wastewater processing and water conservation practices in florida
水污染的建议书
水污染的建议书英文回答:Water pollution is a significant environmental issuethat poses serious threats to human health, aquatic ecosystems, and the overall well-being of our planet. It'sa complex problem with myriad causes and far-reaching consequences. I'm deeply concerned about the devastating effects of water pollution and feel compelled to offer my suggestions for addressing this pressing challenge.Industrial activities, agricultural runoff, sewage discharge, and littering are just a few of the human-induced factors that contribute to water pollution. These pollutants can include toxic chemicals, heavy metals, pesticides, and pathogens that contaminate our water bodies. When consumed or ingested, contaminated water can lead to a range of health issues, from gastrointestinal problems to cancer and reproductive disorders.Protecting our water resources is paramount. Here are some concrete suggestions that I believe can make a meaningful difference:Enforce stricter regulations and penalties for polluters. Governments must hold industries and individuals accountable for their actions by implementing stringent regulations and imposing hefty fines for non-compliance. This will deter polluters and incentivize responsible behavior.Invest in wastewater treatment facilities. Many developing countries lack adequate wastewater treatment infrastructure, resulting in raw sewage being discharged directly into rivers and streams. Investing in these facilities is essential for preventing the spread of waterborne diseases and protecting aquatic life.Promote sustainable agricultural practices. Farmers should adopt eco-friendly methods such as crop rotation, cover crops, and precision fertilization to minimize the use of pesticides and fertilizers that can pollute watersources.Reduce plastic consumption and waste. Plastics are a major source of marine pollution, as they break down into tiny pieces that are ingested by wildlife and can accumulate in the food chain. Reducing our reliance on single-use plastics and promoting recycling cansignificantly reduce plastic pollution in our oceans.Educate the public about the importance of water conservation and pollution prevention. Raising awareness about the harmful effects of water pollution can foster behavioral changes that contribute to cleaner water bodies. Educational campaigns can encourage responsible water consumption, proper waste disposal, and support for conservation efforts.By working together, we can turn the tide on water pollution. Governments, industries, and individuals all have a role to play in safeguarding this precious resource. It's time to act decisively to ensure that future generations have access to clean and healthy water.中文回答:水污染是一个严重的环境问题,对人类健康、水生生态系统和我们星球的整体福祉构成了严重威胁。
高中英语作文《水资源利用与保护》
高中英语作文《水资源利用与保护》Title: The Utilization and Protection of Water ResourcesWater resources, as a vital element for the existence and development of human beings, are facing increasing challenges due to over-exploitation and environmental pollution.The efficient utilization and protection of water resources have become topics of great concern globally.On one hand, water resources are indispensable for various sectors such as agriculture, industry, and daily life.Agriculture, in particular, heavily relies on irrigation for crop production.Moreover, industries require vast amounts of water for manufacturing processes, and individuals need clean water for drinking and sanitation.On the other hand, the over-exploitation and pollution of water resources have led to severe problems.For instance, rivers have been drying up, lakes are shrinking, and the quality of groundwater is declining.These issues not only affect the sustainability of water resources but also lead to ecological imbalances, which in turn, impact the economy and social stability.To address these challenges, effective measures should be taken.First and foremost, it is crucial to enhance the awareness of water conservation among the cating individuals about the importance of water resources and the necessary practices to save and protect them cansignificantly contribute to sustainable water usage.Additionally, governments should enforce stricter regulations on water resource management.This includes setting limits on water withdrawal, improving wastewater treatment and recycling systems, and adopting policies that promote water-saving technologies and practices in industries and agriculture.Furthermore, investment in research and development of new technologies for water purification, desalination, and efficient irrigation should be increased.These advancements can help meet the growing demand for water while minimizing the negative impacts on water resources.In conclusion, the efficient utilization and protection of water resources are of utmost importance for sustainable development.By raising public awareness, implementing strict regulations, and investing in technological advancements, we can ensure the availability of clean and adequate water for future generations.。
