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| ===== 2. Background and Related Work ===== | ===== 2. Background and Related Work ===== | ||
| - | //This chapter provides the reader with the relevant technical-scientific background as well as existing related products and research, also known as the state of the art, in the field(s) of the project.// | + | |
| + | |||
| ==== 2.1 Introduction ==== | ==== 2.1 Introduction ==== | ||
| - | This chapter establishes the technical and scientific foundation for the MARIS HABITATS project by situating it within the broader landscape of underwater monitoring and artificial reef design. While the field of marine biology has long utilized static structures for habitat restoration, | ||
| - | By analyzing essential water quality parameters—such as pH, temperature, | + | This chapter establishes the technical |
| + | |||
| + | MARIS HABITATS | ||
| + | |||
| + | The chapter reviews artificial reef concepts, existing companies, material options, sensor | ||
| ==== 2.2 Concepts ==== | ==== 2.2 Concepts ==== | ||
| - | Artificial marine habitats can be designed in several ways to help restore marine ecosystems and support endangered fish species. One approach is the use of 3D-printed reef corals, which can be made from materials such as ceramic, limestone, or eco-concrete. These materials are durable and suitable for marine environments. Examples of projects using this approach include | + | |
| + | Artificial marine habitats can be designed in several ways to help restore marine ecosystems and support endangered fish species. One approach is the use of 3D-printed reef corals, which can be made from materials such as ceramic, limestone, or eco-concrete. These materials are durable and suitable for marine environments. Examples of projects using this approach include Reef Design Lab in Australia, which develops 3D-printed reef structures for marine habitat restoration, | ||
| Another commonly used solution is reef balls. These are concrete dome structures with holes that mimic natural reef caves. Because of their simple design they are easy to mass produce and very stable when placed on the seabed. The holes and cavities provide immediate shelter for fish and other marine animals, allowing the structures to quickly function as protective habitats [(Eternal Reef)], [(Reef Innovations)]. | Another commonly used solution is reef balls. These are concrete dome structures with holes that mimic natural reef caves. Because of their simple design they are easy to mass produce and very stable when placed on the seabed. The holes and cavities provide immediate shelter for fish and other marine animals, allowing the structures to quickly function as protective habitats [(Eternal Reef)], [(Reef Innovations)]. | ||
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| A different method is the creation of Bio-Rock or electric reefs. These reefs consist of metal structures through which a small electrical current is passed. This current causes minerals from seawater to deposit onto the structure, gradually forming a limestone-like coating. This process helps corals grow much faster than under normal conditions, and fish rapidly colonize these artificial reefs. This technique is known as Bio-Rock technology [(BioRocks)]. | A different method is the creation of Bio-Rock or electric reefs. These reefs consist of metal structures through which a small electrical current is passed. This current causes minerals from seawater to deposit onto the structure, gradually forming a limestone-like coating. This process helps corals grow much faster than under normal conditions, and fish rapidly colonize these artificial reefs. This technique is known as Bio-Rock technology [(BioRocks)]. | ||
| - | Artificial habitats can also be designed as modular “fish cities.” These structures include holes of different sizes so that multiple fish species can use them for shelter. Vertical elements are often incorporated to mimic natural reef cliffs, and the modules can be interconnected to create more complex ecosystems that support a greater diversity of marine life [(rrreefs)]. | + | Artificial habitats can also be designed as modular “fish cities”. These structures include holes of different sizes so that multiple fish species can use them for shelter. Vertical elements are often incorporated to mimic natural reef cliffs, and the modules can be interconnected to create more complex ecosystems that support a greater diversity of marine life [(rrreefs)]. |
