{"schema_version":"1.0","canonical_url":"https://patentable.app/patents/US-9852861","patent":{"patent_number":"US-9852861","title":"Addressable electric safety contact monitoring system","assignee":null,"inventors":[],"filing_date":"2015-09-12T00:00:00.000Z","publication_date":"2017-12-26T00:00:00.000Z","cpc_codes":["G06F","G06F"],"num_claims":20,"abstract":"An addressable electrical safety contact monitoring system is described. The system includes an input terminal connected to an external signal relating to a safety fault, a first signal wire connect the input terminal, a switch having a default position and an active position, a first electric connection between the input terminal and a switch, a microprocessor, a second electric connection between the microprocessor and the switch, an address-section mechanism, an output terminal and a third electric connection between the microprocessor and the output terminal. When the external signal is activated, the switch changes from the default position to the active position, the microprocessor is activated and the microprocessor activates a signal on the third electric connection corresponding to the address-selection mechanism."},"analysis":{"summary":"The Addressable Electric Safety Contact Monitoring System patent (US-9852861) introduces a sophisticated solution for precisely detecting and identifying electrical safety faults within complex systems. At its core, this innovation provides an intelligent mechanism to move beyond generic fault alerts, offering pinpoint accuracy in diagnosing issues.\n\nThe primary problem this technology solves is the inefficiency and risk associated with traditional electrical safety monitoring. Current systems often indicate a general fault, requiring extensive manual troubleshooting to locate the specific source, leading to prolonged downtime, increased operational costs, and potential safety hazards for personnel. This invention aims to mitigate these challenges by offering real-time, location-specific fault data.\n\nThe key technical approach involves an input terminal that receives an external safety fault signal, which then triggers a switch to change from its default to an active position. This state change activates a microprocessor. Crucially, the system incorporates an address-selection mechanism, enabling the microprocessor to generate an output signal that directly corresponds to the unique address of the specific safety contact or component where the fault originated. This addressable output allows for immediate and accurate fault localization.\n\nFrom a business value perspective, this innovation offers significant advantages across various sectors, including manufacturing, energy distribution, and smart infrastructure. It promises drastically reduced diagnostic and downtime periods, leading to substantial cost savings. Enhanced precision in fault detection translates to improved operational efficiency, better resource allocation for maintenance, and, most importantly, a safer working environment. The ability to integrate this addressable data into broader industrial control and IoT systems further amplifies its value, supporting predictive maintenance and data-driven decision-making.\n\nThe market opportunity for such an advanced safety monitoring system is substantial, driven by the increasing automation of industries and the imperative for robust safety compliance. As electrical systems become more intricate, the demand for intelligent, self-diagnosing safety solutions will only grow, positioning this patent as a critical enabler for future-proof industrial and commercial operations.","layman_explanation":"For business professionals, understanding the core value of new technologies without getting bogged down in technical minutiae is key. The **Addressable Electric Safety Contact Monitoring System** patent (US-9852861) is one such innovation with profound implications for operational efficiency and safety across various industries.\n\n**1. What Problem Does This Solve?**\nThink of a large factory or a sprawling corporate campus with countless electrical connections, circuits, and safety switches. In traditional setups, if an electrical safety fault occurs – say, a critical contact fails – the system might trigger a general alarm, or a section of the facility might simply shut down. The problem isn't just that something went wrong, but *where* it went wrong. Pinpointing the exact faulty component often requires maintenance teams to manually inspect numerous points, sometimes for hours or even days. This diagnostic delay is incredibly costly: it leads to significant operational downtime, lost productivity, increased labor expenses, and, most importantly, prolongs the potential exposure of personnel to hazardous conditions. Existing solutions are often reactive and lack the granularity needed for rapid, precise intervention.\n\n**2. How Does It Work?**\nThis patent introduces a 'smart' approach to safety monitoring. Imagine that every critical electrical safety contact within your system has its own unique digital identification tag, or 'address.' When an external signal indicates a safety fault (e.g., a sensor detects an anomaly), a special switch connected to that specific contact reacts. This reaction then communicates with a central 'brain' – a microprocessor. Instead of just registering a generic 'fault,' this microprocessor uses its internal 'address book' to identify which specific contact, by its unique address, has failed. It then sends out a signal that says, 'Problem detected at Address A-17,' rather than just 'Problem in Sector B.' It's like having a GPS for every single safety component in your electrical infrastructure.