水处理英语词汇
水处理通用术语一、水处理通用术语给水排水工程的通用术语及其涵义:1、给水工程 water supply engineering 原水的取集和处理以及成品水输配的工程。
2、排水工程 sewerage ,wastewater engineering 收集、输送、处理和处置废水的工程。
3、给水系统 water supply system 给水的取水、输水、水质处理和配水等设施以一定方式组合成的总体。
4、排水系统 sewerage system 排水的收集、输送、水质处理和排放等设施以一定方式组合成的总体。
5、给水水源 water source 给水工程所取用的原水水体。
6、原水raw water 由水源地取来的原料水。
7、地表水surface water 存在于地壳表面,暴露于大气的水。
8、地下水ground water 存在于地壳岩石裂缝或工壤空隙中的水。
9、苦咸水(碱性水) brackish water ,alkaline water 碱度大于硬度的水,并含大量中性盐,PH值大于7。
10、淡水fresh water 含盐量小于500mg/L的水。
11、冷却水cooling water 用以降低被冷却对象温度的水。
12、废水 wastewater 居民活动过程中排出的水及径流雨水的总称。
它包括生活污水、工业废水和初雨径流以及流入排水管渠的其它水。
13、污水sewage ,wastewater 受一定污染的来自生活和生产的排出水。
14、用水量 water consumption 用水对象实际使用的水量。
15、污水量 wastewater flow ,sewage flow 排水对象排入污水系统的水量。
16、用水定额 water flow norm 对不同的排水对象,在一定时期内制订相对合理的单位排水量的数值。
17、排水定额 wastewater flow norm 对不同的排水对象,在一定时期内制订相对合理的单位排水量的数值。
污水处理流程英语介绍
污水处理流程英语介绍Wastewater treatment is a critical process that aims to remove contaminants from wastewater, primarily from industrial, commercial, and domestic sources, to produce an effluent that can be safely discharged into the environment. The process typically involves several stages to ensure that the water is clean and free from harmful substances.The first stage in wastewater treatment is the preliminary treatment, which includes screening to remove large debris such as leaves, branches, and trash. This is followed by grit removal, where small stones and sand are separated from the water.The next step is the primary treatment, which is the sedimentation process. Here, suspended solids settle at the bottom of sedimentation tanks, forming sludge. This sludge is then removed and treated further, while the clarified water moves on to the secondary treatment.Secondary treatment involves biological processes that use microorganisms to break down organic matter in the wastewater. This can be done in various ways, such as activated sludge, trickling filters, or rotating biological contactors. During this stage, a significant portion of the organic material is converted into carbon dioxide, water, and new biomass.Tertiary or advanced treatment is the final stage, which may include processes like filtration, disinfection, and nutrient removal. Filtration removes fine particles, while disinfection, typically using chlorine or ultraviolet light, kills any remaining pathogens. Nutrient removal, especially phosphorus and nitrogen, is important to prevent eutrophication in water bodies.After tertiary treatment, the treated water, known as effluent, is often discharged into rivers or used for non-potable purposes such as irrigation or industrial cooling. The sludge produced during the treatment process is typically further processed to reduce its volume and treated to be used as fertilizer or disposed of in a sanitary landfill.It's important to note that the exact treatment process can vary depending on the nature of the wastewater and the local regulations. Continuous monitoring and maintenance are essential to ensure the effectiveness of the treatment plant and to protect public health and the environment.。
英语作文废水处理
英语作文废水处理Water is one of the most essential resources for human survival, and it is crucial to ensure that the water we use is clean and safe. However, with the rapidindustrialization and urbanization, the issue of water pollution has become increasingly severe. One of the major sources of water pollution is the discharge of wastewater from industrial processes and domestic activities. Therefore, it is important to develop effective wastewater treatment methods to protect our water resources and the environment.Wastewater treatment is the process of removing contaminants from wastewater, making it safe to be discharged back into the environment or reused. There are several steps involved in wastewater treatment, including physical, chemical, and biological processes. The goal of these processes is to remove pollutants such as organic matter, nutrients, and toxic substances from the wastewater, and to disinfect it to prevent the spread of waterbornediseases.One of the most common methods of wastewater treatmentis the use of sewage treatment plants. These plants use a combination of physical, chemical, and biological processes to remove contaminants from the wastewater. In the physical treatment stage, large solids are removed from the wastewater through processes such as screening and sedimentation. Then, in the chemical treatment stage, chemicals such as chlorine are added to the wastewater to remove pathogens and other harmful substances. Finally, in the biological treatment stage, microorganisms are used to break down organic matter in the wastewater.Another method of wastewater treatment is the use of constructed wetlands. Constructed wetlands are artificial wetlands that are designed to mimic the natural processesof wetland ecosystems. In these wetlands, plants and microorganisms help to remove pollutants from the