通过种植制度改革实现黄淮海北部地区玉米机械籽粒直收

doi:10.3864/j.issn.0578-1752.2023.19.007

中国农业科学 ›› 2023, Vol. 56 ›› Issue (19): 3788-3798.doi: 10.3864/j.issn.0578-1752.2023.19.007

• 耕作栽培·生理生化·农业信息技术 • 上一篇下一篇

通过种植制度改革实现黄淮海北部地区玉米机械籽粒直收

侯梁宇¹(), 张镇涛²(), 黄兆福¹, 李璐璐¹, 郭亚南¹, 明博¹, 谢瑞芝¹, 侯鹏¹, 薛军¹, 王克如¹(), 李少昆¹()

¹ 中国农业科学院作物科学研究所/农业农村部作物生理生态重点实验室，北京 100081
² 中国农业大学资源与环境学院，北京 100193

收稿日期:2021-11-28 接受日期:2022-01-24 出版日期:2023-10-01 发布日期:2023-10-08
通信作者:
王克如，E-mail：wkeru01@163.com。
李少昆，E-mail：lishaokun@caas.cn
联系方式: 侯梁宇，E-mail：105948179@qq.com。张镇涛，E-mail：zhangzhentao@cau.edu.cn。侯梁宇和张镇涛为同等贡献作者。
基金资助:
国家重点研发计划(2016YFD0300605); 国家自然科学基金(31371575); 国家自然科学基金(31360302); 国家玉米产业技术体系建设专项(CARS-02-25); 中国农业科学院农业科技创新工程

Reforming the Cropping System to Achieve Maize Mechanical Grain Harvesting in Northern Huang-Huai-Hai Area of China

HOU LiangYu¹(), ZHANG ZhenTao²(), HUANG ZhaoFu¹, LI LuLu¹, GUO YaNan¹, MING Bo¹, XIE RuiZhi¹, HOU Peng¹, XUE Jun¹, WANG KeRu¹(), LI ShaoKun¹()

¹ Institute of Crop Sciences, Chinese Academy of Agricultural Sciences/Key Laboratory of Crop Physiology and Ecology, Ministry of Agriculture and Rural Affairs, Beijing 100081
² College of Environment and Resources, China Agricultural University, Beijing 100193

Received:2021-11-28 Accepted:2022-01-24 Published:2023-10-01 Online:2023-10-08

摘要/Abstract

摘要：

【目的】机械粒收是玉米收获技术发展的方向。在“冬小麦-夏玉米”一年两季轮作种植制度下，黄淮海北部地区热量资源不足，玉米生长季节有限，收获时籽粒含水率高，难以进行机械粒收，是世界上玉米机械粒收技术应用难度最大的区域，探索玉米机械粒收的可行性对推动区域玉米生产全程机械化和玉米产业提质增效、提升竞争力具有重要意义。【方法】2016—2017年在新乡、2018年在北京分别对郑单958、先玉335、迪卡517、京农科728和丰垦139等不同熟期品种的籽粒脱水积温需求进行系统观测；利用黄淮海北部地区近10年气象数据，以冬前预留500 ℃·d积温为小麦适宜播期，按玉米生长季节活动积温（≥0 ℃）100 ℃为梯度，将其划分为7个积温带；将区域热量资源条件和不同品种籽粒脱水积温需求进行定量匹配分析。【结果】在玉米正常夏播条件下，随着品种熟期提早，各供试品种在黄淮海北部地区达到生理成熟并且可以实现粒收的区域逐渐向北扩展，一般比小麦适宜播期推迟5—10 d，但是区域内北端和西端的积温带Ⅰ—Ⅲ（1 900— 2 800 ℃·d）的热量资源仍无法满足熟期较早的京农科728和丰垦139籽粒含水率下降至25%甚至是达到生理成熟的积温需求。将冬小麦-夏玉米一年两熟改为夏玉米-春玉米-冬小麦两年三熟制后，玉米春播和夏播各供试品种籽粒含水率都能下降至25%以下实现机械粒收，如果选择熟期较早的品种，在冬小麦或春玉米播种前还可以通过田间站秆脱水延迟收获，使籽粒含水率进一步降至20%以下，提高粒收质量，降低烘干成本。【结论】通过种植制度改革可以有效解决黄淮海北部地区玉米生长季节热量不足、收获时期含水率过高导致的玉米成熟度差、容重低、易霉变和机械粒收难度大的问题，实现提质增效。

关键词: 黄淮海北部地区, 热量资源, 玉米, 籽粒含水率, 种植制度, 机械粒收

Abstract:

【Objective】Mechanical grain harvesting is the development direction of maize harvesting technique, however, under a crop rotation system of winter wheat and summer maize, which is hardly to be achieved in China, resulting from insufficient heat resource in limited growing season for maize. So far, the northern Huang-Huai-Hai area is the area where the mechanical grain harvesting for maize is most difficult to be applied and spread all over the world. Thus, a study on the feasibility of corn’s mechanical grain harvesting is considerably significant to the whole-process mechanization, quality, proceeds and industrial competitiveness of corn production in Huang-Huai-Hai area.【Method】 In northern Huang-Huai-Hai area, the dynamic observation for the accumulated temperature requirements for grain dehydration of 5 maize cultivars with different physiological maturity, including Zhengdan958, Xianyu335, Dika517, Jingnongke728 and Fengken139, were designed in Xiangxiang, Henan province from 2016 to 2017 and then in Beijing, in 2018 respectively. Then, based on the meteorological data from 2007 to 2018, after reserving 500 ℃·d for winter wheat growth, the northern Huang-Huai-Hai area was divided into 7 accumulated temperature zones according to a temperature gradient of 100 ℃, so as to spatially illustrate the heat resource distribution during maize growth season in this area. Hence, the different cultivars’ accumulated temperature requirements for grain dehydration were mapped under the heat resource distribution in this area. 【Result】 Under the conventional sowing condition of summer maize, each cultivar’s coverage that mechanical grain harvesting could be achieved after physiological maturity, with the advance of maturity, which were gradually extended northwardly, commonly 5-10 d later than the current sowing time for winter wheat in northern Huang-Huai-Hai area. However, the heat resource of accumulated temperature zonesⅠ-Ⅲ (1 900-2 800 ℃·d) were still hardly able to meet the requirements of Jingnongke728 and Fengken139 for a relative earlier physiological maturity than other 3 tested cultivars, not to metion reaching a grain moisture content of 25%. When the double cropping per year (winter wheat-summer maize) was reformed into the triple cropping per 2 years (summer maize-spring maize-winter wheat), the grain moisture content of all the tested cultivars, no matter planted in spring or summer, could reach 25% even less, achieving mechanical grain harvesting. Besides, for early-matured cultivars, by drying in filed and delaying harvesting, their moisture content might reach below 20% before winter wheat’s sowing, thus not only elevating harvesting quality, but also cutting drying costs.【Conclusion】In Northern Huang-Huai-Hai area, the problem, hindering maize production that insufficient heat resource in limited growing season issues in the difficult achievement of mechanical grain harvesting, could be effectively solved by reforming the current cropping system. Meanwhile, it also might provide a new horizon with theoretical foundation for the application of maize mechanical grain harvesting, further improving the quality and efficiency of maize production in Northern Huang-Huai-Hai area.

Key words: Northern Huang-Huai-Hai area of China, heat resource, maize, grain moisture content, cropping system, mechanical grain harvesting

侯梁宇, 张镇涛, 黄兆福, 李璐璐, 郭亚南, 明博, 谢瑞芝, 侯鹏, 薛军, 王克如, 李少昆. 通过种植制度改革实现黄淮海北部地区玉米机械籽粒直收[J]. 中国农业科学, 2023, 56(19): 3788-3798.

HOU LiangYu, ZHANG ZhenTao, HUANG ZhaoFu, LI LuLu, GUO YaNan, MING Bo, XIE RuiZhi, HOU Peng, XUE Jun, WANG KeRu, LI ShaoKun. Reforming the Cropping System to Achieve Maize Mechanical Grain Harvesting in Northern Huang-Huai-Hai Area of China[J]. Scientia Agricultura Sinica, 2023, 56(19): 3788-3798.

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生育期 Growth stage	年份 Year	参试品种Tested cultivar
生育期 Growth stage	年份 Year	郑单958 ZD958	先玉335 XY335	迪卡517 DK517	京农科728 JNK728	丰垦139 FK139
播种日期 Sowing date (M-D)	2016	06-04	06-04	06-04	06-04	06-04
	2017	06-18	06-18	06-18	06-18	—
	2018	05-15	05-15	05-15	05-15	05-15
吐丝日期 Silking date (M-D)	2016	07-31	07-30	07-28	07-26	07-23
	2017	08-10	08-08	08-05	08-07	—
	2018	07-12	07-10	07-10	07-10	07-05
黑层出现日期 Black-layer appearing date (M-D)	2016	09-28	09-26	09-21	09-12	09-05
	2017	10-26	10-15	10-14	10-01	—
	2018	09-11	09-03	09-03	08-30	08-26
25%籽粒含水率达到日期 Date when 25% grain moisture reached (M-D)	2016	10-13	10-07	09-25	09-17	09-16
	2017	11-06	10-24	10-18	10-19	—
	2018	09-24	09-13	09-08	09-03	09-05
20%籽粒含水率达到日期 Date when 20% grain moisture reached (M-D)	2016	10-25	10-13	10-02	09-25	09-23
	2017	11-13	10-29	10-27	10-30	—
	2018	10-05	09-16	09-13	09-11	09-09

生育阶段 Growth stage	年份 Year	参试品种Tested cultivar
生育阶段 Growth stage	年份 Year	郑单958 ZD958	先玉335 XY335	迪卡517 DK517	京农科728 JNK728	丰垦139 FK139
播种-生理成熟 Sowing-physiological maturity (℃·d)	2016	3130.7	3090.8	2922.2	2766.7	2685.3
	2017	3235.9	3069.4	2975.8	2856.8	—
	2018	3205.5	3015.8	3015.8	2916.3	2809.9
均值 Mean (℃·d)		3190.7	3058.7	2971.3	2846.6	2747.6
播种-25%籽粒含水率 Sowing-25% grain moisture (℃·d)	2016	3367.6	3157.5	2977.3	2818.4	2765.6
	2017	3459.5	3185.6	3058.6	3014.9	—
	2018	3479.7	3251.3	3138.8	3015.3	3067.5
均值 Mean (℃·d)		3435.6	3198.1	3058.2	2949.5	2916.55
播种-20%籽粒含水率 Sowing-20% grain moisture (℃·d)	2016	3608.9	3312.5	3170.7	3046.3	3014.7
	2017	3899.9	3318.8	3353.7	3301.5	—
	2018	3675.4	3545.7	3251.2	3205.3	3160.7
均值 Mean (℃·d)		3728.1	3392.3	3258.5	3184.4	3087.7

通过种植制度改革实现黄淮海北部地区玉米机械籽粒直收

Reforming the Cropping System to Achieve Maize Mechanical Grain Harvesting in Northern Huang-Huai-Hai Area of China

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