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About this Item:
1. Antimicrobial Moisture-Wicking Surface Layer
· Material: This layer uses a special moisture-wicking, antimicrobial fabric that is environmentally friendly, durable, and highly breathable. It is made from yarn treated for waterproof and mold resistance.
· Material Properties: The special cross-porous design and antimicrobial treated fibers create a breathable yet moisture-wicking surface. Even under heavy perspiration, sweat moves through the porous structure into the 3D breathable layer beneath, ensuring the surface remains dry.
· Design Features and Functional Benefits:
o Porosity and Structural Design: The fabric features a 50-60% porosity rate, providing excellent breathability with over 95% moisture permeability. The material can wick away sweat in just 1-3 seconds, keeping feet dry during intense physical activities.
o Antimicrobial and Odor-Resistant: The antimicrobial properties help maintain foot hygiene and odor control, ensuring comfort throughout prolonged basketball games.
2. 3D-Printed Breathable Layer
· Material: Made from 99% antimicrobial TPU (thermoplastic polyurethane).
· Material Characteristics: TPU combines flexibility, elasticity, and durability. The antimicrobial additives inhibit bacterial and fungal growth, providing added health protection.
· Design Features:
o Porosity and Structure: The 3D-printed layer has a porosity of 65-75%, with a thickness of 1.2mm, offering both lightweight and high breathability. This layer includes over 2.33 million micro-pores, ensuring even air circulation.
o Layered Structure: The multi-layered 3D printing design provides support and cushioning, optimizing comfort and airflow.
o Customization: The 3D printing technology allows customization based on individual foot contours, ensuring an ergonomic fit.
· Functional Benefits:
o Breathability: The 3D micro-porous structure ensures continuous airflow, allowing rapid sweat evaporation and maintaining foot dryness.
o Antimicrobial Protection: The antimicrobial additives effectively control odor by reducing bacterial growth.
o Cushioning and Comfort: The natural cushion zones absorb impact, reducing foot pressure, providing comfort during high-intensity activities.
o Temperature Regulation: Enhanced airflow helps cool the feet during warm conditions, while keeping them warm in colder environments.
o Customization: Customization enhances comfort by providing an optimized fit that reduces friction and pressure.
3. Moisture Absorption and Massage Layer
· Material: This layer is made of a special foam with an open-cell structure and a 280% absorption rate.
· Material Properties: The foam material effectively absorbs and locks in sweat, ensuring that the insole remains dry.
· Design Features:
o Pyramid Surface Structure: The surface is covered with pyramid-shaped protrusions, significantly increasing the contact area with the foot and boosting absorption efficiency.
o Micro-Channel Design: Small channels between the pyramid structures enhance lateral moisture distribution and ensure even absorption throughout the insole.
· Functional Benefits:
o Quick Moisture Absorption: The pyramid structure helps absorb moisture faster, keeping feet dry.
o Massage Effect: The pyramid-shaped protrusions provide a gentle massage to the feet, stimulating nerves and promoting blood circulation.
o Pressure Reduction: The pyramid design helps distribute foot pressure evenly, reducing concentrated stress points and enhancing comfort during physical activity.
4. Quick-Drying Layer
· Material and Design: The quick-drying layer features 800-1000 specific drainage holes combined with a 3D-printed Laval system. The funnel-shaped Laval structure ensures water flows downwards and prevents upward wicking, allowing for rapid drying.
· Functional Benefits:
o Quick Drying: The specific design of the drainage holes quickly expels water, allowing the insoles to be worn immediately after washing.
o Laval System: This system accelerates moisture removal through aerodynamic principles, ensuring a dry and comfortable experience.
o Comfort and Health: The downward flow of moisture prevents bacteria growth, maintaining a healthy and comfortable foot environment.
5. Automatic Air-Drying System
· Design: The insole base includes 32 airbags, 12 air ducts, and over 2,000 micro-scale 3D-printed Laval structures, producing 4-6 mL of airflow per step.
· Working Principle:
o Airflow Channels: The airflow system accelerates the evaporation of absorbed moisture. The combination of pressure and heat generated from movement (42-45°C) effectively promotes rapid drying.
o Pressure-Driven Circulation: The 32 airbags and ducts work together to channel airflow, maintaining a dry insole.