wastewater through processes such as filtration, adsorption, and microbial degradation. Constructed wetlands are an effective and environmentally friendly method of wastewatertreatment, as they can remove a wide range of contaminants and provide habitat for wildlife.In addition to these traditional methods of wastewater treatment, there are also emerging technologies that show promise in treating wastewater more effectively. For example, membrane bioreactors use a combination of biological treatment and membrane filtration to remove contaminants from wastewater. This technology is particularly effective in treating wastewater with high organic and nutrient content. Another emerging technology is electrocoagulation, which uses an electric current to remove contaminants from wastewater through processes such as coagulation, flocculation, and oxidation.Overall, wastewater treatment is a crucial process for protecting our water resources and the environment. By developing and implementing effective wastewater treatment methods, we can ensure that the water we use is clean and safe for both human consumption and the environment. It is important for governments, industries, and individuals to work together to invest in wastewater treatmentinfrastructure and technologies, and to promote water conservation and pollution prevention practices. Only by doing so can we ensure a sustainable and healthy future for our water resources.。
污水制理英语作文
污水制理英语作文Wastewater treatment is a critical process that plays a vital role in maintaining the health and well-being of our communities and the environment. As our population continues to grow and industrialization expands, the volume of wastewater generated has increased significantly, making effective treatment a pressing concern. Wastewater, which includes domestic sewage, industrial effluents, and agricultural runoff, can contain a variety of contaminants that, if left untreated, can have severe consequences on our water resources, ecosystems, and human health.The primary goal of wastewater treatment is to remove or reduce the level of these contaminants to acceptable levels before the water is discharged back into the environment. This process typically involves a series of physical, chemical, and biological treatments that work together to ensure the water meets the required standards for safe discharge or reuse.The first stage of wastewater treatment is the preliminary treatment, which involves the removal of large solids, debris, and other coarsematerials that may have entered the system. This is typically done through screening and grit removal processes, which help to protect the downstream equipment and processes from damage or clogging.Following the preliminary treatment, the wastewater undergoes primary treatment, where the focus is on the removal of suspended solids and organic matter. This is typically accomplished through sedimentation, where the wastewater is allowed to settle, allowing the heavier solids to sink to the bottom of the treatment tank. The settled solids, known as primary sludge, are then removed for further processing or disposal.The next stage is the secondary treatment, which is designed to remove the remaining organic matter and nutrients, such as nitrogen and phosphorus, from the wastewater. This is typically achieved through biological processes, where microorganisms are used to break down the organic matter and convert the nutrients into less harmful forms. Common secondary treatment methods include activated sludge, trickling filters, and membrane bioreactors.In the activated sludge process, for example, the wastewater is aerated and mixed with a population of microorganisms, which consume the organic matter and convert it into carbon dioxide and new cellular material. The treated wastewater is then separated from the microorganisms, and the excess sludge is removed for furtherprocessing.After the secondary treatment, the wastewater may undergo additional advanced treatment, depending on the specific requirements of the receiving water body or the intended use of the treated water. This may include processes such as disinfection, to remove any remaining pathogens, or nutrient removal, to further reduce the levels of nitrogen and phosphorus.One of the key benefits of effective wastewater treatment is the protection of our water resources. By removing contaminants from the wastewater, we can prevent the pollution of lakes, rivers, and oceans, which are vital sources of drinking water, recreation, and habitat for aquatic life. Additionally, the treated water can be reused for various purposes, such as irrigation, industrial processes, or even groundwater recharge, reducing the demand on freshwater sources.Another important aspect of wastewater treatment is the management of the byproducts generated during the process. The sludge and other solid waste that are removed from the wastewater must be properly handled and disposed of to prevent further environmental harm. This may involve