Demystifying 3D Printing: Your Ultimate Guide

Welcome to the fascinating world of 3D printing! Whether you’re a curious hobbyist, an aspiring designer, or a tech enthusiast, understanding the different types of 3D printers and their applications is essential. In this comprehensive guide, we’ll unravel the intricacies of various 3D printing technologies, introduce you to top manufacturers, and explore real-world use cases. So, grab your virtual safety goggles, and let’s dive into the layers of innovation!

Table Of Content

  1. Type of 3D Printers
  2. Comparison
  3. Manufacturers
  4. Conclusion
  5. References


1.      Type of 3D Printers

1.1) Stereolithography (SLA)

SLA printers use a laser to draw out each layer from a liquid photopolymer (resin). This process results in high-resolution prints and is commonly used for prototyping and intricate designs.


1.2) Fused Deposition Modeling (FDM)

FDM printers extrude molten thermoplastic filament through a heated nozzle. They are widely available, affordable, and great for hobbyists and beginners. FDM is commonly used for functional prototypes and low-cost production parts.

1.3) Digital Light Processing (DLP)

DLP printers also work with liquid photopolymer resin, but they use a projector chip to project a full layer of curing light. DLP printing is faster than SLA and is suitable for both prototyping and production.

1.4) Selective Laser Sintering (SLS)

SLS printers use a high-energy laser to fuse powder particles (usually nylon or other polymers) layer by layer. SLS is ideal for complex geometries, functional parts, and small production runs.

1.5) Selective Laser Melting (SLM)

Similar to SLS, SLM uses a laser to melt metal powder, creating fully dense metal parts. It’s commonly used in aerospace, automotive, and medical industries for high-strength components.

1.6) Electron Beam Melting (EBM)

EBM is another metal 3D printing technique that uses an electron beam to melt metal powder. It’s particularly suitable for titanium and other high-performance alloys.

1.7) Binder Jetting (BJ)

In binder jetting, a liquid binding agent is selectively deposited onto a powder bed, layer by layer. It’s used for sand casting molds, architectural models, and more.

1.8) Material Jetting (MJ)

MJ printers deposit droplets of liquid photosensitive fusing agent onto a powder bed, which is then cured by light. They offer high precision and are used for detailed models and dental applications.

1.9) Laminated Object Manufacturing (LOM)

LOM printers create objects by layering and bonding sheets of material (usually paper or plastic). They are cost-effective and suitable for large-scale prototypes and architectural models.


2.      Comparison

  1. Precision:
    • Stereolithography (SLA): SLA printers offer high precision due to their laser-based curing process. They can achieve fine details and smooth surfaces.
    • Digital Light Processing (DLP): DLP printers also provide good precision, similar to SLA, but with faster print speeds.
    • Selective Laser Sintering (SLS): SLS printers have excellent precision for complex geometries and functional parts.
    • Material Jetting (MJ): MJ printers offer high precision and are commonly used for detailed models and dental applications.
  1. Cost of 3D Printer:
    • Fused Deposition Modeling (FDM): FDM printers are generally more affordable and widely available. They are great for hobbyists and beginners.
    • Binder Jetting (BJ): BJ printers are cost-effective and used for sand casting molds and architectural models.
    • Laminated Object Manufacturing (LOM): LOM printers are also budget-friendly and suitable for large-scale prototypes.
  1. Cost of Materials:
    • FDM: FDM filament materials (such as PLA or ABS) are relatively inexpensive.
    • SLA/DLP: Resin materials for SLA and DLP printers can be costlier than filaments.
    • SLS: SLS powders (usually nylon) are moderately priced.
    • Metal 3D Printing (SLM/EBM): Metal powders for SLM and EBM are expensive.
  1. Size of 3D Printer:
    • FDM: FDM printers come in various sizes, from small desktop models to large industrial machines.
    • SLS/SLM/EBM: These printers are typically larger due to their powder bed size and build volume.
    • SLA/DLP: SLA and DLP printers vary in size, but desktop versions are common.


3.      Manufacturers

  1. Stereolithography (SLA):
    1. Creality: Creality, a global leader in consumer-level 3D printer ecosystems, offers a range of SLA printers along with their popular FDM models.
    2. Formlabs: Formlabs is known for its high-quality SLA printers, including the Form 3 and Form 3L, which are widely used in various industries.
  1. Fused Deposition Modeling (FDM):
    1. Prusa Research: Prusa Research, founded by Josef Prusa, produces the popular Original Prusa i3 series, known for their reliability and open-source design.
    2. Anycubic: Anycubic manufactures budget-friendly FDM printers like the Anycubic Kobra 2 and Anycubic Photon M3, catering to both beginners and enthusiasts.
  1. Digital Light Processing (DLP):
    • Peopoly: Peopoly offers DLP printers like the Moai series, known for their precision and compatibility with various resins.
    • Wanhao: Wanhao’s Duplicator 7 and Duplicator 8 are well-regarded DLP printers in the market.
  1. Selective Laser Sintering (SLS):
    1. Sintratec: Sintratec produces compact SLS printers suitable for prototyping and small-scale production.
    2. EOS: EOS, a pioneer in industrial 3D printing, offers high-end SLS machines for aerospace, automotive, and medical applications.
  1. Selective Laser Melting (SLM):
    1. Concept Laser (now part of GE Additive): Concept Laser produces SLM machines for metal printing, used in aerospace and medical industries.
    2. Renishaw: Renishaw’s SLM systems are known for their precision and reliability in producing metal parts.
  1. Electron Beam Melting (EBM):
    1. Arcam (now part of GE Additive): Arcam specializes in EBM technology, particularly for aerospace and orthopedic applications.
    2. Sciaky: Sciaky offers large-scale EBM machines for metal additive manufacturing.
  1. Binder Jetting (BJ):
    1. ExOne: ExOne manufactures industrial binder jetting printers, suitable for sand casting molds and metal parts.
    2. Voxeljet: Voxeljet’s VX1000 and VX2000 are popular binder jetting systems for foundry applications.
  1. Material Jetting (MJ):
    1. Stratasys: Stratasys produces PolyJet printers, which use material jetting technology to create high-resolution, multi-material prototypes.
    2. 3D Systems: 3D Systems offers the ProJet series, known for their precision and versatility in material jetting.
  1. Laminated Object Manufacturing (LOM):
    1. Mcor Technologies: Mcor produces LOM printers that use paper as the base material, creating full-color, low-cost models.
    2. ZCorp (now part of 3D Systems): ZCorp was an early player in LOM technology, offering printers for architectural models and prototypes.


4.      Conclusion

In summary, 3D printing technology has evolved significantly, offering a range of options for different needs. If precision and intricate details are crucial, consider SLA or DLP printers. For budget-friendly choices, FDMBinder Jetting, and Laminated Object Manufacturing are excellent. When it comes to material costs, keep in mind that resin-based printers may be pricier than filament-based ones. Finally, consider the size of the printer based on your available space and intended projects. Happy printing!

Download PDF Version Here:
Demystifying 3D Printing: Your Ultimate Guide

5.      References








The Ultimate Guide to choosing best software for product designers


In this succinct article, I delve into the diverse landscape of software options available to product designers. Whether you’re a seasoned professional or just starting out, I’ll guide you through the tools that can elevate your design process. From ideation to high-fidelity creations, let’s explore the best solutions tailored to your needs.

