WORKING SAMPLE FOR INTERN 2021 IN HENNING LARSEN
PORTFOLIO 2019-2022
Juntian Chen
02. REORGANIZATION OF RECLAMATION Inland flood prevention+Coastal freshwater supply WORKS 03. URBAN (CIRCULAR) FOOD SYSTEM Facilitating circular food system in city region Renovation of community from children's perspective 04. GREEN LINK Ecoduct+Green trail 05. PILOT PROJECTS OF CHILDREN FRIENDLY COMMUNITY 01. LAVA DIVERSION Iava prevention infrastructures+Regenerative landscapel
02. REORGANIZATION OF RECLAMATION
Integrating Inland flood prevention and
Coastal freshwater supply
Ecological importance of the site Current
Study of the Jiangsu tidal flat and coastal environment
reclamation process
Idle land after tidal flat reclamation Tidal flat and salt marsh A.build concret barrier B.Salt elimination C.Agriculture&water channel Industry in the reclamation zone Intensive aquaculture Idle land after reclamation Pollution from local industry Intensive aquaculture
Future planning of tidal flat reclamation and landcover change in the research zone
In the coastal area of Jiangsu Province, according to current coastal reclamation and development plan of the province (2010), the distribution and management of the land for reclamation is based on the area between 2 different river esturies along the coastal line. In the map below, the future plan of tidal flat reclamation area between different esturies in 3 municipalities (Nantong, Yancheng and Lianyungang) are mapped based on the study of literature and existing document. In this project, Rudong is chosen to be the research zone for further study
Future planning of tidal flat reclamation
The distribution of the reclamation area is based on the location of esturies
Research zone (Rudong country)
Reclamation plays a vital role in providing land for urban expansion and guaranteeing the food security for the Jiangsu Province (Yu and Xu.2017). Recent land reclamation schemes will cause 44%–45% loss of the most important ecotopes on mid-range and low-range littoral zones (Muller et al.2020). Based on the data from landsat 4-8, The maps below shows the trend of different types of landcover. In summary, the right chart shows that the area of tidal flat has been declining since 2000 and the area of land reclamation has been growing since 1996.
Landcover change in the research zone
Landcover (1995)
Built area and agriculture: 727991100m²
Bare land: 42759000m²
Aquaculture: 32673600m²
Tidal flat: 395082900m²
Landcover (2000)
Built area and agriculture: 718479000m²
Bare land: 85581000m²
Aquaculture: 33068700m²
Tidal flat: 500102100m²
Landcover (2005)
Built area and agriculture: 743504400m²
Bare land: 75237300m²
Aquaculture: 73177200m²
Tidal flat: 382016700m²
Landcover (2010)
Built area and agriculture: 895839300m²
Bare land: 128404800m²
Aquaculture: 46798200m²
Tidal flat: 300813300m²
Landcover (2015)
Built area and agriculture: 884268000m²
Bare land: 142115400m²
Aquaculture: 106347600m²
Tidal flat: 271883700m²
Landcover (2021)
Built area and agriculture: 919288800m²
Bare land: 117594900m²
Aquaculture: 147304800m²
Tidal flat: 178367400m²
A g ic lt e b ld g 7 7 9 0 M B a e n d 4 7 0 0 ² A q c ltu e 3 6 36 0 T a fla 3 5 2 00 L A N D C O V E R (1995 ) A g i u l a b ild n g 8 2 8 0 ² B a e n 14 1154 0 M A q c ltu e 10 34 6 0 ² T da fla 2 18 8 7 0 M ² L A N D C O V E R (20 15 ) A gric ltu e n b ld g 8 9 8 9 0 B are n d 12 0 0 A qu c ltu e 4 6 9 2 0 M ² T a fla 3 8 0 M L A N D C O V E (20 10 ) A g ic ltu e an b ld n g 7 35 4 4 0 B a e n d 7 2 7 0 A q c ltu e 7 17 20 M T a fla 3 0 7 M L A N D C O V E R (20 5 ) A g ic lt e b ld g 7 7 0 M B are n d 8 58 00 ² A qu c ltu e 3 6 7 M T a fla 5 10 0 L A N D C O V E (2000 ) A g i u lt an b ild n g 9 2 8 M B a e n 117 9 9 0 M A q c ltu e 14 30 8 0 M T da fla 17 36 0 ² L A D C O V E R (20 21) 0 20000 40000 60000 80000 100000 120000 140000 1995 2000 2005 2010 2015 2021 Land reclamation Tidal flat Year 100M²
Current landuse pattern and landuse trajetories of 3 types of coastal reclamation area
Current landuse pattern and landuse trajetories of 3 different reclamation area
Based on previous study, there are 3 typical landuse pattern based on different suitability: 1. Not suitable for both agriculture and urban development ("Tidal flat→halophytes→cropland") , 2. Suitable for agriculture ("Tidal flat→halophytes→aquaculture pond→cropland"). 3. Suitable for urban development ("Tidal flat→halophytes→cropland→construction land" in the central par t of the province's coastal area).
