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== What is additive manufacturing? ==
== What is Additive Manufacturing (AM)? ==
3D printing - also referred to as additive manufacturing - has enabled the manufacturing of complex geometries to the final shape without need for additional specialized tools, devices, or jigs. The cycle starts with designing the part or assembly in a 3D CAD, or three-dimensional computer-aided design, software. The part is then converted into a triangular mesh that defines its interior and exterior surfaces, commonly known as an STL file. The STL file is then imported into a slicing program that allows the user to manipulate the mesh and define the printing parameters for the process. Slicing is then performed by taking all the user-defined parameters and generating a tool path for each layer of the print. Understanding this workflow is an important factor when designing parts for additive manufacturing because of the different challenges that come with producing a quality part.  
3D printing - also referred to as additive manufacturing - has enabled the manufacturing of complex geometries to the final shape without need for additional specialized tools, devices, or jigs. Additive manufacturing works by joining layers of material sequentially one on the other, to build any unique final form. Whether it's extruding filament through a nozzle, melting metal powder, or curing resin with UV light. There are many different types of additive manufacturing technologies that might not necessarily look alike, but they all create parts by adding material in layers. The most common materials used in additive manufacturing are plastics and metals. The equipment typically costs less than subtractive manufacturing, and various material properties are available for many 3D printing operations.  


Subtractive manufacturing involves material removal with turning, milling, drilling, grinding, cutting, and boring. They start with a larger piece of stock and then remove material until the final part is revealed. Some examples of subtractive manufacturing include laser cutting, waterjet cutting, CNC Machining Centers, Electrical Discharge Machining (EDM), and abrading.
In contrast, subtractive manufacturing involves material removal with turning, milling, drilling, grinding, cutting, and boring. This process starts with a larger piece of stock and then material is removed until the final part is revealed. Some examples of subtractive manufacturing include laser cutting, waterjet cutting, CNC Machining Centers, Electrical Discharge Machining (EDM), and abrading.  


In contrast, additive manufacturing works by joining layers of material sequentially one on the other, to build any unique final form. Whether it's extruding filament through a nozzle, melting metal powder, or curing resin with UV light. There are many different types of additive manufacturing technologies that might not necessarily look alike, but they all create parts by adding material in layers. The most common materials used in additive manufacturing are plastics and metals. The equipment cost is less than subtractive manufacturing, and various material colors are available for most 3D printing operations.
The AM cycle starts with designing the part or assembly in 3D CAD, or three-dimensional computer-aided design, software. The part is then converted into a triangular mesh that defines its interior and exterior surfaces, commonly known as an STL file. The STL file is then imported into a program that allows the user to manipulate the mesh and define the parameters for the AM process. This program then takes all the user-defined parameters and generating a tool path for each layer of the print, called slicing. These tool paths are then exported to the machine and the part is made. Understanding this workflow is an important factor when designing parts for additive manufacturing because of the different challenges that come with producing a quality part.


==Why choose additive manufacturing?==
==Why choose additive manufacturing?==
Additive manufacturing is not a drop-in replacement for any manufacturing process, however a number of different industries such as aircraft, dental restorations, medical implants, and automotive products have turned to additive manufacturing technologies to design prototypes prior to mass production. Additive manufacturing technologies are generally most attractive when there is a need for a fast turnaround from design to finished part, customization of parts, only a small production run or extremely unusual shapes that are not feasible to manufacture with traditional methods.  
Additive manufacturing is not a drop-in replacement for any manufacturing process, however a number of different industries such as aircraft, dental, medical, and automotive have turned to additive manufacturing technologies for a number of advantages. Additive manufacturing can be used to design prototypes prior to mass production, customize parts to individual users or setups, quickly create parts for small a production run, or build extremely unusual shapes that are not feasible to manufacture with traditional methods.  


Additive manufacturing is most useful for those who need the following.
Additive manufacturing is most useful for those who need the following.


#Parts with complex geometries: because of the way additive manufacturing builds can create parts that would either be expensive or impossible with traditional manufacturing techniques.
#Parts with complex geometries: The way additive manufacturing builds can create parts that would either be expensive or impossible with traditional manufacturing techniques.
#In-house custom parts: additive manufacturing allows you to rapidly go from cad to fully realized parts without the need of a specialized manufacturer. This will enable organizations to easily create iterative prototypes and small-scale manufacturing of custom parts for clients.
#In-house custom parts: Additive manufacturing allows for rapid progress from cad to fully realized parts without the need of a specialized manufacturer. This enables organizations to easily create iterative prototypes and small-scale manufacturing of custom parts for clients.
#Specific material properties: Because of the unique way that parts are formed, and the variety of materials available allows for control of various material properties such as strength, stiffness, and toughness. Materials and techniques also allow for more specific properties like food-safe, chemically resistant, UV reactive, etc.
#Specific material properties: The variety of materials available in AM allows for control of various material properties such as strength, stiffness, and toughness. Materials and techniques also allow for more specific properties like food-safe, chemically resistant, and UV reactivity.


