Optically Clear Materials | Encapsulants & Underfills

Product Selector Guide

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OPTOLINQ&#; Optically Clear Epoxy Liquid Encapsulant and Casting Compounds

Product Chemistry Key Benefit Mix Ratio (w/w) Mixed Viscosity at 25°C (cP) Hardness Glass Transition Temperature (°C) CTE 1 / CTE 2 Refractive Index Optical Transmittance Dielectric Strength (kV/mm) Baking Condition LE- Epoxy Non-Yellowing 300:100 548 70 Shore D - 80 - >90 20 24h @ 25°C, 4h @ 50&#;60°C LE-HT Epoxy + PU Hybrid BPA Free 300:100 370 77 Shore D - 80 - >90 >16 24h @ 25°C, 4h @ 50&#;60°C, 2h @ 80°C LE- Epoxy Halogen Free 300:100 450 - - - - - - 24h @ 25°C, 2-4h @ under 60°C, 1h @ 100°C LE-HY Epoxy Yellowing Resistant 300:100 449 72 Shore D - - 84.5 at 550 nm 12-18 - 24h @ 25°C, 2-4h @ under 60°C, 1h @ 100°C LE- Epoxy UV and Thermal Resistant 100:95 400-800 - 167-173 65-75/170-190 - >80% at 900nm -nm - 1 h at 130 °C and 4 h at 150 °C LE-U Epoxy UV and Thermal Resistant 100:95 400-800 - 167-173 65-75/170-190 - >80% at 400nm -nm - 1 h at 130 °C and 4 h at 150 °C OLS- Epoxy Low Cost 100:100 - 88 Shore D 130 60/183 1.52 at 460nm >90% at 460nm >23 See Curing Conditions  OLS-HF Epoxy Low Halogen, High Transmittance 100:100 88 Shore D 159 66/ 1.51 at 460nm >90% at 400nm -nm >23 See Curing Conditions OLS- Epoxy Anti-blue decay 100:100 85 Shore D 127 - 1.52 at 460nm >99% at 400nm -nm - See Curing Conditions OLS-HV Epoxy Available with VIS Light Blockers 100:100 840±170 85±5 Shore D 137±5 <80/- - >90% at 400nm -nm 20 1 - 1.5hrs at 130-145°C OLS-LV Epoxy Available with VIS Light Blockers 100:100 100±50 - 143±5 <80/- - >90% at 400nm -nm 20 1 - 1.5hrs at 130-145°C OLS- Epoxy Low Viscosity 100:20 250±100 - 122&#;132 85/- - - 20 4-6 hrs at 150°C OLS- Epoxy - 100:100 - - 81-91 40/- - - - 5 mins at 150 °C and 6&#;8 hrs at 130&#;135 °C Top of Page

 

OPTOLINQ&#; Optically Clear Silicone Liquid Encapsulant and Casting Compounds

Product Chemistry Key Benefit Mix Ratio (w/w) Mixed Viscosity at 25°C (cP) Hardness Glass Transition Temperature CTE α1 / CTE α2 Refractive Index Optical Transmittance Temperature Resistance (°C) Baking Condition OLS- Dimethyl Silicone Very High Transmittance 100:100 3 Shore D - -/270 1.41 >99  Up to 170 1 h at 80°C  and 3 hrs at 150°C OLS- Phenyl Silicone Sulfur Resistant 100:500 35 Shore D 13 105/153 1.54 >95  Up to150 1 h at 80°C  and 4 hrs at 150°C OLS- Silicone High Power Applications 1:10 - 40-46 Shore D 30   1.48-1.50 >95 - 100&#;200 s at  110&#;130 °C and 2 hrs at 150 °C OLS-M Silicone Balance Formulation 100:400 42 Shore D - - 1.53 >95 -  5 mins at 125 °C and 3 hrs at 150 °C OLS- Silicone High Reliability 1:10 65 Shore D 42     >95 - 1 h at 80 °C and 4 h at 150 °C PM- Silicone  High Elasticity 100:100 50 Shore A - - 1.41 >95 - 1 h at 80 °C and 3 h at 150 °C PM- Silicone High Power Applications 1:10 110 49 shore A - - 1.41 >95 - 1 h at 60-80 °C and 3 h at 150 °C Top of Page

 

Optolinq&#; Optically Clear Liquid Encapsulant and Casting Compounds

Property Unit Product Names Optolinq&#;
OLS- Optolinq&#;
OLS- Optolinq&#;
OLS- Optolinq&#;
OLS- Optolinq&#;
OLS- Top of Page

Optically clear liquid encapsulants and casting materials
Manufactured, sold and serviced by Caplinq Corporation

Chemistry Type N/A Epoxy Epoxy Silicone Silicone Hybrid Key Benefits of Chemistry Type N/A Low cost Anti-blue decay Temp up to 170°C Max temp 150°C Price/Performance balance Mix ratio : 100:100 100:100 100:100 100:500 One part Hardness (Shore D) N/A 88 85 3 35 88 Glass Transition Temperature, Tg °C 130 127 - 13 152 CTE Alpha 1 ppm/°C 60 - - 105 69 CTE Alpha 2 ppm/°C 183 - 272 153 171 Refractive Index N/A 1.52 1.52 1.41 1.54 1.52 Optical Transmittance
Initial, @ 460nm
%

