Smart bivalve purification system development
| Main Author: | |
|---|---|
| Publication Date: | 2023 |
| Format: | Master thesis |
| Language: | eng |
| Source: | Repositórios Científicos de Acesso Aberto de Portugal (RCAAP) |
| Download full: | http://hdl.handle.net/10773/41836 |
Summary: | The contamination of coastal areas caused by rising industrial activity is an expanding issue that substantially impacts bivalve molluscs. Known for their ability to filter their surroundings and essential to the world’s fishing industry for food, molluscs affected by bacteria require decontamination. The objective of this dissertation is to develop a purification system for areas classified as Class C in terms of E. coli contamination. The proposed system involves immersing bivalves in a tank of filtered seawater for a specified duration, where they expel the bacteria from their organisms via excrement, liberting bacteria eliminated within the Water Purification Zone. During the preliminary stage, LEDs with a wavelength of 254 nm were chosen as they were optimal for dealing with E. Coli. A circuit was constructed to monitor and regulate the energy supplied to the LEDs. Furthermore, the radiated power was analysed in relation to the input power and the wavelength where that power was being irradiated. Three depuration experiments were carried out. 3D structures were created and printed for the first trial to support one and three LED strip configurations. A comparison was made between their performance and a conventional UV lamp, with the result that the three-strip LED configuration was more effective. During the second round of testing, two different configurations of three LED strips were trialled, with one-strip configuration being excluded due to its previous underperformance. To monitor water quality, pH, temperature, ORP, water flow and turbidity sensors were integrated into the process, and both LED configurations were found to outperform the conventional UV lamp. In the final section of the experiment, the system’s ultimate design was showcased. This included a PCB responsible for controlling the LED power and monitoring sensors, alongside solenoid valves designed for filling and emptying the tank’s water. In addition, nitrite and salinity sensors were also installed. To collect and store data from the purifiers, a data centre was implemented into a Raspberry Pi utilising the MQTT protocol, and a graphical user interface was created for visualising the data. The findings have established that LEDs are more effective than conventional UV lamps at purifying E. Coli in shellfish. |
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Smart bivalve purification system developmentBivalve depurationLEDMonitorization sensorsE. Coli.The contamination of coastal areas caused by rising industrial activity is an expanding issue that substantially impacts bivalve molluscs. Known for their ability to filter their surroundings and essential to the world’s fishing industry for food, molluscs affected by bacteria require decontamination. The objective of this dissertation is to develop a purification system for areas classified as Class C in terms of E. coli contamination. The proposed system involves immersing bivalves in a tank of filtered seawater for a specified duration, where they expel the bacteria from their organisms via excrement, liberting bacteria eliminated within the Water Purification Zone. During the preliminary stage, LEDs with a wavelength of 254 nm were chosen as they were optimal for dealing with E. Coli. A circuit was constructed to monitor and regulate the energy supplied to the LEDs. Furthermore, the radiated power was analysed in relation to the input power and the wavelength where that power was being irradiated. Three depuration experiments were carried out. 3D structures were created and printed for the first trial to support one and three LED strip configurations. A comparison was made between their performance and a conventional UV lamp, with the result that the three-strip LED configuration was more effective. During the second round of testing, two different configurations of three LED strips were trialled, with one-strip configuration being excluded due to its previous underperformance. To monitor water quality, pH, temperature, ORP, water flow and turbidity sensors were integrated into the process, and both LED configurations were found to outperform the conventional UV lamp. In the final section of the experiment, the system’s ultimate design was showcased. This included a PCB responsible for controlling the LED power and monitoring sensors, alongside solenoid valves designed for filling and emptying the tank’s water. In addition, nitrite and salinity sensors were also installed. To collect and store data from the purifiers, a data centre was implemented into a Raspberry Pi utilising the MQTT protocol, and a graphical user interface was created for visualising the data. The findings have established that LEDs are more effective than conventional UV lamps at purifying E. Coli in shellfish.A contaminação das zonas costeiras, intensificada pelo aumento da atividade industrial, constitui um problema crescente que afeta significativamente os moluscos bivalves, organismos conhecidos pela sua capacidade de filtrar o meio ambiente onde habitam. Estes moluscos desempenham um papel crucial na indústria pesqueira a nível global, no que toca a alimentação, sendo necessária a descontaminação destes quando infetados por bactérias. O objetivo desta dissertação prende-se em desenvolver um sistema de depuração eficaz para zonas classificadas como Classe C em termos de contaminação por E. Coli. Este sistema de depuração é constituído por um tanque de água marinha limpa, onde os bivalves são colocados durante um período definido para expelirem as bactérias presentes nos seus organismos através de