Precision glass moulding is a replicative process that allows the production of high precision
optical components from
glass
Glass is a non-crystalline, often transparent, amorphous solid that has widespread practical, technological, and decorative use in, for example, window panes, tableware, and optics. Glass is most often formed by rapid cooling (quenching) of ...
without
grinding
Grind is the cross-sectional shape of a blade.
Grind, grinds, or grinding may also refer to:
Grinding action
* Grinding (abrasive cutting), a method of crafting
* Grinding (dance), suggestive club dancing
* Grinding (video gaming), repetitive and ...
and
polishing
Polishing is the process of creating a smooth and shiny surface by rubbing it or by applying a chemical treatment, leaving a clean surface with a significant specular reflection (still limited by the index of refraction of the material accordin ...
. The process is also known as ultra-precision glass pressing. It is used to manufacture precision glass
lenses
A lens is a transmissive optical device which focuses or disperses a light beam by means of refraction. A simple lens consists of a single piece of transparent material, while a compound lens consists of several simple lenses (''elements''), ...
for consumer products such as
digital camera
A digital camera is a camera that captures photographs in digital memory. Most cameras produced today are digital, largely replacing those that capture images on photographic film. Digital cameras are now widely incorporated into mobile device ...
s, and high-end products like medical systems. The main advantage over mechanical lens production is that complex lens geometries such as
aspheres can be produced cost-efficiently.
Process
The precision glass moulding process consists of six steps:
[Klocke, F. et al.: "Manufacturing of glass diffractive optics by use of molding process", ''American Society for Precision Engineering (Annual Meeting)'' 21, 2006, Monterey/Calif.]
#The
glass blank
A glass blank is a piece of glass that requires additional decoration before it is considered finished. Types of decoration include cutting, engraving, acid-etching, gilding, and enameling. Often the term blank is used in reference to an uncut pie ...
is loaded into the lower side of the moulding tool.
#
Oxygen
Oxygen is the chemical element with the symbol O and atomic number 8. It is a member of the chalcogen group in the periodic table, a highly reactive nonmetal, and an oxidizing agent that readily forms oxides with most elements as wel ...
is removed from the working area by filling with
nitrogen
Nitrogen is the chemical element with the symbol N and atomic number 7. Nitrogen is a nonmetal and the lightest member of group 15 of the periodic table, often called the pnictogens. It is a common element in the universe, estimated at se ...
and/or
evacuation of the process chamber.
#The tool system is nearly closed (no contact of the upper mould) and the entire system of mould, die and glass is heated up.
Infrared
Infrared (IR), sometimes called infrared light, is electromagnetic radiation (EMR) with wavelengths longer than those of visible light. It is therefore invisible to the human eye. IR is generally understood to encompass wavelengths from around ...
lamps are used for heating in most systems.
#After reaching the working temperature, which is between the
transition temperature
Transition temperature is the temperature at which a material changes from one crystal state (allotrope) to another. More formally, it is the temperature at which two crystalline forms of a substance can co-exist in equilibrium. For example, when ...
and the
softening point The softening point is the temperature at which a material softens beyond some arbitrary softness. It can be determined, for example, by the Vicat method (ASTM-D1525 or ISO 306), Heat Deflection Test (ASTM-D648) or a ring and ball method (ISO 4625 ...
of the glass, the moulds close further and start pressing the glass in a travel-controlled process.
#When the final thickness of the part has been achieved, the pressing switches over to a force-controlled process.
#After moulding has been completed, the glass is cooled down and the working environment is filled with nitrogen. When the lens has cooled to the point where it can be handled, it is removed from the tool.
The process is executed on a specialized moulding machine, which precisely controls the temperature, travel, and force during the process. The tools used must withstand high temperatures and pressures, and need to be resistant to chemical interaction with the glass. The mold materials also have to be suitable for machining into the precise surface profiles.
Process chain
In order to ensure the desired quality the parts are measured between each process step. Additionally, the parts are handled and transported carefully between the processing and metrology steps.
#Hotforming of gobs: The precision glass moulding process yields the best results in both quality and cost if it works with precise preforms. These are usually acquired by pressing or hotforming of "gobs" of molten glass. This step is done by continuous glass melting and moulding in single-sided metal moulds. This process is only suitable for high production volumes. For smaller production volumes, the preforms have to be manufactured by mechanical material-removing steps from blocks or slices of raw glass.
#Precision glass moulding: In this step the preform is directly formed into an optical glass lens. It is necessary to clean the glass preform and the mould before starting the process, but there is no polishing or post-machining required.
