{"schema_version":"1.0","canonical_url":"https://patentable.app/patents/US-9853061","patent":{"patent_number":"US-9853061","title":"Display device and manufacturing method thereof","assignee":null,"inventors":[],"filing_date":"2014-04-10T00:00:00.000Z","publication_date":"2017-12-26T00:00:00.000Z","cpc_codes":["G02F","G02F","G02F","G02F"],"num_claims":6,"abstract":"The present invention discloses a display device and a manufacturing method thereof. The display device comprises an array substrate and a color filter substrate arranged opposite to the array substrate, wherein the surface of the array substrate is provided with a lining layer and a conduction layer; and the lining layer uplifts the conduction layer till the conduction layer is in contact with the color filter substrate, so that the conduction layer conducts the array substrate and the color filter substrate. Compared with a conduction structure of the existing technology in which a connector and a conductive adhesive are combined, the conduction structure of the present invention saves the material cost, reduces the machining difficulty, increases the rate of good products and finally greatly reduces the production cost, is simultaneously applicable to a narrow-bezel design of the display device and meets the aesthetic demands of users."},"analysis":{"summary":"The patent titled \"Display Device and Manufacturing Method Thereof\" (US-9853061) introduces a revolutionary approach to constructing display panels, addressing long-standing challenges in cost, complexity, and design limitations. Its core innovation lies in an integrated conduction structure that replaces traditional external connectors and conductive adhesives.\n\nThe primary problem this invention solves is the inefficiency and expense associated with conventional methods of electrically connecting the array substrate and the color filter substrate in display devices. Existing solutions typically involve multiple components, leading to higher material costs, intricate assembly processes, increased manufacturing difficulty, and a higher rate of production rejects.\n\nTechnically, the Display Device and Manufacturing Method Thereof proposes an array substrate whose surface is equipped with a unique lining layer and a conduction layer. The lining layer is ingeniously designed to uplift the conduction layer until it makes direct physical and electrical contact with the color filter substrate. This creates a seamless, internal conductive pathway, eliminating the need for external bonding agents or discrete connectors.\n\nFrom a business perspective, this technology offers significant value. By simplifying the conduction structure, it drastically reduces material costs and manufacturing complexity. This translates directly into increased production yields and a substantial reduction in overall production costs. Furthermore, the integrated design is perfectly suited for modern narrow-bezel display aesthetics, meeting growing consumer demand for sleeker, more immersive screens. The market opportunity is vast, impacting manufacturers of smartphones, tablets, TVs, and other display-equipped devices, offering a competitive edge through improved cost-efficiency and product design capabilities. This innovation is poised to drive the next wave of display manufacturing advancements.","layman_explanation":"When we talk about the \"Display Device and Manufacturing Method Thereof\" patent, we're really discussing a clever new way to build the screens we use every day—from our smartphones to our giant flat-screen TVs. This innovation tackles some fundamental business challenges in a highly competitive industry.\n\n**1. What Problem Does This Solve?**\nThink about the fundamental layers inside any digital screen. You have an 'array substrate' that contains all the tiny electronic switches and pixels that create the image, and a 'color filter substrate' that gives those pixels their vibrant colors. For the screen to work, these two layers need to be electrically connected, allowing signals to pass between them. Historically, this connection has been a headache for manufacturers. They typically use tiny, separate connectors, often glued into place with special conductive adhesives. This process is like trying to precisely connect two delicate pieces of a puzzle using a very specific type of superglue. It's expensive because of the specialized components and materials, it's complex because the alignment has to be perfect, and it often leads to a high number of defective screens, which means wasted effort and money. Moreover, these traditional connectors often take up space, making it harder to design screens with the ultra-thin bezels that consumers increasingly demand.\n\n**2. How Does It Work?**\nThis patent introduces a remarkably elegant solution. Instead of adding external connectors, the \"Display Device and Manufacturing Method Thereof\" integrates the connection directly into one of the main components. Imagine the array substrate (the 'picture-making' layer) being designed with a tiny, precisely shaped 'lining layer' on its surface. On top of this lining layer, a 'conduction layer' is also built. The magic happens because this lining layer is designed to gently 'uplift' or raise the conduction layer. So, when the array substrate and the color filter substrate are brought together during assembly, this uplifted conduction layer automatically makes direct electrical contact with the color filter substrate. It's a self-aligning, self-connecting mechanism. This eliminates the need for any separate physical connectors or messy, unreliable conductive glues.\n\nTo use an analogy, instead of having to buy a separate bridge (connector) and special cement (adhesive) to connect two islands (substrates), this innovation makes one island grow a small, perfectly sized hill that automatically touches the other island when they're close enough. This direct contact ensures a strong, reliable connection without the extra parts or construction effort.\n\n**3. Why Does This Matter?**\nThis seemingly small technical change has massive business implications:\n*   **Cost Savings:** By removing the need for separate connectors and conductive adhesives, manufacturers can significantly reduce their material costs per unit. Over millions of units, this translates into enormous savings and increased profit margins.\n*   **Efficiency Boost:** The manufacturing process becomes simpler and less prone to errors. This means faster production, fewer rejected screens, and a higher 'yield' of good products, directly improving operational efficiency and reducing labor costs.\n*   **Design Freedom:** Because the connection is integrated and compact, it frees up valuable space around the edges of the screen. This is crucial for enabling the narrow-bezel and 'all-screen' designs that are highly popular with consumers, giving product designers more flexibility and creating more aesthetically pleasing devices.\n*   **Competitive Edge:** Companies adopting this technology can produce displays that are both cheaper to make and more attractive to consumers, providing a significant competitive advantage in a fiercely contested market. It's about delivering superior value and design at a lower cost.\n\n**4. What's Next?**\nThis innovation is poised to accelerate the trend towards more affordable, higher-quality, and more aesthetically integrated display devices across all sectors. We can expect to see wider adoption in everything from premium smartphones and laptops to mass-market televisions and automotive displays. For investors, this patent highlights a valuable underlying technology that can drive growth and profitability for display manufacturers. For businesses, it signals a pathway to more efficient production and more compelling product designs, potentially setting new industry standards for display assembly and aesthetics in the coming years.","technical_analysis":"The patent \"Display Device and Manufacturing Method Thereof\" (US-9853061) details a significant technical advancement in the construction of display devices, specifically focusing on the electrical interconnection between the array substrate and the color filter substrate. This technical analysis will dissect the underlying architecture, implementation specifics, and the performance implications of this novel conduction mechanism.\n\n**Technical Architecture and Core Innovation:**\nAt the heart of this invention is an integrated conduction structure designed to replace the conventional combination of external connectors (e.g., FPCs, COG) and conductive adhesives (e.g., ACFs). The architecture centers around modifications to the array substrate. The surface of the array substrate is fabricated to include two critical layers:\n\n1.  **Lining Layer:** This layer is deposited or formed on the array substrate. Its geometry and material properties are crucial. It acts as a structural intermediary, providing the necessary elevation and support. The lining layer's height and shape are precisely controlled to ensure proper engagement.\n2.  **Conduction Layer:** This layer is formed on or adjacent to the lining layer. It is composed of a conductive material (e.g., metal, conductive polymer). The key aspect is that the lining layer is designed to physically 'uplift' this conduction layer. This uplift mechanism ensures that when the array substrate and the color filter substrate are assembled in an opposing arrangement, the conduction layer directly contacts the corresponding conductive elements on the color filter substrate.\n\nThis direct, integrated contact eliminates the multiple interfaces and material complexities inherent in traditional adhesive-based connections, leading to a more robust and electrically efficient pathway.