· Functional Benefits:
o Efficient Airflow Expulsion: The automatic drying system removes moisture quickly and maintains foot comfort, significantly reducing dampness during sports activities.
6. Customizable Functional Inserts
· Material Selection: Custom inserts include options like Ortholite foam, high-rebound materials, ACF (advanced cushioning foam), and silicone.
· Functional Description:
o High-Support Inserts: Suitable for scenarios requiring greater arch support, especially for athletes.
o Shock-Absorbing Inserts: Made from ACF, these inserts reduce the impact on the feet and knees, minimizing fatigue.
o High-Rebound Inserts: Enhance agility, making each step more powerful.
o Combination Options: Inserts can be mixed to cater to individual needs, enhancing the overall insole function for specific scenarios.
7. Health and Therapy Features
· Therapeutic Materials: The insole can be customized with various therapeutic materials, such as energy chips, magnets, and terahertz elements.
· Design Features:
o Independent Airbag Structure: An airbag located in the center of the insole helps position therapeutic elements effectively for maximum benefit.
· Functional Benefits:
o Enhanced Circulation: Heat-generating chips promote blood flow and relieve fatigue.
o Antimicrobial Ion Balls: Help suppress bacterial growth and maintain freshness.
o Energy Balance: Grounding chips release negative ions, helping reduce stress.
8. Medicated Patch Application
· Patch Types: Different medicated patches can be added to the insole for specific health needs, such as muscle enhancement or pain relief.
· Application Method: Patches are inserted into a specially designed airbag that releases active ingredients through the foot's pores, aided by body heat.
· Functional Benefits:
o Health Management: Patches target specific needs like weight loss or muscle gain, providing effective therapy through foot absorption.
9. Micro-Intelligent Arch Support and Carbon Plate Stability
· Design: The insole includes an ergonomic arch groove and protruding arch support to offer optimal stability for various foot types.
· Carbon Plate Integration: Carbon plates enhance support and efficiency for athletes.
· Applicable Athletes:
o Flatfoot Athletes: The arch protrusion helps relieve foot fatigue.
o Wide/Narrow Foot Types: Adaptive groove design offers individual comfort.
Summary
These basketball insoles combine advanced multi-layer construction, high-performance materials, and ergonomic design to address the diverse needs of basketball athletes. The features, such as moisture-wicking antimicrobial layers, customizable inserts, an automatic drying system, therapeutic benefits, and carbon plate integration, provide optimal support, comfort, and health benefits for athletes during high-impact sports activities.
The insole design keeps the athlete's feet dry, comfortable, and supported while reducing the risks of injury and enhancing overall performance during intense basketball games.
Frequently Asked Questions
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+ -How do I know VKTRY Insoles will fit my shoes?
+ -How are VKTRY Insoles customized for each athlete?
+ -Do VKTRY Insoles come in different widths or arch types?
+ -If I am on the border of a weight level, should I go up or down?
+ -If I sometimes wear a 9.5 shoe size and in other shoes wear a 10, what size VK should I order?
+ -What is VKTRY’s warranty policy?
+ -Do you offer product exchanges?
+ -Still have questions?
+ -89%would recommend these products
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About this Item
Table Format
Targeted Design
1. Antimicrobial Moisture-Wicking Surface Layer
· Material: This layer uses a special moisture-wicking, antimicrobial fabric that is environmentally friendly, durable, and highly breathable. It is made from yarn treated for waterproof and mold resistance.
· Material Properties: The special cross-porous design and antimicrobial treated fibers create a breathable yet moisture-wicking surface. Even under heavy perspiration, sweat moves through the porous structure into the 3D breathable layer beneath, ensuring the surface remains dry.
· Design Features and Functional Benefits:
o Porosity and Structural Design: The fabric features a 50-60% porosity rate, providing excellent breathability with over 95% moisture permeability. The material can wick away sweat in just 1-3 seconds, keeping feet dry during intense physical activities.
o Antimicrobial and Odor-Resistant: The antimicrobial properties help maintain foot hygiene and odor control, ensuring comfort throughout prolonged basketball games.