1: Not suitable for both agriculture / urban development
2: Suitable area for agriculture / aquaculture
3: Suitable area for urban development
Landuse trajetories and relevant soil problems
IDLE L AND IDLE L AND
salinity
Soil
EUTROPHICATION
Idle tidal flat
soil for farming Greenhouse Aquaculture Aquaculture Urban development Urban development Crop land Halophytes Halophytes Tidal flat Tidal flat Tidal flat Tidal flat Idle land Tidal flat Crop land Crop land Crop land Crop land Crop land Halophytes Suitable for construction Eutrophication of water Eutrophication of soil Productivity Organic matter Soil salinity Productivity Organic matter Soil salinity Construction Construction Halophytes→Agriculture Halophytes→Agriculture 7 years 26 years 7 years 4 years 4 years Salt discharge Farming Farming Halophytes→Aquaculture Productivity Organic matter SITE SITE SITE
Suitable
Reorganization of the reclamation process for 3 types of coastal reclamation area
Strategies of reorganizing the reclamation process for area with 3 different suitability
Based on previous study, 3 new landuse solutions are proposed: 1. Not suitable for both agriculture and urban development (return farmland and restore salt marsh) , 2. Suitable for agriculture(aquaculture between terraced field for salt discharge). 3. Suitable for urban developme (buffer for canal and restore wetland). The aim is for balancing the time, ecological value and economical profit in the process of developing reclamation area.
Managed relignment+ Siltation Promotion
Not suitable for both agriculture / urban development
Salt elimination+ Aquaculture in terraced field
Suitable area for agriculture / aquaculture
Restore wetland+ More room for the canal
Suitable area for urban development
Integrated water strategies for 3 different types of reclamation zone
Broader context
Nature based water strategies for risk mitigation+freshwater supply
Flood from May to October
Freshwater supply capacity: 37.6 billion m³
Freshwater demand: 60 billion m³
30% of the planned drainage capacity
1.Multifunctional peak (fresh) water storage + flood defence
2.Nature based coastal salinization defence solutions
Freshwater (+)
Salinization (-)
Stereoscopic agriculture zone
Construc ed wetland+freshwater storage Reclamation zone with soil salin zation
Wa er efficient agriculture
Potential peakwa er storage zone+ wet agriculture
er s orage
Suitability assessment of 3 development modes in the new reclamation zone 3 development modes in the new reclamation zone and water integration strategies
In Northern Jiangsu, there are 3 types of developing modes for most of the tidal flat reclamation areas based on 3 categories of suitability, and they are 1)suitable for agriculture,2)suitable for urban development,3)not suitable for both agriculture and urban development (Chen Cheng. 2017). For the area 1, the development mode is: “halophytes→aquaculture pond→cropland”, for the area 2, the development mode is: “halophytes→ cropland”, for the area 3, the development mode is “halophytes→cropland→urban development”(Xu et al.2017). Meanwhile, the development modes is also relevant to the per GDP of coastal municipalities (He et al.2021).
Indicators
and their weights for the suitability assessment of the tidal flat reclamation area
Legend
Construc ed tidal inlet
Reconstruc ed fringing marsh
Stereoscopic agriculture
Boundar y of towns
Double dike Sea dike
Second grade river
First grade river (canal)
Freshwater direction
Tidal flat
Urban
Salt marsh and halophytes
Potential oom for peakwater storage+Wet agricultu e
Existing water body
Suitability + 3 development modes
river Chayang river
Not suitable for agriculture and urban(halophytes→cropland)
Suitable for agriculture (halophytes→aquacultu e pond→c opland)
Suitable for urban development (halophytes→c opland→urban)
Pre-cond t on or choos ng the landuse type ndex Factor Agriculture We ght N ot su table for agriculture and urban Weigh Urban deve opment Weight pH √ 0 1804 Organic matter √ 0 1803 Fresh wa er avai abi ty Prox mity to resh water channel √ 0 2867 √ 0 1875 Water depth o the shorel ne √ 0 2245 Barr er condi ion √ Tida range √ Landscape resources Prox m ty o t da f at landscape √ 0 3852 Eco og cal mportance Eco og ca mportance √ 0 3506 √ 0 4045 √ 0 1457 Environmenta capac ty Water qua ty √ 0 2103 √ 0 1967 Location Transportation Accessib l ty √ 0 2456 Shore ne cond t on Soi qual ty Eco og ca condi ion Condition of ocal resources
KM Rutai canal Jiuwei canal Juekan river Jueju river
Yangkou Po Yangkou canal Dongling river Estuary o Bencha canal Estua y o Mafeng canal Estuary o Jueju canal Estuary o Juekan canal Estuary o Rutai canal
ma sh Existing fringing marsh Opening the sea dike
sewage plant+nitrification
Ocean currents
wetland+rainwa
Muddy rom
X +
Mafeng
Reconstruct fringing
Local
facilities Managed ealignment zone
Constructed
channel dredging of Yangkou port
Plain eser voir Sponge city Freshwater
1st grade canal 2nd grade river
supply direction
Integrated water strategies for 3 types of coastal reclamation area Inland water storage&flood prevention+Coastal freshwater supply
Integrated water strategies for 3 types of coastal reclamation zone
Inland water storage&flood prevention+Coastal freshwater supply
Urban food production
Compost Food industry
Urban (Circular) Food system
Facilitating circular food production model in Gothenburg
SITE: Gothenburg, Sweden
03. URBAN(CIRCULAR) FOOD SYSTEM
TYPE OF PROJECT: Master thesis project
SUPERVISOR: Jorge Gil, Jonathan Cohen
BRIEF
Facilitating urban circular food system in
city region
Peri-urban food production
Nutrients recovery Residential building
According to the waste management plan of Gothenburg, Gothenburg are planning to reduce the food-waste production by 50% per inhabitant in 2030, while 20% more food waste should be sent to nutrition recovery or biogas or other equivalent purpose. In order to realize the goal of waste reducing and recycling. New system, service and facilities in the urban food waste recyclingsystem are required.
