MAPPING OF RAINWATER HARVESTING POTENTIAL, A CASE STUDY OF SZEGED, HUNGARY

Ákos Kristóf Csete¹, Ágnes Gulyás¹

1Department of Climatology and Landscape Ecology, Urban Climate Research Group, University of Szeged, H-6722 Szeged, Egyetem utca 2-6, Hungary

e-mail: cseteakos@geo.u-szeged.hu Abstract

In urban environment, rainwater harvesting is a good solution to make the water management sustainable. The rainwater harvesting potential of a whole city gives information to the urban planners about the building possibilities of real collecting systems. In our work, with the help of hydrological modeling we create urban micro-watersheds, which based on the roof of buildings. Our expected results can give a comprehensive picture of rainwater harvesting possibilities in urban areas.

Introduction

In the 21st century one of the most urgent problem is the climate change and its impacts on the whole environmental system. The problem with the effect caused by climate change is the uncertainty. The weather extremes will occur more and more often, and the preparation for their impacts is one of the biggest challenges of the environmental planning. In the urban systems – where the impacts affect many citizens – the changes will also cause serious problems. The artificial pavements and the sewer system alter the hydrological system in urban areas. In addition to these changes in urban areas there are less green surfaces and vegetation cover.

Based on these, the hydrological system changed in the cities and the urban planning system needs to be prepared different problems, than natural areas [3]. The first main problem is the occasional too much available water. Heavy rainfalls can cause flooding in cities owing to the impervious pavement, the undersized sewer system and sometimes the obsolete drainage method. The other side of the problems is too less available water in cities [1]. During the long drought period – which is climatic characteristic of the southern part of the Great Hungarian Plain – in the cities the urban vegetation needs irrigation and usually the source of this is potable water, which is not a sustainable solution in long term. Rainwater harvesting can help to reduce the volume of drinking water usage [4].

Study area, methods

The aim of our research is to examine the processes on urban micro-watershed (roofs). The information about these processes (runoff and evaporation on roofs) contribute to create a rainwater harvesting potential map based on a building database. The rainwater harvesting potential map can provide information about the volume of the potentially collectable rainwater.

In this study we use the EPA SWMM model, which is one of the widespread storm water management model [2]. The base of the modeling is a building data base, which contains approxametly 15 000 building polygons (Figure 1.). Each polygon represents an urban micro-watershed. Owing to the database it is possible to separate the slope/pitched roof and flat roofs which also allowed us to determine which roofs have the potential to be used as a green roofs to further facilitate efficient rainwater harvesting. Among the geoinformatics database, the model need some meteorological data like daily temperature, windspeed and hourly precipitation.

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Figure 1. Spatial extent of the building database Expected results, conclusions

With the help of the modeling processes we can examine both city- and district scale result about the rainwater harvesting possibilities within Szeged. We can also delineate which roofs suitable for to build real rainwater harvesting systems. Based on the whole year meteorological data the result can give information about the seasonal distribution of the collected rainwater and which volume of these water can be used in drought periods. Our results could contribute to the local decision-making processes and give usable data for urban planners to make into greater account the potential of rainwater storage.

Acknowledgements

Supported by the ÚNKP-20-3 - New National Excellence Program of the Ministry for Innovation and Technology from the source of the National Research, Development and Innovation Fund.

References

[1] Fletcher, T.D., Andrieu, H. & Hamel P. 2013 Understanding, management and modelling of urban hydrology and its consequences for receiving waters: A state of the art. Advances in Water Resources, 51, 261-279.

[2]Jayasooriya, V. M., & Ng, A. W. M. (2014). Tools for Modeling of Stormwater Management and Economics of Green Infrastructure Practices: a Review. Water, Air, & Soil Pollution, 225(8), 2055.

[3] Prudencio, L. & Null, S.E 2018 Stormwater management and ecosystem services: a review.

Environmental Research Letters, 13, 033002.

[4] Ward, S., Memon F. A., and Butler D. (2010). Rainwater harvesting: model-based design evaluation. Water Science and Technology, 61(1), 85 LP-96.

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OPTIMIZED HUMIC PRODUCTS FROM NATURAL SOURCES A. Csicsor^a, E. Tombácz^b

aHymato Products Ltd., H-8225 Szentkirályszabadja, Kossuth u 33., Hungary

bUniversity of Pannonia, Soós Ernő Water Technology Research and Development Center, H-8800 Zrínyi M. str. 18. Nagykanizsa, Hungary

e-mail: csicsor.attila@gmail.com Abstract

Humic substances are the biological-chemical-geological decomposition products of the living plant origin matter on the Earth. The biggest part of the terrestrial organic matter (non-living biomass) are humic substances. Humus is the most relevant decomposition product of living matter, so it is the most important media for the reproduction of the continental biomass. Our latest researches shows that these materials can be great antioxidants.[1]

The formation of humic acids in humification processes needs geological times, that is minimum thousands of years. There are many sources of humic substances in nature, like soil, water, organic manure, compost, sapropels, peat, lignite, brown coal, Leonardite.

Our company is engaged in research and production of natural humic substances-based pioneer products. Careful extraction and purification, as well as quality control, are also important in order to produce humic and fulvic acid based products for healthy life. We are producing several humic and fulvic acid based products, as active ingredients for medicines, food supplements and cosmetics.

For our products, we use only contamination free Leonardite deposits in Hungary. The so called standard extraction method of humic substances is based on their alkaline solubility.

We extract with sodium hydroxide (NaOH). After the first extraction, the Na-humate solutions may contain some contaminants and sediment that should be removed. The main thing we must first consider is the strict food regulations including heavy metal contaminations and microbiology. Second, we must work according to the GMP (Good Manufacturing Practice) regulations, which is strict in the identification of the active ingredients. [2]

Important question is the analytics and identification of the humic acid fractions. There are no international standards for the analysis of the humic fractions. Our company developed a complex humic-fulvic acid identification and standardization method for the humic substance content of the raw materials and the end products. In our poster, the main extraction process and analytical methods will be shown. [3]

Some application examples of the humic substances are:

[1] Eladia M. Peña-Méndez, at. al.: Humic substances, compounds of still unknown structure:

applications in agriculture, industry, environment, and biomedicine; J. Appl. Biomed. 3: 13.24.

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[2] Nelson N. Schwartz at al.: Production of humic acid, United States Patent 3,398,186, Filed Dec. 23, 1963, Ser. No. 332,841 9

[3] Bleam W. (2017). Soil and Environmental Chemistry. Academic Press, Amsterdam.

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IMPACT OF THE LAND COVER CHANGE ON THE ABUNDANCE OF