Abstract
The use of organic Rankine cycle systems for waste heat recovery on heavy-duty vehicles is one of the most effective solutions to reduce the fuel consumption and the environmental pollution of heavy-duty transport. In this application, the variable driving conditions cause such systems to be operated with a highly fluctuating heat source, which must be primarily handled by properly designing the system components and, in particular, the evaporator. This paper investigates the effect of the design parameters of a fin-and-tube evaporator on the dynamic response of the organic Rankine cycle system. The goal is to understand and quantify the dampening effect given by the evaporator design parameters, which influence its weight, and, in turn, its dynamic time response. A finite-volume dynamic model of the evaporator is built in Dymola. Subsequently, the dynamic behaviour of the high-pressure part of the organic Rankine cycle system is simulated based on measurement data of the exhaust gas mass flow rate and temperature from a heavy-duty vehicle taken during a 45-min driving cycle. Simulations are carried out in MATLAB®/Simulink®, by importing the Dymola model as a functional mock-up unit. The results suggest that the larger the heat source fluctuations, the stronger the need to increase the evaporator weight to obtain appreciable dampening effects. The simultaneous variation of the inner diameter of the evaporator tube and the tube spacing leads to the highest dampening effect on the net power output, with a reduction of about 11% of the highest peak value (8220 W).
Highlights
Significant progress has been done in the transport sector to implement emission abatement strategies [1], the target of a 60 % reduction by 2050 compared with 1990 levels [2] requires significant measures to be taken with respect to the state of the art
This paper investigates the effect of the design parameters of a fin-and-tube evaporator on the dynamic response of the organic Rankine cycle system
This paper presents an analysis of the effect of the geometrical parameters of a fin-and-tube evaporator on the time response of the heat exchanger and on the design of a simple proportional-integral (PI) controller that keeps a constant degree of superheating at the evaporator outlet of an Organic Rankine cycle (ORC) system, rejecting the fluctuations of the waste heat conditions
Summary
Significant progress has been done in the transport sector to implement emission abatement strategies [1], the target of a 60 % reduction by 2050 compared with 1990 levels [2] requires significant measures to be taken with respect to the state of the art. The most important ones deal with low efficiency-to-cost ratios [5,6,7], stringent constraints on unit weight and volume [8,9,10], integration issues [11,12,13], and the development of controllers that can ensure safe operation for the highly fluctuating heat source [14] In spite of these challenges, the high amount of waste heat released by the internal combustion engine (about two-thirds of the total input fuel energy [15]) makes the WHR option very attractive. They showed how evaluations based on steady-state operating conditions overestimated the fuel savings by about 50 % compared with evaluations based on dynamic conditions
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