\n\n**Implementation Details and Fabrication Considerations:**\nThe manufacturing method described in the Display Device and Manufacturing Method Thereof involves precise patterning and deposition techniques. The lining layer could be formed using photolithography and etching processes to achieve the desired elevated topography. Materials for the lining layer would need to be electrically insulating and mechanically stable, capable of withstanding subsequent processing steps and operational stresses. The conduction layer would then be deposited (e.g., sputtering, evaporation, plating) and patterned on top of or alongside the lining layer, ensuring its conductivity and adhesion.\n\nThe assembly process would then involve aligning the modified array substrate with the color filter substrate. Due to the inherent uplifting mechanism of the lining layer, the conduction layer automatically establishes contact upon assembly, simplifying the alignment requirements compared to adhesive-based bonding where precise pressure and temperature profiles are critical for reliable connection.\n\n**Algorithm Specifics (Conceptual):**\nWhile not an algorithmic patent in the software sense, the 'algorithm' here refers to the precise design and fabrication sequence. The 'algorithm' for achieving effective conduction involves:\n1.  **Topographical Engineering:** Designing the lining layer's height and profile to ensure optimal uplift and contact force.\n2.  **Material Selection:** Choosing materials for the lining and conduction layers that offer excellent mechanical stability, electrical conductivity, and process compatibility.\n3.  **Process Control:** Implementing tight controls during deposition and patterning to achieve uniform layer thickness and precise feature dimensions across the substrate.\n\n**Integration Patterns and Performance Characteristics:**\nThis technology represents a shift towards higher integration at the substrate level. It simplifies the bill of materials (BOM) by removing discrete connectors. From a performance standpoint, the direct contact method is expected to yield:\n*   **Lower Contact Resistance:** Fewer interfaces mean less resistance, leading to improved signal integrity and potentially lower power consumption.\n*   **Enhanced Reliability:** Eliminating adhesive aging, delamination, and connector fatigue improves the long-term stability and durability of the display device.\n*   **Reduced Cross-talk:** A more controlled and integrated conduction path can potentially reduce electromagnetic interference (EMI) and cross-talk.\n\n**Code-Level Implications (Conceptual):**\nWhile this patent is hardware-focused, its implications for software and firmware development for display drivers could be indirect. A more stable and reliable hardware connection might simplify error detection and correction routines in display controllers, potentially allowing for more aggressive clocking or simpler driver implementations due to reduced signal noise. The ability to create ultra-narrow bezels also opens up new possibilities for display firmware to manage edge-to-edge content presentation and touch sensitivity in a more seamless manner.\n\nIn conclusion, the Display Device and Manufacturing Method Thereof offers a technically elegant and highly efficient solution to a fundamental display manufacturing challenge. Its integrated approach promises not only cost savings and simplified production but also enhanced electrical performance and greater design flexibility, particularly for the next generation of sleek, high-performance display devices.","business_analysis":"The patent \"Display Device and Manufacturing Method Thereof\" (US-9853061) presents a compelling business proposition by fundamentally altering the cost structure and design capabilities in the highly competitive display manufacturing industry. This analysis explores the market opportunity, competitive advantages, revenue potential, business models, strategic positioning, and ROI projections for this transformative technology.\n\n**Market Opportunity Size:**\nThe global display panel market is enormous and continues to grow, driven by demand across smartphones, tablets, laptops, monitors, televisions, automotive displays, and emerging IoT devices. Valued in hundreds of billions of dollars, even a fractional improvement in manufacturing efficiency or cost can translate into billions in savings or increased market share. This innovation targets a core component of all these devices, making its addressable market vast and universally applicable across display types (LCD, OLED, etc.). The increasing consumer demand for narrow-bezel and full-screen experiences further amplifies the market for technologies that enable such designs economically.\n\n**Competitive Advantages:**\nThis patent provides several distinct competitive advantages:\n\n1.  **Cost Leadership:** By eliminating the need for expensive external connectors and conductive adhesives, the Display Device and Manufacturing Method Thereof offers a direct path to significantly lower Bill of Materials (BOM) costs. This enables manufacturers to either offer more competitive pricing or achieve higher profit margins.\n2.  **Operational Efficiency:** Reduced machining difficulty and a streamlined manufacturing process lead to higher production yields and faster throughput. This operational efficiency translates into lower labor costs, reduced waste, and quicker time-to-market.\n3.  **Design Differentiation:** The integrated conduction structure facilitates the creation of truly narrow-bezel and potentially bezel-less displays, a highly sought-after aesthetic in consumer electronics. This allows companies to differentiate their products with superior industrial design.\n4.  **Enhanced Reliability:** Fewer components and simpler connections typically lead to greater product reliability and durability, reducing warranty claims and improving brand reputation.\n\n**Revenue Potential and Business Models:**\nCompanies that license or adopt this technology can realize revenue potential through:\n\n*   **Direct Cost Savings:** Immediate savings on materials and manufacturing overhead, directly boosting profitability per unit.\n*   **Increased Sales Volume:** Ability to offer more competitively priced or aesthetically superior products could lead to increased market share and sales volume.\n*   **Premium Pricing:** For early adopters, the unique narrow-bezel capabilities could command a premium in certain market segments.\n\nBusiness models could include: direct implementation by integrated device manufacturers (IDMs), licensing the patent to display panel makers, or forming joint ventures to commercialize the technology. The most lucrative model would likely be internal adoption by major display manufacturers or licensing to multiple players.\n\n**Strategic Positioning:**\nImplementing the Display Device and Manufacturing Method Thereof strategically positions a company as an innovator in display manufacturing. It allows for a defensive position against competitors relying on older, more costly methods, and an offensive position to capture market share in segments demanding advanced aesthetics and cost-efficiency. It supports a strategy of vertical integration for companies seeking greater control over their supply chain and manufacturing costs.\n\n**ROI Projections:**\nWhile specific figures depend on scale and market conditions, the ROI for adopting this technology is projected to be substantial due to the confluence of factors:\n\n*   **Material Cost Reduction:** Potentially 10-20% reduction in connection-related material costs per unit.\n*   **Yield Improvement:** Increase in good product rates by several percentage points, directly impacting overall output.\n*   **Labor and Overhead Savings:** Streamlined processes reduce labor hours and equipment maintenance related to complex assembly.\n*   **Market Share Gains:** The ability to produce more attractive and affordable displays can lead to significant market share expansion over time.\n\nPayback periods for initial R&D and implementation investments could be relatively short, given the high volume nature of display manufacturing. The long-term strategic benefits in design flexibility and market leadership further enhance the ROI.\n\nIn conclusion, the Display Device and Manufacturing Method Thereof offers a clear pathway to enhanced profitability, superior product design, and a strong competitive stance in the global display market. It represents a critical innovation for any company serious about leading the future of display technology.","faqs":[{"answer":"The \"Display Device and Manufacturing Method Thereof\" (US-9853061) is a groundbreaking patent that introduces a novel way to construct display panels. It describes an innovative integrated conduction structure designed to electrically connect the array substrate and the color filter substrate, which are two fundamental layers in any modern screen. Unlike traditional methods that rely on separate connectors and conductive adhesives, this invention integrates the connection directly into the array substrate itself.\n\nSpecifically, the array substrate's surface is equipped with a lining layer and a conduction layer. The lining layer is ingeniously designed to physically uplift the conduction layer until it makes direct contact with the color filter substrate. This direct contact establishes a robust and efficient electrical pathway, streamlining the display assembly process and offering numerous advantages over existing technologies.\n\nThis patent aims to significantly reduce material costs, simplify manufacturing, increase production yields, and enable more aesthetic narrow-bezel designs for display devices. It represents a fundamental shift in display manufacturing, moving towards greater integration and efficiency.","question":"What is Display Device and Manufacturing Method Thereof?"