Optimization in refrigeration systems
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The presentation of a Lecture on optimization of refrigeration systems given during a workshop in IITD. Includes an illustration and some generic ideas.
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Optimization in refrigeration systems
- 2. Synopsis The design Process Need for Optimization How Energy Conservation – innovative concepts
- 3. The Design Process Traditional approach Design of a window air-conditioner What is the basis of choosing ? Condenser Temperature Evaporator temperature No. of Rows Tube diameter
- 4. The Design Process Condenser temp Compressor Power Consumption Condenser size Evaporator Tube Dia Pressure gradient Surface Area / frontal area ? Heat transfer coefficient ? ? Effective temp difference
- 5. Why Optimization ? Increasing Competition Increasing energy costs Stringent energy standards Ecological considerations Availability of computational tools
- 6. Formulation of an Optimization Problem Three basic steps : Objective function Variables Constraints Special features of thermal system Optimization Nature of variables—discrete + continuous We may want to optimize only some equipment NOT the whole system
- 8. Optimum Design of a Refrigeration System -- problem formulation Min TCs = FCe + FCc + RCe + RCc +Rcco TCs= ΣNte(i) Lte Cct +Σ Ntc(i) Ltc Cct + [K Mwe PDe + K Mwc PDc + 0.746 (BHP) ] Ckw Lh Variables : Lte , Nte( 1,2) ; Ltc , Ntc (1,7) No of passes, Fin design, tube layout, etc Constraints: : Qe = Qer ; Mwe = Mwer, Twic = Twicr ; Qc = Qcr Max Vel of water < Vr; Tube lengths within bounds
- 12. Optimizing a Component Case Study 40 TR DX Chiller Min. initial cost design SN No of tubes shell dia baffle cut 1 12 16 20 24 30 1.28 .24 32 32 32 34 2 16 16 17 21 Obj fn pr. at entry psi 1452 77.5 1.07 .324 998 78.7
- 13. Optimizing a Component Case Study: Condenser coil of an AC Min initial cost design Design variable No of Rows No of Ckts Tube Length Tube O/ D Tubes/row Heat Transfer Pressure Drop Base Cost Initial Design 2 2 .585 m 7 mm 23 5080 W 1.0166 bar Rs 6377 Optimize d Design 2 3 .594 m 7 mm 21 5090 W .8438 bar Rs 5940
- 14. ECO – Design of Refrigeration Equipment Life cycle analysis based on emissions
- 15. Reducing Energy Consumption What should be the thermostat settings of a Window AC ? Do we need to maintain 24oC indoors ? Experience of Air conditioned trains . Comfort research shows PPD for 24oC is the same as for 27.2oC. Impact of high outdoor temperatures and short duration of occupancy on “optimal” indoor temperatures
- 16. Reduce Energy Consumption through Innovative Concepts Using stratification to reduce cooling load Window AC + Table fan Regenerative evaporative cooling for “hotdry” climates : “Green AC” Regenerative Evaporative cooling based cool chests for vegetable & fruit retail outlets Desiccant based cooling
- 17. Reduce Energy Consumption through innovative concepts Combining multiple uses -- Customized A/C Solutions e.g. for kitchens, hostels, restaurants Air conditioning, cold water, hot water Multiple indoor and outdoor unit split AC Fuzzy Control + variable speed control for energy saving Variable dead-band thermostats Personal AC
- 18. Reduce Energy Consumption through innovative concepts LPG based AC / refrigerator Bio-mass/Bio-gas energized cold chests for rural areas Low cost Domestic refrigerator without freezer Consumer education
- 19. Thank you !