Boron Nitride : Electronic Applications Requiring More Than Heat Dissipation:

Thermal management has always been a major concern in the design of high frequency, high power electronic devices. For example, historically, in many power amplifier designs, the vast majority of the power that needs to be dissipated is from the high power field effect transistors, or FET's, themselves. In these cases, the high power dissipation often requires direct attachment of the FET's to a heat sink of some type. Heat sinks have become almost essential to modern central processing units and other electronic devices.

Ideally, heat sinks are made from a good thermal conductor such as silver, gold, copper or aluminum alloy. Copper and aluminum are among the most frequently used materials for this purpose with electronic devices. In addition, recently, synthetic diamond cooling sinks have been developed to provide better cooling. Further, some heat sinks are constructed of more than one material with desirable features, such as phase change materials. Such materials can store a great deal of energy due to their heat of fusion. However, while many of these materials provide heat sink features, they do not address other needs of the device, such as electrical insulation. This article will highlight those needs and how new materials deal with those requirements.

Applications Overview

Before discussing new developments in materials for thermal management, an overview of electronics applications and thermal management will be given. Currently, there are four general categories of electronic applications that require thermal management such as provided by heat sinks and other approaches. They can be broadly classified as (1) medical electronics (2) consumer electronics (3) automotive electronics and (4) aerospace and defense electronics. Each of these categories has unique requirements in terms of thermal management. A brief discussion of those various needs will now be presented.

In the area of medical electronics, from imaging equipment to surgical instruments and automated immunoassays, more power means more heat, generally in a small space. Further, as greater demands for precision and reliability are placed on medical equipment, thermal control becomes more critical. To address that concern, medical equipment designers are using passive thermal control systems that include heat pipes and vapor chambers. Such devices offer high reliability, design flexibility, manageable cost, and quiet operation.

The consumer electronics field is being driven by the need for smaller, faster and lighter products. That need has put considerable demands on the thermal management of microelectronics. This area offers potential opportunities for materials-enabled innovation. Materials for electronics such as tablets and smart phones are moving to encompass the entire body of the smart phone or tablet, making heat dissipation more effective. This will likely push the boundaries in new materials where aesthetics such as color and texture will become important features for adoption. Thermally conductive polymers are seeing an increase in this segment of the market.

Electronics in automobiles has become more and more sophisticated and power consumption only seems to increase. In recent years, the proliferation of electronic hybrid cars has created new cooling problems with electronics that control large amounts of current. For example, in automobiles like the Toyota Prius, cooling of the battery pack is necessary to keep the temperatures of all of the modules as uniform as possible. This maximizes the performance and the life of the battery. Unique materials solutions may offer opportunities to address these issues.

Aircraft thermal management is becoming increasingly important to the safe design and operation of commercial and military aircraft due to the growing heat loads from expanded avionic functionality, more electrical systems architectures, and the greater temperature sensitivity of composite material systems compared to traditional metallic designs. Military aircraft designers face the additional challenges of removing the waste heat from advanced weapon systems. Examples of components that are sensitive to thermal fluctuations are heat shields, anti-icing systems and propulsion systems. Presently, these needs are typically addressed through the use of air exchangers or some type of fan assembly.

Thus, of the four applications that have been discussed, the two areas for which new materials are of high priority are automobile and consumer electronics. Of these, consumer electronics appears to be the most needing of the new technologies. Attention will now be turned to current requirements and how those can be met by new materials.

Market Requirements

Until recently, metal-based systems have been the primary material solution of choice. Aluminum was primarily selected for various light-weight thermal management systems. However, these systems are becoming more expensive based on raw material price increases that have been observed over the past few years. In that regard, plastics offer suitable performance for many of the thermal management applications that are being developed.

In order to gain insight into developing needs, a recent SpecialChem survey asked respondents about material requirements for thermal management applications. The results of the survey were that thermal management goes beyond thermal conductivity alone. Specifically, electrical insulation and color freedom were valued as other features beyond thermal conductivity. In addition, the following percentage of the respondents voted for the various options:

Physical Properties Best In Class Well Balanced Cost Option Electrically Insulating Plastic Yes Yes No Color/Colorability White White Black Resin + Filler Compound Price ($/100 cc) 3,5 3 1 Tensile Strength (MPa) 100 65 65 Impact Strength (J/m) 80 35 35 % of votes 27% 49% 24% Table 1: Results of Survey on Thermal Management Materials (based on 77 feedbacks)

From these results, it can be seen that a well-balanced formulation is the choice of about one-half of the respondents. In this context, a well-balanced formulation is described as one that provides not only thermal conductivity but also other features such as color. It should be noted that the cost option gathered the lowest percentage in the survey.

