The Flood Map for Planning (Rivers and Sea) includes several layers of information. This dataset covers Water Storage Areas. It shows those areas that act as a balancing reservoir, storage basin or balancing pond. Their purpose is to attenuate an incoming flood peak to a flow level that can be accepted by the downstream channel. It may also delay the timing of a flood peak so that its volume is discharged over a longer time interval. We have assumed that water storage areas act perfectly and give the same level of protection as when our assessment of the area was carried out. Water storage areas do not completely remove the chance of flooding and can be overtopped or fail in extreme weather conditions.

This dataset is designed to raise awareness of the likelihood of flooding and to encourage people living and working in areas prone to flooding to find out more and take appropriate action.

Elevated Water Storage Tanks Market Outlook

The global elevated water storage tanks market size was valued at approximately USD 4.5 billion in 2023 and is projected to reach around USD 7.8 billion by 2032, growing at a compound annual growth rate (CAGR) of 6.5% during the forecast period. Key growth factors include the increasing demand for water storage solutions driven by rising urbanization, industrialization, and the need for reliable water supply systems in both developed and developing regions.

One of the primary growth drivers for the elevated water storage tanks market is the rapid pace of urbanization across the globe. As more people move to urban areas, the demand for reliable water infrastructure increases significantly. Elevated water storage tanks play a crucial role in ensuring a consistent water supply in densely populated areas where ground-level storage is insufficient. This trend is particularly pronounced in emerging economies where urban expansion is at its peak.

Another significant factor contributing to market growth is the rising industrial activities worldwide. Industrial processes often require substantial water resources, and the need for secure and efficient water storage solutions is paramount. Elevated water storage tanks offer an optimal solution for industries to maintain a steady water supply, thus preventing operational disruptions. The increased focus on sustainable industrial practices also drives the adoption of advanced water storage technologies.

The role of a Water Tank in modern infrastructure cannot be overstated, as it serves as a critical component in managing water supply effectively. These tanks are designed to store water at elevated heights, ensuring gravity-fed distribution systems that maintain consistent water pressure across various applications. In urban settings, water tanks are essential for balancing supply and demand fluctuations, especially during peak usage times. They also act as a buffer during emergencies, providing a reserve that can be tapped into when needed. The design and capacity of water tanks are tailored to meet the specific needs of the communities they serve, making them indispensable in both residential and industrial contexts.

The growing emphasis on water conservation and management is further bolstering the demand for elevated water storage tanks. Governments and regulatory bodies are implementing stringent guidelines to ensure efficient water usage. Elevated storage tanks are essential in managing water distribution systems, reducing waste, and enhancing water conservation efforts. Additionally, advancements in tank materials and manufacturing technologies have made these solutions more durable and cost-effective, encouraging widespread adoption.

Regionally, the Asia Pacific market is expected to witness the most substantial growth due to rapid industrialization and urbanization in countries like China and India. North America and Europe also represent significant market shares owing to the modernization of water infrastructure and the replacement of aging water storage systems. The Middle East & Africa and Latin America regions are anticipated to experience moderate growth driven by increasing investments in infrastructure development and water management projects.

Material Analysis

The material segment in the elevated water storage tanks market is categorized into steel, concrete, and composite. Steel tanks hold a significant market share due to their durability, strength, and resistance to environmental factors. They are widely used in both municipal and industrial applications where large volumes of water need to be stored securely. Steel tanks are often preferred for their longevity and ability to withstand adverse weather conditions, making them a reliable choice for long-term water storage solutions.

Concrete elevated water storage tanks are prominent, particularly in regions where construction materials are readily available. Concrete tanks offer excellent stability and can be customized to fit specific site requirements. They are often used in municipal applications to store water for residential areas. The ability to construct these tanks on-site allows for flexibility in design and capacity, making them a popular choice for large-scale water storage projects.

