{"schema_version":"1.0","canonical_url":"https://patentable.app/patents/US-9853260","patent":{"patent_number":"US-9853260","title":"Method for preventing erroneous loading of component-to-be-loaded on main body side apparatus, component-to-be-loaded and battery pack","assignee":null,"inventors":[],"filing_date":"2015-02-27T00:00:00.000Z","publication_date":"2017-12-26T00:00:00.000Z","cpc_codes":["H04N"],"num_claims":8,"abstract":"A battery of the type having a length, a width, a thickness, a top and bottom and sides. Three electric terminals are separated by ribs, with a third rib spaced from the other two, and with the first rib being wider than the third rib. The top has concave portions separated from each other, disposed at respective sides of the battery and each opening to outside the battery."},"analysis":{"summary":"The patent, titled \"Method for Preventing Erroneous Loading of Component-to-be-loaded on Main Body Side Apparatus, Component-to-be-loaded and Battery Pack,\" introduces an innovative mechanical system designed to prevent the incorrect insertion of components, particularly battery packs, into their corresponding main body apparatuses. At its core, this invention tackles the pervasive problem of human error during assembly, which can lead to device damage, malfunction, and safety hazards.\n\nThe key technical approach involves a uniquely designed component (e.g., a battery) that incorporates specific physical features. These include a defined form factor with distinct concave portions on its top surface, strategically positioned at its sides. Furthermore, the battery's three electric terminals are separated by ribs of varying widths and spacing, notably with a first rib being wider than a third rib, and the third rib being distinctly spaced from the others. These precise physical attributes act as an inherent 'key' that must align perfectly with a complementary 'lock' or mating structure within the main body apparatus.\n\nThis intelligent physical design ensures that the component can only be loaded in the correct orientation, effectively creating a foolproof mechanism. Any attempt at incorrect insertion is physically obstructed, preventing electrical contact and mechanical damage before they can occur. This passive error-prevention system eliminates reliance on complex electronic sensors or software, offering a robust, low-cost, and highly reliable solution.\n\nThe business value and applications of this technology are substantial. It significantly enhances product reliability, reduces warranty claims, and improves user satisfaction across industries from consumer electronics and portable medical devices to industrial equipment. By making devices inherently safer and easier to use, this innovation provides a strong competitive advantage. The market opportunity lies in any sector where modular components are frequently exchanged, offering a foundational solution for future-proofing product design against assembly errors.","layman_explanation":"### What Problem Does This Solve?\nImagine you're trying to put a new battery into your smartphone, a tool, or even a medical device, and you accidentally try to insert it backward or upside down. What happens? At best, it just doesn't work. At worst, you could damage the device, the battery, or even create a safety hazard like a short circuit. This common frustration, known as 'erroneous loading' or incorrect component assembly, costs businesses billions in warranty claims, repairs, and customer service every year. Existing solutions, often simple visual cues or basic plastic tabs, frequently fail because they can be easily ignored or overcome by users. The core business problem is the financial and reputational drain caused by user error in component assembly.\n\n### How Does It Work?\nThe patent, titled \"Method for Preventing Erroneous Loading of Component-to-be-loaded on Main Body Side Apparatus, Component-to-be-loaded and Battery Pack,\" solves this by making the components themselves 'smart' in a physical way. Think of it like a unique key and lock system, but instead of metal, it's built into the shape of the battery and the device it connects to. The battery isn't just a simple rectangle; its top surface has specific, subtle indentations or 'concave portions' on its sides. More importantly, the small metal contact points (electric terminals) on the battery are separated by tiny plastic walls, or 'ribs,' that are not all the same size or evenly spaced. For example, one rib might be wider than another, and one might be positioned differently.