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Fin tubes are used wherever efficient cooling or heating is required. These kind of extended surface tubes are used for the production of shell and tube heat ex-changers, air-cooled heat ex-changers condensers and even convection coils used in furnaces.
Fins are basically external and extended surfaces located or inserted on outside of tubes and or pipes in order to increase the total surface area and thermal efficiency, resulting in compact heat transfer equipment.
The method of attaching the fins over the tube is very important, since any slightness, air gap between the tube and fins may create an additional resistance to heat flow. When the heat transfer coefficient on the outside of the tube is significantly lower than the heat transfer coefficient on the inside of the tube, there is a major advantage to incorporate fins on the outside tube surface to take full advantage of the high heat transfer rate on the inside of the tube.
If the fin and tube have different thermal coefficients of expansion, the bond may loosen due to a differential movement between them. The loosening effect will increase as the bond temperature increases and consideration must be given to the bond temperature which be attained should the fan fail. The bond may loosen due to the weakening effect of thermal and pressure cycling and also because of corrosion at the fin-base tube junction. Operating temperature limits for the various types of fin-tubes.
Finned tubes are used in applications involving the transfer of heat from a hot fluid to a colder fluid through a tube wall. The rate at which such heat transfer can occur depends on three factors: (1) the temperature difference between the two fluids; (2) the heat transfer coefficient between each of the fluids and the tube wall; and (3) the surface area to which each fluid is exposed. In the case of a bare (unfinned) tube, where the outside surface area is not significantly greater than the inside surface area, the fluid with the lowest heat transfer coefficient will dictate the overall heat transfer rate. When the heat transfer coefficient of the fluid inside the tube is several times larger than that of the fluid outside the tube (for example steam inside and oil outside), the overall heat transfer rate can be greatly improved by increasing the outside surface area of the tube. In mathematical terms, the product of heat transfer coefficient for the outside fluid multiplied by outside surface area is made to more closely match the product of the inside fluid heat transfer coefficient multiplied by tube inside surface area.
So the whole concept of finned tubes is to increase outside surface area. As an example, a common finned tube configuration of 2″ (nominal) pipe with 3/4″ high welded helical solid fins of 12 gauge thickness with 6 fins per inch has an outside surface area of 8.23 sq. ft. per linear foot; whereas the same bare pipe has an outside surface area of only 0.62 sq. ft. per linear foot. (See Design Info for extensive tables of surface areas and fin weights.)
The advantage of finned tubes is that by increasing overall heat transfer rate, the total number of tubes required for a given application is reduced, thereby also reducing overall equipment size and decreasing the cost of the project. In many application cases, one finned tube replaces six or more bare tubes at less than 1/3 the cost and 1/4 the volume.
Fin tubes are used wherever efficient cooling or heating is required. These kind of extended surface tubes are used for the production of shell and tube heat ex-changers, air-cooled heat ex-changers condensers and even convection coils used in furnaces.
Fins are basically external and extended surfaces located or inserted on outside of tubes and or pipes in order to increase the total surface area and thermal efficiency, resulting in compact heat transfer equipment.
The method of attaching the fins over the tube is very important, since any slightness, air gap between the tube and fins may create an additional resistance to heat flow. When the heat transfer coefficient on the outside of the tube is significantly lower than the heat transfer coefficient on the inside of the tube, there is a major advantage to incorporate fins on the outside tube surface to take full advantage of the high heat transfer rate on the inside of the tube.
If the fin and tube have different thermal coefficients of expansion, the bond may loosen due to a differential movement between them. The loosening effect will increase as the bond temperature increases and consideration must be given to the bond temperature which be attained should the fan fail. The bond may loosen due to the weakening effect of thermal and pressure cycling and also because of corrosion at the fin-base tube junction. Operating temperature limits for the various types of fin-tubes.
Finned tubes are used in applications involving the transfer of heat from a hot fluid to a colder fluid through a tube wall. The rate at which such heat transfer can occur depends on three factors: (1) the temperature difference between the two fluids; (2) the heat transfer coefficient between each of the fluids and the tube wall; and (3) the surface area to which each fluid is exposed. In the case of a bare (unfinned) tube, where the outside surface area is not significantly greater than the inside surface area, the fluid with the lowest heat transfer coefficient will dictate the overall heat transfer rate. When the heat transfer coefficient of the fluid inside the tube is several times larger than that of the fluid outside the tube (for example steam inside and oil outside), the overall heat transfer rate can be greatly improved by increasing the outside surface area of the tube. In mathematical terms, the product of heat transfer coefficient for the outside fluid multiplied by outside surface area is made to more closely match the product of the inside fluid heat transfer coefficient multiplied by tube inside surface area.
So the whole concept of finned tubes is to increase outside surface area. As an example, a common finned tube configuration of 2″ (nominal) pipe with 3/4″ high welded helical solid fins of 12 gauge thickness with 6 fins per inch has an outside surface area of 8.23 sq. ft. per linear foot; whereas the same bare pipe has an outside surface area of only 0.62 sq. ft. per linear foot. (See Design Info for extensive tables of surface areas and fin weights.)
The advantage of finned tubes is that by increasing overall heat transfer rate, the total number of tubes required for a given application is reduced, thereby also reducing overall equipment size and decreasing the cost of the project. In many application cases, one finned tube replaces six or more bare tubes at less than 1/3 the cost and 1/4 the volume.
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