AQUAPONICS SYSTEM FOR TREAT A CATFISH WASTEWATER

 

Table Of Contents


Chapter ONE

INTRODUCTION

  • 1.1Introduction
  • 1.2Background of Study
  • 1.3Problem Statement
  • 1.4Objective of Study
  • 1.5Limitation of Study
  • 1.6Scope of Study
  • 1.7Significance of Study
  • 1.8Structure of the Research
  • 1.9Definition of Terms

Chapter TWO

LITERATURE REVIEW

  • 2.1Overview of Aquaponics System
  • 2.2Principles of Aquaponics
  • 2.3Benefits of Aquaponics
  • 2.4Types of Aquaponics Systems
  • 2.5Components of Aquaponics System
  • 2.6Nutrient Cycling in Aquaponics
  • 2.7Challenges in Aquaponics
  • 2.8Success Stories of Aquaponics
  • 2.9Aquaponics vs. Traditional Farming
  • 2.10Future Trends in Aquaponics

Chapter THREE

RESEARCH METHODOLOGY

  • 3.1Research Design
  • 3.2Population and Sampling
  • 3.3Data Collection Methods
  • 3.4Data Analysis Techniques
  • 3.5Research Ethics
  • 3.6Research Limitations
  • 3.7Instrumentation
  • 3.8Data Validity and Reliability

Chapter FOUR

DATA PRESENTATION AND ANALYSIS

  • 4.1Aquaponics System Implementation
  • 4.2Water Quality Monitoring
  • 4.3Fish Growth and Health Assessment
  • 4.4Plant Growth and Nutrient Uptake
  • 4.5System Troubleshooting
  • 4.6Economic Viability Analysis
  • 4.7Environmental Impact Assessment
  • 4.8Stakeholder Engagement

Chapter FIVE

SUMMARY, CONCLUSION AND RECOMMENDATIONS

  • 5.1Summary of Findings
  • 5.2Conclusion
  • 5.3Recommendations
  • 5.4Implications for Future Research
  • 5.5Contribution to Knowledge

Project Abstract

<p>&nbsp;               <b>ABSTRACT&nbsp;</b></p><p>The combination of fish and plant production in an integrated recirculation system is called Aquaponics System. In natural waters, ammonium is converted rather rapidly to nitrite and further to nitrate by aerobic bacteria from the genera Nitrosomonas and Nitrobacter, through a process called nitrification. Ammonia (NH3) is the waste products of the fish and extremely toxic to fish. First nitrifying process is by Nitrosomonas bacteria. Nitrosomonas bacteria is cultured in the grow beds (gravel). This bacteria feed on both oxygen' and ammonia and with their biological activities. Reaction of Nitrosomonas bacteria produces excretes a chemical called nitrite (NO2). Nitrite is toxic to fish but not toxic as ammonia. Second of nitrifying process is by Nitrobacter bacteria. Nitrobacter bacteria also cultured in the grow beds (gravel). These bacteria utilize oxygen in its respiration, acts in similar way as Nitrosomonas bacteria. Reaction of Nitrobacter bacteria have changes the nitrite into a relatively harmless chemical called nitrate (NO3). Nitrate is primary source of plant nutrition. Plants take in the converted nirates as nutrients. The nutrients are a fertilizer, feeding the plants. This system produces the clean water to fish tank and ready for next cycle. The aims of this research are to determine the characteristics of water quality from the cultured catfish (Siluriforme) tank, to determine effect of vegetable (Ipomoea aquatic) distribution on the wastewater quality and effect of the vegetable (Ipomoea aquatic) growth. The results found the ideal range of temperature 27.92°C to 29.14°C and ideal range of pH 6.50- 6.94. The temperature and pH in fish tank in controlled conditions. Besides that, the results of BOD5, COD, TSS and N}14 - N concentration have decrease responding to retention time. It is because of nitrifying process and the growing root of plants and increasing the plants in Aquaponics. Besides that, Ipomoea aquatic grow rapidly and seemed healthy <br></p>

