Thermal - Heat Pipes, Vapor Chambers

Part Number	Description / PDF	Quantity
126644 Wakefield-Vette	FLATTENED, COPPER HEATPIPE, SINT	50
ATS-HP-F8L450S14W-443 Advanced Thermal Solutions, Inc.	FLAT HEATPIPE 14W 10.1X5X450MM	0
ATS-HP-F6L70S60W-251 Advanced Thermal Solutions, Inc.	FLAT HEATPIPE 60W 8.3X2.5X70MM	473
ATS-HP-F7L150S65W-017 Advanced Thermal Solutions, Inc.	FLAT HEATPIPE 65W 3.5X11.2X150MM	86
ATS-HP-F8L450S13W-371 Advanced Thermal Solutions, Inc.	FLAT HEATPIPE 13W 11.3X3X450MM	0
126765 Wakefield-Vette	FLATTENED, COPPER HEATPIPE, SINT	50
ATS-HP-F6L150S26W-241 Advanced Thermal Solutions, Inc.	FLAT HEATPIPE 26W 8.6X2X150MM	0
126468 Wakefield-Vette	FLATTENED, COPPER HEATPIPE, SINT	50
126579 Wakefield-Vette	FLATTENED, COPPER HEATPIPE, SINT	50
ATS-HP-D8L200S77W-148 Advanced Thermal Solutions, Inc.	ROUND HEATPIPE 78W 8X200MM	0
126554 Wakefield-Vette	FLATTENED, COPPER HEATPIPE, SINT	50
ATS-HP-F5L200S20W-234 Advanced Thermal Solutions, Inc.	FLAT HEATPIPE 20W 5.9X4X200MM	0
ATS-HP-F6L100S47W-308 Advanced Thermal Solutions, Inc.	FLAT HEATPIPE 47W 7.5X4X100MM	0
126694 Wakefield-Vette	FLATTENED, COPPER HEATPIPE, SINT	50
126588 Wakefield-Vette	FLATTENED, COPPER HEATPIPE, SINT	50
126088 Wakefield-Vette	FLATTENED, COPPER HEATPIPE, SINT	50
126030 Wakefield-Vette	FLATTENED, COPPER HEATPIPE, SINT	50
126599 Wakefield-Vette	FLATTENED, COPPER HEATPIPE, SINT	50
126191 Wakefield-Vette	FLATTENED, COPPER HEATPIPE, SINT	50
ATS-HP-F8L150S42W-419 Advanced Thermal Solutions, Inc.	FLAT HEATPIPE 42W 10.4X4.5X150MM	0

Thermal - Heat Pipes, Vapor Chambers

1. Overview

Heat pipes and vapor chambers are passive two-phase heat transfer devices that utilize phase change cycles (evaporation-condensation) to efficiently redistribute thermal energy. These technologies play critical roles in modern electronics, aerospace, and energy systems by maintaining optimal operating temperatures for high-performance components.

2. Major Types & Functional Classification

Type	Functional Features	Application Examples
Sintered Wick Heat Pipe	High thermal conductivity (5-10x copper), anti-gravity operation	CPU/GPU cooling in servers
Gravity-Assisted Heat Pipe	Lower cost, requires vertical orientation	Air-cooled heat sinks for consumer electronics
Variable Conductance Heat Pipe (VCHP)	Temperature-controlled operation via non-condensable gas	Aerospace thermal regulation systems
Copper-Water Vapor Chamber	Ultra-thin design ( 3mm), planar heat spreading	Smartphone SoC cooling
Stainless Steel-Amonia VC	High reliability for extreme environments	Satellite thermal control

3. Structure & Composition

Heat pipes typically consist of: 1) Inner wick structure (sintered powder, grooved, or mesh), 2) Working fluid (water, ammonia, or methanol), 3) Sealed container (copper, aluminum). Vapor chambers have similar components but feature: 1) Flat sealed enclosure with internal support pillars, 2) Multi-directional vapor flow channels, 3) Advanced micro-structured wick layers.

4. Key Technical Specifications

Parameter	Importance	Typical Values
Effective Thermal Conductivity	Determines heat transport capacity	10,000-50,000 W/m K
Operating Temperature Range	Defines environmental compatibility	-50 C to 300 C
Maximum Heat Transport Capacity	Design limit for thermal load	50-500 W
Pressure Resistance	Structural integrity under stress	1-5 MPa
Response Time	Speed of thermal equilibrium	10-100 ms

5. Application Fields

Consumer electronics: Smartphone processors, gaming consoles
Data centers: Server rack cooling systems
Renewable energy: Solar inverters, energy storage systems
Automotive: EV battery pack thermal management
Industrial: High-power laser modules, semiconductor manufacturing equipment

6. Leading Manufacturers & Products

Manufacturer	Representative Product	Key Features
Cooler Master	Hyper Heat Pipe Series	Nano-fiber wick structure, 120W capacity
Thermacore	TS Heat Pipe	Space-qualified VCHP design
Aavid (TE Connectivity)	Vapor Chamber 3.0	0.8mm thickness for mobile devices
Calsonic Kansei	AeroChamber VC	For automotive LiDAR systems

7. Selection Guidelines

Key considerations include: 1) Thermal load requirements, 2) Available space constraints, 3) Operating environment conditions (temperature/vibration), 4) Interface compatibility (Cp vs. Al), 5) Cost-performance trade-offs. For high-reliability applications, materials selection and accelerated life testing become critical factors.

8. Industry Trends

The market is evolving towards micro-scale integration (e.g., 0.4mm diameter heat pipes), advanced nanofluid working media, and hybrid systems combining heat pipes with liquid cooling. Emerging applications in 5G infrastructure and autonomous vehicle systems are driving demand for ultra-thin vapor chambers with 3D printing-formed wick structures. Market growth is projected at 12.8% CAGR through 2030, with significant R&D investments in space thermal control and data center liquid-assisted solutions.