The identification of the imperfection originating from finite-temperature-difference heat transfer is an indispensable step for both the performance analysis and the better design of a heat exchanger network (HEN) ...The identification of the imperfection originating from finite-temperature-difference heat transfer is an indispensable step for both the performance analysis and the better design of a heat exchanger network (HEN) with the aim of energy saving. This study develops a convenient area method for visualizing the heat-transfer imperfection of a HEN in terms of temperature-heat flow diagrams ( T-Q diagrams) by combining the composite curves that have already been used in pinch analysis and the re- cently developed entransy analysis. It is shown that the area between the hot and cold composite curves and the hot and cold utility lines on a T-Q diagram is just equal to the total entransy dissipation rate during the multi-stream heat transfer process occurred in a HEN, and this area can be used to graphically represent the total heat-transfer imperfection of the HEN. The increase in heat recovery or decrease in energy requirements with decreasing the minimum temperature difference, ATmin, of a HEN can then be attributed to a lower entransy dissipation rate, quantitatively represented by the decrease of the area between the composite curves and the utility lines. In addition, the differences between the T-Q diagram and the pre-existing energy level-enthalpy flow diagram (12-H diagram) in the roles of visualizing process imperfection and designing HENs are dis- cussed.展开更多
文摘贝氏体钢轨闪光焊过热区奥氏体晶界微区出现:1 Mn和Cr偏析,金属显微组织出现马氏体组织,从而使得奥氏体晶界脆化;2Mn和S偏析,形成Mn S夹杂物,进一步脆化奥氏体晶界;3偏析进一步严重可导致晶界开裂。控制焊接热输入可以有效控制缺陷形成的数量。焊接热输入试验结果显示:预热次数控制在10次以下,热输入控制在5600 k J以下,可以消除裂纹,最大程度减少马氏体微区和夹杂物数量。
基金supported by the National Natural Science Foundation of China(Grant Nos.51206079,51356001)
文摘The identification of the imperfection originating from finite-temperature-difference heat transfer is an indispensable step for both the performance analysis and the better design of a heat exchanger network (HEN) with the aim of energy saving. This study develops a convenient area method for visualizing the heat-transfer imperfection of a HEN in terms of temperature-heat flow diagrams ( T-Q diagrams) by combining the composite curves that have already been used in pinch analysis and the re- cently developed entransy analysis. It is shown that the area between the hot and cold composite curves and the hot and cold utility lines on a T-Q diagram is just equal to the total entransy dissipation rate during the multi-stream heat transfer process occurred in a HEN, and this area can be used to graphically represent the total heat-transfer imperfection of the HEN. The increase in heat recovery or decrease in energy requirements with decreasing the minimum temperature difference, ATmin, of a HEN can then be attributed to a lower entransy dissipation rate, quantitatively represented by the decrease of the area between the composite curves and the utility lines. In addition, the differences between the T-Q diagram and the pre-existing energy level-enthalpy flow diagram (12-H diagram) in the roles of visualizing process imperfection and designing HENs are dis- cussed.
