The Combining Ability of Different Maize Hybrid Combinations and the Influencing Factors on Mechanical Grain Harvest Quality

doi:10.11923/j.issn.2095-4050.cjas2020-0146

Abstract

Abstract:

Mechanical grain harvest of maize is the development direction of China’ maize industry. The purpose of the study is to explore the combining ability of different maize inbred lines and the influence on the mechanical grain harvest quality of the hybrid combinations. Seven American inbred lines were used as female parent, five ‘Xin 01A3’ improved lines were used as male parent, incomplete diallel cross was adopted, and 35 maize hybrid combinations were used as materials. After mechanical grain harvest, the yield and grain moisture content were measured, and the impurity rate, broken rate, and the shatter loss rate were calculated. The combining ability of yield was analyzed. The results showed that the general combining ability of ‘XL2’ was the highest. Among the five male inbred lines, the general combining ability of ‘Xin A389’ was the highest, and that of ‘Xin 69’ was the second. The special combining ability of ‘XL6× Xin 69’ was the highest, and that of ‘XL7× Xin 3764’ was the second. The correlation of each character was analyzed, and the results showed that there was a significantly positive correlation between the broken rate and the moisture content. Among the 35 hybrid combinations, compared with the adjacent control, the yield of 32 maize hybrid combinations increased by more than 5%, and the grain moisture content of all hybrid combinations was lower than 28.0%, suggesting that these hybrid combinations were suitable for mechanical grain harvest. In the future, the utilization of high combining inbred lines ‘XL2’, ‘XL5’, ‘Xin A389’ and ‘Xin 69’ should be enhanced.

Key words: Maize, Mechanical Grain Harvest, General Combining Ability, Special Combining Ability, Hybrid Combination

CLC Number:

S513

WEI Feng, YANG Haifeng, WANG Jiamu, MA Yi, MA Junfeng, HONG Defeng, WEI Xiaoyi. The Combining Ability of Different Maize Hybrid Combinations and the Influencing Factors on Mechanical Grain Harvest Quality[J]. Journal of Agriculture, 2021, 11(12): 28-33.

Figures/Tables 8

References 21

[1]	李少昆, 王克如, 谢瑞芝, 等. 实施密植高产机械化生产实现玉米高产高效协同[J]. 作物杂志, 2016(4):1-6.
[2]	WAELTI H. Physical properties and morphological characteristics of maize and their influence on threshing injury of kernels[D]. Ames: Iowa State University, 1967.
[3]	WAELTI H, BUCHELE W F. Factors affecting corn kernel damage combine cylinders[J]. Transactions of the ASAE, 1969, 12(1):55-59.
[4]	DUTTA P K. Effects of grain moisture, drying methods, and variety on breakage susceptibility of shelled corns as measured by the Wisconsin Breakage Tester[D]. Ames: Iowa State University, 1986.
[5]	陈志. 玉米全价值收获关键技术与装备[M]. 北京: 科学出版社, 2014.
[6]	胡伟. 中国玉米收获机械化发展分析[J]. 农业技术与装备, 2008(1):16-17.
[7]	杨锦越, 宋碧, 罗英舰, 等. 不同玉米品种机械粒收质量评价及其鉴定指标初步筛选[J]. 河南农业科学, 2018, 47(11):25-31.
[8]	李少昆, 赵久然, 董树亭, 等. 中国玉米栽培研究进展与展望[J]. 中国农业科学, 2017, 50(11):1941-1959.
[9]	柳枫贺, 王克如, 李健, 等. 影响玉米机械收粒质量因素的分析[J]. 作物杂志, 2013(4):116-119.
[10]	YANG L, CUI T, QU Z, et al. Development and application of mechanized maize harvesters[J]. Int J Agric & Biol Eng, 2016, 9(3):15-28.
[11]	马延华, 孙德全, 李绥艳, 等. 20份玉米种质选系的利用潜力分析[J]. 玉米科学, 2014, 22(5):1-5.
[12]	孙海艳, 蔡一林, 王国强, 等. 10个玉米自交系穗部性状的配合力分析[J]. 玉米科学, 2006, 14(4):61-63.
[13]	福田雷沃国际重工股份有限公司, 中国农业机械化科学研究院, 黑龙江省农业机械试验鉴定站, 等. GB/T 21961-2008,玉米收获机械试验方法[S]. 北京: 中国标准出版社, 2008.
[14]	CHAUDHARY A I. Effect of grain moisture on efficiency of harvesting machinery for oats and corn[D]. Ames: Iowa State University, 1952.
[15]	ASHTARI A K. Effect of internal and external damage on deterioration rate of shelled corn[D]. Ames: Iowa State University, 1980.
[16]	PLETT S. Corn kernel breakage as a function of grain moisture at harvest in a prairie environment[J]. Canadian Journal of Plant Science, 1994, 74(3):543-544. doi: 10.4141/cjps94-097 URL
[17]	柳枫贺. 影响玉米机械收粒质量的主要因素研究[D]. 石河子:石河子大学, 2013.
[18]	董朋飞, 郭亚南, 王克如, 等. 玉米子粒耐破碎性及其评价与测试方法[J]. 玉米科学, 2018, 26(4):79-84.
[19]	卫晓轶, 魏锋, 洪德峰, 等. 黄淮海不同生态区玉米机械化粒收初步研究[J]. 河南农业科学, 2019, 48(11):40-44.
[20]	姜春雨, 李银昌, 杨锦忠, 等. 玉米脱粒破碎率关键影响因子及其最优预测模型研究[J]. 玉米科学, 2020, 28(3):142-147.
[21]	DUTTA P K. Effects of grain moisture, drying methods, and variety on breakage susceptibility of shelled corns as measured by the Wisconsin Breakage Tester[D]. Ames: Iowa State University, 1986.

