cut-in point and wire threading point are same as in CAD drawing.
Cut-in point: can be modified by clicking cut-in point of present graph.
Wire threading point: can be modified by clicking cut-in point of present graph.
Cutting direction: can be modified by clicking cutting direction of present graph.
Offset direction: can be modified by clicking offset direction of present graph.
Clearing corner setting: edit clearing corner for present graph. After confirm offset
direction, set clearing corner.
16. image 4-1
4.2 Non-closed graph programming
The first few steps of non-closed graph programing are same as first few steps of 4.1.
Step 1: Set cut-in point, lead-in line, cutting direction, offset direction in sequence (1
of image 4-2)
Step 2: set end point, default end point is the last point of graph, operator can select
back to wire threading point or end point of graph, or click any point of the interface
as end point; if select back to wire threading point, there are two modes, dry run or cut
back to end point, shown in 2 of image 4-2.
Step 3: right click the moues or click “OK”, to set path parameters, after confirm
17. confirmation, edit done, refer to 3 and 4 of image 4-2.
Repeat above steps to edit other graphs if there are other graphs to edit.
image 4-2
4.3 Variable cone path: single graph path programming
The first few steps of variable cone path programing are same as first few steps of 4.1.
Step 1: set cut-in point, lead-in line, cutting direction, offset direction, input variable
path data, 1 and 2 of image 4-3.
Step 2: after confirmed above data, then set angles of each segment, same method as
explained in 3.9, refer to 3 of image 4-3.
Step 3: click “OK” to generate the path programming.
Repeat above steps to edit other graphs if there are other graphs to edit.
image 4-3
18. 4.4 Abnormity path: single graph path programming.
Step 1: click “abnormity” to enter its interface, first finish the track programming, 1 of
image 4-4. Then select upper and lower graph to enter page of combination of upper
and lower graph.
Step 2: generate the abnormity path programming, same setting as explained in 3.10.
image 4-4
4.5 Cylinder-cone path programming: single graph
Enter page of cylinder-cone, first finish the track editing of the graph; right click the
mouse or click “OK” to set parameters of cone cutting and straight cutting, 1 of
image 4-5. After setting cutting parameters of both cuts, generate the program, refer
to 2 of image 4-5.
image 4-5
19. Chapter 5 setting of programming path
During steps of path editing, according to practical requirement, for example, clearing
corner, after editing, array copy, edit path parameters, select machining sequence.
Modify parameter of the path: modify parameter for programming finished graph.
Clearing corner: during editing, set clearing corner of the graph.
Array copy: do array copy for programming finished graph.
Select machining sequence: if there are multiple graphs to cut, use this function to
select which one first, which one last, to cut these graphs in sequence.
5.1 Modify parameters of the path
For the paths that have already been edited, click modify path parameters to enter its
interface, refer to 1 and 2 of image 5-1.
Click select the graph to modify (S), left click any graph or right click the mouse, use
W key of keyboard to select all graphs, 2 and 3 of image 5-1.
Click modify the graph (M), then edit new parameters that needed, refer to 4 of image
5-1.
image 5-1
5.2 Clear corner setting
There are two modes of clear corner. First mode is used during the programming
process of one path or multiple paths, 1 2 3 of image 5-2 shows the steps; second
mode is used after programming is done, 4 5 6 of image 5-2 show steps.
Take one path programming for instance, 1 of 5-2, first confirm cut-in point, set
length of lead-in line, confirm wire threading point, machining direction and offset
direction. Click clear corner to enter its setting page. Green circle shows present
corner has no clear corner, red circle shows that present corner has clear corner, blue
circle means corner of present corner is set, 4 and 5 of image 5-2 shows. After
20. setting, go back to path programming interface, and finish parameters and other
relative settings to finish the process, 6 of image 5-2 shows.
Image 5-2
Clear corner delay: delay the timing of clear the corner
Extended direction: clear corner
Left clear corner: implement clear corner in left side of cutting path of graph
Right clear corner: implement clear corner in right side of cutting path of graph
No clear corner: no implement of clear corner.
1st cut, 2nd cut, 3rd cut, 4th cut, 5th cut: after selection, implement clear corner of
relative chosen cut.
Select all: select all options of clear corner
Select non: select nothing of clear corner
5.3 Array copy
For the graph that already done path programming, array copy function is available,
as shown in image 5-3.
Step 1: Press “A” of keyboard to enter the step of selecting the graph. Mouse click the
planned graph, which is in green color, then it turns to cyan color when it is selected,
1 and 2 of image 5-3 shows how it looks like.
21. Step 2: enter array setting interface. Input parameters of array, click button to generate
array, refer to 3 and 4 of image 5-3.
Step 3: after confirmation, enter path edit interface, then will find out array is there. If
it needs to delete array graph, left click the mouse the graph, press “Del” key of
keyboard to delete the selected graph, refer to 5 and 6 of image 5-3.
image 5-3
5.4 Appoint cutting sequence
After path programming is done, if there are several graphs and necessary to select
cutting sequence, it must arrange cutting sequence first and then go back to main
interface.
