Performance investigation of a novel Franchot engine design

Daoud, Jafar M.; Friedrich, Daniel

doi:10.1002/er.3850

Cited by 6 publications

(16 citation statements)

References 22 publications

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“…Figure 2 clearly shows the differences between the isothermal and adiabatic processes on the cycle work. Daoud and Friedrich [7] reported a novel Franchot engine design in which the heat transfer area was extended to the whole cylinder wall area, which allows the use of high temperatures. In addition, they increased the phase angle to allow faster speeds and hence increased the heat transfer.…”

Section: Heat Exchangermentioning

confidence: 99%

“…However, for a double acting Franchot engine (see, for example, Figure 1 in [7]) the connecting rods will be inside the swept volume of one half of the engine and will thus influence the engine behavior. An increase in the connecting rod diameter will reduce the hydraulic diameter, which increases the heat transfer per volume, thus acting like an internal fin although it has unheated and uncooled surfaces (see Figure 4).…”

Section: Isothermalizing the Franchot Enginementioning

confidence: 99%

“…The study is based on a second order model derived in a previous contribution for the Franchot engine [7]. The model assumes an ideal Franchot engine with polytrophic expansion and compression processes and ideal regenerator.…”

Section: Mathematical Modellingmentioning

confidence: 99%

“…The optimisation was performed manually until the maximum power is reached for the speed range 100-500 rpm. Each single speed, phase angle and connecting rod diameter were changed manually with a step size of 50 It is shown that adding fins is superior to the phase angle control method [7] in terms of power and efficiency. The engine with fins works closer to the Curzon efficiency at the maximum power than the phase angle method.…”

Section: Influence Of the Isothermal Finsmentioning

confidence: 99%

“…It is shown that adding fins is superior to the phase angle control method [7] in terms of power and efficiency. The engine with fins works closer to the Curzon efficiency at the maximum power than the phase angle method.…”

Section: Optimised Responsementioning

confidence: 99%

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Parametric Study of an Air Charged Franchot Engine with Novel Hot and Cold Isothermalizers

Daoud

Friedrich

2017

Inventions

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Abstract:The Stirling engine is an external combustion engine that uses heat exchangers to enhance the addition and removal of energy. This makes the engine power-dense but expensive, less efficient and complicated. In this contribution, the Stirling engine based on the Franchot engine has novel cylindrical fins working as isothermalizers to improve heat transfer without the complications of heat exchangers. Enhancing the power density by isothermalizing work spaces is compared to the bare cylinder optimized by varying the phase angle. The theoretical analysis shows that both the adiabatic and isothermal fins increase the power and efficiency, achieving the Curzon and Ahlborn efficiency at the maximum power point. In comparison to the phase angle method, the finned engine resulted in much lower gas mass flow rate, which leads to a reduction in the regenerator pumping and enthalpy losses. Thus, the Stirling engine has the potential to be simple, cheap, efficient and power-dense, and thus can be used effectively for different applications.

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Section: Heat Exchangermentioning

confidence: 99%

Section: Isothermalizing the Franchot Enginementioning

confidence: 99%

Section: Mathematical Modellingmentioning

confidence: 99%

Section: Influence Of the Isothermal Finsmentioning

confidence: 99%

Section: Optimised Responsementioning

confidence: 99%

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Parametric Study of an Air Charged Franchot Engine with Novel Hot and Cold Isothermalizers

Daoud

Friedrich

2017

Inventions

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Analysis of a novel rotating disk cylinder engine concept for power generation

Roux

Swanepoel

2018

Int J Energy Res

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Summary A new type of engine concept is proposed, namely a rotating disk cylinder engine. Unique secondary rotors with grooves act as guide vanes for a working fluid to power a main rotor with multiple cylindrical pistons. Currently, no literature exists on the proposed device and the modelling thereof. The aim of this paper is to determine the dynamic and thermodynamic behaviour of the machine so that recommendations can be made for further research work. A transient as well as a steady‐state thermodynamic model is developed for an adiabatic expansion process using first and second law analysis with air as ideal gas. The model is compared with experimental results of a piston engine driven by compressed air. Results show that the secondary rotor's angle of rotation is not a linear function of the main rotor's angle of rotation, which suggests a limitation in terms of operating speed. Furthermore, for constant power, the efficiency increases as the inlet pressure and speed decrease, while for constant efficiency, the power increases as the inlet pressure and speed increase. Results show the advantage of using three secondary rotors as it drastically decreases the pressure requirement for a constant torque output. The speed and inlet pressure of the device is, however, limited by the mass and material properties of the rotors as well as the effects of leakage. These limitations have not been considered in this initial analysis of the device and are recommended for future work.

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A new duplex Stirling engine concept for solar‐powered cooling

Daoud

Friedrich

2020

Int J Energy Res

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The global cooling demand is one of the fastest growing energy demands and is putting a strain on the electricity infrastructure. Solar-powered cooling could provide most of the cooling demand due to the coincidence of the cooling demand and the solar irradiance. In particular, the solar-powered Stirling-cycle cooler has low maintenance requirement, high theoretical efficiency, and use of environmentally friendly gases. However, Stirling-cycle coolers are expensive due to high driving temperatures, complex heat exchangers, and expensive solar tracking so that they have so far only been successful at high-temperature difference applications. This study introduces a novel directly coupled solar Stirling cooler for which the hot engine cylinders are deployed inside evacuated tube collectors. The machine uses air as working fluid, and its driving mechanism is based on the free-piston, balanced compound technology that was patented by Finkelstein. A second-order mathematical model is used to investigate the performance of the machine for different cylinder arrangements, gas leakage rates, chilling temperatures, and solar irradiance. In addition, the regenerators are optimised to maximise the cold production. It is shown that mechanical frictions can be reduced to 20% by selecting an appropriate cylinder arrangement. The solar cooler achieves a maximum cold production rate of 367.5 W/m 2 without using external heat exchangers at load temperature of 7 C, which is comparable with photovoltaic powered coolers.In addition, the machine is relatively simple, has safe and quiet operation, uses ambient air as working gas, and is able to produce a wide range of chilling including sub-zero temperatures without changing the working gas. The direct thermal coupling of the Stirling cooler to evacuated tube collectors significantly reduces the complexity of the machine and removes intermediate heat transfer steps which reduce the performance. Thus, the suggested cooling technology has great potential for solar refrigeration, especially for low power and near ambient cooling.

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Performance investigation of a novel Franchot engine design

Cited by 6 publications

References 22 publications

Parametric Study of an Air Charged Franchot Engine with Novel Hot and Cold Isothermalizers

Parametric Study of an Air Charged Franchot Engine with Novel Hot and Cold Isothermalizers

Analysis of a novel rotating disk cylinder engine concept for power generation

A new duplex Stirling engine concept for solar‐powered cooling

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