Design B-Pillar Through Master Section Development 

Aim:-To Design B-Pillar  Through Master Section Development And Write a Detailed Report.

Given:

-A-Surface 

-Master Sections 

-Distance Between Ribs Should Be 50mm 

-B-Pillar 
The B-Pillar Is The Central Pillar Of The Car. This Pillar Is Actually a Sheet Metal Part Which Is Welded In The Biw Of The Car. The B-Pillar Trim Is Attached To The B-Pillar And Improves The Aesthetic Look Of The Car. Mostly The Trims Are Manufactured By The Injection Molding Process. The Design Of The B-Pillar Is Carefully Done To Make The Part Manufacturable And Usable In The Interior. While Manufacturing a Part Through Injection Molding a Lot Of Defects Can Occur On The Plastic Part Which Will Destroy The Look Of The Panel. The Design Has To Made In Such a Way That All The Errors Can Be Rectified.

                                                         Fig :-Pillars In a Car  

 

 

                                                                                        Fig:- B-Pillar

-Master Section:-

Master Sections Are The Guides For Design Requirements Which Shapes The Component After Technical Styling Of Class A Surfaces

-The Body Frame Is Mainly Composed Of Floor Longitudinal Beams, Upper Side Beams, Door Sill Beams, And Front Cover, The Rear Beam, A-Pillar, B-Pillar, C-Pillar And Other Load-Bearing Beam Structures Are Composed.

Master Sections Are Parameterized Model Of The Vehicle Body That Outlines The Guide For Npd Team

In This Report B Pillar Cover Creation With Detailed Procedures Of Surface Development And Attachement Features Are Covered 

Overview Design Life Cycle Automotive Industry  

 The Stages Of Design Life Cycle Are 

-Concept Sketches:

Concept Sketches Are Rough Idea Of Free Hand Sketch Obtained Through Styling Team And Will Be Used To Prepare The Model. It Is Usually Done Through Pen And Paper And Through  The Painting Software. This Is Will Be Used To Generate The Concept For Preparing The Model By Incorporating Various Styles And Information Obtained Through The Stakeholders

-Class A Creation:

After Finalizing The Concept The Sketches Are Usually Worked In Software’s Such As Auto-Desk Alias To Create Class A Surface 

-Clay Modeling :

The Class A Surface Is Concurrently Worked By Clay Modelers To Brainstorm And Benchmark The Styling Of The Product And Later The Concept Is Validated By Bringing Up a Rough Clay Model And Then It Is Passed On To The Design Team For The Preparation Of New Product Design (Npd) Cad.

-Npd Cad:

This Where The Development Of Surfaces To Parts In Cad Kick Off And Design Engineers Involvement Is Vital In This Stage.

The Designers Will Work On The Input Class A Surfaces Which Are Validated From The Feasibility Team

The Procedure Followed In Creation Of The Plastic New Product Design Are 

Tooling Axis

B Surface Creation

C Surface Creation

Closed Body Creation 

Draft Analysis

-Tooling Axis:

The Given Class A Input Is Analyzed To Envision The Part To Manufacture And Tooling Axis Or Tooling Direction Or Die Line Is The Direction That Molds Pull Apart In Injection Molding. There Are Two Mold Pieces Names Core And Cavity. Thus Tooling Direction Determines Mold Separation And Also Becomes Vital In Developing The Plastic Product Which Is Drafted To Desired Nominal Angle For Feasible Clearance And Ejection Of Final Part From The Mold.

The Steps Followed In Creating Tooling Axis

-A Reference Point Is Created Along The Surface Zero And New Axis System Is Created 

-The X Direction And Y Direction Along The Class A Were Used To Create Tooling Direction

-Finally The Tooling Axis Is Created By Bisecting The Two Lines And It Is Published. Class A Surface As Input Using Surface Operation Commands Class B Is Developed

-The Tooling Axis Determines The Direction Of Class C Boundary Swept With Draft Direction.

-When Viewing From Tooling Direction Normal All The Parts That Are Drafted Should Be Visible So It Gives An Rough Idea To Determine Product Manufacturing In Injection Molding 

In B Pillar Model There Are Two Tooling Directions One On Main Tooling And Other On Lifter Side That Is Used To Eject The Parts During Injection Modling 

Lifter Axis Is Used Because The Attachment Feature Is Bounded By Close Walls 

-A Surface Improvement. 
Before We Start Creating The Closed Body For The B-Pillar We Need To Check The Quality Of The Given A-Surface. The A-Surface Needs To Be Free Of All The Patches Or Error Elements. For This First, We Need To Disassemble The Given Styling Surface And Join It With The Merging Distance Of 0.001mm.