| Another concept is the development of living seawalls. These are harbor walls or seawalls designed with textured panels and cavities so that marine organisms can attach to them and live on them. Instead of smooth concrete surfaces that support little life, these modified structures create habitats for algae, small invertebrates, | Another concept is the development of living seawalls. These are harbor walls or seawalls designed with textured panels and cavities so that marine organisms can attach to them and live on them. Instead of smooth concrete surfaces that support little life, these modified structures create habitats for algae, small invertebrates, | ||
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| In habitat design, the shape of the structure is often more important than the material used. It is important to include many holes and cavities in different sizes so that different fish species can find suitable shelter. Vertical structures are also important because they mimic natural reef cliffs. In addition, rough surface textures help corals and algae attach and grow on the structures. Finally, ensuring good water flow around the habitat is essential, as it brings nutrients and oxygen that support marine life. | In habitat design, the shape of the structure is often more important than the material used. It is important to include many holes and cavities in different sizes so that different fish species can find suitable shelter. Vertical structures are also important because they mimic natural reef cliffs. In addition, rough surface textures help corals and algae attach and grow on the structures. Finally, ensuring good water flow around the habitat is essential, as it brings nutrients and oxygen that support marine life. | ||
| + | ==== 2.3 Comparative Analysis ==== | ||
| + | The selected companies and solutions are evaluated based on criteria such as reef structure, modularity, material approach, monitoring capability, data collection method, maintenance, | ||
| + | Since MARIS HABITATS is designed to observe how an artificial reef and the surrounding marine conditions change over time, the comparison looks beyond ecological enhancement. It also considers whether each solution can collect, store, and retrieve environmental data for later analysis. | ||
| + | <table tab: | ||
| + | < | ||
| - | ==== 2.3 Products ==== | + | ^ Criteria ^ ECOncrete ^ Reef Design Lab ^ IntelliReefs ^ rrreefs ^ MARIS HABITATS ^ |
| + | | Main business focus | Bio-enhancing concrete for marine and coastal infrastructure | Designed and 3D-printed reef structures | Oceanite-based artificial reef restoration | 3D-printed modular clay reef restoration | Modular reef infrastructure and environmental data | | ||
| + | | Product type | Eco-engineered concrete infrastructure units | Modular reef modules and design services | Artificial reef modules made with Oceanite marine substrate | Interlocking 3D-printed clay reef modules | Reef blocks with a removable smart sensor box | | ||
| + | | Main application | Ports, seawalls, shoreline protection, offshore assets, and subsea cable protection | Reef restoration and marine habitat construction | Coral reef restoration and marine habitat support | Coral reef regeneration and habitat creation | Reef installation, | ||
| + | | Modularity | Moderate | High | High | High | High | | ||
| + | | Ecological design focus | High | High | High | High | Moderate to high | | ||
| + | | Material / design approach | Bio-enhancing concrete composition, | ||
| + | | Integrated sensors | No clear indication as a core product feature | No clear indication | No clear indication | No clear indication | Yes | | ||
| + | | Real-time data transmission | No clear indication | Not specified | Not specified | Not specified | No | | ||
| + | | Long-term local data logging | No clear indication as a core product feature | Not specified | Not specified | Not specified | Yes | | ||
| + | | Data retrieval method | Not specified | Not specified | Not specified | Not specified | SD card / scheduled annual retrieval | | ||
| + | | Service model | Project-based marine infrastructure solution | Design and project-based reef solution | Restoration project-based solution | Impact-driven reef restoration projects with local partners | Reef modules with optional monitoring and data service | | ||
| + | | Main differentiation | Ecological concrete material and infrastructure integration | Complex modular reef design | Alternative Oceanite-based reef material | 3D-printed clay reef modules and local restoration partnerships | Removable sensor box and long-term environmental data | | ||
| - | **MEITEC** | + | </ |
| - | MEITEC | + | The comparison presented in Table {{ref> |
