用化学过程工程的思维方式开发降低复杂性的植物模型

IF 0.5 Q4 ENGINEERING, CHEMICAL

Hungarian Journal of Industry and Chemistry Pub Date : 2022-09-27 DOI:10.33927/hjic-2022-09

M. Varga

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引用次数: 0

摘要

鉴于农业系统在基于生物的循环经济的更广泛背景下日益复杂，需要简化和统一的植物模型来代表太阳能驱动的二氧化碳封存的初级生物质生产。利用过程系统工程的经验，最初受到化学工程的启发，提出了一个合适的工厂模型。该模型的结构是由下伏状态和过渡元素的过程网络生成的。引入了两种特殊的状态元素，用于分配供应的生物质的短期储存和蒸散和光合作用所需的含营养水分的吸收。以过渡为导向的功能描述遵循了自然自我控制的基本因果关系和平衡。通过一个简单的例子说明了该模型的实现。

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Developing Plant Models of Reduced Complexity by Chemical Process Engineering Way of Thinking

Given the increasing complexity of agricultural systems within the broader context of the bio-based circular economy, simplified and unified plant models are needed that represent the primary biomass production by solar-driven carbondioxide sequestration. Utilizing experiences from process systems engineering, which was originally inspired by chemical engineering, a suitable plant model is proposed. The structure of the model is generated from the process net of theunderlying state and transition elements. Two special-state elements are introduced for the short-term storage of the supplied biomass to be distributed and the uptake of nutrient-containing water, necessary for evapotranspiration and photosynthesis. The transition-oriented description of functionalities follows the essential causalities and balances of natural self-control. Implementation of the model is illustrated by a simple example.

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来源期刊

Hungarian Journal of Industry and Chemistry ENGINEERING, CHEMICAL-

自引率

50.00%

发文量

审稿时长

6 weeks