Composite tanks, made from materials like fiberglass, have been gaining traction due to their lightweight nature and co

The dataset contains year- and reservoir-wise compiled data on the weekly water storage level of reservoirs whose storage level is 80% or less than that of their normal average storage capacity in the last decade

Note: The term 'Reservoir' denotes to Dams, Reservoirs, Barrages and other Water Bodies where the water is stored and are monitored by Central Water Commission (CWC)

The Water Resources Agency and its affiliated agencies provide relevant information on the water storage range maps of various reservoirs in Taiwan for use by civil institutions, groups commissioned by government agencies, or academic units for government projects. This dataset is linked to a list of Keyhole Markup Language (KML) files, which is a markup language based on the XML syntax standard. It is developed and maintained by Keyhole, a company owned by Google, for expressing geographical annotations. Documents written in KML language are KML files, which also use the XML file format and are used in Google Earth-related software (Google Earth, Google Map, Google Maps for mobile...) to display geographical data (including points, lines, areas, polygons, polyhedra, and models...). Many GIS-related systems now also adopt this format for exchanging geographical data, with the KML in this dataset using UTF-8 for fields and encoding.

Plastic Water Storage Tank Market Outlook

The global plastic water storage tank market size is poised to grow significantly, reaching an estimated value of USD 9.5 billion by 2032, up from USD 5.3 billion in 2023, with a compound annual growth rate (CAGR) of 6.8% from 2024 to 2032. This market expansion is driven by a confluence of factors including the rising scarcity of freshwater resources, increasing global urbanization, and substantial developments in water management infrastructure. The demand for efficient and safe storage solutions is crucial as population growth and industrialization exert pressure on existing water supplies. Consequently, the plastic water storage tank industry is witnessing substantial investments and rapid innovation to meet the global demand.

One of the primary growth factors for the plastic water storage tank market is the increasing awareness and need for water conservation. As water scarcity becomes an intensifying global challenge, both developed and developing regions are investing in sustainable water management solutions. Plastic water storage tanks, known for their durability, adaptability, and cost-effectiveness, are increasingly being adopted for residential, commercial, and industrial applications. Furthermore, governments around the world are implementing policies and incentives to encourage the adoption of water storage systems as a means of promoting water conservation. This legislative support is providing a significant impetus to the market's growth trajectory.

Technological advancements in material science and manufacturing processes are further propelling the growth of this market. Innovations in plastic material compositions, such as the development of UV-stabilized and non-toxic plastics, have substantially enhanced the lifespan and safety of these storage tanks. The incorporation of smart technologies, including sensors for real-time monitoring and maintenance alerts, is also enhancing the appeal of plastic water storage tanks. These advancements are addressing consumer demand for reliable and long-lasting water storage solutions that require minimal maintenance, thus attracting a larger customer base and driving market growth.

The versatile application of plastic water storage tanks across various sectors is another critical factor contributing to market growth. These tanks are utilized in residential settings for rainwater harvesting and emergency water storage, while in industrial and commercial sectors, they are integral for processes requiring large quantities of water. The municipal sector also relies heavily on these tanks for public water supply systems. This broad application spectrum ensures a steady demand across diverse market segments, further bolstered by the rising need for clean and safe water storage solutions in disaster-prone and remote areas. As a result, the market is expected to experience steady growth across all application domains.

Agricultural Water Tanks play a crucial role in supporting the agricultural sector by providing reliable water storage solutions for irrigation and livestock needs. As agriculture remains a backbone of many economies, especially in rural areas, the demand for durable and efficient water storage systems is on the rise. These tanks are designed to withstand harsh environmental conditions and are often made from materials that prevent contamination, ensuring safe water for crops and animals. The integration of agricultural water tanks into farming practices not only aids in water conservation but also enhances productivity by ensuring a steady water supply during dry spells. With the increasing focus on sustainable farming, the adoption of these tanks is expected to grow, offering farmers a practical solution to manage water resources effectively.