2. 3D-Printed Breathable Layer
· Material: Made from 99% antimicrobial TPU (thermoplastic polyurethane).
· Material Characteristics: TPU combines flexibility, elasticity, and durability. The antimicrobial additives inhibit bacterial and fungal growth, providing added health protection.
· Design Features:
o Porosity and Structure: The 3D-printed layer has a porosity of 65-75%, with a thickness of 1.2mm, offering both lightweight and high breathability. This layer includes over 2.33 million micro-pores, ensuring even air circulation.
o Layered Structure: The multi-layered 3D printing design provides support and cushioning, optimizing comfort and airflow.
o Customization: The 3D printing technology allows customization based on individual foot contours, ensuring an ergonomic fit.
· Functional Benefits:
o Breathability: The 3D micro-porous structure ensures continuous airflow, allowing rapid sweat evaporation and maintaining foot dryness.
o Antimicrobial Protection: The antimicrobial additives effectively control odor by reducing bacterial growth.
o Cushioning and Comfort: The natural cushion zones absorb impact, reducing foot pressure, providing comfort during high-intensity activities.
o Temperature Regulation: Enhanced airflow helps cool the feet during warm conditions, while keeping them warm in colder environments.
o Customization: Customization enhances comfort by providing an optimized fit that reduces friction and pressure.
3. Moisture Absorption and Massage Layer
· Material: This layer is made of a special foam with an open-cell structure and a 280% absorption rate.
· Material Properties: The foam material effectively absorbs and locks in sweat, ensuring that the insole remains dry.
· Design Features:
o Pyramid Surface Structure: The surface is covered with pyramid-shaped protrusions, significantly increasing the contact area with the foot and boosting absorption efficiency.
o Micro-Channel Design: Small channels between the pyramid structures enhance lateral moisture distribution and ensure even absorption throughout the insole.
· Functional Benefits:
o Quick Moisture Absorption: The pyramid structure helps absorb moisture faster, keeping feet dry.
o Massage Effect: The pyramid-shaped protrusions provide a gentle massage to the feet, stimulating nerves and promoting blood circulation.
o Pressure Reduction: The pyramid design helps distribute foot pressure evenly, reducing concentrated stress points and enhancing comfort during physical activity.
4. Quick-Drying Layer
· Material and Design: The quick-drying layer features 800-1000 specific drainage holes combined with a 3D-printed Laval system. The funnel-shaped Laval structure ensures water flows downwards and prevents upward wicking, allowing for rapid drying.
· Functional Benefits:
o Quick Drying: The specific design of the drainage holes quickly expels water, allowing the insoles to be worn immediately after washing.
o Laval System: This system accelerates moisture removal through aerodynamic principles, ensuring a dry and comfortable experience.
o Comfort and Health: The downward flow of moisture prevents bacteria growth, maintaining a healthy and comfortable foot environment.
5. Automatic Air-Drying System
· Design: The insole base includes 32 airbags, 12 air ducts, and over 2,000 micro-scale 3D-printed Laval structures, producing 4-6 mL of airflow per step.
· Working Principle:
o Airflow Channels: The airflow system accelerates the evaporation of absorbed moisture. The combination of pressure and heat generated from movement (42-45°C) effectively promotes rapid drying.
o Pressure-Driven Circulation: The 32 airbags and ducts work together to channel airflow, maintaining a dry insole.
· Functional Benefits:
o Efficient Airflow Expulsion: The automatic drying system removes moisture quickly and maintains foot comfort, significantly reducing dampness during sports activities.
6. Customizable Functional Inserts
· Material Selection: Custom inserts include options like Ortholite foam, high-rebound materials, ACF (advanced cushioning foam), and silicone.
· Functional Description:
o High-Support Inserts: Suitable for scenarios requiring greater arch support, especially for athletes.
o Shock-Absorbing Inserts: Made from ACF, these inserts reduce the impact on the feet and knees, minimizing fatigue.
o High-Rebound Inserts: Enhance agility, making each step more powerful.
o Combination Options: Inserts can be mixed to cater to individual needs, enhancing the overall insole function for specific scenarios.
