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PERFORMANCE 1 EVALUATION OF A BAMBARA GROUND NUT SHELLER A.A. Atiku; N.A. Aviara* and M.A. Haque Department of Agricultural Engineering University of Maiduguri, Maiduguri, Nigeria. *Corresponding author, e-mail address: nddyaviara@yahoo.com Abstract The shelling of pod to obtain clean seed is one of the most tedious operations in Bambara groundnut processing. As a result, it has constituted a bottle- neck to the large scale production and processing of this important proteinous crop. To overcome the problem, some physical properties of bambara groundnut pod relevant in bulk handling and processing, were investigated and a sheller using roller mechanism was designed for the crop, constructed and tested. Measurements of the physical properties showed that at the moisture content of 5% (wb), the major, intermediate and minor diameters of Bambara groundnut pod averaged 1.89 cm, 1.57 cm and 1.44cm respectively. The true and bulk densities, porosity and one thousand-pod weight averaged 754.83 kg/m3 and 432 kg/m3, 42.77% and 1.24 kg, respectively and the angle of repose and static coefficient of friction of the pod on steel sheet averaged 30.4o and 0.56. Results of machine performance tests showed that the moisture content, material feed rate and the interaction between them had significant effect on the quantity of shelled, unshelled and partially shelled pods as well as that of damaged seeds and winnowed chaffs at 1% level of significance. Shelling and winnowing efficiencies decreased while percentage of partially shelled and unshelled pods increased with increase in moisture content and feed rate. The maximum shelling and winnowing efficiencies of 80% and 79.5% respectively, were obtained at the moisture content of 5% (wb) and feed rate of 93.6 kg/h. The percentage seed damage increased with increase in moisture content between 5 and 10% (wb) - to a maximum value of about 38%, and decreased with further increase in moisture content. At low moisture levels, it increased with increase in feed rate but at higher moisture levels, it decreased with increase in feed rate. Regression models that could be used to express the relationship existing between the sheller performance indices, pod moisture content and feed rate were established. Further work would be carried out to modify the sheller and optimize its performance. Keywords: Bambara groundnut, Efficiency, Evaluation, Performance, Sheller, Shelling, Winnowing ______________________________________________________________________ A. Atiku, N. Aviara, and M. Haque. Performance Evaluation of a Bambara Ground Nut Sheller . Agricultural Engineering International: the CIGR Journal of Scientific Research and Development. Manuscript PM 04 002. Vol. VI. July, 2004. 2 Introduction Bambara groundnut (Vigna subterranea (L.) verdc.) is an indigenous African crop that is now grown across the continent from Senegal to Kenya and from the Sahara to South Africa. It is a highly nutritious crop that plays an important role in the people s diet. The seed contains about 63% carbohydrate, 19% protein and 6.5% oil (Goli, 1997) and is consumed in different forms. For instance, it is usually fried or boiled with salt and eaten as snack or pounded into flour and used in the preparation of soup, porridge and various fried or steamed food products such as akara , moi-moi and okpa in Nigeria. It also finds a use in the preparation of the local food drink kunu and such dish as tuwo (Linnemann, 1988). Linnemann (1990) reported that bambara groundnut flour has been used in making bread in Zambia, and Brough et al. (1993) noted that the milk prepared from bambara groundnut gave a preferred flavour to that of milks from cowpea, pigeon pea and soybean. Atiku (2000) found that in North Eastern Nigeria, bambara groundnut is not only consumed as food, but also used for medicinal purposes. The haulm is used for livestock feed (Tanimu and Aliyu, 1997) and the leaves, which have been reported to be rich in nitrogen and phosphorus, are suitable for animal grazing. Mungate (1997) noted that bambara groundnut is not only to be used for relish and livestock fodder but also as a soil conditioner since it has the ability to fix much needed nitrogen in the soil. Inspite of the growing importance of bambara groundnut, research efforts have been concentrated on its agronomy and little attention has been paid to the technologies