• Company
  • About us
  • Locations
  • Exclusive Member Club
  • General Terms of Business
  • Copyright
  • Disclaimer
  • Imprint
• Where to buy
  • Retailer
  • Reseller
  • Distributor
  • Online-Shops
• Marketing
  • Press
  • Reviews & Awards
  • Sponsorship
    • Cheat report
  • Events
    • Lan Parties
    • Exhibitions
    • Other events
• Products
  • Power Supply Units
    • Classic Series
    • Professional Series
    • Advance Series
    • AdvancePlus Series EOL
    • Exxtreme Series
    • ITX-Series
  • Headphones
    • Professional Series
    • Advance Series
  • Speaker
• Support
  • RMA
    • Conditions
    • Form
  • Download Center
  • Technical Inquiry
  • RoHS
  • WEEE
  • DSD
• Technology
  • PSU Design Guides
  • Troubleshooting
  • Operating Temps
  • PSU Terminology
    • FAQ
    • [PDF] Installation PSU
    • [PDF] PFC
    • Lexikon
  • Reduce downtime
• Contact
  • General inquiry
  • Sales partner inquiry
  • Product review request
  • Lan party request
  • Testimonials
  • Dealer registration

Operating Temps

Operating Temperature vs System Reliability

At elevated temperatures a silicon device can fail catastrophically, but even if it doesn't, its electrical characteristics frequently undergo intermittent or permanent changes.

Manufacturers of processors and other computer components specify a maximum operating temperature for their products. Most devices are not certified to function properly beyond 50°C-80°C (122°F-176°F). However, in a loaded PC with standard cooling, operating temperatures can easily exceed the limits. The result can be memory errors, hard disk read-write errors, faulty video, and other problems not commonly recognized as heat related.

The life of an electronic device is directly related to its operating temperature. Each 10°C (18°F) temperature rise reduces component life by 50%*. Conversely, each 10°C (18°F) temperature reduction increases component life by 100%. Therefore, it is recommended that computer components be kept as cool as possible (within an acceptable noise level) for maximum reliability, longevity, and return on investment.

* Based on the Arrhenius equation, which says that time to failure is a function of e-Ea/kT where Ea = activation energy of the failure mechanism being accelerated, k = Boltzmann's constant, and T = absolute temperature.