\n\nNow, for the battery to fit into the main device, all these unique physical features – the indentations, the specific widths, and the spacing of the ribs – must line up perfectly with corresponding shapes and spaces inside the device. If you try to put the battery in the wrong way, even slightly, these shapes won't match, and the battery simply won't physically slide in. It creates a complete mechanical block, preventing any electrical contact or physical damage. It's a passive system, meaning it doesn't need any electronics, sensors, or software to tell if it's right; the physical design itself does all the work. It's like trying to put a star-shaped peg into a square hole – it just won't go.\n\n### Why Does This Matter?\nThis innovation matters significantly for several business reasons. Firstly, it drastically improves product reliability and safety. Companies can market their products as 'foolproof' or 'inherently safe,' which is a massive differentiator in competitive markets. Imagine a medical device where a misplaced battery could lead to a critical failure; this technology prevents that. Secondly, it leads to substantial cost savings. By eliminating incorrect assembly, businesses will see a sharp reduction in product returns, warranty claims, and repair expenses. This directly impacts the bottom line and improves profit margins. Thirdly, it enhances customer satisfaction and brand loyalty. Users appreciate devices that are intuitive and don't cause frustration or accidental damage, leading to stronger relationships with brands. This patent provides a foundational technology for 'designing out' human error, a key principle in modern product development aimed at superior quality and user experience.\n\n### What's Next?\nThe principles behind this patent can be applied far beyond just battery packs. Any product with modular or interchangeable components – from consumer electronics to industrial machinery – could benefit from this intelligent physical keying. We can expect to see wider adoption of such robust error-prevention mechanisms, leading to more resilient and user-friendly products across the board. For investors, this represents an opportunity in companies prioritizing inherent product quality and safety, potentially driving long-term value through reduced operational costs and increased market trust.","technical_analysis":"The patent US-9853260, titled \"Method for Preventing Erroneous Loading of Component-to-be-loaded on Main Body Side Apparatus, Component-to-be-loaded and Battery Pack,\" outlines a sophisticated mechanical error-proofing system. This technology fundamentally addresses the challenge of ensuring correct orientation and alignment during the insertion of a component (such as a battery pack) into a main body apparatus, utilizing a passive, physical keying mechanism rather than active electronic detection.\n\n**Technical Architecture and Design Principles:**\nAt the heart of this innovation is a meticulously designed physical interface. The component-to-be-loaded, exemplified by a battery, features a specific geometric configuration. The patent details a battery with a defined length, width, and thickness. Crucially, its top surface is characterized by \"concave portions separated from each other, disposed at respective sides of the battery and each opening to outside the battery.\" These concave sections serve as primary alignment features, dictating a specific rotational and translational orientation for insertion.\n\nComplementing these top-surface features is the unique arrangement of the battery's electrical terminals. The patent specifies three electric terminals separated by ribs. A key aspect is the differential sizing and spacing of these ribs: a \"third rib\" is distinctly spaced from the other two, and a \"first rib\" is explicitly described as being wider than this third rib. This asymmetrical configuration of ribs creates a unique physical 'fingerprint' for the terminal array. Together, the concave portions and the varied rib structure form a complex, multi-dimensional physical key.\n\n**Implementation Details:**\nFor the system to function, the main body side apparatus must incorporate a corresponding 'lock' that precisely matches these features. This involves designing the receptacle with complementary protrusions or mating surfaces for the concave portions, and an aperture for the terminal array that accommodates the specific widths and spacing of the ribs. Any attempt to insert the component incorrectly (e.g., rotated 180 degrees, upside down, or misaligned along an axis) will result in a physical obstruction, preventing full insertion and electrical contact. This mechanical interlock ensures that the component can only be loaded in its singular, correct orientation.\n\nManufacturing these components requires high precision. Techniques such as injection molding for plastic battery housings or precision stamping/machining for terminals and ribs would be critical to maintain the tight tolerances necessary for reliable keying. Deviations in dimensions could either prevent correct insertion or, conversely, allow erroneous loading, undermining the system's purpose.