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1、Original Article Effects of operating factors for an axial-fl ow corn shelling unit on losses and power consumption Waree Srison,a, b Somchai Chuan-Udom,a, b,* Khwantri Saengprachatanaraka, b aDepartment of Agricultural Engineering, Faculty of Engineering, Khon Kaen University, Khon Kaen 40002, Thai

2、land bApplied Engineering for Important Crops of the North East Research Group, Khon Kaen University, Khon Kaen 40002, Thailand a r t i c l e i n f o Article history: Received 20 August 2015 Accepted 2 May 2016 Available online 26 December 2016 Keywords: Corn shelling unit Moisture content Feed rate

3、 Rotor speed a b s t r a c t The operating factors were studied for an axial-fl ow corn shelling unit that affected losses and power consumption. The shelling unit was 0.90 m long, with a diameter toward the end of the peg tooth of 0.30 m. The factors comprised three levels of moisture content (MC),

4、 three levels of feed rate (FR), and three levels of rotor speed (RS). The experiments were conducted based on response surface method- ology and 23 factorial designs. The results of this study indicated that the MC signifi cantly affected grain breakage and power consumption, but did not affect she

5、lling unit losses. Increasing the MC increased both the grain breakage and power consumption. The FR affected the power consumption but did not affect shelling unit losses and grain breakage. Increasing the FR increased the power consumption. The RS had a signifi cant impact on the shelling unit los

6、ses, grain breakage and power consumption. Increasing the RS increased the grain breakage and power consumption, but decreased the shelling unit losses. Empirical models were formulated based on multiple linear models. Production and hosting by Elsevier B.V. on behalf of Kasetsart University. This i

7、s an open access article under the CC BY-NC-ND license (/licenses/by-nc-nd/4.0/). Introduction Corn is a feed raw material and is important for the livestock industry (Farjam et al., 2014). Corn production is based on its va- rietyand, additionally,the harvesting mechanism i

8、s oneof themost important components in corn production processes (Reference) (Chuan-Udom, 2013). Kunjara et al. (1998) discussed corn shelling in Thailand from which the following information is sourced. Corn shelling has been used and modifi ed since 1929. The development of corn sheller equipment

9、 was mostly conducted by local manufacturers, with the most corn shellers used for de-husking being the rasp bar sheller and peg-tooth sheller. These shellers have been tested and evalu- ated to determine their best operational performance until the accumulative losses (grain losses and grain breaka

10、ge) were less than 1.5%. Nevertheless, with a rasp bar sheller, it was found that broken crop components remaining on the concave surfaces reduced the effectiveness of grain separation, while the power consumption and shelling drum speed of the peg-teeth sheller were double that of the rasp bar shel

11、ler (Kunjara et al., 1998). A shelling unit for corn husker shelling was originally developed based on a wheat threshing unit, which was effi cient but the grain breakage was relatively high (Department of Agriculture, 1996). Chuan-Udom (2013) studied the operating factors of Thai threshers affectin

12、g corn shelling losses and found that an axial fl ow rice thresher was highly effi cient and easy to clean, with little grain breakage, with the adjustment to shell corns being economical and requiringonlyeasy modifi cation. Moreover, the principle of an axial fl ow shelling unit is suitable for Tha

13、iland and conditions in Asian countries (Singhal and Thierstein, 1987; Chuan-Udom, 2011). The study of the operations and adjustments of the Thai, axial fl ow, rice combine harvester by Chuan-Udom and Chinsuwan (2009) showed that the rotor speed, guide vane inclination, grain moisture content, feed

14、rate and grain material other than grain had signifi cant effects on the threshing unit losses. Chinsuwan et al. (2003) studied the effects of the rotor tangential speed and feed rate on threshing unit losses and rice grain damage. The data ob- tained showed that the threshing unit losses decreased

15、and the damage increased when the rotor tangential speed was increased. Andrews et al. (1993) studied the effects of combine operating parameters on the harvest loss in rice and reported that the feed rate, the ratio of material other than grain to that of grain, grain moisture content, rotor speed

16、and concave clearance affected threshing unit losses. Gummert et al. (1992) reported that the rotor * Corresponding author. Department of Agricultural Engineering, Faculty of Engineering, Khon Kaen University, Khon Kaen 40002, Thailand. E-mail address: (S. Chuan-Udom). Contents lists available at Sc

