Hydrology and Irrigation Systems for Agriculture
A.Y. 2019/2020
Learning objectives
To learn about the main hydrological processes, the quantities that characterize them, the instrumentation and technologies for their measurement. To learn methods of investigation and monitoring techniques to describe the dynamics of water fluxes in the soil-crop-atmosphere system, in order to be able to estimate the irrigation requirements and schedule irrigation events in a rational way. To learn methods of investigation and monitoring techniques to characterize high intensity precipitation events and to describe processes of flood generation, for the design of hydraulic defense structures and river restoration interventions. To learn about collective and on-farm irrigation systems, with particular attention to high-efficiency irrigation systems (sprinkler and micro-irrigation). To explore the different components of on-farm irrigation systems and their management and maintenance. To investigate the criteria for choosing the proper irrigation method and system in the various environmental conditions. To learn about the general and hydraulic design of on-farm irrigation systems and the evaluation of their irrigation efficiency.
Expected learning outcomes
The student will develop expertise related to the acquisition and analysis of meteorological and hydrological data; to the use of GIS software for the processing of spatial information at the farm and territorial scales; to the implementation of a dynamic water balance model for the simulation of the soil-crop-atmosphere system and its use for the scheduling of irrigation events; to the implementation of a dynamic model for the estimation of the flood hydrogram at the closing section of a hydrographic basin and its use for the design of hydraulic defense structures and river restoration interventions. Moreover, the student will be able to find and process data needed for the design of on-farm irrigation systems, to perform the general and hydraulic design of the systems, also using calculation and GIS/CAD tools. The student will acquire skills for assessing technical and economic implications of the project implementation, and will be able to consult technical and scientific material concerning the irrigation sector.
Lesson period: Second semester
Assessment methods: Esame
Assessment result: voto verbalizzato in trentesimi
Single course
This course cannot be attended as a single course. Please check our list of single courses to find the ones available for enrolment.
Course syllabus and organization
Single session
Responsible
Lesson period
Second semester
Course syllabus
UD1: HYDROLOGY
3 CFU (Frontal lessons) - Study of the hydrological cycle and basis of hydrological processes such as precipitation, rainfall interception, evapotranspiration, infiltration and percolation. Methods of physical and mechanical soil analysis and study of soil hydrological properties. Analysis of water movements in saturated and unsaturated soils. Measurement of the main hydrological variables. Calculation of crop water and irrigation needs and irrigation scheduling (irrigation amount and frequency). Estimation of the hydrological balance at a field scale. Statistical analysis of the extreme hydrological events. Calculation of the river discharge duration curves. Assessment of project precipitation. Calculation of hydrological losses using models based on Horton or on Curve Number. Evaluation of the critical rainfall duration. Analysis of runoff processes. Evaluation of the river catchment peak of discharge through rational method, lag-time method and statistical analysis of observed flows.
1 CFU (Practicals in computer lab) - Calculation of crop water needs according to FAO-56 method for different crops and soils, assessment of the irrigation water need at the irrigation district scale (8 hours). Estimation of the river peak discharge under conditions of different rainfall return time and land use changes (8 hours).
UD2: IRRIGATION SYSTEMS FOR AGRICULTURE
3 CFU (Frontal lessons) - Irrigation systems (irrigation intake structures; supply and distribution networks; irrigation methods; drainage networks; irrigation service). Gravitational irrigation methods. Pressurized irrigation methods and systems: sprinkler irrigation with static irrigators and irrigation machines. Pressurized irrigation methods and systems: micro-irrigation (drip irrigation and micro-sprinklers). Advantages and limitations of gravitational, sprinkler and micro-irrigation methods. Theoretical efficiency of irrigation methods and systems. Hydraulic and technological characteristics of irrigators (sprinklers) and micro-irrigators (drippers and micro-sprinklers). Uniformity of distribution. Main components of pressurized systems: pumping group, water quality and filters, pressure reducers, special components, automation components, fertigation systems. Fundamental concepts for the irrigation scheduling: evapotranspiration, hydrological balance in agricultural soils and crop irrigation requirements. Irrigation scheduling: how to determine the amount and frequency of irrigation events with the different irrigation methods. Preliminary design of pressurized irrigation systems. Hydraulic design of pressurized irrigation systems. Examples of calculation.