7. Health and Therapy Features
· Therapeutic Materials: The insole can be customized with various therapeutic materials, such as energy chips, magnets, and terahertz elements.
· Design Features:
o Independent Airbag Structure: An airbag located in the center of the insole helps position therapeutic elements effectively for maximum benefit.
· Functional Benefits:
o Enhanced Circulation: Heat-generating chips promote blood flow and relieve fatigue.
o Antimicrobial Ion Balls: Help suppress bacterial growth and maintain freshness.
o Energy Balance: Grounding chips release negative ions, helping reduce stress.
8. Medicated Patch Application
· Patch Types: Different medicated patches can be added to the insole for specific health needs, such as muscle enhancement or pain relief.
· Application Method: Patches are inserted into a specially designed airbag that releases active ingredients through the foot's pores, aided by body heat.
· Functional Benefits:
o Health Management: Patches target specific needs like weight loss or muscle gain, providing effective therapy through foot absorption.
9. Micro-Intelligent Arch Support and Carbon Plate Stability
· Design: The insole includes an ergonomic arch groove and protruding arch support to offer optimal stability for various foot types.
· Carbon Plate Integration: Carbon plates enhance support and efficiency for athletes.
· Applicable Athletes:
o Flatfoot Athletes: The arch protrusion helps relieve foot fatigue.
o Wide/Narrow Foot Types: Adaptive groove design offers individual comfort.
Summary
These basketball insoles combine advanced multi-layer construction, high-performance materials, and ergonomic design to address the diverse needs of basketball athletes. The features, such as moisture-wicking antimicrobial layers, customizable inserts, an automatic drying system, therapeutic benefits, and carbon plate integration, provide optimal support, comfort, and health benefits for athletes during high-impact sports activities.
The insole design keeps the athlete's feet dry, comfortable, and supported while reducing the risks of injury and enhancing overall performance during intense basketball games.
Here's the detailed product features and descriptions for the basketball insoles, presented in a table format:
| Layer | Material | Material Characteristics | Design Features | Functional Benefits |
| Antimicrobial Moisture-Wicking Surface Layer | Environmentally Friendly Antimicrobial Yarn | Special cross-porous design, antimicrobial, durable, porosity of 50-60%, quick moisture-wicking. | Woven with waterproof yarn, moisture permeable, wicks away moisture in 1-3 seconds, keeps the surface dry. | High breathability, waterproof, odor-resistant, quick absorption, keeps feet dry, suitable for intense basketball activities. |
| 3D-Printed Breathable Layer | Antimicrobial TPU | TPU combines softness, elasticity, and durability, with antimicrobial additives to inhibit bacterial growth. | 3D-printed micro-porous structure with 65-75% porosity, over 2.33 million micro-pores, multi-layer structure for breathability and support. | Continuous airflow, antimicrobial, odor-resistant, cushioning, temperature regulation, reduced foot moisture, high comfort, customizable fit. |
| Moisture Absorption and Massage Layer | High-Efficiency Absorptive Foam | Open-cell structure with a 280% absorption rate, quickly absorbs and locks in moisture. | Pyramid surface structure increases contact area; small channels enhance lateral moisture spread, boosting absorption efficiency. | Quick moisture absorption to keep feet dry; gentle massage effect to promote blood circulation; effective pressure distribution, enhancing comfort during activities. |
| Quick-Drying Layer | Drainage Holes + 3D-Printed Laval System | Drainage holes and inverted funnel Laval structures quickly guide water downward, preventing upward wicking. | 800-1000 drainage holes for rapid water expulsion, no drying needed. | Rapid drying, ready to wear immediately after washing, good ventilation, reduces bacterial growth, ideal for humid environments after basketball activities. |
| Automatic Air-Drying System | Airbags + Airflow Channels + Laval Structures | 32 airbags, 12 airflow channels, and over 2,000 Laval microstructures generate 4-6 mL of airflow per step for automatic drying. | Laval system channels accelerate air movement; pressure from the airbags expels moisture, combined with body heat to enhance drying. | Automatic drying keeps insoles and shoes dry, reducing foot dampness and heat, providing comfort for long-duration basketball activities. |
