際際滷

際際滷Share a Scribd company logo

Summary(group 55)

Mahzabin Alamgir Teethi
Mahzabin Alamgir Teethi

This document describes a project to design and implement an automatic irrigation system. It discusses three main components: 1) A solar tracking device that uses sensors and a microcontroller to adjust solar panels to maximize sunlight, 2) An automatic pump control system that uses a water level sensor to turn a pump on and off to refill a water tank, and 3) An automatic irrigation system that uses a soil moisture sensor to open and close a solenoid valve to control water flow to fields based on moisture levels. The document outlines the system architecture, provides block diagrams of each component, discusses simulations of the full system, and concludes the system allows more efficient, less labor intensive irrigation.

1 of 4
Downloaded 11 times
息 Faculty of Engineering, American International University Bangladesh Design and Implementation of an Automatic Irrigation System Project Group # 55 Under the supervision of Md. Saniat Rahman Zishan Assistant Professor American International University - Bangladesh Fall Semester 2013-2014 December, 2013 1. Alamgir, Mahzabin 10-16538-2 2. Chowdhury, Alma Taziz 10-16884-2 3 Mollah, Gloria 10-16583-2 4. Mullick, Homaira Amina 09-14880-3
息 Faculty of Engineering, American International University Bangladesh Design and Implementation of an Automatic Irrigation System Alamgir, Mahzabin, Mollah, Gloria , Chowdhury, Alma Taziz, Mullick, Homaira Amina Department of Electrical and Electronic Engineering, American International University-Bangladesh Abstract Automation is very important in the advanced world. Automation makes life more easier, reduces time for working manually and spontaneous. In an irrigation based country it is very important to have a developed irrigation system. This project deals with the automatic operation of the pump to supply water in the field depending on the soil moisture. The system can be operated using solar energy or even the DC voltage converted from AC. This is done by programming in ATmega328. Index Terms Introduction, Solar Tracking Device, Automatic pump control, Automatic Irrigation System, Simulation, References, Conclusion. I. INTRODUCTION Use of proper method of irrigation is significant in the field of agriculture. To fulfill this necessity we introduce an advanced automatic irrigation system. In this automatic system, we have used sensors, digital circuits, water sources and a control unit. An ATMEGA328 microcontroller is used which plays the part to control the whole process of irrigation. It is programmed to turn on a solenoid when the moisture in the soil falls below a certain level which is detected by a moisture sensor. Our circuit implemented, aims to sense and monitor the irrigation system which in turn makes the entire irrigation process much more efficient, less time consuming and less labor intensive. To achieve our goal of a totally automated farm, we decided to cascade three individual projects and merge them into one. The three projects in action are: An automatic solar tracking device. Automatic pump controller. Automatic farm irrigation system II. ARCHITECTURE OF THE SYSTEM The Automatic Irrigation System is designed in such a way that irrigation can be done automatically using less labour, less time and without wasting water. This is done by merging three different projects into an individual one where which of them got specific operation in the system. A. Solar Tracking Device Solar panels are fitted on the solar tracker. This device tracks the solar energy following the position of the sun during the day so that maximum amount of sunlight is received by the solar panel with the motion of the sun. Using solar panels increased efficiencies can be achieved. It is mostly used in remote areas where there is scarcity of electricity or electrical lines are not situated. The selection of tracker depends on many factors some of which are installation size, electric rates, government incentives, land constraints, latitude, and local weather. The solar tracker reduces the consumption of electricity with greater efficiency. This tracker is accompanied with the LDR variation of resistance and feeds the data to the microcontroller. The microcontroller sends signal to the servo motor. The backelite sheet is required to mount the Light dependant resistors (LDRs). The servo motor shifts the position of the solar panels as required sensed by the light dependant resistor (LDR). The LCD display whether solar energy is generated or not. In this way the solar tracking device operates. Figure 2 : Block Diagram of Solar tracker The block diagram above depicts the behavior of the solar tracker. The block diagram shows that the power is supplied to the microcontroller ATMEGA 328. Light dependant resistor (LDR), servo motor and LCD display are connected to the microcontroller. As we see, a light dependent resistor (LDR) senses the position of the sun, through the variation of resistance and feeds the data to the