1 CFU (Practicals in computer lab) - Preliminary and hydraulic design of a drip irrigation system for a maize farm, with the support of a spreadsheet with the implementation of all the main calculation steps, and using GIS and CAD software.
3 CFU (Frontal lessons) - Study of the hydrological cycle and basis of hydrological processes such as precipitation, rainfall interception, evapotranspiration, infiltration and percolation. Methods of physical and mechanical soil analysis and study of soil hydrological properties. Analysis of water movements in saturated and unsaturated soils. Measurement of the main hydrological variables. Calculation of crop water and irrigation needs and irrigation scheduling (irrigation amount and frequency). Estimation of the hydrological balance at a field scale. Statistical analysis of the extreme hydrological events. Calculation of the river discharge duration curves. Assessment of project precipitation. Calculation of hydrological losses using models based on Horton or on Curve Number. Evaluation of the critical rainfall duration. Analysis of runoff processes. Evaluation of the river catchment peak of discharge through rational method, lag-time method and statistical analysis of observed flows.
1 CFU (Practicals in computer lab) - Calculation of crop water needs according to FAO-56 method for different crops and soils, assessment of the irrigation water need at the irrigation district scale (8 hours). Estimation of the river peak discharge under conditions of different rainfall return time and land use changes (8 hours).
UD2: IRRIGATION SYSTEMS FOR AGRICULTURE
3 CFU (Frontal lessons) - Irrigation systems (irrigation intake structures; supply and distribution networks; irrigation methods; drainage networks; irrigation service). Gravitational irrigation methods. Pressurized irrigation methods and systems: sprinkler irrigation with static irrigators and irrigation machines. Pressurized irrigation methods and systems: micro-irrigation (drip irrigation and micro-sprinklers). Advantages and limitations of gravitational, sprinkler and micro-irrigation methods. Theoretical efficiency of irrigation methods and systems. Hydraulic and technological characteristics of irrigators (sprinklers) and micro-irrigators (drippers and micro-sprinklers). Uniformity of distribution. Main components of pressurized systems: pumping group, water quality and filters, pressure reducers, special components, automation components, fertigation systems. Fundamental concepts for the irrigation scheduling: evapotranspiration, hydrological balance in agricultural soils and crop irrigation requirements. Irrigation scheduling: how to determine the amount and frequency of irrigation events with the different irrigation methods. Preliminary design of pressurized irrigation systems. Hydraulic design of pressurized irrigation systems. Examples of calculation.
1 CFU (Practicals in computer lab) - Preliminary and hydraulic design of a drip irrigation system for a maize farm, with the support of a spreadsheet with the implementation of all the main calculation steps, and using GIS and CAD software.
Prerequisites for admission
In order to successfully follow the course, students should meet the following requirements: (a) good theoretical basis of hydraulics; (b) good familiarity with personal computers (Windows environment, word processing and calculation programs).
Teaching methods
Both UDs are articulated into 3 CFU of frontal lectures (24 hours) and 1 CFU of practicals in a computer lab (16 hours). During the computer classroom training hours, the following software will be mainly used: Excel (spreadsheets with the implementation of calculation procedures), QGIS, CAD, Matlab. The attendance at lectures and practicals is recommended. Missed lesson can be substituted by self-study using the reference material indicated by the course lecturer.
Teaching Resources
For students who have to fill previous knowledge gaps, textbook: FONDAMENTI DI IDRAULICA. Mario Gallati e Stefano Sibilla. Carocci Editore, 2009.
