高寒荒漠草原季节性放牧管理优化模拟研究

doi:10.3864/j.issn.0578-1752.2022.19.015

摘要/Abstract

摘要：

【目的】保护中国高寒荒漠草原的生态环境,指导草原牧区的全面可持续发展,从草畜平衡的角度为制定高寒荒漠草原牧区合理的放牧管理政策及实现牧草资源高效利用提供依据。【方法】根据季节性轮牧的特点和牲畜生产节律,考虑了草地资源的时空隔离和牲畜数量的动态变化,对暖季、冷季两个草场放牧时间段进行细化,在现有合理载畜量计算方法的基础上,以载畜量最大为目标,以动态草畜平衡为约束条件,以转场时间和出栏率为优化参数,建立了放牧-管理优化模型,并选取青海省乌兰县牧区作为高寒荒漠草原季节性牧区的典型代表,利用遗传算法寻优,确定乌兰县牧区丰、平、枯3种降水情景下最优放牧条件,进行草畜平衡优化模拟计算和动态草畜平衡分析,并与优化前进行对比。【结果】放牧-管理优化模型对牧区不同降水情景的模拟结果均较好。以未利用饲草量最低为依据,确定乌兰县牧区丰、平、枯3种降水情景下最优放牧条件分别为11月1日转场,出栏率43.4%、11月3日转场,出栏率38.2%和11月3日转场,出栏率36.7%,最优合理载畜量分别为109.92、96.14和83.64万标准羊单位,较优化前合理载畜量分别提高了11.75%、10.44%和10.43%;优化前后乌兰县牧区丰水年的合理载畜量分别为98.38和109.92万标准羊单位,比枯水年的75.74和83.64万标准羊单位的适宜承载量高30%,可见除牲畜出栏率和转场时间外,降水量也是影响牧区合理载畜量的重要因素;通过对牧区产草过程与牲畜动态需草过程的分析,进行乌兰县牧区平水年动态草畜平衡计算后发现,优化前冷季牧场可利用饲草不能被完全利用,放牧过程存在不合理之处,剩余草量超过6 130万kg,而优化后可利用饲草未充分利用问题得到有效解决,牧草资源得到高效利用,对于乌兰县整个牧区而言,调整放牧转场时间和牲畜出栏率是改良放牧制度的可靠方式;利用放牧-管理优化模型对牧区放牧过程进行优化,可以在保证牧区全年合理载畜量较高的同时,能够实现季节性轮牧区动态草畜平衡。【结论】放牧-管理优化模型对高寒荒漠草原季节性牧区的适用性较好,对轮牧区放牧管理过程调控和草畜平衡优化具有一定的优越性;放牧-管理优化模型可有效调控牧区载畜量,其优化结果可为制定合理的放牧制度提供参考,因此可将该模型用于优化单个牧户或牧场的放牧过程,得到单个牧户或牧场的最优放牧条件,从而制定相应的放牧制度,对单个牧户或牧场的生产实践工作更具有实际指导意义和可操作性。

关键词: 模型, 季节性轮牧, 动态草畜平衡, 放牧管理过程, 乌兰县

Abstract:

【Objective】In order to protect the ecological environment of China’s alpine desert steppe and guide the comprehensive and sustainable development of grassland pastoral areas, this study took the alpine desert steppe as the research object, and the optimization simulation calculation and dynamic balance analysis of grassland and livestock were carried out. 【Method】In this paper, based on the characteristics of seasonal rotational grazing and livestock production rhythms, the spatial and temporal segregation of grassland resources and the dynamic changes in livestock numbers were considered, and the two pasture grazing time periods of warm season and cold season were refined. On the basis of the existing reasonable livestock carrying capacity calculation method, the maximum livestock carrying capacity was the goal, the dynamic grass-livestock balance was the constraint, and the turnout time and slaughter rate were the optimization parameters. A grazing-management optimization model was established, and the Ulan County Pastoral area of Qinghai Province was selected as the typical representative of alpine desert seasonal pastoral area. Based on the genetic algorithm optimization, the optimal grazing conditions under the three precipitation scenarios of wet, normal and dry in the pastoral area of Ulan County were determined, a simulation to optimize the forage-livestock balance and dynamic forage-livestock balance analysis was carried out, and then the results with those before optimization were compared. 【Result】 The simulation results of the grazing-management optimization model were better for different precipitation scenarios in the grazing area. Based on the lowest amount of unutilized forage, the optimal grazing conditions under the three precipitation scenarios of wet, normal and dry in the pastoral area of Ulan County were determined to be the transition of livestocks on November 1 with a slaughter rate of 43.4%, the transition of livestocks on November 3 with a slaughter rate of 38.2% and the transition of livestocks on November 3 with a slaughter rate of 36.7%, respectively. The optimal proper carrying capacity was 1.099 million sheep unit, 0.961 million sheep unit and 0.836 million sheep unit in high, normal, and low flow years, respectively, which were 11.75%, 10.44% and 10.43% higher than the proper carrying capacity before optimization, respectively. In addition to the livestock slaughter rate and the transition time, the precipitation was also an important factor affecting the proper carrying capacity in pastoral areas. Before and after optimization, the proper carrying capacity of Ulan County’s pastoral area in wet years was 0.983 and 1.099 million sheep unit, respectively, which was 30% higher than the proper carrying capacity of 0.757 and 0.836 million sheep unit in dry years, respectively. Through the analysis of pasture grass production process and livestock dynamic grass demand process, the dynamic grass-livestock balance calculation for the normal flow year in the pasture area of Ulan County was found that the available forage in the cold season pasture before optimization could not be fully utilized, the grazing process was unreasonable, and the surplus grass amount was more than 61.3 million kg, while after optimization, the problem of underutilization of available forage was effectively solved and the forage resources were efficiently utilized. For the whole grazing area of Ulan County, the adjusting grazing turnout time and livestock slaughter rate was a reliable way to improve the grazing system. The grazing-management optimization model was used to optimize the grazing process in the grazing area, which could ensure the high proper annual carrying capacity in the grazing area while being able to achieve a dynamic grass-livestock balance in the seasonal grazing area. 【Conclusion】The grazing-management optimization had the good applicability to alpine desert seasonal pasturing areas and had the certain superiority in the regulation of grazing management process and the optimization of forage-livestock balance in rotating pastoral areas. The grazing-management optimization model could effectively regulate the livestock carrying capacity of a grazing area, and its optimization results could provide reference for the development of a reasonable grazing system. Therefore, the model could be used to optimize the grazing process of a single herding household or ranch, to obtain the optimal grazing conditions for a single herding household or ranch, so as to develop the corresponding grazing system, which was more practical guidance and operability for the production practice of a single herding household or ranch.

Key words: model, seasonal rotational grazing, dynamic forage-livestock balance, grazing management process, Ulan County

胡志强,宋孝玉,覃琳,刘辉. 高寒荒漠草原季节性放牧管理优化模拟研究[J]. 中国农业科学, 2022, 55(19): 3862-3874.

HU ZhiQiang,SONG XiaoYu,QIN Lin,LIU Hui. Study on Seasonal Grazing Management Optimal Model in Alpine Desert Steppe[J]. Scientia Agricultura Sinica, 2022, 55(19): 3862-3874.

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牧区 Pasturing area	暖季牧场 Warm season meadow		冷季牧场 Cold season meadow		人工草地 Artificial meadow
牧区 Pasturing area	面积 Area (10⁴hm²)	干草生产力 Grassland productivity (kg·hm^-2)	面积 Area (10⁴hm²)	干草生产力 Grassland productivity (kg·hm^-2)	面积 Area (hm²)	利用方式 Utilization method
希赛盆地 Xisai basin	17.4	1378.0	23.6	1383.2	1128.0	冷季补饲 Cold season supplementary feeding
茶卡盆地Chaka basin	3.5	1354.3	4.7	1384.3	405.3
合计 Total	17.0	1354.3	20.3	1384.3	1533.3

牧区 Pasturing area	降水频率 Rainfall frequency (%)	暖季牧场 Warm season meadow (10⁴kg)	冷季牧场 Cold season meadow (10⁴kg)	人工草地 Artificial meadow (10⁴kg)	合计 Total (10⁴kg)
希赛盆地 Xisai basin	25	20321	29509	1218	51048
	50	17983	26115		45316
	75	15646	22719		39583
茶卡盆地 Chaka basin	25	4019	5879	438	10336
	50	3555	5202		9195
	75	3093	4525		8056
合计 Total	25	24340	35388	1656	61384
	50	21538	31317		54511
	75	18739	27244		47639

降水频率 Rainfall frequency (%)	序号 Serial number		X₁ (d)	X₂ (%)	A (10⁴ sheep unit)	未利用饲草量 Unutilized forage (10⁴kg)	合理载畜量偏差计算 Carrying capacity deviation calculation (%)
25	优化前Before optimization		21	45.33	98.38	6742.8	\
	优化后 Optimized	①	0	43.40	109.92	2.8	11.75
		②	1	41.40	109.29	3.0	11.11
		③	2	39.40	108.65	3.3	10.46
		④	3	37.40	108.00	3.5	9.80
50	优化前Before optimization		21	45.33	87.05	6160.0	\
	优化后 Optimized	①	0	42.20	97.28	3.1	11.75
		②	1	40.20	96.72	1.3	11.11
		③	2	38.20	96.14	0.4	10.44
		④	3	36.20	95.56	1.6	9.78
75	优化前Before optimization		21	45.33	75.74	5571.6	\
	优化后 Optimized	①	0	40.60	84.62	3.8	11.72
		②	1	38.70	84.15	4.7	11.10
		③	2	36.70	83.64	1.2	10.43