Table of contents:

  1. Introduction
    • The Importance of Choosing the Right Software for Product Design
  1. Understanding Product Design
  • Definition and Importance of Product Design
  • The Role of Software in Product Design
  1. Factors to Consider When Choosing Product Design Software
    • Budget
    • Usability
    • Features
    • Compatibility
    • Support and Community
  1. Sketching Software
    • Adobe Illustrator & Photoshop
    • Krita
    • Autodesk sketchbook
  1. Review of Popular Product Design Software – 3D Modeling
    • Blender3D – 3DsMax – Maya – C4D
    • Rhino 3D
    • Fusion360
    • Solidworks
    • Autodesk Inventor
  1. Review of Popular Product Design Software – Render and presentation
    • Keyshot
    • V-Ray
    • Unreal engine and Unity
    • Other Render Engines
    • Substance 3D Painter
    • Adobe Illustrator & Photoshop
  1. My journey to finding the best software
    • Success Stories of Using the Right Software
    • Lessons Learned from Using the Wrong Software
  1. Combination of software
    • 1st combo: Concept design
    • 2nd combo: Design and prototype
    • 3rd combo: Organic surface related products
  1. The Future of Product Design Software
    • Emerging Trends
    • Impact of Technology Advancements (AI, VR, etc.)
  1. Conclusion
    • Key Takeaways
  1. References

1.    Introduction


The Importance of Choosing the Right Software for Product Design


The importance of selecting the right software for product design cannot be overstated. In the dynamic landscape of innovation, product design software serves as the digital canvas where groundbreaking ideas take shape. It’s the modern-day workshop where designers, engineers, and creatives collaborate to mold and perfect the products that will shape our future. As technology advances, the role of this software extends beyond mere sketching and rendering. It now provides comprehensive solutions that streamline the entire product development process. Here’s why choosing the right software matters:

  1. Efficiency and Creativity Fusion: Product design software bridges creativity and efficiency. It inspires groundbreaking innovation while expediting the journey from idea to final product. By providing a digital environment for drafting, refining, and evaluating designs, it reduces the need for physical prototypes and costly iterations. This results in shorter development cycles, cost savings, and enhanced product quality.
  2. Comprehensive Capabilities: Product design software encompasses an array of tools and features. These include drawing and modeling utilities, simulation and analysis functions, and collaboration capabilities. Designers can work seamlessly within this ecosystem, ensuring the resultant product aligns with stipulated specifications and requirements.
  3. Types of Product Design Software:
    • 2D Design Software: These programs focus on creating two-dimensional designs, essential for graphic design, vector-based illustration, and layout design. Examples include Adobe Illustrator and CorelDRAW.
    • 3D Design Software: Specializing in three-dimensional models, these tools find extensive use in mechanical engineering, architecture, and industrial design. Notable examples are SOLIDWORKS, Autodesk Fusion 360, and Rhino.

Choosing the right software empowers designers to sail confidently in the world of product creation, turning visions into tangible reality. Whether it’s free open-source options like Blender or specialized platforms like Solidworks and Autodesk Inventor, the decision impacts not only the design process but also the future of innovation.

2.    Understanding Product Design


Definition of Product Design:

Product design is the dynamic process that brings a product to life by considering its functionality, aesthetics, and user experience. It’s the harmonious blend of art, science, and technology, resulting in intuitive and visually appealing products that meet specific user needs and contribute to business success. This multidisciplinary field intersects with UX and UI design, engineering, and product management, fostering collaboration and innovation.

Importance of Product Design:

  1. Enhancing User Experience:
    • Well-designed products resonate with users. Whether it’s the sleek lines of a smartphone or the ergonomic handle of a kitchen appliance, good design makes interactions enjoyable.
    • Intuitive interfaces, seamless navigation, and thoughtful features contribute to positive user experiences, fostering customer loyalty and satisfaction.
  2. Driving Innovation and Creativity:
    • Product design serves as a playground for creativity. It encourages experimentation with new materials, technologies, and concepts.
    • By pushing boundaries, businesses discover novel solutions and stay ahead in competitive markets.
  3. Establishing Brand Recognition:
    • Iconic designs become synonymous with brands. Think of Apple’s minimalist aesthetics or Coca-Cola’s timeless bottle shape.
    • A well-designed product reinforces brand identity, making it instantly recognizable and memorable.
  4. Reducing Costs:
    • Effective product design minimizes waste, streamlines manufacturing processes, and optimizes resources.
    • Thoughtful design choices lead to cost savings in production, assembly, and maintenance.

In summary, product design isn’t just about aesthetics; it’s a strategic investment that impacts user satisfaction, brand reputation, and business growth. So, whether you’re crafting digital experiences or tangible goods, prioritize design—it’s your gateway to success.

3.    Factors to Consider When Choosing Product Design Software


  1. Budget

Design software, akin to any other product, comes with a price tag. In the bustling marketplace of digital tools, myriad licensing options cater to diverse user requirements. Whether you’re a fledgling designer, a seasoned architect, or a visionary entrepreneur, there’s a licensing tier tailored just for you. These tiers span from individual licenses to enterprise packages, ensuring accessibility across the spectrum of creative minds.

But wait, there’s more! Beyond the commercial behemoths, a constellation of free and open-source programs twinkles on the horizon. These gems democratize creativity, empowering enthusiasts and startups without hefty budgets. In the following paragraphs, I’ll unveil these stellar contenders—software constellations that beckon you to explore, ideate, and craft without constraints.”

  1. Usability

It is very important to know what do you exactly want from a design software. Do you want to create action figures or something like that? Or you want to create daily functional products like a phone mount. Some of software available like Blender3D or ZBrush gives you the right tools to create organic surfaces with ease, and other software like Solidworks will let you consider all manufacturing needs and techniques that you need (for example all kind of nuts, bolts, screws, surface analysis and so much more).

So first of all, you need to know what you want to make. An organic surface product or a hard surface one with accurate dimensions and tolerance.

Understanding your precise design goals is paramount when selecting software. Are you envisioning intricate action figures or perhaps functional everyday items like a phone mount? The software landscape offers a diverse palette, each brushstroke catering to distinct needs.

  • Organic Surfaces and Artistic Expression:
    1. Blender3Dand ZBrush emerge as virtuoso tools for sculpting organic forms. Their intuitive interfaces empower artists to breathe life into digital clay, shaping curves, textures, and intricate details with grace.
    2. Whether it’s the sinuous contours of a character’s face or the undulating folds of fabric, these software options grant creative freedom.
  • Precision Engineering and Manufacturing Considerations:
    1. SolidWorks, on the other hand, dons the mantle of precision. It’s the drafting table where engineers and industrial designers converge.
    2. Here, every nut, bolt, and screw align meticulously. Surface analyses, material properties, and manufacturability take center stage.
    3. If your vision involves hard surfaces—machined components, enclosures, or architectural elements—SolidWorks stands ready.

So, step one: Define your design destination. Are you embarking on an odyssey of organic surfaces or navigating the precise coordinates of engineering rigor? Your choice will shape not only your designs but also the world they inhabit.

