杨松夏, 吕恩利, 陆华忠, 吕盛坪, 岑康华. 液氮充注式果蔬气调保鲜运输箱能耗模型建立与验证[J]. 农业工程学报, 2014, 30(15): 299-308. DOI: doi:10.3969/j.issn.1002-6819.2014.15.038
    引用本文: 杨松夏, 吕恩利, 陆华忠, 吕盛坪, 岑康华. 液氮充注式果蔬气调保鲜运输箱能耗模型建立与验证[J]. 农业工程学报, 2014, 30(15): 299-308. DOI: doi:10.3969/j.issn.1002-6819.2014.15.038
    Yang Songxia, Lü Enli, Lu Huazhong, Lü Shengping, Cen Kanghua. Establishment and verification of energy consumption model of fruits and vegetables fresh-keeping transportation container with controlled atmosphere by liquid nitrogen injection[J]. Transactions of the Chinese Society of Agricultural Engineering (Transactions of the CSAE), 2014, 30(15): 299-308. DOI: doi:10.3969/j.issn.1002-6819.2014.15.038
    Citation: Yang Songxia, Lü Enli, Lu Huazhong, Lü Shengping, Cen Kanghua. Establishment and verification of energy consumption model of fruits and vegetables fresh-keeping transportation container with controlled atmosphere by liquid nitrogen injection[J]. Transactions of the Chinese Society of Agricultural Engineering (Transactions of the CSAE), 2014, 30(15): 299-308. DOI: doi:10.3969/j.issn.1002-6819.2014.15.038

    液氮充注式果蔬气调保鲜运输箱能耗模型建立与验证

    Establishment and verification of energy consumption model of fruits and vegetables fresh-keeping transportation container with controlled atmosphere by liquid nitrogen injection

    • 摘要: 为掌握液氮充注式果蔬气调保鲜运输箱能耗规律,该文分析了运输箱的传热传质过程及其能耗构成,在分别研究了气调过程、制冷过程和加湿过程的基础之上建立了液氮充注式果蔬气调保鲜运输箱能耗模型,并对所建能耗模型进行了试验验证。研究结果表明,液氮充注式果蔬气调保鲜运输箱能耗主要由气调能耗、制冷能耗和加湿能耗构成;根据能耗模型所得的理论能耗与试验能耗基本一致,平均相对误差为11.86%±4.29%;根据能耗模型所得的理论液氮消耗量与试验液氮消耗量基本一致,平均相对误差为11.60%±3.51%;液氮充注气调过程消耗较少能耗即可产生较大的附加制冷总量,并且气调附加制冷总量与箱体气调体积有关,在该验证试验中理论液氮充注气调附加制冷总量所占理论制冷总量的比例达22%左右。该研究为液氮充注式果蔬气调保鲜运输装备优化以及果蔬保鲜运输节能提供参考。

       

      Abstract: Abstract: China is a country that produces and consumes large amounts of fruits and vegetables. During fresh-keeping transportation, energy consumption rises with the increase of traffic volume of fruits and vegetables. The fresh-keeping transportation container with controlled atmosphere by liquid nitrogen injection is an advanced and efficient equipment for transporting fruits and vegetables. However, there is little research on the energy consumption regulations of this kind of fresh-keeping transportation container so this article puts forward a research method. Fresh-keeping transportation with controlled atmosphere by liquid nitrogen injection for fruits and vegetables keeps the temperature, relative humidity, and oxygen volume fraction of the transportation container in a state of relative balance, which could meet the demand for fruit and vegetable fresh-keeping. However, due to the influence of heat transferring towards the container, cold consuming of electrical appliances, cold consuming of fruits and vegetables, heat transferring by door opening, aperture heat leaking, container pre-cooling, and solar radiation in transportation, the equilibrium states of fresh-keeping environment in the container is broken. In addition, heat and mass transferring between the inside and outside of the container has begun. At this time, the fresh-keeping equipments started to keep the equilibrium states of fresh-keeping environment, and then energy consumption was generated. The fresh-keeping equipments of controlled atmosphere fresh-keeping transportation container by liquid nitrogen injection consist of refrigeration, humidification, and controlled atmosphere system, and the energy consumption generated from these three equipments. Finally, the energy consumption model was established based on the analysis of the heat and mass transfer and energy consumption in refrigerating, humidifying, and injecting. After the energy consumption model was set up, the verification experiment was carried out using litchi as testing material and was based on fresh-keeping transportation platform with controlled atmosphere by liquid nitrogen injection for fruits and vegetables. The fresh-keeping transportation platform can adjust the temperature, relative humidity, and oxygen volume fraction in the container automatically and intelligently through refrigeration, humidification, and controlled atmosphere system, creating a suitable fresh-keeping environment for the litchi. Results indicated that the energy consumption was mainly composed of the controlled atmosphere energy, refrigerating energy consumption, and humidifying energy. The theoretical energy consumption obtained through the energy consumption model was basically consistent to the experimental energy consumption with the average relative error of 11.86%±4.29%. The theoretical liquid nitrogen consumption value was basically consistent to the experimental liquid nitrogen consumption mass with the average relative error of 11.60%±3.51%. The total refrigerating capacity from the controlled atmosphere process was associated with the controlled atmosphere volume of the container. What's more, by consuming less energy, the controlled atmosphere could produce a large total refrigerating capacity that accounted for about 22% of the total theoretical refrigerating capacity in the experimental verification. This research provides a reference for optimizing the equipments of controlled atmosphere transportation by liquid nitrogen injection and saving energy of fruits and vegetables during fresh-keeping transportation.

       

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