Abstract
As technology advances, rotating machinery are operating at higher rotational speeds and increased pressures with greater heat concentration (i.e. smaller and hotter). This combination of factors increases structural stresses, while increasing the risk of exceeding temperature limits of components. To reduce stresses and protect components, it is necessary to have accurately designed thermal management systems with well-understood heat transfer characteristics. Currently, available heat transfer correlations operating within high Taylor number (above 1×10^10) flow regimes are lacking. In this work, the design of a high Taylor number flow experimental test rig is presented. A non-invasive methodology, used to capture the instantaneous heat flux of the rotating body, is also presented. Capability of the test rig, in conjunction with the use of high-density fluids, increases the maximum Taylor number beyond that of previous works. Data of two experiments are presented. The first, using air, with an operating Taylor number of 8.8± 0.8 ×10^7 and an effective Reynolds number of 4.2± 0.5 ×10^3, corresponds to a measured heat transfer coefficient of 1.67 ± 0.9 ×10^2 W/m2K and Nusselt number of 5.4± 1.5×10^1. The second, using supercritical carbon dioxide, demonstrates Taylor numbers achievable within the test rig of 1.32±0.8×10^12. A new correlation using air, with operating Taylor numbers between 7.4×10^6 and 8.9×10^8 is provided, comparing favourably with existing correlations within this operating range. A unique and systematic approach for evaluating the uncertainties is also presented, using the Monte-Carlo method.
Highlights
Rotating machinery is used in a wide variety of applications, from turbines and electric generators to motors and workshop equipment
This paper describes the design of a test rig and methodology for measuring T-C-P heat transfer rates in high Taylor number flows
This section describes the necessary steps to determine the Heat Transfer Coefficient (HTC) from the measurements taken in the test rig
Summary
Rotating machinery is used in a wide variety of applications, from turbines and electric generators to motors and workshop equipment. Thermal management has been of increasing interest as machines become smaller and faster (Heshmat et al, 2018; Yin et al, 2018). High temperature gradients can cause large thermal stresses and shorten the life of temperature sensitive components such as seals, shafts, discs, and bearings. As well as minimizing thermal stresses, minimizing coolant flows is essential to the efficient operation of most rotating machinery. It is critical to have accurate models of the cooling mechanisms present and knowledge of the heat transfer rates to prevent undue stresses and ensure coolant flow rates are minimized. Rotating machines involve a shaft with a static outer casing and a small annulus filled with gas or oil for thermal management and lubrication purposes
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