\n\n**3. Why Does This Matter?**\nThis precision matters immensely for business. First, it translates directly into **drastically reduced downtime**. If you know exactly where the fault is, your team can go straight to it and fix it, often in minutes rather than hours or days. This protects your production schedules and revenue streams. Second, it significantly **enhances safety**. By quickly isolating and addressing faults, you reduce risks to employees and prevent more serious incidents, thereby lowering liability and improving your safety record. Third, it offers **operational efficiency gains** beyond just repairs. The precise data generated by this system can feed into predictive maintenance programs, allowing you to anticipate and prevent failures before they occur. It also streamlines compliance reporting and resource allocation. For example, a facility using this technology could see a 50% reduction in average fault resolution time, leading to millions in annual savings for large operations. This innovation positions a company as forward-thinking and committed to leveraging technology for both safety and profitability.\n\n**4. What's Next?**\nThe Addressable Electric Safety Contact Monitoring System is poised to become a foundational technology for future-proof industrial and commercial infrastructure. We can expect to see its integration into advanced smart factories (Industry 4.0), intelligent building management systems, and even smart grid applications. As electrical systems become more complex and interconnected, the demand for this kind of precise, addressable monitoring will only grow. For investors, this represents an opportunity in a critical and expanding market, offering solutions that deliver tangible ROI through improved safety, efficiency, and operational resilience. Early adoption and strategic integration of this technology will provide a significant competitive advantage.","technical_analysis":"The Addressable Electric Safety Contact Monitoring System, protected by patent US-9852861, presents a meticulously designed architecture for precise electrical safety fault detection. This innovation moves beyond simple circuit break detection, introducing an intelligent, address-centric mechanism for fault localization, critical for modern, complex electrical infrastructures.\n\n**Technical Architecture:**\nAt the heart of this system is a carefully orchestrated interaction between an input interface, a sensing element, a processing unit, and an addressing mechanism. The system begins with an **input terminal** designed to receive an external signal indicative of a safety fault. This signal could originate from various sensors monitoring parameters like overcurrent, voltage anomalies, ground faults, or contact failures. This input terminal is connected via a first signal wire to a **switch**, which is fundamental to the fault detection process.\n\nThe **switch** itself is characterized by two states: a default position and an active position. In the absence of a fault, the switch resides in its default state. Upon activation of the external safety fault signal, the switch transitions to its active position. This state change is not merely a binary indication but a critical event that triggers the subsequent intelligent processing. A **microprocessor** serves as the central control and processing unit. It is connected to the switch via a second electric connection, allowing it to continuously monitor the switch's state. This continuous monitoring enables the microprocessor to detect the precise moment the switch changes from its default to its active position, signaling a fault event.\n\nThe system's distinct advantage lies in its **address-selection mechanism**. This component, though not explicitly detailed in its internal workings in the abstract, conceptually functions to associate each monitored safety contact or zone with a unique digital address. When the microprocessor detects a switch activation, it consults or utilizes this address-selection mechanism to determine the specific source of the fault. Finally, an **output terminal**, connected to the microprocessor via a third electric connection, is responsible for transmitting the fault information. Upon processing the switch activation and identifying the fault's address, the microprocessor activates a signal on this output terminal, where the signal directly corresponds to the unique address identified by the address-selection mechanism.\n\n**Implementation Details and Algorithm Specifics:**\nThe core algorithm can be summarized as: `IF (External_Signal_Activated) THEN (Switch_State_Change) -> (Microprocessor_Detects_Change) -> (Microprocessor_Consults_Address_Mechanism) -> (Microprocessor_Activates_Address_Specific_Output)`. The microprocessor would likely employ a polling mechanism or an interrupt-driven approach to monitor the switch's state. For the address-selection mechanism, this could involve a lookup table, a hardwired addressing scheme, or programmable logic within the microprocessor itself, where each input channel (corresponding to a safety contact) is mapped to a unique digital output sequence or code. The output signal could be a digital data stream, a modulated signal, or a unique voltage/current pulse, depending on the communication protocol with external systems.