Regionally, the Asia Pacific market is anticipated to lead in terms of growth rate due to rapid urbanization and industrialization, coupled with increasing government initiatives to enhance water infrastructure. North America and Europe are also significant markets, driven by stringent regulations regarding water quality and conservation. The Middle East & Africa region, although currently a smaller market segment, presents lucrative growth opportunities due to its chronic water scarcity issues. Latin America is witnessing moderate growth, with increasing investments in water management systems adding to the market dynamics. Overall, the global outlook for the plastic water storage tank market is robust, driven by a confluence of technological, regulatory, and societal

Making Earth System Data Records for Use in Research Environments (MEaSUREs) empowers the research community to participate in developing and generating data products that complement and augment NASA produced and distributed Earth science data products. NASA’s Enhanced Solid Earth Science Earth Science Data Record (ESDR) System (ESESES) continues and extends mature geodetic data product generation and archival as part of the MEaSUREs SESES project providing new, multi-decade, calibrated and validated geodetic-derived ESDRs obtained by the Scripps Institution of Oceanography (SIO) and NASA's Jet Propulsion Laboratory (JPL). These data-derived products include continuous multi-year high-rate GNSS, seismogeodetic, and meteorological time series, a catalog of transient deformation in tectonically active areas known for aseismic motion such as ETS with focus in Cascadia, and continuous estimation and cataloging of total near-surface water content derived from continuous GNSS time series over the continental U.S. These data products are grids of changes in total water storage over the continental U.S.; continuous estimation and cataloging of total near-surface water content derived from continuous GNSS time series over the continental U.S.

The province and its partners want to prevent flooding from watercourses as much as possible. Water storage areas are set up for this purpose. The Environmental Vision was adopted by the Provincial Council on 9 July 2014.

Drinking Water Storage Tank Market Outlook

The global drinking water storage tank market size was valued at approximately USD 3.5 billion in 2023 and is expected to reach around USD 5.8 billion by 2032, growing at a compound annual growth rate (CAGR) of 5.4% during the forecast period. The market growth is primarily driven by the increasing demand for safe and reliable drinking water storage solutions, coupled with the rising urban population and industrialization.

One of the key growth factors for the drinking water storage tank market is the growing awareness regarding the importance of clean and safe drinking water. With increasing concerns about water contamination and the rising prevalence of waterborne diseases, there is a significant push towards the development and adoption of advanced water storage solutions. This trend is further supported by stringent government regulations and initiatives aimed at ensuring water quality and public health. Moreover, technological advancements in materials and manufacturing processes are enhancing the efficiency and durability of drinking water storage tanks, thereby boosting market growth.

Another pivotal factor contributing to the market's expansion is the rapid urbanization and industrialization observed across various regions. As urban areas continue to expand and industrial activities increase, the demand for large-scale water storage facilities is on the rise. Industrial sectors, in particular, are major consumers of water storage tanks due to their extensive water usage requirements. Additionally, residential areas are also witnessing an upsurge in the installation of water storage tanks to address intermittent water supply issues and to ensure a consistent water supply during emergencies.

Technological innovations and the development of smart water storage solutions are also playing a crucial role in market growth. With the advent of smart sensors and IoT-enabled systems, modern water storage tanks are now equipped with features that allow for real-time monitoring of water levels, quality, and usage patterns. These advancements not only improve the efficiency of water management systems but also help in early detection of potential issues, thereby reducing maintenance costs and enhancing the overall lifespan of the tanks.

In addition to the growing demand for drinking water storage solutions, Chilled Water Storage Tanks are gaining traction in various sectors. These tanks play a crucial role in HVAC systems, particularly in large commercial and industrial buildings, where they are used to store chilled water for air conditioning purposes. The ability to store chilled water during off-peak hours and utilize it during peak demand times helps in reducing energy consumption and operational costs. The integration of chilled water storage systems is becoming increasingly popular in regions with high energy costs and stringent environmental regulations, as they contribute to energy efficiency and sustainability goals. Furthermore, advancements in tank materials and insulation technologies are enhancing the performance and efficiency of chilled water storage tanks, making them a viable option for modern building designs.

