Abstract
Low delta-T syndrome often occurs in building chilled water systems, which makes systems fail to operate as efficiently as originally anticipated. Extensive studies have been conducted on the subject of low delta-T syndrome with the aims of investigating the potential causes behind and the ways to keep delta-T high. This paper addresses to explain the causes of degrading delta-T from a mathematic perspective and to analyze the impacts of important operational parameters on the delta-T quantitatively. A simplified global cooling coil model representing the relationship between the total cooling load and the total water flow rate of chilled water systems is developed, which can be used to predict the system delta-T under different load distribution and system operation conditions. It is proved mathematically that the load distribution characteristic is an important factor in influencing the system delta-T of a chilled water system. This finding explains why the system delta-T is always lower than the delta-T of individual coils, particularly under low partial load conditions. A system-level fault detection and diagnosis (FDD) method is proposed for identifying the possible causes of the low delta-T problem. A case study is conducted to validate the proposed global model and FDD method in a real building.
Highlights
Centralized air conditioning systems are one of the largest energy consumers in commercial buildings [1]
The schematic of a typical primary-secondary chilled water system is shown in Figure 1, which consists of two chilled water loops, including a primary loop and a secondary loop
There are a lot of faults that can result in low delta-T syndrome, which can be classified into two categories: “heat transfer deterioration” faults and “improper water flowrate” faults
Summary
Centralized air conditioning systems are one of the largest energy consumers in commercial buildings [1]. To distinguish different causes coil fouling, outdoor air economizers, 100% outdoor air systems, which are and not faults of butlow the delta-T syndrome, some researchers proposed various fault detection and diagnosis (FDD). Kirsner [14] proposed that the use of a check valve in the bypass pipeline is a cheap and a simple measure to deal with low delta-T syndrome for a primary–secondary chilled water plants. This method was experimentally validated in a real building in Hong Kong conducted by Wang [15]. It can be used to explain the low delta-T syndrome from a mathematic perspective and to diagnose the possible causes of low delta-T problem in practice for primary-secondary chilled water systems
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