| - | In some cases, MEITEC | + | Compared with these companies, MARIS HABITATS is positioned as a modular reef infrastructure and environmental data solution. The project does not focus only on ecological design or reef structure, but also on collecting environmental data around the reef over time. The main difference is the removable smart sensor box, which stores data locally and allows scheduled retrieval during annual maintenance. |
| + | ==== 2.4 Companies==== | ||
| + | |||
| + | This section reviews selected companies related to artificial reef systems and marine habitat infrastructure. The aim is to understand how existing companies approach reef structure, material choice, modularity, and ecological design. | ||
| + | |||
| + | The review also considers whether these solutions include monitoring or environmental data collection as a core feature. This helps identify the position of MARIS HABITATS as a modular reef infrastructure system with a removable smart sensor box and long-term local data logging. | ||
| + | |||
| + | **ECOncrete** | ||
| + | |||
| + | ECOncrete is a company that develops bio-enhancing concrete technologies for coastal, marine, and offshore infrastructure. Its solutions are designed to improve the ecological performance of concrete structures while still maintaining their engineering function. The company’s approach is applied in infrastructure | ||
| + | |||
| + | The main idea of ECOncrete is to make marine infrastructure less biologically poor than conventional smooth concrete structures. This is achieved through changes in concrete composition, surface texture, and structural design. According | ||
| + | |||
| + | One example of ECOncrete’s application is the Living Ports Project at the Port of Vigo. In this project, ECOncrete Coastalocks and ecologically enhanced seawalls were used to create nature-inclusive port infrastructure. As shown in Figure {{ref> | ||
| + | |||
| + | However, ECOncrete is different from MARIS HABITATS in its main focus. Based on the available product descriptions, | ||
| <WRAP centeralign> | <WRAP centeralign> | ||
| - | <figure fig:MEITEC> | + | <figure fig:ECOncrete> |
| - | <WRAP half column> | + | {{ :report:cordis.jpg? |
| - | {{:report:메이텍.jpg? | + | <caption> |
| - | </WRAP> | + | ECOncrete bio-enhancing coastal protection units used in the Living Ports Project at the Port of Vigo [(CORDIS2025)] |
| - | <WRAP half column> | + | </ |
| - | {{: | + | |
| - | </ | + | |
| - | < | + | |
| </ | </ | ||
| </ | </ | ||
| + | **Reef Design Lab** | ||
| - | **ECOncrete** | + | Reef Design Lab is an Australian design and fabrication company that develops artificial reef and marine habitat solutions. The company describes its work as the design, prototyping, |
| + | |||
| + | One of its well-known systems is MARS, which stands for Modular Artificial Reef Structure. MARS is a ceramic 3D-printed modular system designed to construct reef habitat without the need for heavy-duty equipment. The system can be deployed from small boats and assembled by divers, making it suitable for reef restoration projects in locations where large marine construction equipment may be difficult to use [(ReefDesignLabMARS)]. | ||
| - | ECOncrete develops special types of concrete that are designed | + | Reef Design Lab is relevant |
| - | Even though ECOncrete provides clear ecological benefits, their systems | + | However, Reef Design Lab differs from MARIS HABITATS in its main focus. Based on the available product descriptions, Reef Design Lab mainly |
| <WRAP centeralign> | <WRAP centeralign> | ||
| <figure fig: | <figure fig: | ||
| - | {{ :report:에콘크리트.webp |}} | + | {{ :report:products_mars_new_hero.webp? |
| - | < | + | < |
| + | Reef Design Lab's MARS system, a ceramic 3D-printed modular artificial reef structure [(ReefDesignLabMARS)] | ||
| + | </ | ||
| </ | </ | ||
| </ | </ | ||
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| **IntelliReefs** | **IntelliReefs** | ||
| - | The IntelliReefs | + | IntelliReefs |
| + | |||
| + | The main idea of IntelliReefs | ||
| + | |||
| + | As shown in Figure {{ref> | ||
| + | |||
| + | However, IntelliReefs differs from MARIS HABITATS in its main focus. Based on the available information, | ||
| - | Although IntelliReefs offers flexibility and uses sustainable materials, the available information does not show that the system includes any type of sensor or monitoring technology. Similar to the other solutions, it focuses mainly on providing habitat, without offering tools for real-time environmental data collection or analysis [(IntelliReefs)]. | ||
