ȸ¿ø°¡ÀÔ | ¿¬¶ôó | »çÀÌÆ®¸Ê | English

      È¸»ç¼Ò°³ | ¸®Æ÷Æ® | Ä¿½ºÅÒ ¸®¼­Ä¡ | °í°´Áö¿ø


·Î±×ÀÎ

Ä«Å×°í¸®

À¯/¹«¼±Åë½Å

Àü±â/ÀüÀÚ

µðÁöÅбâ±â/¹Ìµð¾î/¹æ¼Û

Information Technology

¿¡³ÊÁö

»ý¸í°øÇÐ

È­ÇÐ/½Å¼ÒÀç

ÀÚµ¿Â÷

ȯ°æ

ÀϹݼҺñÀç

¸¶ÄÉÆÃ/±¤°í

±ÝÀ¶

°Ç¼³

±³Åë/¿î¼Û

¼ÒºñÀÚÁ¶»ç

¹æÀ§/Ç×°ø/¿ìÁÖ

½ÄÀ½·á

Áß°ø¾÷

±³À°

±â°è

¹«¿ª

½ºÆ÷Ã÷/·¹Àú

ÇØ¿î/Á¶¼±

ÆмÇ

Á¤ºÎ/Á¤Ã¥

°ø¿¹/±Í±Ý¼Ó

ÄÄÆÛ´Ï ÇÁ·ÎÆÄÀÏ

±âŸ»ê¾÷

 
ÇöÀçÀ§Ä¡ : HOME > ¸®Æ÷Æ® > ±â°è
Applications of 3D Printing 2014-2024: Forecasts, Markets, Players
¹ßÇà»ç IDTechEx

¹ßÇàÀÏ 2015-11
ºÐ·® 159 pages
¼­ºñ½ºÇüÅ Report
ÆǸŰ¡°Ý

ÀμâÇϱâ

Table of Contents

1. EXECUTIVE SUMMARY

2. EXISTING APPLICATIONS OF 3D PRINTING

  • 2.2. Aerospace
    • 2.2.1. Jet engine fuel nozzles
    • 2.2.2. KySat-2
    • 2.2.3. SULSA
  • 2.3. Architecture
  • 2.4. Automotive
    • 2.4.1. Prototyping
    • 2.4.2. Areion and Eve
    • 2.4.3. Triumph Rocket III
  • 2.5. Art
    • 2.5.1. Action figures
    • 2.5.2. Jewelry
    • 2.5.3. Miniatures
    • 2.5.4. Ornaments
    • 2.5.5. Props
  • 2.6. Consumer
  • 2.7. Clothing
  • 2.8. Education
    • 2.8.1. Brain surgery
    • 2.8.2. Mock-up Fluoroscopic C-Arm
  • 2.9. Gadgets
    • 2.9.1. iPhone cases
    • 2.9.2. iPod holders
  • 2.10. Hobbyist
  • 2.11. Justice
    • 2.11.2. Maps
  • 2.12. Medical
    • 2.12.1. Orthopaedics
  • 2.13. Prototyping
  • 2.14. Sport

3. EMERGING APPLICATIONS OF 3D PRINTING

  • 3.1. Aerospace
    • 3.1.1. Landing gear
    • 3.1.2. Jet engine brackets
    • 3.1.3. Jet engine low-pressure turbine blades
    • 3.1.4. Rocket engines
    • 3.1.5. SpaceX
    • 3.1.6. AMAZE
  • 3.2. Art
  • 3.3. Automotive
    • 3.3.1. Urbee 2
  • 3.4. Construction
    • 3.4.1. Bricks
    • 3.4.2. Concrete
  • 3.5. Education
  • 3.6. Food
    • 3.6.1. Confectionaries
    • 3.6.2. Meat
  • 3.7. Advanced design
  • 3.8. Mechanical
  • 3.9. Medical
    • 3.9.1. Bacterial traps
    • 3.9.2. Microstructures
    • 3.9.3. Nerves
    • 3.9.4. Organ tissue
    • 3.9.5. Prosthetics
    • 3.9.6. Skin
  • 3.10. Printed electronics
  • 3.11. Printed solder
    • 3.11.2. Conductive thermoplastic filament
    • 3.11.3. Conductive inks
  • 3.12. Space
    • 3.12.1. On-orbit
    • 3.12.2. Lunar
    • 3.12.3. Mars

