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1.
Sprinkler water distributions as affected by winter wheat canopy 总被引:8,自引:0,他引:8
Sprinkler uniformity is often used to evaluate irrigation system performance. The measurement of uniformity is generally
made from one test when no crop is present. However, a developing crop canopy has significant potential to modify the distribution
of water applied during irrigation. This study was conducted to evaluate the influence of a winter wheat canopy on sprinkler
uniformity and on canopy-intercepted water by measuring water distributions above and below the canopy. The Christiansen uniformity
coefficient (CU) was calculated on both a daily and a cumulative basis. The CU was higher below the canopy than above the
canopy. Canopy-intercepted water, which is here defined as the sum of canopy storage and stemflow, increased with increasing
water application depth. Sprinkler uniformity had no significant effect on the mean amount of water interception by the canopy.
The ratio of water interception to total water application depth for the whole irrigation season was between 0.24 and 0.28.
The CUs calculated from the cumulative depth caught above and below the canopy are larger than the averages of individual
CU values during the irrigation season. Measurement of individual CUs during the irrigation season therefore underestimates
the cumulative CU. Experimental results also demonstrated that sprinkler uniformity in this study had little effect on crop
yield.
Received: 1 February 2000 相似文献
2.
Talel Stambouli Antonio Martínez-Cob José Maria Faci Terry Howell Nery Zapata 《Irrigation Science》2013,31(5):1075-1089
Gross sprinkler evaporation losses (SELg) can be large and decrease irrigation application efficiency. However, it is not universally established how much of the SELg contributes to decrease the crop evapotranspiration during the sprinkler irrigation and how much are the net sprinkler losses (SELn). The components of SEL were the wind drift and evaporation losses (WDEL) and the water intercepted by the crop (IL). The gross WDEL (WDELg) and evapotranspiration (ET) were measured simultaneously in two alfalfa (Medicago sativa L.) plots, one being irrigated (moist, MT) and the other one not being irrigated (dry, DT). Catch can measurements, mass gains, and losses in the lysimeters and micrometeorological measurements were performed to establish net WDEL (WDELn) during the irrigation and net IL (ILn) after the irrigation as the difference between ETMT and ETDT. Also, equations to estimate ILn and net sprinkler evaporation losses (SELn) were developed. ILn was strongly related to vapor pressure deficit (VPD). SELn were 8.3 % of the total applied water. During daytime irrigations, SELn was 9.8 % of the irrigation water and slightly less than WDELg (10.9 %). During nighttime irrigations, SELn were slightly greater than WDELg (5.4 and 3.7 %, respectively). SELn was mainly a function of wind speed. 相似文献
3.
Experiments were undertaken at CCS Haryana Agricultural University Farm, Sirsa (India) to estimate the optimum irrigation
schedule for cotton resulting in minimum percolation losses. The sprinkler line source technique was adopted for creating
various irrigation regimes at different crop growth stages. The SWASALT (Simulation of Water And SALT) model after calibration
and validation provided water balance components. The wa-ter management response indicators (WMRI's) such as transpiration
efficiency Et/(Irr + P), relative transpiration Et/Etp, evapotranspiration efficiency ET/(Irr + P), soil moisture storage change ΔW/Wint (deficit/excess) and percolation loss Perc/(Irr. + P) were evaluated using water balance components as estimated by the simulation
study. Under limited water supply conditions, the optimum irrigation depth was found to be 57 mm at crop growth stages with
pre-sowing and 1st irrigation of 120 mm and 80 mm respectively for sandy clay loam underlain by sandy loam soil (Type I). The corresponding
values of relative transpiration, transpiration efficiency and evapotranspiration efficiency were 0.65, 0.65 and 0.89 respectively.