== Subtypes ==
== Categories ==


The generally accepted system for sorting additive manufacturing technologies was created by the [https://www.iso.org/home.html international standards organization] (ISO). This systems sorts printers into seven categories based on how they join material together.


* [[Material extrusion|Material Extrusion]]: general purpose low cost polymer printing
* [[Powder Bed Fusion]]: small scale metal prototyping/ specialized polymer printing
* [[Vat Polymerization]]: fine detail resin printing
* [[Direct Energy Deposition]]: large scale metal printing
* [[Binder Jetting]]: low energy polymer printing/multi color printing
* [[Material Jetting]]: high precision polymer prints/ wax casting blanks
* [[Sheet Lamination]]: rapid production of simple parts
Each category has different strengths and weaknesses when compared with the other additive manufacturing categories. Below is a table populated by observing the range of capabilities within the AM database created by PSU, OIT, and OMIC in Phase 1 of this project. More detailed information on the different categories can be found on the individual webpages, and a more direct comparison can be made between different machines and the potential cost of making parts on those machines can be done using the AM database.
{| class="wikitable"
|+Properties by Category
!Type
!Volume (L)
!XY Resolution (mm)
!Layer height (um)
!Materials
!Footprint (m^2)
!Energy use
!Surface finsih
!Price
|-
|Material Extrusion
|1.224 - 1000
|0.25 - 1
|20 - 300
|Thermoplastics, some metals
|.1-1
|Medium
|Medium
|Low
|-
|Powder Bed Fusion
|20 - 160
|0.06 - 0.1
|20 - 120
|Metals, Thermoplastics
|1-10
|High
|Medium
|High
|-
|Vat Polymerization
|0.65 - 36
|0.003 - 0.05
|15 - 25
|Resins
|.05-1
|Low
|High
|medium
|-
|Direct energy depostion
|8 - 40,000
|0.67 - 1
|800 - 1000
|Metals
|4-12
|High
|Poor
|High
|-
|Binder Jetting
|20 - 160
|0.03 - 0.5
|80 - 100
|Plastics, Metals, Concrete, Wood
|1-4
|Low
|Medium
|High
|-
|Material Jetting
|.8 - 3,000
|.02 - .03
|10 - 50
|Resins, Wax, Thermoplastics
|1-6
|Low
|Best
|High
|-
|Sheet lamintion
|9 - 20
|.02 - .042
|50 - 200
|Plastics, Metals, Wood
|3-12
|Medium
|Poor
|High
|}
Parts created through AM technologies have standards that apply to them, similarly to parts created using other technologies. These include Mechanical Testing, Design, Precursor Material, Process and Control, Post Processing, Qualification and Vertification, Nondestructive Evaluation, and Maintenance and Repair. A [https://docs.google.com/spreadsheets/d/1wTo78i2y23a_z90w1knmXU3aXxdiXiPH/edit?usp=sharing&ouid=112155835546453592882&rtpof=true&sd=true detailed document on AM standards] was produced in Phase 1 of the project.


Given the vast number of printing technologies available it makes sense to have some sort of system to sort them by. The generally accepted system  was created by the international standards organization this systems sorts printers into seven categories based on how they physically print the material
== References ==
Rosen, David, Brent Stucker, and Mahyar Khorasani. Additive Manufacturing Technologies. Third edition. Cham, Switzerland: Springer, 2021.


 
“3D Printing - Additive | Make.” Accessed August 10, 2023. <nowiki>https://make.3dexperience.3ds.com/processes/3D-printing</nowiki>.
 
[[Material extrusion|Material Extrusion]]: general purpose low cost polymer printing
 
[[Powder Bed Fusion]]: small scale metal prototyping/ specialized polymer printing
 
[[Vat Polymerization]]: fine detail resin printing
 
[[Direct Energy Deposition]]: large scale metal printing
 
[[Binder Jetting]]: low energy polymer printing/multi color printing
 
[[Material Jetting]]: high precision polymer prints/ wax casting blanks
 
[[Sheet Lamination]]: rapid production of simple parts)
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Latest revision as of 13:09, 12 October 2023

What is Additive Manufacturing (AM)?

