Search Results for Water cooling

Fig. 5.1 Simple water-cooling system designed to control temperature with minimum water throughput. From F. W. Curtis, High Frequency Induction Heating , McGraw-Hill, New York, 1950 ( Ref 1 ) More

Fig. 7.34 Water cooling schedule planning More

Fig. 4.8 Axial powder-feed adapter with water cooling. Courtesy of Impact Innovations GmbH More

Fig. 15 Sectional views of conventional (non-water-cooled) and water-cooled cupolas. The conventional type shown is refractory lined. Water-cooled types incorporate either an enclosed jacket or an open cascade flow. Source: Ref 5 More

Fig. 8.20 Water-cooled flux “robbers” inserted between adjacent coils in a multizone camshaft-hardening machine Source: American Induction Heating Corp. More

Fig. 8.21 Typical construction of a water-cooled flux robber More

Fig. 8.67 Water-cooled flexible coaxial cable used in radio-frequency induction heating to connect the inductor to the power supply Source: L. C. Miller Co. More

Fig. 3.6 Typical water-cooled capacitors used to tune low- to medium-frequency induction heating circuits. From P. H. Brace, Induction Heating Circuits and Frequency Generation, in Induction Heating , ASM, Metals Park, OH, 1946, p 36 ( Ref 1 ) More

Fig. 4.15 Fully enclosed, horizontal motor-generator set that is water cooled Source: Westinghouse Electric Corp. More

Fig. 6.4 Crucible-free atomization in plasma-torch-heated water-cooled copper crucible. Courtesy of Impact Innovations GmbH More

Fig. 12 A cross section of a channel-type induction furnace showing the water-cooled copper induction coil that is located inside of a 360° loop formed by the throat and channel portion of the molten metal vessel. It is the channel portion of the loop that serves as the secondary More

Fig. 13 A cross section of a coreless-type induction furnace showing water-cooled copper induction coil and key structural components. The entire molten metal bath (which serves as the secondary) is surrounded by the coil (the primary) that encircles the working lining. Source: Ref 5 More

FIG. 13.5 Twin roll casting uses two copper water-cooled, counter-rotating rolls. The Castrip process produces a thin strip that requires minimal rolling to achieve finished size. Source: www.castrip.com . More

Fig. 6.3 Relation of surface cooling power of water with moderate agitation and water temperature. Source: Ref 3 More

Fig. 7.3 Midplane cooling rates for varying water quench temperatures and aluminum alloy casting thicknesses More

Fig. 7.33 Mold cooling water system schematic More

Fig. 11 Relationship between the surface cooling power of water with mild agitation and water temperature More

Fig. 18 Cooling time-temperature curves for water, petroleum oil, and an aqueous polymer (polyalkylene glycol, or PAG) quenchant superimposed on the continuous cooling transformation (CCT) curve for AISI 1045 steel More

Fig. 5 Cooling rates in air, water, or oil at the center of (a) bar as a function of diameter and (b) plates as a function of thickness. Source: Ref 5 More

Fig. 2 Real-time monitoring of chemical injection in a cooling-water system with online corrosion rate and pitting tendencies (localization index). October 10—Chemical treatment program transition: Inhibitor was turned off, acid addition was stopped, blowdown was increased, and dispersant More