Effect of Water-Jumper Slope on Performance of Breastshot Wheel

Abubakar, Syafriyudin; Fajar, Berkah; Winoto, Sony; Facta, Mhd

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Effect of Water-Jumper Slope on Performance of Breastshot Wheel

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Original scientific paper

Journal of Sustainable Development of Energy, Water and Environment Systems
Volume 11, Issue 1, March 2023, 1100420
DOI: https://doi.org/10.13044/j.sdewes.d10.0420

Syafriyudin Abubakar¹ , Berkah Fajar², Sony Winoto², Mhd Facta²

¹ Institut Sains dan Teknologi AKPRIND, Yogyakarta, Indonesia
² Universitas Diponegoro, Semarang, Indonesia

Abstract

Common problem in the operation of breastshot water wheel in Indonesia is discontinuity operation of the wheel due to very low stream velocity in the channel during dry season. In order to minimize the problem, it is important to study the method of maintaining the continuity operation of the wheel during dry season. Thus, the installation of water-jumper at upstream of the wheel is proposed in the present work. The laboratory models of the water channel and breastshot water wheel were fabricated. The water jumper is attached at the upstream whose slope angle can be adjusted. The present work investigates the effect of water-jumper slope on the performance of the breastshot wheel. The slope angles are set at 5°, 10°, 15°, 20°, 25°, 30°, 35°, and 40°and the upstream velocities are 1.1, 1.2, 1.3, 1.4, 1.5, and 1.6 m/s. The result reveals that the use of water-jumper can increase the gross head and hydraulic power of very low stream, and hence the torque and the output power of the breastshot wheel are enhanced. The highest efficiency is achieved at the slope angle of 10º for stream velocity of 1.3 m/s. The water-jumper gives significant effect at stream velocity lower than 1.3 m/s. The hydraulic power is influenced by both discharge and gross head where they increase at increasing slope angle of the water-jumper. However, higher momentum losses occurs at the wheel for stream velocity higher than 1.3 m/s, thus output power and efficiency of the breastshot decreases even though hydraulic power increases. The water-jumper can keep continuous operation of the breastshot wheel in the irrigation channel during dry season.

Keywords: breastshot wheel; irrigation; performance; water-jumper; slope.

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INTRODUCTION

Renewable energy generation is important due to environmental concerns, increased global demand, and fossil fuel limitations [1]. Sources, such as biomass, solar and hydro energy, have been considered worldwide to reduce dependence on fossil resources. As countries evaluate their energy resources, many have recognized hydrokinetic energy as a significant contributor to their portfolio regarding this commodity [2]. For instance, Ersoy et al. modeled water scenarios in Southern Marocco for renewable energy development [3].

Human development requires access to electricity because it is essential for basic activities such as lighting, refrigeration, and running household appliances [4]. Many rural regions in poor and developing countries lack reliable access to national power grids, and they utilize hydro energy for electrification. For this reason, a decentralized micro-hydro power plant has been developed in North-Eastern Afghanistan [5]. Moreover, [6] examined hydro power-boosting using an underwater power generator based on a gravity vortex siphon. Hydropower has become an attractive source of renewable energy for electricity generation because it is eco-friendly, pollution-free, natural, and favorable for future development. Dependency on fossil fuels can be reduced by increasing renewable energy production [7] and applying small-scale hydro power in locations where available head and discharge are relatively low [8]. The hydropower plant could provide cheap, clean, and reliable electricity [9]. However, hydropower plants are highly water-intensive because large volumes of water evaporate from the increased reservoir surface [10]. Many countries have a significant but unused hydropower potential with head differences below 2.5 m. Standard turbines appear uneconomical because they require large turbine diameters, extensive civil engineering works, and ecological effect considerations [11]. The hydropower plants capture the energy in flowing water and make it useful. Recent studies showed that conventional technologies such as water wheels are suitable devices for low-head sites [12].