-B Surface Creation

-The Next Step Is To Design B Surface For The Input Which Is Usually The Surface Where All Engineering Aspects And Support Creations Are Done.

-The B Surface Creation Is Performed Using Surface Operations In Catia Which Is An Offset From Class A With Dimension Proportional To The Thickness Of The Part 

-In B Pillar Design  The B Surface Is Offset 2mm From The Input Which Is The Thickness Of The Part 

-The Offset Surface Leads To Surface Degenerations If Rapid  Change In Curvature Or Surface Continuity

-Low Radius Of Class A

-Conic Or Styling Fillets

-The Remedy Is To Untrim , Extrapolate And Trim Or Create Surfaces Using Multi Surface Option And Join 

-Flange Creation 

 -  According To The Master Section, The B-Pillar Has Flanges On Both Sides. The Flanges Have To Be Included In The Design And The A And B Surface Has To Be Modified. The Surfaces Should Match The Master Section.

                                                                                                                    

                                                                                                                                   Fig: A-Surface Flange With Master Section.

-Main Tooling Axis Creation: 
The Tooling Axis Is The Direction In Which The Core Moves. During Injection Molding The Core Is Moved Into The Cavity And Molten Plastic Is Injected. When This Molten Plastic Is Cooled Down Then The Core Is Moved Away From The Cavity. The Direction In Which The Core Moves Is The Tooling Direction For The Part.
To Find The Tooling Direction We Use The Mastersection For The Engineering Feature. Here We Take The Two Boundaries And Find a Bisecting Line Between Them. 

                                                                                                                   

                                                                                                                                               Fig: Main Tooling Direction 

-Manufacturing Feasibility Of The A-Surface (Draft Analysis):

          Draft Analysis Is Used To Check The A-Surface Manufacturing Feasibility. The Tooling Axis Is Used As a Reference. Draft Analysis Checks The Angle At Which The Surface Is With Respect To The Tooling Axis. As We Know For Injection Molding The Draft On The Surface Should Be Positive And Greater Or Equal To 3 Degrees. Areas With The Draft Less Than 3 Degrees Are a Bit Difficult And Costly To Manufacture. 

-C Surface Creation

-The Next Step Is To From The C Surface Which Is An Intermediate Surface Between A And B And Is Used To Give The Closed Surface Appearance To The Design 

-The C Surface Is Swept Using The Profile As Boundary Line Of Class A Which Is The Guide Curve With a Subtype Along Draft Direction.

-The Direction Of The Sweep Is The Tooling Direction Formed Earlier.

-The Draft Angle For The Sweep Operation Is Provided Which Is 3 Degree And Surface Is Swept For Length Above The Thickness Of The Specified Part .

-The C Surfaces Must Be Drafted Outwards From The A Side To Avoid The Parting Line Along The A Surface.

-The C Surface Is Refined Using Smooth Curve Options To Remove The Complexity And Patches Along The Swept Surface.

-Finally The Class A And Class C Surfaces Are Joined Together And Connexity Of Surfaces Should Be Less Than 0.003mm And The Surfaces Are Merged.

C Surface Merged With Class A 

-Closed Body Creation

-The Merged Surface Is Then Trimmed With B Surface To Form The Closed Surface.

-The Closed Surface Is Then Validated To Find The Irregularities Along The Edges And Imperfections Along The Edges Were Then Corrected Using Operation Like Extrapolate And Surface Trim 

-This Closed Surface Is The Outer Skin And Finally The Part Is Formed By Closed Surface In Part Design Workbench 

-The Final Part Is Measured To Validate The Uniform Thickness Of The Part Especially Along The Filleted Edges.

-The Uniform Thickness Ensures That The Part Created Doesnt Form Sink Mark And Flow Lines Along Class A

             

Fig : Flash (Plastic Defect )                             

                  

    Fig:Closing Surface At Angle Of 3 Degrees With Respect To Tooling Direction 

 

 

 

Attachment Features

The Attachment Features Are The Fixation And Location Features That Fixes The Components The Common Attachment Features Used In B Pillar Are

-Doghouse With 4 Way Locator

-Ribs

Doghouse

Using The Master Section The Doghouse Is Created And Then Part Modelled Using Thickness Option

-The 4 Way Locator Is Formed Above The Dog House Which Locates The B Pillar Towards The Mating Surfaces

-The Dog House Design Rules Are

-The Thickness Of The Connecting Surface Towards B Side Should Be 40% Off The Main Thickness