Thermally Conductive Plastics

In order to address present needs, thermally conductive plastics are made through the incorporation of high thermal conductivity fillers into the thermoplastic polymer matrix. Examples of common conductive fillers that are used are graphite, expanded graphite and carbon fibers. But, the use of these materials results in the final composite material being black and electrically conductive. As already stated, this is undesirable for consumer electronics applications such as smartphones. On the other hand, boron nitride is a synthetic ceramic that is both an excellent conductor of heat and a dielectric material. Recently, Momentive Performance Materials has developed Boron Nitride fillers enabling composite to reach acceptable thermal and electrical properties.

There are other ceramic materials, such as alumina, aluminum nitride and silica that show similar characteristics but boron nitride has the highest thermal conductivity of any of these materials. Table 2 provides a comparison of some properties of boron nitride to other competing fillers.

Property BN Al2O3 AlN SiO2 Thermal Conductivity (W/m/K) 300 30 260 1.3 Dielectric Constant 2.28 3.98 3.26 2.20 Mohs hardness <2 >9 ~ 7 ~ 6.5 Table 2: Comparison of Boron Nitride to Other Fillers

As can be seen from this Table, boron nitride offers both very high thermal conductivity values as well as a low dielectric constant. In addition, due to its softness, it can be readily compounded into many polymers with limited wear on the processing equipment.

Momentive Performance Materials' New Grade of Boron Nitride

Momentive Performance Materials has recently developed a new grade of boron nitride, designated CFX 600, which provides enhanced thermal conductivity while at the same time providing electrical insulation in a wide variety of thermoplastic resins. It is a surface treated version of boron nitride that allows for the attainment of high thermal conductivity and improved physical properties at lower loading levels than are commonly used. Specifically, CFX 600 can provide up to 20% enhancement in thermal conductivity while potentially also providing improvements in mechanical properties compared to untreated boron nitride powder at the same loading level.

This is just one example of a material development for thermal management that is focused on the growing needs of applications like consumer electronics. Those needs are clearly pointing out the requirement for more than simply thermal conductivity. Instead, materials solutions are being sought that provide a balance of properties in the final composite material. As these developing applications continue to stress the need for faster electronics, it is expected that materials developments will need to continue to address those needs.

Source: Special4polymers

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Momentive Hot Pressed Boron Nitride Shapes

Hot-Pressed BN

Momentive Hot-pressed BN is compacted at temperatures up to 2000°C and pressures up to 14MPa. B2O3 is introduced to help form a dense, strong engineering material that is remarkably easy to machine.

Several grades of hot-pressed boron nitride are available which differ in the type and amount of binder present. Standard grades, such as Momentive Performance Materials’ grade HBN, have 2-5 per cent B2O3 which can hydrate when exposed to moisture or high humidity.

This can result in limited thermal shock resistance. Other grades have a calcium addition which combines with the B2O3 to form a higher melting point glass binder which is less hygroscopic and gives improved performance at high temperatures (up to 1200°C). There is a high purity grade HBC from which the B2O3 binder has been removed. The process yields a diffusion bonded ceramic that actually increases in strength with increasing temperature. This grade HBC is commonly used at temperatures over 2000°C.

In addition to sharing the performance characteristics of powdered hexagonal boron nitride from which it is made— chemically inert, high thermal shock resistance, high electrical resistance, high thermal conductivity, excellent corrosion resistance, low loss tangent and low dielectric constant—HPBN adds some strengths of its own. It is not wetted by most molten metals including aluminum, antimony, bismuth, cadmium, copper, germanium, indium, iron, silicon, steel and tin. It does not react with halide salts and many other chemicals. Because HPBN is relatively soft, it is easily machined. This is unusual among ceramics used in electronics applications and reduces the need for precision surfaces to maximize contact area.