In this thesis I will explore how urban planing and design can support facilitaing circular economy in city by choosing the integration of foodwaste recycling system and future’s local food production planning ( ’Stadslandet” ). Scenario planning ,evaluation of keep performance indicators (KPIs) and geodesign methods will be applied in the project.
Current linear urban food production and food(bio) waste recycling system in Gothenburg
This map shows all of the actors related to current foodwaste recycling flow in Gothenburg. This map will be the starting point of next step flow mapping.
Flow type A. (from household foodwaste to energy and existing agriculture)
Flow type B. (from sewage slurry to energy and peri-urban agriculture)
Flow type C.(from industrial foodwaste to energy/peri-urban agriculture)
Flow type D. (from grazing waste to peri-urban crop production)
Food waste Input Foodwaste Processing Resource Output 1.Household
2.Peri-urban farmland 3.Food market 4.Food
5.Sewage
foodwaste
industry
system
1.Renova-Marieholm (Pre treatment)
2.Gryaab(Slurry treatment and biogas production)
2.Renova
3.Biofuel
4.Surrounding
3.ST1 Refinery(Biorefinery)
4.Gothenburg
energy(From biogas to biofuel)
1.Gothenburg
energy (district heating)
CHP plant(heating and energy production)
stations
farmland
MFA (Material flow analysis) based evaluation of current food system strategies for improving circularity in current food system
Data analysis A-Food demand in 2030 + Relevant demand of resources
STEP1.Implement new food production actors in urban and periurban area
Data analysis B-Gap of resources between actors after expanding food production
STEP2.Improve circularity of the food system in different recycling levels
STEP3.Balance strategy for gap of resource demand between actors
BALANCE
FOODWASTE INPUT ACTORS FOODWASTE PROCESSING ACTORS RESOUECE-OUTPUT ACTORS Waste Plan in 2030 Composition of Gothenburg's district heating Household foodwaste Pre-treatment facility Gryaab sewage plant Industrial foodwaste Total foodwaste:25799t/yr 18661t less than 2020) Foodwaste for biotreatment 18059t/yr 4171t less than 2020) Foodwaste Composition of total electricity sales Population in 2030: 661508 1.5% incerease every year) Estimation of total vegetable consumption 2030 based on population 42071908.8kg Estimation of total potatoes consumption in 2030 based on population 30760122kg Estimation of total flour/cereal consumption in 2030 based on population 11510239.2kg Peri-urban agriculture Biofuel station Future's actors ST1 bio-refinery CHP plants of Gothenburg Actor's production demand (Heating) Renewable + Heat recovery: 100% in 2025 (11% more production than 2020 Demand of nutrients for growing regional food in 2030 (population 661508) kg/ha Average demand for N: 142616(mineral);71369(mamual) Average demand for P: 57366(mineral);18290(manual) Average demand for K: 207105(mineral);70706(manual) (N=Nitrogen;P=Phosphorus;K=Potassium) Actor's production demand (Electric) Renewable power: 100% in 2040 (29% more production than 2020 Actor's (ST1) demand for foodwaste input Expected Industrial foodwaste for production: 21000t (13800t more input than 2020 Energy Nutrients
Optimization of urban food production flow (Linking urban food production to foodwaste recycling system)
New flow type A.(from household food waste to urban/ peri-urban food production and energy)
A-The first type of circular low (from household food waste to urban/peri-urban food production)
Mapping the circular steps in future's household circular food production and waste recycling system
Mapping the circular steps in the food-industrial&agriculture waste recycling
Map of actors in future's household related circular food production system
Urban circular food production flow diagram (from household food waste to resource)
STEP1
household food waste to new actors (local food production) with treatment facilities and and central treatment facility
New flow type B (from sewage to resources for peri urban/urban food production)
B.The second type of circular flow (from sewage to urban/peri urban food production)
STEP2
Local facilities for reusing greywater and from pretreatment facility to sewage plant
STEP3
From sewage plant to CHP&Agriculture
STEP4
From CHP to biofuel station
+ + + + + + + + + + + + + + + + + + + + + + + + + + Household < < < Marieholm. Local food produc�on Local treatment facility = < < < Gryaab Peri-urban food produc�on CHP plants < CHP Renova < Biofuel sta�on Building Local food produc�on (suitable) sewage water < Gryaab Peri-urban Agriculture CHP plants < Sewage(Sludge) < < Biofuel sta�on
New actors + + + + + + + + + + + + + + + + + + + +
Relevant treatment facilities +
+
+
Community garden District greenhouse Roof-top farming in industrial area Peri-urban start up companies
Optimization of urban food production flow------From linear to circular (link peri urban agriculture to industrial foodwaste)
