Technology Applications, Inc provides 
Pyrolytic Graphite Links (PGL™), and Graphene Composite Thermal Links (GCL™).
While they offer high thermal performance, all forms of pyrolytic graphite/graphene sheet straps are far more fragile than metallic or graphite fiber straps, and not ideal for certain applications requiring large scale range of motion, flexibility on all axes, or operating temperatures <60K. As a result---just as is the case in any other thermal strap program--it is critical that customers provide a comprehensive list of their requirements and description of the operational environment, in order to ensure PGL™ or GCL™ is a workable solution.
Pictured (right): PGL™ built by TAI (November 2014).
What sets these straps apart from our GFTS® products, and other thermal straps in the industry? Simply put: they offer the highest thermal performance available in the market.
In place of our space-qualified GraFlex fiber bundles (GraFlex I & II), or our GraFlex III woven fiber sheet material, we utilize pyrolytic graphite sheets, or multilayered, high conductance graphene composite (97% graphene). These materials provide a material thermal conductance of 1,500 - 1,900 W/(m-K); though graphene composite may one day offer even higher thermal performance than the current 1,500 W/(m-K) available in the industry (as the technology improves). While both multilayered GCL™ and PGL™ offer extremely high thermal performance, our unique, proprietary PGS material provides nearly 2,000 W/(m-K), and offers superior thermal performance to any graphite fiber or graphene strap.
It should be noted that we do not provide single layer graphene straps, as there are no (actual) single layer graphene sheet thermal straps available in the world (just a multilayered composite). While single layer graphene sheet can achieve conductance in excess of 3,000 W/(m-K)---and could theoretically achieve well over 5,000 W/(m-K))---there is a catch: single layer sheets are only 0.35 nm thick. This makes single layer graphene entirely impractical--if not impossible--to use in a thermal strap application (as this would require stacking millions of sheets to make your typical strap). 
While these straps do not have years of space qualification and flight heritage (like our copper and graphite fiber thermal straps), they are a unique strap product, offering a particular set of benefits which may make them ideal in volume-restricted applications (such as electronics boxes).
Pictured (top): Graphene Thermal Link (GCL™) made with carbon composite end fittings (April 2017). Pictured (right): First generation PGL™ with inverted aluminum fittings (August 2013).
First and foremost: don't confuse "single layer graphene," with "multilayered graphene composite," or be deceived by claims regarding the durability of pyrolytic graphite and multilayered graphene composite sheets/films/foils. While (theoretically), graphene sheets should be extremely strong ("as strong as diamond," as material manufacturers often claim), the reality is that pyrolytic graphite and graphene is delicate, fragile, and susceptible to tearing. Not only can these straps be easily torn if flexed on the lateral axis, but repeated flexing or movement on ANY axis can cause localized creasing, damage, and eventual tearing of sheets (even after as little as 10 cycles; depending on length of strap, range of motion, and other factors). This limits carbon film/foil/sheet straps to niche applications requiring no load bearing, nor large range of motion requirements.
As a result, mishandling during shipping/receiving, testing, and installation (let alone the typical vibration and shock profiles straps are subject to during qualification and launch), can catastrophically damage non-woven, carbon-based sheet straps--rendering them unusable.
This is not to dissuade you from using PGL™/GCL™ (in certain situations); as TAI began designing and manufacturing PGL™ products in 2013 (and released our GCL™ products in early 2017).
Pictured (right): Preparing a PGL™ thermal conductance test (August 2013).
Like all strap options, PGL™ and GCL™ assemblies have their benefits and drawbacks. If your application requires:
• Operation at cryogenic temperatures...Then a copper rope/cabling strap is your best option. If these issues do not factor in to your application, then mass-sensitive customers may realize significant benefits from a graphite or graphene (non-woven) film/sheet/foil strap.
The chart below provides a simplified comparison of the various graphite and graphene strap configuration options available to customers. Please note: while graphene and pyrolytic graphite sheets/films/foils may have up to 2x the material thermal conductance of graphite fiber configurations, actual measured/realized thermal performance with these materials (due to resistance losses, the assembly process, and material properties), results in an improvement of just 20-40% higher thermal performance than GFTS® products.
| GraFlex I and II | GraFlex III Sheet | Graphene Sheet | Pyrolytic Graphite Sheet | |
| Material Thermal Conductance >200K) | 800 - 1000 W/(m-K) | 800 - 1000 W/(m-K) |
1,500 W/(m-K) |
1,500 - 1,900 W/(m-K) (Material Dependent) |
| Durability | Highly Durable | Highly Durable | Extremely Fragile - Repeated bending/flexing causes localized weakening, creasing, and eventual tearing of sheets | Extremely Fragile - Repeated bending/flexing causes localized weakening, creasing, and eventual tearing of sheets |
| Flexibility | Moderaltely Flexible. Configuration Dependent. | Highly Flexible | HIghly Flexible on X & Z axes. NOT on Lateral (Y) axis | HIghly Flexible on X & Z axes NOT on compression/X axis |
| Range of Motion | Moderate (Configuration Dependent). Can Be Limited on Compression (X) Axis in Certain Designs | Largest Range of Motion (on all Axes) | Large Range of Motion on Compression and Vertical (X and Z) Axes. Movement on Lateral (Y) Axis Will Tear Sheets. | Large Range of Motion on Compression and Vertical (X and Z) Axes. Movement on Lateral (Y) Axis Will Tear Sheets. |
| Space Flight Heritage | YES | COMING 2018 | NO | NO |
| Cost | Similar to Metallic Foil Straps. Less Than Any Competing Carbon Strap | Similar to Metallic Foil Straps. Less Than Any Competing Carbon Strap | More Expensive Than GFTS™ or Any Metallic Straps | More Expensive Than GFTS™, or Any Metallic Straps, Cheaper Than Graphene Straps |