The crop yield varied linearly with increasing irrigation depth which was evident from increase in relative transpiration
with increasing depth of water application. However, increased depth of irrigation resulted in less moisture utilisation from
soil storage (20% depletion at 40 mm depth and 4.4% moisture built up at 100 mm depth). The extended simulation study for
sandy soil underlain by loamy sand (Type II) indicated that two pre-sowing irrigations each 40 mm and subsequent irrigations
of 40 mm at an interval of 20 days depending upon rainfall were optimum. This irrigation scenario resulted in zero percolation
loss accompanied by 74% relative transpiration and 14 per cent soil moisture depletion.
Received: 20 November 1995 相似文献
4.
In semi-arid environments, the use of irrigation is necessary for sunflower production to reach its maximum potential. The aim of this study was to quantify the consumptive water use and crop coefficients of irrigated sunflower (Helianthus annuus L.) without soil water limitations during two growing seasons. The experimental work was conducted in the lysimeter facilities located in Albacete (Central Spain). A weighing lysimeter with an overall resolution of 250 g was used to measure the daily sunflower evapotranspiration throughout the growing season under sprinkler irrigation. The lysimeter container was 2.3 m × 2.7 m × 1.7 m deep, with an approximate total weight of 14.5 Mg. Daily ET c values were calculated as the difference between lysimeter mass losses and lysimeter mass gains divided by the lysimeter area. In the lysimeter, sprinkler irrigation was applied to replace cumulative ET c, thus maintaining non-limiting soil water conditions. Seasonal lysimeter ET c was 619 mm in 2009 and 576 mm in 2011. The higher ET c value in 2009 was due to earlier planting and a longer growing season with the maximum cover coinciding with the maximum ET o period. For the two study years, maximum average K c values reached values of approximately 1.10 and 1.20, respectively, during mid-season stage and coincided with maximum ground cover values of 75 and 88 %, respectively. The dual crop coefficient approach was used to separate crop transpiration (K cb) from soil evaporation (K e). As the crop canopy expanded, K cb values increased while the K e values decreased. The seasonal evaporation component was estimated to be about 25 % of ET c. Linear relationships were found between the lysimeter K cb and the canopy ground cover (f c) for the each season, and a single relationship that related K cb to growing degree-days was established allowing extrapolation of our results to other environments. 相似文献
5.
Evaluation of crop water stress index for LEPA irrigated corn 总被引:6,自引:0,他引:6
This study was designed to evaluate the crop water stress index (CWSI) for low-energy precision application (LEPA) irrigated
corn (Zea mays L.) grown on slowly-permeable Pullman clay loam soil (fine, mixed, Torrertic Paleustoll) during the 1992 growing season at
Bushland, Tex. The effects of six different irrigation levels (100%, 80%, 60%, 40%, 20%, and 0% replenishment of soil water
depleted from the 1.5-m soil profile depth) on corn yields and the resulting CWSI were investigated. Irrigations were applied
in 25 mm increments to maintain the soil water in the 100% treatment within 60–80% of the “plant extractable soil water” using
LEPA technology, which wets alternate furrows only. The 1992 growing season was slightly wetter than normal. Thus, irrigation
water use was less than normal, but the corn dry matter and grain yield were still significantly increased by irrigation.
The yield, water use, and water use efficiency of fully irrigated corn were 1.246 kg/m2, 786 mm, and 1.34 kg/m3, respectively. CWSI was calculated from measurements of infrared canopy temperatures, ambient air temperatures, and vapor
pressure deficit values for the six irrigation levels. A “non-water-stressed baseline” equation for corn was developed using
the diurnal infrared canopy temperature measurements as T
c–T
a = 1.06–2.56 VPD, where T
c was the canopy temperature (°C), Ta was the air temperature (°C) and VPD was the vapor pressure deficit (kPa). Trends in
CWSI values were consistent with the soil water contents induced by the deficit irrigations. Both the dry matter and grain
yields decreased with increased soil water deficit. Minimal yield reductions were observed at a threshold CWSI value of 0.33
or less for corn. The CWSI was useful for evaluating crop water stress in corn and should be a valuable tool to assist irrigation
decision making together with soil water measurements and/or evapotranspiration models.
