TR2024012290A2 - FOOTWEAR WITH NON-SLIP, HEATING AND MASSAGE FUNCTIONS WITH A SOCKS STRUCTURE WITH INTEGRATED SLIPPER SOLE - Google Patents

Abstract

This invention covers an innovation related to a foot garment consisting of a sock and an integrated slipper sole. The invention integrates a slipper sole made of a non-slip, flexible and soft material, preferably polyurethane, at the bottom of a sock. The slipper sole provides safe walking on the ground by offering anti-slip properties and has anti-sweating properties, increasing user comfort. In addition, it supports the user's comfort and physical well-being with its sole heating and massage functions. Thanks to the breathable structure, the breathability of the sole is ensured and its portability is facilitated. This foot garment can be produced for both summer and winter conditions. In addition, it is designed to be used in various environments such as home use, fitness activities, poolsides and seasides, pilgrimage and circumambulation worships. Depending on the need, a single model containing all of these features or various models carrying each feature separately can be produced.

Description

DESCRIPTION: SLIPPER SOLE WITH INTEGRATED SOCK STRUCTURE, NON-SLIP, STATE OF THE ART Today, socks and slippers play an important role in the daily lives of individuals. Socks are generally designed to protect and provide comfort to the feet and are manufactured from a variety of materials. Common sock types include fabrics such as cotton, wool, polyester, and elastane, which offer comfort, breathability, and flexibility. However, existing socks generally lack anti-slip properties, heating, or massage functions. This creates limitations in terms of foot safety and comfort, especially under certain conditions of use. Slippers, on the other hand, are used as footwear that protects and supports the feet and are generally made of rubber, polyurethane, or similar durable materials. While slippers focus on factors such as anti-slip properties and sole stiffness, unlike socks, they generally lack softness, flexibility, and warming functions. Therefore, existing slippers lack comfort and can be uncomfortable, especially with prolonged use. Deficiencies in existing technologies are related to the inadequate functional characteristics that users expect from footwear, both indoors and outdoors. While socks generally offer comfort and breathability, they lack additional functionality such as anti-slip, heating, or massaging. On the other hand, slippers offer anti-slip and durable properties, but they fall short in terms of comfort, softness, flexibility, and warming and massaging functions. This invention was developed to address the shortcomings of existing technologies mentioned above. The invention offers a footwear that enhances user comfort with the anti-slip, flexible, and soft properties of a slipper sole integrated into the bottom of a sock. The slipper sole offers anti-slip properties, while its anti-perspirant structure and heating and massage functions provide additional comfort and physiological relief to the user. Furthermore, the breathable structure ensures the sole's breathability and enhances its portability. This innovative footwear can be manufactured for both summer and winter conditions and is designed for effective use in a variety of environments, including home use, fitness activities, poolsides, and seaside locations. Thus, the invention addresses shortcomings in existing technologies and offers a comprehensive solution for all user needs. Description of the Invention General Description of the Invention This invention encompasses an innovative footwear comprising a slipper sole integrated into the bottom of a sock. The combination of a sock and slipper sole combines the comfort of a sock with the functional features of a slipper sole, providing users with comprehensive comfort and functionality. The sock generally encases the feet and is equipped with a slipper sole made of polyurethane or similar materials. This slipper sole offers anti-slip properties, flexibility, softness, heating functions, and massage functions, as well as a breathable structure that prevents sweating. By combining these features, the invention offers a suitable footwear solution for both indoor and outdoor activities. Technological Field This invention falls within the field of footwear technology, slippers, and comfort-enhancing footbeds, and represents an innovative approach specifically for the integration of sock and slipper soles. By combining the functionality of existing socks and slippers, the invention aims to increase user comfort and safety, thus making a significant contribution to the technological advancements related to footwear. Current Technologies Current socks generally provide comfort and breathability and are designed to enhance foot comfort. However, these socks do not offer anti-slip, heating, or massaging functions. Conversely, current slippers offer anti-slip properties, improving safety, but they do not adequately provide comfort, flexibility, heating, or massaging functions. Shortcomings Current