Uniform Plumbing Code
The Uniform Plumbing Code (UPC) is a model building code that establishes minimum standards for the installation, alteration, repair, and maintenance of plumbing systems, including water supply, drainage, and venting, to safeguard public health, safety, and welfare.[1] Developed by the International Association of Plumbing and Mechanical Officials (IAPMO), the UPC emphasizes water efficiency, innovation in plumbing technologies, and comprehensive coverage of both residential and commercial applications within a single codebook.[2] The UPC traces its origins to 1926, when IAPMO was founded to address plumbing and mechanical standards amid rapid urbanization in the western United States.[3] It was first introduced as a local code in Los Angeles in 1928 and formally published as the UPC in 1945, marking the first edition adopted by IAPMO to promote uniform plumbing practices across jurisdictions.[3] Over the decades, the code has evolved through regular updates, with the 2021 edition representing the 29th iteration and incorporating advancements like a Peak Water Demand Calculator for sizing systems efficiently.[2] The UPC is developed through an ANSI-accredited consensus process, involving input from plumbing officials, industry experts, manufacturers, and other stakeholders who propose changes during annual conferences and technical committee meetings, requiring a two-thirds majority for approval.[1] This rigorous, transparent methodology ensures the code remains current with technological innovations, such as provisions for all-gender restrooms, non-sewered waste systems, and the Water Efficiency (WE)-Stand rating system for sustainable plumbing.[1] Editions are published every three years, with the latest being the 2024 UPC (as of November 2025; 2027 edition in development), which includes 17 core chapters on topics ranging from fixtures and appliances to storm drainage and medical gas systems, supplemented by appendices for specialized applications like tiny houses.[4] Widely adopted across the United States, the UPC serves as the basis for plumbing regulations in several states, including California, Idaho, Minnesota, Nevada, North Dakota, and Washington, as well as major cities such as Los Angeles, Houston, Seattle, and Portland.[5][6] Its flexibility allows for local amendments in home-rule jurisdictions like Texas, contributing to its use in numerous U.S. jurisdictions and protecting the health of millions through standardized, sanitary plumbing infrastructure.[1] As the only U.S. plumbing code designated as an American National Standard, the UPC plays a pivotal role in balancing safety, efficiency, and environmental sustainability in modern building practices.[2]Development and History
Origins and Founding
The Uniform Plumbing Code (UPC) was established in 1945 by the Western Plumbing Officials Association, which later evolved into the International Association of Plumbing and Mechanical Officials (IAPMO), as the first model code aimed at standardizing plumbing practices across jurisdictions. Initially limited to California, the UPC addressed the patchwork of inconsistent local regulations that had proliferated in the state, complicating construction and enforcement for plumbing officials. This founding effort stemmed from a committee formed in 1944 by IAPMO predecessors, which compiled and approved the code for publication, marking a pivotal step toward uniform standards for installation and maintenance.[7] The development of the UPC occurred amid the post-World War II housing boom, which spurred rapid urbanization and increased demand for safe, reliable plumbing systems to support expanding residential and commercial construction in California. Building on earlier regional efforts, such as the 1928 Los Angeles plumbing code derived from the 1920s Southern California standards, the UPC sought to mitigate public health risks by ensuring consistent sanitary practices. This context was influenced by historical lessons from 19th-century cholera outbreaks, like those in 1832 and 1849, which highlighted the dangers of inadequate water supply and waste management, prompting ongoing advocacy for robust sanitation codes.[8][9] Early adoption of the UPC was driven by collaboration among plumbing officials, manufacturers, and engineers, who recognized the need to prevent sanitation failures in growing urban areas. The code's initial focus emphasized basic requirements for sanitary drainage, venting, and potable water supply in both residential and commercial buildings, providing a foundational framework to protect public health without the variability of local ordinances. First adopted by Beverly Hills in 1946 and Los Angeles in 1948, it facilitated its integration into regional building practices.[7]Evolution and Major Milestones
