Research Article
Technical Evaluation of Sprinkler Irrigation Systems in Arak, Iran
Shahid Chamran University, Ahvaz, Iran
F. Baradarane-Hezave
Shahid Chamran University, Ahvaz, Iran
M. Behzad
Shahid Chamran University, Ahvaz, Iran
Due to low precipitation and its disproportional distribution in terms of time and space, Iran is located in arid and semi arid regions where almost 94% of abstractions from renewable resources are allocated to agricultural sector. The overall irrigation efficiency in this sector on average is estimated as 30 to 35%. Where by implementing pressurized irrigation projects the consumption efficiency can be considerably enhanced to improve the existing values. One of the inseparable exercises in irrigation projects is to be evaluation. Irrigationevaluation is defined as analysis of any irrigation method which is based upon the measurements takes under actual conditions of a land (Anonymous, 1997).
Baghbani (1995) reviewed the influences of varieties of sprinklers heights on evaporation and drift losses in center pivot irrigation systems and concluded that with a wind velocity of 2 m sec‾1, should the height of sprinklers be reduced from 2.25 to 1.65 m, the evaporation and drift losses would be reduced by 50%. Ataee (1997) studied a number of pressurized irrigation system in different point of Isfahan, Iran and achieved a potential efficiencies for drip and sprinkler irrigation systems between 18 to 70% and 28 to 62%, respectively with actual efficiencies of 51 and 37%, respectively. Ebrahimi (1996) evaluated different wheel move irrigation systems in Mashhad and Torbate-e Heidarieh regions in Iran and attained actual efficiency of 54 to 62%. Tarjuelo et al. (2000) designed a model to calculate the evaporation and wind losses in a semi arid environmental where the influences of factors such as the type of the riser, nozzle composition, vapor pressure deficit and wind velocities were considered. They concluded that with an increase of wind velocity up to 20 km h‾1, the distribution uniformity decreased nonlinearly and declined afterward. Jiusheng (1998) presented a simulation model including the effect on crop yield of both sprinkler uniformity and water deficit. Ayers et al. (1991) studied sugar beet and cotton yield response to the uniformity of a linear-move sprinkler irrigation system that can generate different uniformities and scales of variation. The last two studies have shown important effects of the non-uniformity pattern on crop yield.
In the present study, two different irrigation systems i.e., solid set irrigation system and wheel move irrigation system, two soil textures (loamy and fine) and two crop fields namely alfalfa and potato were utilized under the same environmental conditions.
Table 1: | Characteristics of the sprinkle irrigation systems |
The experiments were conducted in Arak agricultural region center of Iran, during year of 2004.Table 1 reflects the characteristics of both irrigation systems. This study mainly focuses upon the technical evaluation of the performance of the two sprinkle irrigation systems. All of the experiments were undertaken in moderate environmental conditions while the average wind velocity was less than 6 km h‾1.
In order to evaluate the both systems, initial data and information were collected upon topography, features of water supplies, pumping, main pipes, semi main and lateral pipes, characteristics of the sprinklers, opening and closing values and detailed drawings of the joints. Soil and planting parameters including soil texture, soil density, soil moisture before any irrigation exercise to estimate Soil Moisture Deficit (SMD), soil moisture in Field Capacity (FC), soil infiltration and root zoon depth were measured. Environmental parameters such as wind velocity and direction, relative humidity and temperature were collected. The sprinklers discharge and pressure were also measured. For measuring water distribution one of the lateral pipes was selected initially then pooling buckets were placed with space of 3χ3 m between two moderate pressure sprinklers. The time of the experiment was between 1 to 2 h depending on the farm conditions. Eq. 1 was used to obtain the coefficient uniformity:
(1) |
Where:
Di | = | The water depths in each bucket in mm, |
D̄ | = | The average of the water depths in mm |
n | = | The number of observation. |
To attain the potential efficiency of water Eq. 2 was applied.
(2) |
Dq | = | The average of one fourth the lowest water depth infiltrating into the soil which is equal to maximum discharge in mm |
Dr | = | The average irrigation water depths in mm. |
The values determined for the parameters above should be adjusted considering the pressure differences in the system being valid enough to be applied for the entire system. The distribution of the system is as follow:
(3) |
where, index (S) relates to the system and index (t) is related to testing block, Pmax, Pmean and Pmin are maximum, average and minimum pressure, respectively inside the irrigation system. After the parameter required were obtained, the evaluation parameters were calculated using the related equations.
Table 2-5 show the evaluation parameters calculated for sample systems where differences between actual efficiencies and potential efficiencies reflect the management state of the systems. Other parameters show the design and excision of the systems.
Coefficients of uniformity in the testing blocks in GK2, MK2, VK, AW1, AW2, MW1 and MW2 were more than 80%. Appropriate selection of the types of sprinklers, spacing, efficient functional pressure of sample sprinklers and ideal weather conditions during the sampling led to the increase of distribution coefficient and distribution uniformity in these systems compared to those of the other systems. Distribution coefficient and uniformity in GK1 and MK1 systems was much less than those of the other system which was because of aging and exhaustion of the systems insufficient spacing of sprinklers, crookedness of the sprinklers risers also, high pressure differences along the lateral pipes in the GK1 system and through the MK1 system, inefficient relation of sprinklers due to insufficient pressure and inadequate overlapping of sprinklers. Pressure variances in most of the sampling systems where in and acceptable range except for the GK1 and AW2 systems, thus the distribution and coefficient uniformity to the entire system were not lower than the measured values at sampling blocks.
Table 2: | Results of evaluation parameters in the solid set sprinkle systems |
Table 3: | Pressure variations in the solid set sprinkle systems |
Table 4: | Results of evaluation parameters in the wheel move systems |
Table 5: | Pressure variations in wheel move sprinkle systems |
Table 6: | Comparison of the two systems |
Pressure variance through the GK1 system was more than the maximum allowable friction losses due to the excessive length of lateral pipes despite there adequate stop to compensate for pressure losses hence the coefficient unity and distribution uniformity decreased throng entire system. Table 6 reflects the average distribution coefficient and potential efficiencies of water application for both solid set sprinkler and wheel move systems. It can be inferred that the values of the aforementioned parameters are considerably higher for wheel moves than solid set systems.
With due regard to the fact that the areas for both types of the systems and the number of operating sprinklers at the same time were not similar, pressure and sprinklers efficiencies were different in the both systems thus comparing two systems on the surface of the experimental block would result in more accurate data. It can be concluded that for the experimental block, coefficient uniformity and potential efficiencies of water application in the wheel move systems were higher than those in the solid set systems. However in high wind velocity conditions, heavy soil texture with high degree of cohesion performance of the wheel move irrigation system is much weaker than the solid set system. Since by selecting adequate time step and sufficient irrigation the actual efficiency of the system can be enhanced enough to meet the potential efficiency. Of note is that the scarcity of water resources causes low irrigation which in turn increases the potential efficiency values.