#Lens coating: An
antireflection coating
An antireflective, antiglare or anti-reflection (AR) coating is a type of optical coating applied to the surface of lenses, other optical elements, and photovoltaic cells to reduce reflection. In typical imaging systems, this improves the effici ...
is applied to the finished lenses. The lenses are first cleaned, and then loaded into a fixture. The fixture, containing a large number of lenses, is placed in the coating machine. After finishing the process the glass lenses are removed from the holder and the holder is cleaned by sand-blasting or other techniques. Usually the
optical coating
An optical coating is one or more thin layers of material deposited on an optical component such as a lens, prism or mirror, which alters the way in which the optic reflects and transmits light. These coatings have become a key technology in th ...
is done by one of two methods:
physical vapour deposition
Physical vapor deposition (PVD), sometimes called physical vapor transport (PVT), describes a variety of vacuum deposition methods which can be used to produce thin films and coatings on substrates including metals, ceramics, glass, and poly ...
(PVD), in which oxide materials evaporate and are deposited on the lens, and
plasma-enhanced chemical vapor deposition
Plasma-enhanced chemical vapor deposition (PECVD) is a chemical vapor deposition process used to deposit thin films from a gas state (vapor) to a solid state on a substrate. Chemical reactions are involved in the process, which occur after creati ...
(PECVD). Chemical reactions take place in a vacuum and the reaction product is deposited on the lens. The lenses are coated for two reasons:
##Manipulate or improve the optical transmission / reflection
##Enhance the mechanical, chemical or electrical properties
Tool and mould design
Lens shapes
Shape of optical element
Precision glass moulding can be used to produce a large variety of optical form elements such as
spheres
The Synchronized Position Hold Engage and Reorient Experimental Satellite (SPHERES) are a series of miniaturized satellites developed by MIT's Space Systems Laboratory for NASA and US Military, to be used as a low-risk, extensible test bed for the ...
,
aspheres, free-form elements and
array
An array is a systematic arrangement of similar objects, usually in rows and columns.
Things called an array include:
{{TOC right
Music
* In twelve-tone and serial composition, the presentation of simultaneous twelve-tone sets such that the ...
-structures.
Concerning the curvature of the lens elements, the following statements can be drawn: Acceptable lens shapes are most
bi-convex,
plano-convex
Plano-convex may refer to:
* Plano-convex lens, in optics
* Plano-convex, a type of mudbrick
A mudbrick or mud-brick is an air-dried brick, made of a mixture of loam, mud, sand and water mixed with a binding material such as rice husks or ...
and mild
meniscus
Meniscus may refer to:
*Meniscus (anatomy), crescent-shaped fibrocartilaginous structure that partly divides a joint cavity
*Meniscus (liquid)
The meniscus (plural: ''menisci'', from the Greek for "crescent") is the curve in the upper surface ...
shapes. Not unacceptable but hard to mould are
bi-concave lenses, steep meniscus lenses, and lenses with severe features (e.g. a bump on a convex surface).
In general, plano-curved lenses are easier to mould than lenses with both sides curved since matching of flat faces is easier.
Moulding concave forms with small centre thickness is difficult due to sticking of the moulded part to the mould occurring as a result of the different thermal expansion coefficients.
Furthermore it is recommended to avoid undercuts and sharp edges. For the lens design it should be considered that the lens has to be mountable in measurement systems.
Shape of preforms
The shape of the preform or "blank" needs to be chosen according to the geometry of the finished optical element. Possible
preforms are spherical (ball), near spherical (gob), plano-plano, plano-convex, plano-concave, biconvex and biconcave blanks. Ball and gob-blanks do not have to be premachined whereas other preforms require grinding and polishing.
The following section describes basic traits of preform choice:
* Formed Ball Preform
“Used specifically for lenses with positive power: biconvex, plano-convex, and meniscus where the convex side is stronger than the concave side, this only works for a relatively small volume of material.”
* Ground and Polished Plano-Plano Preform
“As a lens changes to negative in power biconcave, plano-concave, and meniscus
where the concave side is stronger, an alternative preform shape, plano-plano, is required
for the molding process.
Relative to a formed preform an increase in cost is observed for the manufacturing of this type of preform.”
* Ground and Polished Ball Preform
“When the geometry of a lens extends beyond the volume range of a formed ball
preform, a ground and polished ball preform is required. Used for lenses with positive
power: biconvex, plano-convex, and meniscus: where the convex side is stronger, this
geometry allows for molding of lenses with larger total volume.
Relative to a formed
preform and a plano-plano preform, an increase in cost is observed for the manufacturing
of this type of preform.”