socks do not offer anti-slip, heating, or massaging features, making them inadequate in situations requiring such functions. Current slippers, however, are limited in terms of comfort and flexibility, and do not offer the comfort and additional functions offered by socks. This creates shortcomings in meeting the various needs of users. Technical Specifications and Innovative Elements of the Invention Key Features This invention incorporates a slipper sole manufactured from high-performance polymeric materials within an integrated sock structure. The slipper sole is preferably manufactured from materials such as polyurethane, thermoplastic elastomer (TPE), ethylene-vinyl acetate (EVA), or silicone, each of which offers superior mechanical properties. Polyurethane and similar materials provide high elasticity and excellent shock absorption, increasing the flexibility and softness of the sole. These materials minimize deformation even under dynamic loading, providing a long-lasting and comfortable wearing experience. The polyurethane sole's micro-surface structure features special cuts and grooves that ensure rapid water drainage and a secure grip on wet surfaces. These microstructures on the sole's surface increase slip resistance in both static and dynamic conditions, particularly around baths and pools. This has been confirmed by slip test results in accordance with ASTM (American Society for Testing and Materials) standards. Preventing Unbalanced Loading on the Feet and Knees: The inventive sole structure was developed through a detailed engineering and design process to prevent unbalanced loading on the foot and knee joints. This system is achieved through the placement and strategic positioning of elastomeric shock absorber elements. Elastomeric shock absorbers are designed within the sole's internal structure to effectively absorb pressure and impact on the sole. Elastomeric materials are manufactured from polymer structures with varying hardness levels to optimize the absorption of dynamic loads and shocks. These shock absorber elements are placed in various areas of the sole, ensuring even distribution of loads across the sole. Elastomeric shock absorbers can be manufactured primarily from polyurethane, thermoplastic elastomer (TPE), ethylene-vinyl acetate (EVA), or silicone. These materials possess high elasticity and viscoelastic properties, absorbing impact and pressure and evenly distributing distributed loads. Shock absorbers positioned in various areas of the sole have optimized hardness and density profiles to adapt to different loading conditions. These profiles support the arch and heel area, balancing unbalanced loads. Specifically, the sole's support zones, designed based on orthopedic analysis and biomechanical assessments, target the arch and heel area, ensuring better distribution of loads generated in these areas. The positioning of these support points has been carefully designed to adapt to the foot's anatomy, minimizing pressure on the sole. Additionally, the sole's internal structure contains specially designed shock-absorbing pads to absorb sudden impacts and shocks that occur during dynamic movements. These pads are manufactured from select elastomeric materials to reduce stress on the foot and knee joints and protect joint health during long-term use. The positioning and material selection of the shock-absorbing pads are designed to provide users with optimal comfort and support during their daily activities. These engineering and design elements minimize the unbalanced loads on the foot and knee joints of the sole and increase user comfort. Innovative Elements: This invention includes a special slipper sole structure designed with high engineering principles that is integrated into the sock and slipper combination and incorporates heating and massage functions. PTC (Positive Temperature Coefficient) thin-film heating elements integrated into the sole are placed in a homogeneous distribution using nano-coating methods and lamination technology to be compatible with the elastic structure of the sole. These heating elements are based on a joule heating principle optimized at the micro level and provide temperature regulation as a result of the increase in electrical resistance with temperature. The temperature profile, continuously monitored by the thermistor-based feedback circuit, minimizes temperature differences across the surface of the sole and achieves the desired temperature values within ±0. This ensures that temperatures are reached with 1°C precision. Multilayer composite structures are used between the surfaces to minimize thermal bridging. These structures are composed of graphene-reinforced polymer matrix composite materials, and graphene's high thermal conductivity (N5300 W/m-K) ensures even and homogeneous heat transfer. Heat transfer is modeled according to the Fourier Thermal Conduction Law to prevent local temperature fluctuations on the surface and optimized using FEM (Finite Element Method) analyses. Furthermore, the aerogel layer located between these layers provides both lightweight base and thermal