processes such as dewatering, stabilization, and incineration, depending on the characteristics of the waste.In recent years, there has been a growing focus on the concept of resource recovery from wastewater, where the byproducts of the treatment process are viewed as valuable resources rather than waste. This includes the recovery of nutrients, such as nitrogen and phosphorus, which can be used as fertilizers, as well as the production of biogas, which can be used as a renewable energy source.Overall, wastewater treatment is a critical component of our modern infrastructure, ensuring the protection of our water resources, public health, and the environment. As the demand for water continues to grow, the need for efficient and sustainable wastewater treatment solutions will only become more pressing. By investing in the development and implementation of advanced wastewater treatment technologies, we can work towards a future where water is managed as a precious and renewable resource, rather than a waste product.。
英语作文-废水处理与再利用技术创新
英语作文-废水处理与再利用技术创新In the realm of environmental engineering, wastewater treatment and reuse stand as critical components in the sustainable management of water resources. The innovation in this field is not just a matter of necessity but also an opportunity to demonstrate the ingenuity of human ingenuity in the face of ecological challenges.The journey of wastewater from being a potential pollutant to a valuable resource begins with the understanding that water, once used, does not have to be wasted. Technological advancements have paved the way for various treatment processes that can effectively remove contaminants, making the water safe for reuse. These processes range from primary treatments, which remove solids and organic matter, to advanced tertiary treatments that employ sophisticated methods like reverse osmosis and ultraviolet disinfection.One of the most promising innovations in wastewater treatment is the development of membrane bioreactors (MBRs). MBRs combine conventional biological treatment with membrane filtration, resulting in a system that provides high-quality effluent suitable for reuse in irrigation and even as potable water. The compact nature of MBRs also means they require less space than traditional treatment plants, making them ideal for urban areas where space is at a premium.Another significant advancement is the use of constructed wetlands for wastewater treatment. These engineered ecosystems mimic the natural purification processes found in wetlands. As wastewater flows through the wetland, plants and microorganisms work in concert to remove pollutants. This method not only treats the water but also creates habitats for wildlife, contributing to biodiversity.The integration of smart technologies into wastewater treatment processes is also gaining traction. Sensors and real-time data analytics can optimize treatment operations, ensuring maximum efficiency and minimal energy consumption. These smart systems can adapt to changes in wastewater flow and composition, providing consistent treatment quality and reducing the need for human intervention.The reuse of treated wastewater is equally important as the treatment itself. Reclaimed water can be a reliable alternative source for agricultural irrigation, industrial processes, and replenishing groundwater. This not only conserves freshwater resources but also reduces the environmental impact of discharging treated water into natural bodies of water.Public perception and acceptance play a vital role in the success of wastewater reuse programs. Educational campaigns and transparent communication about the safety and benefits of using reclaimed water can help in garnering public support. It is essential to ensure that the water meets stringent quality standards and is safe for its intended use.In conclusion, the innovation in wastewater treatment and reuse technologies is a testament to the resilience and adaptability of human ingenuity. By embracing these technologies, we can turn the tide on water scarcity and protect our precious water resources for future generations. The continuous improvement and implementation of these systems will be crucial in building a sustainable and water-secure world. 。
最新环境科学专业外语Unit 13复习过程
Occasionally,raw water with low turbidity can be treated by plain sedimentation (no chemicals) to remove larger particles and then filtration to remove the few particles that failed to settle out.
它工艺相对简单,造价低廉,可以造成圆形、正方形、 矩形。
As noted earlier, sedimentation may follow coagulation and flocculation (for highly turbid water) or be omitted entirely (with moderately turbid water).
地表水中的悬浮颗粒物的粒径在10-1和10-7毫米之间, 分别是细沙和微尘的尺寸。
Turbidity or cloudiness in water is caused by those particles larger than 10-4 mm, while particles smaller than 10-' contribute to the water's color and taste.
从水中去除颗粒物的操作步骤包括隔离、混凝/ 絮凝、沉淀、过滤。
Screening to remove large solids such as logs, branches, rags,and small fish is the first stage in the treatment of water.
