黄淮海夏玉米品种脱水类型与机械粒收时间的确立

doi:10.3724/SP.J.1006.2018.01764

作物学报 ›› 2018, Vol. 44 ›› Issue (12): 1764-1773.doi: 10.3724/SP.J.1006.2018.01764

• 专题: 玉米籽粒脱水与机械收获研究 • 上一篇下一篇

黄淮海夏玉米品种脱水类型与机械粒收时间的确立

李璐璐,明博,谢瑞芝,王克如,侯鹏,李少昆()

中国农业科学院作物科学研究所 / 农业部作物生理生态重点实验室, 北京100081

收稿日期:2018-02-08 接受日期:2018-06-12 出版日期:2018-12-12 网络出版日期:2018-08-07
通讯作者: 李少昆
基金资助:
本研究由国家重点研发计划项目(2016YFD0300605);国家自然科学基金项目(31371575);国家现代农业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项目资助

Grain Dehydration Types and Establishment of Mechanical Grain Harvesting Time for Summer Maize in the Yellow-Huai-Hai Rivers Plain

Lu-Lu LI,Bo MING,Rui-Zhi XIE,Ke-Ru WANG,Peng HOU,Shao-Kun LI()

Institute of Crop Sciences, Chinese Academy of Agricultural Sciences / Key Laboratory of Crop Physiology and Ecology, Beijing 100081, China

Received:2018-02-08 Accepted:2018-06-12 Published:2018-12-12 Published online:2018-08-07
Contact: Shao-Kun LI
Supported by:
This study was supported by the National Key Research and Development Program of China(2016YFD0300605);the National Natural Science Foundation of China(31371575);the China Agriculture Research System(CARS-02-25);the Agricultural Science and Technology Innovation Project of Chinese Academy of Agricultural Sciences

摘要/Abstract

摘要：

黄淮海一年两熟模式下玉米成熟和熟后籽粒脱水的热量资源紧缺, 是制约机械粒收在该区域发展的关键因素。本文尝试建立黄淮海一年两熟制地区玉米机械粒收适宜品种筛选和以授粉至生理成熟积温和生理成熟期籽粒含水率为指标, 运用双向平均法将参试品种划分为晚熟高含水率(I)、早熟高含水率(II)、早熟低含水率(III)和晚熟低含水率(IV)4种类型。基于玉米生长进程及籽粒含水率动态测试, 估算不同品种播种至适宜机械粒收含水率(28%、25%)所需活动积温, 以黄淮海区夏玉米常年播种日期为起点, 结合历史气象资料的累积计算, 利用地统计分析技术明确不同类型品种适宜机械粒收的时空分布规律, 建立适宜机械粒收时期的预测方法, 为机械粒收在黄淮海区域推广提供指导。选择27个主推品种, 播种至籽粒含水率下降到28%、25%所需要积温分别为, 类型I 2982°C d、3118°C d, 类型II 2770°C d、2873°C d, 类型III 2729°C d、2845°C d, 类型IV 2860°C d、2980°C d。类型III品种降至28%、25%含水率时间分别较类型II品种早2~3 d、约2 d, 较类型IV品种早7~9 d、7~10 d, 较类型I品种早13~17 d、16~17 d。各类型品种籽粒由28%含水率降至25%水平, 所需时间约6~8 d。在当前玉米种植模式及下茬小麦适期播种条件下, 黄淮海南部的豫南、皖北地区, 各类玉米品种均能满足籽粒脱水至适宜机械粒收含水率的要求, 而在黄淮海北部、关中西部以及山东半岛地区, 现有品种很难降至适宜含水率, 需通过选择早熟和籽粒脱水快的适宜品种加以实现。本研究建立的以积温预测籽粒含水率动态变化及其适宜机械粒收时间的预测方法, 为各地合理配置玉米粒收品种、确定适宜机械粒收时间提供了可行的技术方法。

关键词: 玉米, 籽粒含水率, 脱水类型, 粒收时期, 空间分布

Abstract:

The wheat-maize double cropping system limits the heat resources of maize ripening and dewatering, which is the key factor to restrict the development of mechanical grain harvesting in the Yellow-Huai-Hai Rivers Plain. In this paper, methods of the optimum cultivar selection and harvesting time forecast were established to provide guidance for the promotion of mechanical grain harvesting in the double cropping system of the Yellow-Huai-Hai Rivers Plain. Twenty-seven main planting cultivars were selected and divided into four types by using the two-way average method. This method based on two parameters including the accumulated temperature from pollination to physiological maturity and the grain moisture content at physiological maturity. These four types were the later maturing and higher moisture content (I), the earlier maturing and higher moisture content (II), the earlier maturing and lower moisture content (III) and the later maturing and lower moisture content (IV). When grain moisture content reduced to 28% and 25% (suitable for mechanical grain harvesting) the cultivars’ active accumulated temperatures were simulated based on measurements of vegetative growth stage and dynamic change of grain moisture. According to the accumulated temperature and the historical meteorological data, the suitable days for mechanical grain harvesting of different cultivar types were estimated by using the geostatistical analysis method based on the starting points of normal sowing dates in the Yellow-Huai-Hai Rivers Plain, thus establishing the prediction method of optimum dates for mechanical grain harvesting. The accumulated temperatures from sowing to the time reaching grain moisture of 28% and 25% were 2982°C d and 3118°C d (I), 2770°C d and 2873°C d (II), 2729°C d and 2845°C d (III), and 2860°C d and 2980°C d (IV), respectively. The time for the type III cultivar with 28% and 25% moisture content respectively was two to three days and about two days earlier than that for the type II cultivar, seven to nine days and seven to ten days earlier than that for the IV type cultivar, and thirteen to seventeen days and sixteen to seventeen days earlier than that for the type I cultivar. All types of cultivar needed six to eight days to reduce grain moisture from 28% to 25%. Under the current maize cropping pattern and the sowing date of following wheat, all maize cultivars could be planted for mechanical grain harvesting in southern Henan and northern Anhui provinces in the southern Yellow-Huai-Hai Rivers Plain, while no cultivars could be used in the northern Yellow-Huai-Hai Rivers Plain, Guanzhong Area, and Shandong Peninsula where the mechanical grain harvesting of summer maize should be realized by selecting cultivar with the shorter maturing date and the rapid dehydration characteristic. In this study, the method to predict the dynamic change of grain moisture content and the optimum time of mechanical grain harvesting was established by the accumulated temperature. This method provides a feasible technical means for rationally distributing the grain harvesting cultivars and determining the suitable harvesting time.

Key words: maize, grain moisture content, dehydration types, grain harvesting time, spatial distribution

李璐璐,明博,谢瑞芝,王克如,侯鹏,李少昆. 黄淮海夏玉米品种脱水类型与机械粒收时间的确立[J]. 作物学报, 2018, 44(12): 1764-1773.

Lu-Lu LI,Bo MING,Rui-Zhi XIE,Ke-Ru WANG,Peng HOU,Shao-Kun LI. Grain Dehydration Types and Establishment of Mechanical Grain Harvesting Time for Summer Maize in the Yellow-Huai-Hai Rivers Plain[J]. Acta Agronomica Sinica, 2018, 44(12): 1764-1773.

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		日期 Date (month/day)
		6/1-6/30	7/1-7/31	8/1-8/31	9/1-9/30	10/1-10/31	11/1-11/30
2014北京 2014 Beijing	积温 Accumulated temperature (°C)	752.1	870.0	814.6	629.1	434.7
2014北京 2014 Beijing	降水Precipitation (mm)	91.8	119.8	50.1	127.6	12.0
2015河南新乡 2015 Xinxiang, Henan	积温 Accumulated temperature (°C)	799.6	862.0	827.7	662.9	510.6	192.5
2015河南新乡 2015 Xinxiang, Henan	降水Precipitation (mm)	87.7	77.2	115.0	39.6	36.3	57.6
2016河南新乡 2016 Xinxiang, Henan	积温 Accumulated temperature (°C)	796.3	876.9	850.2	712.5	504.8
2016河南新乡 2016 Xinxiang, Henan	降水Precipitation (mm)	136.7	552.3	95.9	32.0	66.4

