Drill of IPA Terpadu for UM UPI
Aquaponics?
Fish effluent from traditional aquaculture systems is used to fertilize plants in a hydroponic system.
When the two practices are combined they work in a symbiotic relationship to create a natural growing system. The benefits of keeping fish in an aquaponic system include maximum efficiency of water. University trials showed that growing plants in an aquaponic system used 90% less water than soil grown crops, as the only water lost is through evaporation and transpiration. In traditional aquaculture water is discharged regularly often 10-20% of the total water every day, this water is often pumped into open streams where it pollutes and destroys waterways.
Instead of discharging water, aquaponics recycles the water in a reticulating system. Water is pumped from the fish tank through grow beds where the water is cleaned by the plants and media before being returned to the fish tank providing the fish with freshly oxygenated clean water. Hydroponic gardening often relies on the addition of costly chemical nutrients using valuable time, energy and money.
By combining the processes we can easily grow vegetables, herbs and fruits simply by feeding the fish. In an aquaponic system the nutrients are supplied by the fish. They produce ammonia as they breathe and when they excrete waste, this ammonia is converted by beneficial bacteria into nutrients available to the plants. The solids are broken down and filtered in the media beds, effectively cleaning the water before returning it to the fish tank. The good bacteria occur naturally in soil, air and water. They colonise the media and a healthy population is an essential ingredient of any aquaponic system. By working with nature we encourage natural processes that can be monitored and recorded for lessons in schools about integrated science, biology, horticulture, health, society and the environment.
There are many different methods that can be adapted to an aquaponic system including flood and drain, floating rafts on deep water channels or using a nutrient film technique, a style that is very popular in hydroponic operations.
Aquaponics is not a new concept, but a century's old technique that has been practiced by elite societies around the world for thousands of years including the Chinese, Aztecs, Egyptians and Babylonians (Gardens of Babylon).
Aquaculture and hydroponics system for the concurrent production of fish and plant species, wherein a feed is added to meet the fish and plant species nutrient requirements, a method for maintaining dissolved mineral concentrations in the system at optimal levels, determining a nitrogen concentration in said feed that produces a substantially constant nitrogen concentration in the system, for each of a plurality of minerals in the system, determining a rate of decrease of the concentration of said mineral in the system when said nitrogen concentration is maintained substantially constant and supplement said feed with each of said plurality of minerals such that the concentration of the mineral is maintained substantially constant in the system.
Fish effluent from traditional aquaculture systems is used to fertilize plants in a hydroponic system.
When the two practices are combined they work in a symbiotic relationship to create a natural growing system. The benefits of keeping fish in an aquaponic system include maximum efficiency of water. University trials showed that growing plants in an aquaponic system used 90% less water than soil grown crops, as the only water lost is through evaporation and transpiration. In traditional aquaculture water is discharged regularly often 10-20% of the total water every day, this water is often pumped into open streams where it pollutes and destroys waterways.
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Instead of discharging water, aquaponics recycles the water in a reticulating system. Water is pumped from the fish tank through grow beds where the water is cleaned by the plants and media before being returned to the fish tank providing the fish with freshly oxygenated clean water. Hydroponic gardening often relies on the addition of costly chemical nutrients using valuable time, energy and money.
By combining the processes we can easily grow vegetables, herbs and fruits simply by feeding the fish. In an aquaponic system the nutrients are supplied by the fish. They produce ammonia as they breathe and when they excrete waste, this ammonia is converted by beneficial bacteria into nutrients available to the plants. The solids are broken down and filtered in the media beds, effectively cleaning the water before returning it to the fish tank. The good bacteria occur naturally in soil, air and water. They colonise the media and a healthy population is an essential ingredient of any aquaponic system. By working with nature we encourage natural processes that can be monitored and recorded for lessons in schools about integrated science, biology, horticulture, health, society and the environment.
There are many different methods that can be adapted to an aquaponic system including flood and drain, floating rafts on deep water channels or using a nutrient film technique, a style that is very popular in hydroponic operations.
Aquaponics is not a new concept, but a century's old technique that has been practiced by elite societies around the world for thousands of years including the Chinese, Aztecs, Egyptians and Babylonians (Gardens of Babylon).
Aquaculture and hydroponics system for the concurrent production of fish and plant species, wherein a feed is added to meet the fish and plant species nutrient requirements, a method for maintaining dissolved mineral concentrations in the system at optimal levels, determining a nitrogen concentration in said feed that produces a substantially constant nitrogen concentration in the system, for each of a plurality of minerals in the system, determining a rate of decrease of the concentration of said mineral in the system when said nitrogen concentration is maintained substantially constant and supplement said feed with each of said plurality of minerals such that the concentration of the mineral is maintained substantially constant in the system.
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