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Running head: Wastewater Processing and Water Conservation Practices in FloridaWastewater Processing and Water Conservation Practices in FloridaJake EmersonUniversity Of FloridaAbstractThe sustainable use of water has become quite a concern for all professionals within the building construction and construction design industry. Our lack of water conservation practices in the United States and the steady increase in worldwide population has led to a deficiency of water supply to the expected future demand. In an effort to efficiently utilize our water resources, architects have made design innovations and construction professionals have utilized new construction techniques. Some of the most popular practices used today are water harvesting, and the reuse of greywater. Water from the bath, shower, washing machine, and bathroom sink are the sources of greywater that can effectively be recycled for other uses. The ways in which these two water conservation practices are used in construction is limitless, but the benefit from the sustainable use of finite water resources is necessary for future demand. The state of Florida could potentially be a perfect candidate for these types of green practices due to its climate and need for sustainable water supply/use techniques. The reuse of greywater has many applications and has long strides to make in the future. Greywater treatment and reuse will hold many innovative techniques and practices that professionals are developing every day.Wastewater Processing and Water Conservation Practices in Florida “Despite the common belief that Florida has an overabundance of freshwater for human use, in reality Florida has similar water shortage problems as do many other states” (Plant Management in Florida Waters, 2004). Florida has a large population and due to its beautiful coastline and comfortable climate, the population is exponentially growing every year. The state of Florida is divided into five subdivisions of populations that consume water. Some of the divisions do not have any problems supplying the current demand, and there are other divisions that do not have enough water to supply the population. These water deficient divisions are requesting more of the finite resource to supply the growing demand when they did not have enough water to supply the population they started with. It is not just the population growth that is a cause for concern, there is also data that supports that the individual citizens of Florida consume a great deal of water. Floridians use more water per capita than residents of any other state except California(Plant Management in Florida Waters, 2004). The fresh water is used for many different purposes in Florida including: agriculture, industrial, recreational irrigation, domestic lawn irrigation, municipal, and power generation. Agriculture in Florida is the largest consumer of fresh water due to the required water for proper irrigation. These consumption issues must be resolved by Florida and its citizens to ensure that we find a sustainable balance of our finite water resources. Some of the most promising methods of water conservation are the reuse of greywater and water harvesting. These two methods are already in use in many different countries including the United States. This report will explain the two methods in their application to Florida as well as some of the examples that are already in progress.Using water harvesting as a way to conserve water is not a new technique. In fact, the practice of rainwater harvesting or the catchment and distribution of rainwater is hundreds of years old. The reason why this can be such a beneficial technique for Florida is because the state receives an average of 54 inches of rainfall per year (Plant Management in Florida Waters, 2004). A rainwater harvesting system is typically composed of the following components: catchment, conveyance system, filtration, storage, and distribution. The catchment is the area by which the rainwater falls and eventually collected by. In Florida, a catchment surface would typically be metal, clay, and cementitious materials however; other materials such as asphalt shingles can be used with proper filtration systems (Sustainable Building Sourcebook, 2005). A conveyance system is the means by which water is transported to the rainwater storage unit. A gutter system and possibly conveyance piping are the most popular conveyance systems in Florida. The gutter system optimizes gravity as a propulsion system for the rainwater with the application of a slope upon gutter installment. The gutter is eventually connected to a downspout that takes the rainwater to either conveyance piping or the storage system. The rainwater is stored in a cistern that can be installed above or below ground. To optimize the performance a cistern, the storage unit should be composed of concrete, steel, ferro-cement, or fiberglass (Sustainable Building Sourcebook, 2005). The cistern type is dependent upon whether its intended use is for potable or non-potable water. Because the catchment surface is exposed to outside elements that may cause contamination, a filtering system is required to separate the water from potential debris.A filter can be placed over the gutter system for this process but if the rainwater is intended to be a source of potable water the use of a roof washer is suggested. “Theprimary function of the roof washer is to isolate and discard the first water that has fallen on the roof after rain has begun and then direct the rest of the water to the cistern. Ten gallons of