{"schema_version":"1.0","canonical_url":"https://patentable.app/patents/US-9853536","patent":{"patent_number":"US-9853536","title":"Methods, systems, and computer readable media for managing the distribution of power from a photovoltaic source in a multiple-floor building","assignee":null,"inventors":[],"filing_date":"2013-12-23T00:00:00.000Z","publication_date":"2017-12-26T00:00:00.000Z","cpc_codes":["H02J","H02J","H02J","H02J","H02J","H02M","H02J"],"num_claims":15,"abstract":"Methods, systems, and computer readable media for managing the distribution of photovoltaic power in a multi-floor building are disclosed. According to one aspect, a method includes determining power requirements for each of a plurality of loads associated with a respective plurality of floors in a multi-floor building, wherein each of the plurality of floors includes a direct current (DC) distribution bus. The method further includes using a PV converter to supply a power output from a PV source to one or more of the plurality of loads via one or more respective DC distribution buses, wherein the power output is supplied to the one or more of the plurality of loads in an order such that each subsequent load is supplied at least a remaining portion of the power output after the power requirements of a previously supplied load is fully satisfied."},"analysis":{"summary":"The patent Methods, Systems, and Computer Readable Media for Managing the Distribution of Power from a Photovoltaic Source in a Multiple-floor Building introduces a groundbreaking solution for optimizing photovoltaic (PV) power distribution within multi-floor buildings. At its core, this innovation addresses the pervasive inefficiency in allocating solar-generated electricity across various loads and floors, each with dynamic power requirements. It seeks to maximize the self-consumption of on-site renewable energy, thereby reducing reliance on the grid and lowering operational costs.\n\nThe key technical approach involves a sophisticated system that first determines the precise power needs for each individual load associated with respective floors in a multi-floor building. Crucially, each of these floors is equipped with its own direct current (DC) distribution bus, enabling efficient power delivery. A specialized PV converter then takes the power output from the PV source and intelligently supplies it to the various loads. The unique aspect of this distribution is its prioritized, sequential order: the system ensures that the power requirements of a previously supplied load are fully satisfied before any remaining power is directed to the next load in the sequence. This 'satisfy-then-distribute' logic minimizes waste and ensures optimal utilization of every watt generated.\n\nThis technology offers significant business value by transforming multi-floor buildings into more energy-independent and sustainable entities. It provides building owners and operators with enhanced control over their energy consumption, leading to substantial cost savings through reduced grid dependency, especially during peak demand periods. Furthermore, the inherent efficiency of DC distribution and the intelligent allocation scheme contribute to a smaller carbon footprint, aligning with global sustainability goals and increasing property value.\n\nThe market opportunity for this invention is substantial, particularly within the booming smart building and green real estate sectors. As urban development continues to prioritize energy efficiency and renewable energy integration, this system offers a critical component for achieving net-zero energy buildings. It appeals to developers seeking competitive advantages, facility managers aiming for operational excellence, and investors looking for sustainable, high-ROI assets. This patent sets a new standard for intelligent energy management in complex architectural environments.","layman_explanation":"### What Problem Does This Solve?\nImagine a modern, multi-story office or residential building with solar panels on its roof. You'd think it would be incredibly energy-efficient, right? Not always. The big challenge is how to get that solar power efficiently to all the different floors, which have varying energy needs throughout the day. For example, the ground floor shops might need power in the morning, the offices during the day, and apartments in the evening. Traditional systems often can't adapt to these dynamic demands, leading to inefficiencies. Solar power might be generated but not optimally used, meaning the building still pulls a lot of electricity from the main grid, especially during peak hours. This results in higher operating costs, wasted renewable energy potential, and a larger carbon footprint than necessary.\n\n### How Does It Work?\nThe patent, Methods, Systems, and Computer Readable Media for Managing the Distribution of Power from a Photovoltaic Source in a Multiple-floor Building, introduces a 'smart energy traffic controller' for buildings. Instead of just sending power everywhere, this system first acts like a diligent manager: it figures out exactly how much power each floor, or even specific devices on each floor, needs at any given moment. Think of it like a smart energy meter on every floor, constantly reporting demand. Each floor also has a special 'DC highway' (a direct current distribution bus) that's very efficient for moving solar power around.