3D printing - also referred to as additive manufacturing - has enabled the manufacturing of complex geometries to the final shape without need for additional specialized tools, devices, or jigs. Additive manufacturing works by joining layers of material sequentially one on the other, to build any unique final form. Whether it's extruding filament through a nozzle, melting metal powder, or curing resin with UV light. There are many different types of additive manufacturing technologies that might not necessarily look alike, but they all create parts by adding material in layers. The most common materials used in additive manufacturing are plastics and metals. The equipment typically costs less than subtractive manufacturing, and various material properties are available for many 3D printing operations.

In contrast, subtractive manufacturing involves material removal with turning, milling, drilling, grinding, cutting, and boring. This process starts with a larger piece of stock and then material is removed until the final part is revealed. Some examples of subtractive manufacturing include laser cutting, waterjet cutting, CNC Machining Centers, Electrical Discharge Machining (EDM), and abrading.

The AM cycle starts with designing the part or assembly in 3D CAD, or three-dimensional computer-aided design, software. The part is then converted into a triangular mesh that defines its interior and exterior surfaces, commonly known as an STL file. The STL file is then imported into a program that allows the user to manipulate the mesh and define the parameters for the AM process. This program then takes all the user-defined parameters and generating a tool path for each layer of the print, called slicing. These tool paths are then exported to the machine and the part is made. Understanding this workflow is an important factor when designing parts for additive manufacturing because of the different challenges that come with producing a quality part.

Why choose additive manufacturing?

Additive manufacturing is not a drop-in replacement for any manufacturing process, however a number of different industries such as aircraft, dental, medical, and automotive have turned to additive manufacturing technologies for a number of advantages. Additive manufacturing can be used to design prototypes prior to mass production, customize parts to individual users or setups, quickly create parts for small a production run, or build extremely unusual shapes that are not feasible to manufacture with traditional methods.

Additive manufacturing is most useful for those who need the following.

  1. Parts with complex geometries: The way additive manufacturing builds can create parts that would either be expensive or impossible with traditional manufacturing techniques.
  2. In-house custom parts: Additive manufacturing allows for rapid progress from cad to fully realized parts without the need of a specialized manufacturer. This enables organizations to easily create iterative prototypes and small-scale manufacturing of custom parts for clients.
  3. Specific material properties: The variety of materials available in AM allows for control of various material properties such as strength, stiffness, and toughness. Materials and techniques also allow for more specific properties like food-safe, chemically resistant, and UV reactivity.

Categories

The generally accepted system for sorting additive manufacturing technologies was created by the international standards organization (ISO). This systems sorts printers into seven categories based on how they join material together.

Each category has different strengths and weaknesses when compared with the other additive manufacturing categories. Below is a table populated by observing the range of capabilities within the AM database created by PSU, OIT, and OMIC in Phase 1 of this project. More detailed information on the different categories can be found on the individual webpages, and a more direct comparison can be made between different machines and the potential cost of making parts on those machines can be done using the AM database.

Properties by Category
Type Volume (L) XY Resolution (mm) Layer height (um) Materials Footprint (m^2) Energy use Surface finsih Price
Material Extrusion 1.224 - 1000 0.25 - 1 20 - 300 Thermoplastics, some metals .1-1 Medium Medium Low
Powder Bed Fusion 20 - 160 0.06 - 0.1 20 - 120 Metals, Thermoplastics 1-10 High Medium High
Vat Polymerization 0.65 - 36 0.003 - 0.05 15 - 25 Resins .05-1 Low High medium
Direct energy depostion 8 - 40,000 0.67 - 1 800 - 1000 Metals 4-12 High Poor High
Binder Jetting 20 - 160 0.03 - 0.5 80 - 100 Plastics, Metals, Concrete, Wood 1-4 Low Medium High
Material Jetting .8 - 3,000 .02 - .03 10 - 50 Resins, Wax, Thermoplastics 1-6 Low Best High
Sheet lamintion 9 - 20 .02 - .042 50 - 200 Plastics, Metals, Wood 3-12 Medium Poor High

Parts created through AM technologies have standards that apply to them, similarly to parts created using other technologies. These include Mechanical Testing, Design, Precursor Material, Process and Control, Post Processing, Qualification and Vertification, Nondestructive Evaluation, and Maintenance and Repair. A detailed document on AM standards was produced in Phase 1 of the project.

References

Rosen, David, Brent Stucker, and Mahyar Khorasani. Additive Manufacturing Technologies. Third edition. Cham, Switzerland: Springer, 2021.

“3D Printing - Additive | Make.” Accessed August 10, 2023. https://make.3dexperience.3ds.com/processes/3D-printing.