Regionally, the Asia Pacific dominates the drinking water storage tank market, driven by the rapid urbanization, industrial growth, and increasing investments in infrastructure development. Countries such as China and India are witnessing significant demand for water storage solutions due to their large populations and growing urban centers. North America and Europe also hold substantial market shares, primarily due to the presence of well-established water infrastructure and stringent regulatory frameworks. Latin America and the Middle East & Africa are emerging markets, with increasing investments in water infrastructure projects contributing to market growth in these regions.

Material Analysis

The drinking water storage tank market is segmented by material into concrete, steel, plastic, fiberglass, and others. Concrete tanks, known for their durability and high strength, are widely used in large-scale water storage applications. Their ability to withstand extreme weather conditions and provide long service life makes them a preferred choice for municipal and industrial applications. However, the heavy weight and complex installation process of concrete tanks can be a drawback, limiting their use in certain scenarios.

Steel tan

This dataset provides the measurements of raw water storage levels in reservoirs crucial for public water supply, The reservoirs included in this dataset are natural bodies of water that have been dammed to store untreated water.This dataset must not be used to determine the implementation of low supply or high supply measures such as hose pipe bans being put in place or removed. Please await guidance from your water supplier regarding any changes required to your usage of water.Particularly high or low reservoir levels may be considered normal or as expected given the season or recent weather.This dataset does not remove the requirement for visual checks on reservoir levels that are in place for caving/pot holing safety.Some water companies calculate the capacity of reservoirs differently than others. The capacity can mean the useable volume of the reservoir or the overall volume that can be held in the reservoir including water below the water table.

The NASA/NOAA Suomi National Polar-orbiting Partnership (Suomi NPP) Visible Infrared Imaging Radiometer Suite (VIIRS) Water Reservoir 8-day Level 3 (L3) Global (VNP28C2) Version 2 product provides current data for 151 man-made reservoirs and 13 regulated natural lakes for a total of 164 reservoirs.The VNP28C2 data product provides an 8-day time series of surface area, elevation, and water storage. Datasets are combined with pre-established Area-Elevation (A-E) curves and image classifications of near-infrared (NIR) reflectance from the surface reflectance product acquired by the VIIRS satellite (VNP09H1).The VNP28C2 data product consists of a single layer with information about the reservoir identifier, dam location (longitude and latitude), reservoir surface area, elevation, and water storage capacity. Known Issues* Water occurrence images generally show smaller surface area dynamics in high latitude regions, creating pixels with low occurrence values that have relatively large uncertainties. In addition, the quality of raw water area classification can be affected by lake ice coverage typically creating an overestimation of surface area in the enhancement algorithm. This issue will be addressed in a future release of the enhancement algorithm. For additional information about known issues, refer to the User Guide.