\n\n**Integration Patterns:**\nThis system is designed for robust integration into existing and future industrial control architectures. The output terminal's address-specific signal can be fed into various systems such as SCADA (Supervisory Control and Data Acquisition), DCS (Distributed Control Systems), PLCs (Programmable Logic Controllers), or IoT gateways. This allows for centralized monitoring, data logging, and the initiation of automated safety protocols. The addressability makes it highly suitable for integration with digital twin applications, providing real-time, precise status updates of physical assets in a virtual environment.\n\n**Performance Characteristics:**\nKey performance indicators for this technology would include fault detection latency (time from fault occurrence to address-specific signal output), accuracy of address identification, and robustness against electrical noise or interference. The microprocessor's speed and the efficiency of the address-selection logic would directly influence latency. The digital nature of the address output enhances accuracy and reduces ambiguity. Its design implies a low power consumption profile for the monitoring component, making it suitable for continuous operation in critical safety applications.\n\n**Code-Level Implications:**\nFrom a software perspective, the microprocessor would run firmware implementing the described logic. This firmware would include: initialization routines for I/O ports and the address-selection mechanism; an interrupt service routine (ISR) or a polling loop to detect the switch's state change; a mapping function to translate the active switch's input port to its corresponding unique address; and a communication module to transmit the address-specific signal via the output terminal. Error handling and self-diagnostic routines would also be crucial for ensuring the reliability of the safety system. This robust technical foundation positions the Addressable Electric Safety Contact Monitoring System as a critical enabler for advanced industrial safety solutions.","business_analysis":"The Addressable Electric Safety Contact Monitoring System patent (US-9852861) represents a significant advancement in industrial and commercial electrical safety, offering compelling business value and strategic positioning in a market increasingly demanding intelligent, reliable, and efficient safety solutions.\n\n**Market Opportunity Size:**\nThe global industrial control and factory automation market, which heavily relies on robust electrical safety, is projected to reach hundreds of billions of dollars in the coming years. Within this, the segment for safety systems and monitoring is a crucial, high-growth area. Traditional safety systems often provide generalized fault alerts, leading to substantial downtime and troubleshooting costs. This invention directly addresses this inefficiency, tapping into a vast market of manufacturing plants, power generation and distribution networks, smart building infrastructure, and transportation systems that require precise, real-time electrical safety monitoring. The increasing adoption of Industry 4.0 and IoT technologies further amplifies this market, as addressable data becomes a cornerstone for predictive maintenance and operational optimization.\n\n**Competitive Advantages:**\nThis technology offers several distinct competitive advantages. Firstly, **precision fault localization** is its paramount differentiator. Unlike prior art that might only indicate a circuit fault, this system pinpoints the exact safety contact's address, drastically reducing diagnostic time. Secondly, **reduced downtime** directly translates to significant cost savings for businesses, making the ROI compelling. In industries where every minute of production loss costs thousands, this efficiency gain is invaluable. Thirdly, **enhanced operational safety** for personnel is a critical, non-negotiable benefit, reducing liability and improving compliance. Finally, its **inherent addressability** makes it 'smart-grid' and 'smart-factory' ready, offering seamless integration into advanced digital ecosystems, a capability often lacking in legacy systems.\n\n**Revenue Potential and Business Models:**\nRevenue streams for this innovation could be multi-faceted. It could be licensed to existing industrial safety equipment manufacturers or integrated into proprietary product lines. Potential business models include: \n1.  **Direct Sales:** Selling the monitoring modules as standalone components or integrated units to industrial clients.\n2.  **Subscription Services:** Offering cloud-based monitoring and analytics platforms that leverage the addressable data, providing insights into system health and predictive maintenance alerts.\n3.  **OEM Partnerships:** Supplying the core technology to original equipment manufacturers (OEMs) of machinery, robotics, and electrical panels.\n4.  **Consulting and Integration Services:** Providing expertise for custom integration into complex existing infrastructures. The recurring revenue potential from software/platform subscriptions and ongoing maintenance contracts could be substantial.\n\n**Strategic Positioning:**\nThis patent positions its underlying technology as a leader in the next generation of industrial safety. It moves beyond basic protection to intelligent, data-driven safety management. Companies adopting or licensing this technology can differentiate themselves by offering superior reliability, efficiency, and safety standards. It enables a shift from reactive maintenance to proactive, predictive strategies, aligning with modern industrial demands for resilience and continuous operation. It can also serve as a foundational technology for developing new safety-as-a-service offerings.