New flow type C: (from food industry and food markets to local/peri-urban agriculture and energy)
C.The third type of circular flow (from food industry and food markets to local/peri-urban agriculture and energy)
Mapping the circular steps in future's industrial and agriculture circular food production and waste recycling system
Mapping the circular steps in the food-industrial&agriculture waste recycling
Map of actors in future's food industry and agriculture related circular food production system
Urban circular food production flow B. (from industrial foodwaste to resource)
STEP1
More industrial-food waste or commercial food waste to ST1 bio-refinery
STEP2 Bio-refinery to biofuel stations&africulture
New flow type D: (from residual/grazing waste to local nutrients and energy)
D.The fourth type of circular flow (from residual/grazing waste to local nutrients and energy
Linking resource from grazing field to crops field; More digestion facilities
Peri-urban Agriculture (Crop/Animal) Food Industry Specific food market Biofuel sta�on Building Bio-refinery ST1 > > > > + Peri-urban agriculture Building local-CHP Grazing Field +
. . .. .. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Bakery and food industry
CHP(Combined heat and power)
Marieholm waste recycling centre Peri-urban farmland
URBAN (CIRCULAR) FOOD SYSTEM IN GOTHENBURG
SYSTEM AT URBAN SCALE
Circular food production model at urban scale and suitable locations
Suitable land for new food production actors in Gothenburg Region
Map of suitable location for 4 types of new urban food production actors
Supporting Infrastructures
Balance strategy between resources demand of actors in circular food production system
Balance model for gap of resource between actors in future's flow (After expanding urban food production)
HOUSEHOLD FOODWASTE BASED RESOURCES FOR FARMING
4 Main new local food production actors
INDUSTRIAL FOODWASTE BASED RESOURCES FOR FARMING
BALANCE Potential local water resources and rainwater collecting locations Transportation network for local food production and logistic actors Potential green structure( green buffer for reducing nutrients from food production) IoT and smart devices for waste management Food production actor example 1 Community garden in Gothenburg Food production actor example 2 Local food-waste recycling buisiness (from food waste to fertilizer for local food production) Household < < / < / Marieholm. Local food produc�on Local treatment (suitable) sewage water = < < < Gryaab Agriculture CHP plants < CHP Renova Sewage water < Biofuel sta�on Agriculture (Crop/Animal) Food Industry Specific food market Biofuel sta�on Building Bio-refinery local-CHP ST1 > > > > + Grazing Field
CIRCULAR FOOD
Fertilizer storage Bioswale collecting rainwater Parking lot Local CHP (combines heat and power) Rooftop sh-vegetable symbiosis production Biowaste digestor Rainwater storage and puri cation Local biowaste digestor Peri-urban green start-up companies Outdoor food production Local CHP (combines heat and power) Community Garden District greenhouse (Parking
Fish-vegetable
(Roof-top
lot based)
symbiosis farm
based) Peri-urban green start up (Greenhouse)
URBAN (CIRCULAR) FOOD SYSTEM IN GOTHENBURG
CIRCULAR FOOD SYSTEM AT NEIGHBOURHOOD SCALE
Circular food production model at neighbourhood scale ( Typical areaA: Community garden)
Community Garden
Prototye (key actor) of future's community garden
Circular food production model for community garden
Circular food production model of future's community garden
District (Parking
Suitable site for community garden
(Proximity to urban green, local compost and potential runoff )
Fish-vegetable symbiosis farm (Roof-top based)
Application of the circular model on site
Circular food production model for rooftop farm
Peri-urban (Greenhouse
IoT enabled foodwaste digestor Allotment garden Fertilizer storage Parking Runo Puri ed water Runo Fertilizer Fertilizer for urban-green Local food Food-waste Biogas based Power IoT ENABLED FOODWASTE CONTAINER RESIDENTIAL AREA ALLOTMENT GARDEN DETENTION POND URBAN RUNOFF SMART GRID
Suitable locations for community garden Application of the circular model Bike Tricycle Car Tractor Runoff Power flow Food waste flow Water flow Food flow Fertilizer flow Truck Walking Bus Typical area Zoom in area Suitable locations ZOOM-IN AREA
Circular food production model at neighbourhood scale (Typical areaB: District greenhouse)
District greenhouse (Parking lot based)
Prototye (key actor) of district greenhouse
Circular food production model for district greenhouse
Circular food production model of future's district greenhouse
Suitable site for parking lot based district green house
Peri-urban green start up companies (Greenhouse based)
Application of the circular model on site
Circular food production model for peri-urban green start up companies
