SENIOR DESIGN PROJECT- 2 MARINE SHIP “OIL TANKER” MECHATRONICS SPECIALIZATION FINAL EXTERNAL PRESENTATION PREPARED BY:- 1)SAUD AHMED NIZAMI(4558) 2)SAQIB.

Slides:

Advertisements

Similar presentations

A force applied over a surface is pressure.

Advertisements

L 13 Fluids [2]: Statics  fluids at rest

Applications of Integration

Mechatronics Department Graduation Project II. OutlineIntroduction. Methodology. Mechanical Design. Control Design.

Chapter 7 Discrete Control Using Wireless Field Devices.

© Blue Graphics Concept Sauer-Danfoss START-UP PROCEDURE PROPEL PUMP Instruction Sauer-Danfoss Belgium – T. Van Mossevelde.

LESSON TWO BEFORE YOU GET UNDERWAY. Key Topics Vessel’s capacity Vessel’s capacity Float plans Float plans Fueling a vessel Fueling a vessel Trailering.

RDP-TEKKEM Precision Hydrated Lime Systems. Lime Silo Precision Dosing Assembly RDP-Tekkem System Controls Lime Slurry Piping Lime Slurry Pump Slurry.

Fire Fighting Robot Prepared by: Fatima Darawsheh Jameela Rabaya.

Adam Hertzlin Dustin Bordonaro Jake Gray Santiago Murcia Yoem Clara P14651: Drop Tower for Microgravity Simulation.

DENEB-R Vessels loading control, stability, strength Short guide.

The tendency or ability of an object to float.

1. Read the problem, pull out essential information and identify a formula to be used. 2. Sketch a diagram if possible. 3. Write down any known rate of.

User Interface The conveyor line is an essential part in the modern industry, and it is one of the major parts that contributed in almost all industrial.

1 Math Questions. 2 Length x Width x Water Depth = cubic feet.

CHS PROBLEM SOLVING

A look at buoyancy and ballast Mr. Williams Grade 8 Science

Prepared By : NUR AZWANI BINTI ZAMRI (A131388). DEFINITION OF ARCHIMEDES PRINCIPLE An object is immersed in a fluid is buoyed up by a force equal to the.

Muhajir Ab. Rahim School of Mechatronic Engineering

Lesson 5 Fluid Systems.

Water Handling Operations

Hydraulic and Pneumatic Transmission

Greg Kelly, Hanford High School, Richland, WashingtonPhoto by Vickie Kelly, 2004 Section 6.7 Work and Pumping Liquids Hoover Dam Nevada & Arizona.

Engineering and Process Control You know more than you realize.

Module 1: Introduction to PLC

Ancillary Services UNIT 10.

CS-EE 481 Spring Founder’s Day, 2006 University of Portland School of Engineering Electric Vehicle Drive System Authors Steven Arlint Abdullah Binsaeed.

L 13 Fluids [2]: Statics  fluids at rest  More on fluids.  How can a steel boat float.  A ship can float in a cup of water!  Today’s weather Today’s.

L 13 Fluids [2]: Statics  fluids at rest  More on fluids.  How can a steel boat float.  A ship can float in a cup of water!  Today’s weather Today’s.

Student Book © 2004 Propane Education & Research CouncilPage Reducing Cargo Tank Vapor Pressure Using a Plant Compressor In order to use.

ARM BASED SMART HELMET USING XBee WITH ALCOHOL DETECTION

CONTENTS: 1.Abstract. 2.Objective. 3.Block diagram. 4.Methodology. 5.Advantages and Disadvantages. 6.Applications. 7.Conclusion.

Mid -Term Presentation Senior Design II Fall 2015.

7.5 - Work. When the force acting on an object is constant, work can be described without calculus But constant force is very limiting. Take a simple.

Student Name USN NO Guide Name H.O.D Name Name Of The College & Dept.

Section 6.4 Work. In physics the word “work” is used to describe the work a force has done on an object to move it some distance. Work done = Force ·

* PowerPoint Presentation *

L 13 Fluids [2]: Statics  fluids at rest  More on fluids.  How can a steel boat float.  A ship can float in a cup of water!  Today’s weather Today’s.

Randy Draeger Grant Stockton David Upp

L 13 Fluids [2]: Statics  fluids at rest  More on fluids at rest  How is atmospheric pressure measured?  Today’s weather Today’s weather Today’s weather.

Simple Water Level Controller Circuit with Microcontroller and Alarm.

SAL COLLEGE OF ENGINEERING AHMEDABAD LIQUID LEVEL MEASUREMENT

Fire Fighting Robotic Vehicle. Introduction:  It is designed to develop a fire fighting robot using RF technology for remote.