\n\n**ROI Projections:**\nThe return on investment for end-users deploying this system is high. For large industrial facilities, the cost of a single major electrical fault causing extensive downtime can easily run into millions of dollars. By reducing diagnostic time from hours/days to minutes, and preventing cascading failures through precise, rapid isolation, the system can pay for itself very quickly. Furthermore, reduced insurance premiums, avoidance of regulatory fines, and improved worker safety contribute to a robust, long-term ROI. Investors would find the technology appealing due to its clear market need, strong competitive advantages, and diverse revenue generation potential in a critical and expanding market.","faqs":[{"answer":"The Addressable Electric Safety Contact Monitoring System is an innovative patent (US-9852861) designed to precisely detect and identify electrical safety faults within complex systems. Unlike traditional systems that might only indicate a general problem, this technology provides a specific 'address' or location for the fault. This means that when a safety contact fails, the system doesn't just tell you *that* something is wrong, but *exactly where* it is.\n\nAt its core, the invention integrates an input terminal that receives a signal related to a safety fault, a switch that changes its position upon fault detection, and a microprocessor. The microprocessor then uses an address-selection mechanism to generate an output signal that corresponds to the unique address of the specific faulty contact. This level of precision is critical for rapid diagnosis and intervention.\n\nThis system is particularly valuable in environments with extensive electrical networks, such as manufacturing plants, power distribution facilities, and smart buildings. It moves beyond generic alerts to offer highly specific, actionable intelligence, significantly improving the efficiency and effectiveness of safety protocols. The patent lays the groundwork for a new generation of smart, self-diagnosing safety infrastructure.","question":"What is Addressable Electric Safety Contact Monitoring System?"},{"answer":"The Addressable Electric Safety Contact Monitoring System operates through a carefully orchestrated sequence of events.\n\nFirst, an external signal, indicating a safety fault (e.g., a broken wire, an activated emergency stop, or a sensor anomaly), is received by an input terminal. This terminal is connected to a switch that has a default 'normal' position and an 'active' position. When the fault signal is activated, the switch immediately changes from its default to its active state.\n\nSecond, a microprocessor, which is constantly monitoring the switch, detects this state change. This detection triggers the microprocessor to engage its address-selection mechanism. This mechanism is crucial as it stores or computes the unique digital address associated with the specific safety contact or zone where the switch is located.\n\nFinally, the microprocessor activates a signal on an output terminal. This output signal is encoded with the precise address identified by the address-selection mechanism. Therefore, instead of a general 'fault' message, an external system receives a message like 'Fault at Address A-17,' enabling immediate and accurate fault localization. This intelligent process ensures rapid and targeted response to safety issues.","question":"How does Addressable Electric Safety Contact Monitoring System work?"},{"answer":"The Addressable Electric Safety Contact Monitoring System primarily solves the problem of inefficient and imprecise electrical safety fault detection in complex environments. Traditional safety systems often provide only broad, generalized indications when a fault occurs. This means that while a problem is identified, its exact location within a vast electrical network remains unknown.\n\nThis lack of precise information leads to significant operational challenges. Maintenance teams must spend considerable time manually troubleshooting and searching for the fault, resulting in prolonged downtime for machinery or entire production lines. Such downtime translates directly into substantial financial losses due to lost productivity and increased labor costs. Moreover, the extended time spent diagnosing faults increases the exposure of personnel to potentially hazardous live electrical systems, raising safety risks.\n\nBy providing immediate, address-specific fault localization, the Addressable Electric Safety Contact Monitoring System drastically reduces diagnostic time, minimizes operational disruptions, and significantly enhances worker safety. It transforms a reactive, 'needle-in-a-haystack' problem into a proactive, 'here-is-the-needle' solution, making industrial and commercial operations more efficient and secure.","question":"What problem does Addressable Electric Safety Contact Monitoring System solve?"},{"answer":"The patent data for US-9852861, the Addressable Electric Safety Contact Monitoring System, does not list specific inventors or assignees in the provided abstract. This information is typically found in the full patent document, including the claims and detailed description sections of the filing. To identify the inventors and the entity (assignee) to whom the patent rights were assigned, one would need to consult the complete patent record available through official patent databases.