Following its initial publication in 1945, the Uniform Plumbing Code (UPC) transitioned from a regional standard primarily used in California to a widely adopted model code across the United States, with regular updates reflecting advancements in plumbing technology and public health needs.[7] The code's development incorporated a triennial revision cycle, allowing for systematic incorporation of innovations and responses to emerging challenges, beginning in the mid-20th century as adoption expanded beyond the West Coast.[1] The 1953 edition marked a significant step in national expansion, as jurisdictions outside California, such as Las Vegas, began integrating the UPC into local regulations, broadening its influence on plumbing standards nationwide.[10] In the 1960s, the UPC embraced material innovations, notably incorporating plastic piping systems like ABS in the 1965 edition, which facilitated more durable and cost-effective installations while maintaining safety requirements.[7] The 1970s editions responded to global energy concerns, including the oil crises, by integrating early provisions for energy efficiency in plumbing systems, such as improved water heater standards to reduce consumption.[11] These updates laid the groundwork for ongoing emphasis on resource conservation amid rising awareness of environmental impacts. The 1980s brought heightened focus on contamination prevention, with the UPC integrating comprehensive backflow prevention standards, aligned with developments like the 1980 ASSE 1013 for reduced pressure zone devices, to safeguard potable water supplies.[12] Concurrently, in response to lead contamination crises, the code aligned with the federal Safe Drinking Water Act Amendments of 1986, which banned lead pipes, solder, and flux in public water systems effective June 19, 1986, prompting material restrictions and testing protocols in subsequent UPC revisions.[13] By the 1990s, the UPC addressed regional hazards through enhanced seismic provisions, requiring bracing and flexible connections for plumbing systems in earthquake-prone areas to minimize rupture risks during seismic events, as incorporated into model codes during that decade.[14] A pivotal organizational milestone occurred in 2003 when the UPC received American National Standards Institute (ANSI) accreditation as a consensus standard, affirming IAPMO's rigorous development process and boosting its credibility for broader adoption.[7] Entering the 2000s, the UPC saw international adaptations, with IAPMO establishing offices in India (2007) and China (2008) to support code influences in Asia, while elements informed plumbing regulations in Canada and Mexico through harmonized standards for cross-border projects.[7] The 2010s emphasized sustainability, with the 2010 Green Plumbing and Mechanical Code Supplement introducing provisions for water and energy efficiency that aligned with Leadership in Energy and Environmental Design (LEED) criteria, such as low-flow fixtures and recycled water systems to promote green building practices.[15] These developments, under IAPMO's ongoing governance, solidified the UPC's role as a forward-looking standard balancing safety, innovation, and global applicability.[16]Governing Organization and Process
Role of the International Association of Plumbing and Mechanical Officials (IAPMO)
The International Association of Plumbing and Mechanical Officials (IAPMO) was founded in 1926 as a non-profit organization dedicated to advancing public health and safety.[17] Its mission centers on protecting the public through the development of codes and standards, product and systems testing, evaluation and certification, personnel training and certification, and industry research, with a particular emphasis on uniform codes for plumbing, mechanical, and solar systems.[17] IAPMO operates globally, with members in 17 countries and all 50 U.S. states, totaling over 4,500 individuals and organizations.[17] IAPMO's organizational structure is governed by a board of directors that provides strategic oversight and guidance, drawing on expertise from industry leaders.[18] The association employs over 300 staff members across more than 20 affiliated companies within The IAPMO Group, supporting operations worldwide.[17] Key to its work are technical committees, such as the Plumbing Technical Committee, which serve as consensus bodies for code development; these include diverse stakeholders like enforcing authorities and chief building officials, manufacturers and installers from industry, and representatives from the public sector including consumers, labor organizations, research labs, and standards bodies.[19] Committee membership requires demonstrated qualifications, such as at least five years of relevant experience, and undergoes annual review to ensure balanced representation.[19] In relation to the Uniform Plumbing Code (UPC), IAPMO has served as the publisher and custodian since the code's first edition in 1945, building on its foundational expertise in plumbing systems established since 1926.[7] The organization conducts essential research to inform code updates, such as developing tools like the Peak Water Demand Calculator introduced in the 2021 edition to modernize plumbing system sizing.[1] Additionally, IAPMO oversees testing and certification through its Research and Testing (R&T) laboratory, which maintains over 4,000 product certification files and evaluates tens of thousands of plumbing products for compliance, ensuring they meet UPC requirements via listings like the Uniform Solar Energy Code.[17] This work underscores IAPMO's role in fostering innovation and reliability in plumbing infrastructure. IAPMO's operations are funded primarily through membership dues, sales of codes and standards, and fees from certification and testing services.[20] For instance, annual individual membership dues start at $35, while organizational dues begin at $500, providing access to code development participation and other benefits.[20] Certification programs, including exams and renewals requiring continuing education units, generate additional revenue while upholding professional standards.[21] The code development process, including for the UPC, adheres to an ANSI-accredited consensus procedure that promotes impartiality, open public input, and balanced stakeholder involvement to maintain credibility and broad adoption.[16]Code Development and Revision Process
