High Purity Copper Vc Heat Spreader

Product Introduction

Exceptional thermal conductivity for efficient heat dissipation.
High purity copper ensures long-lasting durability and performance.
Optimized for use in high-performance electronics and computing.
Compact design suitable for space-constrained applications.
Easy integration with existing cooling systems.
Enhances device reliability by preventing overheating.
Supports sustainable energy solutions with efficient cooling capabilities.
Customizable dimensions to fit various industrial needs.

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Products Details

Type	Broaching, Drilling, Etching / Chemical Machining, Laser Machining, Milling, Other Machining Services
Material Capabilities	Brass, Aluminum, Copper, Stainless Steel, Steel Alloys
CNC Machining or Not	CNC Machining
Micro Machining or Not	Not Micro Machining
Material Purity	High-purity copper ≥99.9%, optional copper alloys (Cu-Ni, Cu-Sn)
CNC Machining Tolerance	±0.005mm precision, multi - axis milling for complex channel designs
Surface Finish Options	Polishing, nickel plating, anodizing; Ra 0.8-1.6μm for heat transfer
Thermal Conductivity	≥401W/(m K) , optimized by internal micro-channel structures
Application Compatibility	High-end GPU, server CPU, 5G base stations, industrial power module
Customization Flexibility	CAD - driven design, micro - channels/grooves added via precision CNC
Pressure Resistance	Withstand up to 10 bar, suitable for liquid - cooled cooling systems
Thickness Customization	1mm - 20mm thickness range, ultra - thin (≥1mm) for compact devices
Certification Compliance	ISO-9001,ISO-14001,ISO-45001, ISO-IATF 16949
Lead Time for Samples	Sample: 5 - 7 days; Mass order: 2 - 3 weeks, rush service available
Selling Units	Single item
Package size per batch	8X7X3 cm
Gross weight per batch	0.800 kg

FAQ

1. What is a heat spreader?
A heat spreader is a device that distributes heat evenly across a surface to enhance cooling efficiency.

2. Why use high purity copper?
High purity copper offers superior thermal conductivity and durability for heat spreaders.

3. How does the heat spreader improve device performance?
It enhances device performance by efficiently dissipating heat to prevent overheating.

4. Can it be used in compact devices?
Yes, its compact design allows it to fit in space-constrained applications.

5. Is it compatible with existing systems?
Yes, it integrates easily with most existing cooling systems.

6. How does it support sustainability?
The heat spreader's efficient cooling capabilities contribute to energy-saving solutions.

7. Can the dimensions be customized?
Yes, dimensions can be tailored to suit various industrial requirements.

8. What industries benefit from this product?
Industries like electronics and computing benefit from improved heat management and device reliability.