4. MAIN PLAYERS AND END USERS

  • 4.1. 3DPonics
  • 4.2. Biobots
  • 4.3. BMW
  • 4.4. Boeing
  • 4.5. BotFactory
  • 4.6. Chemcubed
  • 4.7. CRP Group
  • 4.8. Dyson
  • 4.9. EPSRC
  • 4.10. Ford Motor Company
  • 4.11. Fraunhofer Additive Manufacturing Alliance
  • 4.12. Fripp Design Ltd
  • 4.13. Impossible Objects
  • 4.14. Lockheed Martin
  • 4.15. LUXeXceL
  • 4.16. Nascent Objects, Inc
  • 4.17. Norsk Titanium
  • 4.18. Orbital Composites
  • 4.19. Organovo
  • 4.20. Reebok International
  • 4.21. Star Prototype
  • 4.22. Volvo Construction Equipment
  • 4.23. Voxel8

5. TECHNOLOGY READINESS

  • 5.1. Larger build volumes
  • 5.2. Build speed vs precision
  • 5.3. Software
  • 5.4. Non-destructive examination (NDE)
  • 5.5. The concept of layers
  • 5.6. Cost of printers
  • 5.7. Feedback
  • 5.8. Energy efficiency
  • 5.9. Materials

6. MARKET READINESS

  • 6.2. Aerospace
  • 6.3. Architecture
  • 6.4. Construction
  • 6.5. Consumer print services
  • 6.6. Consumer printers and scanners
  • 6.7. Jewelry
  • 6.8. Medical

7. MARKET SIZE AND GROWTH

  • 7.1. Aerospace
  • 7.2. Architecture
  • 7.3. Automotive
  • 7.4. Construction
  • 7.5. Dental
  • 7.6. Education
  • 7.7. Food
  • 7.8. Jewelry
  • 7.9. Consumer printers
    • 7.9.1. Thermoplastic extrusion
    • 7.9.2. Photopolymer curing
  • 7.10. Consumer print services
  • 7.11. Medical
    • 7.11.1. Orthopaedics
    • 7.11.2. Human tissues

