Skiving is an advanced manufacturing process used to produce high-performance heatsinks by shaving thin layers of metal directly from a solid metal block. This process creates dense, thin fins with a large surface area, significantly improving heat dissipation efficiency.
Our skived heatsinks deliver excellent thermal performance, high reliability, and long-term durability, making them ideal for demanding thermal management applications across industries such as power electronics, telecommunications, automotive, renewable energy, aerospace, LED lighting, and industrial automation.
We use high-quality materials and precision manufacturing techniques to ensure every heatsink meets strict performance and reliability standards. Skived heatsinks are an excellent choice for applications requiring compact size, high thermal efficiency, and optimized airflow cooling performance.
A skived heatsink is manufactured from a single solid block of material—typically aluminum or copper—using a precision skiving process that forms thin fins directly from the base material.
Compared with traditional heatsink manufacturing methods such as bonded fins, stamped fins, or folded fins, skived heatsinks offer several advantages:
Higher fin density
Thinner fins
Lower thermal resistance
Improved heat transfer efficiency
No additional thermal interface resistance between fins and base
Because the fins and base are formed from one continuous piece of material, there is no need for soldering or bonding, eliminating the thermal resistance commonly associated with assembled fin structures.
This combination of:
high aspect ratio fins,
dense fin distribution,
and monolithic construction
provides excellent cooling performance, especially in forced-air and high-airflow applications.
Skived heatsinks are produced using a specialized skiving machine equipped with a precision cutting blade.
During the manufacturing process:
Thin layers of material are continuously sliced from the metal block.
The cut material is lifted upward to form fins.
Multiple passes create a dense fin structure with excellent thermal characteristics.
The skiving process allows the production of ultra-thin fins. Fin thicknesses as thin as 0.008” (0.2 mm) are achievable, enabling very high fin aspect ratios and significantly increased heat transfer surface area.
Copper is commonly used for skived heatsinks due to its superior thermal conductivity, although aluminum skiving is also widely available.
One advantage of the skiving process is its relatively low tooling cost and quick setup time, making it highly suitable for:
rapid prototyping,
custom heatsink development,
and low-to-medium production volumes.
Additional CNC machining operations can also be performed after skiving to create:
mounting holes,
cutouts,
stepped surfaces,
or custom assembly features.
However, these secondary operations require careful process control to avoid introducing mechanical stress into the fin structure.
Skived heatsinks can usually be identified by several characteristic features:
A curved transition area near the fin base where the skiving blade exits the material
Slightly curved fins rather than perfectly vertical fins
More noticeable fin curvature on taller fin structures
Typical skived heatsink widths are up to 200 mm, although widths up to 400 mm are achievable by rotating the material block and performing a secondary skiving pass in the opposite direction.
Since skived heatsinks are produced from long metal blocks, there is generally very little limitation on heatsink length other than the raw material size itself.
Different base heights and fin heights can also be achieved through additional machining processes.
The excess material removed during manufacturing is recyclable, helping reduce material waste and improve sustainability.
Typical surface treatments include:
Anodizing
Nickel plating
Typical surface treatments include:
Anti-oxidation coating
Nickel plating
These finishes improve corrosion resistance, oxidation protection, and long-term reliability.
In one application example, a copper skived heatsink was designed with two different fin heights to optimize airflow and thermal performance.
Some taller fins were selectively removed, and additional CNC machining features were incorporated to accommodate nearby assembly components.
The customer originally manufactured the heatsink entirely by CNC machining. After optimizing the design for the skiving process, the final solution achieved:
improved thermal performance,
reduced manufacturing cost,
and enhanced production efficiency.
This demonstrates how skived heatsink technology can provide both superior cooling capability and cost-effective manufacturing advantages for high-performance thermal applications.