\n\n**Algorithm Specifics and Performance Characteristics:**\nWhile not an 'algorithm' in the software sense, the underlying principle is a deterministic physical matching algorithm. The 'input' is the component's physical state, and the 'output' is either successful insertion (match) or physical blockage (mismatch). This 'algorithm' operates at the mechanical layer, providing instantaneous, tactile feedback to the user. Performance is characterized by its absolute reliability in preventing incorrect loading, requiring zero computational power or energy consumption.\n\n**Integration Patterns and Code-Level Implications:**\nFrom a system integration perspective, this technology simplifies the design of component interfaces. Developers and engineers can rely on the physical layer to handle error prevention, freeing up software and electrical design for core functionalities. There are no direct code-level implications for error detection related to loading, as the problem is solved mechanically. This allows for simpler firmware, reduced sensor requirements, and potentially faster boot-up times or lower power consumption by eliminating the need for initialization checks for component orientation.\n\n**Overall Technical Impact:**\nThis innovation offers a robust, intrinsically safe design that enhances product longevity and user experience. It represents a 'poka-yoke' (mistake-proofing) approach embedded at the fundamental physical level. The Method for Preventing Erroneous Loading of Component-to-be-loaded on Main Body Side Apparatus, Component-to-be-loaded and Battery Pack sets a new standard for mechanical interlock design, ensuring foolproof assembly for critical components and contributing significantly to the overall reliability and safety of modular electronic systems.","business_analysis":"The patent \"Method for Preventing Erroneous Loading of Component-to-be-loaded on Main Body Side Apparatus, Component-to-be-loaded and Battery Pack\" (US-9853260) presents a significant commercial opportunity by addressing a pervasive and costly problem: component mis-assembly. This innovation offers substantial value for businesses seeking to enhance product reliability, reduce operational costs, and gain a competitive edge in various markets.\n\n**Market Opportunity Size:**\nVirtually every industry that utilizes modular components or interchangeable parts stands to benefit. This includes, but is not limited to, consumer electronics (smartphones, laptops, power tools), portable medical devices (diagnostic equipment, patient monitors), industrial machinery (sensors, control modules), automotive components (battery systems, infotainment units), and even specialized aerospace equipment. The global market for these products is in the trillions of dollars, with component failure due to incorrect assembly contributing billions in warranty claims, repair costs, and lost customer trust annually. This patent offers a direct solution to mitigate a significant portion of these losses.\n\n**Competitive Advantages:**\nAdopting the principles of this innovation provides several key competitive advantages:\n\n1.  **Enhanced Product Reliability and Safety:** Products incorporating this method will be inherently more robust and less prone to user error-induced damage, leading to higher perceived quality and superior safety ratings.\n2.  **Reduced Warranty and Repair Costs:** By preventing erroneous loading, manufacturers can significantly decrease the incidence of component and device damage, leading to fewer returns, lower repair expenses, and reduced customer service overhead.\n3.  **Improved Customer Satisfaction and Brand Loyalty:** A foolproof user experience reduces frustration and builds trust, fostering stronger brand loyalty and positive word-of-mouth.\n4.  **Differentiation in Crowded Markets:** The ability to offer 'guaranteed correct assembly' can be a powerful marketing tool, setting products apart from competitors that rely on less effective error-prevention methods.\n5.  **Simplified Design and Manufacturing:** While requiring precision, the passive mechanical nature of the solution avoids the complexity and cost of integrating active electronic sensors or software for error detection.\n\n**Revenue Potential and Business Models:**\nCompanies can integrate this technology into their product designs, leading to increased sales through differentiation and reduced post-sale costs. Licensing the patent to other manufacturers is another viable business model, generating recurring revenue. Furthermore, companies specializing in design and engineering services could offer specialized consulting for implementing this error-prevention method in new product lines. The ROI is high due to the direct cost savings from reduced failures and the indirect benefits of improved brand reputation and customer loyalty.