Project Overview

<p> 1<b>.1 BACKGROUND OF PROPOSED STUDY&nbsp;</b></p><p>The combined culture of fish and plants in re-circulating systems is called aquaponics (Graber &amp; Junge, 2009, p.148). Nutrients flow from wastewater generated by the fish, either by direct excretion or the microbial breakdown of organic wastes are absorbed by plants cultured hydroponically. Aquaponics also known as the integration of hydroponics with aquaculture is gaining increased attention as bio- integrated food production. Nutrient-rich effluent from fish tanks in aquaponics is used to fertigate hydroponic production beds. This is good for the fish because plant roots and rhizobacteria remove nutrients from the water. Fish mature, algae and decomposing fish feed are generated the nutrients. These nutrients are contaminants that would otherwise build up to toxic level in the fish tank, but instead serve as liquid fertilizer to hydroponically grown plants. The hydroponic beds function as a biofilter where ammonia, nitrates, nitrites and phosphorus are stripping off. So, the freshly cleansed water can then be re-circulated back into the fish tank. The plant roots in association with the nitrifying bacteria living in the gravel play a critical role in nutrient cycling without these microorganisms the whole system would stop functioning. Thus, aquaponics sytem can enable the production of fresh vegetables and fish protein since it is water re-uses system. Nutrient removal is essential for aquaculture wastewater treatment to protect receiving water from eutrophication and for potential reuse of the treated water. The integration of aquaculture with agriculture appears to be an excellent way of saving water, disposing aquaculture wastewater and providing fertilizer to the agriculture crop. <br></p><p> <b>1.2 STATEMENT OF PROBLEM&nbsp;</b></p><p>The intensive development of the aquaculture industry has been accompanied by an increase in environmental impact. Discharges from aquaculture into the aquatic environment generate substantial amounts of polluted effluent, containing uneaten feed and feces. Wastewater from aquaculture contains nutrients, various organic and inorganic compounds such as ammonium, phosphorus, dissolved organic carbon and organic matter. The high levels of nutrients cause environmental deterioration of the receiving water sources. Wastewater treatment of aquaculture is important because in many areas, water is a limited resource and depending on the receiving water source. The total nutrients form effluents can contribute to significant environmental degradation. The concept of aquaponics involves integrating aquaculture and hydroponics is gaining increased attention as a bio- integrated food production systems (Fox, Howerton &amp; Tamatu, 2010). Reuse the nutrient released by fish to grow crop plants is the primary goal of aquaponics. Aquaponics systems are more environmentally sustainable than most traditional farming practices, which have resulted in widespread soil erosion, desertification and pollution in Asia (A. Endut, A. Jusoh, N. Ali, &amp; W.B. Wan Nik, 2011). Thus, aquaponics system efficient use of resources, reduction in risk of total crop failure, additional sources of food, extra income and reduction of operation costs for farmers than fish culture alone.</p><p> <b>1.3 RESEARCH OBJECTIVES&nbsp;</b></p><p>The objectives of this research are: L To determine the characteristics of water quality from the cultured fish tank. ii. To determine effect of vegetable distribution on the wastewater quality iii. Effect of the vegetable growth 1.4 SCOPE OF PROPOSED STUDY In the proposed study, an aquaponics system is my conducted research. I will determine the water quality characteristics from culture fish tank. Besides, I will determine effect of vegetable distribution on the wastewater quality and effect of the vegetable growth. Fish species is an important material in my research besides vegetables. I used catfish (Siluriformes) as fish species and water spinach (Ipomoea aquatic) as vegetable to run my experiment. The catfish I get from Agro Bazaar, Sungai Pekan and brought back to my lab in University Malaysia Pahang (lIMP). In my experimental design, I will build a mini aquaponics system. The waste discharge from catfish will treat by Ipomoea aquatic roots and bacteria's and return to fish tank as a clean water. The parameters that will be observed are Biochemical Oxygen Demand (BOD), Chemical Oxygen Demand (COD), Total Suspended Solids (TSS), Ammonia Nitrogen (NH) and pH. During the experiment, the heights of plant were observed and record every day. &nbsp; <br></p>

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