17、ienceDirect Agriculture and Natural Resources journal homepage: natural-resources/ /10.1016/j.anres.2016.05.002 2452-316X/Production and hosting by Elsevier B.V. on behalf of Kasetsart University. This is an open access article under the CC BY-NC-ND license (http:/creativecommons. or

18、g/licenses/by-nc-nd/4.0/). Agriculture and Natural Resources 50 (2016) 421e425 speed, feed rate and louver inclination affected threshing unit losses and that the rotor speed affected grain damage. The appropriate axial fl ow sheller for shelling corn requires the study of important factors that aff

19、ect losses and the power con- sumption, namely, the rotor speed, feed rate and grain moisture content Therefore, the aim of this research was to study the effects of operating factors of an axial-fl owcorn shelling unit on losses and the power consumption. Materials and methods Corn shelling unit Th

20、is study was conducted using an axial fl ow corn shelling unit provided by the Agricultural Research Development Agency (Public Organization), Thailand as shown in Fig. 1. The shelling unit was 0.90 m long, with a diameter toward the end of the peg tooth of 0.30 m, with a controllable rotor speed. T

21、here was a power measuring device as shown in Fig. 2. The axial fl ow corn shelling unit consisted of a spike-toothed cylinder. The concave portion located under the cylinder was made of curved steel bar. The guide vane inclination was adjustable. The chute for grain under the shelling unit was divi

22、ded into nine slots. The feed rate was adjustable by controlling the conveyer belt speed of the materials into the shelling unit. The experiments were performed at the laboratory scale. This study was performed with Pioneer B-80 corn variety. Factors studied and experimental design The range of oper

23、ating factors affecting losses and the power consumption of an axial fl ow corn shelling unit were the mois- ture content (MC), feed rate (FR) and rotor speed (RS), as shown in Table 1. Following a factorial experimental design, a large number of factors and degrees were required to determine the qu

24、antity of materials and the experimental unit. Thus, a 23 factorial experimental design was applied, as shown in Table 2, to reduce the use of materials and the time for testing (Berger and Maurer, 2002). Testing method Each test used 10 kg of corn. The corn was fed into the inlet of the shelling un

25、it on a conveyor belt. The samples taken from the husks and cobs outlet was screened until only corn grain remained and the grain was weighed and subtracted from the original 10 kg of corn and the result was considered as the shelling unit loss (TL). To obtain the percentage of grain breakage (GB),

26、two 1 kg samples wererandomly taken fromthe chute, the GB wasseparated byhand and the weight of the GB was recorded. In this experiment, a torque transducer with a strain gauge (KFG-2-350-D2-11L1M3R; Sokki Kenyujo Co. Ltd.; Tokyo, Japan) was used. The torque meter was installed on the cylinder shaft

27、 to measure the torque and to calculate the power consumption (P). Data analysis From the obtained parameters, the terms TL, GB and P were used to construct multiple line models. Then, the models were Fig. 1. Corn shelling unit. Fig. 2. Power measuring device. Table 1 Independent variables and their

28、 factor levels. VariableRange and Levels (coded) e 0 X1; Moisture content (% wet basis)142128 X2; Feed rate (t/hr) X3; Rotor speed (m/s)81012 Table 2 Experimental units based on a 23factorial design for losses and po- wer consumption of an axial fl ow corn shelling unit for the variables mo

29、isture content (X1), feed rate (X2) and rotor speed (X3). Experiment numberX1X2X3 1eee 2ee 3ee 4e 5ee 6e 7e 8 9000 10000 11000 12000 W. Srison et al. / Agriculture and Natural Resources 50 (2016) 421e425422 applied in the analysis of the effects of parameters on losses and the power consumption base

30、d on response surface methodology and 23factorial designs, determining the effects of each param- eter on the coeffi cient of determination (R2) using the Design Expert software package (version 7; Stat-Ease Inc; Minneapolis, MN, USA.). ANOVA was used for regression analysis of the design factors af

31、fecting TL, GB and P. Signifi cance was tested at p F Model10.1571.4518.770.0001 Model is signifi cant MC1.93 ? 10?0.00511.93 ? 10?0.0052.49 ? 10?0.0040.9876 FR1.82 ? 10?0.00311.82 ? 10?0.0030.0240.8796 RS9.5719.57123.93 F Model19.5471.4551.620.0001 Model is signifi cant MC16.80116.80310.70F Model6.59 ? 100.00679.42 ? 100.005580.580.0001 Model is s