VHTX: A code for simulation of steady state and dynamic response of single or multiple networked cross flow heat exchangers in data center thermal management systems

2017 33rd Thermal Measurement, Modeling & Management Symposium (SEMI-THERM) Pub Date : 1900-01-01 DOI:10.1109/SEMI-THERM.2017.7896913

A. Ortega, M. del Valle, Carol Caceres

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引用次数: 2

Abstract

Crossflow heat exchangers are key components of both centralized (e.g. CRACs) and decentralized (rear door, in-row) cooling equipment utilized in data center thermal management systems. Modeling of their behavior in steady state is well documented but transient or dynamic operation, whether by intent or as a result of a system failure, has not been well documented. In “smart cooling” scenarios, cooling should be modulated with heating (i.e. IT) load which can vary with time and space as IT load varies within a rack and within the data center room. Cooling is optimally utilized when the cooling load follows or even anticipates the heating (IT) load and as such the heat exchanger operates in a dynamically controlled mode. In data center operation, there is also interest in understanding their behavior in case of system malfunctions such as pump or chiller failures which results in transient operation. The MATLAB™ simulation code VHTX was developed in order to simulate the performance of crossflow heat exchangers in both steady and dynamic operation. It is a standalone code for simulation of heat exchanger networks and core code elements are also being embedded into or coupled with other simulation environments such as MATLAB SIMULINK™ for control investigations, VTAS for data center system thermodynamic and energy analysis, and CFD codes for room simulations. This paper describes the basic formulation of the VHTX solver and its validation against research quality data on heat exchanger cores. It is shown that the code can accurately predict the coolant flow distribution within the heat exchanger core and its dynamic response to temporal events such as modulation of the coolant flow rate or temperature to match the air side thermal load. A case study simulating a typical rear door heat exchanger is presented as an example of the use of the code in a data center simulation.

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数据中心热管理系统中单个或多个网络交叉流热交换器的稳态和动态响应仿真代码

横流热交换器是数据中心热管理系统中使用的集中式(例如crac)和分散式(后门，排内)冷却设备的关键组件。它们在稳定状态下的行为建模有很好的记录，但无论是出于意图还是由于系统故障造成的瞬态或动态操作，都没有很好的记录。在“智能冷却”场景中，冷却应该与加热(即IT)负载一起调节，加热(即IT)负载可以随着时间和空间的变化而变化，因为IT负载在机架和数据中心房间内的变化。当冷却负荷跟随或甚至预期加热(IT)负荷时，冷却得到最佳利用，因此热交换器在动态控制模式下运行。在数据中心运行中，也有兴趣了解它们在系统故障情况下的行为，如泵或冷却器故障，导致瞬态运行。开发了MATLAB™仿真代码VHTX，以模拟横流式换热器在稳态和动态运行中的性能。它是用于热交换器网络模拟的独立代码，核心代码元素也被嵌入或与其他模拟环境相耦合，例如用于控制调查的MATLAB SIMULINK™，用于数据中心系统热力学和能量分析的VTAS，以及用于房间模拟的CFD代码。本文介绍了VHTX求解器的基本公式，并对换热器堆芯的研究质量数据进行了验证。结果表明，该程序能够准确地预测换热器芯内冷却剂流量分布及其随时间变化的动态响应，如冷却剂流量或温度的调节以匹配空气侧热负荷。以一个典型的后门热交换器为例，介绍了该代码在数据中心仿真中的应用。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2017 33rd Thermal Measurement, Modeling & Management Symposium (SEMI-THERM)

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