年份Year	品种 Hybrid
2014	郑单958, 先玉335, 华美1号, KWS1568, KX9384, 先玉696, 真金8号, 中种8号, 迪卡519 Zhengdan 958 (ZD958), Xianyu 335 (XY335), Huamei 1 (HM1), KWS1568, KX9384, Xianyu 696 (XY696), Zhenjin 8 (ZJ8), Zhongzhong 8 (ZZ8), Dika519 (DK519)
2015	郑单958, 先玉335, 农华101, 农华816, 京农科728, 中单909, 宁玉721, 联创808, 裕丰303, 中科玉505, 禾田1号 Zhengdan 958 (ZD958), Xianyu 335 (XY335), Nonghua 101 (NH101), Nonghua 816 (NH816), Jingnongke 728 (JNK728), Zhongdan 909 (ZD909), Ningyu 721 (NY721), Lianchuang 808 (LC808), Yufeng 303 (YF303), Zhongkeyu 505 (ZKY505), Hetian1 (HT1)
2016	郑单958, 先玉335, 农华101, 农华816, 京农科728, 中单909, 华美1号, 真金323, 新单58, 新单65, 辽单575, 锦华318, 锦华207, 金通152, 迪卡517, 陕单636, 丰垦139 Zhengdan 958 (ZD958), Xianyu 335 (XY335), Nonghua 101 (NH101), Nonghua 816 (NH816), Jingnongke 728 (JNK728), Zhongdan 909 (ZD909), Huamei 1 (HM1), Zhenjin 323 (ZJ323), Xindan 58 (XD58), Xindan 65 (XD65), Liaodan 575 (LD575), Jinhua 318 (JH318), Jinhua 207 (JH207), Jintong 152 (JT152), Dika 517 (DK517), Shaandan 636 (SD636), Fengken 139 (FK139)

类型 Type	品种 Hybrid	播种-出苗^§ Sowing-Emergence	出苗-吐丝^§ Emergence-Silking	授粉-生理成熟^§ P-PM	授粉-28%^# P-28% MC	授粉-25%^# P-25% MC
I	ZD909(2015)	191	1276	1439	1453	1594
	XY335(2014)	169	1318	1446	1362	1446
	ZD958(2016)	116	1464	1501	1505	1664
	ZD909(2016)	116	1435	1501	1526	1684
II	DK519(2014)	169	1289	1334	1291	1370
	KWS1568(2014)	169	1347	1337	1322	1398
	ZJ8(2014)	169	1159	1394	1372	1470
	ZZ8(2014)	169	1289	1394	1382	1473
	ZD958(2014)	169	1456	1366	1431	1544
	HT1(2015)	191	1116	1166	1140	1221
	JNK728(2015)	191	1221	1200	1249	1354
	NH101(2015)	191	1276	1365	1331	1436
	NH816(2015)	191	1304	1316	1363	1474
	FK139(2016)	116	1215	1179	1293	1411
	HM1(2016)	116	1279	1344	1331	1436
	XD58(2016)	116	1279	1394	1388	1521
	ZJ323(2016)	116	1403	1389	1410	1544
III	KX9384(2015)	169	1120	1257	1065	1156
	JNK728(2016)	116	1310	1291	1260	1369
	NH816(2016)	116	1403	1389	1356	1476
	XD65(2016)	116	1371	1400	1332	1461
	LD575(2016)	116	1403	1389	1394	1528
IV	HM1(2014)	169	1158	1472	1447	1526
	XY696(2014)	169	1151	1533	1534	1627
	ZKY505(2015)	191	1304	1410	1307	1417
	LC808(2015)	191	1304	1439	1349	1465
	XY335(2015)	191	1276	1475	1348	1468
	NY721(2015)	191	1304	1485	1431	1575
	ZD958(2015)	191	1276	1475	1446	1599
	YF303(2015)	191	1276	1553	1489	1630
	DK517(2016)	116	1371	1443	1293	1412
	NH101(2016)	116	1371	1421	1345	1459
	JH207(2016)	116	1403	1457	1314	1434
	JT152(2016)	116	1403	1457	1363	1479
	XY335(2016)	116	1435	1490	1361	1483
	SD636(2016)	116	1310	1459	1417	1540
	JH318(2016)	116	1371	1553	1443	1580

黄淮海夏玉米品种脱水类型与机械粒收时间的确立

Grain Dehydration Types and Establishment of Mechanical Grain Harvesting Time for Summer Maize in the Yellow-Huai-Hai Rivers Plain

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类型 Type	播种-生理成熟 Sowing-PM	播种-28%含水 Sowing-28% MC	播种-25%含水 Sowing-25% MC
I	2993	2982	3118
II	2760	2770	2873
III	2793	2729	2845
IV	2942	2860	2980