Received Date: April 14, 2015; Accepted Date: May 14, 2015; Published Date: May 21, 2015
Citation: Sobowale SS, Adebiyi JA, Adebo OA (2015) Design, Construction and Performance Evaluation of a Melon Seeds Sheller. J Food Process Technol 6: 463. doi: 10.4172/2157-7110.1000463
Copyright: © 2015 Sobowale SS, et al. This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.
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Melon seed is an important oil seed crop that serves numerous food purposes. Shelling of this crop is vital, prior to its vast applications. To address the challenges associated with shelling melon, a design for shelling melon seeds on a small scale was presented and evaluated. Parameters evaluated include shelling efficiency, percentage seed shelled and damaged, throughput and machine capacity. The machine was constructed using locally available materials and consists of a hopper, frame, shelling and cleaning unit, chutes and prime mover. Shelling operation was carried using melon seeds of three different moisture contents (6.99, 11.90 and 18.32%) and at different shelling speeds of 2500 and 1500 rpm, while performance evaluation were evaluated. Results obtained showed that shelling speed of 1500 rpm and moisture content of 18.32% has the best shelling efficiency of 76.30% and least percentage seed damage of 22.60%, compared to shelling speed of 2500 rpm and seed moisture content of 6.99%, which had a shelling efficiency of 70.0% and percentage seed damage of 68.10%. Shelling speeds of the machine and seed moisture content of melon affects the rate, efficiency and percentage seed damage. The machine and throughput capacity of the equipment are 7.95 and 9.56 kg/h, respectively.This design and set of conditions selected were the most preferred because of the low cost, rapid operation, lesser seed damage and minimal human energy expenditure. The melon seed sheller is user friendly, does not require skilled labor and independent from any central electric power supply. The equipment design was found suitable for rural development.
Melon; Shelling; Seed damage; Performance evaluation; Efficiency
Melon (Colocynthiscitrullus.L.) is an extensively cultivated and consumed oil seed crop in Nigeria and West Africa [1,2]. As reported by Aguayo, it is the fourth most important crop in the world in terms of production (18 metric tons), after orange, banana and grape . These seeds are vastly nutritious, furnishing the human diet with good quality proteins . It contains about 41.51% essential amino acids and other essential nutrients [5-7]. Melon seed is also a good source of minerals, vitamins, oil and energy in form of carbohydrates . The seed contains 0.6 proteins, 4.6g carbohydrates, 33 mg vitamin C, 0.6 g crude fiber, 230 mg K, 16 mg P, 17 g Ca per 100 g edible seeds and unsaturated fatty acids . According to Bankole, it is grown mainly for the intended use of its shelled kernel. This can be sprinkled into a soup or stew and can also be grounded into a thick paste. It is also transformed into products such as ‘ogiri’, baby ‘robo cake’, livestock feed, while its oil is used in the production of soap and local pomade [10,11].
The processing of melon is imperative to further diversify its use. This includes shelling, washing, coring, drying, fermentation, drying and oil extraction. Shelling involves removing the outermost part (husk) from the melon kernel. Here, the seed is separated from the spiny husk. This operation can be carried out in the field or at the storage environment . Shelling of melon as a unit operation is therefore an important step towards the processing of melon to its finished products. Most acreage farmers, who cultivate this crop in Nigeria and West Africa alike, encounter several processing challenges of shelling, as it requires a relatively high expenditure of human energy which is a major concern.
The inability to effectively shell melon in order to meet the requisite capacity necessary for industrial utilization, has been a hindrance to its use for large scale production of various commodities . The conventional, traditional or manual method of shelling melon is inefficient, tedious and time consuming, thus limiting the availability of their products in the market [14,15]. Furthermore, these obsolete methods results in bruising and serious injury to the human fingers, coupled with low output rates . Thus the quest for a satisfactory, cheap and effective means such as mechanized shelling technique is of importance, for small and medium scale farmers in Nigeria. Different forms and types of melon shellers exist, according to their source of power, and can thus be classified as electrically powered or fuel-driven melon shellers. However, with the prevalence of the erratic power supply, which is synonymous with Nigeria, it is imperative to look for other means of powering equipment. Fuel-powered sheller is a better choice and has advantages over the electrical powered one such as its availability, either in the presence or absence of electric power supply and also non-reliance on electricity.