8. GLOSSARY

IDTECHEX RESEARCH REPORTS AND CONSULTANCY

FIGURES

  • 1.1. Traditional value chain in 3D printing
  • 1.2. Proportion of Google searches for three main players
  • 1.3. Value chain for print shops
  • 1.4. Value chain for consumer-level 3D printers with a free market for consumables
  • 1.5. Historical and forecast price of thermoplastic filament for consumer-level 3D printers
  • 1.6. Hype curve for 3D printing applications
  • 1.7. Market growth vs size for 3D printing applications
  • 2.1. Breakdown of applications according to the Shapeways print service
  • 2.2. Breakdown of applications according to the 3D Hubs print service
  • 2.3. Fuel nozzle for a jet engine
  • 2.4. A 3D printed SULSA aircraft
  • 2.5. 3D printed architectural model
  • 2.6. 3D printed architectural element installed in a building
  • 2.7. Ford technologist Dennis DuBay removing the sand surrounding a cast mold for an engine component
  • 2.8. Pouring molten metal into a 3D printed sand mold
  • 2.9. Cast metal part created from a 3D printed mold
  • 2.10. Finished part after post-processing
  • 2.11. The Areion and Eve cars created for the Formula Student Challenge
  • 2.12. 3D printed action figures
  • 2.13. 3D printed jewelry samples
  • 2.14. Gold-plated 3D printed jewelry
  • 2.15. 3D printed ring generated by wrapping an image around the ring
  • 2.16. 3D printed life-size replica of an unborn child
  • 2.17. Website allowing consumers to create a Star Trek figurine of themselves
  • 2.18. Triple gear
  • 2.19. 3D printed Strandbeest walking in the wind
  • 2.20. Three different designs of Strandbeest that can be 3D printed
  • 2.21. Complicated mechanism printed as a single object
  • 2.22. Fractal coffee table
  • 2.23. Mjölnir hammer
  • 2.24. Monograph of the letters A and H
  • 2.25. Child's drawing and full-color 3D printed derivative
  • 2.26. 3D printed bobble head
  • 2.27. Evolutionary design
  • 2.28. Easy-to-use CAD software from Microsoft's Windows Store
  • 2.29. Monster customised on a mobile phone and the corresponding 3D printed toy
  • 2.30. The N12, a 3D printed bikini
  • 2.31. Close-up of the intricate design of the N12 bikini
  • 2.32. Mock-up human head used to train neurosurgeons
  • 2.33. Real and mock-up fluoroscopic arm
  • 2.34. 3D printed iPhone case that contains moving gears
  • 2.35. Nanolet bracelet
  • 2.36. Pod à porter is a necklace
  • 2.37. Custom Arduino case for a hobbyist electronics project
  • 2.38. A simple 3D printed fixture
  • 2.39. A 3D printed bike lock
  • 2.40. A 3D printed nozzle for a vacuum cleaner
  • 2.41. A 3D printed lathe
  • 2.42. A 3D printed tool for creating hobbed bolts
  • 2.43. A 3D printed GoPro mount for a Nerf gun
  • 2.44. A 3D printed reconstruction of a crime scene
  • 2.45. A full-color 3D printed height map
  • 2.46. Visualization of an implanted hip socket
  • 2.47. Comparison of custom 3D printed vs traditional off-the-shelf knee implants
  • 2.48. Visualization of 3D printed surgical instrumentation used to implant a custom knee
  • 2.49. Aireal prototype
  • 2.50. Fencing swords and some 3D printed hilts
  • 3.1. Traditional bracket design for subtractive manufacture
  • 3.2. Award-winning bracket design for 3D printing
  • 3.3. Competing bracket designs for 3D printing
  • 3.4. Low-pressure turbine blade 3D printed in titanium-aluminide
  • 3.5. Rocket engine 3D printed as a single object
  • 3.6. Experimental 3D printed rocket engine design
  • 3.7. 3D printed pottery
  • 3.8. The Urbee 2
  • 3.9. Large 3D printed component of the Urbee 2
  • 3.10. 3D printed bricks
  • 3.11. Various designs of 3D printed bricks
  • 3.12. Traditional manufacture of replacement stones for York Minster
  • 3.13. Contour Crafting robot for the construction industry
  • 3.14. Visualization of 3D printed corrugated walls enclosing non-printed functional elements
  • 3.15. A 3D printed wall
  • 3.16. 3D printed graded concrete
  • 3.17. 3D printed foam structure
  • 3.18. 3D printed bench
  • 3.19. The D-shape printer in action
  • 3.20. A 3D printed building
  • 3.21. Architectural design that leverages the capabilities of 3D printing
  • 3.22. 3D printed confectionaries
  • 3.23. 3D printed fractal microstructures
  • 3.24. Heat exchanger designed to be 3D printed
  • 3.25. Traditional (non-printed) fractal softener
  • 3.26. Design, 3D printed ABS prototype and 3D printed metal impeller
  • 3.27. A prison for bacteria
  • 3.28. A microvalve designed to prevent backflow in veins, high-porosity tissue engineering scaffold, and an array of micro needles
  • 3.29. High-speed photograph of jetted living nerve cells
  • 3.30. Novel apparatus used to jet living nerve cells
  • 3.31. Cross-section of multi-cellular bioprinted human liver tissue, stained with hematoxylin & eosin (H&E)
  • 3.32. 3D printed prosthetic eyes
  • 3.33. 3D scanning and bioprinting for a burns victim
  • 3.34. 3D printed solder and early 3D printed electronics employing printed thermoplastic and solder in a single object
  • 3.35. Experimental 2.5D printed electronics employing a 3D printed object with electronics printed onto its surface
  • 3.36. 3D printed samples by NASA using their own technology
  • 3.37. A 1.5 tonne sample block created using the D-shape printer
  • 5.1. A cable-suspended robotic gantry designed to 3D print large structures
  • 5.2. Power vs build rate for 3D printers
  • 5.3. Intricate designs made for 3D printing using artificial intelligence
  • 5.4. Procedurally-generated Trabecular structures on the surface of a hip implant
  • 5.5. A custom Cranio-Maxillofacial implant
  • 5.6. Visualization of a vehicular robot depositing material as part of a swarm 3D printing process
  • 6.1. Build volume vs precision categorised by application sector
  • 6.2. Build volume vs precision categorised by 3D printing process
  • 7.1. Market value ($M) forecasts for the aerospace industry2012-2025
  • 7.2. Market value ($M) forecasts for the aerospace industry2012-2025
  • 7.3. Market value ($M) forecasts for the aerospace industry2012-2025
  • 7.4. Market forecast for sub-$4k printers
  • 7.5. Historical and forecast price of thermoplastic filament for consumer-level 3D printers
  • 7.6. Estimated revenue for different applications derived from Shapeways data

ȸ»ç¼Ò°³ | °³ÀÎÁ¤º¸º¸È£Á¤Ã¥ | ÀÌ¿ë¾à°ü | ¹è¼Û/°áÁ¦¾È³» | ÀÌ¿ë¾È³»

¼­¿ï½Ã °­³²±¸ ³íÇöµ¿ 210-1 »ï¿øºôµù | ȸ»ç¸í : (ÁÖ)¿¤¾Ø¿¡Ä¡
´ëÇ¥ÀüÈ­ : 02-554-0001 / Æѽº : 02-3444-5501 / À̸ÞÀÏ : sales@landh.co.kr
Copyright ¨Ï 2008 LNH, Inc. All rights reserved.