Many countries have used irrigation channels for pico-hydro and micro-hydro power plants. Examples include a 0.5 kW electric power generation in Padang Panjang, Indonesia [13], a 160 kW hydropower in Thailand [14], and a micro-hydro in Srilangka [15]. Typically, the micro-hydro power plant capacity is less than 500 kW [16]. Micro-hydro power plants have attracted increasing attention for renewable energy conversion systems due to their simplicity and low-cost installation. As a result, many micro-hydro plants have been successfully developed and tested, as reported by Kamran et al. [17], Jawahar and Michael [18], Nasir [19], and Pigaht and Van der Plas [20]. A stream water wheel seems suitable for a micro-hydro power plant for an irrigation channel.

Stream water wheel could be divided into undershot, overshot, and breastshot [21], as shown in the schematic diagram in Figure 1. Many studies examined stream water wheels, such as Quaranta and Ravelli [22], which investigated output power and power losses estimation for an overshot water wheel. The study of [23] also evaluated breastshot water wheels performance using different inflow configurations. Moreover, Quaranta et al.[24] analyzed the efficiency of a traditional water wheel, while the performance evaluation of a breastshot water wheel was experimentally conducted by Vidali et al. 2016 [25] and Muller and Kauppert [26]. Small-hydro power plants intended for low head difference, such as irrigation channels, have also been reported by Bakis et al. [27] and Senior [28]. Other studies performed simulation work to investigate breastshot water wheel performance. For instance, Adanta et al., 2020 [29] simulated the effect of channel slope on breastshot water wheel performance. Budiarso et al. 2018 [30] simulated the impact of bucket shape and kinetic energy on breastshot water wheel performance. A suitable stream water wheel could be selected using the diagram in Figure 2, as suggested by Quaranta [31].

Figure 1.

Categories of the stream water wheel

Figure 2.

Diagram for selection of water wheel [31]; HPM - Hydrostatic Pressure Machine

The common problem in the micro hydropower plant is operation discontinuity due to low stream velocity in the channel during the dry season. A sustainable operation could be achieved using a water-jumper at the wheel upstream. The blocking effect of the water-jumper may increase the water depth in the conveying channel, increasing the stream’s potential energy. However, the blocking of the flow may affect the velocity of the water downstream and the stream’s kinetic energy. The effect of the water-jumper on depth and velocity results in the availability of the gross head flow.

This study designed the breastshot water wheel for a laboratory-scale open channel. It aimed to investigate the effect of the water-jumper slope angle on the breastshot wheel performance at various upstream velocities. This kind of experiment has not been conducted by any study.

EXPERIMENT

The experimental test rig and measurement devices were set before data collection and analysis.

Experiment Description

The experimental test rig was installed at Institut Sains & Teknologi AKPRIND Indonesia laboratory. Figure 3a shows the experimental test rig comprising a water pump plenum chamber, adapter, jumping-water, breastshot wheel, conveying channel, exit gate, and draught passage. The test rig also has measurement devices, including a digital flow meter, disk brake, load cell, and tachometer, as shown in Figure 3b. The channel is made of a Mild Steel (MS) plate measuring 10 m in length, 0.56 m in width, and 0.4 m in depth. The water-jumper with an adjustable angle (α) was attached at the wheel’s upstream. The breastshot wheel was hand-made from MS plate, measures 0.8 m in diameter, and has 16 galvanized blades, each measuring 0.4 m and 0.5 m in width and length, respectively. The stream velocity was measured using a digital flow meter, while a tachometer measured the wheel’s rotational speed. Furthermore, a disk brake dynamometer was used to obtain the wheel’s torque. The experiment was conducted at stream velocities of 1.1, 1.2, 1.3, 1.4, 1.5, and 1.6 m/s and water-jumper slope angles of 5°, 10°, 15°, 20°, 25°, 30°, 35°, and 40°.

Figure 3.