for its post harvest handling and processing operations. Bambara groundnut seed is contained in pod, which usually developed underground (Figure 1). The pod is harvested by pulling or lifting the plant manually or by using a hoe. Sometimes, a single furrow ox-drawn plough is used. The pod is then washed, dried and shelled or stored in Rhumbus, Hessian bag or pot. Traditional technologies are still employed in the shelling of bambara groundnut. These include pounding in mortar with pestle, beating with stick on a flat surface and cracking with a stone on top of another stone or a hard flat surface. These techniques are not only laborious and time consuming, but also wasteful. As a result, the shelling of Bambara groundnut pod has constituted a bottleneck to the large-scale production and processing of the crop. To solve this problem and relief the processors of the tedium of the manual shelling operation, a mechanical device that is capable of shelling the pod to produce clean seed was designed and fabricated. ______________________________________________________________________ A. Atiku, N. Aviara, and M. Haque. Performance Evaluation of a Bambara Ground Nut Sheller . Agricultural Engineering International: the CIGR Journal of Scientific Research and Development. Manuscript PM 04 002. Vol. VI. July, 2004. 3 Figure 1: Bambara groundnut pods and seeds, A: pods; B: seeds As part of the machine development efforts, this paper reports the performance evaluation of the Bambara groundnut sheller. The effect of moisture content and material feed rate on the sheller s performance indices was also investigated. Materials and Methods Physical Properties of Bambara Groundnut pod Some physical properties of bambara groundnut pod relevant in bulk handling and processing were investigated. A bulk quantity of pods was purchased from local farmers in Mubi, Adamawa State, Nigeria. The variety was the common milk coloured one, which is mainly grown in North Eastern Nigeria (Atiku, 2000). The pods were cleaned and sampled for experiment using a multi-slot riffle box divider. The moisture content was determined using the ASAE (1983) recommended method for edible beans, and the initial content of the pods was found to be 5 0.38% (wb). At this moisture content, the physical properties of the pods were determined. Pod size was determined by measuring the axial dimensions of 100 randomly selected pods, using a vernier caliper reading to 0.05mm. Values of the axial dimensions would govern the clearance between the rollers of the sheller that would engender effective shelling of the pod. The true density was determined using the water displacement method as reported by Aviara et al. (1999). The bulk density was determined using the AOAC (1980) recommended method and the porosity of the pods was calculated from the relationship given by Mohsenin (1986) as follows: ______________________________________________________________________ A. Atiku, N. Aviara, and M. Haque. Performance Evaluation of a Bambara Ground Nut Sheller . Agricultural Engineering International: the CIGR Journal of Scientific Research and Development. Manuscript PM 04 002. Vol. VI. July, 2004. 4 (1) P 1 b 100 t where P = porosity, %; b = bulk density, kg/m3; t = true density, kg/m3. The one thousand pod weight was obtained with an electronic balance reading to 0.001g. An open ended box with removable front panel was used to determine the pod angle of repose and the inclined plane method as described by Aviara et al. (2002) was used to determine the static coefficient of friction of the pod on metal sheet. All the experiments were replicated five times at the above moisture content and the average values are reported. Bambara Groundnut Sheller Description and Operation The Bambara groundnut sheller designed to operate by means of roller mechanism, consists of a feed hopper, shelling unit, winnowing unit and power system (Fig. 2). The hopper, which is rectangular in shape, is mounted on the shelling unit at an inclination of the pod s angle of repose. It is held on to the tool frame by a hopper support mounting. A flow rate control device is located at the hopper base and used to obtain varying gate openings between the hopper and the shelling unit. By this device, the quantity of pods entering into the shelling chamber per unit time was regulated and varying feed rates were achieved. Figure 2: Photograph of the fabricated bambara groundnut sheller ______________________________________________________________________ A. Atiku, N. Aviara, and M. Haque. Performance Evaluation of a Bambara Ground Nut Sheller . Agricultural Engineering International: the CIGR Journal of Scientific Research and Development. Manuscript PM 04 002. Vol. VI. July, 2004. 