Received: 19 May 1998 相似文献
6.
Effects of applied water and sprinkler irrigation uniformity on alfalfa growth and hay yield 总被引:1,自引:0,他引:1
This study was conducted to investigate the effects of applied water and sprinkler irrigation uniformity on alfalfa (Medicago sativa L.) growth and hay yield in a semi-arid region. Field experiments were carried out in 2006 in Varamin, Iran, on three plots of 25 m × 30 m. Each plot was subdivided into 25 subplots of 5 m × 6 m. Different irrigation depths and sprinkler water uniformities were obtained by various scenarios of sprinkler nozzle pressure. In each plot, applied water was measured at 250 points (125 points above and 125 points below canopy) and the soil water content of 40 cm deep below soil surface was monitored at 25 points, each in the center of a subplot, throughout the irrigation season. The results showed that sprinkler water and soil water content uniformity varied between 66-78 and 88-91%, respectively. The findings revealed that soil water content uniformity was around 20% higher than sprinkler water uniformity. The irrigation uniformity below the canopy was estimated to be 2.5% greater than above the canopy, and canopy-intercepted water could account for 11-15% of the total seasonal applied water. Evaluation showed that alfalfa leaf area index relies more heavily on farm water application uniformity than hay yield and crop height. The experimental results illustrated that water distribution in sprinkler irrigation systems has a direct effect on alfalfa growth, hay yield and water productivity such that the applied water reduction and the increased sprinkler water uniformity led to an increased alfalfa water productivity of 2.41 kg m−3. 相似文献
7.
《Agricultural Water Management》1996,32(1):37-48
Microirrigation techniques can be used to improve irrigation efficiency on vegetable gardens by reducing soil evaporation and drainage losses and by creating and maintaining soil moisture conditions that are favourable to crop growth. Water balance experiments in Zimbabwe showed that over 50% of the water applied as surface irrigation on traditional irrigated gardens can be lost as soil evaporation. This result gives an indication of the potential improvement in irrigation efficiency that can be achieved by adopting irrigation methods that reduce soil evaporation at the same time as minimising losses due to drainage and canopy interception. During the period 1985 to 1995, irrigation trials and experiments were carried out in south-east Zimbabwe and northern Sri Lanka with the main aim of comparing and quantifying the benefits of using simple microirrigation techniques on traditional vegetable gardens. This paper reviews the results of these trials and experiments. Microirrigation techniques that were evaluated included low-head drip irrigation, pitcher irrigation and subsurface irrigation using clay pipes. Of these methods, subsurface irrigation using clay pipes was found to be particularly effective in improving yields, crop quality and water use efficiency as well as being cheap, simple and easy to use. The comparative advantages of subsurface irrigation were maintained for a range of crops grown under different climatic conditions. Good results were also obtained with subsurface irrigation when irrigation was carried out using with poor quality irrigation water. 相似文献
8.
A field experiment was performed to study the effect of the space and time variability of water application on maize (Zea mays) yield when irrigated by a solid set sprinkler system. A solid set sprinkler irrigation layout, typical of the new irrigation developments in the Ebro basin of Spain, was considered. Analyses were performed (1) to study the variability of the water application depth in each irrigation event and in the seasonal irrigation and (2) to relate the spatial variability in crop yield to the variability of the applied irrigation and to the soil physical properties. The results of this research showed that a significant part of the variability in the Christiansen coefficient of uniformity (CU), and wind drift and evaporation losses were explained by the wind speed alone. Seasonal irrigation uniformity (CU of 88%) was higher than the average uniformity of the individual irrigation events (CU of 80%). The uniformity of soil water recharge was lower than the irrigation uniformity, and the relationship between both variables was statistically significant. Results indicated that grain yield variability was partly dictated by the water deficit resulting from the non-uniformity of water distribution during the crop season. The spatial variability of irrigation water depth when the wind speed was higher than 2 m s–1 was correlated with the spatial variability of grain yield, indicating that a proper selection of the wind conditions is required in order to attain high yield in sprinkler-irrigated maize. 相似文献
9.