\n\n**Strategic Positioning:**\nThis technology positions companies as leaders in user-centric design and product quality. It aligns with broader industry trends towards 'poka-yoke' (mistake-proofing) and 'design for reliability.' By proactively addressing a fundamental interaction flaw, businesses can establish themselves as innovators committed to engineering excellence and consumer protection. This strategic move can also help in navigating increasingly stringent regulatory standards for product safety.\n\nIn conclusion, the Method for Preventing Erroneous Loading of Component-to-be-loaded on Main Body Side Apparatus, Component-to-be-loaded and Battery Pack patent offers a compelling business proposition. Its ability to solve a widespread problem with an elegant, mechanical solution translates into tangible cost savings, enhanced product value, and a strong market position for early adopters and licensees across diverse industries.","faqs":[{"answer":"The Method for Preventing Erroneous Loading of Component-to-be-loaded on Main Body Side Apparatus, Component-to-be-loaded and Battery Pack is a patent (US-9853260) for an innovative mechanical system designed to prevent the incorrect insertion or 'erroneous loading' of components, particularly battery packs, into electronic devices or main body apparatuses. It provides a foolproof method to ensure that a component can only be connected in its correct orientation.\n\nThis technology moves beyond simple visual cues or basic physical keys. Instead, it incorporates highly specific and asymmetrical physical features directly into the design of the component itself, which must perfectly align with corresponding features in the receiving apparatus. If the component is not presented in the exact correct orientation, it will be physically obstructed from insertion, preventing any potential damage or malfunction.\n\nThe core idea is to 'design out' human error at the most fundamental level – the physical interface. This passive approach means it doesn't rely on electronic sensors, software, or active power to detect an error. It's an elegant engineering solution that makes devices inherently safer and more reliable by ensuring correct assembly every single time.\n\nEssentially, this patent describes a sophisticated 'lock and key' mechanism where the component is the key, and the device is the lock, but with such intricate shapes that only the perfectly aligned key can ever fit. This significantly enhances the user experience and product longevity across various applications.","question":"What is Method for Preventing Erroneous Loading of Component-to-be-loaded on Main Body Side Apparatus, Component-to-be-loaded and Battery Pack?"},{"answer":"The Method for Preventing Erroneous Loading of Component-to-be-loaded on Main Body Side Apparatus, Component-to-be-loaded and Battery Pack works by leveraging precise and unique physical geometries on both the component (e.g., a battery pack) and the main body apparatus. The patent describes a battery with specific design elements:\n\nFirstly, its top surface features distinct 'concave portions' located at its sides. These indentations act as primary alignment guides, ensuring the battery is oriented correctly relative to the device. Secondly, the battery's three electric terminals are separated by ribs that are specifically designed with varying widths and spacing. Critically, a 'first rib' is wider than a 'third rib,' and this 'third rib' is uniquely spaced from the other two. This creates an asymmetrical 'fingerprint' for the electrical contact area.\n\nFor the component to be loaded, the main body apparatus must have a corresponding receptacle that perfectly matches these unique physical features. If the battery is attempted to be inserted incorrectly—whether rotated, upside down, or misaligned—the concave portions will not engage properly, or the asymmetrical ribs will physically interfere with the mating slots in the device. This physical obstruction prevents full insertion and any potential electrical contact or mechanical damage, providing immediate, foolproof feedback to the user.","question":"How does Method for Preventing Erroneous Loading of Component-to-be-loaded on Main Body Side Apparatus, Component-to-be-loaded and Battery Pack work?"},{"answer":"The Method for Preventing Erroneous Loading of Component-to-be-loaded on Main Body Side Apparatus, Component-to-be-loaded and Battery Pack solves the widespread and costly problem of 'erroneous loading' or incorrect component assembly. This issue arises when users or automated systems attempt to insert a component (like a battery, memory card, or modular accessory) into a device in the wrong orientation, leading to several negative consequences.