>90% >99% >99% >95% >92% Sulphur Resistance - &#;&#;&#;&#; &#;&#;&#;&#; &#;&#;&#;&#; &#;&#;&#;&#; &#;&#;&#;&#; Relative Cost - $ $ $$$$ $$$ $$ Applications best suited for Low-Power LED Encapsulation, Tj < 80°C N/A &#;&#;&#;&#; &#;&#;&#;&#; &#;&#;&#;&#; &#;&#;&#;&#; &#;&#;&#;&#; Mid-Power LED Encapsulation 80°C < Tj < 115°C N/A &#;&#;&#;&#; &#;&#;&#;&#; &#;&#;&#;&#; &#;&#;&#;&#; &#;&#;&#;&#; High-Power LED Encapsulation Tj < 150°C N/A &#;&#;&#;&#; &#;&#;&#;&#; &#;&#;&#;&#; &#;&#;&#;&#; &#;&#;&#;&#;

 

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   What is Potting and Casting?

Casting and Potting can be used to encapsulate sensitive electronics as well as opto-electronic devices. In the case of LEDs they can be both cast or potted.

In the casting process, liquid resin is poured into the LED chamber and cured into the shape of the cavity. This produces a stand-alone device which can then become a component in another printed circuit board assembly.

In the potting process, LEDs are already wired and connected to a circuit board or substrate. The circuit board or substrate usually already has a frame or cavity which is then filled with a liquid resin and then cured. This results in a group of LEDs set in a ready-to-go circuit board or substrate.

CAPLINQ offers a range of Encapsulants, Potting Materials and Casting Materials

CAPLINQ OPTOLINQ&#; OLS-Series are a family of optically clear (often called &#;water-white&#;) liquid encapsulants that are used to encapsulate optical or optoelectronic devices that require both a high level of light transmittance as well as a good level of mechanical protection. Products in this OLS-Series family can be epoxies, silicones or hybrid technologies. They are used extensively for the encapsulation of LED devices but could be well suited for other applications that require a clear, optical grade encapsulation system.

 

 

   Liquid Resins For Potting

There are three main types of liquid resin for potting and casting applications: Epoxy, Polyurethane, and Silicone.

Resin encapsulants are used to protect and insulate electronic components from harsh environments, including moisture, thermal shock, physical vibration and shock, chemicals and dust, etc, which help electronics achieve stable performance in long term. Potting resin encapsulants are widely applied due to their usage flexibility and easy automation.

In order to meet different application needs, the properties of resin encapsulants could be adjusted. There are mainly three types of resin chemistry systems being widely applied as liquid encapsulants. The comparison between the key performance considerations is shown in the table below. Some other considerations are not mentioned here, such as flame retardancy, volatility, dielectric resistance, etc.

PROPERTIES / RESIN TYPES EPOXY POLY-URETHANE SILICONE Glass Transition Temperature High Medium/Low Very Low Hardness (Shore) High Shore D Shore A to Shore D Low Shore A Heat Resistance Tj Up To 160 ~ 180 °C Tj Up To 135 °C Tj Up To 230 ~ 260 °C Flexibility Brittle Flexible, Crack Resist Very Flexible Mechanical Strength High Medium Very Low Chemical Resistance Excellent Good Poor Adhesion Excellent Good Poor Material Cost Medium Low High Reworkability Very Hard Hard Easy Stress & Heat During Curing High Medium Very Low Suitable For

• High rigid casting
• Against harsh humidty/chemical environment
• Not suitable for sensitive parts

• Stress-sensitive parts
• PCB with surface mount components
• Water resistant for marine application
• Flexible from soft gel to semi-rigid casting

• Fragile electronic components/module
• PCB with surface mount components

*Reworkability: Epoxy and urethane are hard materials, providing good mechanical strength and protection for electronics. Besides, their strong adhesion to components makes them very hard to remove and rework.

*Stress & Heat During Curing: Epoxy and urethane materials produce heat while curing and create stress from shrinkage. Both the heat and stress generated could cause damage to sensitive components and wire connections.

 

   Liquid Potting Resins Key Considerations

After deciding the basic chemistry of potting materials for your applications, there are some other features to be considered while selecting. 

Hardness It is a key consideration for selecting materials. Depending on your applications and purpose of encapsulating, you need different levels of hardness. Hard materials provide better mechanical protection against the environment. Soft materials absorb vibrations well and make the component easy to repair and rework.

Thermal Conductivity The components being encapsulated may generate different levels of heat in the area, especially high power electronics. Potting materials could help to dissipate heat to ensure long-term reliability of electronics. The thermal conductive value could be adjusted by adding various fillers.

Color & Viscosity Depending on the visibility requirement of your application, you may need transparent, dark opaque, or even specific colors; Generally speaking, potting materials are designed to have low viscosity (<10 Pa.s) to ensure flowability and self-leveling for easy usage. Medium and high viscosity (>100 Pa.s) products are suitable for sealing and adhesion.

