Requirements and Economic Implications of Integrating a PV-Plant-Based Energy System in the Dairy Production Process

AgriEngineering Pub Date : 2023-11-16 DOI:10.3390/agriengineering5040135

Martin Höhendinger, Hans-Jürgen Krieg, R. Dietrich, Stefan Rauscher, Christina Hartung, J. Stumpenhausen, Heinz Bernhardt

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Abstract

To expand the potential of renewable energies, energy storage is required to level peaks in energy demand and supply. The aim of the present study was to examine and characterize the energy consumption of a milk production system to find possibilities and boundaries for a self-sufficient energy system. A detailed quantification of energy production of the test farm and the consumption of the milk production system showed, that the total energy production could cover the energy consumption of the production process. However, the temporal distribution of energy production and consumption requires energy storage in the production process. Though ice bank milk cooling and water heating have the potential to cover parts of this storage capacity, battery storage is mandatory to enable full autarky. The consideration of different seasons leads to different optimal dimensions of the energy system. The energy price is decisive for profitability, both in the purchase and in the sale. Smaller energy systems are generally at an advantage due to the higher self-consumption quota.

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在奶制品生产过程中整合光伏发电系统的要求和经济意义

要扩大可再生能源的潜力，就需要储能来平抑能源需求和供应的峰值。本研究的目的是检查和描述牛奶生产系统的能源消耗情况，以找到自给自足能源系统的可能性和边界。对试验牧场的能源生产和牛奶生产系统的能源消耗进行的详细量化显示，总的能源生产可以满足生产过程的能源消耗。然而，能源生产和消耗的时间分布要求在生产过程中进行能源储存。虽然冰库牛奶冷却和水加热有可能满足部分储能需求，但电池储能是实现完全自给自足的必要条件。考虑到不同季节，能源系统的最佳尺寸也不同。无论是购买还是销售，能源价格都对盈利起着决定性作用。较小的能源系统通常具有优势，因为自耗配额较高。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

AgriEngineering

CiteScore

4.70

自引率

0.00%

发文量