《Agricultural Water Management》2005,74(3):189-199
Field studies on winter wheat canopy interception with its relations to leaf area index (LAI), plant height, drop diameter, wind speed, and water application intensity were carried out. Canopy interception was measured using the water wiping method. Results indicate that the maximum value of winter wheat canopy interception was not more than 1.0 mm, much smaller than presented by previous investigators. The total canopy interception for the growing season was 2.4 mm, only 1.3% of the total irrigation amount (194.6 mm), for four sprinkler irrigation events during 2003. Canopy interception increased as leaf area index and plant height increased. A linear regression model was developed to express the relationship of canopy interception with leaf area index and plant height. There was good agreement between the values of canopy interception measured using the water wiping method and estimated using the linear regression model. Results also indicate that canopy interception decreased as drop diameter and wind speed increased. An exponential relationship was found between canopy interception and drop size, and a linear relationship between canopy interception and the square of the wind speed. Water application intensity does not affect canopy interception significantly. 相似文献
10.
Evapotranspiration components and dual crop coefficients of coffee trees during crop production 总被引:1,自引:0,他引:1
Danilton Luiz Flumignan Rogério Teixeira de FariaCássio Egídio Cavenaghi Prete 《Agricultural Water Management》2011,98(5):791-800
Quantifying crop water consumption is essential for many applications in agriculture, such as crop zoning, yield forecast and irrigation management. The objective of this study was to determine evaporation (E), transpiration (T) and dual crop coefficients (Ke and Kcb) of coffee trees during crop production (3rd and 4th year of cultivation), conducted under sprinkler and drip irrigation and no irrigation, in Londrina, Paraná State, Brazil. Crop evapotranspiration (ET) was measured by weighing lysimeters cultivated with plants of cultivar IAPAR 59, E was measured by microlysimeters installed on the lysimeters and T was obtained by the difference between ET and E. The crop coefficient (Kc) was determined for the irrigated treatments as the ratio between ET and the reference evapotranspiration (ETo). Similarly, evaporation coefficient (Ke) and basal crop coefficient (Kcb) were determined as the ratio of E and T, respectively, to the value of ETo, which was estimated by the ASCE Penman-Monteith method on an hourly basis. The values of E and Ke varied due to atmospheric demand and water application method. Those factors, in addition to crop phenology and leaf area evolution, also influenced T and Kcb. Regardless irrigation treatment, the measured values of E represented 35% of ET, while T was 65% of ET. The recommended values of Ke were 0.46 and 0.26 for sprinkler and drip irrigation, respectively. The recommended values of Kcb were 0.52 and 0.82 for sprinkler-irrigated, and 0.5 and 0.65 for drip-irrigated treatments, varying as a function of daily ETo (ETo ≥ or <3 mm day−1, respectively). 相似文献
11.
L. Mateos 《Irrigation Science》1998,18(2):73-81
The procedure established in the literature for the evaluation of stationary sprinkler irrigation systems is limited in space
and time since it is based on a sample of precipitation taken around one sprinkler during a given period of the whole irrigation
event. This procedure also ignores what happens in the soil after water infiltrates. A model of the drop trajectory and of
the water distribution pattern is formulated here for simulating precipitation from single sprinklers. The operating pressure
determines sprinkler flow and maximum throw. Wind and evaporation distort the distribution patterns. The water distribution
of individual sprinklers is overlapped to generate precipitation over the whole field and to calculate a coefficient of uniformity.
