co2基太阳能热水器逆流壳盘管换热器原理与设计

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摘要

采用CO2制冷剂材料,设计、制造和试验了一种壳式螺旋管逆流换热器。螺旋铜管浸入散装水箱。热CO2通过管道输送到上盘管挡板,冷CO2通过下盘管挡板进入集热器回路。冷水从下龙头进入,热水从上龙头流出。进出管均从顶部插入,盘管从水箱的上下两侧插入。采用CO2制冷剂,利用真空玻璃管太阳能集热器实现了超临界热虹吸操作。在真空玻璃管内插入包有铝箔的U型铜管,利用热虹吸原理将热量传递到连接壳式螺旋盘管换热器进口挡板的上集管。下集箱连接到换热器螺旋盘管出口挡板上。太阳能集热器将CO2制冷剂的温度从35℃提高到78℃,产生43℃的温差。当周围环境温度为36℃时,从热交换器出口的CO2制冷剂温度为40℃。在关闭水龙头的情况下,热交换器在3小时内将进水温度从26℃提高到55℃。测得换热器进出口温差为27℃。我们相信,如果在日照温和寒冷的地区使用该系统,可以进一步提高系统效率。
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Theory and Design of Counter Flow Shell-and-Coil Heat Exchanger for CO2Based Solar Water Heater
A shell type helical tube countercurrent flow heat exchanger was designed, fabricated and tested using CO2 refrigerant material. Helical copper tube was immersed in bulk water tank. Hot CO2 was piped to upper coil baffle and cold CO2 was circulated into collector loop through lower baffle. Cold water was made to enter through lower tap and hot water was taken out from upper tap. Both in/out pipes were inserted from the top and coil tubes from upper and lower sides of water tank. Supercritical thermosyphon operation was achieved by evacuated glass tube solar heat collector using CO2 refrigerant. U shaped copper pipes enveloped in aluminum foil were inserted in evacuated glass tubes to transfer heat under thermosiphon principle to upper header connected to inlet baffle of shell type helical coil heat exchanger. Lower header was connected to heat exchanger helical coil outlet baffle. Solar collector heat raised CO2 refrigerant temperature from 35 to 78C giving temperature difference of 43C. Temperature of CO2 refrigerant at exit from heat exchanger was found to be 40C at surrounding ambient temperature of 36C. Heat exchanger raised the inlet water temperature from 26 to 55C under off water tap condition in about 3 hours. Inlet and outlet temperature difference of heat exchanger was measured to be 27C. We believe system efficiency can further increase if we use the system in mild sunshine cold weather regions duplicating geothermal loop.
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