5 The shelling system consists of two rollers in the shelling chamber. One of the rollers is driven by a belt and pulley arrangement, while the other is not driven. The rotary roller has three shelling bars welded at an angle to its surface and running through its length. It creates a clearance that is less than the pod size but greater than the seed size with the stationary roller. During machine operation, the pod from the hopper drops between the rollers. The shelling bar of the rotary roller collects and compresses it against the nondriven roller and by that action the pod is shelled. The mixture of seed and shell falls through a drop or opening at the base of the shelling unit into the winnowing chamber. The winnowing unit comprises the winnowing chamber (where the seed and shell are separated by air current) and the blower, which is powered by a 3.5 hp, 1000 rpm electric motor. There is also a shell outlet and a seed collection chute. As the mixture of seed and shell falls through the winnowing chamber, the air current from the blower lifts the lighter shell and carries it out through the shell outlet. The denser seed falls through the air stream into the collection chute. The power system consists of the electric motor and belt and pulley drives by which it runs the shelling roller and the blower. The above components were assembled and mounted on a rectangular tool frame. Figure 3 shows the assembly details of the sheller and its part list. Performance Tests and Evaluation Tests were conducted to evaluate the performance of the Bambara groundnut sheller. The flow rate control device was calibrated following the procedure outlined by Oluwole et al. (2004) in a work on sheanut cracking. The moisture content of the pods was varied using the method of Ezeike (1986) as reported by Aviara et al (2002). This involved the soaking of a bulk quantity of the pods at an initial moisture content of 5% (wb) in clean water for one, two and three hours respectively. At the end each period of soaking, the pods were spread out in thin layer to dry in natural air for about eight hours. The pods were then sealed in marked polyethylene bags and stored in that condition for a further twenty four hours. This enabled stable and uniform moisture content of the pods to be achieved in the bags. The polyethylene bags were transferred into a refrigerator and when needed for experiments, the pods were allowed to equilibrate in ambient condition for six hours. To conduct a performance test, the hopper base was completely closed using the flow rate control device. The hopper was filled with Bambara groundnut pods at specified moisture content and the total number of nuts (NT) was determined by counting. The nuts were poured back into the hopper, the power supply was switched on to run the electric motor and set the working components of the sheller in motion. The flow rate control device was adjusted to select the gate opening that will deliver a particular feed rate of the pods into the shelling chamber. The pods were discharged into the machine and shelled until the hopper was emptied. The number of pods that were completely shelled and unbroken (N1), completely shelled but broken (N2), partially shelled and unbroken (N3), partially shelled and broken (N4) and the number of unshelled pods (N5) were determined at the end of each run. The quantity of shells winnowed out and those collected with the seeds were noted. Preliminary tests showed that good results could be obtained with the roller clearance of 18mm. Therefore, this clearance was maintained throughout the performance tests. ______________________________________________________________________ A. Atiku, N. Aviara, and M. Haque. Performance Evaluation of a Bambara Ground Nut Sheller . Agricultural Engineering International: the CIGR Journal of Scientific Research and Development. Manuscript PM 04 002. Vol. VI. July, 2004. 