息 Faculty of Engineering, American International University Bangladesh microcontroller. The microcontroller sends signal to the servo motor. The backelite sheet is required to mount the Light dependant resistors (LDRs). The servo motor shifts the position of the solar panels as required sensed by the light dependant resistor (LDR). The LCD display whether solar energy is generated or not. In this way the solar tracking device operates. B. Automatic Pump Controller Automatic Pump Control system consists of a water storage, water level detector and indicator, relay, solar tracker, dc motor and microcontroller. This automatic pump control can work using two different inputs solar energy from Solar tracking device and from main power supply. The solar tracker will take the solar energy as an input to the relay that switches it on, switching the pump on to supply the water to the water storage tank. This can also be done when there is no solar power. When solar power is unavailable, that is during night, the power is taken from a dc motor which gets power from the ac (main) supply. The switching on of the pump depends on the water level of the storage. The water level detector has two different levels set-one of them is maximum or high level and the other is low or minimum level. When it detects that the water is at low or minimum level, it will send a signal to the microcontroller to turn on the pump and supply water to the storage and according to the level of the water in the storage, the LEDs will blink which are connected to the water level indicator. There are three LEDs connected to the water level indicator. When one LED or no LED glows then the second relay is switched on to start the pump so that water starts to fill in the storage and as the water level increases the rest of the LEDs starts to glow. When all the LEDs glow, then the relay stops the pump. When the water level is low the pump is switched on and when the water level is high the pump is switched off. This is how the Automatic pump control works as a whole. Figure: The hardware implementation of the automatic pump control system. C. Automatic Farm Irrigation system The automatic irrigation system consists of the soil moisture sensor to sense the soil moisture and feed the input in the microcontroller, the solenoid valve to allow the water supply to the field depending on the soil moisture detected, the microcontroller to control all the operations, the LCD display and the power supply as shown in the block diagram below. Figure: Block diagram for the automatic irrigation system. The Block diagram of an automatic irrigation system using moisture sensor is showed above. It consists of a an Arduino with ATmega328 Microcontroller, Moisture sensor, solenoid valve , power supply and LCD Display. At first, the moisture sensor senses the amount of moisture content in the soil and inputs it to the microcontroller. Depending on the moisture content of the soil, it will input the microcontroller to turn on or turn off the solenoid valve which actually gives a pressure to turn on the pump and supply water to the fields. The Moisture level is displayed in the LCD display. III.Simulation Figure: Final simulation.
息 Faculty of Engineering, American International University Bangladesh The diagram shows the full simulation of our project. The simulation is done using Proteus version 7.8. The simulation shows the full experimental setup. The project consists of three parts- Solar tracking device, automatic pump control and Automatic Irrigation system using Moisture sensor. The Solar tracker captures the energy from the sun and use it to convert it generate electricity. This electricity is used to drive the automatic pump control system. The Automatic pump control consists of two relays connected in series and a dc motor. The automatic pump control system can be turned on in two different ways- using the main supply and using the solar energy. When the solar power is available then controller uses the solar power. When it is unavailable then the controller uses the dc power which is converted from ac supply. The solar power is in one input of the first relay and the dc power is connected in the other input. The output of the first relay is connected as the input of the second relay. The output of water level detector and indicator also works as an input to the microcontroller. The water level indicator indicates by lighting LEDs, that is there are three LEDs attached with the Indicator. Microcontroller sends the signal to the dc motor accordingly to switch on or off the pump in the water tank. The soil moisture sensor senses the soil moisture and informs the microcontroller to open the solenoid valve which basically is used to give force to turn on the pump. IV. Conclusion Our paper provided the design processes to build a large system consisting of several individual parts with several functions. For hardware implementation, proper organizations had to be made to make the parts to communicate with each other smoothly with very minimum error. Analysis has been shown and on the basis of the analysis, proper decisions were made that required for completely implementing the automatic irrigation system. The whole system together exhibit numerous features which can be used in several ways according to need and thus our designed and implemented automatic irrigation system is quite user friendly too. REFERENCES [1] Automatic Irrigation Based on Soil Moisture for Vegetable Crops [Online] (Accessed on 10.9.2013) Available: http://edis.ifas.ufl.edu/pdffiles/ae/ae35400.pdf [2] Automatic Irrigation systems [Online] (Accessed on 6.8.2013) Available: http://www.chilliwacktimes.com/news/automatic- irrigation-systems-1.431180 [3] Sun power signature black solar panels [Online] (Accessed on 8.10.2013) Available: http://us.sunpowercorp.com/homes/products- services/solar-panels/signature-black/ [4] The advantages of water level controller [Online] (Accessed on 14.10.2013) Available: http://www.ehow.com/info_8688159_advantages-water- level-controller.html [5] Case Study 4, 09 | 2012 Solar powered Vineyard Irrigation system [Online] (Accessed on 8.10.2013) Available: http://www.lorentz.de/pdf/lorentz_casestudy_vineyardlurt on_chile_en-en.pdf [6] VH400 Soil moisture sensor probes [Online] (Accessed on 12.11.2013) Available: http://www.vegetronix.com/Products/VG400/