| <WRAP centeralign> | <WRAP centeralign> | ||
| <figure fig: | <figure fig: | ||
| - | {{:report:intellireef.png? | + | {{ :report:intellireefs.png? |
| - | < | + | < |
| + | IntelliReefs | ||
| + | </ | ||
| </ | </ | ||
| </ | </ | ||
| + | **rrreefs** | ||
| + | rrreefs is a Swiss start-up that focuses on rebuilding and regenerating degraded coral reefs. The company develops a 3D-printed modular reef system made from clay, designed to support coral growth and provide habitat for marine life [(rrreefs)]. | ||
| - | ==== 2.4 Projects ==== | + | The rrreefs system is based on interlocking clay modules that can be arranged in different shapes depending on the local reef conditions and restoration needs. These modules are designed to mimic natural reef structures, create |
| - | For our project involving a marine | + | |
| - | The selection of materials and the structural design of artificial habitats are fundamental | + | rrreefs is relevant |
| - | Studies indicate that the high alkalinity of newly submerged concrete (typically between 12–14) is rapidly diluted by seawater, resulting | + | However, rrreefs differs from MARIS HABITATS |
| - | Based on the research | + | <WRAP centeralign> |
| - | === 2.4.1. Structural Materials === | + | <figure fig: |
| + | {{ : | ||
| + | < | ||
| + | Underwater view of rrreefs modular clay reef structures used for coral reef regeneration [(rrreefs)] | ||
| + | </ | ||
| + | </ | ||
| + | </ | ||
| + | |||
| + | ==== 2.5 Materials ==== | ||
| + | For this project involving a marine habitat at a maximum depth of 50 m off the Portuguese coast, the materials must withstand a pressure of approximately 5 bar while fostering biological growth | ||
| + | |||
| + | The selection of materials and the structural design of artificial habitats are fundamental to ensuring both environmental compatibility and long-term viability. For this project, concrete has been identified as the primary | ||
| + | |||
| + | Studies indicate that the high alkalinity of newly submerged concrete (typically between 12–14) is rapidly diluted by seawater, resulting in no significant long-term detriment to coral growth or benthic colonization [(KNOESTER2024)]. This suggests that ecological success depends less on extended curing periods or pH-neutral mixtures and more on the physical attributes of the habitat. Consequently, | ||
| + | Based on the research and articles reviewed, the following subsection evaluates different material options—ranging from traditional foundations to innovative biocompatible substrates—from which the selection for the most suitable components will be done for this specific implementation. | ||
| + | === 2.5.1. Structural Materials === | ||
| **A. Bacterial (Self-healing) High-Strength Concrete (HSC)** | **A. Bacterial (Self-healing) High-Strength Concrete (HSC)** | ||
| This material incorporates bacterial spores, specifically *Bacillus sphaericus* (strain ATCC 14577), which remain dormant until a crack occurs. Water ingress activates the bacteria, which then precipitate calcium carbonate to seal the crack [(ALYAARI2026)]. | This material incorporates bacterial spores, specifically *Bacillus sphaericus* (strain ATCC 14577), which remain dormant until a crack occurs. Water ingress activates the bacteria, which then precipitate calcium carbonate to seal the crack [(ALYAARI2026)]. | ||
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| **E. Recycled Glass (Partial Aggregate Replacement)** | **E. Recycled Glass (Partial Aggregate Replacement)** | ||
| - | Crushed waste glass used to replace up to 30% of fine aggregates in the concrete mix [(DAAROL2026)]. | + | Crushed waste glass used to replace up to 30 % of fine aggregates in the concrete mix [(DAAROL2026)]. |
| * **Pros:** Improves **chemical resistance** and reduces water absorption [(DAAROL2026)]. It offers an eco-friendly way to utilize waste while maintaining sufficient compressive strength for marine applications [(DAAROL2026)]. | * **Pros:** Improves **chemical resistance** and reduces water absorption [(DAAROL2026)]. It offers an eco-friendly way to utilize waste while maintaining sufficient compressive strength for marine applications [(DAAROL2026)]. | ||
| - | * **Cons:** Replacing more than 30% of aggregate leads to a **significant reduction in compressive strength** [(DAAROL2026)]. | + | * **Cons:** Replacing more than 30 % of aggregate leads to a **significant reduction in compressive strength** [(DAAROL2026)]. |
| * **Price:** Estimated at **90 €/ | * **Price:** Estimated at **90 €/ | ||
| + | |||
| **F. Biorock (Mineral Accretion)** | **F. Biorock (Mineral Accretion)** | ||
