Heat Sinks

Results: 5
Attachment Method
AdhesiveBolt On
Length
12.000" (304.80mm)36.000" (914.40mm)
Width
5.860" (148.84mm)6.500" (165.10mm)6.800" (172.72mm)6.960" (176.78mm)
Fin Height
2.000" (50.80mm)2.190" (55.63mm)2.790" (70.87mm)
Thermal Resistance @ Natural
0.20°C/W0.23°C/W0.28°C/W0.35°C/W
Stocking Options
Environmental Options
Media
Marketplace Product
5Results
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Mfr Part #
Quantity Available
Price
Series
Package
Product Status
Type
Package Cooled
Attachment Method
Shape
Length
Width
Diameter
Fin Height
Power Dissipation @ Temperature Rise
Thermal Resistance @ Forced Air Flow
Thermal Resistance @ Natural
Material
Material Finish
125643
125643
6.961WX36" EXTRUSIO 13694 XX6274
Wakefield-Vette
47
In Stock
1 : ¥1,524.83000
Box
-
Box
Active
Top Mount, Extrusion
-
Adhesive
Rectangular, Fins
36.000" (914.40mm)
6.960" (176.78mm)
-
2.790" (70.87mm)
-
-
0.20°C/W
Aluminum
-
127766
127720
6.50" X 12" FLATBACK HEATSINK 16
Wakefield-Vette
26
In Stock
1 : ¥527.38000
Box
-
Box
Active
Top Mount, Extrusion
-
Adhesive
Rectangular, Fins
12.000" (304.80mm)
6.500" (165.10mm)
-
2.190" (55.63mm)
-
-
0.35°C/W
Aluminum
-
127761
127761
5.86" X 36" FLATBACK HEATSINK 14
Wakefield-Vette
30
In Stock
1 : ¥577.79000
Box
-
Box
Active
Top Mount, Extrusion
-
Adhesive
Rectangular, Fins
36.000" (914.40mm)
5.860" (148.84mm)
-
2.000" (50.80mm)
-
-
0.28°C/W
Aluminum
-
127736
127736
6.8" WIDE X 12" FLATBACK W/ MOUN
Wakefield-Vette
33
In Stock
1 : ¥361.14000
Box
-
Box
Active
Top Mount, Extrusion
-
Bolt On
Rectangular, Fins
12.000" (304.80mm)
6.800" (172.72mm)
-
2.000" (50.80mm)
-
-
0.23°C/W
Aluminum
-
127794
127794
6.8" WIDE X 36" FLATBACK W/ MOUN
Wakefield-Vette
12
In Stock
1 : ¥881.04000
Box
-
Box
Active
Top Mount, Extrusion
-
Bolt On
Rectangular, Fins
36.000" (914.40mm)
6.800" (172.72mm)
-
2.000" (50.80mm)
-
-
0.23°C/W
Aluminum
-
Showing
of 5

Heat Sinks

Passive heat exchangers that transfer the heat generated by an electronic component to a fluid medium, often air or a liquid coolant, dissipating it away from the device to maintain an optimal operating temperature. They are designed to maximize the surface area in contact with the medium surrounding it. They are usually made out of copper or aluminum due to their high thermal conductivity.