UD1: HYDROLOGY
· Lecture note available in line (http://ariel.unimi.it)
· MIPAAF - Paolo Sequi/Marcello Pagliai. Metodi di analisi fisica dei suoli. FrancoAngeli
· Ferro V. (2006). Elementi di idraulica e idrologia per le scienze agrarie ed ambientali. Mc Graw Hill
· Moisello U. (1998). Idrologia tecnica. La Goliardica Pavese.
· Maione U. - Moisello U. (1993). Elementi di statistica per l'idrologia. La Goliardica Pavese.
UD2: IRRIGATION SYSTEMS FOR AGRICULTURE
The material for the course is available on the ARIEL site, and consists of the slides shown during the lectures and of supplementary material, such as reference to book chapters, text of laws, scientific and technical papers and documents, websites.
The reference textbook for the course is: PROGETTAZIONE E GESTIONE DEGLI IMPIANTI DI IRRIGAZIONE - Criteri di impiego e valorizzazione delle acque per uso irriguo. Antonina Capra e Baldassarre Scicolone. Edagricole Editore, 2016.
UD1: HYDROLOGY
· Lecture note available in line (http://ariel.unimi.it)
· MIPAAF - Paolo Sequi/Marcello Pagliai. Metodi di analisi fisica dei suoli. FrancoAngeli
· Ferro V. (2006). Elementi di idraulica e idrologia per le scienze agrarie ed ambientali. Mc Graw Hill
· Moisello U. (1998). Idrologia tecnica. La Goliardica Pavese.
· Maione U. - Moisello U. (1993). Elementi di statistica per l'idrologia. La Goliardica Pavese.
UD2: IRRIGATION SYSTEMS FOR AGRICULTURE
The material for the course is available on the ARIEL site, and consists of the slides shown during the lectures and of supplementary material, such as reference to book chapters, text of laws, scientific and technical papers and documents, websites.
The reference textbook for the course is: PROGETTAZIONE E GESTIONE DEGLI IMPIANTI DI IRRIGAZIONE - Criteri di impiego e valorizzazione delle acque per uso irriguo. Antonina Capra e Baldassarre Scicolone. Edagricole Editore, 2016.
Assessment methods and Criteria
UD1: HYDROLOGY - The exam for UD1 consists of a writing multiple-choice test and a subsequent in-depth interview. The interview mainly focusses on the discussion of a technical report prepared by the student and concerning the topics addressed during the computer classroom training hours.
UD2: IRRIGATION SYSTEMS FOR AGRICULTURE - The exam for UD2 consists of a written test and an oral test. It is more precisely articulated as follows: (a) written test with 2 exercises to choose from 3 assigned (2 hours); (b) written report of the practical exercise carried out in the computer lab (project of the drip irrigation system), to be submitted by the exam registration date; (c) if the student has passed the written exam, oral test aimed at discussing the two previous points and at exposing the theoretical parts of the course not covered by the written test or the report.
UD2: IRRIGATION SYSTEMS FOR AGRICULTURE - The exam for UD2 consists of a written test and an oral test. It is more precisely articulated as follows: (a) written test with 2 exercises to choose from 3 assigned (2 hours); (b) written report of the practical exercise carried out in the computer lab (project of the drip irrigation system), to be submitted by the exam registration date; (c) if the student has passed the written exam, oral test aimed at discussing the two previous points and at exposing the theoretical parts of the course not covered by the written test or the report.
Idrologia
AGR/08 - AGRICULTURAL HYDRAULICS AND WATERSHED PROTECTION - University credits: 4
Computer room practicals: 16 hours
Lessons: 24 hours
Lessons: 24 hours
Professor:
Deangelis Maria Laura
Shifts:
-
Professor:
Deangelis Maria Laura
Progettazione e gestione degli impianti di irrigazione
AGR/08 - AGRICULTURAL HYDRAULICS AND WATERSHED PROTECTION - University credits: 4
Computer room practicals: 16 hours
Lessons: 24 hours
Lessons: 24 hours
Professor:
Facchi Arianna
Shifts:
-
Professor:
Facchi AriannaProfessor(s)