6 The tests were conducted at the initial moisture content of 5% (wb) and the moisture contents of 8.5, 12.2 and 18% (wb) obtained after conditioning. The three feed rates used were 93.6, 187.2 and 374.4 kg/h. At a combination of each of the above conditions, the test was replicated three times and the performance of the sheller was evaluated on the basis of the following indices: N + N2 100% (a) Shelling efficiency, Es 1 (2) NT N + N4 100% (b) Percentage damage, Pd 2 N T N + N4 100% (c) Percentage partially shelled, Pps 3 N T (3) (4) N (d) Percentage of unshelled pods, Pu 5 100% (5) N T m (6) (e) Winnowing efficiency, Ew ws 100% m Ts where mws = Mass of winnowed shells, and mTs = Total mass of shells. Regression analyses were performed on the data obtained, to determine the relationship existing between the machine performance indicators, moisture content and material feed rate. Analysis of variance (ANOVA) was used to determine the extent to which moisture content and or feed rate affected the indices. ______________________________________________________________________ A. Atiku, N. Aviara, and M. Haque. Performance Evaluation of a Bambara Ground Nut Sheller . Agricultural Engineering International: the CIGR Journal of Scientific Research and Development. Manuscript PM 04 002. Vol. VI. July, 2004. 7 Figure 3: Detailed assembly and parts list of Bambara groundnut sheller ______________________________________________________________________ A. Atiku, N. Aviara, and M. Haque. Performance Evaluation of a Bambara Ground Nut Sheller . Agricultural Engineering International: the CIGR Journal of Scientific Research and Development. Manuscript PM 04 002. Vol. VI. July, 2004. 8 18. 17. 16. 15. 14. 13. 12. 11. 10. 9. 8. 7. 6. 5. 4. 3. 2. 1. S/N Shelling bar Flat metal bar Blower shaft Steel Hopper Metal sheet Roller bearing High carbon steel Roller shaft Steel Tool frame 1.5 inch angle iron Blower housing Metal sheet Drive belt Electric motor Electric motor mounting 1 inch angle iron Electric motor mounting bolt Steel Drive pulley Cast iron Blower blade Metal sheet Seed collection chute Metal sheet Chaff outlet Metal sheet Roller shaft bearing housing and High carbon steel mounting Roller High carbon steel pipe Feed rate control device Metal steel sheet DESCRIPTION OF ITEM MATERIAL 3 1 1 2 2 1 assembly 1 2 1 1 assembly 4 4 4 1 1 4 2 1 NO. OFF Figure 3(Continued)--Parts list of Bambara groundnut sheller Results and Discussion Physical Properties of Bambara Groundnut Pod The values of the physical properties of bambara groundnut determined are presented in Table 1. The maximum, minimum and average values at the moisture content of 5% (wb) are reported with the standard deviation. The properties play important role in the determination of the sheller features and performance characteristics. The pod size governs the clearance between rollers that would make for effective shelling operation. The true and bulk densities, porosity and coefficient of friction the influence pressures exerted on hopper walls and flow through the orifice. The one thousand pod weight could be used for the theoretical determination of the pod s effective diameter and the angle of repose was used to determine the hopper inclination. ______________________________________________________________________ A. Atiku, N. Aviara, and M. Haque. Performance Evaluation of a Bambara Ground Nut Sheller . Agricultural Engineering International: the CIGR Journal of Scientific Research and Development. Manuscript PM 04 002. Vol. VI. July, 2004. 9 Table 1: Some physical properties of Bambara groundnut pod at the moisture content of 5% (wb) Values Properties Maximum Minimum Mean Standard deviation Axial dimensions: Major diameter (cm) 2.16 1.64 1.89 0.13 Intermediate diameter (cm) 1.74 1.35 1.57 0.11 Minor diameter (cm) 1.65 1.22 1.44 0.101 True density 1060 630 754.83 101.83 (kg/m3) Bulk density (kg/m3) 442 410 432 12.01 Porosity (%) 42.77 One thousand pod weight (kg) 1.36 1.08 1.238 0.10 Angle of repose 35 28 30.4 2.21 Static coefficient of friction on metal sheet 0.715 0.406 0.561 0.082 ______________________________________________________________________ A. Atiku, N. Aviara, and M. Haque. Performance Evaluation of a Bambara Ground Nut Sheller . Agricultural Engineering International: the CIGR Journal of Scientific Research and Development. Manuscript PM 04 002. Vol. VI. July, 2004. 