编号	组合名称	编号	组合名称
CK1	郑单958	CK3	郑单958
1	XL1×新A389	19	XL5×新69
2	XL2×新A389	20	XL6×新69
3	XL3×新A389	21	XL7×新69
4	XL4×新A389	22	XL1×新ANA-4567
5	XL5×新A389	23	XL2×新ANA-4567
6	XL6×新A389	24	XL3×新ANA-4567
7	XL7×新A389	25	XL4×新ANA-4567
8	XL1×新4095	26	XL5×新ANA-4567
9	XL2×新4095	27	XL6×新ANA-4567
CK2	郑单958	CK4	郑单958
10	XL3×新4095	28	XL7×新ANA-4567
11	XL4×新4095	29	XL1×新3764
12	XL5×新4095	30	XL2×新3764
13	XL6×新4095	31	XL3×新3764
14	XL7×新4095	32	XL4×新3764
15	XL1×新69	33	XL5×新3764
16	XL2×新69	34	XL6×新3764
17	XL3×新69	35	XL7×新3764
18	XL4×新69	CK5	郑单958

编号	组合名称	编号	组合名称
CK1	郑单958	CK3	郑单958
1	XL1×新A389	19	XL5×新69
2	XL2×新A389	20	XL6×新69
3	XL3×新A389	21	XL7×新69
4	XL4×新A389	22	XL1×新ANA-4567
5	XL5×新A389	23	XL2×新ANA-4567
6	XL6×新A389	24	XL3×新ANA-4567
7	XL7×新A389	25	XL4×新ANA-4567
8	XL1×新4095	26	XL5×新ANA-4567
9	XL2×新4095	27	XL6×新ANA-4567
CK2	郑单958	CK4	郑单958
10	XL3×新4095	28	XL7×新ANA-4567
11	XL4×新4095	29	XL1×新3764
12	XL5×新4095	30	XL2×新3764
13	XL6×新4095	31	XL3×新3764
14	XL7×新4095	32	XL4×新3764
15	XL1×新69	33	XL5×新3764
16	XL2×新69	34	XL6×新3764
17	XL3×新69	35	XL7×新3764
18	XL4×新69	CK5	郑单958

月份	平均气温/℃	比历年相差/℃	降雨量/mm	日照时数/h
6月上旬	28.0	3.2	17.3	77.0
6月中旬	29.3	2.9	1.0	74.9
6月下旬	28.7	2.0	16.3	43.3
7月上旬	28.3	1.6	7.0	72.4
7月中旬	28.6	1.6	0.9	49.5
7月下旬	31.6	4.0	18.2	61.7
8月上旬	27.4	0.2	52.7	33.4
8月中旬	27.6	1.6	1.3	76.3
8月下旬	26.6	1.9	5.3	50.1
9月上旬	25.8	2.8	1.1	77.7
9月中旬	19.7	-1.6	76.8	14.1
9月下旬	22.9	3.2	0.0	95.0

月份	平均气温/℃	比历年相差/℃	降雨量/mm	日照时数/h
6月上旬	28.0	3.2	17.3	77.0
6月中旬	29.3	2.9	1.0	74.9
6月下旬	28.7	2.0	16.3	43.3
7月上旬	28.3	1.6	7.0	72.4
7月中旬	28.6	1.6	0.9	49.5
7月下旬	31.6	4.0	18.2	61.7
8月上旬	27.4	0.2	52.7	33.4
8月中旬	27.6	1.6	1.3	76.3
8月下旬	26.6	1.9	5.3	50.1
9月上旬	25.8	2.8	1.1	77.7
9月中旬	19.7	-1.6	76.8	14.1
9月下旬	22.9	3.2	0.0	95.0

性状	XL1	XL2	XL3	XL4	XL5	XL6	XL7
产量	-295.93	1895.87	-610.93	-495.43	1186.67	-1588.63	-91.63
子粒含水率	0.85	0.31	-1.43	1.05	-0.85	-0.05	0.15