| Customizable Functional Inserts | Ortholite Foam, High Rebound Materials, ACF | Various materials for different functions: Ortholite for support, high rebound materials for elasticity, ACF for shock absorption. | Inserts can be customized and positioned in the forefoot or heel to meet specific basketball needs, offering personalized functionality. | Custom combinations for support, cushioning, or elasticity, improving comfort and performance; suitable for different basketball athletes' needs. |
| Health and Therapy Features | Vortex Energy Chips, Terahertz Discs, Magnetic Balls | High-tech materials combining modern technology and traditional therapy, offering personalized health support for athletes. | Independent airbag structure to position therapeutic materials effectively, providing contact with foot reflex zones, enhancing therapeutic effects. | Boost immunity, promote circulation, antimicrobial, energy balance, ideal for basketball athletes with frequent activity. |
| Medicated Patch Application | Herbal, Western, Tibetan Medicine, etc. | Various medicated patches for health needs, such as muscle enhancement, therapy, and others. | Medicated patches inserted into airbag, release active ingredients through foot pores aided by temperature and air flow. | Continuous release of medication to enhance therapy, achieve goals like weight management, muscle gain; high absorption efficiency, gentle, and non-harmful. |
| Micro-Intelligent Arch Support & Carbon Plate Stability | Arch Groove + Arch Protrusion + Carbon Plate | Ergonomic arch groove design with arch support, and carbon plate integration to enhance stability and efficiency for basketball athletes with different foot types. | Arch protrusion to fit foot arch, central groove for pressure relief, adaptive heel cup, carbon plate for increased support. | Suitable for flat feet, wide/narrow foot types, providing effective support, stability, and comfort during long-term basketball activities, especially for positions like center and power forward. |
This table clearly outlines each layer's materials, design features, and corresponding functional benefits, providing a comprehensive understanding of the superior features of these basketball insoles.
Here's a comparison table between our basketball insoles and other brands on the market:
| Comparison Item | Our Developed Basketball Insoles | Other Brand Basketball Insoles |
| Materials | Multi-layer construction, combining antimicrobial moisture-wicking fabrics, 3D-printed antimicrobial TPU layer, high-absorption foam layers, customizable materials like Ortholite foam and high-rebound materials. | Primarily use EVA foam, polyurethane, and simple fabrics with limited antimicrobial properties and simpler multi-layer structures. |
| Antimicrobial & Odor Resistance | Uses antimicrobial fabrics and antimicrobial TPU to inhibit bacterial and fungal growth, reducing odor and maintaining foot hygiene. | Most brands lack antimicrobial treatment, leading to bacterial growth and odor after extended use. |
| Breathability | 3D-printed breathable layer with over 2.33 million micro-pores and 65-75% porosity, combined with quick-drying layer for superior airflow and circulation. | Most brands lack 3D-printed micro-porous structures, with average breathability leading to trapped moisture and sweaty feet. |
| Moisture Absorption | Moisture-absorbing foam with an open-cell structure and pyramid surface design, offering 280% absorption rate, ensuring fast moisture removal. | Most insoles use basic foam with limited moisture absorption, leading to dampness after prolonged use. |
| Quick Drying Feature | Equipped with 800-1000 drainage holes and a 3D-printed Laval system for rapid drying, allowing the insoles to be worn immediately after washing. | Other insoles typically lack a quick-dry feature, requiring time to air dry before reuse. |
| Automatic Air-Drying System | Includes 32 airbags, 12 air ducts, and over 2,000 micro-scale 3D-printed Laval structures, generating 4-6 mL of airflow per step for automatic drying. | Most brands do not have an automatic air-drying system, leading to moisture retention post-activity. |
| Support & Cushioning | Customizable inserts (Ortholite, high-rebound, ACF) offer personalized support, cushioning, and rebound, suitable for different athletic needs. | Most insoles use standard foam without customization options, lacking support for specific athletic needs. |
| Health & Therapy Features | Customizable with therapeutic materials like energy chips, magnets, and terahertz elements to promote blood circulation, antimicrobial action, and stress reduction. | Few brands offer health-focused features, such as therapy or additional health benefits. |
