[CES 2026 Deep Dive] From Fingertips to the Stars: Lens Technology Debuts Aerospace-Grade UTG, Reshaping the LEO Satellite “Energy Canopy”
Media OutReach Newswire 
There are no flashy RGB lighting effects here, only a sheet of glass as thin as a cicada’s wing, being repeatedly rolled and unrolled like a tape measure. This is the public debut of Lens Technology’s aerospace-grade UTG (Ultra-Thin Glass) photovoltaic encapsulation solution. This technology marks the official entry of the manufacturing titan—best known as a giant in the Apple supply chain—transferring its precision manufacturing capabilities from consumer electronics to humanity’s next trillion-dollar market: space infrastructure.
As leading global satellite companies begin the mass deployment of third-generation (V3) satellites, the Low Earth Orbit (LEO) internet race is entering a “second half” defined by heavy payloads, long lifespans, and low costs. Lens Technology’s entry aims to untie the knot that has long plagued the aerospace industry: the trade-off between flexibility and durability.
Farewell to the “Plastic Feel”: The Material Battle in Space
At the Lens Technology booth, engineers demonstrated the core contradiction to the audience: Traditional aerospace solar cell covers are either heavy Cerium-doped Glass (CMG) or expensive Fused Silica, typically ranging from 100μm to 500μm in thickness. They are robust, but too heavy and impossible to bend.
To adapt to the massive power demands of next-generation satellites (such as those supporting direct-to-cell services), solar wing designs are rapidly evolving from rigid panels to Roll-Out Solar Arrays (ROSA-like structures). This shift forced designers to temporarily turn to polymer materials like transparent Polyimide (CPI).
“However, polymers have a fatal weakness in space,” explained a Lens Technology on-site technical lead. “The LEO environment is filled with high-energy Atomic Oxygen (AO) and strong UV radiation. Under long-term exposure, polymer molecular chains break, causing the material to yellow, become brittle, and suffer a drastic drop in light transmission. This efficiency decay was tolerable for early satellites with 5-7 year lifespans, but for the new generation of mega-constellations pursuing higher commercial returns, it is unacceptable.”
Lens Technology’s answer is Aerospace-Grade UTG. As an inorganic material, glass possesses innate “immunity” to Atomic Oxygen and UV aging, ensuring high light transmission throughout the satellite’s lifecycle. More importantly, its dense structure provides an effective barrier against water vapor and micrometeoroids, offering physical protection for delicate ultra-thin HJT or future Perovskite batteries.
The 30-Micron “Moat”: A Perfect Match for Next-Gen Satellites
In the demo area, a piece of glass only 30μm-50μm thick is bent to an astonishing radius of R1.5mm. This level of flexibility drew gasps from the audience.
This is exactly the characteristic most coveted by top global satellite companies today. To reduce the cost per launch, next-generation mega-satellites must be stowed with origami-like efficiency inside the rocket fairing. Lens Technology’s UTG solution allows solar wings to be tightly wound like a tape measure during launch, and instantly recover to a flat state upon orbital deployment.
However, making glass thin is the first step; keeping it from shattering during the violent vibration of a rocket launch is the real challenge.
Analysts point out that Lens Technology’s core competitiveness lies in its proprietary chemical strengthening processes and laser/diamond wire cutting technologies. Glass fractures often originate from micro-cracks invisible to the naked eye. Leveraging processes honed on foldable smartphones, Lens has significantly reduced the density of micro-defects on the glass edges and surfaces. This means that even under immense tension and vibration, this “glass skin” remains tough and resilient.
Dimensional Strike: Reshaping Aerospace Costs with “Consumer-Grade” Capacity
If technical specifications are the ticket to entry, then capacity and cost control are Lens Technology’s ultimate weapons.
“The logic of commercial space has changed; it is now the era of industrial mass production,” commented an industry analyst at the scene. Compared to the small-batch, lab-grade customization model of traditional aerospace glass manufacturers, Lens Technology brings the scale of consumer electronics manufacturing.
Facing the grand ambition of global satellite leaders planning to launch tens of thousands of satellites annually, supply chain elasticity is critical. Lens Technology stated that it has the capability to rapidly expand existing pilot lines or flexibly retrofit mass production lines. This potential for “ten-thousand-satellite scale” delivery and yield control can significantly lower the BOM (Bill of Materials) cost per satellite—addressing the most sensitive pain point for commercial space giants today.
Outlook: The New Cornerstone of Next-Gen Space Energy
At CES, Lens Technology also “spoiled” its future technology roadmap.
As Perovskite/Silicon tandem cells are viewed as the mainstream for future satellite power, UTG will serve not just as a cover, but as an encapsulation substrate. Lens Technology revealed it is developing next-generation composite UTG integrated with Anti-Static (ESD) coatings and Selective Radiation coatings, which will not only protect chips from electrostatic discharge damage but also assist in regulating battery temperature.
Although this business currently accounts for a tiny fraction of Lens Technology’s massive revenue and is in a period of intensive validation with global top-tier photovoltaic component manufacturers (Tier 2) and top commercial space clients (Tier 1), its signal significance cannot be ignored.
From smartphone screens to satellite wings, Lens Technology is proving that in the era of scaled expansion for space infrastructure, ground-based industrial giants possessing extreme craftsmanship and mass manufacturing capabilities will be indispensable “pavers” for the interstellar journey.
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