Schematic diagram (a) and photograph (b) of experimental test rig; dimensions are given in mm

Data Analysis

Figure 4 shows a schematic diagram of a breastshot wheel in the channel without a water-jumper. Water flows with velocity v₁ and depth h₁ at the upstream and v₂ and h₂ at the downstream. The diagram governs the flow’s head gross equation. Head gross would be converted to rotate the wheel to produce mechanical energy. In this case, the flow head gross is the difference between the energy head comprising pressure, kinetics, and upstream and downstream potential, as shown in Eq. 1. Since the upstream and downstream pressure is the same (p₁ = p₂) and the channel is horizontal (z₁ = z₁), Eq. (1) simplifies as Eq. (2):

$H_{g r} = \{\frac{p_{1}}{γ} + \frac{υ_{1}^{2}}{2 g} + (z_{1} + h_{1})\} - \{\frac{p_{2}}{γ} + \frac{υ_{2}^{2}}{2 g} + (z_{2} + h_{2})\}$ (1)

$H_{g r} = (\frac{υ_{1}^{2} - υ_{2}^{2}}{2 g}) + (h_{1} - h_{2})$ (2)

Where H_gr is the head gross [m], v is the stream velocity [m/s], h is the stream height [m], g is the gravitational acceleration (9.81 m/s²), and subscripts 1 and 2 indicate the wheel’s upstream and downstream, respectively.

Figure 4.

Schematic diagram of the wheel in the channel without water-jumper

Figure 5 shows the schematic diagram of the water wheel installed in the channel with a water-jumper. The upstream head (h₁) was effectively replaced by water jumping height (y₂) following the hydraulic jump theory [32]. Therefore, the flow’s head gross equation with the water-jumper changes to:

$H_{g r} = (\frac{υ_{1}^{2} - υ_{2}^{2}}{2 g}) + (y_{2} - h_{2})$ (3)

Based on hydraulic jump theory and assuming the use of a water-jumper with a length of 0.4 m and slope angle α, the height of hydraulic jump at the wheel’s upstream becomes:

$y_{2} = 2.2 h_{1} + (0.4 s i n α - h_{1})$ (4)

By substituting Eq. (4) into Eq. (3), the head gross for the channel with water-jumper is given by Eq. (5):

$H_{g r} = (\frac{υ_{1}^{2} - υ_{2}^{2}}{2 g}) + \{((2.2 \times h_{2}) + (0.4 s i n α - h_{1})) - h_{2}\}$ (5)

Figure 5.

Schematic diagram of the wheel in a channel with water-jumper

Comparing the water-jumper with the broad caster weir [32], the discharge coefficient is calculated using Eq. (6). The volumetric flow rate of the channel is derived from the flow rate equation, Eq. (7).

$C_{d} = 1.125 {(\frac{1 + (y_{2} - h_{1}) / 0.4 \sin α}{2 + (y_{2} - h_{1}) / 0.4 \sin α})}^{1 / 2}$ (6)

$Q^{'} = C_{d} \times b \times υ_{1} \times h_{1}$ (7)

Substituting Eq. (6) into Eq. (7) and assuming the water-jumper width b = 0.56 m, the volumetric flow rate becomes:

$Q^{'} = 0.63 {(\frac{1 + (y_{2} - h_{1}) / 0.4 \sin α}{2 + (y_{2} - h_{1}) / 0.4 \sin α})}^{1 / 2} \times υ_{1} \times υ_{2}$ (8)

Once the head gross and volumetric flow rate are known, input hydraulic power to the water wheel is calculated using Eq. (9), where ρ is the density of water (1000 kg/m³).

$P_{i n} = ρ g Q^{'} H_{g r}$ (9)

The wheel’s torque, output power, and efficiency are obtained using Eqs. (10), (11), and (12), respectively.

$T_{a} = m_{b} \times g \times l$ (10)

$P_{o u t} = \frac{2 \times π \times N_{a} \times T_{a}}{60}$ (11)

$η = \frac{P_{o u t}}{P_{i n}} \times 100 %$ (12)

where T_a is the torque [N m], m_b is the mass of the load cell [kg], l is the distance from the wheel's axis to the load cell (0.4 m), P_in is the output power [W], and N_a is the rotational speed [rpm].

RESULTS AND DISCUSSION

This study analyzed the effect of slope angle on gross head, hydraulic power, torque, output power, and efficiency.

Effect of slope angle on the gross head

Figure 6 shows the effect of the water-jumper slope angle on head gross at different upstream velocities. The head gross increases significantly at slopes above 10o (the height of the hydraulic jump increases with slope, resulting in increased potential and gross head). Figure 6 also shows that the gross head increases with upstream water velocity for the same jumper angle due to increased hydraulic jump.