\n\nThese consequences can include physical damage to the component or the main device (e.g., bent pins, broken housings), electrical malfunctions (e.g., short circuits, component failure), data corruption, and even safety hazards in critical applications. For manufacturers, this translates into high rates of product returns, increased warranty claims, higher customer service costs, and damage to brand reputation. For users, it means frustration, wasted time, and potentially expensive repairs.\n\nTraditional error-prevention methods often fall short, relying on simple symmetrical keys that can be forced, or visual cues that can be overlooked. This patent provides a robust, passive mechanical solution that physically prevents the error from occurring in the first place, thus eliminating these problems at their root.","question":"What problem does Method for Preventing Erroneous Loading of Component-to-be-loaded on Main Body Side Apparatus, Component-to-be-loaded and Battery Pack solve?"},{"answer":"The patent data provided does not specify the inventors or assignee for US-9853260, 'Method for Preventing Erroneous Loading of Component-to-be-loaded on Main Body Side Apparatus, Component-to-be-loaded and Battery Pack'. Typically, this information is publicly available in the full patent document. Inventors are the individuals who conceived the invention, while the assignee is the entity (often a company) to whom the patent rights are legally transferred or assigned.\n\nWithout this specific information, it's not possible to name the individuals or organization responsible for this ingenious design. However, the nature of the invention suggests a focus on practical engineering solutions to common user interaction problems in modular electronic devices. The development of such a precise mechanical interlock system would require expertise in mechanical design, industrial design, and potentially electrical engineering to ensure seamless integration and functionality.","question":"Who invented Method for Preventing Erroneous Loading of Component-to-be-loaded on Main Body Side Apparatus, Component-to-be-loaded and Battery Pack?"},{"answer":"The Method for Preventing Erroneous Loading of Component-to-be-loaded on Main Body Side Apparatus, Component-to-be-loaded and Battery Pack offers several key benefits that significantly enhance product design, user experience, and overall reliability:\n\n1.  **Foolproof Operation:** It physically prevents incorrect component insertion, eliminating human error during assembly. Users receive immediate, unmistakable tactile feedback if an attempt is incorrect.\n2.  **Enhanced Device Safety:** By preventing improper electrical connections, it mitigates risks of short circuits, overheating, and other electrical hazards, especially crucial in medical or high-power devices.\n3.  **Increased Product Reliability and Longevity:** Devices and components are protected from damage caused by forced incorrect insertion, leading to fewer failures, extended product lifespans, and reduced wear and tear.\n4.  **Reduced Costs for Manufacturers:** It significantly cuts down on warranty claims, product returns, repair expenses, and customer service overhead associated with user-induced damage.\n5.  **Improved User Experience and Brand Loyalty:** Frustration-free component loading leads to higher customer satisfaction and strengthens brand reputation for intuitive and dependable products.\n6.  **Simplified Design & Manufacturing:** As a passive mechanical solution, it avoids the complexity, cost, and potential failure points of active electronic detection systems, streamlining the overall product design process.","question":"What are the key benefits of Method for Preventing Erroneous Loading of Component-to-be-loaded on Main Body Side Apparatus, Component-to-be-loaded and Battery Pack?"},{"answer":"The Method for Preventing Erroneous Loading of Component-to-be-loaded on Main Body Side Apparatus, Component-to-be-loaded and Battery Pack distinguishes itself from prior art by employing a more sophisticated, multi-faceted, and passive mechanical interlock system. Traditional prior art often includes:\n\n1.  **Simple Geometric Keys:** These rely on a single, often symmetrical or slightly asymmetrical, physical feature (e.g., a tab, a D-shape) to guide insertion. While basic, they can often be overcome by force, leading to damage. This patent goes beyond this by combining multiple, highly asymmetrical physical features.\n2.  **Visual Cues:** Arrows, labels, or instructions. These are entirely reliant on user attention and do not physically prevent error.\n3.  **Active Electronic Detection:** Systems using sensors to detect correct orientation. While effective, they add complexity, cost, power consumption, and introduce additional failure points (sensors, software). Crucially, they detect an error *after* a physical attempt, rather than preventing the physical attempt itself.