摘要
为研究日光温室土墙体温度变化规律及蓄放热特性,以泰安市下挖式土墙日光温室为研究对象,在温室北墙布置5个测试层,通过各测试层最冷季节(30 d)温室内气温、墙体温度、室外气温及室外太阳辐照度测试数据,分析了土墙日光温室内部温度及墙体内温度的分布规律。结果表明:各测试层墙体表面及0.1~0.6 m处测点的温度均呈现出随温室气温周期性变化的规律,且随着墙体厚度的增加温度的波动幅值逐渐减小,相位明显后移;0.7 m以后测点的温度幅值趋于稳定,处于稳态向室外的导热过程。基于墙体温度分布规律,对墙体白天的蓄热量、夜间的放热量及墙体夜间放热效率进行了计算,得出墙体夜间放热效率为43%,表明土墙白天蓄积热量的43%用于改善夜间温室内热环境。对墙体蓄热和放热量计算,综合评价墙体的平均放热效率,可以为土墙日光温室结构优化及热负荷计算提供指导,为各地土墙温室轻简化技术研究提供理论基础。
The solar greenhouse of soil wall, which has the advantages of good heat storage and low construction cost, is widely used in China. At present, the study on the heat storage and heat release performance of soil wall is an important hot spot, which can provide the theoretical basis for the simplification and thickness optimization of soil wall. In the paper, the sunken soil wall greenhouse serves as the research object in Taian, Shandong Province, China. The length is 50 m and the width is 10 m. The top and bottom thicknesses of the soil wall are 1.47 and 3.0 m, respectively. In order to get a better analysis of the heat storage and heat release performance of soil wall, the five testing layers of temperature were arranged in the north wall of greenhouse. The testing period was from Dec. 1st, 2014 to Jan. 30th, 2015. The outdoor weather conditions, indoor air temperature and interior wall temperature were monitored during the testing period. The variation regularity of the indoor and interior wall temperature was analyzed according to the monitoring data in the coldest season (from Dec. 20th, 2014 to Jan. 19th, 2015). The results showed that the testing point temperature of wall surface and interior wall (0.1-0.6 m) presented periodicity variation regularity with the indoor temperature variation in greenhouse, and temperature fluctuation amplitude reduced gradually, at the same time the phase was lags obviously along the wall thickness direction. Moreover, it showed that the interior wall (0-0.6 m) could be considered as the heat storage and heat release body in the soil wall. The heat storage body in the soil wall had large temperature fluctuation, which could be used for storing heat during daytime and releasing heat into the solar greenhouse during night. Besides that, the temperature fluctuation of testing point behind 0.7 m tended to the stabilization, which was in the process of the steady-state heat transfer from the soil wall to outdoors and could be considered as temperature stabilization body in the soil wall. The average temperatures of the testing points of 0.7 m from the first layer to the fifth layer were 8, 10.45, 12.79, 15.19 and 17.42℃ respectively, and the testing points behind 0.8 mwere also the same temperature change regularity. It showed that the equidistance testing point between interior wall surface and interior soil wall on each testing layer had the same regularity of temperature change, that was, increased regularly with the thickening of the soil wall. In order to evaluate the performance of the heat storage and the heat release of soil wall better, the weighted average values of heat storage of all five testing layers were calculated, which were then converted to the heat storage and heat release relative to unit wall area so as to calculate the corresponding heat storage and heat release of the 0.6 m soil wall during a whole day. On the basis of the heat storage and the heat release results, the average efficiency of heat release for the soil wall during the coldest season period was calculated. The result showed that the average efficiency of heat release was 43% for solar greenhouse of the soil wall, which could release 43% of the heat storage of soil wall during the day to improve the thermal environment of the greenhouse nighttime. The study on heat storage calculation, heat release calculation and efficiency evaluation of average heat release will not only provide guidance for structural optimization and heat load calculation of greenhouse, but also provide theoretical basis for the simplification technology of soil wall greenhouse in different region of china.
出处
《农业工程学报》
EI
CAS
CSCD
北大核心
2016年第22期214-221,共8页
Transactions of the Chinese Society of Agricultural Engineering
基金
国家现代农业产业技术体系建设专项(CAR-25)
关键词
温室
温度
环境调控
温室墙体
蓄热量
放热量
放热效率
greenhouses
temperature
environmental regulations
greenhouse wall
heat storage
heat release
heat releaseefficiency
作者简介
史宇亮,女,博士生,讲师。主要从事设施环境工程与调控方面的工作和研究。泰安山东农业大学园艺科学与工程学院,271018。Email:shiyuliang1981@126.com
通信作者:王秀峰,男,教授,博士生导师。主要从事设施环境工程与调控方面的工作和研究。泰安山东农业大学园艺科学与工程学院,271018。Email:xfwang@sdau.edu.cn