  1. Features
  • User Interface (UI) and Workflow:
    1. Intuitive Interface: A well-designed UI enhances productivity. Look for software with a clean layout, customizable menus, and efficient navigation.
    2. Workflow Efficiency: Consider how seamlessly the software integrates into your existing workflow. Does it support collaboration, version control, and easy file sharing?
  • Modeling Capabilities:
    1. Parametric Modeling: Software like SolidWorksexcels in parametric modeling. It allows you to create designs based on parameters, making changes and iterations a breeze.
    2. Sculpting and Organic Modeling: If you’re sculpting characters, creatures, or artistic forms, explore tools like ZBrushor Blender3D. These excel in organic surfaces.
  • Analysis and Simulation:
    1. Finite Element Analysis (FEA): For engineering applications, FEA tools within software like ANSYSor COMSOL are indispensable. They predict structural behavior and stress distribution.
    2. Fluid Dynamics Simulation: If your designs involve fluid flow (think aerodynamics or water flow), look for software with robust fluid dynamics modules.
  • Rendering and Visualization:
    1. Realistic Rendering: High-quality rendering engines like KeyShotor V-Ray transform 3D models into photorealistic images. Visual appeal matters!
    2. Animation and Walkthroughs: Some software allows you to create animations or interactive walkthroughs. Useful for presentations and marketing.

Remember, the right software aligns with your vision, amplifying your creative prowess. Whether you’re sculpting dreams or engineering precision, choose wisely!

  1. Compatibility
  • Operating System Compatibility:
    1. Consider the operating system (OS) you’re using. Some software is exclusive to Windows, while others thrive on macOS or Linux.
    2. SolidWorks, for instance, predominantly caters to Windows users, whereas Fusion 360spans multiple platforms.
  • File Format Interoperability:
    1. Import and Export: Ensure the software supports common file formats. Look for compatibility with industry standards like STEPIGES, and STL.
    2. Collaboration: If you collaborate with others, seamless file exchange is vital. Choose software that aligns with your team’s tools.
  • Hardware Requirements:
    1. Resource Demands: Different software has varying hardware requirements. Some demand powerful GPUs and ample RAM, while others are more forgiving.
    2. Cloud-Based Solutions: Cloud-based tools like Onshapealleviate local hardware constraints.
  • Integration with Other Tools:
    1. Ecosystem Harmony: Does the software play well with other tools you use? Integration with design libraries, rendering engines, or simulation software matters.
    2. Plugins and Extensions: Explore available plugins and extensions. They enhance functionality and streamline workflows.
  • Industry Standards and Practices:
    1. Industry-Specific Software: Certain fields favor specialized software. Architects lean toward AutoCAD, while game designers embrace Unityor Unreal Engine.
    2. Compliance: If your work aligns with specific industry standards (e.g., ISO certifications), ensure the software complies.

Remember, compatibility isn’t just about software—it’s about harmonizing your creative journey with the digital symphony of tools at your disposal. Choose wisely, and may your designs flourish!

  1. Support and community
  • Official Support Channels:
    1. Responsive Customer Support: When you encounter roadblocks or have technical queries, reliable customer support is invaluable. Look for software providers that offer timely assistance via email, chat, or phone.
    2. Documentation and Knowledge Base: Well-organized documentation, FAQs, and user manuals enhance your self-help journey. A robust knowledge base can be your compass through software intricacies.
  • User Communities and Forums:
    1. Active User Forums: Seek out vibrant online communities where fellow users share insights, troubleshoot issues, and exchange tips. These forums often harbor hidden gems and workarounds.
    2. Social Media Groups: Platforms like Reddit, Stack Exchange, and LinkedIn host specialized groups for software enthusiasts. Join these digital watering holes to tap into collective wisdom.
  • Tutorials and Learning Resources:
    1. Video Tutorials: Platforms like YouTube host a treasure trove of video tutorials. From basic navigation to advanced techniques, these visual guides accelerate your learning curve.
    2. Online Courses: Consider enrolling in structured courses on platforms like Udemy, Coursera, or LinkedIn Learning. Expert instructors guide you through the software’s nuances.
  • Third-Party Plugins and Extensions:
    1. Community-Developed Plugins: Some software ecosystems thrive on third-party plugins. These extend functionality, adding features not native to the core software.
    2. Custom Scripts and Macros: If you’re an advanced user, delve into scripting. Custom macros can automate repetitive tasks and unlock hidden potential.
  • User Feedback and Software Updates:
    • Feedback Channels: Does the software provider actively seek user feedback? Regular updates based on user input indicate a responsive development team.
    • Version History: Investigate the software’s update history. Frequent updates signal ongoing improvements and bug fixes.

Remember, a robust support network isn’t just a safety net—it’s a launchpad for your creative endeavors. Choose software that embraces you as part of its digital family!

4.    Sketching Software


1)    Adobe Photoshop:

Photoshop reigns as the industry-standard photo editing software.

  • Pixel Powerhouse:
    • Raster-based images thrive here. Photoshop handles detailed colors, shading, and precise edits.
    • From retouching to mind-bending photo art, it’s your canvas.
  • Photo Composites and Collages:
    • Layer images, blend elements, and create magic.
    • Craft original visuals from different photo files.
  • Raster Graphics Brilliance:
    • Photoshop’s pixel-based approach excels in detailed textures.
    • Ideal for enhancing photos, correcting lighting, and making subjects look their absolute best.
  • Seamless Integration with Illustrator:
    • Both apps play well together within Adobe Creative Cloud.
    • Illustrator’s vector art can fit into larger Photoshop projects, and vice versa.

In my opinion Photoshop is a good choice for digital sketch and package while illustrator will be a good tool for designing package or any type of brand identity graphics that you need.

2)    Krita

Krita | The Free and Open-Source Canvas

  • Purpose: Krita is a free, open-source program tailored for digital illustration, animation, and painting.
  • Digital Painting: It’s a playground for artists, offering an impressive brush library and customizable tools.
  • Ease of Use: Krita’s flow is akin to Photoshop but simpler, making it accessible for beginners.
  • Compatibility: Works across various operating systems.
  • Pricing: Krita wins here—it’s free!
  • Photoshop vs. Krita: The Showdown:
  • Features: Photoshop is a powerhouse with an extensive feature set, including camera raw and other tools for photo editing. Krita does less but excels in digital painting and sketching.
  • Usability: Krita’s user-friendly interface lets you dive in without getting lost.
  • Support: Photoshop’s robust support system trumps Krita’s volunteer-run service.
  • Users: Photoshop boasts a broader user base, while Krita caters to hobbyists and illustrators.
  • Longevity: Adobe Photoshop’s business-driven innovation ensures long-term viability.

In summary, Krita is the free-spirited sibling, perfect for digital artists, while Photoshop remains the industry standard for graphic design and photo manipulation. Choose wisely based on your creative journey!

2)    SketchBook

Autodesk Sketchbook is a powerful tool that caters to digital artists, illustrators, and designers. Here’s why it stands out:

  • Intuitive User Interface (UI):
  • SketchBook boasts an incredible UIthat feels like an extension of your creativity. The interface is clean, customizable, and designed for seamless navigation.
  • Whether you’re a seasoned artist or a beginner, the intuitive layout ensures a smooth workflow.
    • Customizable Brushes and Tools:
  • The brush library in SketchBook is a treasure trove. From realistic pencils to vibrant watercolors, you’ll find the perfect brush for every stroke.
  • Customize brushes, adjust opacity, and experiment freely.
    • Professional-Grade Perspective Tools:
  • Architects, concept artists, and illustrators benefit from SketchBook’s perspective tools. Create accurate vanishing points, grids, and 3D scenes effortlessly.
  • Achieve depth and realism in your designs.
    • Cross-Platform Compatibility:
  • SketchBook works seamlessly across various platforms—Windows, macOS, iOS, and Android.
  • Sync your work across devices and continue your creative journey wherever you go.
    • Affordability and Potential:
  • Unlike some premium software, SketchBook is inexpensive. It offers incredible value for its price.
  • Whether you’re sketching, painting, or creating concept art, SketchBook has the potential to elevate your work.