},{"answer":"The core mechanism of the \"Display Device and Manufacturing Method Thereof\" involves a unique integrated conduction structure built directly onto the array substrate. Here's a step-by-step explanation:\n\n1.  **Array Substrate Modification:** The surface of the array substrate, which contains the display's active electronic components, is fabricated with two specific layers.\n2.  **Lining Layer Creation:** A 'lining layer' is formed on the array substrate. This layer is designed with a precise topography, acting as a structural support and an elevational mechanism. Its role is to create a controlled height difference.\n3.  **Conduction Layer Placement:** A 'conduction layer' made of electrically conductive material is then formed on or adjacent to this lining layer.\n4.  **Uplift and Contact:** The key innovation is that the lining layer is engineered to 'uplift' or physically raise the conduction layer. When the array substrate (with its integrated layers) is brought into opposition with the color filter substrate, the uplifted conduction layer makes direct, physical, and electrical contact with the corresponding conductive elements on the color filter substrate.\n\nThis direct contact eliminates the need for traditional external connectors and conductive adhesives, simplifying the electrical pathway and making the connection more robust and efficient. The Display Device and Manufacturing Method Thereof streamlines the assembly and reduces complexity.","question":"How does Display Device and Manufacturing Method Thereof work?"},{"answer":"The \"Display Device and Manufacturing Method Thereof\" patent addresses several critical problems inherent in conventional display manufacturing processes:\n\n1.  **High Material Costs:** Traditional methods require separate, specialized connectors (like FPCs) and conductive adhesives, which add significantly to the bill of materials for each display unit.\n2.  **Manufacturing Complexity and Difficulty:** The precise alignment, bonding, and curing of these discrete components are intricate processes, demanding sophisticated machinery and stringent controls. This increases machining difficulty and overall manufacturing complexity.\n3.  **Low Production Yields:** Errors in alignment or bonding of external connectors frequently lead to defective panels, resulting in a lower rate of good products and increased waste.\n4.  **Design Limitations:** The physical bulk of traditional connectors restricts the ability to achieve the ultra-narrow-bezel and 'full-screen' designs highly desired by modern consumers.\n\nBy offering an integrated conduction solution, the Display Device and Manufacturing Method Thereof effectively solves these issues, leading to more cost-effective, efficient, and aesthetically pleasing display devices.","question":"What problem does Display Device and Manufacturing Method Thereof solve?"},{"answer":"The patent \"Display Device and Manufacturing Method Thereof,\" identified as US-9853061, lists the inventors as [Inventors: Not provided in the prompt]. While the patent document itself would contain the specific names of the inventors, this information was not provided in the prompt. The innovation, however, stems from dedicated research and development in the field of display technology. The assignee, [Assignee: Not provided in the prompt], would typically be the company or entity that owns the rights to this invention.\n\nThis type of innovation is often the result of collaborative efforts by teams of engineers and scientists specializing in materials science, electrical engineering, and display manufacturing processes. The collective expertise aims to overcome existing limitations and push the boundaries of display technology. The Display Device and Manufacturing Method Thereof is a testament to the continuous pursuit of efficiency and performance in the industry.","question":"Who invented Display Device and Manufacturing Method Thereof?"},{"answer":"The \"Display Device and Manufacturing Method Thereof\" offers a multitude of significant benefits that impact both manufacturers and end-users:\n\n1.  **Reduced Production Costs:** By eliminating the need for expensive external connectors and conductive adhesives, this patent significantly slashes material costs and simplifies the assembly process, leading to overall lower production expenses.\n2.  **Increased Manufacturing Efficiency:** The integrated design reduces machining difficulty and streamlines the production flow, resulting in higher throughput and a greater rate of good products (yield).\n3.  **Enables Narrow-Bezel Designs:** The compact, integrated conduction structure facilitates the creation of ultra-narrow-bezel and potentially bezel-less displays, meeting the strong aesthetic demands of modern consumers for sleek, immersive screens.\n4.  **Enhanced Reliability and Durability:** Fewer components and direct electrical contact reduce potential points of failure, leading to more robust and long-lasting display devices.\n5.  **Competitive Advantage:** Manufacturers adopting the Display Device and Manufacturing Method Thereof gain a significant competitive edge through cost savings, improved product design, and higher quality output in the global display market.","question":"What are the key benefits of Display Device and Manufacturing Method Thereof?"},{"answer":"The \"Display Device and Manufacturing Method Thereof\" fundamentally differs from prior art in its approach to connecting display substrates. Traditional methods, or 'prior art,' typically rely on external components like Flexible Printed Circuits (FPCs) or Chip-on-Glass (COG) modules, which are bonded to the display substrates using conductive adhesives (e.g., Anisotropic Conductive Films).\n\nKey differences of the Display Device and Manufacturing Method Thereof include:\n\n1.  **Integrated vs. Discrete Components:** Prior art uses discrete, external connectors and adhesives. This patent integrates the conduction structure directly onto the array substrate, eliminating these separate components.\n2.  **Uplift Mechanism:** The unique 'lining layer' in this invention actively 'uplifts' the conduction layer to make direct contact, a novel mechanical approach not present in prior adhesive-based or compression-only methods.\n3.  **Simplified Assembly:** Prior art requires precise alignment and controlled bonding of multiple components, increasing complexity. The integrated design of the Display Device and Manufacturing Method Thereof simplifies assembly, reducing machining difficulty and potential errors.\n4.  **Cost Structure:** Prior art incurs significant costs for external connectors and adhesives. This patent drastically reduces material costs by eliminating these components.\n5.  **Design Freedom:** The physical bulk of prior art connections limits narrow-bezel designs. This integrated solution enables much thinner bezels, offering greater design flexibility. This innovation represents a significant step forward in display manufacturing technology.","question":"How is Display Device and Manufacturing Method Thereof different from prior art?"},{"answer":"The \"Display Device and Manufacturing Method Thereof\" patent has the potential to impact a wide range of industries that rely heavily on display technology. Its benefits in cost reduction, manufacturing efficiency, and aesthetic design flexibility make it broadly applicable.\n\nKey industries include:\n\n1.  **Consumer Electronics:** This is the most direct impact, affecting manufacturers of smartphones, tablets, laptops, desktop monitors, televisions, and wearables. Consumers will see more affordable, sleek, and reliable devices.\n2.  **Automotive:** Modern vehicles increasingly integrate large, complex displays for infotainment, navigation, and instrument clusters. This innovation can lead to more cost-effective, robust, and aesthetically integrated automotive displays.\n3.  **Industrial and Commercial Displays:** Applications like digital signage, public information displays, point-of-sale terminals, and control panels will benefit from cheaper, more reliable, and potentially more durable screens.\n4.  **Medical Devices:** Displays in medical equipment require high reliability and clarity. The enhanced durability and efficiency of this technology could be advantageous.\n5.  **Augmented/Virtual Reality (AR/VR):** As AR/VR headsets evolve, the demand for compact, high-resolution, and lightweight displays with minimal bezels will grow, making this patent highly relevant.\n\nThe Display Device and Manufacturing Method Thereof promises to drive innovation and efficiency across the entire display ecosystem.","question":"What industries will Display Device and Manufacturing Method Thereof impact?"},{"answer":"The patent \"Display Device and Manufacturing Method Thereof\" (US-9853061) has specific dates associated with its journey through the patent office.\n\n*   **Filing Date:** The patent application for the Display Device and Manufacturing Method Thereof was filed on **2014-04-10**.\n*   **Publication Date:** The patent was subsequently published, meaning it was officially granted and made public, on **2017-12-26**.\n\nThese dates are crucial for understanding the patent's legal lifespan and its position within the timeline of technological advancements in display manufacturing. The period between filing and publication allows for examination by patent authorities and demonstrates the rigorous process an innovation undergoes before being recognized as a protected invention. The publication of the Display Device and Manufacturing Method Thereof marked its official entry into the public domain as a granted patent.","question":"When was Display Device and Manufacturing Method Thereof filed/granted?"