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| * **Price:** Base infrastructure **120 €/ | * **Price:** Base infrastructure **120 €/ | ||
| - | --- | + | == 2.5.1.1 Summary Table == |
| - | == 2.4.1.1 Summary Table == | + | The previous subsection regarding the materials evaluated for the project, is sumarized in Table {{ref> |
| - | <color # | + | <WRAP> |
| <table tab: | <table tab: | ||
| - | < | + | < |
| - | | Material | Primary Requisite Met | Pros | Cons | Price (est. / $m^3$) | | + | | Material | Primary Requisite Met | Pros | Cons | Estimated |
| - | | **Bacterial HSC** | Longevity/ | + | | **Bacterial HSC** | Longevity/ |
| - | | **Basalt Reinforcement** | Corrosion Resistance | Non-corrosive; | + | | **Basalt Reinforcement** | Corrosion Resistance | Non-corrosive; |
| - | | **ECOncrete®** | Sea-life Friendly | Neutral pH; bioprotection | Specific mix needs | €140–€180 | | + | | **ECOncrete®** | Sea-life Friendly | Neutral pH; bioprotection | Specific mix needs | 140–180 € | |
| - | | **Recycled Glass** | Sustainability | Increased chemical resistance | Strength loss >30% | €90–€140 | | + | | **Recycled Glass** | Sustainability | Increased chemical resistance | Strength loss > 30 % | 90–140 € | |
| - | | **Biorock** | Life Promotion | 4:1 growth; self-repairing | + | | **Biorock** | Life Promotion | 4:1 growth; self-repairing |
| </ | </ | ||
| + | </ | ||
| + | |||
| + | |||
| + | == 2.5.1.2 Materials for Prototype vs. Final == | ||
| + | |||
| - | == 2.4.1.2 Materials for Prototype vs. Final == | ||
| Here we have another issue, since we have to present a prototype where it has to be functional and pass some test previously mentioned, we need to select a material with similar characteristics to the actual model, in order to be as close as possible. But also that is easy to get and handle since we are gonna be the ones using it. | Here we have another issue, since we have to present a prototype where it has to be functional and pass some test previously mentioned, we need to select a material with similar characteristics to the actual model, in order to be as close as possible. But also that is easy to get and handle since we are gonna be the ones using it. | ||
| - | __//**TO BE CHECKED**// | + | <color #6aa84f>__//**TO BE CHECKED |
| - Option 1 : Basalt fabric-reinforced is attached to abandoned concrete or industrial waste. We need to check the pH level is neutral this process. | - Option 1 : Basalt fabric-reinforced is attached to abandoned concrete or industrial waste. We need to check the pH level is neutral this process. | ||
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| * **cons** There are size limitations depending on the oven and it is different from the model of actual project so not sure if it will approve. | * **cons** There are size limitations depending on the oven and it is different from the model of actual project so not sure if it will approve. | ||
| - | === 2.4.2 Sensor placements === | + | === 2.5.2 Sensor placements === |
| - | Designing a successful marine habitat involves a delicate technical paradox. On one hand, the project’s primary objective is to encourage biological colonization and the growth of marine life; on the other, the integrated sensors require direct, unobstructed contact with seawater to maintain accuracy. This necessity creates a significant challenge, as the very " | + | Designing a successful marine habitat involves a delicate technical paradox. On one hand, the project’s primary objective is to encourage biological colonization and the growth of marine life; on the other, the integrated sensors require direct, unobstructed contact with seawater to maintain accuracy. This necessity creates a significant challenge, as the very " |
| - | To resolve this conflict, | + | To resolve this conflict, |
| - | == 2.4.2.1 Materials for Housing == | + | == 2.5.2.1 Materials for Housing == |
| - | **Titanium alloy (TC4)** or **316 L stainless steel** are recommended for pressure resistance and durability [(SAHOO2025)]. For a 200 m depth, **Titanium** is preferred for long-term corrosion resistance [(evologics)]. | + | |
| - | == 2.4.2.2 Antifouling Coatings == | + | The housing material must protect |
| - | * | + | |
| - | * **CPT (Camptothecin)-based Paint:** A natural compound that has shown virtually no macrofouling after nine months of immersion [(SAHOO2025)]. | + | |
| - | * | + | |
| + | **Titanium alloy (TC4)** or **316 L stainless steel** are recommended for pressure resistance and durability [(SAHOO2025)]. For more than 200 m depth, **Titanium** is preferred for long-term corrosion resistance [(evologics)]. | ||