10 Machine Performance The results of the performance test analyses are presented in Table 2 and Figures 3, 4, 5, 6 and 7 respectively. Table 2 shows that moisture content significantly affected the quantity of shelled pods at 1% level of significance. The effect of moisture content on the shelling efficiency at various feed rates is shown in Figure 3. From this figure, it can be seen that the shelling efficiency decreased with increase in moisture content at each of the feed rates employed. It also decreased with increase in feed rate at any moisture level within the studied range. As a result of the above trend, the maximum shelling efficiency of 80% was obtained at the lowest moisture content and feed rate of 5% (wb) and 93.6kg/h respectively. The relationship existing between the shelling efficiency, moisture content and feed rates could be expressed by the following regression equation. Es = 137.892 8.994M 1.954 x 10-2F 3.04 x 10-4MF + 0.118M2 + 1.492 x 10-4F2 (7) (R2 = 0.89) where M = Moisture content, % (wb) and F = Feed rate, kg/h. The moisture content was found to make the strongest unique contribution to the shelling efficiency. The t-test of the coefficients showed that the F, MF, M2 and F2 terms did not make statistically significant unique contribution to the equation. ______________________________________________________________________ A. Atiku, N. Aviara, and M. Haque. Performance Evaluation of a Bambara Ground Nut Sheller . Agricultural Engineering International: the CIGR Journal of Scientific Research and Development. Manuscript PM 04 002. Vol. VI. July, 2004. 11 90 80 70 Shelling efficiency, % 60 50 40 30 20 10 0 0 5 10 15 20 Moisture content, % (wb) Figure 4: Effect of moisture content on shelling efficiency at various feed rates 93.6 kg/h 187.2 kg/h 374.4 kg/h The result of the ANOVA of shelled pods with unbroken seeds presented in Table 2 shows that moisture content; feed rate and the interaction between them all have significant effects on the quantity of shelled pods at 1% level. Although the effect of feed rate and its interaction with moisture content reached statistical significance, the actual size of their effect was found to be smaller than that of moisture content. Table 2 also shows that moisture content, feed rate and the interaction between them had significant effects on the quantity of damaged seeds at 1% level of significance. The percentage seed damage increased with increase in moisture content to a maximum value and decreased with further increase in moisture content (Figure 5). Figure 5 also shows that at lower moisture levels, the percentage damage increased with increase in feed rate but at higher moisture levels, it decreased with increase in feed rate. Bambara groundnut seeds are likely to be brittle at low moisture contents and this may have caused them to be susceptible to mechanical damage. Also, the seed size may have increased with moisture content leading to increase in damage at constant roller clearance. ______________________________________________________________________ A. Atiku, N. Aviara, and M. Haque. Performance Evaluation of a Bambara Ground Nut Sheller . Agricultural Engineering International: the CIGR Journal of Scientific Research and Development. Manuscript PM 04 002. Vol. VI. July, 2004. 12 Table 2: F ratio for the results of performance tests F - ratio Source of variation Shelled pods Shelled pods Partially with but with shelled pods unbroken broken seeds seeds Moisture content M 21957.61* 2926.1* 18930.1* Feed rate F 363.85* 83.3* 518.11* Interaction M*F 93.59* 345.23* 18.53* * significant at 1% ** significant at 5% As the moisture content continued to increase, a moisture level must have been attained at which the effect of moisture content on the seed size was no longer significant with the seed becoming more visco-elastic. This could have been responsible for the decrease in seed damage recorded after certain moisture levels were exceeded. The relationship existing between percentage damage and moisture content and material feed rate could be expressed by the equation Pd = 0.862 + 6.532M + 2.623 x 10-2F 4.40 x 10-3MF 0.322M2 + 1.744 + 10-5F2 (8) (R2 = 0.802) The moisture content made the strongest unique contribution to the percentage of seed damage, while the constant, F, MF and F2 terms did not make statistically significant unique contributions to the equation. Unshelled pods Winnowed chaff 1181.78* 286.74* 10.6* 41068.3* 2075.63* 165.64* ______________________________________________________________________ A. Atiku, N. Aviara, and M. Haque. Performance Evaluation of a Bambara Ground Nut Sheller . Agricultural Engineering International: the CIGR Journal of Scientific Research and Development. Manuscript PM 04 002. Vol. VI. July, 2004. 