In my opinion sketchbook is the fastest and most user-friendly software for digital sketch. You almost don’t need to learn anything in this software. When you open sketchbook for the first time everything is familiar to you, there isn’t any unnecessary tools or feature, everything and every tool is there if it is only related to sketching and nothing else.

In summary, Autodesk SketchBook is a unique blend of power, simplicity, and artistic freedom. Whether you’re a hobbyist or a professional, this canvas awaits your imagination!

5.    Review of Popular Product Design Software – 3D Modeling




  • Blender3D – 3DsMax – Maya – C4D
  • Rhino 3D
  • Fusion360
  • Solidworks
  • Autodesk Inventor

In the following tables I mentioned every good software available in the market in a short but useful way.

Blender 3D

  • 3D Modeling Capability:
    1. Blender3D: Robust modeling capabilities, including parametric design using modifiers and nodes.
    2. 3DsMax: Excellent for modeling, texturing, and meshing. Not inherently parametric.
    3. Maya: Primarily geared toward animation but offers solid modeling features.
    4. Cinema4D: Strong modeling tools, especially for creative applications.
    5. Rhino 3D: NURBS-based modeling, precise curves, and freeform surfaces.
    6. Fusion 360: Parametric modeling with history-based design.
    7. Solidworks: Industry standard for parametric modeling, especially for mechanical design.
    8. Autodesk Inventor: Specialized for product design and engineering.
  • User Interface (UI):
    1. Blender3D: Customizable UI, suitable for both beginners and experts.
    2. 3DsMax: Clean interface, automation features.
    3. Maya: Versatile UI, used in film, TV, and games.
    4. Cinema4D: User-friendly, intuitive layout.
    5. Rhino 3D: Navigable interface, especially for NURBS modeling.
    6. Fusion 360: Modern UI, cloud-based collaboration.
    7. Solidworks: Industry-standard UI for mechanical design.
    8. Autodesk Inventor: Familiar interface for engineers.
  • Analysis and Simulation:
    1. Blender3D: Limited built-in simulation tools.
    2. 3DsMax: Offers fluid, particle, and physics simulations.
    3. Maya: Extensive simulation capabilities (fluids, cloth, dynamics).
    4. Cinema4D: Good for creative simulations (cloth, smoke, fire).
    5. Rhino 3D: Lacks advanced simulation tools.
    6. Fusion 360: Simulation for mechanical designs.
    7. Solidworks: Robust simulation for engineering.
    8. Autodesk Inventor: Simulation for product design and engineering.
  • Rendering and Visualization:
    • Blender3D: Cycles X for fast rendering.
    • 3DsMax: V-Ray integration, photorealistic rendering.
    • Maya: Arnold renderer, widely used in VFX.
    • Cinema4D: Advanced rendering options.
    • Rhino 3D: Basic rendering capabilities.
    • Fusion 360: Real-time rendering.
    • Solidworks: Basic rendering, focused on engineering.
    • Autodesk Inventor: Limited rendering features.
  • Operating System Capability:
    1. All tools support Windows, some also on macOS and Linux.
  • Hardware Requirements:
    1. Vary by tool, but generally require multicore CPUs, 4-8 GB RAM, and dedicated GPUs.
  • File Format Interoperability:
    1. All tools support common formats (STL, STEP, IGES).
  • Industry Standards Capability:
    1. Solidworksand Autodesk Inventor excel in engineering.
    2. Mayadominates film and animation.
  • Tutorials and Courses (Community):
    1. Blender3D: Abundant tutorials and active community.
    2. Mayaand 3DsMax: Extensive learning resources.
    3. Cinema4D: Growing community.
    4. Rhino 3D: Niche community.
    5. Fusion 360: Autodesk’s resources.
    6. Solidworksand Autodesk Inventor: Industry-specific training.
  • Open Source or Third-Party Plugins:
    1. Blender3D: Open source, extensive plugin support.
    2. Others: Limited open-source options, but plugins available.
  • Pricing and Licenses:
    1. Blender3D: Free and open-source.
    2. Others: Commercial licenses, varying costs.

Choose wisely based on your specific needs and industry focus!


6.    Review of Popular Product Design Software – Render and presentation

  • Keyshot
  • V- Ray
  • Unreal engine and Unity
  • Other Render Engines
  • Substance 3D Painter
  • Adobe Illustrator & Photoshop

1)   KeyShot


  • Realism and Output Quality: KeyShot provides high-quality, realistic renders with real-time feedback.
  • User Interface: KeyShot has an intuitive, user-friendly interface.
  • Analysis and Simulation: Limited simulation capabilities.
  • Rendering and Visualization: Excellent for product visualization and marketing materials.
  • Operating System Capability: Works on both Windows and macOS.
  • Hardware Requirements: Not resource-intensive; runs on most systems.
  • File Format Interoperability: Supports various file formats.
  • Industry Standards Capability: Commonly used in product design and marketing.
  • Tutorials and Courses: Active community and online tutorials.
  • Open Source or Plugins: Not open source, but supports plugins.
  • Pricing and Licenses: Commercial licenses, annual subscription model.

2)   V-Ray


V-Ray is not a standalone software and it is installing as a plugin
  • Realism and Output Quality: V-Ray offers photorealistic rendering with advanced features.
  • User Interface: Complex UI, integrates with various 3D software.
  • Analysis and Simulation: Extensive simulation capabilities (fluids, particles, etc.).
  • Rendering and Visualization: Widely used in architectural visualization and film.
  • Operating System Capability: Available on Windows, macOS, and Linux.
  • Hardware Requirements: Requires powerful GPUs and CPUs.
  • File Format Interoperability: Supports common formats.
  • Industry Standards Capability: Strong presence in architectural visualization.
  • Tutorials and Courses: Abundant resources available.
  • Open Source or Plugins: Not open source, but supports plugins.
  • Pricing and Licenses: Commercial licenses, varying costs.

3)   Unreal Engine and Unity



Unreal engine is a game engine but it can be used as a good real time render engine

  • Realism and Output Quality: Both engines offer high-quality real-time rendering.
  • User Interface: Unreal Engine has a complex UI, while Unity is more user-friendly.
  • Analysis and Simulation: Unreal Engine excels in interactive simulations.
  • Rendering and Visualization: Used in gaming, virtual reality, and architectural visualization.
  • Operating System Capability: Both support Windows and macOS.
  • Hardware Requirements: Require powerful GPUs for real-time rendering.
  • File Format Interoperability: Support common formats.
  • Industry Standards Capability: Unreal Engine dominates gaming and film.
  • Tutorials and Courses: Abundant resources for both engines.
  • Open Source or Plugins: Both have active communities and support plugins.
  • Pricing and Licenses: Unreal Engine is free with royalties; Unity has various licensing options.

