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CNC Glass Machining

December 2017 | See all Trending in Optics Topics

Machining of Optical Components with Complex Geometries

 

Facilitates Manufacture of Optical Components with Complex Geometries

 

Machine Wide Range of Materials that Cannot be Machined Through Conventional Methods

 

Creates Specialty Counterbores, Bevels, Chamfers, Steps, Slots, and More

 

More Repeatable than Conventional Manually Operated Machining

Computer Numerical Control (CNC) machines are quickly gaining traction as indispensable tools for machining optical components with complex geometries. They are computer controlled electro-mechanical devices programmed with a machining language called “G-code,” and have numerous benefits over operator-required conventional machining. CNC machines offer the highest amount of precision, flexibility, and repeatability when it comes to fabricating components beyond basic shapes. CNC machining has been used for manufacturing metal and plastic parts for decades but is now pushing the boundaries of manufacturing glass and other optical materials. In addition to optical glass, CNC machining can be used to machine a wide range of demanding materials including ceramics, corundum, tungsten carbide, and even composites. Some of these advanced materials, such as Tungsten Carbide and composites, cannot be machined using conventional machining.

Advantages of CNC Glass Machining

CNC machining offers numerous advantages over conventional grinding and polishing for fabricating optical components including:

 24 Hour Operation
CNC machines have the ability to work 24 hours a day, 365 days a year, only needing to be switched off for maintenance or repair.

 Complex Component Geometries
CNC machines are able to create components with complex geometries including bevels, deep holes, counterbores, chamfers, steps, slots, notches, and more. Even the most skilled operators using conventional machines cannot achieve the same precision and repeatability as CNC machines.

 Limited Supervision Required
Fewer technicians are required to monitor the work of CNC machines compared to conventional methods because CNC machines are autonomous. Their autonomy allows for one person to watch several machines operate for hours on end after they have been programmed. The reduction of the number of technicians needed also reduces operating costs.

 Repeatability
CNC machines have excellent repeatability because every component is manufactured following the same program. In conventional machining, even the most talented operators will produce components that vary slightly; this is not the case with CNC machines.

CNC UltraForm® Finishing Asphere Polisher
Figure 1: CNC UltraForm® Finishing Asphere Polisher
CNC DMG MORI® ULTRASONIC 5-Axis Precision Machine Center
Figure 2: CNC DMG MORI® ULTRASONIC 5-Axis Precision Machine Center

Disadvantages of CNC Glass Machining

The main disadvantage of CNC glass machining is that the upfront cost of purchasing CNC machines is higher than that of conventional machines. More expensive equipment leads to higher prices for customers, but CNC glass machining can create intricate features with far more precision and repeatability than conventional equipment. CNC glass machining isn’t a cost effective method for making simple optics like spherical lenses and right angle prisms, but it is the ideal method for manufacturing components with complex geometries.

Example Applications

CNC machined precision optical components from Edmund Optics are ideal for a wide variety of applications including advanced space telescopes and liquid chromatography systems.

Defense and Aerospace

Defense and Aerospace

Ultra-lightweight mirror substrates and other components with intricate cuts and bevels

Biotechnology

Biotechnology

Flow cells and other glass components with intricate channels and holes

Semiconductor

Semiconductor

Reference frames and cubes, wafer stages, high precision polygon mirrors, and more

Advanced Telescopes

Advanced Telescopes

Stabilized mirror substrates made from ZERODUR® and other advanced materials

CNC Glass Machining at Edmund Optics®

Edmund Optics® (EO) employs a wide range of CNC glass machining equipment to machine complex optical component geometries including ultrasonic machining and high speed cutting (HSC) technology from DMG MORI®. Our true 5-axis precision machine centers have the capability to machine lightweight structures and high aspect ratio components with specialty bevels, precision holes and inserts, and mounting interfaces. In addition to optical glass, we machine a wide range of demanding materials including ceramics, corundum, tungsten carbide, and even composites.

Capabilities

Visit our capabilities section to learn more about our CNC Glass Machining

CNC Glass Machining at Edmund Optics

FAQ's

FAQ  What materials can Edmund Optics® machine using CNC equipment?
Edmund Optics® can manufacture optical components with complex geometries out of optical glass, ZERODUR®, Ceramics, Corundum, Tungsten Carbide, and even composite materials.
FAQ  What other types of CNC equipment does Edmund Optics® have besides the DMG MORI® ULTRASONIC 5-Axis Precision Machine Centers?

In addition to DMG MORI® ULTRASONIC 5-Axis Precision Machine Centers, Edmund Optics® utilizes 5-Axis CNC Grinding Machines, 5-Axis CNC Polishing Machines, 3-Axis CNC Profiling Machines, 4-Axis CNC Slicing Machines, and 3-Axis CNC Milling Machines.

FAQ  What are the largest size component(s) Edmund Optics® can manufacture using CNC equipment?

The maximum component diameter that Edmund Optics® can manufacture using our DMG MORI® ULTRASONIC 5-Axis Precision Machine Centers is 175mm.

FAQ  Why hasn’t all optical manufacturing equipment been replaced with CNC machines?
The high upfront cost of CNC equipment prevents it from being adopted universally, but its numerous advantages and long-term cost savings are making these machines become more universally used.
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