Rainwater storage and puri cation Bioswale for collecting rainwater District greenhouse Parking lot Local biowaste digestor IoT enabled digestor Local CHP (combines heat and power) Puri ed water Runo Runo Runo Local food Local food Local food Local food Food-waste Biogas based Power FARMER’S MARKET DISTRICT GREENHOUSE SMART GRID LOGISTIC CENTER RESIDENTIAL AREA BIOSWALE DETENTION POND
Bike Stream Truck Walk Bus Tricycle Car Tractor Power flow Food waste flow Water flow Food flow Fertilizer flow Typical area Application of the circular model Zoom in area
locations for district greenhouse ZOOM-IN AREA
Suitable
Circular food production model at neighbourhood scale (Area with community garden and district greenhouse)
Systemic section 1-1'
Typical area A Typical area B 1 1'
Local compost Community garden local CHP IoT enabled foodwaste collector district greenhouse agroforestry Residen�al building and local market Agroforestry Community garden Community garden Community garden Community garden Community garden Urban Green Urban Green Urban Green Urban Green Urban Green District greenhouse Wind buffer Wind buffer REKO ring market Rooftop fish-vegetable symbiosis farm Dag Hammarskjöldsleden Waste room Agriculture waste Agriculture waste Food waste Biowaste based fertilizer Biowaste based fertilizer Food produced locally Biogas based heat Local compost Local compost Aerobatic digestion Miljonprogrammet Apartment Detention pond with buffer Detention pond Detention pond Forest Tram line Aerobatic digestion Typical area Agroforestry Agroforestry Pasture Forest Buffer zone Buffer zone Intercropping field Intercropping field Community garden Community garden Community garden Community garden Community garden Urban Green Urban Green Urban Green Urban Green Urban Green District greenhouse Wind buffer Wind buffer REKO ring market Rooftop fish-vegetable symbiosis farm Rooftop fish-vegetable symbiosis farm Permeable Parking lot Permeable Parking lot Industrial building Boulevard Boulevard Offices building Rooftop fish-vegetable symbiosis farm Dag Hammarskjöldsleden Rooftop fish-vegetable symbiosis farm Road Industrial warehouse Tram line Wind buffer Green corridor Green Corridor Local food market COOP Detention pond Grey infrastructure Waste room Intercropping field Grass strip Local CHP Vertical aquaponic crops Rooftop greenhouse Outdoor Food production Agriculture waste Agriculture waste Agriculture waste Agriculture waste Agriculture waste Food waste Biowaste based fertilizer Biowaste based fertilizer Biowaste based fertilizer Biowaste based fertilizer Biowaste based fertilizer Agriculture waste Biogas Manure produced locally Food produced locally Food produced locally Biogas based heat Biogas based heat Biogas based heat Biogas based heat Biogas based heat Local compost Local compost Aerobatic digestion Aerobatic digestion To other local food market Miljonprogrammet Apartment Permeculture park Peri-urban green start up Peri-urban green start up Detention pond with buffer Detention pond with buffer Detention pond Detention pond Railway station Forest Farmer’s market Bio swale Detention pond Detention pond Forest Tram line Bio swale Stream Riparian buffer Filtration buffer Filtration buffer Filtration buffer Functional edge Filtration buffer Buffer for nutrients removal Local CHP Aerobatic digestion Aerobatic digestion Aerobatic digestion To other local food market Connect to Smart grid Connect to Smart grid Connect to Smart grid Aerobatic digestion Energy flow Energy produc�on flow Fer�lizer flow Food (bio) waste flow Regional and local food flow Suppor�ng infrastructures LEGEND Suitable locations for community garden
Application of the circular model
Circular food production model at neighbourhood scale ( Typical areaC: Rooftop fish-vegetable symbiosis farm)
Fish-vegetable symbiosis farm (Roof-top based)
Prototye (key actor) of future's rooftop fish-vegetable symbiosis farm
Circular food production model for rooftop farm Peri-urban (Greenhouse
Circular food production model of rooftop fish-vegetable symbiosis farm
Suitable locations for fish-vegetable symbiosis farm
Suitable site for rooftop fish-vegetable symbiosis farm (Rooftop of industrial building)
Application of the circular model on site
Rooftop sh-vegetable symbiosis production Biowaste digestor Puri ed water Runo Runo Local food Local food Local food Local food Local food Local food Food-waste Biogas based Power FARMER’S MARKET ROOFTOP FISH-VEGETABLE FARM DETENTION POND URBAN RUNOFF FOOD MARKET SMART GRID LOGISTIC CENTER RESIDENTIAL AREA
Power flow Bike Tricycle Car Tractor Pipe Stream Truck Walking Bus Food waste flow Water flow Food flow Fertilizer flow Typical area
of the circular model Zoom in area Zoom in area
locations
farmland
Application
Suitable
green start
Zoom-in area
Typical area 2 2' Typical area Suitable locations for fishvegetable symbiosis farm Circular food production model at neighbourhood scale (Area with rooftop fish-vegetable symbiosis farm)
section 2-2' Rooftop fish-vegetable symbiosis farm Rooftop fish-vegetable symbiosis farm Permeable Parking lot Permeable Parking lot Industrial building Boulevard Boulevard Offices building Rooftop fish-vegetable symbiosis farm Road Industrial warehouse Tram line Wind buffer Green corridor Green Corridor Local food market COOP Detention pond Grey infrastructure Vertical aquaponic crops Rooftop greenhouse Outdoor Food production Agriculture waste Agriculture waste Biowaste based fertilizer Biowaste based fertilizer Food produced locally Biogas based heat Biogas based heat Local CHP Aerobatic digestion Aerobatic digestion To other local food market Connect to Smart grid Connect to Smart grid Local compost CHP Sewage plant biogas local CHP IoT enabled Foodwaste collector Roo�op fish-vegetable symbiosis farm Residen�al building and local market Agroforestry Agroforestry Pasture Forest Buffer zone Buffer zone Intercropping field Intercropping field Community garden Community garden Community garden Community garden Community garden Urban Green Urban Green Urban Green Urban Green Urban Green District greenhouse Wind buffer Wind buffer REKO ring market Rooftop fish-vegetable symbiosis farm Rooftop fish-vegetable symbiosis farm Permeable Parking lot Permeable Parking lot Industrial building Boulevard Boulevard Offices building Rooftop fish-vegetable symbiosis farm Dag Hammarskjöldsleden Rooftop fish-vegetable symbiosis farm Road Industrial warehouse Tram line Wind buffer Green corridor Green Corridor Local food market COOP Detention pond Grey infrastructure Waste room Intercropping field Grass strip Local CHP Vertical aquaponic crops Rooftop greenhouse Outdoor Food production Agriculture waste Agriculture waste Agriculture waste Agriculture waste Agriculture waste Food waste Biowaste based fertilizer Biowaste based fertilizer Biowaste based fertilizer Biowaste based fertilizer Biowaste based fertilizer Agriculture waste Biogas Manure Food produced locally Food produced locally Food produced locally Biogas based heat Biogas based heat Biogas based heat Biogas based heat Biogas based heat Local compost Local compost Aerobatic digestion Aerobatic digestion To other local food market Miljonprogrammet Apartment Permeculture park Peri-urban green start up Peri-urban green start up Detention pond with buffer Detention pond with buffer Detention pond Detention pond Railway station Forest Farmer’s market Bio swale Detention pond Detention pond Forest Tram line Bio swale Stream Riparian buffer Filtration buffer Filtration buffer Filtration buffer Functional edge Filtration buffer Buffer for nutrients removal Local CHP Aerobatic digestion Aerobatic digestion Aerobatic digestion To other local food market Connect to Smart grid Connect to Smart grid Connect to Smart grid Aerobatic digestion Energy flow Energy produc�on flow Fer�lizer flow Food (bio) waste flow Regional and local food flow Suppor�ng infrastructures LEGEND
Systemic
Circular food production model at neighbourhood scale (Typical areaD: Peri-urban green start up companies and existing farm)
Peri-urban green start up companies (Greenhouse based)
Prototye of future's peri-urban green start up companies
Circular food production model for peri-urban green start up companies
Circular food production model of peri-urban green start up companies
Suitable locations for peri-urban green start up companies and existing farmland
Suitable site for peri-urban green start up companies. (Proximity to existing farm)
Application of the circular model on site
Rainwater storage and puri cation Local biowaste digestor Peri-urban green start-up companies Outdoor food production Local CHP (combines heat and power) Fertilizer Runo Runo Runo Runo Puri ed water Puri ed water Fertilizer Local food Local food Local food Local food Local food Local food Fertilizer Agri-waste Biogas based Power Agri-waste Agri-waste BIOSWALE DETENTION POND PERMECULTURE FIELD BIOWASTE DIGESTOR GRAZING FIELD SMART GRID FARMER’S MARKET LOGISTICS CENTER URBAN RUNOFF FOOD MARKET PERI-URBAN GREENHOUSE
Power flow Bike Runoff Truck Walking Bus Tricycle Car Tractor Food waste flow Water flow Food flow Fertilizer flow Typical area Application of the circular model
of the circular model Zoom in area Zoom in area
Application
Zoom-in area
Circular food production model at neighbourhood scale (Area with peri-urban green start up companies and existing farm)
Systemic section 3-3'
Typical area 3 3' Agroforestry Pasture Buffer zone Buffer zone Intercropping field Intercropping field Community garden Community garden Community garden Community garden Community garden Urban Green Urban Green Urban Green Urban Green Urban Green District greenhouse Wind buffer REKO ring market Rooftop fish-vegetable symbiosis farm Rooftop fish-vegetable symbiosis farm Permeable Parking lot Permeable Parking lot Industrial building Boulevard Boulevard Offices building Dag Hammarskjöldsleden Rooftop fish-vegetable symbiosis farm Road Industrial warehouse Tram line Wind buffer Green corridor Grey infrastructure Waste room Intercropping field Grass strip Local CHP Vertical aquaponic crops Rooftop greenhouse Outdoor Food production Agriculture waste Agriculture waste Agriculture waste Food waste Biowaste based fertilizer Biowaste based fertilizer Biowaste based fertilizer Biowaste based fertilizer Biowaste based fertilizer Agriculture waste Manure Food produced locally Food produced locally Food produced locally Biogas based heat Biogas based heat Biogas based heat Biogas based heat Local compost Local compost Aerobatic digestion Aerobatic digestion To other local food market Miljonprogrammet Apartment Permeculture park Peri-urban green start up Detention pond with buffer Detention pond with buffer Farmer’s market Bio swale Detention pond Detention pond Forest Tram line Bio swale Stream Riparian buffer Filtration buffer Filtration buffer Functional edge Filtration buffer Buffer for nutrients removal Local CHP Aerobatic digestion Aerobatic digestion To other local food market Connect to Smart grid Aerobatic digestion Ene gy flow Ene gy produc�on flow Fer�lizer flow Food (bio) was e flow Regional and local food flow Suppor�ng infrastructures LEGEND Typical area Suitable locations for peri-urban green start up companies and existing farmland
Agroforestry Pasture Forest Buffer zone Buffer zone Intercropping field Intercropping field Intercropping field Grass strip Local CHP Agriculture waste Biowaste based fertilizer Agriculture waste Biogas Manure Food produced locally Biogas based heat Biogas based heat Aerobatic digestion To other local food market Permeculture park Peri-urban green start up Peri-urban green start up Detention pond with buffer Detention pond Detention pond Railway station Forest Farmer’s market Bio swale Bio swale Stream Riparian buffer Filtration buffer Filtration buffer Filtration buffer Functional edge Filtration buffer Buffer for nutrients removal Connect to Smart grid Aerobatic digestion CHP Sewage plant biogas anaerobic diges on & local CHP Peri urban green start-up companies Cul vated cropland Pasture Residential building and local market
Location of the suppoting system for the new food production actors based on GIS analysis
GIS analysis of the supporting system for urban circular food system
Supporting system1. blue system
1.Map of groundwater reservoir and suitable soil for farming (silt)
2.Map of runoff and stream system of Gothenburg
Supporting system2. green system
1.Map of current urban green area and forest area
2.Map of functional buffer for forest patches
3.Map of potential wadi for rainwater detention
4.Map of open water surface and lakes in Gothenburg
3.Map of buffer filter for runoff/streams and green corridor along river
4.Map of buffer for lakes and wetland in Gothenburg
Location of the suppoting system for the new food production actors based on GIS analysis
Supporting system3. Relevant transportation network
1.Map of exsisting parking space for bikes and new parking space for bikes
2.Map of parking lots where farmers market and relevant facilities can be built
Supporting system4. Smart management facilities for future's food system
1.Map of water storing and purification
2.Map of smart facilities for rainwater irrigation
3.Map of existing cycling line and new cycling line
4.Map of existing walking paths and new walking paths
3.Map of (Recycling room based) food waste composting and information system
4.Map of basin for water and nutrients management
02.Green Link
Planning of Ecoduct and Ecological corridor
SITE: Gothenburg, Sweden
ACADEMIC: Year1,Semester1 (Msc.)
Tutor: Meta Berghauser Pont
04. GREEN LINK
BRIEF
Green trail + Ecological corridor
In this project I researched the social-ecological solutions for connecting important biotopes which is cut through by highway-159 in the south part of Gothenburg. In the project I combine the design of ecological corridors, ecoduct with social benefits for people, like public open space, cycling route and urban permaculture space. Which provide different types of landscape for surrounding residents.
GREEN TRAIL | Vision of bioswale park and multifunctional ecoduct
5.Bioswale park in-between farmpark and residential area
In the bioswale based community park, the steep slope of the existing bioswale is widened and the overgrown grass along the ditch is replaced by local meadow species, so the bioswale become more visible and approachable, also the stormwater storage capacity is improved. Existing shrubs and trees along the biowale are moved in order to provide better vista for visitors walking in the park and residents living. Meanwhile, two 1m width gravel routes linked by 3 walkable stone check-dams on the stream are built for guiding people approach the viewpoints and small playground along the bioswale in nearby houses. New local shrubs are planted in the west slope for marking and provide protection for small playgrounds in the lawn.
6. Multifunctional ecoduct connecting Anggardsbergen and Balltorp
Over the highway159, a multifunctional ecoduct with 1:12 slope for both local target animals and local residents is planned for connecting anggardsbergen nature reserve and forest in Balltorp. Above the ecoduct, a 20M width green belt for linking ecological corridor on both sides of the highway is designed, soil type and morphology of the green belt on the ecoduct is referred from surrounding ecological corridor and patches. Also, Plants in the green belt are mainly local shrubs,herbs and meadows based on the study of species composition of the surrounding nature area. Shrubs,trunks and stone boulders are put on the green belt which function as a natural“screen”, dividing the 4M width trail for humans and the green area for animals. small infiltration ponds connected to ditches are created for attracting animals, also collecting water from the ecoduct through gentle slope.
07.Pilot project of Meiyuan children friendly community
Renovation of Shanghai Meiyuan community
Site: Shanghai, 2022
Situation: Preparing for construction
My role: Junior project leader, cooperated with community architect.
Meiyuan community was built in the 1980s.In 2023,Meiyuan community will be renovated and become one of the children friendly communities in Shanghai municipality. After discussion with local officers, teachers from school and local residents, a pilot site is selected and two scenarios (Co-build garden + Pick up harbor) are proposed, and now preparing for
continued discussion and construction.
Co-build edible garden at night
Site analysis of the pilot project
Scenario1: Children friendly route + Co-build edible garden
Scenario2: Children friendly route + Pick up harbor for parents
N Entrance renovation Facade renovation New paving Facade renovation for the distribution station Community-School co-build garden Kids trail Kids Playfield P N Entrance renovation Facade renovation New paving Facade renovation for the distribution station Picking up Harbour Kids trail Kids Playfield P
Existing plant bed Existing community road Existing community route Existing plant bed
edible garden+Children friendly route
edible garden Pick up harbor Pick up harbor+Children friendly route
Solutions for the children-friendly community Co-build
Co-build
Scenario1: Co-build edible garden (Community and school)
In the first scenario, Current plant bed is transformed into a co-build garden. Nowadays, the edge of the plant bed is divided into 4 waiting areas for kids from 4 classes. Based on the current plan, we divide the greenbelt into 4 small permaculture gardens with similar areas and students from each class are responsible for each area. Children can engage in the urban farming process, cooperating with teachers and the community. Bench is added to the edge of the co-build garden, offering a rest area for local residents and parents.
Existing Plant
Children friendly route
Rest area for residents and parents Co-build garden (community and school) CLASS1 CLASS2 CLASS3 CLASS4
Co-build edible garden
Co-build edible garden
Rest area for parents/residents
Scenario2: Pick-up harbor for parents
In the 2nd scenario, we transformed the green belt into a seating platform for local residents and parents. From 4 pm to 6 pm, the seating platform functions as a rest area for parents who pick up children. At other times, the pick up harbor can function as a rest area for local residents. Wood is used in the construction and local plants are planted, for adding more natural atmosphere for the community.
Waiting area for parents
Pick-up habor for parents
Kids friendly route
Co-build flower bed (community and school) Rest area for residents and parents CLASS1 & CLASS2 CLASS3 CLASS4
Other Works
+1. Tibro resilient water system (Work from Local context studio)
+2. Izmir Water Integrated Planning (Internship Work)
2. Izmir water integrated plnning (Internship Work)
I. Water integration planning of Izmir(Basin Bostanli and Poligon)
(My role: 1.GIS analysis of water system and existing water infrastructue
2.Section drawing of proposal in key zoom-in area)
GIS mapping and data analysis of Bostanli water system (Cooperated with Josje Hoefsloot)
Section drawing based on water storage proposals in zoom-in area
Section A-A
Visualization of general longlitude of the Bostanli basin
Section B-B
Section C-C
The Bostanli catchment has an extensive hinterland of approx. 40 km2. In the upstream area, many small natural streams come together and form wider streams that run towards the city. These streams are denaturalized in downstream urban areas, where infrastructure often crosses the canals. In addition, the culverts under the bridges are relatively small, resulting in bottlenecks for water drainage during extreme weather events.
Section D-D
Section E-E
Section F-F
Section G-G
12 50 20 17 20 17 48 12 110 32 15 20 100 4 8 15 60 4 4 16 32 18 4.5 4.5 8 2.5 25 4.5 20 20 4 4 2 8 4 80 2 20 4 4 45 28 18 21 30 10 7 5 3 7 Bestekar Yusuf Nalkesen Sk. 12 4 2 4 6 10 6 5 8 8 8 22 2018. Sk. Bestekar Yusuf Nalkesen Sk. Keep the tram 12 10 20 6 4 5 8 8 22 6 IZMIR - WATER VISION WATER SYSTEM • BOSTANLI
RURAL AREAS CITY OF THE HILLS CITY IN THE COASTAL PLAIN Erosion Pasture Urban green Nature Bareland Fast run-o Over owing at constructing culverts and bridges Fast runo in new urban developments on hill-slopes Bank over owing & blocked drainage High water level in the canal due to in ow and sea water rise Coastal ooding Over owing neighbourhoods Bareland X X X X X X X A B B C C D E E F F G G D A
THANKS for READING