The global Outdoor Industrial Water Storage Tank market is poised for robust growth, projected to reach an estimated market size of approximately $6,400.5 million by 2025. This expansion is driven by a confluence of critical factors including increasing demand for reliable water management solutions across various industrial sectors, stricter environmental regulations promoting efficient water usage and storage, and the continuous need for robust infrastructure to support burgeoning populations and industrial activities. The market is anticipated to witness a Compound Annual Growth Rate (CAGR) of roughly 6.5% during the forecast period of 2025-2033, indicating a healthy and sustained upward trajectory. Key sectors like agriculture, water treatment, and pharmaceuticals are major contributors to this demand, each requiring specialized and large-scale storage capabilities to ensure operational continuity and compliance. Furthermore, the ongoing development and expansion of industrial facilities worldwide necessitate substantial investments in water storage infrastructure, further fueling market expansion. Emerging trends in the Outdoor Industrial Water Storage Tank market include a growing preference for advanced materials offering enhanced durability, corrosion resistance, and environmental sustainability. Innovations in tank design, such as modular systems and smart monitoring capabilities, are also gaining traction, enabling greater flexibility and efficiency in water management. While the market presents significant opportunities, certain restraints, such as the high initial investment cost for large-scale installations and the complexity of regulatory approvals in some regions, need to be navigated. However, the overarching imperative for water security, coupled with technological advancements, is expected to outweigh these challenges, ensuring a dynamic and expanding market landscape. Leading companies are actively investing in research and development to offer a diverse range of tank types, including concrete, metal, plastic, and fiberglass, catering to the specific needs of different applications and environmental conditions across global regions. This report delves into the dynamic global market for outdoor industrial water storage tanks, offering a detailed analysis of its current landscape and future trajectory. We provide in-depth insights into production volumes, key market drivers, prevailing trends, and segment-specific dominance, equipping stakeholders with actionable intelligence. The report meticulously examines industry characteristics, regulatory impacts, competitive strategies, and emerging technologies that are shaping the future of water storage solutions. With an estimated global market size exceeding USD 3,500 million in 2023, this sector is poised for significant expansion driven by increasing water scarcity concerns and robust industrial development across various applications.

The purpose of this feature class is to illustrate the location of water tanks in public water systems in the Commonwealth of Kentucky as collected by Kentucky’s Area Development Districts and provided by the Kentucky Division of Water. The locations of water tanks, along with the basic attribute data concerning those features, are used by the Kentucky Infrastructure Authority, Area Development Districts, public water systems, and other state/local agencies for the purpose of water infrastructure planning and management, project development, asset inventories, capital improvement plans, data analysis, and for any other purpose that will improve the potable water infrastructure and service in the Commonwealth of Kentucky.

The NOAA-20 Visible Infrared Imaging Radiometer Suite (VIIRS) Water Reservoir 8-day Level 3 (L3) Global (VJ128C2) Version 2 product provides current data for 151 man-made reservoirs and 13 regulated natural lakes for a total of 164 reservoirs.The VJ128C2 data product provides an 8-day time series of surface area, elevation, and water storage. Datasets are combined with pre-established Area-Elevation (A-E) curves and image classifications of near-infrared (NIR) reflectance from the surface reflectance product acquired by the VIIRS satellite (VJ109H1).The VJ128C2 data product consists of a single layer with information about the reservoir identifier, dam location (longitude and latitude), reservoir surface area, elevation, and water storage capacity. Known Issues* Water occurrence images generally show smaller surface area dynamics in high latitude regions, creating pixels with low occurrence values that have relatively large uncertainties. In addition, the quality of raw water area classification can be affected by lake ice coverage typically creating an overestimation of surface area in the enhancement algorithm. This issue will be addressed in a future release of the enhancement algorithm. For additional information about known issues, refer to Section 4 in the User Guide.

The City of Shasta Lake serves our customers with a reliable supply of drinking water through a distribution system with approximately 4000 connections over 11 square miles.