13 40 Percentage seed damage, % 35 30 25 20 15 10 5 0 0 5 10 15 20 Moisture content, % (wb) Figure 5: Effect of moisture content on percentage seed damage at various feed rates 93.6 kg/h 187.2 kg/h 374.4 kg/h The quantities of partially shelled and unshelled pods were both significantly affected by moisture content, feed rate and the interaction between them at 1% level of significance (Table 2). The results presented in Figures 6 and 7 respectively show that the percentage of partially shelled and unshelled pods increased with increase in both moisture content and feed rate. This is quite unexpected since bambara groundnut size is expected to increase with increase in moisture content, and the roller clearance was kept constant. The above results may be attributable to some extraneous factors. The clearance between the rollers may not have remained constant throughout the duration of the shelling operation and the shelling bars may have undergone some deformation with time. The speed of machine operation could be another factor that contributed to the above results. However, the relationship existing between the percentages partially shelled and unshelled pods, moisture content and material feed rate can be expressed with the following equations: Pps = -35.188 + 6.36M + 0.1F + 5.178 x 10-4MF 5.63 x 10-2M2 1.61 x 10-4F2 (9) (R2 = 0.90) Pu = -12.135 + 2.826M + 6.206 x 10-2F + 6.967 x 10-4MF 8.43 x 10-2M2 1.04 x 10-4F2 (R2 = 0.74) (10) ______________________________________________________________________ A. Atiku, N. Aviara, and M. Haque. Performance Evaluation of a Bambara Ground Nut Sheller . Agricultural Engineering International: the CIGR Journal of Scientific Research and Development. Manuscript PM 04 002. Vol. VI. July, 2004. 14 The moisture content made the strongest unique contribution to equations 9 and 10, while the F, MF, M2 and F2 terms for equation 9 and the F, MF and F2 terms for equation 10 did not make statistically significant unique contributions. 80 70 Percentage partially shelled pods, % 60 50 40 30 20 10 0 0 5 10 15 20 Moisture content, % (wb) Figure 6: Effect of moisture content on percentage partially shelled pods at various feed rates 93.6 kg/h 187.2 kg/h 374.4 kg/h ______________________________________________________________________ A. Atiku, N. Aviara, and M. Haque. Performance Evaluation of a Bambara Ground Nut Sheller . Agricultural Engineering International: the CIGR Journal of Scientific Research and Development. Manuscript PM 04 002. Vol. VI. July, 2004. 15 30 Percentage unshelled pods,% 25 20 15 10 5 0 0 5 10 15 20 Moisture content, % (wb) Figure 7: Effect of moisture content on percentage unshelled pods at various feed rates 93.6 kg/h 187.2 kg/h 374.4 kg/h The pod moisture content, material feed rate and the interaction between them significantly affected the quantity of winnowed chaffs at 1% level of significance (Table 2). The winnowing efficiency presented in Figure 8 decreased with increase in moisture content and feed rate. Increase in moisture content may have resulted in increase in shell bulk density, which in turn could have increased its resistance to pneumatic transportation. Increase in feed rate must have increased the weight of the material being handled by the air stream and decrease in winnowing efficiency must have resulted from inadequacy of the air pressure supplied to convey the materials away. For the above reason, a blower of adjustable speed would be suitable for use in this type of shelling equipment. The relationship existing between the winnowing efficiency, moisture content and material feed rate can be expressed by the following equation: ______________________________________________________________________ A. Atiku, N. Aviara, and M. Haque. Performance Evaluation of a Bambara Ground Nut Sheller . Agricultural Engineering International: the CIGR Journal of Scientific Research and Development. Manuscript PM 04 002. Vol. VI. July, 2004. 16 Ew = 143.509 10.112M 0.188F 1.79 x 10-4 + 0.218M2 + 3.206 x 10-4F2 (R2 = 0.89) (11) Again, the moisture content made the strongest unique to the equation and the F, MF and F2 terms did not make statistically significant unique contributions. 