The development and revision of the Uniform Plumbing Code (UPC) follow a consensus-driven process accredited by the American National Standards Institute (ANSI), ensuring openness, balance among stakeholder interests, and due process. This ANSI-accredited methodology, audited every five years, involves a triennial cycle spanning approximately three years to produce each new edition, allowing for systematic updates based on technological advancements, safety needs, and industry input. The process is governed by IAPMO's balanced technical committees, where no single interest group—such as manufacturers, installers, or enforcers—exceeds one-third of the membership to prevent dominance.[22][16] The cycle begins with Step 1: the Public and Committee Proposal Stage, where any interested party, including the public, industry professionals, and IAPMO members, can submit code change proposals through the online IAPMO Codes Portal. Proposals must include substantiation and are due roughly 18 to 42 months before the target edition's publication, depending on the cycle; for instance, in past cycles, deadlines have fallen in the fall of the year initiating the process. A technical committee then reviews these submissions during meetings, voting on them by simple majority, with final committee actions confirmed by a two-thirds letter ballot. The outcomes are compiled into a Report on Proposals (ROP), posted publicly for transparency. This stage emphasizes inclusivity, as submissions are open without membership requirements, fostering broad stakeholder participation from engineers, inspectors, unions, and manufacturers.[23][16][24] In Step 2: the Public Comment Stage, the ROP prompts further public comments, due about six months after the ROP release, followed by a second technical committee meeting to address them. Committee decisions again require simple majority votes, confirmed by two-thirds letter ballots, and results are published in a Report on Comments (ROC). Steps 3 and 4 involve the Association Technical Meeting, where IAPMO membership votes on floor amendments to the ROP and ROC by majority, subject to technical committee confirmation, and final appeals heard by the IAPMO Standards Council. Successful changes must achieve a two-thirds majority overall to ensure consensus. The process aligns with federal regulations, such as the Safe Drinking Water Act, by incorporating requirements for potable water systems and lead-free materials during revisions. Post-adoption, ambiguities are resolved through interpretative rulings submitted via the IAPMO Codes App, and errata are published promptly to correct errors, accessible online for users.[23][22][25]Scope and Structure
Purpose and Objectives
The Uniform Plumbing Code (UPC) establishes minimum standards to safeguard life, health, property, and public welfare by regulating and controlling the design, construction, installation, quality of materials, location, operation, and maintenance of all plumbing systems.[26] Its primary objectives center on ensuring a safe and sanitary water supply and effective waste removal, while preventing contamination, backflow, and structural failures in plumbing installations.[25] These goals address critical public health risks, such as waterborne diseases, by mandating protections like backflow prevention devices and cross-connection controls to maintain potable water integrity.[25] The UPC adopts a balanced approach by setting essential minimum standards for health and safety, while permitting flexibility for innovation and new technologies through provisions for alternate materials and methods, often evaluated via engineering analysis to demonstrate equivalency.[27][25] This framework allows jurisdictions to incorporate emerging solutions without compromising core protections, fostering advancements in plumbing design and efficiency.[28] As a model code developed by the International Association of Plumbing and Mechanical Officials (IAPMO), the UPC serves as a foundational document that jurisdictions adopt and enforce locally, aligning its objectives with broader aims to reduce waterborne diseases and conserve resources through enforceable regulations.[28] Once adopted, it becomes legally binding in those areas, promoting uniform practices across installations.[1] Beyond core protections, the UPC contributes to broader impacts by promoting sustainability through water conservation measures integrated since the 1970s, such as efficient fixture standards that reduce overall usage.[11] It also advances accessibility by incorporating requirements aligned with the Americans with Disabilities Act (ADA), ensuring equitable use of plumbing facilities, and supports economic efficiency by standardizing installations to minimize costs and waste in construction and maintenance.[1] These elements are implemented across the code's chapters to achieve holistic public welfare outcomes.[25]Chapter Organization and Appendices