Different studies have been done on the design and development of shellers [17-19]. But not much work has been done in the literatures on the design and construction of a mechanized fuel-powered melon sheller. Therefore, the need for a more cost effective, simple, friendly, hygienic and technologically feasible system for shelling melon remains imperative. Hence, the objectives of this work are to design and construct a fuel powered melon sheller and to evaluate the performance of the constructed melon shelling machine.
The materials used for the construction of the melon sheller include: mild steel, ball bearings, angle iron, static disc, electrode, single and double groove pulley, shaft and belt. The design of the melon sheller showing all the internal component of the machine is as shown in Figure 1. The melon seeds used to evaluate the performance of the machine were purchased from a local market in Abeokuta (7.15°N, 3.35°E), Nigeria. The samples were cleaned to remove debris and foreign materials.
A machine should not be only technically correct and operated as predicted, but it should be capable of performing the purpose of the proposed application. It is however expedient that a melon sheller apart from effectively performing its proposed application, it should also satisfy process requirement throughout its service life and incorporate the design features of durability and hygiene. The following factors were also considered in the design of the melon seed sheller: (i) availability of raw materials for construction; (ii) mechanical properties of the material; (iii) cost (iv) power requirement; (iv) ease of fabrication and dismantling.
The significant properties of melon seed ,influenced the basic design of this machine . Basic considerations were given to the design for the capacity and size of the machine, power requirement, speed of the pulley, length of the belt, diameter of the shaft. Equations (1 – 9), were used to calculate some of the parameters for the various components of the sheller [21-24].
M=ρ × V (2)
V1=π D1 N1/60; V1=V1 since there is no slip. (6)
L=2C + π/2 (D1 + D2) + (D1 – D2)2/4C (7)
C=(D2 + D1)/2 + D1 (8)
T= P × 60/2πN (9)
where; V=volume of the hopper (m2); π=3.142; r=radius (m); h=height (m); M=mass of melon seeds (Kg); ρ=Density of melon seed (Kg/ m2); W=weight (N); M=mass (Kg); g =acceleration due to gravity (9.81m/s2); d=diameter of the shaft (m); Mb=Bending moment (Nm); Mt=Torsional moment (Nm); Kb=combined shock and fatigue factor applied to bending moment; Kt=combined shock and fatigue factor applied to torsional moment; Ss=allowable shear stress; N1=speed of the driving motor (driver) (rpm); D1=diameter of the driving pulley (mm); N2=speed of the shaft (driven) (rpm); D2=diameter of the driven pulley (mm); V1=speed of the driving pulley (m/s); V2=speed of the driven pulley (m/s); L=Belt length (mm); C=Centre distance (mm); T=torque (Nm); P=power of motor (W); N=revolutions per minute (rpm). From the design calculations, the 0.0089 m3 hopper can hold 7.40 kg of melon seed. Using equation 4, the minimum diameter of the shaft obtained was 13 mm. However, to allow for safety factor, an optimum shaft diameter of 15 mm was used, to overcome load on the shaft. Diameter of the driven pulley was calculated as 71 mm, with a speed of 9.23 m/s. The belt length required was calculated as 457 mm and the torque of the machine is 13.33 Nm.