* Ground and Polished Lenslet Preform
“The Lenslet preform is primarily for lenses with positive power, biconvex, planoconvex,
and meniscus: where the convex side is the strongest surface. The use of this
type of preform allows for molding of the largest volume of glass at any given time in the
molding machines. The Lenslet is traditionally ground and polished to a near net shape of the final lens, and then pressed.
..The cost associated with the manufacturing of the lenslet preform is the highest of all preform types.”
* Gob Preform
Precision gobs can be used as preforms for the production of aspherical lenses in a precision molding process. They are manufactured from a continuous glass melting process. The resulting precision gobs exhibit a very smooth firepolished surface with an excellent surface roughness and high volume accuracy.
Dimensions
The dimensions of the optical elements that can be moulded depend on the size of the moulding machine.
The precision glass moulding process is not limited to small optics. For the right element geometry, it can enable economical production of aspheric lenses up to 60 mm in diameter and more than 20 mm thick.
[Vogt, H.: Precision moulding provides compact consumer optics. Laser Focus World, July 2007, pp.115-118. To view the article online clic]
here
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General design recommendations:
Size:
* Diameter range: 0.5–70 mm depending on the application[Braunecker, B.: Advanced Optics Using Aspherical Elements. SPIE Press, Bellingham, 2008, p.264]
* Flank angle: Sometimes <60 degree due to limited metrology but higher angles are possible by some manufacturers that have expanded metrology capabilities (e.g. Panasonic UA3P or similar).
* Edge thickness preferably > 1.0 mm, alternatively 0.5 to 2.0 x center thickness
* Clear aperture should be smaller than the lens diameter, preferably at least 1.0 mm (per side) less
* Optical surfaces:
Radius:
* Base radius no less than 3.0 mm
Optical Surfaces:
* Sags no greater than 8 mm on both concave and convex surfaces
* Transition from the optical surface to the lens outside diameter requires a minimum radius value of 0.3 mm.
Volume:
* Volume of the lens (including flanges), V <= 4/3 π r3, where r is the smallest local convex radius.
Tolerances
Although the form, dimensional and positional tolerances that can be achieved in precision glass moulding are subject to a natural border, the values being achieved in practice strongly depend on the degree of control and experience in mould making and moulding. The table below gives an overview of achievable manufacturing tolerances in precision glass moulding at different companies.
For aspherical lenses, the design should be able to tolerate 0.010 mm of lateral shear between surfaces plus 5 micrometres Total Internal Reflection of wedge (across the part without considering the lateral shear) to be considered robust.
Specifications for aspheres:
* Surface roughness (Ra): < 3 µm depending on diameter
* Form error (PV): < 1 µm depending on diameter
Index drop
Due to the fast cooling after moulding, the part retains a small amount of residual stress. Consequently, the glass exhibits a small change in the refractive index which has to be considered in the optical design. A higher cooling rate corresponds to a larger decrease of the refractive index. A lower cooling rate could circumvent the index drop, but would be less cost-efficient[Deegan, J. et al.: RPO Precision Glass Moulding Technical Brief 6/28/2007. Downloa]
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Glass material
Many glasses can be used with PGM. However, there are some limitations:
* The glass transition temperature Tg must not exceed the maximum heating temperature of the mould
* Many lead oxide flint glasses are not compliant with the RoHS EU directive (''Restriction of certain Hazardous Substances'')
* The glass composition influences moulding tool life
* Chalcogenide materials require certain preform shapes
* Glass expansion/contraction is highly temperature and rate dependent phenomenon. The coefficient of thermal expansion
Thermal expansion is the tendency of matter to change its shape
A shape or figure is a graphics, graphical representation of an object or its external boundary, outline, or external Surface (mathematics), surface, as opposed to other pro ...
(CTE) of mould and glass should match. High CTE difference means high deviation between the moulded glass and the mould. High CTE glasses are also critical in terms of non-uniform temperature distribution in the glass. This means that especially fast cooling can not be applied. In addition to this, the temperature difference between the warm lens directly after moulding and the surrounding air can easily cause cracks.
* In addition, temperature dependence of viscosity of glass, structural and stress viscoelastic relaxation of glass play an important role in determination of lens preform shape, final state of stress and shape deviation.[Ananthasayanam et.al. Final Shape of Precision Molded Optics: Part II—Validation and Sensitivity to Material Properties and Process Parameters, https://www.tandfonline.com/doi/abs/10.1080/01495739.2012.674838]
* The internal and external quality of the blank must be the same or better than the requirements of the finished lens since the precision glass moulding process is not able to improve the glass quality.