Momentive Hot Pressed Boron Nitride Shapes

Applications for HPBN

The unique combination of thermal and electrical characteristics found in hot-pressed boron nitride, coupled with its machinability, have caught the attention of design engineers in a variety of industries. A sampling of today’s uses includes:

• As a boron source in p-type diffusion furnaces
• As a heat sink in transistor packages
• As a substrate
• As an interface and nozzle material for manufacture of amorphous alloys
• As a break ring in horizontal continuous casting of steel
• As a mold for casting carbon steel, low alloy steels and stainless steel
• As insulators and source holders for ion implant systems
• As insulators for vacuum furnaces
• As glass-forming tools and refractories
• As windows in aerospace re-entry vehicles
• As microwave windows for high frequency satellite applications
• As an ablative material for aerospace applications
• As plasma rings
• As electrical insulating spacers for tungsten resistance heaters
• As refractory wall liners and crucibles in a variety of hot metal applications 

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Momentive Boron Nitride LPC Grade Coatings (Alumina Binder) for Wagstaff Casting System

Momentive Boron Nitride LPC Grade Coatings for Wagstaff Casting Systems

• Yields non-wetting, lubricating surfaces
• Melts do not stick
• excellent release properties and easy removal of melt • contains "white  
   graphite"

Momentive LPC grade Boron-Nitride-Coating is suitable for coating thimbles, transition plates and the refractory lining of the distribution trough of WagstaffTM Casting Systems. The very good non- wetting property of Momentive LPC Boron-Nitride-Coating makes an easy and effective removing of remaining melts possible. It is a proven replacement for graphocote (both based on xylene and water) when applied on thimbles and transition plates. Used on the distribution trough it replaces coatings like terracote and those based on bone ash.

Momentive LPC Boron-Nitride-Coating is a water-based paste-like products and should be diluted with distilled water prior to use. Best performance of LPC Boron-Nitride Coatings achieved by applying thin coats of 50-100μm (2-4 mils).

Application to Thimbles
When a new table is put into service with new thimbles (usually made of fused silica) the inner surface is being coated at room temperature using a soft brush. A mixture of 1 part Momentive LPC and 2 parts water give best results. Coating should air dry before heating up table to casting temperature.

During casting breaks the is being tilted upward araund 90° . Now the remaining metal is easily removed because LPC is an effective release agent. Each casting break should be used to brush the inner surface of the thimbles when being hot by using a mixture of 1 part LPC and 2-3 parts water. It is important to apply thin coats because thick coats may crack during use and do not show any technical advantages.

Application to Transition Plates
Transition plates (usually of Ca-Silicate) may be coated by brushing using a mixture or 1 part LPC and 2-3 parts water. However, it is important not to coat the porous graphite die because this could interrupt gas flow.

Application on the Refractory Lining of the Distribution Trough
After a new refractory lining is installed and coated with the sealer, Momentive LPC Boron- Nitride-Coating is brushed onto the could surface using a mixture of 3 parts LPC and 4 partsof water. A whole table will be covered by about 750g of ready to use mixture. 
During each casting break LPC Boron-Nitride-Coating can be applied on hot surface after removing aluminium by using a spray gun. Best mixture will be 1 part LPC and 3-4 parts water. 

Remark: Caused by thermal stress the refractory lining of the distribution trough shrinks during use forming cracks of a width of 0.5-2mm. Because LPC Boron-Nitride-Coating is applied in thin coats those cracks will not be covered. Therefore, these cracks must be filled in time by using a suitable repair putty. Otherwise liquid aluminium will fill these cracks causing adherence to the lining.

Storage-Container Size
Momentive LPC Grade BN Coating must be protected against frost. A storage temperature of >5°C (>41°F) is recommended. The containers should be kept closed. 

Safety
EPC Boron-Nitride-Coating contains water and is free of solvents. According to data available to us LPC Boron-Nitride-Coating is a non-hazardous preparation. Material safety data sheet is available.

Technical Data
Colour      :  White
Boron Nitride Content : 25%
Binder         : Alumina    
Temperature : 850 DegC Degree in Air, 1850 DegreesC  under inert gas
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Boron Nitride Coatings - Guidelines for Addressing Common Issues

We are giving below some of the common issues that our customers have raised, their causes and probable solutions. Once these issues are addressed after that our customers are getting excellent performance from our Boron Nitride Coatings and Sprays.

Problem	Cause	Solution
Coating peels.	Coating is too thick.	Dilute coating so that the layer thickness does not exceed 100µm.
Coating does not adhere on the surface.	Bad surface conditions.	Clean and degrease surface, perhaps grit blasting, warm surface prior to application to 100-150°C.
Further layers do not stick on the first layer.	First coating is not yet completely dried.	Extend drying time, remove loose particles and coat again.
Exfoliation and cracking.	Coating is too thick.	Dilute coating in such way that thinner layers can be applied.
Cloudy, uneven application when spraying.	Coating is not stirred up, spray gun is led jerkily not homogenious.	Stirr coating or use mixer. Pull even courses with spray gun.

Though the above solutions cure 99% of the issues, but still if you are facing any other issue you can get in touch with us. 

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