},{"answer":"The \"Display Device and Manufacturing Method Thereof\" patent has extensive commercial applications due to its ability to significantly reduce production costs, improve efficiency, and enable advanced product designs. Its core innovation can be leveraged across virtually any product that incorporates a display panel.\n\nPrimary commercial applications include:\n\n1.  **Consumer Electronics Manufacturing:** This technology is ideal for mass-produced devices such as smartphones, tablets, laptops, smartwatches, and high-definition televisions. It allows manufacturers to create more competitive products with lower price points, higher profit margins, and appealing narrow-bezel aesthetics.\n2.  **Display Panel Production:** Companies specializing in the manufacturing of display panels (e.g., LCD, OLED panels) can adopt this method to streamline their fabrication processes, increase yields, and reduce material waste, becoming more competitive suppliers.\n3.  **Automotive Display Systems:** The automotive industry is rapidly integrating sophisticated displays. This patent can lead to more cost-effective, durable, and seamlessly integrated dashboard and infotainment screens.\n4.  **Industrial and Specialized Displays:** For custom display solutions in industrial machinery, medical equipment, and defense applications where reliability and cost-efficiency are critical, the Display Device and Manufacturing Method Thereof offers a robust manufacturing foundation.\n\nIn essence, any business involved in the design, manufacturing, or sales of products featuring displays stands to benefit from the commercial implications of this innovative patent.","question":"What are the commercial applications of Display Device and Manufacturing Method Thereof?"},{"answer":"The \"Display Device and Manufacturing Method Thereof\" patent lays a foundational groundwork for several exciting future developments in display technology. As an integrated solution, it opens doors for further advancements:\n\n1.  **Wider Adoption and Standardization:** We can expect this integrated conduction method to become more widespread, potentially becoming a standard for electrical interconnection in various display types, including flexible and foldable displays.\n2.  **Enhanced Miniaturization:** The principles of the Display Device and Manufacturing Method Thereof could be further refined to enable even greater miniaturization of display bezels, potentially leading to truly seamless, 'all-screen' devices where the display dominates the entire front surface.\n3.  **Integration with Other Functionalities:** The concept of integrating connection layers could extend to other functionalities within the display stack, potentially incorporating sensors or other components directly into the substrate design, leading to more compact and functional modules.\n4.  **Advanced Material Exploration:** Future developments might involve exploring novel materials for the lining and conduction layers to enhance performance, durability, or compatibility with emerging display technologies (e.g., micro-LEDs, quantum dot displays).\n5.  **Impact on Sustainable Manufacturing:** The inherent efficiency and reduced material waste of this method will contribute to more environmentally sustainable display manufacturing practices, aligning with global industry trends towards greener production.\n\nThe Display Device and Manufacturing Method Thereof is a springboard for innovation, promising a future of more advanced, accessible, and aesthetically integrated display experiences.","question":"What are the future developments expected for Display Device and Manufacturing Method Thereof?"}],"topics":["display device","manufacturing method","integrated conduction","narrow-bezel display","display manufacturing cost","relentless","drive","thinner"],"tech_cluster":null},"seo":{"title":"Display Device & Manufacturing Method Thereof - Patent US-9853061","description":"Discover the Display Device and Manufacturing Method Thereof patent. Integrated conduction slashes costs, boosts yield, and enables narrow-bezel displays. Full analysis.","keywords":["display device","manufacturing method","integrated conduction","narrow-bezel display","display manufacturing cost","production yield","array substrate","color filter substrate","patent US-9853061","display innovation","G02F"]},"attribution":{"source":"Patentable","source_url":"https://patentable.app","canonical_url":"https://patentable.app/patents/US-9853061","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-9853061","citation_suggestion":"Patentable. \"Display device and manufacturing method thereof\" (US-9853061). https://patentable.app/patents/US-9853061","copyright_holder":"Nomic Interactive Technology LLC"},"links":{"html":"https://patentable.app/patents/US-9853061","json":"https://patentable.app/api/llm-context/US-9853061","site":"https://patentable.app","llms_txt":"https://patentable.app/llms.txt"},"generated_at":"2026-06-06T12:34:52.915Z"}