More Related Content

Summary(group 55)

  • 1. 息 Faculty of Engineering, American International University Bangladesh Design and Implementation of an Automatic Irrigation System Project Group # 55 Under the supervision of Md. Saniat Rahman Zishan Assistant Professor American International University - Bangladesh Fall Semester 2013-2014 December, 2013 1. Alamgir, Mahzabin 10-16538-2 2. Chowdhury, Alma Taziz 10-16884-2 3 Mollah, Gloria 10-16583-2 4. Mullick, Homaira Amina 09-14880-3
  • 2. 息 Faculty of Engineering, American International University Bangladesh Design and Implementation of an Automatic Irrigation System Alamgir, Mahzabin, Mollah, Gloria , Chowdhury, Alma Taziz, Mullick, Homaira Amina Department of Electrical and Electronic Engineering, American International University-Bangladesh Abstract Automation is very important in the advanced world. Automation makes life more easier, reduces time for working manually and spontaneous. In an irrigation based country it is very important to have a developed irrigation system. This project deals with the automatic operation of the pump to supply water in the field depending on the soil moisture. The system can be operated using solar energy or even the DC voltage converted from AC. This is done by programming in ATmega328. Index Terms Introduction, Solar Tracking Device, Automatic pump control, Automatic Irrigation System, Simulation, References, Conclusion. I. INTRODUCTION Use of proper method of irrigation is significant in the field of agriculture. To fulfill this necessity we introduce an advanced automatic irrigation system. In this automatic system, we have used sensors, digital circuits, water sources and a control unit. An ATMEGA328 microcontroller is used which plays the part to control the whole process of irrigation. It is programmed to turn on a solenoid when the moisture in the soil falls below a certain level which is detected by a moisture sensor. Our circuit implemented, aims to sense and monitor the irrigation system which in turn makes the entire irrigation process much more efficient, less time consuming and less labor intensive. To achieve our goal of a totally automated farm, we decided to cascade three individual projects and merge them into one. The three projects in action are: An automatic solar tracking device. Automatic pump controller. Automatic farm irrigation system II. ARCHITECTURE OF THE SYSTEM The Automatic Irrigation System is designed in such a way that irrigation can be done automatically using less labour, less time and without wasting water. This is done by merging three different projects into an individual one where which of them got specific operation in the system. A. Solar Tracking Device Solar panels are fitted on the solar tracker. This device tracks the solar energy following the position of the sun during the day so that maximum amount of sunlight is received by the solar panel with the motion of the sun. Using solar panels increased efficiencies can be achieved. It is mostly used in remote areas where there is scarcity of electricity or electrical lines are not situated. The selection of tracker depends on many factors some of which are installation size, electric rates, government incentives, land constraints, latitude, and local weather. The solar tracker reduces the consumption of electricity with greater efficiency. This tracker is accompanied with the LDR variation of resistance and feeds the data to the microcontroller. The microcontroller sends signal to the servo motor. The backelite sheet is required to mount the Light dependant resistors (LDRs). The servo motor shifts the position of the solar panels as required sensed by the light dependant resistor (LDR). The LCD display whether solar energy is generated or not. In this way the solar tracking device operates. Figure 2 : Block Diagram of Solar tracker The block diagram above depicts the behavior of the solar tracker. The block diagram shows that the power is supplied to the microcontroller ATMEGA 328. Light dependant resistor (LDR), servo motor and LCD display are connected to the microcontroller. As we see, a light dependent resistor (LDR) senses the position of the sun, through the variation of resistance and feeds the data to the
  • 3. 息 Faculty of Engineering, American International University Bangladesh microcontroller. The microcontroller sends signal to the servo motor. The backelite sheet is required to mount the Light dependant resistors (LDRs). The servo motor shifts the position of the solar panels as required sensed by the light dependant resistor (LDR). The LCD display whether solar energy is generated or not. In this way the solar tracking device operates. B. Automatic Pump Controller Automatic Pump Control system consists of a water storage, water level detector and indicator, relay, solar tracker, dc motor and microcontroller. This automatic pump control can work using two different inputs solar energy from Solar tracking device and from main power supply. The solar tracker will take the solar energy as an input to the relay that switches it on, switching the pump on to supply the water to the water storage tank. This can also be done when there is no solar power. When solar power is unavailable, that is during night, the power is taken from a dc motor which gets power from