| Massage Effect | Pyramid surface design provides a gentle massage, stimulating blood circulation and relieving foot fatigue. | Most insoles lack a dedicated massage structure, offering limited foot stimulation or circulation improvement. |
| Customization | 3D printing allows for customization based on individual foot shape, offering an ergonomic fit that reduces friction and pressure. | Most brands offer standardized insoles with limited customization, unable to cater to unique foot shapes. |
| Target Audience | Suitable for various foot types, especially flat feet, wide/narrow feet, and athletes with specific needs, offering micro-intelligent arch support and carbon plate stability. | Typically designed for average foot types, unable to offer optimal support for those with specific foot conditions (e.g., flat feet). |
| Quick Drying & Comfort | Rapid drying through the automatic air-drying system and breathable layers, keeping feet dry and comfortable during extended activities. | Other insoles lack quick-drying systems, often resulting in discomfort and dampness after physical activities. |
| Price | Advanced materials, complex design, and therapeutic features result in a higher price point. | Generally lower-priced, but with limitations in breathability, antimicrobial features, and overall functionality. |
| Durability | Made with high-quality materials like Ortholite foam and TPU, offering a longer lifespan and stable performance. | Average durability; regular foam insoles tend to compress and lose their effectiveness after prolonged use. |
This comparison highlights that our developed basketball insoles outperform other brands in several key areas, including breathability, antimicrobial properties, moisture absorption, quick drying, support, and health benefits. These advanced features provide athletes with enhanced comfort, performance, and foot protection, reducing the risk of injury and improving overall comfort during intense basketball games.
Targeted Design for Basketball Positions: Forefoot and Rearfoot Inserts
Based on the unique demands of basketball roles, the following design and analysis outline the forefoot inserts and rearfoot inserts tailored to each role. These considerations incorporate the dynamic requirements of basketball, positional characteristics, and optimized lattice and cushioning materials.
1. Point Guard (PG)
Forefoot Insert Design
· Requirements Analysis:
o Frequent use for quick cuts, rapid starts, and stops. Lightweight flexibility and grip are crucial.
o Needs enhanced lateral support to prevent sliding.
· Design Highlights:
o Lattice Angle:
· 45° diagonal lattice: Provides multidirectional dynamic support for both lateral and vertical pressure.
· Dual-layer lattice: Upper flexible lattice (65A TPU) and lower rigid lattice (75A TPU) for quick rebound.
o Structural Optimization:
· V-shaped dynamic support structure: Enhances propulsion during starts.
· Micro wave-like texture on the surface for improved grip.
· Material Selection:
o Base Layer: High-rebound TPU, 70A hardness.
o Surface: Lightweight EVA or soft foam for added comfort.
Rearfoot Insert Design
· Requirements Analysis:
o Rearfoot cushioning is needed to absorb impact during sudden stops and stabilize the arch.
· Design Highlights:
o Lattice Angle:
· 60° diagonal lattice: Strengthens lateral compression resistance and protects the ankle.
· Embedded micro air chambers to enhance cushioning performance.
o Structural Optimization:
· Honeycomb shock-absorbing lattice: Distributes landing impact evenly in the heel area.
· Embedded "rebound pillars" to enhance energy feedback during take-off.
· Material Selection:
o Base Layer: High-cushioning EVA, 55A hardness.
o Surface: Rigid TPU for added stability.
2. Shooting Guard (SG)
Forefoot Insert Design
· Requirements Analysis:
o Maximized vertical jump capability while ensuring quick sprints.
· Design Highlights:
o Lattice Angle:
· 80° upright lattice: Optimized for vertical rebound and jump efficiency.
· Localized 65° diagonal lattice for multidirectional flexibility.
o Structural Optimization:
· Elastic wave lattice: Boosts cushioning, protecting the toe area.
· Centralized high-rebound spring lattice module to enhance energy return.
· Material Selection:
o Base Layer: High-elastic Pebax or TPU, 70A hardness.
o Surface: Ultra-thin flexible foam for reduced pressure on the sole.
Rearfoot Insert Design
· Requirements Analysis:
o Enhanced landing cushioning to protect knees and ankles.
· Design Highlights:
o Lattice Angle:
· 90° upright lattice: Maximizes shock absorption.