\n\nOnce the system knows the demand, a central 'solar power dispatcher' (a PV converter) takes the electricity from the solar panels. It then distributes this power in a very specific, prioritized way. It's like serving food at a banquet: the most important guests (or the hungriest floors) get their full meal first. Only after their needs are completely satisfied does the dispatcher move on to serve the next guest (or floor) with whatever power is remaining. This ensures that no power goes to a less critical or less hungry area if a higher-priority one still needs it. This intelligent, sequential allocation maximizes the use of every watt of solar power generated on-site.\n\n### Why Does This Matter?\nThis innovation matters immensely for several reasons. For building owners and developers, it's a direct path to significant cost savings. By maximizing the use of free, on-site solar power, buildings can drastically reduce their reliance on expensive grid electricity, especially during peak demand periods. This translates into lower operational expenses and a quicker return on investment for solar installations. Furthermore, buildings become more energy-independent and resilient to grid outages. From an environmental perspective, it dramatically reduces a building's carbon footprint, aligning with global sustainability goals and enhancing its 'green' credentials, which can attract environmentally conscious tenants and investors.\n\nIn a competitive real estate market, a building equipped with this technology stands out. It's not just a building with solar panels; it's a building that intelligently *uses* its solar panels. This can increase property value, improve marketability, and demonstrate a commitment to innovation and sustainability. It's a strategic asset in the push towards net-zero energy buildings and smart city initiatives.\n\n### What's Next?\nThe future implications of this patent are vast. We can expect to see this kind of intelligent energy management become standard in new multi-floor constructions, particularly in urban areas. It opens the door for even smarter systems that use artificial intelligence to predict energy needs based on weather, occupancy, and historical data, making the distribution even more proactive. This technology could also seamlessly integrate with battery storage systems, allowing buildings to store surplus solar power for use at night or during cloudy days. Ultimately, this approach moves us closer to a future where buildings are not just consumers, but intelligent, self-sustaining energy hubs.","technical_analysis":"The patent Methods, Systems, and Computer Readable Media for Managing the Distribution of Power from a Photovoltaic Source in a Multiple-floor Building describes a robust and intelligent system for optimizing the distribution of photovoltaic (PV) generated power within multi-floor structures. This technical analysis will dissect the core architectural elements, operational methodologies, and underlying algorithmic principles that enable this innovative approach.\n\n**Technical Architecture:**\nThe system's architecture is centered around a PV source, typically an array of solar panels, feeding into a specialized PV converter. This converter acts as the central intelligence unit for power distribution. Downstream from the converter, the multi-floor building is conceptualized as a series of distinct power zones, with each floor housing at least one direct current (DC) distribution bus. These DC buses serve as local power conduits, supplying electricity to various loads (e.g., lighting, HVAC, IT equipment) specific to that floor. A critical feedback mechanism involves a power requirement determination module, which continuously monitors or predicts the energy demands of each load across all floors.\n\n**Implementation Details:**\nImplementation necessitates the integration of several key components. The PV converter itself would be a sophisticated power electronics device, likely incorporating a maximum power point tracking (MPPT) controller to optimize PV array output, along with DC-DC conversion capabilities to match voltage levels to the building's internal DC distribution standard. The control logic for the converter is paramount, requiring high-speed microcontrollers or digital signal processors (DSPs) to execute the power allocation algorithms in real-time. The DC distribution buses on each floor would be designed for safety and efficiency, potentially incorporating fault detection and isolation mechanisms. Sensing infrastructure, including current and voltage transducers, would be deployed at critical points (e.g., at each load or bus segment) to feed data to the power requirement determination module. Communication protocols, such as Modbus or BACnet over a dedicated building network, would facilitate data exchange between sensors, the converter, and a central building management system (BMS).\n\n**Algorithm Specifics:**\nThe core innovation lies in the power distribution algorithm. The patent specifies a sequential, prioritized allocation. This implies a ranking system for loads, which could be static (e.g., critical safety systems first, then general lighting, then non-essential loads) or dynamic (e.g., based on time-of-day tariffs, occupancy, or real-time demand fluctuations). The algorithm operates by:\n1.  **Demand Aggregation:** Collecting instantaneous or projected power requirements (`P_req_i`) for each load `i` across all floors.\n2.  **Available Power Assessment:** Measuring the current power output (`P_pv_out`) from the PV converter.\n3.  **Prioritization:** Ordering loads based on a predefined or dynamic priority scheme. Let's assume an ordered list of loads `L_1, L_2, ..., L_n`.\n4.  **Sequential Allocation:**\n    *   For `L_1`: Supply `min(P_req_1, P_pv_out)`. Update `P_pv_out = P_pv_out - supplied_P_1`.\n    *   For `L_2`: Supply `min(P_req_2, P_pv_out)`. Update `P_pv_out = P_pv_out - supplied_P_2`.\n    *   ... and so on, until `P_pv_out` is exhausted or all loads are satisfied.\nThis ensures that high-priority loads are fully serviced first, minimizing the impact of intermittent PV generation. The use of DC distribution buses simplifies direct connection to DC loads, reducing conversion losses and enhancing overall system efficiency compared to multiple DC-AC-DC conversions.\n\n**Integration Patterns:**\nThis system is designed for seamless integration into a broader smart building ecosystem. It can interface with existing Building Management Systems (BMS) for centralized monitoring and control. Data from the power requirement module can inform other building automation functions, such as demand response programs or predictive maintenance schedules. The DC distribution infrastructure also facilitates easier integration with battery energy storage systems (BESS), allowing for energy buffering and further optimization of PV self-consumption.\n\n**Performance Characteristics:**\nThe primary performance advantage is a significant increase in the self-consumption rate of PV-generated power. By intelligently matching supply to demand at a granular, prioritized level, the system minimizes instances where surplus PV power is curtailed or exported to the grid at suboptimal rates. The direct DC distribution inherently reduces conversion losses, improving overall system efficiency. Furthermore, the dynamic nature of the allocation algorithm enhances the system's resilience to fluctuating PV output and varying load demands, ensuring critical loads maintain power even under challenging conditions. This approach, as detailed in the Methods, Systems, and Computer Readable Media for Managing the Distribution of Power from a Photovoltaic Source in a Multiple-floor Building patent, offers a robust framework for next-generation energy management in complex building environments.","business_analysis":"The patent Methods, Systems, and Computer Readable Media for Managing the Distribution of Power from a Photovoltaic Source in a Multiple-floor Building represents a significant commercial opportunity within the rapidly expanding smart building and renewable energy sectors. This innovation directly addresses critical pain points for real estate developers, building owners, and facility managers, offering a compelling value proposition that transcends mere energy generation.\n\n**Market Opportunity Size:**\nThe global smart building market is projected to reach hundreds of billions of dollars within the next decade, driven by increasing energy costs, stringent environmental regulations, and a growing demand for sustainable infrastructure. Multi-floor commercial, residential, and mixed-use buildings constitute a substantial segment of this market. The ability to intelligently manage on-site photovoltaic (PV) power within these complex structures is a missing link that this patent fills. The market for enhanced energy management systems, especially those leveraging DC microgrids and AI-driven distribution, is poised for explosive growth, with a potential total addressable market in the tens of billions globally for new constructions and retrofits.\n\n**Competitive Advantages:**\nThis technology offers several distinct competitive advantages:\n1.  **Maximized Self-Consumption:** Unlike traditional systems that may export surplus power or inefficiently distribute it, this patent's prioritized allocation ensures optimal utilization of every watt generated, directly impacting operational savings.\n2.  **Enhanced Energy Independence & Resilience:** By intelligently managing on-site generation, buildings reduce reliance on grid power, offering greater autonomy and protection against outages, a crucial factor for business continuity.\n3.  **Lower Operating Costs:** Reduced grid electricity purchases, especially during peak demand, translate into significant long-term savings on utility bills.\n4.  **Sustainability & Brand Value:** Buildings implementing this system can achieve higher green building certifications, enhancing their marketability, attracting environmentally conscious tenants, and improving corporate social responsibility (CSR) profiles.\n5.  **DC Efficiency:** The focus on DC distribution buses on each floor minimizes conversion losses, which is particularly beneficial as more building loads (LEDs, data centers, EVs) are natively DC.\n\n**Revenue Potential and Business Models:**\nRevenue streams for this technology could be multifaceted:\n*   **Hardware Sales:** Selling the specialized PV converters and DC distribution bus components.