\n\nHowever, the concept itself points to an engineering team focused on advancing industrial safety and control systems. Such innovations are usually developed by experts in electrical engineering, automation, and industrial controls, often within companies that specialize in manufacturing equipment, safety technology, or industrial automation solutions. The absence of specific names in the provided abstract is common in summaries, but the full patent document would contain this crucial attribution information.","question":"Who invented Addressable Electric Safety Contact Monitoring System?"},{"answer":"The Addressable Electric Safety Contact Monitoring System offers several key benefits that significantly enhance industrial and commercial operations.\n\nFirstly, and most importantly, it provides **unparalleled precision in fault localization**. By assigning a unique address to each safety contact and identifying faults by this address, it eliminates the guesswork involved in troubleshooting. This means maintenance teams know exactly where to go, drastically cutting down diagnostic time.\n\nSecondly, this precision leads to a significant **reduction in operational downtime**. Faster fault identification translates directly into quicker repairs and minimal disruption to production or services, resulting in substantial cost savings for businesses. For industries where every minute of downtime costs thousands, this is a critical advantage.\n\nThirdly, it **enhances worker safety**. By enabling rapid and targeted intervention, the system reduces the time personnel spend exposed to potentially hazardous electrical systems, thereby lowering the risk of accidents and improving overall workplace safety. It also supports better resource allocation and more efficient maintenance planning. Lastly, the Addressable Electric Safety Contact Monitoring System generates valuable, granular data that can be integrated into broader industrial control systems and predictive maintenance programs, supporting Industry 4.0 initiatives and data-driven decision-making.","question":"What are the key benefits of Addressable Electric Safety Contact Monitoring System?"},{"answer":"The Addressable Electric Safety Contact Monitoring System distinguishes itself from prior art primarily through its innovative address-selection mechanism and microprocessor-driven precision in fault localization. Traditional safety systems, while effective in detecting a fault, typically only provide a generalized indication, such as a tripped circuit breaker or a 'fault detected' message from a safety relay or PLC.\n\nPrior art solutions often require manual diagnostic steps or complex software logic to narrow down the fault location, which is time-consuming and prone to human error. In contrast, this invention's core difference lies in its ability to assign a unique digital 'address' to each safety contact. When a fault occurs, the system's microprocessor immediately identifies and outputs the specific address of the faulty contact. This means it doesn't just tell you *that* there's a problem, but *exactly where* the problem is.\n\nThis precision offers a significant competitive advantage: it dramatically reduces diagnostic time, minimizes operational downtime, and provides actionable data for targeted repairs. Unlike generic fault annunciators or even basic safety PLCs that may only indicate a faulty input channel, the Addressable Electric Safety Contact Monitoring System delivers pinpoint accuracy, transforming reactive troubleshooting into proactive, intelligent intervention.","question":"How is Addressable Electric Safety Contact Monitoring System different from prior art?"},{"answer":"The Addressable Electric Safety Contact Monitoring System has the potential to profoundly impact a wide range of industries that rely heavily on complex electrical systems and robust safety protocols.\n\n**Manufacturing and Industrial Automation:** This includes automotive, aerospace, electronics, and heavy machinery production. In these environments, thousands of safety interlocks, sensors, and contacts are critical. The system's ability to pinpoint faults will drastically reduce assembly line downtime and enhance worker safety around robotics and automated equipment.\n\n**Energy Generation and Distribution:** Power plants, substations, and smart grids will benefit from faster fault identification in their extensive electrical networks, leading to quicker service restoration and improved grid stability.\n\n**Smart Buildings and Infrastructure:** Large commercial complexes, data centers, hospitals, and transportation hubs can leverage this technology to ensure continuous operation of critical systems like HVAC, elevators, security, and emergency power, while minimizing diagnostic times for electrical issues.\n\n**Logistics and Warehousing:** Automated guided vehicles (AGVs), robotic sorting systems, and conveyor belts in modern warehouses require constant safety monitoring. This system will enable rapid fault detection, ensuring smooth and safe operations. Overall, any industry where electrical safety is paramount and downtime is costly will find significant value in this innovation.","question":"What industries will Addressable Electric Safety Contact Monitoring System impact?"},{"answer":"The Addressable Electric Safety Contact Monitoring System patent, identified by its number US-9852861, was filed on **September 12, 2015**. This date marks when the initial patent application was submitted to the patent office, formally beginning the examination process for this invention.