Field effective uniformity is then calculated by averaging precipitation over the extension of plant roots or water redistribution
within the soil profile. Application of the model has shown the impact of system management and design, field topography and
wind on irrigation uniformity. Management factors such as lateral operation time or riser inclination may account for a large
part of the field precipitation variations. A rough topography may also reduce uniformity significantly. Wind speed is important
when it exceeds 1.8–2 m s–1. The allowable maximum pressure loss of 20% fixed as a design criterion seems an overly strict limit when other factors may
overcome pressure loss as sources of non-uniformity. The sources of non-uniformity have different scales of variation. Large-scale
sources, such as lateral operation time or pressure loss, are not dampened by the crop or soil. Sources of smaller-scale variation,
such as wind or inclination of the sprinkler riser, are better compensated by the crop and soil. The application of this kind
of model to the design and management of sprinkler irrigation systems is discussed.
Received: 9 May 1997 相似文献
12.
J. M. Tarjuelo J. Montero F. T. Honrubia J. J. Ortiz J. F. Ortega 《Agricultural Water Management》1999,40(2-3):315-331
One of the most appropriate sprinkler systems for arid or semi-arid areas – where a great deal of irrigating water is required – are the permanent set systems and the continuous-move laterals. To know the reality of water application in this type of areas, many field evaluations of solid set systems and centre pivot irrigation were conducted in Castilla-La Mancha region (Spain). The main factors affecting water application and evaporation and drift losses with these systems (pressure, wind speed, sprinkler type, etc.) were analysed. A set of performance guidelines and recommendations for the design and management of sprinkle irrigation is presented to attain the highest uniformity and efficiency in water application in semi-arid areas. To use working pressure as low as possible, but with sprinklers that produce a great deal of middle size water drops along with night irrigation for minimising evaporation and drift losses are important aspects. 相似文献
13.
Application of a new method to evaluate crop water stress index 总被引:1,自引:0,他引:1
Optimum water management and irrigation require timely detection of crop water condition. Usually crop water condition can be indicated by crop water stress index (CWSI), which can be estimated based on the measurements of either soil water or plant status. Estimation of CWSI by canopy temperature is one of them and has the potential to be widely applied because of its quick response and remotely measurable features. To calculate CWSI, the conventional canopy-temperature-based model (Jackson’s model) requires the measurement or estimation of the canopy temperature, the maximum canopy temperature (T
cu), and the minimum canopy temperature (T
cl). Because extensive measurements are necessary to estimate T
cu and T
cl, its application is limited. In this study, by introducing the temperature of an imitation leaf (a leaf without transpiration, T
p) and based on the principles of energy balance, we studied the possibility to replace T
cu by T
p and reduce the included parameters for CWSI calculation. Field experiments were carried out in a winter wheat (Triticum aestivum L.) field in Luancheng area, Hebei Province, the main production area of winter wheat in China. Six irrigation treatments were established and soil water content, leaf water potential, soil evaporation rate, plant transpiration rate, biomass, yield, and regular meteorological variables of each treatment were measured. Results indicate that the values of T
cu agree with the values of T
p with a regression coefficient r=0.988. While the values of CWSI estimated by the use of T
p are in agreement with CWSI by Jackson’s method, with a regression coefficient r=0.999. Furthermore, CWSI estimated by the use of T
p has good relations with soil water content and leaf water potential, showing that the estimated CWSI by T
p is a good indicator of soil water and plant status. Therefore, it is concluded that T
cu can be replaced by T
p and the included parameters for CWSI calculation can be significantly reduced by this replacement. 相似文献
14.