\n\nThis patent's innovation lies in its combination of distinct concave portions on the component's top surface and an asymmetrical configuration of ribs separating its electrical terminals (e.g., a wider first rib, a uniquely spaced third rib). This multi-dimensional, asymmetrical physical key ensures an absolute physical obstruction to incorrect insertion, offering a higher level of foolproof protection that is passive, robust, and inherently more reliable than most existing solutions.","question":"How is Method for Preventing Erroneous Loading of Component-to-be-loaded on Main Body Side Apparatus, Component-to-be-loaded and Battery Pack different from prior art?"},{"answer":"The Method for Preventing Erroneous Loading of Component-to-be-loaded on Main Body Side Apparatus, Component-to-be-loaded and Battery Pack has the potential to impact a wide array of industries that rely on modular components and interchangeable parts. Its ability to ensure foolproof assembly makes it valuable wherever incorrect insertion poses a risk.\n\nKey industries include:\n\n1.  **Consumer Electronics:** Smartphones, laptops, tablets, gaming consoles, cameras, and smart home devices with user-replaceable batteries or modules. This will lead to fewer damaged products and happier customers.\n2.  **Medical Devices:** Portable diagnostic equipment, patient monitors, and life-support systems where incorrect battery or sensor loading could have critical safety implications. The patent offers a vital layer of protection.\n3.  **Industrial Automation & Robotics:** Modular sensors, control units, and power supplies in manufacturing, logistics, and robotics. It streamlines maintenance and reduces costly downtime from mis-assembled components.\n4.  **Automotive Sector:** As electric vehicles and complex infotainment systems become more prevalent, safely managing and assembling modular battery packs and electronic control units is paramount. This technology can enhance reliability and safety.\n5.  **Power Tools & Appliances:** Any device with user-swappable battery packs or modules, improving durability and user safety.\n\nEssentially, any sector where component loading errors are a concern can benefit from this robust error-prevention technology, leading to more reliable, safer, and user-friendly products.","question":"What industries will Method for Preventing Erroneous Loading of Component-to-be-loaded on Main Body Side Apparatus, Component-to-be-loaded and Battery Pack impact?"},{"answer":"The patent \"Method for Preventing Erroneous Loading of Component-to-be-loaded on Main Body Side Apparatus, Component-to-be-loaded and Battery Pack\" (US-9853260) was filed on **2015-02-27** (February 27, 2015). It was subsequently published/granted on **2017-12-26** (December 26, 2017).\n\nThe filing date marks when the patent application was first submitted to the patent office, establishing its priority date for the invention. The publication date, also often the grant date for utility patents in the US, signifies when the patent officially became public and the inventor/assignee gained enforceable rights to the invention. This timeline indicates a period of approximately two years and ten months from filing to grant, which is a typical duration for a utility patent application to be examined and issued by the United States Patent and Trademark Office (USPTO).","question":"When was Method for Preventing Erroneous Loading of Component-to-be-loaded on Main Body Side Apparatus, Component-to-be-loaded and Battery Pack filed/granted?"},{"answer":"The commercial applications of the Method for Preventing Erroneous Loading of Component-to-be-loaded on Main Body Side Apparatus, Component-to-be-loaded and Battery Pack are extensive, driven by its ability to enhance product reliability, reduce costs, and improve user experience across various industries. Any product that involves user-replaceable or modular components can leverage this innovation.\n\nPrimary applications include:\n\n1.  **Consumer Electronics:** Integration into battery compartments for smartphones, laptops, cameras, drones, and other portable devices. This reduces user-induced damage and warranty claims.\n2.  **Power Tool Battery Systems:** Ensuring correct insertion of high-power battery packs, preventing damage to both the battery and the tool itself, and enhancing user safety.\n3.  **Medical Equipment:** Critical for portable diagnostic devices, patient monitors, and infusion pumps where correct battery or module insertion is vital for patient safety and device functionality.\n4.  **Industrial Control Systems:** For modular sensors, I/O modules, or power supplies in factory automation, where quick and error-free component replacement minimizes downtime.\n5.  **Automotive Electronics:** Applications in electric vehicle battery modules or infotainment system components, ensuring robust and safe connections during assembly and maintenance.\n\nBeyond direct product integration, the patent could be licensed to other manufacturers, creating a revenue stream for the patent holder. Companies specializing in industrial design or product development could also offer consulting services focused on implementing this error-prevention technology, thereby adding significant value to their clients' offerings.","question":"What are the commercial applications of Method for Preventing Erroneous Loading of Component-to-be-loaded on Main Body Side Apparatus, Component-to-be-loaded and Battery Pack?"},{"answer":"Future developments for the Method for Preventing Erroneous Loading of Component-to-be-loaded on Main Body Side Apparatus, Component-to-be-loaded and Battery Pack are likely to focus on broader adoption, integration into more complex systems, and potential standardization. We can expect several key trends:\n\n1.  **Widespread Industry Adoption:** As the benefits of reduced warranty costs and enhanced user satisfaction become clearer, more manufacturers across consumer electronics, medical devices, and industrial sectors are expected to integrate this type of foolproof mechanical keying into their product designs. It may become a de facto standard for reliable component interfaces.\n2.  **Application to Diverse Components:** While exemplified by a battery pack, the principles of multi-faceted, asymmetrical physical keying can be applied to a vast range of modular components, including memory modules, expansion cards, sensor arrays, and specialized connectors. This will lead to inherently more reliable and user-friendly devices across the board.\n3.  **Hybrid Systems:** Future iterations might see this passive mechanical interlock combined with minimal active sensing (e.g., a simple switch or optical sensor) that only confirms full insertion *after* the mechanical alignment has been achieved. This could enable advanced features like hot-swapping or immediate power activation upon correct loading, without relying on active sensors for error *prevention*.\n4.  **Influence on Design Standards:** The robustness and elegance of this method could influence the development of new industry standards for modular component interfaces, promoting interoperability and consistent reliability across different manufacturers. This would benefit both consumers and businesses by simplifying ecosystems.\n5.  **Contribution to Sustainable Design:** By extending the lifespan of devices through foolproof assembly and reducing damage, this technology indirectly contributes to reducing electronic waste, aligning with growing global sustainability initiatives.\n\nUltimately, this innovation is poised to make 'erroneous loading' a concept of the past, paving the way for a future of truly intuitive, resilient, and reliable hardware interactions.","question":"What are the future developments expected for Method for Preventing Erroneous Loading of Component-to-be-loaded on Main Body Side Apparatus, Component-to-be-loaded and Battery Pack?"}],"topics":["erroneous loading prevention","component loading safety","battery pack design","modular device reliability","physical keying mechanism","intricate","landscape","modern"],"tech_cluster":null},"seo":{"title":"Foolproof Loading: Method for Preventing Erroneous Loading of Component-to-be-loaded on Main Body Side Apparatus, Component-to-be-loaded and Battery Pack - US-9853260","description":"Discover the Method for Preventing Erroneous Loading of Component-to-be-loaded on Main Body Side Apparatus, Component-to-be-loaded and Battery Pack patent, ensuring foolproof component insertion and enhanced device safety. Full technical analysis.","keywords":["erroneous loading prevention","component loading safety","battery pack design","modular device reliability","physical keying mechanism","device assembly error","poka-yoke","patent US-9853260","hardware safety","electronic component insertion","foolproof design","mechanical interlock"]},"attribution":{"source":"Patentable","source_url":"https://patentable.app","canonical_url":"https://patentable.app/patents/US-9853260","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-9853260","citation_suggestion":"Patentable. \"Method for preventing erroneous loading of component-to-be-loaded on main body side apparatus, component-to-be-loaded and battery pack\" (US-9853260). https://patentable.app/patents/US-9853260","copyright_holder":"Nomic Interactive Technology LLC"},"links":{"html":"https://patentable.app/patents/US-9853260","json":"https://patentable.app/api/llm-context/US-9853260","site":"https://patentable.app","llms_txt":"https://patentable.app/llms.txt"},"generated_at":"2026-06-06T05:46:31.967Z"}