-The Walls Are Drafted With Min 0.5 Degrees Along The Main Tooling Direction

-The Attachement Feature Created Needs a Seperate Tooling Axis To Clear The Part Hence a Lifter Axis Is Used 

-The Surfaces That Are Cleared Along The Lifter Axis Are Also Given a Minumal Draft 

-The Height Of The Attahcment Walls Should Be a Minimum Of 3 Mm

-This Avoids The Plastic Defects On The B Side And Maintains The Texture Of A Side

-The Dog House With Four Way Locator Are Shown Below

                                                       

-Four Way Locators Are Tapered Along The Edges To Create An Entry Point For Locators And The Locator Walls Are Drafted Along The Main Tooling Direction.

The Walls Are Minimum Of Above 0.4  Times Of The Total Thickness To Avoid Shot Incapacity During Plastic Product Creations And The Apex Walls Are Ensured To Enough For Creation Of Parts.

Ribs

Ribs Provide Stifness To The Parts And Can Be To Impart Thougness Whthout Increasing The Part Thickenss And Are Locators And Provide Allignment To The Mating Parts

The Design Rules For Two Way And Four Way Fixtures Are 

-Rib Wall Thickness Should Be 0.4 Times Of Thickness Of The Part

-The Drafted Walls Of Rib Should Be Within 0.5 Degrees

-The Top Height Of Rib Should Be At Least  0.70 Mm Thick To Allow The Molten Plastic To Reach The Top To Avoid Short Shot

-The Thickness Of The Rib, Fillet Radius, Draft And Rib Root Thickness Are Measured And Are Withing The Design Specifications 

 

                                        

                                                                                                              

-In B Pillar The Ribs Are 50mm Apart On Both Sides

-Thus B Pillar Cover Is Surface Development Is Completed And Attachment Features Are Added.

-It Should Be Noted That The Fixation Of Bolt Locators Always Follow 3-2-1 Taylor Principle.

-Translational Movements Along X,Y,Z Axis  ( Positive And Negative)

-Rotational Movement Along X,Y,Z Axis ( Clockwise And Anticlockwise)

-The Improvement In Given B Pillar Could Be An Addition Of Another Dog House At An Extreme End To Satisy The Taylor's Principle And Thermal Stakes Are Provide That Arrests All Degrees Of Freedom And Completly Fits The B Pillar Part

Draft Analysis Procedure

-The Part Created Has To Be Changed To Material Mode In Display Frame

-Then By Enabling Compass Definition The Axis System Is Pan Along The Direction Of The Part And Aligned In Line With The Tooling Direction

-Lock Direction Is Applied That Fixes The Compass And Then The Mode Dialog Box Is Formed By Snapping At Any Point On The Part 

-The Color Codes Are Classified And Draft Angle Are Applied

-Then The Running Point Analysis Is Used To Hover Around The Part To Analyze The Permissible Draft Angles And The Analysis Is Saved

 Draft Analysis Report

-The Draft Report For B Pillar Model Is Shown Below

                                

-The Min. Draft For All A Side Surfaces Are 3 Degrees 

-The Surfaces That Are Below 3 Degree Are Shown Below

-The B Side Surface Analysis Is Shown Below

 

                                  

                                  

                                   

Result

-The Green Color Is Drafted Walls Above 3 Degree

-The Blue Color Is Drafted Walls From 0-3 Degree

-The Red Surfaces Are Negative Degree

-The Analysis Shows The Drafted Walls  Are Above The Par Of 3 Degree Which Is Permissible To Manufacture In The Injection Modeling

-The Running Point Analysis Hovered Along The Drafted Walls Show Parts Are Above 3 And Will Be Easily Cleared From Ejection.

-The Areas In Negative Tooling That Falls Short To The Permisble Design Rules Are Shown

-These Surface Are Corrected Using Surface Operations And Generaly In Oem Class A Improvement Requires Prior Approval From Styling Team And The Draft Report And Analysis Is Used To Get Approval  

-The Tree Structure Are Classified And The Important Features Are Published And The Operations Are Renamed And Classified Into Geometric Subset Shown Below.

                                                                    

                                                                                           Fig:-Tree Structure

Conclusion

Thus a Tooling Axis Is Created And a Open Aesthetic Class A Surface Is Developed Into a Closed Surface With All Plastic Design Rules And a Final Part Body Is Created Out Of It In Catia Surface Work Bench. The Design Is Then Validated With Master Section And Understood The Use Of Master Section Development In Product Design Through Development Of B Pillar Cover Used In The Car Interiors.