This service is available to all ArcGIS Online users with organizational accounts. For more information on this service, including the terms of use, visit us online at https://goto.arcgisonline.com/landscape11/USA_Soils_Available_Water_Storage.The amount of water in soil is based on rainfall amount, what proportion of rain infiltrates into the soil, and the soil's storage capacity. Available water storage is the maximum amount of plant available water a soil can provide. It is an indicator of a soil’s ability to retain water and make it sufficiently available for plant use. Available Water Storage is a capacity estimate for the top 150 centimeters of soil. It is calculated from the difference between soil water content at field capacity and the permanent wilting point adjusted for salinity and fragments.Available water storage is used to develop water budgets, predict droughtiness, design and operate irrigation systems, design drainage systems, protect water resources, and predict yields. Available water storage is an important input into hydrologic models including the Soil and Water Assessment Tool (SWAT) - a water quality model that is designed to assess non-point and point source pollution at the river basin scale. Available water storage can also be used as an indication of a soil's drought susceptibility, for water recharge modeling, to assess a soil's ability to support crops, and for many other purposes.Dataset SummaryPhenomenon Mapped: Amount of water a soil can hold, that is available to plantsUnits: MillimetersCell Size: 30 metersSource Type: DiscretePixel Type: Unsigned integerData Coordinate System: USA Contiguous Albers Equal Area Conic USGS version (contiguous US, Puerto Rico, US Virgin Islands), WGS 1984 Albers (Alaska), Hawaii Albers Equal Area Conic (Hawaii), Western Pacific Albers Equal Area Conic (Guam, Marshall Islands, Northern Marianas Islands, Palau, Federated States of Micronesia, and American Samoa)Mosaic Projection: Web Mercator Auxiliary SphereExtent: Contiguous United States, Alaska, Hawaii, Puerto Rico, Guam, US Virgin Islands, Marshall Islands, Northern Marianas Islands, Palau, Federated States of Micronesia, and American SamoaSource: Natural Resources Conservation ServicePublication Date: July 2020ArcGIS Server URL: https://landscape11.arcgis.com/arcgis/Data from the gNATSGO database was used to create the layer for the contiguous United States, Alaska, Puerto Rico, and the U.S. Virgin Islands. The remaining areas were created with the gSSURGO database (Hawaii, Guam, Marshall Islands, Northern Marianas Islands, Palau, Federated States of Micronesia, and American Samoa).This layer is derived from the 30m (contiguous U.S.) and 10m rasters (all other regions) produced by the Natural Resources Conservation Service (NRCS). The value for available water storage is derived from the gSSURGO map unit aggregated attribute table field Available Water Storage 0-150cm Weighted Average (aws0150wta).What can you do with this Layer?This layer is suitable for both visualization and analysis across the ArcGIS system. This layer can be combined with your data and other layers from the ArcGIS Living Atlas of the World in ArcGIS Online and ArcGIS Pro to create powerful web maps that can be used alone or in a story map or other application.Because this layer is part of the ArcGIS Living Atlas of the World it is easy to add to your map:In ArcGIS Online, you can add this layer to a map by selecting Add then Browse Living Atlas Layers. A window will open. Type "available water storage" in the search box and browse to the layer. Select the layer then click Add to Map.In ArcGIS Pro, open a map and select Add Data from the Map Tab. Select Data at the top of the drop down menu. The Add Data dialog box will open on the left side of the box, expand Portal if necessary, then select Living Atlas. Type "available water storage" in the search box, browse to the layer then click OK.In ArcGIS Pro you can use the built-in raster functions or create your own to create custom extracts of the data. Imagery layers provide fast, powerful inputs to geoprocessing tools, models, or Python scripts in Pro.Online you can filter the layer to show subsets of the data using the filter button and the layer's built-in raster functions.The ArcGIS Living Atlas of the World provides an easy way to explore many other beautiful and authoritative maps on hundreds of topics like this one.

Globally, many waterbodies and floodplains have been lost, degraded, or are at risk for further loss, which may have unintended consequences for rivers, including exacerbating flood and drought conditions. We explored how including surface water storage time series in deep learning models influences our ability to predict river discharge. We utilized Sentinel-1 and Sentinel-2 algorithms to generate time series of surface water extent. Surface water extent (m2) was converted to storage (m3) using topographic estimates of depression probability and depth. These surface water storage estimates were then tested with meteorological data and catchment characteristics in four Long Short-Term Memory (LSTM) models, each containing a different combination of variable groups, to simulate daily river discharge (2016-2023) for 72 watersheds across the conterminous United States.

Updated quarterly. To identify the location of water tanks in the County.

