Educational 3D Printing Solutions

Print. Touch. Understand. Empowering Education.

From STEM kits to anatomical models, Sahas brings hands-on learning to life with precision 3D printing making education interactive and visual.

Let’s Discuss

Hands-on Learning Starts Here

3D Printing Applications in the Education Industry

STEM Education
Engineering & Design
Medical & Life Sciences
Architecture & Civil
Hands-on Learning
Medical & Dental Training
Skill Development Institutes

STEM Education

  • Mathematical models
  • Physics demonstration kits
  • Geometric solids and fractals
  • Interactive STEM classroom tools

Engineering & Design

  • CAD prototypes
  • Mechanical assemblies
  • Gear and linkage models
  • Structural load test parts

Medical & Life Sciences

  • Anatomical models
  • Biology & DNA structures
  • Disease progression models
  • Organ system cross-sections

Architecture & Civil

  • Campus and master plan mockups
  • Urban planning layouts
  • Terrain and topography models
  • Scale building models

Hands-on Learning

  • Robotics & automation kits
  • Custom puzzle & game designs
  • Design thinking aids
  • Exploration kits for early learners

Medical & Dental Training

  • Human skull and dental arch models
  • Tooth extraction and drilling practice blocks
  • Surgical suture training forms
  • Simulated tissue for incision practice

Skill Development Institutes

  • Appliance assembly mockups
  • Fabrication & fitment trial kits
  • Electrical panel training boards
  • Job-readiness demo modules

Frequently Asked Questions

3D printing helps students in science, technology, engineering, and mathematics (STEM) visualize complex concepts and create real-world models, enhancing engagement and learning outcomes.

Yes, students can design, prototype, and test functional components using CAD and 3D printers—building critical skills in product development and iterative design.

3D printed anatomical models, organs, and surgical training tools allow medical and life sciences students to study human biology and practice procedures safely and cost-effectively.

Students can build topographic maps, scaled architectural models, and structural prototypes to better understand spatial design, load-bearing structures, and urban planning.

By turning digital ideas into physical objects, 3D printing fosters creativity, problem-solving, and tactile learning—especially in design, fabrication, and STEM labs.

Yes, industrial training institutes use 3D printing to train students in CAD, rapid prototyping, manufacturing workflows, and material science—all aligned with industry demands.

Dental and medical colleges use 3D printed teeth, jaws, and surgical guides to simulate procedures, teach anatomy, and practice treatments before live cases.

Common software includes Tinkercad, Fusion 360, SolidWorks, and Blender—used alongside slicing tools to teach the complete digital-to-physical design workflow.

A 3D printing lab encourages innovation, interdisciplinary collaboration, and entrepreneurship while preparing students for careers in engineering, design, and manufacturing.

FDM is widely used for its affordability and ease of use, while SLA, SLS, and PolyJet are introduced in advanced labs for higher-resolution and industry-relevant training.