90 80 Winnowing efficiency, % 70 60 50 40 30 20 10 0 0 5 10 15 20 Moisture content, % (wb) Figure 8: Effect of moisture content on the winnowing efficiency 93.6 kg/h 187.2 kg/h 374.4 kg/h Conclusions The performance evaluation of bambara groundnut sheller operating by means of roller mechanism showed that moisture content, material feed rate and the interaction between them had significant effect on the performance indices. Shelling and winnowing efficiencies decreased with increase in moisture content, percentage damage increased to a maximum and decreased, and the percentages partially shelled and unshelled pods increased with increase in moisture content. The relationship existing between the performance indices and moisture content were found to be adequately expressed by regression equations. Maximum shelling and winnowing efficiencies of 80% and 79.5% ______________________________________________________________________ A. Atiku, N. Aviara, and M. Haque. Performance Evaluation of a Bambara Ground Nut Sheller . Agricultural Engineering International: the CIGR Journal of Scientific Research and Development. Manuscript PM 04 002. Vol. VI. July, 2004. 17 were obtained. The machine has a compact design and robust building. It will contribute to the enhancement of Bambara groundnut processing as it could replace the present manual methods of shelling the pods, which are very tedious. In order to improve the performance of the Bambara groundnut sheller, the working components would be modified and assembled to withstand the stresses of the shelling operation over time. A roller clearance adjustment device and blower with variable fan speed would be incorporated. Tests would be conducted at different roller clearances, operational speeds and winnowing air velocities with different Bambara groundnut varieties at different moisture contents and material feed rates. An optimization technique would be used to determine the parametric combinations that would yield the optimum machine performance. The machine would be subjected to varying length of operational time to test for endurance. References AOAC (1980). Official methods of analysis, 13th edition. Association of Official Analytical Chemists, Washington D.C. ASAE (1983). ASAE standard S352, moisture measurement grain and seeds. Agricultural Engineers Year book. American Society of Agricultural Engineers. St. Joseph, Michigan. Atiku, A.A. (2000). Bambara groundnut processing and storage practices in North Eastern Nigeria. Postgraduate seminar paper, Department of Agricultural Engineering, University of Maiduguri, Maiduguri, Nigeria. Aviara, N.A; Gwandzang, M.I. and Haque, M.A. (1999). Physical properties of guna seeds. Journal of Agricultural Engineering Research, 73(2): 105 111. Aviara, N.A; Haque, M.A. and Izge, I.A. (2002). Physical properties of sheanut (Butyrospernum paradoxum) in relation to bulk handling and processing. Ife Journal of Technology (In press). Brough, S.H; Azam-Ali, S.N. and Taylor, A.J. (1993). The potential of bambara groundnut (vigna subterranean) in vegetable milk production and basic protein functionality systems. Food Chemistry, 47:277 283. Ezeike, G. O. I. (1986). Quasi-static hardness and elastic properties of some tropical seed grains and tomato fruit. International Agrophysics 2:15-29. Goli, A.E. (1997). Bambara groundnut. Bibliographic review. In Bambara groundnut. Vigna Subterranea (L.) verdc. Promoting the conservation and use of underutilized and neglected crops. Proceedings of the workshop on conservation and improvement of Bambara groundnut (Vigna subterranea (L.) verdc.). Heller, J; Begemann, F. and Mushonge, J. (eds.), 14 16 November, 1995, Harare Zimbabwe; IPGCPR and IPGRI, Rome. Linnemann, A.R. (1988). Cultivation of bambara groundnut in Northern Nigeria. Tropical crop communication, 15: 1 14. Linnemann, A.R. (1990). Cultivation of bambara groundnut (Vigna subterranean (L.) verdc.) in Western province, Zambia. Report of field study of tropical crops. Department of Tropical Crop Science. Wageningen Agricultural University, The Netherlands. ______________________________________________________________________ A. Atiku, N. Aviara, and M. Haque. Performance Evaluation of a Bambara Ground Nut Sheller . Agricultural Engineering International: the CIGR Journal of Scientific Research and Development. Manuscript PM 04 002. Vol. VI. July, 2004. 