* The glass exhibits a change in refractive index, called index drop, during the annealing process. This drop is caused by fast cooling of the mould insert, inducing a small amount of residual stress in the glass. As a result, the glass exhibits a small index change when compared to its fine anneal state. The index drop is small (usually .002-.006), but the optical design needs to be optimized to compensate for this change. As an example, the index drop for different glass types is displayed in the picture on the right for different annealing rates. Note that the annealing rate is not necessarily constant during the cooling process. Typical “average” annealing rates for precision molding are between 1000 K/h and 10,000 K/h (or higher). Not only the refractive index, but also the Abbe-number of the glass is changed due to fast annealing. The shown points in the picture on the right indicate an annealing rate of 3500k/h.
So-called "low-Tg-glasses" with a maximum transition temperature of less than 550 °C have been developed in order to enable new manufacturing routes for the moulds. Mould materials such as steel can be used for moulding low-Tg-glasses whereas high-Tg–glasses require a high-temperature mould material, such as tungsten carbide
Tungsten carbide (chemical formula: WC) is a chemical compound (specifically, a carbide) containing equal parts of tungsten and carbon atoms. In its most basic form, tungsten carbide is a fine gray powder, but it can be pressed and formed into ...
.
Substrate materials
The mould material must have sufficient strength, hardness and accuracy at high temperature and pressure. Good oxidation resistance, low thermal expansion and high thermal conductivity are also required.
The material of the mould has to be suitable to withstand the process temperatures without undergoing deforming processes. Therefore, the mould material choice depends critically on the transition temperature of the glass material. For low-Tg-glasses, steel moulds with a nickel alloy coating can be used. Since they cannot withstand the high temperatures required for regular optical glasses, heat-resistant materials such as carbide alloys have to be used instead in this case. In addition, mould materials include aluminium alloys, glasslike or vitreous carbon, silicon carbide, silicon nitride and a mixture of silicon carbide and carbon.
A commonly used material in mould making is tungsten carbide
Tungsten carbide (chemical formula: WC) is a chemical compound (specifically, a carbide) containing equal parts of tungsten and carbon atoms. In its most basic form, tungsten carbide is a fine gray powder, but it can be pressed and formed into ...
. The mould inserts are produced by means of powder metallurgy, i.e. a sintering process followed by post-machining processes and sophisticated grinding operations. Most commonly a metallic binder (usually cobalt) is added in liquid phase sintering. In this process, the metallic binder improves the toughness of the mould as well as the sintering quality in the liquid phase to fully dense material.[Choi, W. et al.: Design and fabrication of tungsten carbide mould with micro patterns imprinted by micro lithography. J. Micromech. Microeng. 14 (2004) 1519–1525]
Moulds made of hard materials have a typical lifetime of thousands of parts (size dependent) and are cost-effective for volumes of 200-1000+ (depending upon the size of the part).
Mould manufacturing
This article describes how mould inserts are manufactured for precision glass moulding.
In order to ensure high quality standards metrology steps are implemented between each process step.
# Powder processing: This process step is responsible for achieving grain sizes suitable for pressing and machining. The powder is processed by milling the raw material.
# Pressing: This step does the pre-forming of "green" raw bodies of the mould inserts.
# Sintering
Clinker nodules produced by sintering
Sintering or frittage is the process of compacting and forming a solid mass of material by pressure or heat without melting it to the point of liquefaction.
Sintering happens as part of a manufacturing ...
: By sintering, the pre-formed green bodies are compressed and hardened. In order to do this the green body is heated to a temperature below the melting temperature. The sintering process consists of three phases: First, the volume and the porosity is reduced and secondly, the open porosity is reduced. In the third phase, sinter necks are formed which enhance the material's strength.
# Pre-Machining: The step of Pre-Machining creates the main form of the optical insert. It typically contains four process steps. These steps are grinding the inner/outer diameter, grinding the parallel/end faces of the insert, grinding/lapping of the fitting of insert, and finally, the near-net-shape grinding of the cavity. Normally, the cavity is only pre-machined to a flat or a best-fit sphere.
# Grinding
Grind is the cross-sectional shape of a blade.
Grind, grinds, or grinding may also refer to:
Grinding action
* Grinding (abrasive cutting), a method of crafting
* Grinding (dance), suggestive club dancing
* Grinding (video gaming), repetitive and ...
: Grinding or finish-machining creates the final form and the surface finish of the cavity in the mould insert. Usually, the finish is carried out by grinding; a subsequent polishing step is optionally required. Finish grinding can require several changes of the grinding tool and several truing steps of the tool. Finish-machining of the mould is an iterative process: As long as the machined mould shows deviations from the nominal contour in the measurement step after grinding, it has to be reground. There is no well-defined border between pre-machining and fine grinding. Throughout the grinding process of the cavity, the grain size of the tool, the feed rate and the cutting depth are reduced whereas machining time increases. Convex surfaces are easier to manufacture. The necessary steps of workpiece preparation are the mould alignment and the mould referencing. Grinding tool alignment, grinding tool referencing and grinding tool truing also have to be done. After that polishing can be necessary to remove the anisotropic structure which remains after grinding. It can be performed manually or by a CNC-machine.