Fluid Power Control.

XBee Based Motor Control for Farmers

Container shipping business

LEVEL CONTROL SYSTEM USING MICROCONTROLLER

MODELLING THE CRUDE OIL STORAGE MANAGEMENT

Module 1: Introduction to PLC

Design of the thermosiphon Test Facilities 2nd Thermosiphon Workshop

ENGINEERING PLUMBING AND SANITATION

Work (variable distance)

Stand-Alone Solar PV Energy System

L 13 Fluids [2]: Statics  fluids at rest

An-Najah National University Mechatronics Engineering Department

K.JAHIR HUSSAIN ( ) V.MADHU ( ) E.UTTHAMAGURU ( ) INTENAL GUIDE NAME

Wireless charging FACULTY OF ENGINEERING AND INFORMATION TECHNOLOGY

Special-Purpose Outlets—Water Pump, Water Heater

Design and Implementation of an Automated Conveyor Line

CONSTANTA MARITIME UNIVERSITY FACULTY OF MARINE ENGINEERING Engineering programmed: Marine Engineering (Bachelor’s Degree) THE STUDY OF BALLAST SYSTEM.

Firefighting equipment

L 13 Fluids [2]: Statics  fluids at rest

Design and fabrication of seed planting vehicle. Aim of the project The basic objective Fully automatic controlled of showing operation is to put the.

L 13 Fluids [2]: Statics  fluids at rest

Day 153 – Application of volume of a cylinder

Prepared by : TOLERA TAMIRU SAMSON NIGUSE Microcontroller based Fire Fighting Robot.

Presentation transcript:

SENIOR DESIGN PROJECT- 2 MARINE SHIP “OIL TANKER” MECHATRONICS SPECIALIZATION FINAL EXTERNAL PRESENTATION PREPARED BY:- 1)SAUD AHMED NIZAMI(4558) 2)SAQIB MIRZA(4408) 3)ARSALAN ALI(4539) 4)SAJID MAJEED(4556)

 The Marine Ship ‘Tanker’ is a ship in which oil, chemicals or any liquid forms are loaded to export or import.  In Oil Tanker (Ship) there are some hatches to load oil, petrol or other liquid fluids.  Cargos are loaded with the ballast pumping process in order to stable the Ship.  The project will be used for the trading and Merchant Navy’s purpose.  The driving system of an Oil Tanker (Ship) will be control through XBEE module. INTRODUCTION: INTRODUCTIONINTRODUCTION

 The main problem in launching an Oil Tanker (Ship) is competing in a huge market of ship builders and Ship manufacturing companies. o But China our friendly country may help us to launch Pakistani Oil Tanker for economical rates to Middle East and SAARC countries.  To launch this project is to have a research study and material hunting.  Nowadays, the ballast water tanks is measured by the tube scale and then mariner manually control the ballast pumping process according to the measurement of ballast water. o To eliminate manual control of Ballast Pumping process, we made it autonomous. While loading an Oil Tank the ballast pumping process will be done automatically on the same time.  Another problem is manual control of driving section through wheel. So, in order to eliminate the manual control of driving….. o We have controlled the driving section through XBEE transceiver.  As a Mechatronics Engineer this project is a little bit expensive to represent but teamwork sharing the loads in order to successful completion of Ship. PROBLEM DISCUSSION: PROBLEMDISCUSSIONPROBLEMDISCUSSION

To design and development of Marine Ship ‘Oil Tanker’.  To design and develop structure of Marine Ship ‘Oil Tanker’.  To control the Ballast Pumping Process.  To control the directions of Ship through XBEE Module. AIM: OBJECTIVE: AIM&OBJECTIVEAIM&OBJECTIVE

FUNCTIONALITY:  LOADING OIL HATCHES: While loading and unloading an Oil Hatches, ballast pumping process done in order to keep stable an Oil Tanker (Ship).  Initially all the Ballast Tanks are filled with water. Then the oil will be charge on one port, and on the same time the ballast water will be discharge from the respective port to maintain the stability of Ship.  DRIVING SECTION: Then Oil Tanker move towards the desired position where to export and import cargo through XBEE Transciever. F U N C T I O N A L I T Y

 UNLOADING OIL TANKS: After reaching at desire position, Oil is ready to unload. At unloading part initially all the oil tanks are filled with oil. Then the oil will be unload on one port, and on the same time the ballast water will be load on the respective port in order to ship keeps stable. F U N C T I O N A L I T Y