The Uniform Plumbing Code (UPC) is structured to provide a logical progression from foundational administrative and definitional elements to detailed technical requirements for plumbing systems, ensuring comprehensive coverage of design, installation, and maintenance standards. The code consists of 17 chapters, with the first 11 covering foundational administrative and general plumbing requirements, and chapters 12-17 addressing specialized applications such as fuel gas piping, health care facilities, firestop protection, alternate water sources, nonpotable rainwater catchment systems, and referenced standards. This organization facilitates a systematic approach, allowing users to reference requirements in sequence from oversight and terminology to practical implementation across water supply, drainage, and venting systems.[4] Chapter 1 addresses Administration, outlining enforcement, permits, inspections, and violations. Chapter 2 provides Definitions for key terms used throughout the code. Chapter 3 covers General Regulations, including materials, workmanship, and protection of pipes. Chapter 4 details Plumbing Fixtures and Fixture Fittings, specifying installation and performance standards. Chapter 5 focuses on Water Heaters, including requirements for storage, circulation, and safety devices. Chapter 6 governs Water Supply and Distribution, addressing connections, quality, and sizing. Chapter 7 regulates Sanitary Drainage, covering systems for wastewater removal. Chapter 8 handles Indirect Wastes, for non-sanitary discharges. Chapter 9 specifies Vents, ensuring proper air circulation and pressure equalization. Chapter 10 addresses Traps and Interceptors, for sealing and separating wastes. Chapter 11 concludes the foundational chapters with Storm Drainage, for roof and surface water management. This sequential structure builds from broad governance to specialized applications, promoting clarity and enforceability in plumbing projects.[4][1] The code then includes 19 informative appendices labeled A through S, offering supplementary guidance, calculations, and optional provisions that support but do not form part of the mandatory requirements unless locally adopted. These appendices enable flexibility for jurisdictions to incorporate region-specific or advanced practices, such as sustainable designs or alternative systems. For instance, Appendix A provides Recommended Rules for Sizing the Water Supply System, including tables for fixture units and pipe capacities; Appendix E covers Manufactured/Mobile Home Parks and Recreational Vehicle Parks; and newer additions in the 2024 edition include Appendix O on Non-Sewered Sanitation Systems and Appendix R on Tiny Houses. Other notable appendices encompass topics like Sizing Storm Water Drainage Systems (D), Private Sewage Disposal Systems (H), and Sustainable Practices (L). Appendices often feature detailed tables and figures for engineering calculations, such as pipe sizing charts based on flow rates and materials, aiding in precise system design without mandating their use universally.[4][1] The overall document, including chapters, appendices, indexes, and referenced standards, spans approximately 500 pages in its printed edition, reflecting the code's depth while maintaining a focused structure for practical application by plumbers, engineers, and officials. Appendices are designed for optional adoption, allowing local authorities to select relevant sections to address unique environmental, climatic, or infrastructural needs without altering the core code. This modular approach underscores the UPC's adaptability as a model code.[4]Key Provisions
Water Supply, Distribution, and Efficiency
The Uniform Plumbing Code (UPC) establishes stringent requirements for potable water supply and distribution systems to ensure safety, reliability, and conservation. Chapter 6 of the UPC, titled "Water Supply and Distribution," mandates that all plumbing fixtures receive an adequate supply of potable water, defined as water free from contaminants that could pose health risks, with testing required to verify potability per applicable health standards.[29] These provisions emphasize durable materials, precise sizing to match demand, and integration of efficiency measures to minimize waste while preventing backflow and contamination. Approved materials for water supply pipes and fittings include copper, copper alloy, CPVC, PEX, and PVC, provided they meet standards such as ASTM D2846 for CPVC and NSF/ANSI 61 for potability.[25] The UPC prohibits the use of lead in water supply pipes, solder, and flux exceeding 0.25% lead content by weighted average, aligning with the federal Safe Drinking Water Act amendments that banned higher-lead materials since 1986 and tightened limits in 2011 to protect against leaching into potable water.