4)   Substance 3D Painter



Substance Painter

  • Realism and Output Quality: Excellent for texturing and material creation.
  • User Interface: User-friendly, node-based interface.
  • Analysis and Simulation: Not for simulation; focused on texturing.
  • Rendering and Visualization: Used in game development and film.
  • Operating System Capability: Available on Windows and macOS.
  • Hardware Requirements: Moderate hardware requirements.
  • File Format Interoperability: Supports various formats.
  • Industry Standards Capability: Commonly used in game development.
  • Tutorials and Courses: Active community and tutorials.
  • Open Source or Plugins: Not open source, but supports plugins.
  • Pricing and Licenses: Commercial licenses, subscription-based.

5)   Adobe Illustrator & Photoshop


  • Realism and Output Quality: Photoshop excels in photo manipulation; Illustrator for vector graphics.
  • User Interface: Both have user-friendly interfaces.
  • Analysis and Simulation: Not for simulation; focused on design and editing.
  • Rendering and Visualization: Used in graphic design, advertising, and digital art.
  • Operating System Capability: Available on Windows and macOS.
  • Hardware Requirements: Moderate hardware requirements.
  • File Format Interoperability: Support common formats.
  • Industry Standards Capability: Widely used in design and creative industries.
  • Tutorials and Courses: Abundant resources for both.
  • Open Source or Plugins: Not open source, but supports plugins.
  • Pricing and Licenses: Commercial licenses, subscription-based.

Choose the tool that aligns best with your specific needs and workflow!

7.    My journey to finding the best software



Success Stories of Using the Right Software

As I prepared to begin my bachelor’s studies in Industrial Design, I took the initiative to sign up for a Rhino3D course. At that time, I had no prior experience with this type of software, and Rhino served as my entry point into understanding 3D space and its applications. Over the course of a year, I immersed myself in Rhino, exploring its capabilities.

However, when I started searching for local jobs in the CAD field, I noticed a prevailing preference for Solidworks. Curious, I inquired why this was the case. The response was straightforward: “We have extensive experience with Solidworks, and it offers a wealth of resources—tutorials, expert knowledge, and ready-to-use models.” Intrigued, I decided to delve into learning Solidworks.

Surprisingly, my transition to Solidworks was smoother than expected. Having already grasped the fundamentals of 3D space and its vocabulary (including terms like fillet, chamfer, and extrude), I adapted quickly. Solidworks, with its myriad features, is a powerful software suite. While achieving mastery may take considerable time, entering the job market or using it for personal or university projects doesn’t require an extensive commitment. In fact, dedicating just 1 month and spending 2-3 hours per day can yield significant results.

My advice? Begin by mastering the basics, and let the more advanced aspects unfold gradually. Time, indeed, is the best teacher. Continuously challenge yourself, seek knowledge through research, and consider leveraging AI assistance when needed.

After a year and a half, I found myself revisiting the initial motivation that led me into the field of Industrial Design. My unwavering goal had always been to become a transportation designer. At that moment, armed with a solid grasp of 3D modeling using Rhino and Solidworks, I realized that creating a car model within these software packages would demand an enormous investment of time. My attempt at modeling my very first car design in Rhino took two months, and the results were far from satisfactory. The surface quality was lacking, plagued by multiple trims and splits.

It was during this period of reflection that I recognized the need for specialized software tailored specifically to transportation design—a tool that could deliver superior quality in a more efficient process. My search led me to two promising options: Blender3D and Alias Auto Studio.

Let’s delve into what I discovered:

  1. Blender3D: This mesh-based program stood out for its speed and flexibility. Mesh-based software allows designers to shape forms with ease, unencumbered by rigid constraints. Blender3D, in particular, offered several compelling advantages:
  • Freedom: It liberates designers from the confines of predefined frames, allowing them to explore their creativity.
  • Speed: The process is lightning-fast, enabling rapid iterations and adjustments.
  • Community: Blender boasts a vibrant and extensive community. If you encounter any roadblocks, there’s a 99% chancethat a helpful tutorial or discussion topic exists to guide you.

Notably, Blender3D is not only free and open-source, but it also has a minimal impact on system resources. Its lightweight nature ensures smooth performance even on modest hardware.

  1. Alias Auto Studio: As the industry standard for transportation design, Alias Auto Studio commands respect. However, it comes with its own set of challenges. Learning Alias is a formidable task, especially when compared to the relatively accessible Blender. But my ambitions extended beyond transportation design—I wanted to create characters, robots, and diverse 3D models. Hence, I made a deliberate choice: I would master Blender first.

In summary, my journey involved weighing the allure of industry standards against the practicality of a versatile, community-driven tool. Blender3D won my heart, and it continues to serve as my creative companion on this exciting design voyage.

Throughout my journey, I’ve explored various software tools for presentation and rendering. Initially, I stumbled upon the concept of “rendering” and sought a solution to enhance the visual appeal of my 3D models. That’s when I discovered KeyShot—an expensive standalone render engine that seamlessly integrated into my workflow. With KeyShot, I could effortlessly apply materials, adjust camera angles, and hit the render button to achieve stunning results.

KeyShot served as my primary rendering software, complemented by Photoshop for post-processing tasks. I meticulously fine-tuned colors, combined renders, and added text and titles to elevate my presentations. However, my trajectory shifted when I delved into Blender. This powerful 3D software introduced me to its native render engines: Cycles and EEVEE. Suddenly, exporting objects to KeyShot became unnecessary. I could design directly within Blender, leveraging its efficient render engines—no more export-related headaches.

But my exploration didn’t stop there. Enter Substance 3D Painter—a specialized 3D texturing software with a user interface reminiscent of Photoshop. Its promise of achieving hyper-realistic renders intrigued me. In a mere three weeks, I immersed myself in Substance Painter, experimenting with its features. Although it offered an Iray render engine, I found greater satisfaction sticking with Blender’s Cycles.

Fast-forward three years, and my journey has been a rollercoaster of successes and setbacks. Currently, I’m immersed in Alias Auto Studio, wondering if it’s my final destination or merely a stepping stone. The truth is, you never truly know what suits you best until you try it firsthand. So, stay focused on your goals, embrace continuous learning, and remember that mistakes are valuable.

Lessons Learned from Using the Wrong Software

Duplicate software can be frustrating. For instance, consider Blender and 3ds Max. I initially experimented with Blender, followed by a brief trial of 3ds Max. These semi-identical tools ended up consuming valuable time. Looking back, I realize that investing that time solely in Blender would have been more productive. But as they say, you never truly know until you try!

In hindsight, I wish I had been aware of Solidworks—an industry-standard software—before embarking on my journey with Rhino 3D. Although Rhino later incorporated SubD and Grasshopper to enhance its capabilities, Solidworks remains a robust alternative. (For those who find Solidworks UI less appealing, Autodesk Inventor offers a similar experience.)

Reflecting on my experience, I recognize two key mistakes: learning duplicate software and lacking awareness of superior alternatives when I initially started learning. Take these lessons to heart, and may they guide you toward optimal results.

8.    Combination of software

Now, let’s explore some powerful software combinations for various design tasks:

  • Concept Design Combo:
  1. Blender3D: Ideal for 3D modeling, rendering, and animation (You can also use any other mesh-based software, such as 3ds Max).
  2. Photoshop: Perfect for retouching and presentation.
  3. Video Editing Software(Davinci or Premiere): Enhance your concept presentations further.
  • Design and Prototype Combo:
  1. Solidworks or Inventor: Choose either for 3D modeling.
  2. KeyShot: Excellent for rendering.
  3. Photoshop: Essential for retouching and presentation.
  • Organic Surface-Related Products Combo:
    1. Blender3D: Great for 3D modeling, rendering, and animation.
    2. Photoshop: Use it for retouching and presentation.
    3. Ultimaker Cura: If you need to prepare your models for 3D printing.

