Real-time quantitative measurement of a Stirling engine P-V diagram

TL;DR

This paper presents a simple, cost-effective method to measure and display a Stirling engine's P-V diagram in real time, enhancing understanding of its thermodynamic cycle during operation.

Contribution

It introduces minimal modifications to a standard Stirling engine enabling real-time, calibrated P-V diagram measurement and visualization.

Findings

Real-time P-V diagram measurement demonstrated

System accurately tracks engine cycle in operation

Method is inexpensive and easy to implement

Abstract

This paper describes simple modifications to a Stirling-type heat engine that allow its P-V diagram to be measured. The main advantage of our approach is that a calibrated P-V diagram can be measured and displayed in real time as the engine is running. Our implementation uses a relatively inexpensive, but high-quality, gamma-type Stirling engine designed for demonstrations. The only modifications required to the as-purchased engine are a single hole drilled in the top plate to accommodate a pressure sensor and attaching circular choppers to the flywheel. An outer chopper is used to reset the detection electronics when the internal volume of the engine is a minimum. An inner chopper is then used to track the orientation of the flywheel. This paper describes the design of the photogates and electronics used to collect and process the data. Example data are shown to highlight the capabilities of the system.