[13] Dissimilar metals, such as copper and galvanized steel, are restricted unless separated by dielectric unions to avoid galvanic corrosion.[29] Sizing and design of water distribution systems rely on the fixture unit method, where each plumbing fixture is assigned a water supply fixture unit (WSFU) value based on its probable discharge rate and frequency of use, allowing calculation of peak demand for pipe sizing.[30] Pipes must deliver a minimum residual pressure of 15 psi (103 kPa) at the farthest fixture under peak demand, with a maximum static pressure of 80 psi; if supply pressure exceeds this, a pressure-regulating valve conforming to ASSE 1003 must be installed to prevent damage.[4] Backflow prevention is critical, requiring devices such as reduced-pressure principle (RPZ) backflow preventers for high-hazard connections like irrigation or boilers, installed at least 12 inches above grade with annual testing.[31] Efficiency provisions in the UPC promote water conservation through mandatory maximum flow rates for fixtures and fittings, such as 2.2 gallons per minute (gpm) at 60 psi for lavatory faucets and 1.28 gallons per flush for water closets, certified to ASME A112.18.1.[25] Hot water recirculation systems are encouraged to reduce waiting time and waste, with 2024 updates specifying manifold requirements and insulation to maintain temperatures without excessive energy use.[32] Graywater reuse for subsurface irrigation is permitted under Chapter 16, provided systems collect only from lavatories, showers, and laundry, with filtration, storage limited to 24 hours, and clear labeling to prevent potable cross-connections.[4] Special systems for alternate water sources include provisions for rainwater harvesting and reclaimed water, detailed in Chapters 15 and 16, requiring separate piping, UV treatment or filtration for nonpotable uses, and backflow protection to avoid contaminating the public supply.[4] For private wells, the 2024 UPC introduces Section 607.2, mandating pressurized storage tanks compliant with ASSE 1099 to ensure consistent supply and treatment, such as disinfection, before distribution. These measures support sustainable practices while upholding public health standards.Drainage, Waste, Vents, and Fixtures
The Uniform Plumbing Code (UPC) establishes stringent requirements for drainage systems to ensure efficient waste removal while preventing clogs, leaks, and structural damage in plumbing installations. Drainage piping must utilize approved materials such as acrylonitrile-butadiene-styrene (ABS) plastic pipe, polyvinyl chloride (PVC) pipe, and cast iron soil pipe, as specified in Table 701.2 of the 2024 edition.[4] Horizontal drainage piping is required to maintain a uniform slope not less than 1/4 inch per foot (20.8 mm/m) to facilitate gravity flow and avoid sagging or ponding.[4] Cleanouts are mandated at the base of each waste or soil stack, at intervals not exceeding 100 feet (30 480 mm) in horizontal piping, and at any change in direction greater than 45 degrees to allow for maintenance and inspection.[4] Venting systems in the UPC are designed to provide air circulation, protect trap seals from siphonage or backpressure, and maintain atmospheric pressure within the drainage network. Wet venting is permitted for specific configurations, such as bathroom groups where a single vertical vent serves multiple fixtures on the same horizontal branch, with minimum pipe sizes outlined in Section 908.1 to ensure adequate airflow.[4] Traps must incorporate a liquid seal depth of at least 2 inches (51 mm) and are protected against evaporation through methods like drum traps with deep seals or approved seal primers, as detailed in Section 1007.1.[4] Air admittance valves are allowed as an alternative venting method in engineered systems or for specific fixture alterations, provided they comply with standards such as ASSE 1051 and are installed in locations not subject to submergence.[4] Plumbing fixtures under the UPC must be installed to promote sanitation, safety, and accessibility, with connections secured using approved methods to prevent leaks or dislodgement. Bidets require backflow protection, typically via an air gap or atmospheric vacuum breaker, to safeguard against contamination of the potable water supply, per Section 410.2.[4] Accessibility provisions mandate that fixtures in public and common areas be positioned and configured to accommodate individuals with disabilities, including reinforced mounting for grab bars and clear floor space as per Section 403.1.[4] The 2024 edition introduces updated standards for tileable shower receptors, requiring them to be constructed as watertight assemblies using materials like PVC or chlorinated polyethylene (CPE) sheets, with a minimum threshold height and curb design to contain water effectively under Section 408.2.[4] Special waste handling in the UPC prioritizes indirect drainage to isolate potentially hazardous discharges from the sanitary system. Fixtures involved in food preparation, such as commercial sinks, must connect via indirect wastes with an air gap or air break to prevent backflow contamination, as required by Section 801.2.[4] Grease interceptors are essential for food service establishments and are sized based on anticipated flow rates; for gravity-type interceptors, capacity is determined using Table 1014.3.6, which correlates gallons per minute of flow—for example, approximately 1 gallon per meal served in typical operations—with retention volumes to ensure effective separation of fats, oils, and grease.[4] Hydromechanical grease interceptors follow similar sizing protocols in Table 1014.2.1, emphasizing flow-based calculations to maintain system efficiency without excessive maintenance demands.[4]Editions and Updates