insulation, contributing to minimizing heat loss from the outer surface. The massage function is achieved through piezoelectric ceramic-based vibration motors, which are integrated into the inner layers of the sole using dielectric elastomer actuator (DEA) technology. Piezoelectric motors operate by piezoelectric ceramic discs that undergo mechanical deformation under the influence of an electric field, and the resulting micro-vibrations create a massage effect in the form of a mechanical wave on the sole of the foot. These vibration motors, placed within the sole, are programmed using harmonic vibration modes and transfer energy to reflexology points on the sole at appropriate vibration frequencies (N20 Hz - 60 Hz). Viscoelastic polymer structures and biomechanical modulation methods are used to avoid affecting the sole's elastic structure and mobility. The sole was designed using hyperelastic modeling methods, and these elements were placed according to a specific level of flexibility by anticipating areas subject to deformation under flexion and compression. This ensures the mechanical integration of the heating and vibration elements while preserving all the sole's functions. Furthermore, the geometric arrangement of the heating and massage elements within the sole structure was based on biomimetic principles. For example, based on the fractal geometry of biological structures in nature, the heating element placement patterns were shaped using a Hilbeit curve-based structure to minimize energy consumption and optimize heat dissipation. The massage elements are mounted on the sole with fibroelastic materials, which minimize vibration absorption. The sole's non-slip and breathable properties are achieved through specially developed polyurethane-based microcellular foam materials. This material, thanks to the micro-textures on its surface, has a high coefficient of friction (u2 1.2) and minimizes the risk of slipping. Air permeability is achieved through micro-channels and capillary holes drilled into the underside of the sole, the diameters of which are optimized at the µm scale. To maintain the sole's non-slip and breathable properties, hydrophobic surface coatings coated with secondary nano-coating technology are used. This coating both prevents water permeability and enhances the sole's non-slip performance. These elements, integrated into the sole, are supported by high-density polymer materials and lightweight alloy micro-composites, providing a functional structure without increasing weight. The materials used are analyzed using AI-assisted topology optimization techniques, ensuring maximum mechanical strength with minimal material consumption. This keeps the total weight of the slipper sole below 100 g, increasing user comfort and mobility. This integration is tested with multiphysics simulations to minimize deformation under dynamic loads. The sole's breathable structure is supported by a special airflow system composed of microporous polymer composites positioned within the sole. This system includes integrated air channels and ventilation ports under the sole to optimize air circulation. This structure effectively dissipates accumulated moisture and heat under the sole, accelerating evaporation and ensuring dryness. The porous structure was designed to enhance thermal management and comfort, taking into account the size and distribution of micropores, physical limitations, and airflow dynamics. Functional Advantages: The inventive slipper sole comprehensively enhances user comfort and safety with its anti-slip, anti-perspirant, warming, and massaging functions. The anti-slip function is provided by multiple microstructures and grip patterns located on the sole's underside. These patterns are created by the microstructural properties and surface profile arrangements of the polymer compounds. The anti-slip effect is particularly effective on wet and slippery surfaces. This feature increases the maximum contact with the surface and the coefficient of friction, significantly reducing the risk of slipping. The anti-sweat property is provided by hybrid composite materials with high moisture absorption capacity integrated into the inner surface of the sole. These materials rapidly absorb moisture from the soles of the feet and are supported by special coatings that provide dryness. Thanks to their microstructural properties and capacitance, moisture-absorbing materials accelerate evaporation and inhibit bad odor and bacterial growth, thus increasing comfort. The heating elements work in conjunction with an integrated temperature control unit, which automatically manages heat distribution according to user-defined temperature settings. This management is achieved through a thermoregulation system that optimizes energy efficiency. The massage function increases blood circulation and reduces muscle tension through a continuous massage effect applied to the soles of the users. The movable structure of the massage heads adapts to the dynamic movements of the soles, providing a personalized and targeted massage experience. The positioning of these caps