18 Mohsenin, N.N. (1986). Physical Properties of Plant and Animal Materials, 2nd edition (revised). Gordon and Breach, New York. Mungate, D. (1997). Opening address. In Bambara groundnut. Vigna Subterranea (L.) verdc. Promoting the conservation and use of underutilized and neglected crops. Proceedings of the workshop on conservation and improvement of Bambara groundnut (vigna subterranea (L.) verdc.). Heller, J; Begemann, F. and Mushonge, J. (eds.), 14 16 November, 1995, Harare Zimbabwe; IPGCPR and IPGRI, Rome. Oluwole, F.A; Aviara, N.A. and Haque, M.A. (2004). Development and performance tests of a sheanut cracker. Journal of Food Engineering, 65(1): 117 123. Tanimu, B. and Aliyu, L. (1997). Bambara groundnut, country report: Northern Nigeria. In Bambara groundnut. Vigna Subterranea (L.) verdc. Promoting the conservation and use of underutilized and neglected crops. Proceedings of the workshop on conservation and improvement of Bambara groundnut (vigna subterranea (L.) verdc.). Heller, J; Begemann, F. and Mushonge, J. (eds.), 14 16 November, 1995, Harare Zimbabwe; IPGCPR and IPGRI, Rome. ______________________________________________________________________ A. Atiku, N. Aviara, and M. Haque. Performance Evaluation of a Bambara Ground Nut Sheller . Agricultural Engineering International: the CIGR Journal of Scientific Research and Development. Manuscript PM 04 002. Vol. VI. July, 2004.

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424-005.pdf
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03-005.pdf
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LU-CSE-06-005.pdf
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MGMT3160-005.pdf
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444-006.pdf
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006.PDF
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52018.doc
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als9527.0010.006.pdf
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091.pdf
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091.pdf
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L49-091.pdf
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ug086-092.pdf
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ut.cs.09spr.comm.pdf
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092.PDF
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EDUC301-001-Spr06-Harper.pdf
Path: DeAnza College >> EDUC >> 001 Winter, 2008
educ731-001-957-veitch.pdf
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DBEA 1000-001 EducationTeaching.pdf
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041.pdf
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041-05.pdf
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031-041~ACADINFO.pdf
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soc-sci-041.pdf
Path: DeAnza College >> EDUC >> 041 Winter, 2008
058 Alternative Teacher Licensure Program [Cert].pdf
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05-3241df_pt01of03_F.pdf
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Bardsley F08 Phil 203-001.doc
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Making of the Modern Mind 118 b 001.pdf
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1400-001-002.pdf
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02-001.pdf
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1050-002 Syllabus.pdf
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300-002.doc
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100-003.1.pdf
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100-003.2.pdf
Path: DeAnza College >> PHIL >> 003 Winter, 2008
Fall05-1400-003-004.pdf
Path: DeAnza College >> PHIL >> 003 Winter, 2008
FC-09-003-UCC-08-066.docx
Path: DeAnza College >> PHIL >> 003 Winter, 2008
STAD-007 GRADPrgrms-Majs.pdf
Path: DeAnza College >> PHIL >> 007 Fall, 2008
a 007 nov appts.pdf
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group project (007) lab4.doc
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1400-007-syllabus.pdf
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08-008.pdf
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FC-09-013_UCC-09-008.doc
Path: DeAnza College >> PHIL >> 008 Fall, 2008
1400-008-syllabus.pdf
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009-m-phil.pdf
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05-009.pdf
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08-009.pdf
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slac-wp-009-02-Baird.pdf
Path: DeAnza College >> PHIL >> 009 Fall, 2008
03-CNA-017.pdf
Path: DeAnza College >> PHIL >> 017 Spring, 2008