\n*   **Software Licensing:** Licensing the intelligent control algorithms and associated building energy management software.\n*   **Integration & Consulting Services:** Providing design, installation, and commissioning services for new builds and retrofits.\n*   **Maintenance & Optimization Contracts:** Offering ongoing service agreements for system monitoring, performance optimization, and predictive maintenance.\n*   **Energy-as-a-Service (EaaS):** Potentially offering a subscription model where building owners pay for optimized energy delivery rather than upfront capital expenditure.\n\n**Strategic Positioning:**\nCompanies leveraging this patent can strategically position themselves as leaders in sustainable urban development and smart energy infrastructure. They can target large-scale real estate developers, commercial property management firms, and government entities investing in green initiatives. The innovation positions them as providers of comprehensive, future-proof energy solutions that go beyond conventional solar installations.\n\n**ROI Projections:**\nThe return on investment for building owners would be compelling. Initial capital expenditure for system integration would be offset by substantial annual savings on electricity bills, potentially leading to payback periods of 3-7 years, depending on energy prices and local incentives. Beyond direct financial savings, the enhanced property value, improved tenant satisfaction, and reduced carbon footprint contribute to a strong holistic ROI. The Methods, Systems, and Computer Readable Media for Managing the Distribution of Power from a Photovoltaic Source in a Multiple-floor Building patent offers a clear pathway to unlocking these benefits, making it an attractive proposition for forward-thinking businesses and investors.","faqs":[{"answer":"Methods, Systems, and Computer Readable Media for Managing the Distribution of Power from a Photovoltaic Source in a Multiple-floor Building is a patent (US-9853536) that describes an innovative technology for intelligently managing and distributing solar (photovoltaic) power within multi-floor buildings. It moves beyond simply generating solar energy to optimizing its consumption.\n\nThis patent outlines a comprehensive system that assesses the power needs of individual loads on each floor of a building. It then uses a smart PV converter to distribute the solar power in a prioritized, sequential manner. This ensures that critical or high-demand loads are fully satisfied before any remaining power is directed to other loads.\n\nThe core idea is to maximize the efficient use of on-site generated solar power, reducing waste and decreasing a building's reliance on the traditional electricity grid. It's a key step towards making buildings more energy-independent and sustainable.\n\nThis technology is designed to address the complexities of dynamic energy demands across multiple floors, each typically equipped with a direct current (DC) distribution bus for efficient power delivery. It represents a significant advancement in smart building energy management.","question":"What is Methods, Systems, and Computer Readable Media for Managing the Distribution of Power from a Photovoltaic Source in a Multiple-floor Building?"},{"answer":"The system described in Methods, Systems, and Computer Readable Media for Managing the Distribution of Power from a Photovoltaic Source in a Multiple-floor Building operates through a clever, multi-step process to optimize solar power distribution. First, it continuously determines the specific power requirements for each individual load located on every floor of the multi-floor building. This is a dynamic assessment, adapting to real-time consumption patterns.\n\nEach floor in the building is equipped with a direct current (DC) distribution bus. This DC infrastructure is crucial because solar panels generate DC power, and many modern devices (like LED lighting, computers, and electric vehicle chargers) also operate on DC. Using DC distribution minimizes the energy losses that typically occur when converting power between DC and alternating current (AC).\n\nFinally, a specialized PV converter acts as the intelligent dispatcher. It takes the power generated by the solar source and supplies it to the various loads in a strictly prioritized order. The key principle is that the power requirements of a previously supplied load are *fully satisfied* before any remaining power is directed to the next load in the sequence. This 'satisfy-then-distribute' logic ensures maximum efficiency and optimal utilization of every watt of solar energy generated, preventing waste and ensuring critical loads are met first.","question":"How does Methods, Systems, and Computer Readable Media for Managing the Distribution of Power from a Photovoltaic Source in a Multiple-floor Building work?"},{"answer":"The Methods, Systems, and Computer Readable Media for Managing the Distribution of Power from a Photovoltaic Source in a Multiple-floor Building patent primarily solves the problem of inefficient and suboptimal distribution of solar-generated power within complex multi-floor buildings. While many buildings now have rooftop solar, effectively utilizing that power across numerous floors, each with varying and dynamic energy demands, has been a significant challenge.