fezes, sendo estas posteriormente eliminadas na zona de purificação de água. Na fase inicial do desenvolvimento, foram selecionados LEDs com um comprimento de onda de 254 nm, ideal para a eliminação de E. Coli. Foi construído um circuito eletrónico que permite controlar a potência fornecida aos LEDs, sendo realizados testes para avaliar o comportamento da potência irradiada relativamente à potência fornecida. Foi também verificado o comprimento de onda onde a potência era irradiada. Foram conduzidas três experiências de depuração. Na primeira, foram projetadas e impressas estruturas 3D para suportar configurações de uma e três tiras de LEDs. Os seus desempenhos foram comparados com uma lâmpada UV convencional, onde a configuração de três tiras de LEDs mostrou-se mais eficiente. No segundo ensaio, foram testadas duas configurações de três tiras de LEDs, excluindo a configuração de uma tira devido ao seu desempenho insatisfatório registado anteriormente. Foram ainda integrados sensores de pH, temperatura, ORP, fluxo de água e turbidez para monitorizar a qualidade da água, tendo ambas as configurações de LEDs superado a lâmpada UV convencional. Na última secção da experiência, apresentou-se a arquitetura final do sistema, incluindo um PCB para gerir a potência dos LEDs e os sensores de monitorização, para além de umas eletrovávulas com função de enchimento e esvaziamento da água do tanque. Foram ainda acrescentados sensores de nitritos e salinidade. Implementou-se também uma central de dados numa RPi, utilizando o protocolo MQTT para recolher e armazenar os dados das depuradoras, e foi criada uma interface gráfica para a sua visualização. Os resultados confirmaram a superioridade dos LEDs em relação às lâmpadas UV convencionais na depuração eficaz de E. Coli em bivalves.2029-01-02T00:00:00Z2023-12-20T00:00:00Z2023-12-20info:eu-repo/semantics/publishedVersioninfo:eu-repo/semantics/masterThesisapplication/pdfhttp://hdl.handle.net/10773/41836engFerreira, Gonçalo Dinizinfo:eu-repo/semantics/embargoedAccessreponame:Repositórios Científicos de Acesso Aberto de Portugal (RCAAP)instname:FCCN, serviços digitais da FCT – Fundação para a Ciência e a Tecnologiainstacron:RCAAP2024-05-13T01:46:29Zoai:ria.ua.pt:10773/41836Portal AgregadorONGhttps://www.rcaap.pt/oai/openaireinfo@rcaap.ptopendoar:https://opendoar.ac.uk/repository/71602025-05-28T16:35:56.445130Repositórios Científicos de Acesso Aberto de Portugal (RCAAP) - FCCN, serviços digitais da FCT – Fundação para a Ciência e a Tecnologiafalse |
| dc.title.none.fl_str_mv |
Smart bivalve purification system development |
| title |
Smart bivalve purification system development |
| spellingShingle |
Smart bivalve purification system development Ferreira, Gonçalo Diniz Bivalve depuration LED Monitorization sensors E. Coli. |
| title_short |
Smart bivalve purification system development |
| title_full |
Smart bivalve purification system development |
| title_fullStr |
Smart bivalve purification system development |
| title_full_unstemmed |
Smart bivalve purification system development |
| title_sort |
Smart bivalve purification system development |
| author |
Ferreira, Gonçalo Diniz |
| author_facet |
Ferreira, Gonçalo Diniz |
| author_role |
author |
| dc.contributor.author.fl_str_mv |
Ferreira, Gonçalo Diniz |
| dc.subject.por.fl_str_mv |
Bivalve depuration LED Monitorization sensors E. Coli. |
| topic |
Bivalve depuration LED Monitorization sensors E. Coli. |
| description |
The contamination of coastal areas caused by rising industrial activity is an expanding issue that substantially impacts bivalve molluscs. Known for their ability to filter their surroundings and essential to the world’s fishing industry for food, molluscs affected by bacteria require decontamination. The objective of this dissertation is to develop a purification system for areas classified as Class C in terms of E. coli contamination. The proposed system involves immersing bivalves in a tank of filtered seawater for a specified duration, where they expel the bacteria from their organisms via excrement, liberting bacteria eliminated within the Water Purification Zone. During the preliminary stage, LEDs with a wavelength of 254 nm were chosen as they were optimal for dealing with E. Coli. A circuit was constructed to monitor and regulate the energy supplied to the LEDs. Furthermore, the radiated power was analysed in relation to the input power and the wavelength where that power was being irradiated. Three depuration experiments were carried out. 3D structures were created and printed for the first trial to support one and three LED strip configurations. A comparison was made between their performance and a conventional UV lamp, with the result that the three-strip LED configuration was more effective. During the second round of testing, two different configurations of three LED strips were trialled, with one-strip configuration being excluded due to its previous underperformance. To monitor water quality, pH, temperature, ORP, water flow and turbidity sensors were integrated into the process, and both LED configurations were found to outperform the conventional UV lamp. In the final section of the experiment, the system’s ultimate design was showcased. This included a PCB responsible for controlling the LED power and monitoring sensors, alongside solenoid valves designed for filling and emptying the tank’s water. In addition, nitrite and salinity sensors were also installed. To collect and store data from the purifiers, a data centre was implemented into a Raspberry Pi utilising the MQTT protocol, and a graphical user interface was created for visualising the data. The findings have established that LEDs are more effective than conventional UV lamps at purifying E. Coli in shellfish. |
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2023 |
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