#Geometris

Video ini merupakan eksplorasi visual yang menarik tentang bagaimana staples berfungsi dan bagaimana staples dapat digunakan secara kreatif. Video dimulai dengan menunjukkan staples berwarna tembaga yang disusun menjadi struktur geometris zig-zag yang unik, bertransisi dari blok standar menjadi bentuk artistik yang kompleks. Pembuat video kemudian mendemonstrasikan penggunaan praktis standar staples dengan memasukkannya ke dalam stapler berwarna teal dan menjepit selembar kertas, diikuti dengan tampilan close-up dari staples yang bengkok. Bagian kedua video beralih ke animasi 3D detail dengan latar belakang nebula biru kosmik. Animasi ini menguraikan sifat saling terkait dari staples, menunjukkan bagaimana beberapa unit dapat dijalin bersama untuk membentuk kisi kubik 3D yang kaku. Ini berfungsi sebagai demonstrasi alat kantor umum dan tampilan kreatif dari potensi struktural benda-benda sederhana sehari-hari. Poin-Poin Penting Secara Singkat: Perakitan Kreatif: Menunjukkan staples dilipat dan dihubungkan untuk membuat rantai tembaga dekoratif seperti akordeon. Penggunaan Fungsional: Demonstrasi singkat tentang cara mengisi stapler dan transformasi fisik staples saat menjepit kertas. Visualisasi Geometris: Animasi 3D mengilustrasikan bagaimana staples individual secara teoritis dapat saling terkait untuk membentuk kubus anyaman yang kompleks. Kontras Visual: Video beralih dari kerajinan DIY di dunia nyata ke rendering digital berkualitas tinggi untuk menyoroti geometri "tersembunyi" dari staples.

Caustic Projection Optical Element: Creating intricate geometries with light due to refraction through various curved surfaces of transparent plastic. A 488 nm cyan laser pointer is refracted through an optical element with lumpy surface features which create this aurora/nebula effect. When light rays refract through a curved surface they concentrate into bright patches called caustics, often with cusp singularities (sharp points) and intricate threads of shadow. ➡ Follow the link in my profile for info on where to get this and other amazing items featured here on @physicsfun #physicstoy #optics #caustics #laser #refraction

A 1:150 architectural model of the Yidan Center Building in Shenzhen, crafted by @jyd.models for @zahahadidarchitects, is presented at MOCAUP Shenzhen (@szmocaup). The model captures the fluid geometries and spatial complexity of the project, translating Zaha Hadid Architects’ design language into a meticulous physical artifact. Used as part of Zaha Hadid Architects’ exhibition, it highlights how physical models continue to play a role in communicating advanced computational design. 📍 Shenzhen, China Does a physical model still offer something a render cannot? 👩‍🎓Join @thepaacademy’s workshops to learn the most advanced tools in architecture from pioneering architects and designers! #parametricarchitecture #architecturalmodel #buildingmodel #zahahadid #china

Workshop Ingenuity: DIY Profile Gauging with Welding Electrodes! ✨📐 ​Observe the creative and practical application of Manual Contour Mapping! This is a perfect example of "on-the-spot" engineering, where common workshop materials—welding electrodes—are used to replicate complex, irregular geometries for a flawless architectural fit. ​The Art of Geometric Replication ​This process demonstrates how physical alignment can replace complex digital measurements in carpentry and interior finishing: ​The Setup: The challenge is to cut a panel that fits perfectly around an irregular corner featuring both wood and brick. Instead of using a digital scanner, the operator uses a series of stick welding electrodes. Their uniform diameter and rigid structure make them an excellent low-cost substitute for a professional profile gauge. ​Capturing the Contour (0:01 - 0:03): By pressing the electrodes against the irregular surface, each rod slides to a different depth. This creates a "physical map" of the corner's geometry. The use of masking tape is a clever engineering choice to "freeze" the data, locking the electrodes in their exact relative positions. ​Transferring the Data (0:04 - 0:07): The "electrode-map" is then placed onto the material to be cut. By tracing the points where the tips of the electrodes end, the operator transfers the complex 3D profile onto a 2D surface with high accuracy. ​Precision Cutting (0:08 - 0:12): Using a jigsaw, the operator follows the traced line. Because the profile was captured at a 1:1 scale, the resulting cut mirrors the irregularities of the wall perfectly, eliminating gaps and the need for messy fillers. ​The Final Fit: The result is a seamless integration of the panel with the existing structure. It’s a flawless display of how understanding spatial geometry and utilizing available resources can solve even the trickiest design challenges! ​Engineering for Practicality ​From the choice of the tape’s adhesion to the steady hand required for tracing, this "hack" is a testament to the resourcefulness required on every construction site. It’s all about the perfect fit!

