从环境变量获得黑球温度的另一种形式。

Q2 Agricultural and Biological Sciences

Agronomy research Pub Date : 2019-01-01 DOI:10.15159/AR.19.109

R. R. Andrade, M. Barbari, L. Conti, I. Tinôco, F. C. Baêta, C. T. Junior, H. H. Zanetoni, M. O. Vilela, G. Rossi

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引用次数: 6

摘要

达到动物的热舒适条件是提高动物福利和获得良好生产性能的必要条件。因此，农民需要工具来监测谷仓内的小气候情况。黑球湿度指数(BGHI)作为生产者管理工具，协助管理热环境和决策如何保护动物免受热应激。这项工作的目的是建立一个数学模型，从空气温度、相对湿度和空气速度开始估计黑球温度。为了实现这一目标，在记录传感器的帮助下，采集了空气温度和湿度数据。用黑铜球温度计测量黑球温度，用热线风速计监测空气速度。使用回归模型对数据进行分析，以预测黑球温度作为监测的其他变量的函数。根据回归和回归参数的显著性以及决定系数(R2)对模型进行评价。该模型可以很好地估计黑球温度，R2 = 0.9166，回归及其参数显著(p < 0.05)。模型的误差百分比较低(约2.2%)。综上所述，模型估计的数据与标准黑球温度计获得的数据之间具有高度的相关性。

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Alternative form to obtain the black globe temperature from environmental variables.

Reaching thermal comfort conditions of animals is essential to improve well-being and to obtain good productive performance. For that reason, farmers require tools to monitor the microclimatic situation inside the barn. Black Globe-Humidity Index (BGHI) acts as a producer management tool, assisting in the management of the thermal environment and in decision making how protect animals from heat stress. The objective of this work was to develop a mathematical model to estimate the black globe temperature starting from air temperature, relative humidity and air velocity. To reach this goal, data of air temperature and humidity were collected, with the aid of recording sensors. The black globe temperature was measured with a black copper globe thermometer and the air velocity was monitored with a hot wire anemometer. Data were analysed using a regression model to predict the black globe temperature as a function of the other variables monitored. The model was evaluated, based on the significance of the regression and the regression parameters, and the coefficient of determination (R2). The model proved to be adequate for the estimation of the black globe temperature with R2 = 0.9166 and the regression and its parameters being significant (p < 0.05). The percentage error of the model was low (approximately 2.2%). In conclusion, a high relation between the data estimated by the model with the data obtained by the standard black globe thermometer was demonstrated.

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来源期刊

Agronomy research Agricultural and Biological Sciences-Agronomy and Crop Science

CiteScore

2.10

自引率

0.00%

发文量

审稿时长

7 weeks

期刊介绍： Agronomy Research is a peer-reviewed international Journal intended for publication of broad-spectrum original articles, reviews and short communications on actual problems of modern biosystems engineering including crop and animal science, genetics, economics, farm- and production engineering, environmental aspects, agro-ecology, renewable energy and bioenergy etc. in the temperate regions of the world.