Figure 6.

Gross head (Hgr)as a function of the slope angle of water-jumper

Effect of slope angle on hydraulic power

Figure 7 shows the effect of the water-jumper slope angle on the wheel’s hydraulic power. At the same upstream velocity, the hydraulic power increases from 15o and steps up significantly at 10o–20o. The hydraulic power is influenced by discharge and gross head, and its graph is similar to the trend of the gross head and discharge, which increase with the water-jumper slope angle. The hydraulic power is enhanced with increased upstream velocity for a particular slope angle.

Figure 7.

Hydraulic power (P_in) as a function of the slope angle of water-jumper

Effect of slope angle on torque

Figure 8 shows that the torque increases with slope angle. It means that a larger angle produces more power to improve the torque. From Figure 7, the torque and hydraulic power trends are similar.

Figure 8.

Torque (T_a) as a function of the slope angle of water-jumper

Effect of slope angle on output power

Figure 9 shows the effect of slope angle on the breastshot’s actual power, which increases significantly at 10o–20o at all upstream velocities. The actual power remains the same or decreases at a slope angle greater than 20o due to decreased breastshot’s rotational speed (the wheel’s output power is directly proportional to rotational speed, as shown in Eq. (11)). However, a different trend of output power at a slope angle higher than 30o is observed for a stream velocity of 1.6 m/s. The output power decreases significantly from 35o to 40o, even as the hydraulic power increases, due to more momentum losses at 35o to 40o for a higher stream velocity of 1.6 m/s.

Figure 9.

Output power (P_out) as a function of the slope angle of water-jumper

Effect of slope angle on efficiency

Figure 10 shows the effect of slope angle on the wheel’s efficiency, which becomes highest for each upstream velocity at 10o. At a slope angle of 10o, maximum efficiency of 41.73% is obtained for an upstream velocity of 1.3 m/s. The efficiency steps up from 5o and reaches a maximum value at 10o, but decreases at higher slope angles. The water-jumper slope angle higher than 10o is ineffective in improving breastshot performance. Therefore, the slope angle must be set at 10o when the stream velocity varies from 1.1 m/s to 1.6 m/s.

Figure 10.

Efficiency (η) as a function of the slope angle of water-jumper

CONCLUSION

This study aimed to investigate the effect of water-jumper slope angle on breastshot water wheel performance at low stream velocities. The results showed that a water-jumper increases gross head, torque, and hydraulic and output power. However, the highest efficiency is achieved at a slope angle of 10o and stream velocity of 1.3 m/s. The water-jumper significantly affects the water wheel performance, specifically when stream velocity is lower than 1.3 m/s. The hydraulic power is influenced by discharge and gross head, which increase with the water-jumper slope angle. Significant momentum losses occur at the wheel for stream velocity higher than 1.3 m/s, decreasing the breastshot’s output power and efficiency, even as hydraulic power increases. Therefore, a water-jumper could be useful in maintaining continuous breastshot wheel operation in the irrigation channel during the dry season when the slope angle is set at 10o.

ACKNOWLEDGMENT

The authors are grateful to Institut Sains dan Teknologi AKPRIND Yogyakarta for the financial support to pursue a Doctoral program in the Mechanical Engineering Department of Universitas Diponegoro, Central Java, Indonesia.

NOMENCLATURE

width of the water-jumper

[m]

C_d

coefficient of discharge

[-]

gravitational acceleration

[m/s²]

stream height

[m]

H_gr

head gross

[m]

distance from the wheel's axis to the load cell

[m]

m_b

mass of the load cell

[kg]

N_a

rotational speed of the water wheel

[rpm]

P_in

input power

[W]

P_out

output power

[W]

Q’

volumetric flow rate

[m³/h]

T_a

actual torque

[N m]

stream velocity

[m/s]

y²

height of hydraulic jump at the wheel’s upstream

[m]

height from reference line

[m]

Greek letters

slope angle

[^o]

specific weight of water

[N/kg]

efficiency

[%]

density of water

[kg/m³]

Subscripts and superscripts

upstream

downstream

Abbreviations

Total Energy

Rotational speed

Power

Torque

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