Energy targeting and process integration of spray dryer with heat recovery systems

[Display omitted] •Development of pinch analysis strategy for a new domain of an evaporative system.•Process integration of spray dryer with indirect heat recovery, a new approach.•Process integration of spray dryer with a hybrid heat recovery system for high efficiency.•Energy analysis and manageme...

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Bibliographic Details
Published in:Energy conversion and management 2020-10, Vol.221, p.113148, Article 113148
Main Authors: Patel, Sanjay Kumar, Bade, Mukund Haribhau
Format: Article
Language:English
Subjects:
Air pollution
Air temperature
Configurations
Counterflow
Driers
Drying
Economic analysis
Economic conditions
Energy
Energy analysis
Energy conservation
Energy recovery
Evaporation
Exhaust gases
Flow rates
Flue gas
Gases
Heat
Heat recovery
Heat recovery systems
Hybrid systems
Mass balance
Mass flow rate
Moisture content
Pinch analysis
Retrofitting
Spray dryer
Streams
Techno-economic analysis
Thermal energy
Washers & dryers
Waste heat recovery, Driving potential
Water content
Water pollution
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Summary:[Display omitted] •Development of pinch analysis strategy for a new domain of an evaporative system.•Process integration of spray dryer with indirect heat recovery, a new approach.•Process integration of spray dryer with a hybrid heat recovery system for high efficiency.•Energy analysis and management of an integrated system for maximum performance.•Techno-economic analysis of driving potential on the energy recovery configurations. Energy recovery is essential as it reduces fuel cost and pollution due to emission of flue gases. The energy recovery potential can be easily determined by pinch analysis, where individual fluid streams obey mass balance. However, in this paper, pinch analysis based methodology is proposed for energy targeting of evaporative systems such as dryers where the mass balance of individual streams is not possible due to loss of identity of one of the streams (feed) because of evaporation of water content and separation of the solid part. Initially, a spray dryer with a counterflow arrangement is selected to demonstrate the applicability of pinch analysis for targeting of energy requirement considered as the base case. Additionally, three different heat recovery configurations integrated with spray dryers are explored by pinch analysis for energy targeting as: (i) direct heat recovery, (ii) indirect heat recovery, and (iii) hybrid heat recovery systems. Further heat recovery potentials and their effect on the performance of the drying process are evaluated appropriately for different cases based on exhaust gas temperatures. The pinch analysis shows that with decreasing a mass flow rate of supply gases/air, the exhaust losses are also reducing for spray dryer integrated with all configuration of the heat recovery system. For spray dryer with indirect heat recovery configuration, energy-saving potential with and without exhaust gas/air temperature constraint is achieved as 57 and 68%, respectively, for a given illustrative example. Among all configurations, a hybrid heat recovery system with 80% recirculation is having the highest thermal energy saving potential (74%) compared to the base case. Moreover, the reduction in the driving potential of spray dryers for direct and hybrid heat recovery configurations is appropriately analyzed for new as well as retrofitted drying systems. It is observed that the effect of driving potential is insignificant for a lower recirculation ratio. Further, techno-economic analysis reveals that there are
ISSN:0196-8904
1879-2227
DOI:10.1016/j.enconman.2020.113148