· Embedded dynamic cushioning air chambers to adapt to pressure changes.
o Structural Optimization:
· Multidimensional trapezoidal lattice to dissipate impact.
· High-rebound material inserts for efficient energy recovery post-landing.
· Material Selection:
o Base Layer: High-cushioning EVA, 60A hardness.
o Middle Layer: Dynamic air chambers for enhanced cushioning.
3. Small Forward (SF)
Forefoot Insert Design
· Requirements Analysis:
o Balances flexibility and explosive power to support versatile roles.
· Design Highlights:
o Lattice Angle:
· 70° diagonal lattice: Balances lateral and vertical performance for flexibility.
· External 55° small lattice pillars for enhanced lateral support.
o Structural Optimization:
· Integrated "wave-honeycomb" lattice for lightweight cushioning and high rebound.
· Localized grip-enhancing textures to prevent slipping.
· Material Selection:
o Base Layer: High-elastic TPU, 65A hardness.
o Surface: Soft EVA for enhanced comfort.
Rearfoot Insert Design
· Requirements Analysis:
o Emphasizes cushioning and multidirectional stability for quick transitions between offense and defense.
· Design Highlights:
o Lattice Angle:
· 60° and 90° gradient lattice: Balances lateral stability and vertical cushioning.
· Embedded honeycomb support modules to boost stability.
o Structural Optimization:
· Central ring-shaped support frame to minimize deformation during landing.
· Localized micro anti-twist lattice to prevent ankle rollover.
· Material Selection:
o Base Layer: High-cushioning EVA, 55A hardness.
o Surface: High-rebound TPU.
4. Power Forward (PF)
Forefoot Insert Design
· Requirements Analysis:
o High cushioning and support performance to handle physical play.
· Design Highlights:
o Lattice Angle:
· 60° and 90° combined lattice: Enhances lateral stability on the periphery while boosting rebound in the center.
· Reinforced lattice along the edges to prevent compression collapse.
o Structural Optimization:
· Dual-layer compression-resistant lattice: Lower rigid lattice for support, upper flexible lattice for cushioning.
· Material Selection:
o Base Layer: High-strength TPU, 70A hardness.
o Surface: High-cushioning EVA.
Rearfoot Insert Design
· Requirements Analysis:
o Maximized impact absorption while maintaining stability.
· Design Highlights:
o Lattice Angle:
· 90° vertical lattice: Primary shock absorption to relieve knee pressure.
· Peripheral honeycomb structure for anti-twist performance.
o Structural Optimization:
· Gradual zoning lattice: Central cushioning and peripheral stability.
· Material Selection:
o Base Layer: High-cushioning EVA with carbon plate.
o Surface: Soft TPU.
5. Center (C)
Forefoot Insert Design
· Requirements Analysis:
o Moderate cushioning and support for strength-based movements.
· Design Highlights:
o Lattice Angle:
· 70° diagonal lattice: Enhances lateral stability for post moves.
o Structural Optimization:
· Localized embedded support pillars for added anti-twist capacity.
· Material Selection:
o High-strength TPU, 70A hardness.
Rearfoot Insert Design
· Requirements Analysis:
o Maximized cushioning to protect joints.
· Design Highlights:
o Lattice Angle:
· 90° vertical lattice: Absorbs landing impact.
· Embedded honeycomb cushioning chambers for enhanced shock absorption.
o Structural Optimization:
· Multi-layer cushioning framework with external dynamic support lattice.
· Material Selection:
o High-cushioning EVA with honeycomb air chambers, 55A hardness.
Summary Table
| Position | Forefoot Lattice Angle | Rearfoot Lattice Angle | Key Features |
| Point Guard | 45° diagonal | 60° diagonal | High agility for multidirectional movements. |
| Shooting Guard | 80° upright | 90° upright | Vertical explosiveness and quick rebounds. |
| Small Forward | 70° diagonal | 60° & 90° gradient | Balanced flexibility and cushioning. |
| Power Forward | 60° & 90° combined | 90° upright | Enhanced support for physical confrontations. |
| Center | 70° diagonal | 90° upright | High stability and shock absorption. |
This design framework tailors lattice angles and structures to meet the specific needs of basketball roles, optimizing performance and protection.
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