# Coating
A coating is a covering that is applied to the surface of an object, usually referred to as the Substrate (materials science), substrate. The purpose of applying the coating may be decorative, functional, or both. Coatings may be applied as liquid ...
: Coating is the process step in which a layer is applied on the cavity surface of the optical insert which protects the mould against wear, corrosion, friction, sticking of glass and chemical reactions with glass. For coating the surface of moulds by physical vapour deposition (PVD), metals are evaporated in combination with process-gas-based chemicals. On the tool surface, highly adherent thin coatings are synthesized. Materials for coatings on optical inserts are Platinum-based PVD (mostly iridium-alloyed, standard), diamond-like carbon (not yet commercially available), SiC (CVD) on SiC-ceramics (not yet commercially available, have to be post-machined) or TiAlN (not yet commercially available). To achieve a homogeneous layer thickness, the mould's position has to be changed during coating. To prepare the mould for the coating the surfaces have to be degreased, cleaned (under clean room or near-clean room conditions) and batched. Especially the cathode of the machine has to be cleaned. After this process the workpiece has to be debatched.
# Assembly
Assembly may refer to:
Organisations and meetings
* Deliberative assembly, a gathering of members who use parliamentary procedure for making decisions
* General assembly, an official meeting of the members of an organization or of their representa ...
: In this process step the optical insert and the mould base are combined to the assembled mould. For one optical element two mould inserts are necessary which are assembled outside the machine. For the assembly height measurement and spacer adjustment are essential.
# Moulding Tests: This step determines whether the mould creates the specified form and surface quality. If mould is not suitable, it has to be reground. It is part of an iterative loop. The assembly of the mould has to be put into the machine to start the try-out-moulding.
In order to save the quality and enable an early warning in case of any problems between every single step there has to be a step of measurement and referencing. Besides that the time for transport and handling has to be taken into account in the planning of the process.
Metrology and quality assurance
Once process and tool have been developed, precision glass moulding has a great advantage over conventional
production techniques. The majority of the lens quality characteristics are tool-bound. This means that lenses, which
are pressed with the same tool and process, usually have only insignificantly small deviations. For example, an important characteristic of a lens is the form of the optical surface. In the case of aspherical lenses the measurement of optical surfaces is very difficult and connected to high efforts. Additionally, when working with tactile measurement systems there is always a risk that the optical surface might be scratched. For precision moulded lenses such measurements are only necessary for a small amount of sample lenses in order to qualify the tool. The series production can then be executed without further need for measurements. In this case, only the cleanliness of the optical surface has to be monitored. Another advantage is that the lens' center thickness can be estimated from the easily measurable edge thickness or by applying a contactless measurement system.
Protective coatings
In order to enhance the mould insert's lifetime, protective coatings can be applied. “The materials that have been selected for the antistick coatings can be divided into 5 groups including: (1) single layer carbides, nitrides, oxides and borides such as , , , , , , and , (2) nitrides or carbides based gradient and multilayers, (3) nitrides based superlattice films, (4) amorphous carbon or diamond-like carbon and (5) precious metal based alloys”[Ma, K.J. et al.: Design of Protective Coatings for Glass Lens Molding. Key Engineering Materials Vols. 364-366 (2008), pp 655-661]
Experiments carried out by Ma et al. yield the following results:
“The higher the temperature, the smaller the wetting angle between glass gob and substrate could be observed. This indicates that severe interface chemical reaction occurred and resulted in the loss of transparency in glass appearance. The wetting experiment in nitrogen ambient improved the sticking situation. The combination of chemically stable substrates and coatings, such as Sapphire (substrate) / GaN (film) and Glass (substrate) / (film) can achieve the best antistick propose. The precious metal films such as (Platinum, Iridium) coated on the ceramic substrates can effectively reduce the interface reaction between the glass and substrates.”
Although is used as a standard coating material, it has the disadvantage of being expensive. Therefore, research activities aim at substituting with cheaper materials.
See also
*Fabrication and testing (optical components)
Optical manufacturing and testing spans an enormous range of manufacturing procedures and optical test configurations.
The manufacture of a conventional spherical lens typically begins with the generation of the optic's rough shape by grinding a ...
References
{{DEFAULTSORT:Precision Glass Moulding
Optics
Glass production