1. Summary

The Congo basin’s Surface Water Storage (SWS) datasets are generated by Benjamin Kitambo, Fabrice Papa, Adrien Paris, Raphael M. Tshimanga, Frederic Frappart, Stephane Calmant, Omid Elmi, Ayan Santos Fleischmann, Melanie Becker, Mohammad J. Tourian, Rômulo A. Jucá Oliveira, Sly Wongchuig in the article entitled "A long-term monthly surface water storage dataset for the Congo basin from 1992 to 2015", Earth System Science Data (submitted).

The dataset was generated using two methods, one based on a multi-satellite approach and one on a hypsometric curve approach. The multi-satellite approach consists of the combination of surface water extent (SWE) from the Global Inundation Extent from Multi-satellite (GIEMS-2) and satellite-derived surface water height (SWH) from radar altimetry (long-term series ERS-2_ENV_SRL) on the same period of availability for the two datasets, here 1995-2015. The hypsometric curve approach consists of the combination of SWE from GIEMS-2 dataset and hypsometric curves obtained from various digital elevation models (DEMs) (i.e., ASTER, ALOS, MERIT, and FABDEM). Both methods estimate monthly spatio-temporal variations of SWS changes across the entire Congo River basin.

2. Name Description

• HYPSO_XX: hypsometric curve providing the surface water extent area-elevation relationship from XX (where XX stands for ASTER, ALOS, MERIT, and FABDEM DEMs).
• HYPSO_CORR_XX: corrected hypsometric curve providing the surface water extent area-elevation relationship from XX (where XX stands for ASTER, ALOS, MERIT, and FABDEM DEMs).
• AREA_STOR_XX: hypsometric curve providing the surface water extent area-storage relationship from XX (where XX stands for ASTER, ALOS, MERIT, and FABDEM DEMs).
• SWS_XX: monthly surface water storage variations from XX (where XX stands for ASTER, ALOS, MERIT, FABDEM DEMs, and Multi-satellite approach).

3. File Description

The SWS estimates from the multi-satellite approach (1995-2015), as well as the hypsometric curves providing the surface water extent area-elevation relationship from the four DEMs (before and after the corrections), the surface water extent area-storage relationship, along with the four SWS estimates (1992-2005).

The dataset is gridded on equal-area of 0.25° spatial resolution at the equator, each pixel covers almost 773 km². The reference point for calculating the volume variation is the minimum of surface water extent for each pixel.

The files are organized in matrix:

• First column represents the latitude in degree.
• Second column represents the longitude in degree.
• From the third column: data. In case of hypsometric curve, the data represents elevation in meter on 101 columns representing the increment of 1% flooding in each 773 km² pixel from GIEMS-2. In case of SWS data (in km³), there are 288 (respectively 252) columns representing each month of the period over 1992-2015 (respectively 1995-2015) from hypsometric curve approach (respectively multi-satellite approach).

Water Storage Tanks Market Outlook

According to our latest research, the global water storage tanks market size stood at USD 17.45 billion in 2024, reflecting robust demand across diverse end-user sectors. The market is expected to expand at a CAGR of 4.7% from 2025 to 2033, reaching an estimated value of USD 26.51 billion by the end of the forecast period. This growth is primarily fueled by increasing urbanization, heightened awareness regarding water conservation, and the need for reliable water storage solutions in both developed and emerging economies.

One of the key growth drivers for the water storage tanks market is the escalating global water scarcity and the rising emphasis on sustainable water management practices. As urban populations swell and industrialization accelerates, the demand for efficient water storage systems has become paramount. Governments and private organizations are investing heavily in infrastructure upgrades, including robust water storage facilities, to ensure a consistent supply of potable and non-potable water. Additionally, stricter regulations around water conservation and rainwater harvesting, particularly in water-stressed regions, are further propelling the adoption of advanced water storage tanks across the globe.

