BALLISTIC PARTICLE MANUFACTURING (BPM)

Download Report

Transcript BALLISTIC PARTICLE MANUFACTURING (BPM) 

SELECTIVE LASER SINTERING
(SLS)
SLS History

Selective Laser Sintering was developed by the University
of Texas in 1987.

Commercialized by DTM Corporation, a subsidiary of B.F.
Goodrich.

Company has strong patent to help absorb financial
burdens of development.

First SLS system shipped in 1992.
SLS Technology
•
SLS system is ranked as high-end RP
modeling.
•
Builds rapid prototyping models using
additive fabrication method.
SLS Technology Continued...
•Click here to view Sinterstation Pro SLS
System and an animated demonstration on
how to use it.
SLS Technology Continued...
•
Uses DTMView software to import, scale, and orient
part to be modeled.
• The Sinterstation Pro is cost-effective. Directly
manufacture customized short production runs.
•
The Sinterstation Pro has a layer thickness: 0.004"
or 0.006.“
• Build size is 22" x 22" x 30."
• Tool-less plastic part manufacturing
• Form/fit/functional plastic prototypes
SLS Technology Continued...
TYPICAL ROOM LAYOUT
Sinterstation Pro SLS system - Manufactures the part(s) from 3-D CAD data.
Rapid Change Module (RCM) - Build module mounted on wheels for quick and easy transfer between
the
Sinterstation, OTS and BOS.
Nitrogen Generator - Delivers a continuous supply of nitrogen to the SLS system.
Offline Thermal Station (OTS) - Pre-heats the RCM before it is loaded into the SLS system and
manages the RCM
cool-down process after a build has been completed.
Break Out Station (BOS) - In the BOS the parts are removed from the RCM. The non-sintered powder
automatically gets sifted and transferred to the IRS.
Integrated Recycling Station (IRS) - The IRS automatically mixes recycled & new powder. The mixed
powder is automatically transferred to the SLS system.
Intelligent Powder Cartridge (IPC) - New powder is loaded into the IRS from a returnable powder
cartridge.
When the IPC is connected to the IRS, electronic material information is automatically transferred to the
SLS system.
SLS Technology Continued...
Click here to view the SLS Sinterstation Pro
with a typical room layout.
How The Sinterstation Pro Works!







First you have to build the setup for the part.
Then remove the RCM from the OTS, then placed in the Sinterstation.
The part is then goes through the Selective Laser SINTERING
process.
The RCM is then unloaded from the Sinterstation and placed back on
the OTS.
Then the RCM is then loaded into the BOS, where the part is broke
out.
The used powder is then sifted and transferred to the IRS, new powder
is then transferred into the IRS.
The IRS mixes the powders and transfers it back to the SLS System.
How SLS (Selective Laser
Sintering) process works

How SLS Works :- SLS process produces parts directly
from 3D CAD model; layer by layer similar to SLA but
rather than liquid resin powder is used. The CO2 Laser
provides a concentrated heating beam which is traced over
the tightly compacted layer of fine heat-fusible powder.
The temperature in the entire chamber is maintained little
below the melting point of the powder. So laser slightly
raises the temperature to cause sintering, means welding
without melting. For next level, piston moves down along
with the formed object and powder is spread with a roller
for next layer. Process repeats until full object is formed.
How SLS (Selective Laser
Sintering) process works (con’t)
Click here to view a diagram on how the
Selective Laser Sintering process works.
SLS Uses
•
Produces patterns for casting.
•
Creating highly detailed Functional parts.
•
Rapid tooling from powdered carbon steel.
•
Significant impact on prototype manufacturing industry
and RP job shops.
•
Ideal for Automotive, Motorsports, Aerospace, White Goods/Kitchen
Appliances, R&D and others needing small to extra-large plastic parts
from 3-D CAD data
SLS Uses Continued…
•Click here to view samples of SLS uses from
the www.conceptual_reality.com site.
SLS Advantages
•
Robust System and High End Products.
•
Conceptual Models.
•
Functional Prototypes.
•
Pattern Masters for casting.
•
Rapid Tooling.
•
Wide Range of Building Materials.
•
High Throughput Capability.
•
intelligent powder tracking
•
Largest available part size
SLS Disadvantages
•
Large Amount of Up-Front Capital.
•
Designed for Large Manufacturing Industries.
•
High Maintenance Cost
•
High power requirements for Sinterstation Pro.
•
Requires lots of open space.
REFERENCES
• http://www.arptech.com.au/slshelp.htm
• http://www.3dsystems.com/products/sls/sint
erstation_pro/index.asp