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Heat exchanger schematic diagram

Figure 5. Return air heat exchange schematic diagram. Figure 5. Return air heat exchange schematic diagram.
A schematic diagram of a parallel-flow (cocurrent) heat exchanger is shown in Fig. 9.4. [Pg.690]

Figure 8.24. Left schematic diagram of an adiabatical three-bed, indirectly cooled reactor with two heat exchangers. Right a diagram showing the equilibrium curve to the upper right, the optimal operating line and the operation line for the reactor are to the left. [Adapted from C.J.H. Jacobsen, S. Dahl, A. Boisen, B.S. Clausen,... Figure 8.24. Left schematic diagram of an adiabatical three-bed, indirectly cooled reactor with two heat exchangers. Right a diagram showing the equilibrium curve to the upper right, the optimal operating line and the operation line for the reactor are to the left. [Adapted from C.J.H. Jacobsen, S. Dahl, A. Boisen, B.S. Clausen,...
Fig. 2.1 Schematic diagram of the CMR [22]. 1, reactants for processing 2, metering pump 3, pressure transducer 4, micro-wave cavity 5, reaction coil 6, temperature sensor 7, heat exchanger 8, pressure regulator 9, microprocessor controller ... Fig. 2.1 Schematic diagram of the CMR [22]. 1, reactants for processing 2, metering pump 3, pressure transducer 4, micro-wave cavity 5, reaction coil 6, temperature sensor 7, heat exchanger 8, pressure regulator 9, microprocessor controller ...
Fig. 5.13. Schematic diagram of a Klimenko cycle cryocooler. E123 denote heat exchangers V12 3 n are capillary expansion valves S12 3in are liquid-vapour separators [53]. Fig. 5.13. Schematic diagram of a Klimenko cycle cryocooler. E123 denote heat exchangers V12 3 n are capillary expansion valves S12 3in are liquid-vapour separators [53].
Fig. 2. Diagrams of the processes with instrumentation, (a) Schematic diagram for wastewater digester. Two temperature sensors Ti and T2 were nsed for measnre-ments. Time series were acquired from Ti and T2 was nsed for corroborating no transfer heat to surroundings by comparison with TI measnrements. (b) Schematic for the liquid-liquid heat exchanger. Note that the Bioreactor-Exchanger interconnection involves recycle streams between two feedback controlled processes. Fig. 2. Diagrams of the processes with instrumentation, (a) Schematic diagram for wastewater digester. Two temperature sensors Ti and T2 were nsed for measnre-ments. Time series were acquired from Ti and T2 was nsed for corroborating no transfer heat to surroundings by comparison with TI measnrements. (b) Schematic for the liquid-liquid heat exchanger. Note that the Bioreactor-Exchanger interconnection involves recycle streams between two feedback controlled processes.
Figure 2 show the schematic diagram of both heat exchanger and wastewater digester and the interconnection. As was mentioned in previous subsections, if the bioreactor and heat exchanger are separately operated (i.e., uncoupled system), then they do not exhibit oscillatory behavior for the nominal value of the parameter vector and any value of the dilution rate 0 < urr < u < 00. Now, since the bioreactor and the heat exchanger are coupled by the recycle streams and controlled by specific control laws, we need to re-write the models (1) and (3) under recycle and feedback. Figure 2 shows (a) the schematic... [Pg.290]

In the closed cycle, the heat is added to the fluid in a heat exchanger from an external heat source, such as a nuclear reactor, and the fluid is cooled in another heat exchanger after it leaves the turbine and before it enters the compressor. A schematic diagram of a closed Brayton cycle is shown in Fig. 4.3. [Pg.177]

The injection of water or steam in gas turbines has been known (Nicolin, C., A gas turbine with steam injection. Swedish Patent application No.8112/51, Stockholm, Sweden, 1951) as an efficient method for NO abatement and power boosting. Several cycle configurations are possible with respect to water/steam injection. Figure 4.36 is the schematic diagram of the Steam-injection gas turbine cycle. Air is compressed from state 1 to state 2. Water is pumped from state 7 to state 8. Steam at state 9 is generated in a recovery boiler (heat exchanger) from state 8 by the hot exhaust gas. Steam at state 8... [Pg.224]

Fig. 9.10-10. Schematic diagram of prototype Fig. 9.10-11 Detail of a sample container, batch apparatus. Fc, filter R, condenser A, PI, pressure indicator TI, temperature accumulator Pco2, pump W, heat exchanger indicator TC, temperature controller E1, E2, batch reactors (adapted from [29]) (adapted from [29])... Fig. 9.10-10. Schematic diagram of prototype Fig. 9.10-11 Detail of a sample container, batch apparatus. Fc, filter R, condenser A, PI, pressure indicator TI, temperature accumulator Pco2, pump W, heat exchanger indicator TC, temperature controller E1, E2, batch reactors (adapted from [29]) (adapted from [29])...
Figure 22.15 Schematic diagram of a flow-through electrolysis system (1 = heat exchanger 2 = containers 3 = pumps 4 = Teflon body 5 = diaphragm or ion exchange membrane W = working electrode AUX = auxiliary electrode R = reference electrode). Figure 22.15 Schematic diagram of a flow-through electrolysis system (1 = heat exchanger 2 = containers 3 = pumps 4 = Teflon body 5 = diaphragm or ion exchange membrane W = working electrode AUX = auxiliary electrode R = reference electrode).
Figure 4.3. Schematic diagram and sectional views of the autoclave of the pressure-jump apparatus of Knoche and Wiese (1974) 1, conductivity cells 2, potentiometer 3, 40-kHz generator for Wheatstone bridge 4, tunable capacitors 5, piezoelectric capacitor 6, thermistor 7, 10-turn helipot for tuning bridge 8, experimental chamber 9, pressure pump 10, rupture diaphragm 11, vacuum pump 12, pressure inlet 13, heat exchanger 14, bayonet socket. [From Knoche and Wiese (1974), with permission.]... Figure 4.3. Schematic diagram and sectional views of the autoclave of the pressure-jump apparatus of Knoche and Wiese (1974) 1, conductivity cells 2, potentiometer 3, 40-kHz generator for Wheatstone bridge 4, tunable capacitors 5, piezoelectric capacitor 6, thermistor 7, 10-turn helipot for tuning bridge 8, experimental chamber 9, pressure pump 10, rupture diaphragm 11, vacuum pump 12, pressure inlet 13, heat exchanger 14, bayonet socket. [From Knoche and Wiese (1974), with permission.]...
Figure 13 shows a schematic diagram illustrating the configuration of a surface cooling (indirect heat transfer) crystallizer. Heat can be transferred to a coolant in an external heat exchanger, as shown, or in coils or a jacket... [Pg.212]

Figure 7.13 A schematic diagram of a reactor with an external heat exchanger. Figure 7.13 A schematic diagram of a reactor with an external heat exchanger.
Figure 5. (a) Schematic of the Joule-Thomson cryocooler showing the use of an oil-free compressor and a high-effectiveness heat exchanger, (b) The Joule-Thomson cycle shown on a temperature-entropy diagram. Dashed lines indicate the heat exchange process in the heat exchanger. [Pg.97]

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See also in sourсe #XX -- [ Pg.106 ]



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