9.    The Future of Product Design Software

Emerging Trends

  • Augmented Reality (AR) and Virtual Reality (VR):
    1. AR and VR technologies are revolutionizing product design. They create immersive experiences for consumers, allowing them to visualize products in their environment before purchase.
    2. Designers can use AR and VR for virtual prototyping, testing ideas, and gathering user feedback. These technologies enhance collaboration and accelerate the design process.
  • Artificial Intelligence (AI) in Design:
    1. AI analyzes customer data, identifies patterns, and informs design decisions. It prioritizes features based on user preferences.
    2. AI-powered tools automate repetitive tasks, generate design ideas, and recognize errors. Virtual prototypes save time and resources.
    3. Personalized product recommendations enhance user experiences.
  • Sustainability and Eco-Design:
    1. Increasing awareness of environmental impact drives sustainable design practices.
    2. Software will integrate life cycle assessments, material sourcing, and eco-friendly manufacturing processes.
    3. Circular design principles—reducing waste, reusing materials—will shape future software features.
  • Generative Design:
    • AI-driven generative design explores countless design variations based on constraints and goals.
    • It optimizes structures, reduces material usage, and uncovers innovative solutions.
    • Expect generative algorithms to become standard tools for designers.

Impact of Technology Advancements (AI, VR, etc.)

  • 3D Printing and Advanced Materials:
    • 3D printing enables rapid prototyping and customized production.
    • New materials—biodegradable, lightweight, conductive—expand design possibilities.
    • Software will seamlessly integrate with additive manufacturing processes.
  • Computational Design and Parametric Modeling:
    • Algorithms drive form-finding and optimization.
    • Parametric tools adapt designs to changing parameters, such as user preferences or environmental conditions.
    • Designers will harness computational power for complex geometries and adaptive structures.
  • Collaborative Platforms and Cloud-Based Workflows:
    • Distributed teams benefit from real-time collaboration.
    • Cloud-based software ensures seamless data sharing, version control, and scalability.
    • Expect more robust collaboration features in future design tools.
  • Human-Centered Design and Inclusivity:
    • Software will prioritize accessibility, usability, and diverse user needs.
    • Inclusive design principles will guide interface development.
    • AI-driven empathy maps and user personas will enhance user-centric design.
  • Ethical Design and Privacy Considerations:
    • Designers will address ethical dilemmas related to AI bias, data privacy, and unintended consequences.
    • Software will embed ethical guidelines and transparency features.

In summary, the future of product design software lies at the intersection of technology, sustainability, and user-centricity. As these trends unfold, designers will wield powerful tools to shape a more innovative and responsible world.

10. Conclusion

Key Takeaways

  • Identify your precise objectiveswhen utilizing software.
  • Explore superior alternativesbefore making a decision.
  • Select the optimal combination of softwareto enhance your design workflow.
  • Begin with fundamental conceptsand expand your knowledge throughout your journey.
  • Avoid overspending; numerous high-quality software options are available for free.
  • Commit to continuous learning.

This encapsulates my insights in the realm of product design and 3D modeling. The necessities and educational trajectory are distinct for each individual. You may require something that I have not covered in this extensive article, yet there is no challenge that is insurmountable. I have succeeded, as have many others, and so can you.

Should you require any assistance, please feel free to reach out via email. I am always eager to offer my support.



Download The PDF of this article from the link below:
The Ultimate Guide to choosing best software for product designers

11. References


Giorgetto Giugiaro: A Design Journey in Automotive Excellence

Engines roared, curves danced, and innovation took the wheel. Welcome to the captivating world of Giorgetto Giugiaro, where lines on paper transformed into iconic cars that graced our roads. Buckle up as we embark on a design odyssey, tracing Giugiaro’s path from pencil sketches to automotive masterpieces.

Table of Contents

  1. Introduction
  2. Early Career and Influences
  3. Design Evolution
  4. Iconic Cars by Giugiaro
  5. Beyond Cars: Diverse Creations
  6. Legacy and Recognition

1. Introduction

Giorgetto Giugiaro, an Italian automotive designer, has left an indelible mark on the world of cars. His career spans decades, and his work ranges from supercars to everyday vehicles. Let’s delve into the life and creations of this design maestro.

2. Early Career and Influences

Born on August 7, 1938, in Garessio, Italy, Giugiaro’s journey began with tastefully arched and curving shapes. His early designs included the Alfa Romeo 105/115 Series Coupés, the De Tomaso Mangusta, Iso Grifo, and Maserati Ghibli. These cars exuded elegance and sophistication.

3. Design Evolution

Giugiaro’s style evolved over time. In the late 1960s, he embraced angular designs, leading to the iconic “folded paper” era of the 1970s. Straight-lined masterpieces like the BMW M1, Lotus Esprit S1, and Maserati Bora followed suit. In the 1990s, he returned to curvier forms, exemplified by the Lamborghini Calà, Maserati Spyder, and Ferrari GG50.

4. Iconic Cars by Giugiaro

  • Volkswagen Golf Mk1: Perhaps his most commercially successful creation, the Golf Mk1 revolutionized compact cars.
  • DMC DeLorean: The futuristic stainless steel car immortalized in the “Back to the Future” movie series.
  • Lotus Esprit S1: Sleek, angular, and synonymous with James Bond.
  • Maserati Quattroporte: A luxurious sports sedan that blended performance and elegance.

5. Beyond Cars: Diverse Creations

Giugiaro’s talents extended beyond automotive design:

  • Camera Bodies for Nikon: His eye for aesthetics influenced camera design.
  • Organ of Lausanne Cathedral: Comprising 7,000 pipes, a harmonious blend of art and music.
  • New Pasta Shape “Marille”: Yes, even pasta felt his creative touch!

6. Legacy and Recognition

  • Car Designer of the Century (1999): A well-deserved accolade.
  • Automotive Hall of Fame (2002): Inducted for his profound impact.
  • Compasso d’Oro Award (six times): His industrial design excellence celebrated.

Giorgetto Giugiaro’s legacy transcends cars; it’s a symphony of form, function, and innovation. His designs continue to inspire generations of creators. So, next time you admire a sleek automobile or capture a moment with your camera, remember the maestro behind the scenes: Giorgetto Giugiaro.


Battista “Pinin” Farina: A Legacy in Automotive Design

Buckle up, fellow car enthusiasts! In the exhilarating world of automotive design, one name stands tall: Battista “Pinin” Farina. His legacy is etched in the sleek curves of iconic Ferraris and the timeless elegance of Alfa Romeos. Join me on a journey through the life of this visionary artist, where passion met precision, and dreams took the wheel.

Table of Contents

  1. Introduction
  2. Early Life and Passion for Cars
  3. Founding Carrozzeria Pinin Farina
  4. Collaboration with Ferrari
  5. The Last Design: Alfa Romeo 1600 Duetto
  6. Personal Life and Honors
  7. Legacy and Namesake

1. Introduction

Battista “Pinin” Farina, an Italian automobile designer, left an indelible mark on the automotive world. His visionary designs and commitment to excellence continue to inspire generations of car enthusiasts. In this article, we delve into his remarkable career and the iconic cars he shaped.