| + | == 2.5.2.2 Antifouling Coatings == | ||
| + | Even with durable housing materials, marine organisms may attach to exposed surfaces over time. For this reason, antifouling coatings are considered to reduce biological growth on sensors and maintain measurement accuracy. | ||
| + | * | ||
| + | * **CPT (Camptothecin)-based Paint:** A natural compound that has shown virtually no macrofouling after nine months of immersion [(SAHOO2025)]. | ||
| + | * | ||
| - | === 2.4.3 Biologic and geographical analysis === | ||
| - | **Fish structure** | ||
| - | Fish populations are generally associated with habitats that exhibit high structural complexity and spatial heterogeneity. Research suggests that complex environments provide essential ecological resources necessary for survival, including food availability, | ||
| - | Artificial and natural reefs typically contain irregularities and indentations that form small shelters or “nooks”, | ||
| - | Studies also indicate that fish communities tend to perform better in connected habitat mosaics rather than isolated structures [(Graham2013)]. Networks of habitats may facilitate movement, feeding opportunities, | + | === 2.5.3 Biologic |
| - | **Location** | + | **Fish structure** |
| - | The location of artificial reefs plays a key role in determining their effectiveness. The chosen site should encourage marine life to settle while avoiding interference | + | Fish populations are generally associated |
| - | Most of the Artificial | + | Artificial |
| + | Studies also indicate that fish communities tend to perform better in connected habitat mosaics rather than isolated structures [(Graham2013)]. Networks of habitats may facilitate movement, feeding opportunities, | ||
| + | **Location** | ||
| + | The location of artificial reefs plays a key role in determining their effectiveness. The chosen site should encourage marine life to settle while avoiding interference with human activities such as shipping routes or commercial fishing areas. Water depth is another important consideration. Reefs placed too deep may not receive enough sunlight to support the growth of marine plants like algae, whereas reefs that are too shallow can be more vulnerable to damage from storms or human activity [(PHAROS2024)]. | ||
| - | + | Most of the artificial reef projects are placed at the depth of 10-20 meters, but it all depends | |
| - | ==== 2.5 Comparative Analysis ==== | + | |
| - | + | ||
| - | The selected solutions were evaluated based on criteria such as cost, monitoring capability, structural complexity, sustainability, | + | |
| - | + | ||
| - | <table tab_label1> | + | |
| - | < | + | |
| - | ^ Criteria ^ MEITEC ^ ECOncrete ^ IntelliReefs ^ | + | |
| - | | Cost | Medium | High | Medium–High | | + | |
| - | | Real-time Monitoring | No | No | No | | + | |
| - | | Data Transmission | No | No | No | | + | |
| - | | Structural Complexity | Low–Medium | Medium | High | | + | |
| - | | Sustainability | Medium | High | High | | + | |
| - | | Durability (Corrosion Resistance) | High | High | Medium | | + | |
| - | | Ecological Performance | Medium | High | High | | + | |
| - | | Material Type | Conventional concrete | Eco-enhanced concrete | Alternative eco-materials | | + | |
| - | | Modularity | Low | Medium | High | | + | |
| - | | Scalability | High | Medium | Medium | | + | |
| - | | Maintenance Requirements | Low | Low–Medium | Medium | | + | |
| - | | Data-driven Decision Support | No | No | No | | + | |
| - | | Innovation Level | Low | Medium | Medium–High | | + | |
| - | + | ||
| - | </ | + | |
| - | + | ||
| - | + | ||
| - | ==== 2.6 Summary ==== | + | |
| - | //Provide here the conclusions | + | |
| - | + | ||
| - | < | + | |
| - | </ | + | |
| - | + | ||
| - | The comparison indicates that current artificial reef solutions primarily focus on structural | + | |
| - | + | ||
| - | However, none of the analyzed solutions incorporate real-time monitoring or data transmission capabilities. This represents a significant limitation, as the effectiveness of marine restoration projects cannot be easily measured or optimized without continuous environmental data. | + | |
| - | + | ||
| - | In addition, while modularity and structural complexity vary among solutions, scalability and long-term adaptability remain key challenges in existing systems. | + | |
| - | Based on this analysis, it was observed that existing solutions provide valuable approaches to habitat design and ecological enhancement, | ||
| - | The design direction was therefore developed to combine the strengths of current solutions—such as sustainability, | ||