Exploring a Self-Sufficiency Approach within a Sustainable Integrated Pisciculture Farming System
Abstract
:1. Introduction
1.1. Enhancing Farm Autonomy, Self-Sufficiency and Waste Management Strategies
1.2. Self-Sustaining Agricultural Practices
1.3. Approaches towards Sustainable, Resilient and Innovative Systems in Fish Farming
1.4. Current Integration of Renewable Energy in Aquaculture Practices
2. Materials and Methods
2.1. Self-Sufficient and Sustainable Farming System and Model Design
2.2. Equipment and Resources Required for the Experimental Fish Pond
2.2.1. Power Requirements Analysis and Designing Energy Consumption Plan
2.2.2. Power Production and Energy Storage Installations
2.2.3. The Effect of Locally Produced Feed on the Growth of Three Carp Species
2.2.4. Assessment of Statistically Significant Differences among Feed Recipes
2.3. Water and Sludge Management and Conservation
2.4. Economic Viability
2.5. Composting Phase for Ecological Waste Management and Fertilizer Production
3. Results
3.1. Power Requirements Analysis for Fish Pond Operations and Energy Consumption Plan Design
3.2. Power Production and Energy Storage
3.3. Self-Sustaining Feed Production System for Raising Carp in Fish Ponds
3.4. Assessment of Statistically Significant Differences among Feed Recipes
3.5. Developing an Evaluation Model to Assess the Self-Sustainability of the Aquaculture System
4. Discussion
5. Conclusions
Author Contributions
Funding
Institutional Review Board Statement
Informed Consent Statement
Data Availability Statement
Conflicts of Interest
References
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Indicators Achieved to Meet Sustainability and Self-Sustaining Requirements | Grading * | ||||||
---|---|---|---|---|---|---|---|
Objectives | Indicator | Requirement Fulfillment | 1 | 2 | 3 | 4 | 5 |
Resource Efficiency | Energy Use | -Highly efficient in energy consumption, providing a customized consumption regime that flattens power consumption peaks; -Renewable energy sources such (hybrid photovoltaic–wind turbines, coupled with energy storage system for safety. | |||||
Water Utilization | -The wastewater coming from fish farming is used entirely for irrigation in agriculture, and there is no pollution of the emissary (rivers); -Due to the special construction of the fishing pond (waterproof reinforced concrete), there is no pollution of the underground waters; -There is high efficiency in using water per unit of food and endowments regarding water recycling and purification systems. | ||||||
Nutrient Management | -Feed produced locally using local technology and ingredients demonstrates fish growth comparable to that achieved with purchased feed; -Wastes generated from feed production are reintegrated back into the system. | ||||||
System Reliability | Operational Stability | The system operates consistently under normal and stress conditions, including ability to handle variations in weather, resource availability, and potential system failures. The carp is a species that does not show a high sensitivity to the technological problems that may arise. | |||||
Low Maintenance Requirements | -Low frequency and cost of maintenance are needed to keep the system functioning optimally. Maintenance costs can increase over time, due to the high level of automation. | ||||||
Flexibility and Scalability | Adaptability | -The system has an increased ability to adapt to different environments, scales of operation, and changing resource conditions. However, local climatic conditions can negatively influence energy production. | |||||
Expansion Potential (scale up or down) | -The technology can be scaled up or down to meet varying demands or to integrate into larger production systems. However, there is a strong dependance on several factors such as climatic conditions, type of fish raised, and fertility of the soil for feed production. | ||||||
Ease of Operation | -Easy for operators to use, with simple management tasks and minimal expertise required. | ||||||
Integration with Existing Systems | -The system integrates with existing agricultural or energy systems, ensuring compatibility with current infrastructure and technologies. | ||||||
Productivity | Yield | -Achieving a substantial yield of products and energy relative to the inputs utilized, considering factors such as growth rates, harvest times, and overall productivity per unit volume. | |||||
Environmental Impact | Carbon Footprint | -Reducing the GHG emissions, including direct and indirect emissions associated with energy use, production processes, and waste management and transportation (compared to conventional systems). | |||||
Biodiversity and Ecosystem Health | -Highly positive impact on local biodiversity and ecosystem services, including substantial benefits such as reducing surface and underground water pollution and mitigating river nitrification. | ||||||
Climate Resilience | -Ability to withstand and adapt to climate-related challenges, including extreme weather events and long-term climate change. | ||||||
Renewability | -Reliance on renewable resources and capacity to minimize depletion of non-renewable resources. | ||||||
Social Impact | Community Benefits | -System may support local communities, including job creation, food security, and social equity (especially in the production of cereals). However, the increased level of automation reduces the effort with the farm’s labor force, therefore not contributing to the creation of new jobs. | |||||
Resource Resilience | -High capacity to manage resource scarcity or variability, including fluctuations in energy, water, and nutrient availability | ||||||
Local Economy | The system contributes to the local economy, including impacts on local businesses, markets, and economic resilience. |
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Share and Cite
Voicea, I.; Nenciu, F.; Vlăduț, N.-V.; Matache, M.-G.; Persu, C.; Cujbescu, D. Exploring a Self-Sufficiency Approach within a Sustainable Integrated Pisciculture Farming System. Sustainability 2024, 16, 8055. https://doi.org/10.3390/su16188055
Voicea I, Nenciu F, Vlăduț N-V, Matache M-G, Persu C, Cujbescu D. Exploring a Self-Sufficiency Approach within a Sustainable Integrated Pisciculture Farming System. Sustainability. 2024; 16(18):8055. https://doi.org/10.3390/su16188055
Chicago/Turabian StyleVoicea, Iulian, Florin Nenciu, Nicolae-Valentin Vlăduț, Mihai-Gabriel Matache, Catalin Persu, and Dan Cujbescu. 2024. "Exploring a Self-Sufficiency Approach within a Sustainable Integrated Pisciculture Farming System" Sustainability 16, no. 18: 8055. https://doi.org/10.3390/su16188055
APA StyleVoicea, I., Nenciu, F., Vlăduț, N. -V., Matache, M. -G., Persu, C., & Cujbescu, D. (2024). Exploring a Self-Sufficiency Approach within a Sustainable Integrated Pisciculture Farming System. Sustainability, 16(18), 8055. https://doi.org/10.3390/su16188055