Step 1: for the graphs that programming is already done, click appoint cutting
sequence to enter page of its setting, 1 and 3 of image 5-4.
Step 2: left click the graphs one by one to set sequence, 3 of image 5-4. Except
manually set cutting sequence, there are other options, such as short route, first inner
hole and outer profile, or first outer profile and then inner hole, after cutting of first
22. graph starts, right click the main interface, then it will generate the shortest route, 4
and 5 of image 5-4.
Step 3: click OK to enter file management interface, programmed path can be
previewed, then select present graph to proceed actual cutting 6 of image 5-4.
Image 5-4
23. Chapter 6 cutting parameters setting
Parameters setting includes setting of one path, multiple paths, cone, and cylinder &
6.1 Cutting parameters setting of one path program
Set parameters of one path cutting, refer to image 6-1.
Offset: compensation value of wire, set according practical situation, for one path
cutting, usually offset value= diameter of wire/2+0.01mm(spark gap), for instance,
diameter of new wire is 0.18mm, then use this formula,
offset=0.18mm/2+0.01mm=0.1mm.
Angular arc: arc process at sharp corner
Angular line: straight process at sharp corner
PW: pulse width, also known as high frequency width, it’s high frequency power on
time, bigger PW, bigger cutting energy.
PS: pulse interval, also know s high frequency interval, it’s high frequency power off
time, bigger PS, smaller cutting energy.
TubeNum: numbers of power tube, more tubes, bigger cutting power
WS: wire feeding speed, smaller number, faster speed.
Voltage: machining voltage, for present system, always use high voltage.
Trace: it’s a reference value of distance between wire and workpiece. As wire can’t
touch the workpiece (short circuit happens); neither keep big distance to workpiece,
cutting speed is low if distance is too big.
MaxSpeed: the limitation of Max speed of cutting feed.
All these parameters should be adjusted properly together according to different
material, different thickness and different requirement of finish.
=
image 6-1
6.2 parameters setting of multiple cuts.
Set parameters of multiple cuts, refer to image 6-2.
Paths of cutting: set how many paths to cut
Punch L: if it’s multiple cuts for a male die, as we need to do multiple cuts for the job,
24. so it must keep some part of the job not to be cut off first, keep this portion with
workpiece, after finish multiple cuts of first portion, then cut the remaining portion
with one cut or multiple cuts.
Overcut: distance to cut over the final end point, usually set 0
Cut once at punch: the offset value of remaining portion, usually bigger than offset of
first portion multiple cutting for grinding later on. Select and set value.
Punch end when cut off: pause the cutting before punch L starts.
Pause at punch end: pause the cutting after punch L finishes.
Add lead arc: add tiny arc at cut-in point.
Slope line(0-0.5): length of slope line when change between different cuts of inner
hole. Not usually used.
Outline: process path of out line, i.e. outside profile, male .
Inner: inner hole, inside profile is needed, female.
Pause at punch start: pause the cutting at the point of punch L starts
Pause at punch end: pause the cutting at the point of punch L ends
Cut-1 delay at inner corner: delay process of clear corner
Database: go to database to select discharging parameters
Allowance: set allowance value of each cut.
image 6-2
6.3 Allowance
Refer to image 6-3, the explanation of allowance of different cuts.
Allowance of first cut is 0.05mm, second cut is 0.01mm, and third cut is 0mm, offset
of wire is 0.1mm. That means total allowance is 0.05mm, leave 0.01mm for 2nd
cutting, leave 0 for 3rd
cutting. The last cut should always be 0mm.
25. image 6-3
attention: if it’s one path cutting, it only needs to set allowance value for first cut.
If it’s one path cutting, please use one path programming.
6.4 Cone(taper) parameters setting
There are three different types cone, equal taper, variable and abnormity, as shows in
image, some steps of each type are similar.
Work height: the height of workpiece to cut
Radius of wheel: as wire guide is used, so always set 0
D of up-down wheel: distance between upper and lower wire guide
D of plane-down wheel: distance from downside of workpiece to lower wire guide
Laid abnormity: upper profile is different to lower profile
Variable taper: variable degrees of different segments
Equal taper: equal degree of the taper cutting.
Taper shape positive: upper small, lower big
Taper shape negative: upper big, lower small
Base plane up plane: upper side of wokpiece is considered as programming plane
Base plane down plane: down side of wokpiece is considered as programming plane
image 6-5
26. 6.5 straight and cone(taper) parameters setting
Straight and taper parameters setting, refer to image 6-6. The steps of straight and
taper are separately and explained above. Here only explain some parameters for
combination.
h-object: workpiece height
hc-cylinder: the height of straight cutting
angle: degrees of taper cutting
run order: cylinder(straight) first or cone(taper) first
positive hole: upper small, lower big for angle cutting
negative hole: upper big, lower small for angle cutting
the para-cone is same as cylinder: if select this, it only needs to set parameters for
straight cutting.
image 6-6