If you are looking for more details, kindly visit HumenChem.

Curing Process Besides the above-mentioned properties, you may consider the curing conditions like temperature and time which suit your production and also the components. Pot life and application process also.

Potting Material Application Questions 

• What kind of device/component will be potted? What is the volume of the cavity or pot being filled?
• What will the operating environment be like? Temperature range?
• Will there be exposure to moisture? Solvents or other chemicals? Vibration?
• What is the acceptable curing time or gel time? What is the curing mechanism? UV? Room temperature? Oven?
• What is the coefficient of thermal expansion (CTE) of the potting compound?
• Will the material need to be flame-retardant?
• What is the desired hardness of the cured compound?

Epoxy resins

Epoxy resin is super adhesive: making seamless uniform bonds to a wide variety of substrates and cures to become hard with high elastic modulus, great mechanical strength, and toughness. It also has absolutely unparalleled high-temperature resistance, chemical resistance, and electrical insulation. Epoxy resin cures relatively slowly especially in smaller volumes, and so may require fast-cure hardeners that generate an exothermic reaction that may damage sensitive electrical components via mechanical stress on both the components and circuit. 

Polyurethane resins

Polyurethane resins are the kings of process adaptability. Almost every single characteristic of the final cured resin can be dialed in and regulated by adding a little more or a little of a certain additive. Hardness, cure speed, color, gel time, viscosity, all of these can be easily adjusted to suit production requirements. Polyurethanes cure faster and at lower temperatures than epoxy. Polyurethanes have a low elastic modulus in their cured state they are better for extra delicate components such as sensors and reed switches. However, they are notorious for high moisture absorption unless a Polybutadiene base is used.

Silicone resins

Silicone resins have the lowest elastic modulus when cured of all liquid resins. They have great high-temperature and chemical resistance too. Silicone resins also cure with almost no exothermic heat making them great for encapsulating highly heat sensitive components. Silicone resins are great for insulating and covering larger areas than the other two resins, however, because their base chemistry is more expensive to produce they tend to be overall more expensive than the other two. The LED share of the lighting market is set to shift from 20% to 70% by , which means the overcoming years LED encapsulation will be one of the fastest growing markets for liquid encapsulation. Liquid casting and encapsulation, in general, is more adaptive with high flexibility and low throughput which matches the market trends of more diverse low quantity orders rather than long-term high quantity orders. Liquid Epoxy resin used to the king of potting and encapsulation, however, epoxy seems to be running out of room for further developments and the most exciting developments in liquid resins seem to be in polyurethane resins. This is also because polyurethanes can be so easily adapted and so better suits the current economy of diverse smaller quantity orders.

Presentations

Clear and Optical Liquid Encapsulants

The presentation shown on the left is focused on explaining the different chemistry of liquid encapsulant...

Silicone-based Encapsulants 

The presentation shown on the right delves into the value of silcone in liquid encapsulation applications...

The Challenge

The demand for high-power micro-LED is growing exponentially, so it becomes more relevant to increase the demand for encapsulation materials. The micro-LEDs are used in devices to enhance their efficiency and provide high brightness, which comes with challenges like heat dissipation, outside protection, and transparent surface. High-power micro-LEDs have an advantage in automotive applications and general lighting owing to efficient working for extended operating hours and low maintenance costs.

For micro-LEDs, organic encapsulant materials used are acrylic resin, epoxy resin, and phenolic resin; and some of the inorganic encapsulant materials used are silicon nitride layer, silicon oxynitride layer, and silicon oxide layer. Moreover, the encapsulants provide thermal transfer and light emission, which align with the addressable need of mid- and high-power micro-LEDs. Thus, the micro-LED encapsulation market is expected to grow substantially during the forecast period.

Our Solution

Our research team proposed a five-step approach and employed a comprehensive strategy covering secondary research, patent, and scientific research to conduct the study, followed by primary research, to help the client understand technologies and competition and uncover promising opportunity areas.

Business Impact

We provided the client with actionable recommendations on a few types of materials used for the encapsulation of micro-LEDs and their effects:

&#; The client was able to understand the increase in demand and popularity of materials.

&#; The client gained clear insights into overall trends in the utilization of encapsulation materials for the use of different situations.

&#;The client was able to prioritize a few of the materials for their business. Epoxy resin, epoxy molding compounds, silica gel, organic silica gel, Silicone and silicone-based, polyurethane-based, acylate-based, phenyl-based, Internal filling of metal and ceramic materials, and other classes of materials.

&#;The client gained perspective on various solutions & approaches competitors are adopting to address the challenges associated with encapsulation materials of micro-LED.

&#; The client understood competitors&#; strategies for minimizing costs and achieving their goals.

&#;The client got insights on implemented success stories/use cases for a few solutions to establish confidence for collaboration opportunities with solution providers.

 

Contact us to discuss your requirements of High Refractive Index Encapsulation Materials For Led. Our experienced sales team can help you identify the options that best suit your needs.