Historical Editions
The Uniform Plumbing Code (UPC) was first published in 1945 by the International Association of Plumbing and Mechanical Officials (IAPMO), comprising approximately 100 pages and initially focused on standardizing plumbing practices in California.[7] This inaugural edition laid the foundation for safe and sanitary plumbing systems, drawing from regional needs and early 20th-century innovations like those introduced in Los Angeles in 1928.[33] It was distributed free to municipalities upon request and quickly gained traction, with the first adoptions occurring in Beverly Hills in 1946 and Los Angeles in 1948.[7] By the late 1950s, the code had incorporated broader requirements for materials, installation, and safety as plumbing systems became more complex with postwar construction booms.[7] Editions continued to evolve every three years, reflecting technological advances and regulatory refinements.[34] The 1997 edition introduced green amendments, emphasizing early water conservation measures in response to emerging environmental concerns, such as low-flow fixtures mandated by the 1992 Energy Policy Act.[35] By the 2000s, the code had grown substantially, with the 2003 edition achieving designation as an American National Standard by ANSI.[36] This expansion paralleled a gradual shift from purely prescriptive rules—detailing exact methods—to performance-based language that permitted equivalent solutions meeting safety and efficiency goals.[1] Key transitions included the full implementation of metric units alongside imperial measurements in the 2006 edition, facilitating international compatibility.[37] The 2018 edition advanced integration of smart fixtures, supporting connected technologies for monitoring and control in modern plumbing systems.[38] Up through the 2021 edition—the twenty-ninth overall—the UPC prioritized water efficiency, particularly post-drought initiatives, with innovations like the Peak Water Demand Calculator to optimize system sizing and reduce waste.[2][1] Historical editions are archived and available for purchase or online access through IAPMO, enabling research into past standards and their evolution.[39]2024 Edition and Key Changes
The 2024 edition of the Uniform Plumbing Code (UPC) was published by the International Association of Plumbing and Mechanical Officials (IAPMO) on May 1, 2023, following an ANSI-accredited consensus development process.[32][1] This edition, which builds on the 2021 version, comprises approximately 450 pages and incorporates updates to enhance plumbing system safety, efficiency, and adaptability to emerging technologies and building practices.[40][1] Key additions in the 2024 UPC include provisions for tileable shower receptors and kits, which allow for prefabricated shower bases that can be tiled directly to improve installation flexibility and waterproofing.[1] The code also introduces requirements for temperature-actuated flow reduction valves in fixtures to prevent scalding by automatically limiting flow when water exceeds safe temperatures.[1] Additionally, all-gender restroom provisions address inclusive design by specifying signage, fixture layouts, and privacy features for multi-user facilities.[1] New private well tank requirements mandate sizing, installation, and maintenance standards for pressure tanks in residential systems to ensure reliable water supply.[1] Significant updates from the 2021 edition expand hot water recirculation system guidelines, permitting demand-controlled pumps and crossover valves to reduce energy use and water waste in larger buildings.[1] Condensate drain allowances for appliances, such as high-efficiency HVAC units, now include options for indirect connections to avoid material corrosion.[1] Nonpotable water quality tests have been refined, requiring specific microbial and chemical analyses for graywater and rainwater systems to protect public health.[1] The 2024 UPC introduces five new appendices to address specialized applications:- Appendix O: Outlines minimum requirements for non-sewered sanitation systems, including composting toilets and graywater treatment for off-grid structures.[1]
- Appendix P: Specifies qualifications and certification standards for plumbing inspectors and technicians to ensure competent enforcement.[1]
- Appendix Q: Provides plumbing design criteria for indoor horticultural facilities, covering irrigation, drainage, and water reuse in controlled environments.[1]
- Appendix R: Details minimum plumbing systems for tiny houses, including compact fixture sizing and venting for mobile or small-scale dwellings.[1]
- Appendix S: Establishes provisions for onsite stormwater treatment systems, focusing on infiltration, filtration, and reuse to manage runoff.[1]