近代的な製造業がどのようにして、より短い開発サイクルでますます複雑な製品を作成したのか疑問に思ったことがあるなら, 産業用グレードの3D印刷は、おそらく答えの一部です. 小さいものを処理する消費者3Dプリンターとは異なります, 簡単なプロジェクト, 産業3D印刷技術は大規模なものに取り組んでいます, 多様なセクターにわたる高精度の製造上の課題. このガイドで, we’ll explore the key application […]
3Dプリントで作業したことがある場合, あなたは疑問に思ったかもしれません: 「なぜ私は自分のプロトタイプを一度に印刷できないのですか?" 結局, 3D印刷は、単一のビルドで複雑なオブジェクトを作成する能力で祝われます. But the reality is that split printing—breaking a prototype into smaller parts, それらを個別に印刷します, and assembling
3D印刷に入っている場合, 最初に尋ねる質問の1つはです, 「どの3Dモデリングソフトウェアを使用する必要がありますか?」適切なソフトウェアは、成功した3Dプリントの作成においてすべての違いを生むことができます, プロトタイプを設計するかどうか, 機能部品, または創造的なプロジェクト. 非常に多くのオプションがあります, choosing the right tool for your needs
If you’ve ever pulled a fresh 3D print off the build plate, you know the job isn’t quite finished yet. Those layer lines, サポートマーク, and rough edges can keep your part from looking professional or performing at its best. That’s where 3D printing post-processing comes in. But what processes are generally used in 3D
If you’ve been trying to decide between 3D printing and CNC machining for your next project, you’re not alone. These two manufacturing technologies each have their strengths, but 3D printing offers some unique advantages that make it the better choice for many applications. From complex geometries to faster turnaround times, additive manufacturing has transformed what’s
If you’ve ever wondered why some manufacturing projects use CNC machines while others opt for 3D printers, the answer often lies in the materials. These two dominant manufacturing technologies—one subtractive, one additive—handle materials in fundamentally different ways, and those differences shape everything from part strength to production costs. このガイドで, we’ll break down exactly
添加剤製造の領域で, 融合堆積モールディング (FDM) 最もアクセスしやすく、広く使用されているテクノロジーの1つとして立っています. 費用対効果で有名です, 物質的な汎用性, 操作の容易さ, FDMはプロトタイプの作成方法を変え、小型バッチの生産が業界で処理されています. This comprehensive guide explores everything you need to know about
In the world of additive manufacturing, resin light-curing (SLA) 3D printing stands out as a technology renowned for its precision, high resolution, and ability to produce smooth-surfaced parts. From rapid prototyping to low-volume production, SLA has revolutionized how industries approach product development and manufacturing. This comprehensive guide will delve into the intricacies of SLA 3D
選択的レーザー焼結 (SLS) stands out as one of the most versatile and powerful 3D printing technologies available today. Since its introduction in 1986 by Carl Deckard at the University of Texas, SLS has evolved from an experimental technique to an industrial workhorse capable of producing high-quality parts for everything from rapid prototyping to end-use
3D printing technology has revolutionized the world of do-it-yourself projects, empowering hobbyists and makers to create complex, functional objects that were once only possible with industrial manufacturing. The open-source community has embraced this technology, developing an impressive library of project designs that combine engineering, creativity, and hands-on learning. Whether you’re a beginner looking to expand
融合モデリング (FDM) remains one of the most accessible and versatile 3D printing technologies for creating thermoplastic parts. From functional prototypes to custom tooling and small-batch production, FDM offers an affordable solution with a wide range of material options. しかし, achieving high-quality results requires understanding its unique capabilities and limitations. This comprehensive guide shares
HP Nylon Multi-Jet Fusion (MJF) technology has revolutionized industrial 3D printing by combining speed, 精度, and material efficiency. This advanced powder-based additive manufacturing process creates functional nylon parts with mechanical properties comparable to injection-molded components, but with far greater design freedom. しかし, to fully leverage MJF’s capabilities, designers must understand its unique requirements and constraints.
In the world of 3D printing, creating a stunning digital model is just the first step. To transform that virtual design into a physical object, you need a file format that can effectively communicate your vision to a 3D printer. Think of these file formats as different languages that translate your digital design into instructions