Technological advancements in tank materials and manufacturing processes have also played a pivotal role in boosting the market. The development of high-strength, corrosion-resistant materials such as advanced plastics, fiberglass, and coated steel has significantly extended the lifespan and reliability of water storage tanks. These innovations not only reduce maintenance costs but also enhance the safety and quality of stored water. Furthermore, the increased integration of smart monitoring systems and automation in water storage solutions is enabling real-time tracking of water levels and quality, thereby improving operational efficiency for end-users across residential, commercial, and industrial sectors.

Another significant factor contributing to the market’s expansion is the growing adoption of water storage tanks in agriculture and municipal applications. With unpredictable rainfall patterns and the intensification of drought conditions in several regions, farmers and local governments are increasingly relying on storage tanks for irrigation and emergency water supply. The construction industry’s growth, particularly in emerging economies, is also stimulating demand for water storage tanks in residential and commercial buildings. These trends are expected to continue driving the market forward, supported by favorable government policies and incentives for water conservation initiatives.

Regionally, Asia Pacific dominates the water storage tanks market due to rapid urbanization, high population density, and significant investments in water infrastructure. North America and Europe are also witnessing steady growth, driven by modernization of existing water systems and stringent environmental regulations. The Middle East & Africa and Latin America, while currently smaller in market share, are projected to experience above-average growth rates due to increasing focus on water security and infrastructure development. The regional outlook remains positive, with all major markets expected to contribute to the sustained expansion of the global water storage tanks industry through 2033.

Material Analysis

The material segment of the water storage tanks market is highly diversified, encompassing options such as plastic, concrete, steel, fiberglass, and other specialized materials. Plastic water storage tanks, particularly those made from polyethylene and polypropylene, have gained significant traction due to their lightweight nature, ease of installation, and resistance to corrosion and chemical contamination. The cost-effectiveness and adaptability of plastic tanks make them a preferred choice for residential, agricultural, and even certain industrial applications. Their ability to be molded into various shape

Portable Water Tank Market size was valued at USD 1.34 Billion in 2023 and is projected to reach USD 7.46 Billion by 2030, growing at a CAGR of 10.6% during the forecasted period 2024 to 2030

Global Portable Water Tank Market Drivers

Population Growth: As the world's population rises, there is a growing need for solutions for storing drinkable water, which propels the market for potable water tanks to expand.

Urbanization: As cities' water supply networks grow quickly as a result of urbanization, potable water tanks must be installed for distribution and storage in urban regions. Infrastructure Development: To guarantee a sufficient supply of drinkable water, infrastructure development projects, such as the erection of residential complexes, commercial buildings, and industrial facilities, need to have dependable portable water storage systems.

Water Scarcity and Drought Conditions: As worries about water shortages and droughts spread throughout different areas, potable water tanks are being used as an effective way to store and manage water resources.

Government laws: To maintain compliance, industries and municipalities are required to invest in high-quality potable water tanks by government agencies worldwide, who impose strict laws governing water quality and safety standards.

Climate Change: The likelihood of water shortages is increased by climate change-related phenomena including unpredictable rainfall patterns and extreme weather events. These events also highlight the significance of infrastructure for the storage of potable water for resilience and adaptation.

Technological developments: As consumers look for more dependable and environmentally friendly options, improvements in the materials, designs, and manufacturing techniques of potable water tanks lead to increased robustness, longevity, and efficiency. This promotes market expansion.

Issues with Public Health: The necessity for safe and sanitary potable water storage systems is being highlighted by an increasing awareness of waterborne diseases and contaminants. This is driving demand for sophisticated potable water tanks with features like corrosion resistance and UV disinfection.

Industrial Applications: The need for large-scale potable water storage systems for operations across a range of industries, including manufacturing, food and beverage, and pharmaceuticals, is driving the growth of the industrial sector's market.

Economic Factors: The demand for potable water tanks is influenced by economic growth, infrastructural investment, and levels of disposable income, especially in emerging economies that are experiencing fast urbanization and development.