Maize (Zea mays L.) and alfalfa (Medicago sativa L.) were simultaneously irrigated in two adjoining plots with the same sprinkler solid-set system under the same operational and technical conditions. The Christiansen's uniformity coefficient (CUC) and the wind drift and evaporation losses (WDEL) were assessed from the irrigation depth (IDC) collected into pluviometers above each crop. A network of pluviometers was located above the maize canopy. Two networks of pluviometers were located above the alfalfa, one above the canopy and the other at the same level as that above the maize. The latter was used to analyze the effects of the water collecting plane. The wind velocity (WV) profile was measured above each crop using anemometers located at three levels. Both the CUC and the WDEL differed between maize and alfalfa.The crops modified both the wind velocity above the canopy and the water interception plane. Both effects were related to the height of the crops (h).When h increased, the water interception plane increased, and the overlap of the sprinklers decreased. The CUC of the IDC increased with the overlap. Because h was greater for maize than for alfalfa, the CUC was noticeably smaller for maize.The WV greatly decreased in proximity to the canopy. The WV at the level of the nozzles was smaller above the maize because the top of the canopy was closer to the nozzles than it was for alfalfa. However, the CUC of the IDC mainly depended on the WV at higher levels, where the WV was similar above both maize and alfalfa. The logarithmic wind profile overestimated the vertical variation of the WV in the space where the sprinklers distributed the water.The WDEL was greater above the maize than above the alfalfa. This finding was related to the underestimation of the IDC above maize, especially under windy conditions, because the pluviometers were located very close to the nozzles. 相似文献
15.
Comparison between the efficiencies of surface and pressurized irrigation systems in Jordan 总被引:1,自引:0,他引:1
A study was carried out to determine the efficiencies of water use in irrigation in the Jordan Valley Project. The study aimed to evaluate, the overall or project efficiency (Ep) which includes: the irrigation system efficiency, being the combined conveyance and distribution efficiency (Es); and the field application efficiency (Ea). Evaluation of these efficiencies includes the comparison of open canals with surface irrigation versus pressurized pipes with sprinkler or drip irrigation systems. Data was collected from different sources to achieve the above mentioned purposes, beside the field experiments which were carried out specially for this study.It was found that the overall or project efficiency (Ep) for open surface canal with surface irrigation under citrus was 53%. While it was 42% under vegetables. Whereas Ep for pressurized pipe systems was 68%, and 70% for sprinkler and drip irrigation methods, respectively.The Es for an open canal, (King Abdullah Canal, KAC) was 65%. While it was 77% for pressurized pipe projects during 1989–1991. Concerning the Ea, it was found to be equal to 82% and 64%, for surface irrigation on citrus and vegetables, respectively. Whereas it was 88% for citrus under sprinkler, and 91% for vegetables under drip irrigation. These values for the field application efficiency are acceptable according to Finkle (1982). The low Es value for the canal is due, mainly, to high evaporation and seepage, unreported deliveries, and unavoidable measurement losses. Whereas, in pressurized pipe projects, it is due to the unreported deliveries, unavoidable measurement losses, and leakage. 相似文献
16.
Intensification of olive cultivation by shifting a tree crop that was traditionally rain fed to irrigated conditions, calls
for improved knowledge of tree water requirements as an input for precise irrigation scheduling. Because olive is an evergreen
tree crop grown in areas of substantial rainfall, the estimation of crop evapotranspiration (ET) of orchards that vary widely
in canopy cover, should be preferably partitioned into its evaporation and transpiration components. A simple, functional
method to estimate olive ET using crop coefficients (K
c=ET/ET0) based on a minimum of parameters is preferred for practical purposes. We developed functional relationships for calculating
the crop coefficient, K
c, for a given month of the year in any type of olive orchard, and thus its water requirements once the reference ET (ET0) is known. The method calculates the monthly K
c as the sum of four components: tree transpiration (K
p), direct evaporation of the water intercepted by the canopy (K
pd), evaporation from the soil (K
s1) and evaporation from the areas wetted by the emitters (K
s2). The expression used to calculate K
p requires knowledge of tree density and canopy volume. Other parameters needed for the calculation of the K
c’s include the ET0, the fraction of the soil surface wetted by the emitters and irrigation interval. The functional equations for K
p, K
pd, K
s1 and K
s2 were fitted to mean monthly values obtained by averaging 20-year outputs of the daily time step model of Testi et al. (this
issue), that was used to simulate 124 different orchard scenarios. 相似文献
17.
