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A heat dissipation tutorial for wearable computers

Digest of Papers. Second International Symposium on Wearable Computers (Cat. No.98EX215), 2002
Wearable computing brings computation much closer to the user for everyday tasks and may be worn during most of the day. However, with CPU and wireless network intensive applications, higher power microprocessors and radio links are necessary resulting in increased heat generation.
Thad Starner, Yael Maguire
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MR gradient coil heat dissipation

Magnetic Resonance in Medicine, 1995
AbstractThe temperature responses of five different gradient coil designs were modeled using simplified engineering equations and measured. The model predicts that the coil temperature approaches a maximum as an inverse exponential, where the maximum temperature is governed by two parameters: a local power density and a cooling term.
K C, Chu, B K, Rutt
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HEAT DISSIPATION OF PRIMARY AND SECONDARY BATTERIES

Unmanned Spacecraft Meeting 1965, 1965
Calorimetric data are given for the heat generated in a 30-Ah nickel-cadmium battery and a 360-Ah silver--zinc battery. Equations are also given to calculate the amount of heat generated. Heat dissipation in the silver(II) oxide region is about 20% less than in the silver(I) oxide region; also for silver--zinc cells, heat dissipation above 21 C ...
M. G. GANDEL, R. H. KINSEY
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The dissipation of frictional heat

Applied Scientific Research, 1955
The load-carrying or power-transmitting capacity of many machine parts is decisively affected by the maximum temperatures that occur in the source of frictional heat. In controlling these temperatures, and thus the performance limits concerned, two types of dissipation of frictional heat, which act in series, have to be accounted for: 1.
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Dissipation of Heat by Radiation

Transactions of the American Institute of Electrical Engineers, 1930
Heat dissipation is an ever-present factor affecting the design and operation of many kinds of electrical equipment. Usually, the problem is to get rid of heat due to losses. Sometimes the problem is how to conserve heat. Radiation, or convection, or conduction, or combinations of these, enter into all cases.
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Heat dissipation in graphene foams

Nano Research, 2020
Graphene foam (GF)—a three-dimensional network of hollow graphene branches—is a highly attractive material for diverse applications. However, to date, the heat dissipation characteristics of GFs have not been characterized. To fill this gap, we synthesized GF devices, subjected them to high temperatures, and investigated their thermal behavior by using
Yaniv Cohen   +2 more
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A Stochastic Heat Equation with Nonlinear Dissipation on the Boundary

Journal of Optimization Theory and Applications, 2014
zbMATH Open Web Interface contents unavailable due to conflicting licenses.
Viorel Barbu   +2 more
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Effects of Heat Dissipation Fin Shape on Heat Dissipation Performance of UCD Lamp

Transactions of the Korean Society of Mechanical Engineers - B, 2018
Dong Guk Ko, Min Soo Kim
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Experimental testing of the heating performance of a rotor-type dissipative liquid heater

International Journal of Energy and Environmental Engineering, 2020
Sergiĭ Bespalko   +2 more
exaly  

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