\n\nFollowing the examination period, the patent was subsequently granted and published on **December 26, 2017**. The publication date signifies when the patent was officially issued, making its details publicly accessible and granting the patent holder exclusive rights to the invention for a specified period.\n\nThese dates are crucial for understanding the timeline of the innovation's development and its legal protection. The period between filing and publication allows for the examination of novelty, inventiveness, and industrial applicability by patent examiners, ensuring the patent meets all legal requirements before being granted.","question":"When was Addressable Electric Safety Contact Monitoring System filed/granted?"},{"answer":"The commercial applications of the Addressable Electric Safety Contact Monitoring System are extensive, driven by the universal need for improved electrical safety and operational efficiency across industries.\n\nOne primary application is in **industrial automation and manufacturing**. This system can be integrated into production lines, robotic cells, and heavy machinery to monitor safety interlocks, emergency stop buttons, and protective sensors. Its ability to pinpoint faults will significantly reduce costly downtime and accelerate maintenance, making factories safer and more productive.\n\nAnother key area is **smart building management systems**. In large commercial, residential, or public buildings, the system can monitor critical electrical contacts in HVAC systems, elevators, lighting, and security infrastructure. This allows facility managers to quickly identify and address issues, ensuring continuous operation and occupant safety.\n\nFurthermore, the Addressable Electric Safety Contact Monitoring System is highly applicable in **power distribution and energy management**. It can be deployed in substations, switchgear, and renewable energy installations to provide precise fault location, aiding in faster grid restoration and enhancing overall energy reliability. Its addressable data output also makes it ideal for integration with **IoT platforms and predictive maintenance solutions**, enabling new business models focused on 'safety-as-a-service' or advanced analytics for asset health monitoring. This broad applicability underscores its significant commercial potential.","question":"What are the commercial applications of Addressable Electric Safety Contact Monitoring System?"},{"answer":"Looking ahead, several exciting future developments can be expected for the Addressable Electric Safety Contact Monitoring System, building upon its core innovation of precise, addressable fault detection.\n\nOne major area of development is **enhanced integration with AI and Machine Learning**. The granular, address-specific data generated by this system is ideal for training AI models. These models could learn to predict potential safety contact failures before they occur, identify subtle patterns of degradation, or even suggest optimal maintenance schedules. This would enable a shift from proactive to truly predictive safety management.\n\nAnother anticipated development is its role in **self-healing and autonomous systems**. With precise fault location, future iterations could integrate with smart control systems to automatically isolate faulty sections, re-route power, or activate redundant components without human intervention. This would minimize downtime and enhance system resilience significantly. We can also expect **standardization and broader adoption** across critical infrastructure, leading to more robust and interoperable safety ecosystems. Furthermore, advancements in **wireless communication and edge computing** could lead to more compact, distributed versions of the Addressable Electric Safety Contact Monitoring System, allowing for easier deployment in hard-to-reach or mobile industrial assets. Ultimately, this technology is poised to become a foundational component for the next generation of intelligent, self-aware, and highly resilient industrial and commercial safety systems.","question":"What are the future developments expected for Addressable Electric Safety Contact Monitoring System?"}],"topics":["addressable electric safety contact monitoring system","electrical safety patent","fault detection system","microprocessor monitoring","industrial safety","relentless","march","industrial"],"tech_cluster":null},"seo":{"title":"Addressable Electric Safety Contact Monitoring System - US-9852861","description":"Discover the Addressable Electric Safety Contact Monitoring System patent (US-9852861). Pinpoint electrical faults with address-specific monitoring for enhanced safety and efficiency.","keywords":["addressable electric safety contact monitoring system","electrical safety patent","fault detection system","microprocessor monitoring","industrial safety","safety fault detection","US-9852861","smart safety technology","electrical monitoring","downtime reduction","predictive maintenance","safety innovation"]},"attribution":{"source":"Patentable","source_url":"https://patentable.app","canonical_url":"https://patentable.app/patents/US-9852861","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-9852861","citation_suggestion":"Patentable. \"Addressable electric safety contact monitoring system\" (US-9852861). https://patentable.app/patents/US-9852861","copyright_holder":"Nomic Interactive Technology LLC"},"links":{"html":"https://patentable.app/patents/US-9852861","json":"https://patentable.app/api/llm-context/US-9852861","site":"https://patentable.app","llms_txt":"https://patentable.app/llms.txt"},"generated_at":"2026-06-06T07:14:03.133Z"}