8 Axes Simultaneously: A Mesmerizing Toolpath True precision emerges from perfectly synchronized motion. This 8 axis simultaneous operation represents more than machining. It is the integration of advanced kinematics, high level interpolation control, and sophisticated CNC programming. Multi axis simultaneous movement enables complex geometries to be completed in a single setup, reducing cycle time and minimizing positioning errors. A toolpath strategy at this level requires: • Dynamic collision control • Optimized cutting parameters • Stable and efficient motion algorithms • High surface finish and tight tolerance control In aerospace and other high precision industries, multi axis machining is no longer optional. It is becoming the standard. Innovation happens where machine capability meets programming intelligence. 🎥 Video Credit : @titansofcnc ( Instagram ) #cnc #craftsmanship #digitalartistry #technologyandart #architecture #innovation #sustainability #futuredesign #cnc5xis #architecturedesign #ModernLuxury #3DPrinting #SustainableDesign #homedecor #Makers #CircularDesign #3d #robot #parametricarchitecture #engineering #innovation #3dprinting #AdditiveManufacturing #RotaryExtrusion #designinnovation #advancedmanufacturing #3dprint #3dprinting #roboticarm #additivemanufacturing #pellet #3dprintingservice ⚠️ This video is shared for educational and informational purposes only. It does not contain any sponsored deals, advertising, or commercial intent. Credit to the original creator. All rights belong to the respective brand. If you are the owner and wish to have it removed or credited differently, please contact us.

The video displays a industrial video editing screen demonstrating a manufacturing process. The text describes a process designed for intricate shapes, contours, and complex geometries with tight tolerances.  The visual shows water jet cutting technology being used to shape metal.  The cutting technology is versatile, allowing for high-precision cutting on metals and various other materials without heat distortion.

Video ini merupakan eksplorasi visual yang menarik tentang bagaimana staples berfungsi dan bagaimana staples dapat digunakan secara kreatif. Video dimulai dengan menunjukkan staples berwarna tembaga yang disusun menjadi struktur geometris zig-zag yang unik, bertransisi dari blok standar menjadi bentuk artistik yang kompleks. Pembuat video kemudian mendemonstrasikan penggunaan praktis standar staples dengan memasukkannya ke dalam stapler berwarna teal dan menjepit selembar kertas, diikuti dengan tampilan close-up dari staples yang bengkok. Bagian kedua video beralih ke animasi 3D detail dengan latar belakang nebula biru kosmik. Animasi ini menguraikan sifat saling terkait dari staples, menunjukkan bagaimana beberapa unit dapat dijalin bersama untuk membentuk kisi kubik 3D yang kaku. Ini berfungsi sebagai demonstrasi alat kantor umum dan tampilan kreatif dari potensi struktural benda-benda sederhana sehari-hari. Poin-Poin Penting Secara Singkat: Perakitan Kreatif: Menunjukkan staples dilipat dan dihubungkan untuk membuat rantai tembaga dekoratif seperti akordeon. Penggunaan Fungsional: Demonstrasi singkat tentang cara mengisi stapler dan transformasi fisik staples saat menjepit kertas. Visualisasi Geometris: Animasi 3D mengilustrasikan bagaimana staples individual secara teoritis dapat saling terkait untuk membentuk kubus anyaman yang kompleks. Kontras Visual: Video beralih dari kerajinan DIY di dunia nyata ke rendering digital berkualitas tinggi untuk menyoroti geometri "tersembunyi" dari staples.