2. Early Life and Passion for Cars

Born on November 2, 1893, in Cortanze, Italy, Battista Farina was the tenth of eleven children. His nickname, “Pinin,” affectionately referred to him as the youngest sibling. At just 5 feet tall, he may have been small in stature, but his passion for cars was immense. His journey began at his brother Giovanni’s body shop, where he honed his skills and nurtured his love for automotive design.

3. Founding Carrozzeria Pinin Farina

In 1930, Battista established Carrozzeria Pinin Farina, focusing on crafting exquisite car bodies. His creations quickly gained prominence, rivaled only by Carrozzeria Touring during the 1930s. The name “Pininfarina” became synonymous with elegance, aerodynamics, and timeless beauty.

4. Collaboration with Ferrari

Battista’s collaboration with Ferrari, starting in 1952, remains legendary. Although much of the work was overseen by his son, Sergio, the Pininfarina touch graced iconic Ferraris like the 250 GT, the Testarossa, and the Dino. These masterpieces blended performance with aesthetics, setting new standards for automotive design.

5. The Last Design: Alfa Romeo 1600 Duetto

In the early 1960s, Battista’s creativity culminated in the Alfa Romeo 1600 Duetto. Collaborating with Aldo Brovarone, he unveiled this elegant convertible at the Geneva Motor Show in March 1966. Tragically, Battista passed away less than a month later, leaving behind a legacy that endures.

6. Personal Life and Honors

In 1961, he officially changed his name to “Battista Pininfarina.” His nephew, Nino Farina, became the first Formula One world champion. In 2004, Battista was inducted into the Automotive Hall of Fame, a testament to his immense contributions.

7. Legacy and Namesake

Today, the Pininfarina Battista, an all-electric sports car, pays homage to the man who revolutionized automotive aesthetics. Battista Farina’s dream lives on, inspiring designers and enthusiasts alike.

Battista “Pinin” Farina’s legacy transcends time, reminding us that passion and vision can shape the future of mobility. As we admire the sleek lines of a Pininfarina creation, we honor the man who turned dreams into reality.


  1. Mitchell, Paul (November 2016). “Marking a Half Century of the Alfa Romeo Duetto.” Sports Car Market, 28(11), 70.
  2. “Battista ‘Pinin’ Farina.” Automotive Hall of Fame. Retrieved August 28, 2023.
  3. “Battista Announced as Name of the Most Powerful Italian Performance Car Ever.” Automobili Pininfarina. Retrieved August 28, 2023.

Ian Callum: A Visionary in Automotive Design

Table of Contents

  1. Introduction
  2. From Scotland to the World
  3. Ford: Where It All Began
  4. Aston Martin: The DB7 and Beyond
  5. Jaguar: Shaping Elegance
  6. Post-Jaguar Ventures
  7. Conclusion

1. Introduction

Ian Callum, the maestro behind some of the most captivating automotive designs, is a name whispered reverently in car enthusiasts’ circles. Buckle up as we embark on a journey through his life, his creations, and the indelible tire tracks he left on the road of automotive history.


2. From Scotland to the World

Born in Dumfries, Scotland, in 1954, Callum’s passion for cars ignited at an early age. At just 14, he submitted a car design to Jaguar, dreaming of a future in automotive design. His journey took him from the School of Transportation Design in Coventry to the Glasgow School of Art, where he honed his craft. Armed with a post-graduate master’s degree in Vehicle Design from the Royal College of Art, Callum was ready to leave his mark.

3. Ford: Where It All Began

From 1979 to 1990, Callum’s creative genius graced Ford’s design studios. His fingerprints adorned everything from steering wheels to image-defining models like the RS200 and Escort RS Cosworth. Collaborating with fellow designer Peter Horbury, he etched his name into automotive lore. But it was the Escort RS Cosworth that truly set his heart racing—a design he still holds dear.

4. Aston Martin: The DB7 and Beyond

In 1990, Callum embarked on a new adventure, joining forces with Peter Stevens and Tom Walkinshaw to form TWR Design. Here, he played a pivotal role in shaping the iconic Aston Martin DB7. Its sensuous lines and timeless elegance remain etched in our collective memory. But Callum didn’t stop there; he also lent his magic touch to the Aston Martin Vanquish and the V12-powered DB7 Vantage.

5. Jaguar: Shaping Elegance

In 1999, the baton passed to Callum as he stepped into Geoff Lawson’s shoes at Jaguar. His tenure witnessed the birth of automotive poetry—the Jaguar XK, the sultry F-Type, and the groundbreaking I-PACE. Each curve, each silhouette bore his signature. As the Director of Design, he wove elegance and performance into the very fabric of Jaguar.


6. Post-Jaguar Ventures

But Callum’s journey didn’t end with Jaguar. In 2019, he founded his eponymous design company, Callum. His canvas expanded beyond cars, touching everything from product design to the future of mobility. The man who once stood in a “little tin shed” in Kidlington now stands tall as an industry icon.

7. Conclusion

Ian Callum’s legacy transcends metal and rubber. It’s about daring to dream, pushing boundaries, and creating art on wheels. So, the next time you admire a sleek Jaguar or marvel at an Aston Martin’s grace, remember that behind those lines lies the spirit of Ian Callum—a visionary who turned steel into symphonies.

As the sun sets on his illustrious career, Ian Callum’s designs continue to race toward eternity. 🚗✨


Chris Bangle: A Maverick in Automotive Design

Chris Bangle: A Maverick in Automotive Design

Revving engines, sleek curves, and daring lines—these are the hallmarks of Chris Bangle’s legacy. Buckle up as we explore the life and designs of the man who dared to reshape the automotive world.


Table of Contents

  1. Introduction
  2. Early Life and Education
  3. Career at Opel and Fiat
  4. The BMW Era
  5. Controversial Designs
  6. Legacy and Post-BMW Ventures
  7. Conclusion

1. Introduction

Chris Bangle, an American automobile designer, is a name that evokes strong reactions. His bold and unconventional designs have left an indelible mark on the automotive industry. Let’s delve into his fascinating journey and explore the cars he shaped.


2. Early Life and Education

Born in Ravenna, Ohio, in 1956, Bangle’s path to automotive design was anything but conventional. Initially considering a career as a Methodist minister, he eventually pursued his passion for design. Bangle attended the Art Center College of Design in Pasadena, California, where he honed his skills and earned a Bachelor of Science degree.

3. Career at Opel and Fiat

Bangle’s career took off at Opel in Germany, where he worked from 1981 to 1985. His early designs included the interior of the Opel Junior concept car. Later, he moved to Fiat in Italy, contributing to the second-generation Fiat Panda and designing the Fiat Coupé and Alfa Romeo 145.

4. The BMW Era

In 1992, Bangle became the first American Chief of Design at BMW. His tenure revolutionized the brand’s aesthetics. Notable designs under his leadership include:

  • BMW Z9 Gran Turismo Concept
  • BMW Z4
  • 1, 3, 5, 6, and 7 Series
  • X3, X5, and X6 SUVs
  • BMW Gina Concept Car

Despite controversy, BMW’s global sales surged during the Bangle era, solidifying his impact.