Construction and description of the machine
The pictorial view of the constructed melon sheller was shown in Figure 2. Locally available, but quality materials (mild steel, angle iron, pulleys, shaft, belts and motor) which produce the desired objective at minimum cost were used. The machine consists of the hopper, shelling unit (which consists of rotating disc and static disc), the frame, the cleaning unit and chutes. To facilitate free flow of seeds into the shelling unit, the conical shaped hopper was fabricated using mild steel into a height of 200 mm, upper radius of 200 mm and lower radius of 50 mm and inclined at an angle of 120o. The shelling unit consists of the rotating and static discs, vanes and the shelling drum. The outer part of the rotating disc is lined with flat metal blades (¾ inch) of 50 mm length were welded at an angle of 60o, and were arranged side by side with a distance of 10 mm between the blades, along the diameter (150 mm) of the disc, forming vane slots at the edges of the rotating disc. The static disc consists of flat metal rods of 120 mm length, arranged side by side and welded at a distance of 10 mm to each other at an angle of 60o along the walls of the fixed drum which formed spikes. The frame which is the support on which the whole unit rests, was made from angle iron into a rectangular of size 920 mm × 256 mm × 730mm high. The cleaning unit is to facilitate the separation of the shelled melon seeds from the chaff. The cleaning unit consists of mild steel folded and welded to form a chute of 350 mm × 50 mm × 40 mm, length, width and height respectively. A regulated fan was installed at one end of the tunnel to supply air to separate the chaff from the cotyledon after shelling. Power was supplied by a 5.5 Hp gasoline engine and transmitted to the machine through the use of pulleys, belts and shaft.
To operate the machine, appropriate quantity of fuel (gasoline) and engine oil was correctly measured into the fuel and oil tanks, respectively. The prime mover was started and left to operate for few minutes to enable the machine attain its operational speed. About 5 kg of melon seeds were fed in through the hopper continuously but gradually. The seeds flowed through the lower opening of the hopper onto the vanes into the shelling unit. In the shelling unit, the melon seeds were thrown against the wall of the shelling drum and the rotating vanes. Through impact of the shelling vanes, walls of the shelling drum, and collision of the seeds with each other, the shells were weakened and subsequently broke. After the shelling process, both mixture of the seeds and chaff fell through a chute, leading to the cleaning unit. In the cleaning unit, a fixed regulated fan separated the shelled seeds from the chaff, by air current. The denser shelled seeds fell through a discharge outlet, while the chaff was blown through a chute opposite the fan. The dimensioning and design parameters were done in accordance to standard engineering practices.
The performance evaluation of the machine was done with a 5.5 Hp. prime mover, using melon seeds of three different moisture contents. The untreated seeds; seeds soaked for 12 hours and sun dried; and seeds sprinkled with water and partially dried with natural air for 10 minutes. The moisture contents of these samples were determined using the methods of AOAC (2004), just before the shelling operation as given in Table 1. This was done because the moisture content of the seeds varies according to place, variety, season, time of harvest and processing. The melon shelling machine was fed with a known initial quantity of melon seeds (N0) and the shelling experiments were performed using the following variables as shown in Table 1.
|Seed moisture content, d.b (%)||6.99, 11.90, 18.32|
|Shelling speeds (rpm)||1500, 2500|
|Performance indicators||Shelling efficiency, percentage seed damage|
Table 1: Variables used for the experiment.
After each experiment, the seeds were carefully collected from the outlets and divided into shelled-unbroken seeds (N1), shelled-broken seeds (N2), partially shelled seeds (N3), unshelled seeds (N4), unshelled seeds but broken (N5) and subsequently weighed. Percentages of shelled unbroken-seeds (?s), broken seeds (?b), partially shelled seeds (?p) and unshelled seeds (?u) were evaluated (Eqn 10 – 13) using the methods described by Audu, Khuswaha, Pradhan [25,26]. Percentage seed damage (Sd), shelling efficiency (?e), machine capacity (Cm) and throughput capacity (Ct) were calculated using equations (14 – 17). Each of these tests was done in triplicates at each moisture levels.
?s=N1/ N0 × tT100 (10)
?b=N2/N0 × 100 (11)
?p=N3/N0 × 100 (12)
?u=N4/N0 × 100 (13)
Sd=N5 + N2 / N0 × 100 (14)
?e=N1 + N2 / N0 (15)
where; Ct=Throughput capacity (kg/h); Mf=Mass of seed fed into the machine (kg); T=Time taken to complete the operation (h); Cm=Machine capacity (kg/h); Ms=Mass of seed shelled (kg); T=Time taken to complete the operation (h).
