Download
1 / 41
440 likes | 694 Views
Outline:. Laser TechnologyProcesses:CuttingDrillingWeldingRapid PrototypingOther: Precise Measurement, Heat Treatment, ScribingGeneral Advantages and DisadvantagesEconomicsSafety measures. Laser Technology. Laser Technology. Laser is an abbreviation of light amplification by stimulated emi
E N D
2. Outline: Laser Technology
Processes:
Cutting
Drilling
Welding
Rapid Prototyping
Other: Precise Measurement, Heat Treatment, Scribing
General Advantages and Disadvantages
Economics
Safety measures
3. Laser Technology Laser is an abbreviation of “light amplification by stimulated emission of radiation”
Laser Beam operation are based on producing high energy laser beam that melts and vaporizes the material.
Can be used to cut, weld, drill by varying both power and beam intensity, focus, and duration.
4. Laser Technology
5. Laser Technology A relatively weak light flash bounces back and forth between the mirrors causing the lasing material to produce energy (photons)
These photons accelerate the intensity of the beam of light which will cause the beam to cross the partial mirror after reaching a certain intensity.
A lens focuses the beam on the work piece causing portions of it to melt and vaporize.
6. Laser Technology Beam Generation
8. Laser Technology High Power.
Monochromatic: Same wave length (same color).
Coherent: light waves in phase.
Non-contact.
9. Laser Technology Reflectivity.
Thermal Conductivity.
Specific Heat
Latent Heat
10. Laser Technology 1. Hard Optic Delivery (Moving workpiece):
relatively inexpensive.
can accommodate large heavy lasers.
operate quick (20 m/min).
but heavy large piece limited.
11. Laser Technology
12. Laser Technology
13. Processes
14. Processes: Cutting Cutting starts by drilling a hole then moving the beam in a programmed path.
A stream of assist gas is used to:
blow the molten metal
Cool workpiece
Minimize heat affected zone
15. Processes: Cutting
Mild steel: Oxygen
Stainless steel: Oxygen or nitrogen (nitrogen leaves an oxide free edge that can improve weldability)
Aluminum: Nitrogen
Titanium:Argon (an inert gas because of its reactivity)
Nonmetals: Air or inert gas
16. Processes: Cutting Cutting Temperature could reach 11000oC.
The more uniform the thermal characteristics of component the better the cut and less thermal damage to the material.
Cutting Speed depends on:
(can reach 1000in/min in nonmetals)
Material
Thickness
17. Processes: Cutting Cutting Capabilities: (Thickness)
Acrylic and composites 1 in
Aluminum ¼ in
Mild steel 0.625 in
Stainless steel 5/16 in
Titanium ¼ in
18. Processes: Cutting Applications
19. Processes: Cutting Advantages:
Narrow kerf and heat affected zone
Although cutting produces a thin recast surface, no post-cut finishing is required
Economic alternative for materials that are difficult to cut by conventional methods(plastics, wood, and composites)
Narrow slots
Closely spaced patterns
Does not require smooth surface
20. Processes: Drilling The repeated pulsed laser beam vaporizes the material layer by layer until a through hole is formed.
Larger diameters can be contoured after drilling the through hole if desired.
Blind holes are theoretically possible but not practical.
Hole diameter depends on material thickness.
Cutting and drilling are performed on the same unit.
21. Processes: Drilling Drill micro-holes in metals as thick as 0.1in
L:D ratio: 10:1
Cutting Speed decreases? depth increases but:
Generates irregular holes
Recast layer increases
Heat affected zone increases
22. Processes: Drilling Applications:
Bleeder holes for fuel pump covers
Drilling holes in delicate medical materials
Drilling holes in small polymer tubes
Drills tiny holes in turbine blades of jet engine
23. Processes: Drilling Advantages:
Burr free holes
Eliminates drill breakage and wear
Drills in difficult to access areas, curved surfaces and parts incased in glass
Drills holes of almost any shape
High quality and precision holes
Close tolerances
Limitations:
Holes up to 1” deep in plastics and ferrous metals, and 0.125” in reflective materials.
24. Processes: Welding High intensity beam produces a cause the material to melt and flow into the channel (gap) as the beam advances.
Careful joint preparation is needed to produce the thin gap.
forms a very thin heat affected zone and little thermal distortion.
25. Processes: Welding Solidifies quickly
Filler material is used if gap is large.
Inert (Shielding) gas is may be used to prevent oxidation of weld pool.
Can be used to produce deep penetration welds
Effective with thin workpiece
26. Processes: Welding Applications
Razor blades: 13 pinpoint welds 0.5 mm in diameter
Electronic circuits
27. Processes: Welding Advantages:
Does not require vacuum
Better quality of weld
Beam easily shaped, directed, and focused
No direct contact is necessary to produce a weld
Encapsulated (with transparent containers) and inaccessible areas can be welded
Can be made with access to only one side of joint
Increase speed and strength of welding
Produces maximum penetration and minimum distortion in the material
28. Processes: Rapid Prototyping 3D CAD Software is used to slice a 3D model into 2D horizontal layers packed on top of each other
A laser beam then starts to build the first layer by melting and fusing powder metal.
29. Processes: Rapid Prototyping The layer then solidifies and fresh power is added on top of it for the next layer
The laser beam proceeds building the physical prototype layer by layer until it is done.
Model is cleaned, cured, and then can be used for testing in environments similar to that of the final product
30. Processes: Rapid Prototyping Applications:
31. Processes: Rapid Prototyping Advantages:
Speeds up the design and manufacturing process.
Reduces product development cost.
Allows for instant feedback to design engineers.
Allows for design corrections at an early stage.
The model is used in pre-production planning and tool design.
32. Processes: Rapid Prototyping Disadvantages:
The generated model has shrinkage cracks
The model has high hardness, which makes it brittle
Thick walled structures can’t be built up very well
33. Processes: Measurements Helium-Neon laser beam is split into two beams one beam goes to a reference point and reflects back using a retro-reflector, while the other hits the object.
Then the two beams are recombined, and their relative motion creates a frequency shift.
This shift is then converted into a distance measurement.
34. Processes: Measurements Applications
To align and calibrate machine tools
Useful in Large assembly jigs
Non-contact: used to inspect hot rolled material
35. Processes: Heat Treatment Produces hardened surfaces
For wide variety of geometries
Can work on limited area
Produces little distortion
36. Processes: Scribing Composed of series of closely placed holes
To produce lines and characters with different fonts on materials
As wide as laser beam
Set to a specific tolerance depth
37. General Advantages Operates in fully automated environment
Minimum heat affected zone compared to other thermal processes
Clean
Small clamping force is applied
Can be used with metals, nonmetals, and composites
Excellent surface quality
Minimum thermal stresses on the material
No tooling required
38. General Disadvantages Requires specially trained operators
Not for mass metal removal processes
Requires greater control of joint tolerances
Expensive equipment
Consumes much energy
39. Economics Expensive equipment
Requires skilled operators
Compensated by:
Fast material removal rate (0.5-7.5m/min) ? high production rates
Finishing costs are eliminated
Can be automated ? reducing operational costs
40. Economics Cost of Laser Cutting Machine
New: $200,000
Used: starting $30,000
CNC: $750,000
41. Safety Measures Lasers can burn and blind:
Eyes and skin should be protected from scattered beams
Even low powers can cause damage to retina
Operator should wear gas masks to protect against generated fumes