the ac (main) supply. The switching on of the pump depends on the water level of the storage. The water level detector has two different levels set-one of them is maximum or high level and the other is low or minimum level. When it detects that the water is at low or minimum level, it will send a signal to the microcontroller to turn on the pump and supply water to the storage and according to the level of the water in the storage, the LEDs will blink which are connected to the water level indicator. There are three LEDs connected to the water level indicator. When one LED or no LED glows then the second relay is switched on to start the pump so that water starts to fill in the storage and as the water level increases the rest of the LEDs starts to glow. When all the LEDs glow, then the relay stops the pump. When the water level is low the pump is switched on and when the water level is high the pump is switched off. This is how the Automatic pump control works as a whole. Figure: The hardware implementation of the automatic pump control system. C. Automatic Farm Irrigation system The automatic irrigation system consists of the soil moisture sensor to sense the soil moisture and feed the input in the microcontroller, the solenoid valve to allow the water supply to the field depending on the soil moisture detected, the microcontroller to control all the operations, the LCD display and the power supply as shown in the block diagram below. Figure: Block diagram for the automatic irrigation system. The Block diagram of an automatic irrigation system using moisture sensor is showed above. It consists of a an Arduino with ATmega328 Microcontroller, Moisture sensor, solenoid valve , power supply and LCD Display. At first, the moisture sensor senses the amount of moisture content in the soil and inputs it to the microcontroller. Depending on the moisture content of the soil, it will input the microcontroller to turn on or turn off the solenoid valve which actually gives a pressure to turn on the pump and supply water to the fields. The Moisture level is displayed in the LCD display. III.Simulation Figure: Final simulation.
  • 4. 息 Faculty of Engineering, American International University Bangladesh The diagram shows the full simulation of our project. The simulation is done using Proteus version 7.8. The simulation shows the full experimental setup. The project consists of three parts- Solar tracking device, automatic pump control and Automatic Irrigation system using Moisture sensor. The Solar tracker captures the energy from the sun and use it to convert it generate electricity. This electricity is used to drive the automatic pump control system. The Automatic pump control consists of two relays connected in series and a dc motor. The automatic pump control system can be turned on in two different ways- using the main supply and using the solar energy. When the solar power is available then controller uses the solar power. When it is unavailable then the controller uses the dc power which is converted from ac supply. The solar power is in one input of the first relay and the dc power is connected in the other input. The output of the first relay is connected as the input of the second relay. The output of water level detector and indicator also works as an input to the microcontroller. The water level indicator indicates by lighting LEDs, that is there are three LEDs attached with the Indicator. Microcontroller sends the signal to the dc motor accordingly to switch on or off the pump in the water tank. The soil moisture sensor senses the soil moisture and informs the microcontroller to open the solenoid valve which basically is used to give force to turn on the pump. IV. Conclusion Our paper provided the design processes to build a large system consisting of several individual parts with several functions. For hardware implementation, proper organizations had to be made to make the parts to communicate with each other smoothly with very minimum error. Analysis has been shown and on the basis of the analysis, proper decisions were made that required for completely implementing the automatic irrigation system. The whole system together exhibit numerous features which can be used in several ways according to need and thus our designed and implemented automatic irrigation system is quite user friendly too. REFERENCES [1] Automatic Irrigation Based on Soil Moisture for Vegetable Crops [Online] (Accessed on 10.9.2013) Available: http://edis.ifas.ufl.edu/pdffiles/ae/ae35400.pdf [2] Automatic Irrigation systems [Online] (Accessed on 6.8.2013) Available: http://www.chilliwacktimes.com/news/automatic- irrigation-systems-1.431180 [3] Sun power signature black solar panels [Online] (Accessed on 8.10.2013) Available: http://us.sunpowercorp.com/homes/products- services/solar-panels/signature-black/ [4] The advantages of water level controller [Online] (Accessed on 14.10.2013) Available: http://www.ehow.com/info_8688159_advantages-water- level-controller.html [5] Case Study 4, 09 | 2012 Solar powered Vineyard Irrigation system [Online] (Accessed on 8.10.2013) Available: http://www.lorentz.de/pdf/lorentz_casestudy_vineyardlurt on_chile_en-en.pdf [6] VH400 Soil moisture sensor probes [Online] (Accessed on 12.11.2013) Available: http://www.vegetronix.com/Products/VG400/