BALLAST PUMPING PROCESS SCENARIO: B A L L A S T P U M P I N G S C E N A R I O

GENERAL BLOCK DIAGRAM: BLOCKDIAGRAMBLOCKDIAGRAM

SUB-BLOCK DIAGRAM: BALLAST PUMPING: SUBBLOCKDIAGRAMSUBBLOCKDIAGRAM

OIL TANKS: SUBBLOCKDIAGRAMSUBBLOCKDIAGRAM

SUBBLOCKDIAGRAMSUBBLOCKDIAGRAM DRIVING PART: XBEE TRANSMITTER:

XBEE RECEIVER: SUBBLOCKDIAGRAMSUBBLOCKDIAGRAM

SCHEMATICSCHEMATIC

XBEE RECEIVER(DRIVING PART): S C H E M A T I C

BALLAST PUMPING PART:

Valve ‘WUv’ is for unloading & ‘WLv’ is for Water loading Valve, ‘OUPm’ is for Oil unloading pumping machine. ‘WUPm’ is for Water unloading pumping machine, ‘WLPm’ is for Water loading pumping machine & ‘OUPm’ is for Oil.  System initialized.  Pumping machine ‘WLPm’ and ‘WLv2’ activated.  Charge ballast water tank #2.  ‘WLv1’& ‘WLv2’ valve activated.  Charge ballast water tank #1 & 3 simultaneously.  Load oil hatch #1 manually.  Float Sensor Potentiometer resistance varies as oil level changes.  Ballast Tank Valve ‘WUv1’ and ‘WUPm’ activated.  Discharge ballast tank #1 simultaneously.  Then oil hatch # 2 & 3 will be load as well.  Oil loading and Ballast Pumping process completed.  DC motor and servo motor initialization.  Control the Propeller and Rudder through XBEE transciever.  Ship moves towards desire location.  Unload Oil hatch #1 through switch.  Pumping Machine ‘OUPm’ activated.  Pumping machine ‘WLPm’ & valve ‘WLv1’ activated.  Charge ballast tank #1 simultaneously.  Oil hatch #2 & 3 will be unload as well.  Finish. ALGORITHM:-

SIMULATION:- XBEE TRANSMITTER & RECIEVER:

BALLAST PUMPING PART:-

ANIMATION:

TEST RESULT: SHIP STRUCTURE

 General Formula of Buoyancy Force  FB = (V) x (v) x (SPH2O)  v = (based on volume) of the object will be submerged in the water.  v = 70% submerged in WATER  SPH2O = Specific gravity of water  SPH2O = 64 pounds per cubic foot  Ship’s Volume = V = L x B x H  Length = 5.5 ft  Breadth = 2.0 ft  Height = 2.5 ft o V = 5.5 * 2.5 * 2 = 27.5 cubic feet  FB = 27.5 * 0.70 * 64 = 1232 pounds VOLUME & BUOYANCY FORCE CALCULATION:

VOLTAGE LEVEL TESTING (BALAST PUMPING PART) 1.VOLTAGE Vs Quantity of Oil (Table): Table 2.21 ‑ 1

1.VOLTAGE Vs Quantity of Oil (Graph): Table 2.21 ‑ 1

Quantity of Oil Testing (Ballast Pumping Part): 2.Time Vs Quantity of Oil (Table):

2.Time Vs Quantity of Oil (Graph):

WATER QUANTITY TESTING: 3.Time Vs Quantity of Water (Table)

3.Time Vs Quantity of Water (Graph):

DISTANCE IN METER DATA STATUS 0.5DATA RECEIVED 05DATA RECEIVED 12DATA RECEIVED 15DATA RECEIVED XBEE Module Range Testing:

 Keep away “Oil Tanker” from the fire.  To avoid fire “Fire Fighting System” should be near to the Oil Hatches and Engine Room.  To avoid from unbalancing of Ship, do not load Oil Hatches when the Ballast Tanks are empty.  Oil Hatches should be safe from any electrical shock.  Do not load Oil Hatches in adverse and rainy condition.  Do not drive the Ship while loading and unloading SAFETY & PRECAUTIONS:

 We started off the project with aim to design a Marine Ship ‘Oil Tanker’ but with the time and experience it was learnt that this was not at all an easy job, especially the structure of oil tanker and also to make it stable in water. But at last we completed our structure by the help from our teachers, our advisor and ours fellow relatives.  After the completion of first aim we started our work on electronics to make the driving section of ship wireless through XBEE Transceiver.  Then we started work on the Ballast Pumping Process to make it autonomous. By the bless of Allah we successfully achieved our all aim and objectives.  This project has been a successful as far as learning and practical implementation is concerned. CONCLUSION: