Design of an Instrumented Model Green Roof Experiment

Abstract Current research has validated the purification of rainwater by a substrate layer of green roofs to some extent, though the effects of the substrate layer on rainwater purification have not been adequately quantified. The present study set up nine extensive green roof experiment combinations based on the current conditions of precipitation characteristics observed in Shanghai, China. Different rain with pollutants were simulated, and the orthogonal design L9 (33) test was conducted to measure purification performance. The purification influences of the extensive green roof substrate layer were quantitatively analyzed in Shanghai to optimize the thickness, proportion of substrate, and sodium polyacrylate content. The experimental outcomes resulted in ammonium nitrogen (NH4+-N), lead (Pb), and zinc (Zn) removal of up to 93.87%, 98.81%, and 94.55% in the artificial rainfall, respectively, and NH4+-N, Pb, and Zn event mean concentration (EMC) was depressed to 0.263 mg/L, 0.002 mg/L and 0.018 mg/L, respectively, which were all well below the pollutant concentrations of artificial rainfall. With reference to the rainfall chemical characteristics of Shanghai, a combination of a 200 mm thickness, proportions of 1:1:2 of Loam: Perlite: Cocopeat and 2 g/L sodium polyacrylate content was suggested for the design of an extensive green roof substrate to purify NH4+-N, Pb and Zn.

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Stormwater Retention and Reuse at the Residential Plot Level—Green Roof Experiment and Water Balance Computations for Long-Term Use in Cyprus

Water ◽

10.3390/w11051055 ◽

2019 ◽

Vol 11 (5) ◽

pp. 1055 ◽

Cited By ~ 5

Author(s):

Katerina Charalambous ◽

Adriana Bruggeman ◽

Marinos Eliades ◽

Corrado Camera ◽

Loukia Vassiliou

Keyword(s):

Water Balance ◽

Plant Species ◽

Rainwater Harvesting ◽

Green Roof ◽

Irrigation Treatment ◽

Stormwater Runoff ◽

Green Roofs ◽

Roof Experiment ◽

Stormwater Retention

Green roofs can provide various benefits to urban areas, including stormwater retention. However, semi-arid regions are a challenging environment for green roofs as long dry weather periods are met with short but intense rainfall events. This requires green roofs to retain maximum volumes of stormwater, while being tolerant to minimal irrigation supplies. The objectives of this study are (i) to quantify the stormwater retention of two substrate mixtures with two plant species under natural rainfall; (ii) to assess the performance of two plant species under two levels of deficit irrigation; and (iii) to compute stormwater runoff reduction and reuse by green roofs and rooftop water harvesting systems for three standard residential plot types in urban Nicosia, Cyprus. A rooftop experiment was carried out between February 2016 and April 2017 and results were used to compute long-term performance. Average stormwater retention of the 16 test beds was 77% of the 371-mm rainfall. A survival rate of 88% was recorded for Euphorbia veneris and 20% for Frankenia laevis, for a 30% evapotranspiration irrigation treatment. A combination of a green roof, rainwater harvesting system and 20-m3 tank for irrigation and indoor greywater use reduced stormwater runoff by 47–53%, for the 30-year water balance computations.

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Ten-year persistence of native plant species on a green roof in Northeast US

Native Plants Journal ◽

10.3368/npj.18.3.227 ◽

2017 ◽

Vol 18 (3) ◽

pp. 227-234

Author(s):

Jessica D Lubell ◽

Bryan Connolly ◽

Kristina N Jones

Keyword(s):

Plant Species ◽

Green Roof ◽

Native Plant ◽

Native Plant Species ◽

Northeast Us

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THE GREEN ROOF THERMAL PERFORMANCE EVALUATION IN COMPARISON TO ASBESTOS CEMENT TILES APPLIED TO LIGHT STEEL FRAME BRAZILIAN BUILDINGS

International Journal of Architectural Research Archnet-IJAR ◽

10.26687/archnet-ijar.v12i3.1709 ◽

2018 ◽

Vol 12 (3) ◽

pp. 288

Author(s):

Angélica Felicidade Guião Marcato Costa ◽

João Alexandre Paschoalin Filho ◽

Tatiana Tucunduva Philipi Cortese ◽

Brenda Chaves Coelho Leite

Keyword(s):

Performance Evaluation ◽

Relative Humidity ◽

Heat Flow ◽

Thermal Performance ◽

Green Roof ◽

Steel Frame ◽

Internal Temperature ◽

Green Cover ◽

Asbestos Cement ◽

Data Representative

This research aimed at comparing the thermal performance provided in experimental modules, one of which was performed with conventional cover, made of asbestos cement tiles; an another with green cover. The structure of the studied modules was executed using Light Steel Frame technique. As an experimental research, modules were built in a wide place, without the interference of shading. Instruments were installed in the inner part of the modules to measure the following data: air temperature, relative humidity. From the collected data, representative episodes have been chosen for the studies that aimed to compare the comfort provided by both modules, built with different roofs. As result, it was verified that the module with green roof had better performance than the module covered with asbestos cement tile in all selected episodes. The module covered with green roof maintained lower internal temperature variation throughout the days, indicating that the green roof has characteristic thermal insulation, reducing the heat flow from the roof.

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EVALUATING BIORETENTION CELL AND GREEN ROOF PERFORMANCE IN NORTHEASTERN OHIO

10.1130/abs/2016am-284250 ◽

2016 ◽

Author(s):

Laura Lynn Sugano ◽

◽

Anne J. Jefferson ◽

Lauren E. Kinsman-Costello ◽

Pedro Avellaneda

Keyword(s):

Green Roof ◽

Bioretention Cell

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Performance comparison of green roof hydrological models for full-scale field sites

Journal of Hydrology X ◽

10.1016/j.hydroa.2021.100093 ◽

2021 ◽

pp. 100093

Author(s):

Ico Broekhuizen ◽

Santiago Sandoval ◽

Hanxue Gao ◽

Felipe Mendez-Rios ◽

Günther Leonhardt ◽

...

Keyword(s):

Green Roof ◽

Performance Comparison ◽

Full Scale ◽

Hydrological Models ◽

Scale Field

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Seismic Performance of a Green Roof Structure

Sustainability ◽

10.3390/su13084278 ◽

2021 ◽

Vol 13 (8) ◽

pp. 4278

Author(s):

Svetlana Tam ◽

Jenna Wong

Keyword(s):

Green Roof ◽

Time History ◽

Green Roofs ◽

Moment Frame ◽

Steel Moment Frame ◽

Roof Structure ◽

Nonlinear Time History Analyses ◽

Vegetated Roofs ◽

Nonlinear Time History ◽

The Impact

Sustainability addresses the need to reduce the structure’s impact on the environment but does not reduce the environment’s impact on the structure. To explore this relationship, this study focuses on quantifying the impact of green roofs or vegetated roofs on seismic responses such as story displacements, interstory drifts, and floor level accelerations. Using an archetype three-story steel moment frame, nonlinear time history analyses are conducted in OpenSees for a shallow and deep green roof using a suite of ground motions from various distances from the fault to identify key trends and sensitivities in response.

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Case study investigation of the building physical properties of seven different green roof systems

Energy and Buildings ◽

10.1016/j.enbuild.2017.06.050 ◽

2017 ◽

Vol 151 ◽

pp. 564-573 ◽

Cited By ~ 12

Author(s):

Bernhard Scharf ◽

Irene Zluwa

Keyword(s):

Physical Properties ◽

Green Roof

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Time-Dependent Changes in the Physico-Chemical Parameters and Growth Responses of Sedum acre (L.) to Waste-Based Growing Substrates in Simulation Extensive Green Roof Experiment

Agronomy ◽

10.3390/agronomy11020298 ◽

2021 ◽

Vol 11 (2) ◽

pp. 298

Author(s):

Anna Krawczyk ◽

Iwona Domagała-Świątkiewicz ◽

Agnieszka Lis-Krzyścin

Keyword(s):

Green Roof ◽

Matter Content ◽

Time Dependent ◽

First Year ◽

Chemical Parameters ◽

Growing Media ◽

Extensive Green Roof ◽

Physico Chemical ◽

Commercial Medium ◽

Sedum Acre

Over the last decade, an increase in the use of locally available, recycled, and waste materials as growing media components have occurred in various regions of the world in extensive green roof technology. For eco-concept reasons, such a strategy appears to be appropriate, but can be problematic due to difficulties in obtaining proper parameters of growing substrate. The growing media should be properly engineered in order to enable the proper functioning of green roofs and provide suitable environment for ideal root growth. The aim of the study was to assess the utility of locally occurring waste materials for growing media composition and estimate plant- and time-dependent changes in the physico-chemical parameters of waste-based substrates in a simulated extensive green roof system during a two-year Sedum acre L. cultivation. Five different substrate compositions were prepared using silica waste, crushed brick, Ca- and Zn-aggregates, melaphyre, tuff, sand, muck soil, urban compost, spent mushroom, and coconut fibres. Optimal water capacity, particle-size distribution, pH and salts concentration were found in all substrates. A higher concentration of macronutrients (N, P, K, Mg) and trace elements (B, Cu, Fe, Mn, Zn, Cd, Ni, Pb, and Cr) was found in waste-based substrates than in the commercial medium. In comparison to the parameters determined before establish the experiment, bulk density of tested growing media decreased, except for the substrates where the source of organic matter was the rapidly mineralising spent mushroom. The organic matter content in substrates after the two-year vegetation increased in relation to the ready-made substrate, with the exception of the composition with spent mushroom. After two years of the experiment, all available macronutrients and trace elements (with the exception of mineral N, K, SO4-S, and B) concentration were higher than in 2014, while pH, salt concentration was lower. In general, plants grown in waste substrates had lower dry matter content and higher biomass. A significantly higher biomass of S. acre L. was found in the first year of the experiment. In the second year of the research, the plants grown in the commercial medium, the substrate with silica waste, and the substrate with spent mushroom produced higher biomass than in the first year. No symptoms of abnormal growth were observed, despite the higher trace element concentrations in plants collected from waste-based substrate. Waste-based growing media can be considered as a valuable root environment for S. acre L. in an extensive green roof system.

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Addressing the Water–Energy–Food Nexus through Enhanced Green Roof Performance

Sustainability ◽

10.3390/su13041972 ◽

2021 ◽

Vol 13 (4) ◽

pp. 1972

Author(s):

Jeremy Wright ◽

Jeremy Lytle ◽

Devon Santillo ◽

Luzalen Marcos ◽

Kristiina Valter Mai

Keyword(s):

Climate Change ◽

Performance Optimization ◽

Urban Areas ◽

Stormwater Management ◽

Green Roof ◽

Green Roofs ◽

Management Tool ◽

Contributing Factors ◽

Rainwater Runoff ◽

Rain Events

Urban densification and climate change are creating a multitude of issues for cities around the globe. Contributing factors include increased impervious surfaces that result in poor stormwater management, rising urban temperatures, poor air quality, and a lack of available green space. In the context of volatile weather, there are growing concerns regarding the effects of increased intense rainfalls and how they affect highly populated areas. Green roofs are becoming a stormwater management tool, occupying a growing area of urban roof space in many developed cities. In addition to the water-centric approach to the implementation of green roofs, these systems offer a multitude of benefits across the urban water–energy–food nexus. This paper provides insight to green roof systems available that can be utilized as tools to mitigate the effects of climate change in urbanized areas. A new array of green roof testing modules is presented along with research methods employed to address current issues related to food, energy and water performance optimization. Rainwater runoff after three rain events was observed to be reduced commensurate with the presence of a blue roof retention membrane in the testbed, the growing media depth and type, as well as the productive nature of the plants in the testbed. Preliminary observations indicate that more productive green roof systems may have increasingly positive benefits across the water–energy–food nexus in dense urban areas that are vulnerable to climate disruption.

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