was based on biomechanical analyses and ergonomic evaluations. These innovative features maximize the product's overall performance and user satisfaction by providing increased comfort, safety, and convenience in daily activities. Application Methods of the Invention: Different Models and Application Areas: The invention has been designed in different models and application areas to adapt to various usage conditions. The design of the sock-slipper sole combination offers two main models customized to the user's needs: summer and winter models. Summer Models: Summer models are specifically designed to provide maximum comfort and ease of use in hot weather conditions. These models are made of microporous materials that provide high breathability and are supported by air channels and ventilation ports located in the sole's internal structure. This structure minimizes perspiration and moisture accumulation while maintaining a continuous airflow under the sole, providing a cooling effect. Summer models provide effective anti-slip performance, especially in high humidity and temperature conditions and on wet surfaces like poolsides and seashores. These features minimize the risk of slipping on the sole and provide a safe walking experience. Winter Models: Winter models are designed to effectively provide heating in cold weather conditions. These models are manufactured using materials with integrated heating elements and thermal capacitance properties. This heating function keeps the user's feet warm and reduces the negative effects of cold weather. Winter models are suitable for indoor use, winter sports activities, or outdoor use in winter conditions, while their ventilation systems also ensure effective moisture and sweat management. Conditions of Use: The invention is designed to perform effectively in various environmental conditions. The advantages offered depending on the conditions of use are detailed below: Summer Use: In summer, the invention's sweat-proof structure and high air permeability are effective in minimizing excessive heat and moisture that may occur on the soles of users' feet. Air channels and micropores in the sole increase air circulation, keeping the user's feet cool and preventing moisture accumulation. Furthermore, anti-slip properties ensure safe walking on wet surfaces. Winter Use: During winter months, the invention's integrated heating function works effectively to keep the user's feet warm in cold weather conditions. The heating elements provide targeted heat to the user's feet, minimizing the effects of cold weather and increasing comfort. Thermal capacitance and temperature control systems in the sole stabilize temperature levels, providing the user with flexibility in terms of temperature regulation. General Application Areas: The invention can be used effectively in the home, for fitness activities, and in various outdoor environments (e.g., poolsides, seasides). In domestic use, the invention's comfort and heating features enhance comfort and allow users to use it for extended periods. In fitness activities, the sole's anti-slip properties and massage function provide increased performance and muscle relaxation, providing users with better support during exercise. In outdoor settings such as poolsides and seaside areas, the sole's water-resistant properties and anti-slip structure provide a safe walking experience and perform effectively on wet surfaces. These comprehensive design and functional features enable the invention to deliver high performance and enhance user comfort in a variety of environments and usage conditions. Application Examples: Practical applications of the invention in various areas of use demonstrate the invention's versatility and functionality in various environmental conditions. The following example applications summarize the advantages and benefits of the invention based on its intended use. 1. Domestic Use: The invention's greatest advantage for domestic use is its non-slip base, which minimizes the risk of users slipping on floors. The slip-resistant base, particularly on surfaces such as parquet, tile, and marble, contributes to increased safety within the home. Furthermore, the invention's breathable structure prevents foot sweat during extended use and increases comfort. In winter, integrated heating elements keep feet warm, allowing for comfortable use even on cold floors. 2. Use in Fitness Centers: The invention offers a solution focused on both hygiene and performance in fitness centers. The slipper sole's flexible structure provides flexibility and comfort for feet during fitness activities, while the anti-slip coating on the sole ensures a secure grip on sports equipment and floors. The sole's elastomeric material prevents unbalanced loads on feet and joints during sudden movements, thus preventing injuries that may occur during sports. Furthermore, its sweat-reducing structure keeps feet dry during sports activities, increasing user comfort. 