rainfall per thousand square feet of roof area is considered an acceptable amount for washing” (Sustainable Building Sourcebook, 2005). The final component to the water harvesting system is the distribution system, which can be via gravity or a pumping system depending upon the installation location of the cistern. If the water is intended to be used as potable water, an additional purification system is required. These are all important to consider when applyi ng these systems and their role in Florida’s water conservation effort because each component affects the life cycle cost of the system.Greywater is water that has been used by washing machines, sinks, dishwashers, and bath use. Greywater is not to be confused with blackwater, which is water that has been used for human waste. Greywater and its application towards water conservation does not have the historical roots of water harvesting, however; the technique is gaining in popularity at a rapid pace. On average, the US household will consume 74 gallons of water for indoor use (American Water Works Association, 2005). An average of 42.5 gallons of the 74 gallons is greywater that can be recycled for other uses (American Water Works Association, 2005). Greywater is typically recycled for use in toilets, and landscape irrigation. American households use an average of up to 70% of their water use per capita to irrigate domestic gardens and lawns (American Water Works Association, 2005). This does not even include the countless gallons of water that Florida’s thriving agriculture industry uses to irrigate crops. Though greywater recycling has many benefits, the potential use in irrigation alone could have a huge effect onFlorida’s water conservation effo rt. “The benefits of grey water recycling include: lower fresh water use, less strain on failing septic tanks or treatment plants, grey water treatment in topsoil is highly effective, ability to build in areas unsuitable for conventional treatment, less energy and chemical use, groundwater recharge, plant growth, and reclamation of otherwise wasted nutrients” (Oasis Design, 2005).There are many methods that Florida could use to treat greywater for recycled use. One method that uses biological treatment with a rotating biological contactor (RBC) is very effective (Freewater UK Ltd., 2004). After the RBC stage has completed, the disinfection of greywater is by means of UV radiation (Oasis Design, 2005). Some other systems use natural methods with plants, snails, and other natural means to treat the water before reuse. Countries like Germany are currently experimenting with greywater purification plants for mass production. In Canada, a housing project system will be capable of treating gray water from sinks, laundry, and showers for reuse in showers, laundry, and toilets (Oasis Design, 2005). Processes like this where humans come in direct contact with the water are still in the experimental phase due to possible health issues.Some of the barriers affecting the approval of greywater reuse are mainly due to the soil type and safety. The texture, structure, and the slope of the soil that will utilize the recycled greywater all affect the ability to use the technique. Another problem is that greywater is a perfect carrying system for harmful bacteria like Ecoli. There are many states in the US that have not legally approved the practice of greywater recycling for irrigation. The scope of use and standards of greywater and wastewater reuse are outlined in Chapter 62-610, Florida Administrative Code, and Title XXIX, Public Health Chapter381.0065 of the Florida statutes (Florida Department of Environmental Protection, 2005). Although these policies mainly address reclaimed water, it is the only legal restriction close to greywater that Florida has. The laws set forth by the state of Arizona on greywater are arguably the most inclusive and beneficial way to promote and regulate the process. Arizona uses a three tiered system based on quantity used that includes, R18-9-711 (systems under 400gpd), R18-9-719 (systems 400 to 3000 gpd), and R18-9-101 (systems over 3000gpd) (Oasis Design, 2005). These laws require the permitting of the use of greywater as a means of irrigation as well as a government published booklet on greywater and its safe use. This might be a format that the National Legislative and Regulatory Committee might emulate in the future to promote the legal use of greywater in Florida’s future (Water Reuse for Florida, 2003).One of the biggest barriers of the adoption of these two methods is the initial cost of the system components. A consumer must be able to value the water supply enough to purchase the extra equipment that is necessary to operate one of these efficient systems. The typical cost of water is so low that it takes a relatively long time to make up the cost of the efficient components. The potential of water increasing in price due to the law of supply and demand, or as a method of inducing conservation might be in the near future. Martin and Kulakowski from the EPA recently stated, “Information and education promoting conservation do not appear to be effective by themselves in achieving a conservation goal without at the same time imposing significant price increases to provide a financial incentive to conserve water”(U.S. Environmental Protection Agency, 2003).There are already examples of these water conservation techniques in Florida. One of the most popular residential examples is the house provided by The Florida House Learning Center. This house is located in Sarasota and among its water conserving features is a greywater and water