《Agricultural Water Management》2002,54(3):189-203
This study was designed to evaluate the yield response of low-energy precision application (LEPA) and trickle-irrigated cotton grown on a clay-textured soil under the arid Southeast Anatolia Project (GAP) area conditions during the 1999 growing season at Koruklu in Turkey. The effects of four different irrigation levels (100, 75, 50, and 25% of cumulative Class-A pan evaporation on a 6-day basis) for LEPA, and two irrigation intervals (3-day and 6-day) and three different levels (100, 67, and 33% of cumulative Class-A pan evaporation on a 3-day and 6-day basis) for the trickle system on yield were investigated. Water was applied to alternate furrows through the double-ended Fangmeier drag-socks in the LEPA system. Trickle irrigation laterals were laid out on the soil surface at a spacing of 1.40 m. A total of 814 mm of water was applied to the full-irrigation treatments (100%) for both irrigation systems. Seasonal water use ranged from 383 to 854 mm in LEPA treatments; and 456 to 868 mm in trickle treatments. Highest average cotton yield of 5850 kg/ha was obtained from the full-irrigation treatment (100%) in trickle-irrigated plots with 6-day intervals. The highest yield in LEPA plots was obtained in LEPA-100% treatment with an average value of 4750 kg/ha. Seed cotton yields varied from 2660 to 5040 kg/ha and 2310 to 5850 kg/ha in trickle irrigation plots with 3-day and 6-day intervals, respectively, and from 2590 to 4750 kg/ha in LEPA plots. Irrigation levels both in LEPA and trickle-irrigated plots significantly increased yield. However, there was no significant yield difference between 100 and 67% irrigation levels in trickle-irrigated plots. Maximum irrigation water use efficiency (IWUE) and water use efficiency (WUE) were found as 0.813 and 0.741 kg/m3 in trickle-irrigated treatment of 67% with 6-day interval. Both IWUE and WUE values varied with irrigation quantity and frequency. The research results revealed that both the trickle and LEPA irrigation systems could be used successfully for irrigating cotton crop under the arid climatic conditions of the GAP area in Turkey. 相似文献
18.
This study compares the effects of different irrigation regimes on seed yield and oil yield quality and water productivity of sprinkler and drip irrigated sunflower (Helianthus annus L.) on silty-clay-loam soils in 2006 and 2007 in the Mediterranean region of Turkey. In sprinkler irrigation a line-source system was used in order to create gradually varying irrigation levels. Irrigation regimes consisted of full irrigation (I1) and three deficit irrigation treatments (I2, I3 and I4), and rain-fed treatment (I5). In the drip system, irrigation regimes included full irrigation (FI-100), three deficit irrigation treatments (DI-25, DI-50, DI-75), partial root zone drying (PRD-50) and rain-fed treatment (RF). Irrigations were scheduled at weekly intervals both in sprinkler and drip irrigation, based on soil water depletion within a 0.90 m root zone in FI-100 and I1 plots. Irrigation treatments influenced significantly (P < 0.01) sunflower seed and oil yields, and oil quality both with sprinkler and drip systems. Seed yields decreased with increasing water stress levels under drip and sprinkler irrigation in both experimental years. Seed yield response to irrigation varied considerably due to differences in soil water contents and spring rainfall distribution in the experimental years. Although PRD-50 received about 36% less irrigation water as compared to FI-100, sunflower yield was reduced by an average of 15%. PRD-50 produced greater seed and oil yields than DI-50 in the drip irrigation system. Yield reduction was mainly due to less number of seeds per head and lower seed mass. Soil water deficits significantly reduced crop evapotranspiration (ET), which mainly depends on irrigation amounts. Significant linear relationships (R2 = 0.96) between ET and oil yield (Y) were obtained in each season. The seed yield response factors (kyseed) were 1.24 and 0.86 for the sprinkler and 1.19 and 1.06 for the drip system in 2006 and 2007, respectively. The oil yield response factor (kyoil) for sunflower was found to be 1.08 and 1.49 for both growing seasons for the sprinkler and 1.36 and 1.25 for the drip systems, respectively. Oil content decreased with decreasing irrigation amount. Consistently greater values of oil content were obtained from the full irrigation treatment plots. The saturated (palmitic and stearic acid) and unsaturated (oleic and linoleic acid) fatty acid contents were significantly affected by water stress. Water stress caused an increase in oleic acid with a decrease in linoleic acid contents. The palmitic and stearic acid concentrations decreased under drought conditions. Water productivity (WP) values were significantly affected by irrigation amounts and ranged from 0.40 to 0.71 kg m−3 in 2006, and from 0.69 to 0.91 kg m−3 in 2007. The PRD-50 treatment resulted in the greatest WP (1.0 kg m−3) and irrigation water productivity (IWP) (1.4 kg m−3) in both growing seasons. The results revealed that under water scarcity situation, PRD-50 in drip and I2 in sprinkler system provide acceptable irrigation strategies to increase sunflower yield and quality. 相似文献
19.
