Dairy Cow Thermal Balance Model During Heat Stress: Part 2. Model Assessment

IF 1.2 4区 农林科学 Q3 AGRICULTURAL ENGINEERING Journal of the ASABE Pub Date : 2023-01-01 DOI:10.13031/ja.15191
K. Janni, Chad R. Nelson, B. J. Heins, K. Sharpe
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Abstract

Highlights The thermal balance model body temperature and respiration rate results compared well with published data. Model results were commonly within one standard deviation of reported averages. Research that measures more model inputs, coefficients, and results is needed. The thermal balance model can be used to identify heat stress factors and assess mitigation practices. Abstract. A steady-state process-based lactating cow thermal balance spreadsheet model developed by Nelson and Janni (in press) was compared to mean measured body temperatures, respiration rates, and skin temperatures from two published studies (Gebremedhin et al., 2010; Chen et al., 2015). Model body temperatures were also compared with reticular temperatures from cows standing in unshaded paddocks that were part of a solar shade study (Sharpe et al., 2021). Gebremedhin et al. (2010) reported measured mean rectal temperatures, 39.4 ± 0.5 C and 40.6 ± 0.4 C for hot and dry conditions with and without a solar load; model body temperatures for similar hot and dry conditions were 39.7 C and 40.6 C with and without a solar load, respectively. Model respiration rates were within one standard deviation of measured mean respiration rates (Gebremedhin et al., 2010). The model body temperature for a baseline condition was 39.1°C, which was within 0.1°C of the mean baseline temperature of 39.2 ± 0.6°C (Chen et al., 2015). The model respiration rate was 63 breaths per minute (bpm); much lower than the reported baseline respiration rate of 88 bpm (Chen et al., 2015). Model body temperatures were 0.1°C to 0.7°C lower than the measured mean reticular temperatures of standing cows in non-shaded paddocks with solar loads when ambient temperatures ranged from 24.4°C to 26.5°C. Model results compared well with mean measured parameters from three studies. The model can be used to assess the impact of factors affecting heat exchange (e.g., body mass, milk yield, solar load, air dry-bulb temperature, dew-point temperature, and air velocity) on heat exchange flux, cow respiration rate, and body temperature. Keywords: Body temperature, Dairy, Heat stress, Lactating cow, Respiration rate, Thermal balance model.
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奶牛热应激过程中的热平衡模型:第2部分。模型评估
热平衡模型的体温和呼吸速率结果与已发表的数据比较良好。模型结果通常在报告平均值的一个标准差范围内。研究需要测量更多的模型输入、系数和结果。热平衡模型可用于确定热应力因素和评估缓解措施。摘要由Nelson和Janni(已出版)开发的基于稳态过程的泌乳奶牛热平衡电子表格模型与两项已发表的研究(Gebremedhin等人,2010;陈等人,2015)。模型体温还与奶牛站在无遮阳围场的网状温度进行了比较,这是遮阳研究的一部分(Sharpe et al., 2021)。Gebremedhin等人(2010)报告了在有和没有太阳能负荷的干热条件下测量的直肠平均温度,分别为39.4±0.5℃和40.6±0.4℃;在类似的炎热和干燥条件下,模型体温分别为39.7摄氏度和40.6摄氏度,有和没有太阳能负荷。模型呼吸速率在测量的平均呼吸速率的一个标准差内(Gebremedhin et al., 2010)。基线条件下的模型体温为39.1°C,与平均基线温度(39.2±0.6°C)相差0.1°C (Chen et al., 2015)。模型呼吸速率为63次/分钟(bpm);远低于报告的基线呼吸速率88 bpm (Chen et al., 2015)。当环境温度在24.4°C至26.5°C之间时,模型体温比无遮蔽围场中有太阳负荷的奶牛的平均网状温度低0.1°C至0.7°C。模型结果与三个研究的平均测量参数比较良好。该模型可用于评估影响热交换的因素(如体重、产奶量、太阳能负荷、空气干球温度、露点温度和风速)对热交换通量、奶牛呼吸速率和体温的影响。关键词:体温,奶牛,热应激,泌乳奶牛,呼吸速率,热平衡模型
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