harvesting system. The water harvesting system utilizes 2-2,500 gallon tanks, 3,900 square feet of catchment surface, and a system of pumps to allocate the water (Pushard, 2004). A major component to the greywater system is a kitchen filtration system to cleanse the water of unwanted debris and sediment (Pushard, 2004). This project, designed for public education, has had thousands of visitors since its doors opened in 1994. “The Average water per capita use in Florida has been reduced by almost 40% - from 140 (530 liters) to 88 gallons (333 liters) per day, in the years since the Florida House opened (Pushard, 2004).In non-residential construction, these methods are also prevalent. Florida Universities are adopting water harvesting building techniques. University of Florida uses the technique to obtain LEED certification on new buildings, and the University of South Florida uses water harvesting as a component to green roof systems. Though Florida is showing an interest in the adoption of these water conservation techniques there are a few benchmark examples of water harvesting.In Melbourne, Australia, a zero water use commercial building, the 60L, has been constructed. The building uses rainwater as a supply for every type of consumption with the exception of the fire sprinklers. “The rain is collected from the roof, stored in two tanks on the ground floor, filtered, and then sterilized prior to use by tenants in taps and showers” (Pushard, 2005). “More than 132,000 gallons (500 kiloliters) of rainwater can be collected in an average year” (Pushard, 2005). The 60L also contains a greywaterrecycling system to optimize the tenant’s use of water. The used water from the tenants is fed into a biological treatment system and is then used again as toilet water, irrigation for the roof garden, and use in the water feature of the building. One of the most amazing things about this project compared to Florida is that Australia only receives and average of 25.8 inches of rain per year compared to Florida’s 54 inches. This example illustrates how effective these methods could be if utilized in Florida.The final, and most innovative method of using a greywater technique, is the Living Machine in Oberlin, Ohio. “The Living Machine® treats wastewater using a system of engineered ecologies that include microbes, plants, snails and insects, and is designed to treat up to 2,000 gallons of the building's wastewater daily in a beautiful, garden-like atmosphere”(Janas, 2000). The greywater and blackwater combined go through a system of native plants and different bioreactors before receiving a final Ultraviolet disinfection treatment so that the water can be used again in the 13,600 square foot facility. This is an important example because it can be inexpensively applied to greywater systems in Florida, thus making the cost benefit that much more attractive.There are many different ways in which Florida is attempting to optimize and reduce its consumption of fresh water. There are many associations that are contributing by facilitating water conservation and sustainable building design. The Florida Green Building Coalition is making designations by which homes can achieve a certification for green building. Some of these designations are Florida Green Home Standard, Florida Green Development Standard, Florida Green Local Government Standard for City and County Governments, and Florida Green Commercial Building Standard. These all reward a buildings design and efficient use of water. The Department of EnvironmentalProtection and the Environmental Protection Agency are searching for water conservation policy and for educational programs. The adoption and evolution of greywater reuse and water harvesting technologies will be an indispensable resource in the future as a method of achieving a sustainable consumption rate of our finite water resources.ReferencesAmerican Water Works Association. (2005). Retrieved October 13, 2005, from /community/links.cfm?FuseAction=Links&LinkCategoryID=5 /Advocacy/pressroom/statswp5.cfmU.S. Environmental Protection Agency. (2003). Retrieved October 13, 2005, from /OW/you/chap3.htmlFlorida Green Building Coalition. (2000). Retrieved October 15, 2005, from /Pushard, Doug (2004),Action Learning at Florida House: A Rainwater Harvesting Case Study, from . (2004). Retrieved October 11, 2005site: /floridahouse.shtmlPushard, Doug (2005),A Benchmark for Zero Water Use in Commercial Building: Melbourne's 60L, from . (2004). Retrieved October 11, 2005site: /zerowater.shtmlPlant Management in Florida Waters. (2004). Retrieved October 15, 2005, from /guide/drinking.htmlOasis Design. (2005). Retrieved October 3, 2005, from/greywater/indoorreuse.htm#indoorgwHolly Stallworth, Ph.D. (2000). Conservation Pricing of Water and Wastewater, Environmental Protection Agency Web. Retrieved October 12, 2005,site: /OW-OWM.html/cwfinance/cwsrf/consrvprice.pdfJanas, Marci. Nat ural Wastewater Treatment System “Vital Thread” In Oberlin College’s Adam Joseph Lewis Center for Environmental Studies. (2000). Oberlin Online news andfeature, Retrieved October 3, 2005, from/newserv/stories/living_machine_release.htmlFreewater UK Ltd. (2004). Retrieved October 20, 2005, from/commercial-greywater-II.htmSustainable Building Sourcebook. (2005). Retrieved October 3, 2005, from /sourcebook/Rainwater.html#contentsFlorida Department of Environmental Protection. (2005). Retrieved October 3, 2005, from /water/reuse/flprog.htmWater Reuse for Florida. (2003). Florida Department of Environmental Protection.Retrieved October 15, 2005, from/water/reuse/docs/valued_resource_Final%20Report.pdf。