Effect of seed moisture content and shelling speed
Table 2 shows the shelling characteristics and results of the shelling at different moisture contents and shelling speeds. The performance indicators varied at different shelling speeds and moisture contents. Using equation. 8, the maximum percentage of shelled-unbroken seeds obtained was 61.22 ± 1.20% at a seed moisture content of 18.32% (d,b.) and shelling speed of 1500 rpm, while the minimum percentage of shelled-unbroken seeds obtained were 11.49 ± 0.70% at shelling speed of 2500 rpm and at a moisture content of 6.99% (d.b). This is attributed to the brittleness of the seeds at lower moisture contents, which makes them susceptible to mechanical damage. A similar trend was also observed for the percentage of shelled-broken seeds, evaluated using equation 11, with the highest value of 58.51 ± 1.57% at 2500 rpm and 6.99% (d.b) moisture content, while the lowest 15.13 ± 0.02%, the lowest was obtained at shelling speed of 1500 rpm and 18.32% (d.b) moisture content. From the results obtained, it can also be observed that percentage of seed shelled (unbroken) increased with increase in moisture contents, irrespective of shelling speeds. This shows similar result with the work of Shittu, where increased shelled seeds were obtained with increase in moisture contents. Increase in shelling speeds was also reported to affect the rate of shelling. Higher speeds reduced shelling time, irrespective of the seed moisture contents.
|Moisture content, d.b (%)||Shelling speed (rpm)||Percentage of shelled-unbroken seed, Ƞs (%)||Percentage of shelled-broken seeds, Ƞb (%)||Percentage of partially shelled seeds, Ƞp (%)||Percentage of unshelled seeds, Ƞu (%)||Time taken (hr)|
Table 2: Performance of the melon sheller at different variables.
Percentage seed damage
The percentage seed damage (Sd) was evaluated using equation 14. Figure 3 represents the effect of shelling speed and moisture content on percentage seed damage. The highest seed damage obtained at 1500 rpm was 61.90% at 6.99% (d.b) moisture content and the least value of 22.60% at 18.32% (d.b) moisture content at the same shelling speed. A different trend was however observed at shelling speed of 2500 rpm. While a higher percentage seed damage of 68.10% was obtained at a seed moisture content of 6.99% (d.b), the least seed damage of 48.80% was rather obtained at moisture content of 11.90% (d.b). An increase in mechanical seed damage was also generally observed to occur with a succeeding decrease in moisture content. This is also in agreement with the finding of James, which reported an increase in the damage of melon seeds with a consequent increase in speed. This is credited to the increase dryness of the seed and is also ascribed to the relative increase of impact force that resulted from increase in speed .
The shelling efficiency of the machine (?e) was evaluated using equation 15. The effect of shelling speed and moisture on shelling efficiency is presented in Figure 4. This was observed to increase with an increase in seed moisture content from 73.10% to 76.30% and 70% to 75.20% at 1500 rpm and 2500 rpm respectively. This trend corresponds to the findings of Audu, reported an increase in efficiency of dehulling locust bean with an increase in moisture content.
Machine and throughput capacity
Using equations 16 and 17, the machine and throughput capacity were calculated as 7.95 and 9.56 kg/h respectively, based on the highest shelling efficiency values. The machine capacity obtained is however, relatively low as compared values obtained by James and Shittu [11,15]. This can be attributed to smaller size of hopper used in this study.
A gasoline powered melon seed sheller was designed constructed and evaluated in this study. Results obtained showed that the machine can effectively shell melon seeds and that seed moisture contents and the speed of the shelling machine affected the performance indicators. The shelling efficiency increases with an increase in moisture content and decrease in shelling speed, with an optimum moisture content and shelling speed of 18.32% and 1500 rpm respectively. The machine is user friendly, does not require skilled labor and the incessant power outages prevalent in developing countries such as Nigeria, and does not affect its use. Due to its relative cheaper cost of production, it can effectively address the need of rural dwellers as well as small and medium scale farmers in developing countries, and the difficulties associated with customary method of shelling melon will reduced. Further work should be done using other moisture contents and speed combinations to determine the optimum shelling condition for the sheller. The capacity of the hopper also needs to be increased to upscale the machine capacity.