5. Controversial Designs

Bangle’s styling themes sparked intense debate. His “flame surfacing” approach, inspired by architect Frank Gehry, challenged traditional norms. The E65 7 Series, with its daring lines, epitomized this boldness. Bangle urged critics to see his designs in person, emphasizing their real-world appeal.


6. Legacy and Post-BMW Ventures

After leaving BMW in 2009, Bangle founded his firm, Bangle and Associates, based in Clavesana, Italy. His influence extended beyond cars, collaborating with technology companies like Samsung. Love him or loathe him, Bangle’s legacy endures.

7. Conclusion

Chris Bangle’s unapologetic creativity reshaped automotive design. His legacy lies not only in the cars he penned but also in challenging conventions. Whether you admire his work or not, there’s no denying that Chris Bangle left an indelible tire track on the road of automotive history.

Remember, the next time you see a BMW with daring lines, you might just be witnessing a touch of Bangle magic. 🚗✨


Can Blender 3D Print? A Guide to Blender’s 3D Printing Features

Can Blender 3D Print? A Guide to Blender’s 3D Printing Features

Table of Contents

  1. Introduction
  2. Modeling for 3D Printing
  3. UV Unwrapping and Texture Mapping
  4. Exporting for 3D Printing
  5. Slicing and G-Code Generation
  6. Conclusion


Blender, the versatile open-source 3D modeling software, is not only a powerful tool for creating stunning visual effects and animations but also an excellent choice for 3D printing enthusiasts. In this article, we’ll explore Blender’s features that make it a valuable asset in the world of additive manufacturing.

1. Modeling for 3D Printing

1.1. Precise Geometry Creation

Blender allows you to create intricate 3D models with precision. Its robust modeling tools, including extrusion, beveling, and boolean operations, enable you to design complex shapes suitable for 3D printing.

1.2. Mesh Cleanup and Repair

Before sending your model to the printer, Blender helps you identify and fix issues like non-manifold geometry, intersecting faces, and holes. Here’s a quick step-by-step tutorial to enable the “3D Print Toolbox” add-on in Blender:

  1. Open Blender.
  2. Go to Edit > Preferences.
  3. In the Preferences window, click on the Add-ons tab.
  4. Search for “3D Print Toolbox” in the search bar.
  5. Check the box next to “3D Print Toolbox” to enable the add-on.
  6. Click Save Preferences.

Now you can access the 3D Print Toolbox from the N menu in the 3D Viewport. It provides essential checks to ensure your model is watertight and ready for printing.

2. UV Unwrapping and Texture Mapping

Blender’s UV unwrapping tools allow you to create efficient texture maps for your 3D models. Whether you’re adding logos, patterns, or surface details, Blender ensures that your textures align correctly on the printed object.

3. Exporting for 3D Printing

3.1. STL Export

The standard file format for 3D printing is STL (Stereolithography). Blender supports seamless STL export, allowing you to save your model in a format compatible with most 3D printers.

3.2. Scale and Units

Pay attention to the scale and units in Blender. Ensure that your model’s dimensions match the real-world measurements you desire. Blender’s unit system allows you to work in millimeters, centimeters, or other units, ensuring accurate scaling.

4. Slicing and G-Code Generation

While Blender doesn’t directly handle slicing and G-code generation (functions typically performed by dedicated slicer software), it provides a solid foundation for creating the 3D model. Export your model from Blender and import it into your preferred slicer (e.g., Cura, PrusaSlicer) to generate the G-code instructions for your printer.


In summary, Blender is a capable 3D modeling software that can indeed prepare models for 3D printing. Its robust features, combined with attention to detail during modeling and export, make it a valuable asset for both beginners and experienced designers.

So, the answer to the question “Can Blender 3D Print?” is a resounding yes! Dive into Blender, unleash your creativity, and bring your 3D designs to life through the magic of additive manufacturing.


How to buy from UniBlend using Crypto

In this Quick tutorial, I’m going to show you how to buy from the store using cryptocurrency

1. Installing a wallet (If you don’t have one, yet)

Go to this link in Chrome web store and download Trust Wallet. This wallet is one of the many options you can download

Trust Wallet

2. Choose your product from the store and click “Add to cart”

3. Click on the cart icon in the header and click “Proceed to checkout”

 4. Fill in required information and then Click On “Go to cryptopy”

This is a cryptocurrency getaway that I used for transactions

5. Now final check your order and click “Connect Wallet”

6. you can use Trust, Metamask, Binance Wallet or click “Wallet Connect” to choosing your preferred wallet

7. After connecting the wallet, you can choose the Currency
(Network fee may vary for different currencies)

The equivalent figure of your selected digital currency is calculated in relation to the product price and displayed on the blue button. Here, the product price is 39 dollars, which is equivalent to 39 Tether (USDT)

8. Now click on the blue button and confirm the transaction in your wallet

Your order has submitted successfully, and now you can access your product


 (Without Connecting Wallet) Alternative Way

In this way, I’ll show how you can buy and transfer crypto to a digital wallet without connecting your wallet. In this example I’m using Trust wallet but you use any other wallet you prefer.


1. Install Trust wallet on your phone or browser



2. Buy crypto

Buy crypto in Trust Wallet

Click on Buy

Select your preferred crypto

Enter the amount and click on next –  then you will select your credit card and confirming the purchase





3. Send Crypto

Sending Crypto using Trust wallet

Click on Send

 Select the crypto and enter the amount you want to transfer

Enter the wallet address I gave you

click confirm


Congratulations and thank you for choosing UniBlend

If you need any help, please E-mail me at “mahanrasouli.design@gmail.com” and don’t forget that I’m just a message away 🙂

Wallet Addresses



Polygon Matic:

Tether – ETH – ERC20:

Net Browsing

All Around The Web

Welcome to my collection of interesting and useful websites! Here, you’ll find a carefully curated list of links to websites that I’ve found to be valuable in a variety of fields. Whether you’re looking for inspiration, information, or just something new to explore, this page has something for everyone. Take a look and discover something new today!

Useful website Intro
Website NameURLUseNotes
Blender Demo Filehttps://www.blender.org/download/demo-files/Download Blender demo files to review new software features or test hardware-
Hack Designhackdesign.orgDesign Tips and Article (Mostly UI-UX)-
Learn-anythinglearn-anything.xyzFastest way to become expert in a certain field-
16 Personalitieswww.16personalities.comFull imdb information + test-
Cheap XBOX Gameshttps://www.xbox-now.com/en/game-comparisonBuy XBOX Games at lowest price possible-
Blender Manual (Official)https://docs.blender.org/manual/en/latest/index.htmlOfficial Blender 3D Manual-
Blender Visual Manualhttps://docs.gimp.org/2.10/en/Blender Visual Manual-
UX Libraryhttps://www.uxlibrary.org/more/free-resources/illustrationsEvery kind of Asset needed for UX Design-
Substance 3D Painter Manualhttps://substance3d.adobe.com/documentation/spdoc/substance-3d-painter-20316164.htmlOfficial Substance 3D Painter Manual-
Real Pythonhttps://realpython.com/Learn Python 0 to 100-
Replithttps://replit.com/Millions of codes and programms-
Coolershttps://coolors.co/Free Color Pallette Generator-

If you’d like to access the full list of websites and make a copy for yourself, simply click the button below. This will take you to the Google Sheet where you can view all the links and make a copy to keep for your own reference. Enjoy exploring!