考虑水滴运动蒸发的喷灌水量分布模拟 总被引:3,自引:0,他引:3
提出了有风条件下喷头水滴运动与喷灌水量分布模拟方法,并利用Visual Basic 6.0开发了喷灌水量分布模拟软件.该软件在已知单喷头的径向水量分布数据时,可以模拟出不同风速、风向、空气温湿度等环境条件下单喷头或多喷头组合的喷灌水量分布,计算出喷灌系统的组合喷灌强度、喷灌均匀系数和蒸发损失率.以9708A型喷头为例,分别对工作压力为0.20、0.25和0.30 MPa下单喷头径向水量分布以及喷灌系统组合间距为14 m x 14 m和14 m×12 m时的喷灌水量分布进行了模拟,并与实测值进行了对比,结果表明:模拟的单喷头径向水量分布与实测值总体一致,由模拟水量分布推算的喷头流量与实测值的相对误差为0.83% ~8.01%;喷灌均匀系数模拟值与实测值的相对误差为0.69%~6.36%,蒸发损失率模拟值为0.51% ~ 1.75%,小于实测的水量损失率.模拟了不同组合间距下的喷灌水量分布,得到的喷灌均匀系数模拟值与其他软件比较,相对误差在0.11% ~2.44%之间. 相似文献
20.
Nyland R. Falkenberg Giovanni Piccinni J. Tom Cothren Daniel I. Leskovar Charlie M. Rush 《Agricultural Water Management》2007
The applicability of commercially available remote sensing instrumentation was evaluated for site-specific management of abiotic and biotic stress on cotton (Gossypium hirsutum L.) grown under a center pivot low energy precision application (LEPA) irrigation system. This study was conducted in a field where three irrigation regimes (100%, 75%, and 50% ETc) were imposed on areas of Phymatotrichum (root rot) with the specific objectives to (1) examine commercial remote sensing instrumentation for locating areas showing biotic and abiotic stress symptomology in a cotton field, (2) compare data obtained from commercial aerial infrared photography to that collected by infrared transducers (IRTs) mounted on a center pivot, (3) evaluate canopy temperature changes between irrigation regimes and their relationship to lint yield with IRTs and/or IR photography, and (4) explore the use of deficit irrigation and the use of crop coefficients for irrigation scheduling. Pivot-mounted IRTs and an IR camera were able to differentiate water stress among irrigation regimes. The IR camera distinguished between biotic (root rot) and abiotic (drought) stress with the assistance of groundtruthing. The 50% ETc regime had significantly higher canopy temperatures than the other two regimes, which was reflected in significantly lower lint yields when compared to the 75% and 100% ETc regimes. Deficit irrigation down to 75% ETc had no impact on lint yield, indicating that water savings were possible without reducing yield. 相似文献