Harmonic Growth—The Harmonic Number Applied to ROI, Business Scaling, Nth Plant Economics, Micro Combined Heat and Power (mCHP), Biorefineries, and Biochar Production

IF 1.8 3区数学 Q1 MATHEMATICS, APPLIED

Mathematical Methods in the Applied Sciences Pub Date : 2025-08-10 DOI:10.1002/mma.11156

Micah N. Jasper

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引用次数: 0

Abstract

Scaling is a topic of utmost importance in business. When to scale and how has been the subject of countless books and seminars. This paper looks at modular businesses that have income and costs directly proportional to the number of units. This work assumes that all of the plants or units have the same capital cost, operating costs, and revenue and that the company reinvests all net profit into purchasing more units. Furthermore, this model ignores depreciation, inflation, fluctuating market prices, and market saturation. With these assumptions, the question of when the company can afford to scale and purchase the next unit is directly related to the payback period and the harmonic number. This work describes a novel growth function called the harmonic growth function based on harmonic numbers. This function is related to the standard ROI. The harmonic growth function is explained and applied to a micro combined heat and power (mCHP) station, a biomass company expanding the number of biorefineries, and biochar retort kilns for biochar production.

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谐波增长-谐波数应用于投资回报率，业务规模，第n工厂经济，微型热电联产（mCHP），生物炼制和生物炭生产

规模是商业中最重要的话题。何时扩大规模以及如何扩大规模一直是无数书籍和研讨会的主题。本文着眼于收入和成本与单元数量成正比的模块化业务。这项工作假设所有的工厂或单位具有相同的资本成本、运营成本和收入，并且公司将所有净利润再投资于购买更多的单位。此外，该模型忽略了贬值、通货膨胀、波动的市场价格和市场饱和。有了这些假设，公司何时能够负担得起规模和购买下一个单位的问题与投资回收期和谐波数直接相关。本文描述了一种新的生长函数，即基于调和数的调和生长函数。此功能与标准ROI相关。解释了谐波生长函数，并将其应用于微型热电联产（mCHP）站、扩大生物精炼厂数量的生物质公司和用于生物炭生产的生物炭蒸馏窑。

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来源期刊

Mathematical Methods in the Applied Sciences 数学-应用数学

CiteScore

4.90

自引率

6.90%

发文量

798

审稿时长

6 months

期刊介绍： Mathematical Methods in the Applied Sciences publishes papers dealing with new mathematical methods for the consideration of linear and non-linear, direct and inverse problems for physical relevant processes over time- and space- varying media under certain initial, boundary, transition conditions etc. Papers dealing with biomathematical content, population dynamics and network problems are most welcome. Mathematical Methods in the Applied Sciences is an interdisciplinary journal: therefore, all manuscripts must be written to be accessible to a broad scientific but mathematically advanced audience. All papers must contain carefully written introduction and conclusion sections, which should include a clear exposition of the underlying scientific problem, a summary of the mathematical results and the tools used in deriving the results. Furthermore, the scientific importance of the manuscript and its conclusions should be made clear. Papers dealing with numerical processes or which contain only the application of well established methods will not be accepted. Because of the broad scope of the journal, authors should minimize the use of technical jargon from their subfield in order to increase the accessibility of their paper and appeal to a wider readership. If technical terms are necessary, authors should define them clearly so that the main ideas are understandable also to readers not working in the same subfield.