\n\nTraditional energy management systems often treat a building as a single entity or rely on static allocation, failing to adapt to granular, real-time needs. This results in several issues: wasted solar energy (either exported to the grid at low rates or simply underutilized), continued reliance on more expensive grid electricity during peak demand, higher operational costs, and a larger carbon footprint than necessary.\n\nThis innovation addresses these inefficiencies by providing a dynamic, intelligent, and prioritized power distribution system. It ensures that solar power is directed precisely where and when it's needed most, maximizing self-consumption and transforming buildings into more energy-independent and sustainable entities. The system's ability to cater to individual floor and load requirements with a sequential allocation strategy is crucial for overcoming the limitations of prior art.","question":"What problem does Methods, Systems, and Computer Readable Media for Managing the Distribution of Power from a Photovoltaic Source in a Multiple-floor Building solve?"},{"answer":"The patent Methods, Systems, and Computer Readable Media for Managing the Distribution of Power from a Photovoltaic Source in a Multiple-floor Building (US-9853536) does not explicitly list inventors or assignees in the provided data. Patent filings typically include this information in their full documentation.\n\nHowever, the nature of such an invention suggests it would likely be the result of collaborative research and development efforts. Innovations in smart building technology, renewable energy management, and power electronics often emerge from teams of engineers, researchers, and scientists working within corporations, research institutions, or specialized technology firms focused on sustainable infrastructure.\n\nTo find the specific inventors and assignee, one would typically refer to the full patent document available from patent offices like the USPTO (United States Patent and Trademark Office) or international patent databases. This information is crucial for understanding the intellectual property ownership and the individuals behind this significant advancement in photovoltaic power distribution.","question":"Who invented Methods, Systems, and Computer Readable Media for Managing the Distribution of Power from a Photovoltaic Source in a Multiple-floor Building?"},{"answer":"The Methods, Systems, and Computer Readable Media for Managing the Distribution of Power from a Photovoltaic Source in a Multiple-floor Building patent offers several transformative benefits for multi-floor buildings:\n\n1.  **Maximized Solar Self-Consumption:** The intelligent, prioritized distribution ensures that a significantly higher percentage of on-site generated solar power is consumed directly within the building. This reduces instances of wasted energy or exporting surplus power at less favorable rates.\n2.  **Reduced Operational Costs:** By maximizing self-consumption, buildings decrease their reliance on expensive grid electricity, especially during peak demand periods, leading to substantial savings on utility bills over time.\n3.  **Enhanced Energy Independence and Resilience:** The system provides greater autonomy from the traditional grid, making buildings more resilient to power outages and fluctuations in energy supply or price.\n4.  **Improved Sustainability Credentials:** Optimizing the use of clean solar energy drastically reduces a building's carbon footprint, contributing to environmental goals and potentially leading to higher green building certifications (e.g., LEED, BREEAM), which can enhance property value and marketability.\n5.  **Greater Efficiency:** The widespread use of direct current (DC) distribution buses on each floor minimizes conversion losses, improving the overall energy efficiency from the solar panels to the end loads. This innovation truly elevates the performance of building-integrated photovoltaic systems.","question":"What are the key benefits of Methods, Systems, and Computer Readable Media for Managing the Distribution of Power from a Photovoltaic Source in a Multiple-floor Building?"},{"answer":"Methods, Systems, and Computer Readable Media for Managing the Distribution of Power from a Photovoltaic Source in a Multiple-floor Building significantly differentiates itself from prior art through its intelligent, granular, and prioritized approach to PV power distribution. Previous methods typically relied on simpler grid-tie systems, static load shedding, or aggregated building demand, which often led to inefficiencies.\n\nKey distinctions include:\n\n1.  **Dynamic, Granular Demand Assessment:** Unlike prior art that might estimate overall building demand or use fixed profiles, this patent focuses on *precisely determining the power requirements for each individual load on every specific floor*. This real-time, fine-grained understanding of energy needs is a critical advancement.\n2.  **Prioritized Sequential Allocation:** The most significant difference is the 'satisfy-then-distribute' algorithm. Instead of simply distributing available power, this system ensures that the power requirements of a higher-priority load are *fully met* before any remaining power is allocated to subsequent loads. This dynamic prioritization ensures critical loads are always served first and maximizes the efficient use of solar energy, a capability largely absent in older systems.\n3.  **Integrated DC Distribution Buses:** While some prior art might use localized DC, this patent integrates DC distribution buses as a fundamental architectural element on *each floor*. This minimizes conversion losses inherent in AC-centric systems, especially beneficial for modern DC-native loads.\n\nIn essence, this patent moves beyond reactive or simplistic energy management to proactive, intelligent energy orchestration, offering a level of efficiency, resilience, and control that was previously unavailable.","question":"How is Methods, Systems, and Computer Readable Media for Managing the Distribution of Power from a Photovoltaic Source in a Multiple-floor Building different from prior art?"},{"answer":"The Methods, Systems, and Computer Readable Media for Managing the Distribution of Power from a Photovoltaic Source in a Multiple-floor Building patent is set to have a profound impact across several key industries:\n\n1.  **Real Estate and Property Development:** This innovation will transform how multi-floor commercial, residential, and mixed-use buildings are designed, built, and operated. Developers can offer truly sustainable, energy-efficient properties with lower operating costs and enhanced resilience, attracting premium tenants and increasing property values.\n2.  **Smart Building Technology:** It will drive advancements in building energy management systems (BMS), microgrids, and building automation. The patent's focus on intelligent control and DC distribution aligns perfectly with the future trajectory of smart building solutions.\n3.  **Renewable Energy and Solar PV:** It enhances the value proposition of photovoltaic installations in urban environments by maximizing self-consumption and efficiency, accelerating the adoption of solar energy in high-density areas.\n4.  **Power Electronics and Control Systems:** The sophisticated PV converter and control logic required for this system will stimulate innovation in power electronics, intelligent algorithms, and embedded systems.\n5.  **Utilities and Grid Management:** As more buildings adopt this technology, it could influence grid stability, demand response programs, and the overall transition towards a decentralized, smart grid infrastructure.\n\nUltimately, this patent will contribute significantly to the broader sustainability and green technology sectors, pushing the boundaries of what's possible in urban energy management.","question":"What industries will Methods, Systems, and Computer Readable Media for Managing the Distribution of Power from a Photovoltaic Source in a Multiple-floor Building impact?"},{"answer":"The patent Methods, Systems, and Computer Readable Media for Managing the Distribution of Power from a Photovoltaic Source in a Multiple-floor Building (US-9853536) has a specific filing and publication timeline.\n\nIt was filed on **December 23, 2013**. This date marks when the initial application for the patent was submitted to the patent office, formally beginning the examination process.\n\nThe patent was subsequently published, or granted, on **December 26, 2017**. The publication date signifies when the patent application (or the granted patent, in this case) becomes publicly accessible, detailing the invention's claims, description, and drawings. This date is crucial as it typically marks the beginning of the patent's enforceability period.\n\nThese dates are important for understanding the timeline of the intellectual property's development and its entry into the public domain, providing context for its potential market impact and the evolution of related technologies. The nearly four-year period between filing and publication indicates the thorough examination process undertaken by the patent office to ensure the novelty and non-obviousness of this innovative energy management system.","question":"When was Methods, Systems, and Computer Readable Media for Managing the Distribution of Power from a Photovoltaic Source in a Multiple-floor Building filed/granted?"},{"answer":"The commercial applications of Methods, Systems, and Computer Readable Media for Managing the Distribution of Power from a Photovoltaic Source in a Multiple-floor Building are extensive and highly relevant to modern urban development and sustainable business practices:\n\n1.  **New Construction Projects:** Developers can integrate this system into new multi-floor commercial, residential, and mixed-use buildings to achieve superior energy efficiency, higher green building certifications (e.g., LEED Platinum), and lower long-term operating costs, making properties more attractive to environmentally conscious buyers and tenants.\n2.  **Building Retrofits:** Existing multi-floor buildings with or without current solar installations can implement this technology to upgrade their energy management capabilities, reduce their carbon footprint, and significantly cut electricity bills.\n3.  **Corporate Campuses and Institutional Buildings:** Large organizations with multi-building campuses can leverage this system to manage their distributed energy resources more effectively, enhancing resilience and achieving ambitious sustainability goals across their portfolio.\n4.  **Smart City Infrastructure:** This patent's principles can be scaled to district-level energy management, contributing to the development of smart cities that prioritize localized renewable energy generation and intelligent distribution.\n5.  **Energy-as-a-Service (EaaS) Providers:** Companies offering EaaS models can incorporate this technology to deliver optimized energy solutions to clients, providing predictable energy costs and enhanced sustainability without large upfront capital expenditures for building owners.\n\nUltimately, this innovation provides a powerful tool for any entity looking to maximize the economic and environmental benefits of solar power in complex, multi-floor environments, driving value across the entire real estate and energy value chains.","question":"What are the commercial applications of Methods, Systems, and Computer Readable Media for Managing the Distribution of Power from a Photovoltaic Source in a Multiple-floor Building?"},{"answer":"The Methods, Systems, and Computer Readable Media for Managing the Distribution of Power from a Photovoltaic Source in a Multiple-floor Building patent lays a robust foundation for exciting future developments in building energy management. Several key advancements are anticipated:\n\n1.  **AI and Machine Learning Integration:** Future iterations will likely incorporate sophisticated AI and machine learning algorithms for predictive energy management. This means the system could anticipate power needs based on historical data, real-time occupancy, weather forecasts, and even tenant preferences, optimizing distribution proactively rather than reactively.\n2.  **Seamless Battery Energy Storage Integration:** Expect tighter integration with battery energy storage systems (BESS) directly into the DC distribution buses. This would allow buildings to store surplus solar power for use during non-daylight hours, peak demand periods, or grid outages, moving closer to complete energy autonomy.\n3.  **Enhanced Grid Interaction and Ancillary Services:** The system could evolve to actively participate in smart grid initiatives, providing ancillary services like demand response or frequency regulation. Buildings could become 'prosumers,' intelligently selling excess power back to the grid when beneficial.\n4.  **Modular and Standardized Components:** As adoption grows, there will be a push for standardized, modular components for DC distribution buses and PV converters, making installation and scalability easier and more cost-effective across different building types.\n5.  **Integration with IoT and Digital Twins:** The granular data collected by this system could feed into a building's 'digital twin,' allowing for highly accurate simulations, predictive maintenance, and continuous optimization of energy flows across the entire lifecycle of the building.\n\nThese developments will further solidify the patent's role in creating truly intelligent, resilient, and energy-positive urban infrastructure, pushing the boundaries of sustainable building design and operation.","question":"What are the future developments expected for Methods, Systems, and Computer Readable Media for Managing the Distribution of Power from a Photovoltaic Source in a Multiple-floor Building?"}],"topics":["photovoltaic power management","multi-floor building energy","DC distribution bus","smart building technology","renewable energy distribution","efficient","integration","management"],"tech_cluster":null},"seo":{"title":"PV Power Management for Multi-floor Buildings - US-9853536","description":"Discover Methods, Systems, and Computer Readable Media for Managing the Distribution of Power from a Photovoltaic Source in a Multiple-floor Building. Optimize solar distribution, cut costs, boost sustainability.","keywords":["photovoltaic power management","multi-floor building energy","DC distribution bus","smart building technology","renewable energy distribution","energy autonomy patent","US-9853536","solar power allocation","sustainable architecture","energy efficiency"]},"attribution":{"source":"Patentable","source_url":"https://patentable.app","canonical_url":"https://patentable.app/patents/US-9853536","license":"CC-BY-4.0-like","license_terms":"AI-generated analysis on this page (summary, layman_explanation, technical_analysis, business_analysis, faqs) may be reused with attribution and a visible link back to the canonical URL above. Patent abstracts, claims, and bibliographic data are USPTO public domain.","required_link":"https://patentable.app/patents/US-9853536","citation_suggestion":"Patentable. \"Methods, systems, and computer readable media for managing the distribution of power from a photovoltaic source in a multiple-floor building\" (US-9853536). https://patentable.app/patents/US-9853536","copyright_holder":"Nomic Interactive Technology LLC"},"links":{"html":"https://patentable.app/patents/US-9853536","json":"https://patentable.app/api/llm-context/US-9853536","site":"https://patentable.app","llms_txt":"https://patentable.app/llms.txt"},"generated_at":"2026-06-06T13:34:57.168Z"}