A groundbreaking 3D printing method eliminates the need for support materials in ceramic fabrication by combining direct ink writing, near-infrared light, and up-conversion particles to cure material instantly as it's deposited. This allows complex geometries — overhangs, horizontal spans, intricate lattices — to hold their shape without sagging or collapse. The real-time curing also improves surface quality and cuts production time and cost by removing post-processing steps. Researchers have already printed cantilever beams and bridge-like structures that demonstrate strong mechanical performance after sintering, pointing to real potential in aerospace, biomedical engineering, and electronics. 🚨 Follow @aidisruptor for the latest in AI and tech innovation. Credit: Nature Communications | Jiangnan University, Ren Liu Lab DM for credit/removal (no copyright intended) #3DPrinting #Technology #MaterialsScience #BiomedicalEngineering #Engineering

Advanced woodworking joinery allows complex corner designs to be assembled with high precision, often without the need for visible fasteners. By carefully shaping interlocking geometries, craftsmen can achieve strong, stable connections that distribute load efficiently while maintaining a clean aesthetic. Accuracy in cutting and alignment is critical, as even small deviations can compromise both strength and visual symmetry. These techniques combine traditional craftsmanship with precise measurement and planning. This highlights how engineered design principles are applied even in manual crafts to achieve both function and form. Follow For Daily Breakthroughs At The Intersection Of Technology And AI. IG ➕ @future.explanation Credit: (DM For Credit/Removal) #woodworking #engineeringfacts #craftsmanship #design #precision

Electrical Discharge Machining (EDM) removes material through controlled spark erosion rather than mechanical cutting. That means no cutting forces, minimal tool deflection, and the ability to machine hardened tool steels, carbides, and intricate geometries that would be impractical with conventional CNC methods. Adding a C-axis introduces precise rotational control of the workpiece. Instead of indexing manually or re-fixturing, the part can be rotated in sub-degree increments while maintaining alignment within microns. This enables: • Multi-angle feature creation without repositioning error • True cylindrical symmetry in complex cavities • High-density micro-features distributed around a central axis • Reduced cumulative tolerance stack-up In mold making, this is critical. Insert features often dictate final part quality—especially for optical components, medical devices, and microfluidic systems. Surface finish, edge fidelity, and geometric accuracy directly impact flow behavior, part release, and downstream assembly performance. EDM also allows for: • Sharp internal corners with minimal radius limitations • Controlled surface textures (Ra tuning via discharge parameters) • Repeatable micro-scale detail across production runs The trade-off is time and process control. EDM is slower than conventional machining and requires careful electrode design, flushing strategy, and spark parameter optimization. But when tolerances tighten and geometries become non-negotiable, EDM with C-axis capability becomes a go-to solution. If you’re building high-performance molds, this is where precision engineering meets process physics. Comment your questions or remix with your own machining setups. Save this for later reference if you’re working on precision tooling. #STEM #Manufacturing #EDM #ToolAndDie #PrecisionEngineering

Parallel lines, as defined in Euclidean geometry, are straight lines that never intersect and maintain a constant distance apart. However, this concept shifts fundamentally in non-Euclidean geometries, where the parallel postulate doesn't hold, making "true" parallels either impossible or redefined. Parallels are purely theoretical constructs tied to Euclidean assumptions. Non-Euclidean frameworks, born from rejecting the parallel postulate, reveal them as context-dependent, powering models like relativity's curved spacetime.

In the world of industrial automation, off-the-shelf simply doesn't cut it. Custom CNC turning delivers precision-engineered components tailored to exact specifications — ensuring every part fits, functions, and performs flawlessly within automated systems. Tight tolerances. Complex geometries. Repeatable accuracy. From shafts and bushings to custom connectors and drive components — CNC turned parts are the silent force keeping automation lines running 24/7 without interruption. 🏭🔩 📩 Need custom CNC components for your automation setup? DM us with your requirements. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Source: LSManufacturingltd CNC Turning, Industrial Automation, Custom Machining, Precision Components #cncturning #industrialautomation #custommachining #precisioncomponents #metalwork