3. Poolside Use: The greatest advantage of the invention on wet and slippery surfaces, such as poolsides, is its water-resistant and non-slip sole. Microwave structures integrated into the sole ensure rapid water drainage, increasing slip resistance. Additionally, the invention's quick-drying feature ensures that the sock and sole dry quickly after use on wet surfaces, thus maintaining the user's comfort and safety. 4. Use on Seashores: Safe and comfortable use is offered on various surfaces such as sand, water, and wet surfaces on seashores. The sole's flexible and water-resistant structure provides resistance to seawater and salty environmental conditions, while also protecting the feet from hot sand and hard surfaces. Furthermore, the invention's ergonomic design ensures that feet remain comfortable during long walks by the sea, thus providing the user with extra comfort. The sole's lightweight and flexible structure facilitates easy carrying and offers practical use in environments such as beaches. Use in Islamic Prayers such as Hajj and Tawaf: The invention offers a solution specifically optimized for use during Islamic prayers such as Hajj and Tawaf. In this context, the invention's greatest advantage is maintaining safe and comfortable ground contact during walking. The sole's non-slip structure provides high traction performance on both flat and sloping surfaces, minimizing the risk of slipping during prayer. Especially in crowded and variable ground conditions, the sole's micro-textured surface ensures safe footing. The sole's quick-drying and waterproof properties provide effective protection against puddles or ground moisture that may occur during prayer. These features allow the sole to dry quickly in wet environments and maintain hygienic conditions. Its breathable structure keeps feet refreshed during extended use, preventing discomfort and sweating. Additionally, the ergonomic design of the sole has been developed to support the dynamic movements of the feet, offering high flexibility and support to ensure feet remain comfortable during prayer. The lightweight structure of the sole facilitates easy carrying and provides comfortable use without adding additional weight during prayer. Thus, slippers integrated with this sole enhance user comfort during religious practices such as Hajj and Tawaf, supporting the healthy and peaceful performance of these sacred duties. These sample applications demonstrate the invention's functional and safety advantages in various usage conditions and demonstrate that its versatility offers a wide range of applications. Process of Integrating the Sock and Slipper Sole: In this invention, the process of integrating the slipper sole into the sock structure is achieved through a multilayer lamination process. The bottom of the sock contains a sole composed of elastomeric materials or high-performance synthetic polymers such as thermoplastic polyurethane (TPU) and ethylene-vinyl acetate (EVA). This sole is directly integrated into the sock structure using high-frequency thermal bonding or ultrasonic welding. These methods provide a high-strength and flexible bond without damaging the fabric of the sock. When integrating the slipper sole into the sock structure, nanoscale adhesive materials are used to ensure the bond between the two surfaces is permanent. Nanoscale adhesives form a very thin adhesive layer between the sock surface and the sole material, maintaining the materials' flexibility and minimizing the risk of separation. These adhesives are particularly resistant to perspiration, heat, and moisture, ensuring long-term durability between the sock and sole. The custom molding of the slipper sole to ensure ergonomic and anatomical fit with the sock structure is also a crucial component of the integration process. The sole is shaped to the bottom of the sock using injection molding. Injection molding ensures a perfect fit of the sole to the sock structure and provides support consistent with the natural curves of the sole. The molds used in this process ensure the sole is optimally positioned within the sock structure, eliminating any gaps or the risk of slipping. Furthermore, the air channels and microporous structures integrated into the sole structure are positioned to ensure complete compatibility with the sock material. These air channels support the sock's breathability and sweat-reducing properties, and contribute to the thermal balance of the integrated sole. This structure prevents overheating in the summer and enhances user comfort in the winter. Finally, the anti-slip coatings used during the integration of the sole into the sock ensure safe use, especially in bathrooms, poolsides, and other wet surfaces. When these coatings are applied to the sock surface, a homogeneous surface is created between the sock fabric and the anti-slip material using special plasma coating or vacuum vapor deposition technologies. This surface maintains a high coefficient of friction even when in contact with water, ensuring safe walking. The materials, techniques, and structures discussed in the invention should not be considered binding agents. The intended functions can be achieved by using different techniques and materials.TR TR TR TR TR TR TR TR TR