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Acta Agronomica Sinica ›› 2018, Vol. 44 ›› Issue (12): 1764-1773.doi: 10.3724/SP.J.1006.2018.01764

• SPECIAL SECTION: GRAIN DEHYDRATION AND MECHANICAL GRAIN HARVEST OF MAIZE • Previous Articles     Next Articles

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()   

  1. 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 Online:2018-12-12 Published:2018-08-07
  • Contact: Shao-Kun LI E-mail:lishaokun@caas.cn
  • 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

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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

Table 1

Temperature and precipitation during the experiment"

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
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
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
降水Precipitation (mm) 136.7 552.3 95.9 32.0 66.4

Table 2

Hybrids weed in the experiment"

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)

Fig. 1

Relationships between grain moisture at physiological maturity and accumulated temperature during filling period Abbreviations of hybrids are the same as those given in Table 2."

Table 3

Demands for accumulated temperature at different stages of different maize varieties (°C d)"

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

Table 4

Demands for accumulated temperature at different stages of different maize types (°C d)"

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

Fig. 2

Interpolation result of summer maize sowing period The black dots represent the location of the county used for spatial interpolation (n=96)."

Fig. 3

Distribution of mechanical harvesting time when grain moisture content reduces to 28% for different summer maize types in the Yellow-Huai-Hai Rivers Plain"

Fig. 4

Distribution of mechanical harvesting time when grain moisture content reduces to 25% for different summer maize types in the Yellow-Huai-Hai Rivers Plain"

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Wang H X . Study on Resource-saving Cropping Systems in Northern Region of Huang-Huai-Hai Plain. MS Thesis of Chinese Academy of Agricultural Sciences, Beijing,China, 2011 (in Chinese with English abstract)
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