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株式会社シンセルニューマテリアル

  Suzhou Shincell New Material Co., Ltdは中国の 軽量ポリマーフォームメーカー熱可塑性TPU材料工場、 我々は提供しています 販売のための卸売発泡シートとマット 空気中に一般的に存在する N2 および CO2 ガスを使用してプラスチックを膨張させ、内部に多数のマイクロおよびナノバブルを形成します。これは純粋に物理的な発泡プロセスです。
  Shincell は Dr. Xiulei Jiang によって設立されました。彼は 2003 年に華東科技大学で超臨界流体発泡技術の研究を開始し、超臨界成形マイクロセル発泡の技術プロセスを提案しました。彼の初期の関心は これらの長年の基礎研究に基づいて、Shincell は、ソフトで高弾性の軽量素材とハードで高強度の軽量素材の 2 つの製品シリーズを形成しました。ソフトで高弾性の製品には、TPU、TPEE、PEBA、PEBAX などがあります。硬質高強度製品には、PP、PVDF、PPO、PAなどがあります。
  当社の発泡材料はすべて熱可塑性であり、発泡プロセスで化学発泡剤を添加したり、化学的に架橋したりすることはありません。従来の発泡材料と比較して、当社の発泡材料はリサイクル可能で、無毒で環境に優しく、持続可能な開発のニーズを満たしています!
シンセル
最新ニュース
Why is the closed-cell structure of PVDF foam board better than open-cell material in corrosion resistance?
2025-03-24
PVDF foam board is a high-performance thermoplastic material. Through a specific foaming process, a large number of tiny bubbles are introduced into the PVDF resin matrix to form a unique closed-cell structure. This structure not only reduces the weight of the material, but also improves its mechanical strength, thermal insulation and corrosion resistance. The closed-cell structure means that the bubbles are independent of each other inside the material, and the bubble wall is thicker, forming a continuous and dense protective layer that can effectively isolate external corrosive media. Comparison of corrosion resistance between closed-cell structure and open-cell structureDifference in penetration resistanceClosed-cell structure: The closed-cell structure of PVDF foam board forms a continuous barrier, and the bubble wall is tight and not easily penetrated by corrosive media. This structure significantly improves the material's penetration resistance to corrosive liquids and gases, effectively preventing the corrosive medium from penetrating into the material, thereby protecting the base material from erosion.Open-cell structure: In contrast, the bubbles inside the material of the open-cell structure are interconnected to form an open network structure. This structure makes it easier for corrosive media to penetrate into the material through the gaps between bubbles, causing the base material to be corroded. Comparison of corrosion ratesExperimental studies have shown that under the same corrosive environment, the closed-cell structure of PVDF foam board can significantly reduce the corrosion rate. Due to the barrier effect of the closed-cell structure, the diffusion and penetration of corrosive media on the surface of the material are severely restricted, thereby extending the service life of the material.On the contrary, due to the connectivity of the internal bubbles in the open-cell structure, the corrosive medium can more easily penetrate into the material, resulting in an accelerated corrosion rate and a rapid decline in material performance. Consideration of chemical stabilityPVDF itself has excellent chemical stability and can resist the erosion of a variety of corrosive media. However, due to the openness of the internal structure of the open-cell structure, the corrosive medium is more likely to contact the base material, thereby reducing its overall chemical stability.In contrast, the closed-cell PVDF foam board can better maintain its chemical stability due to its effective barrier effect, and can maintain a longer service life even in harsh corrosive environments. Specific mechanism of closed-cell structure improving the corrosion resistance of PVDF foam boardThe closed-cell structure of PVDF foam board forms a continuous and dense physical barrier, which can effectively prevent the penetration and diffusion of corrosive media. This barrier effect not only protects the base material from erosion, but also improves the overall corrosion resistance of the material. The bubble walls in the closed-cell structure are thicker and denser, with higher mechanical strength and chemical stability. These bubble walls can resist the erosion of corrosive media, further enhancing the corrosion resistance of the material. Materials with open-cell structures are prone to stress corrosion cracking under the action of corrosive media, resulting in a rapid decline in material performance. The closed-cell structure of PVDF foam board can reduce stress concentration and reduce the risk of stress corrosion cracking, thereby improving the reliability and service life of the material. In addition to corrosion resistance, the closed-cell structure of PVDF foam board can also improve its weather resistance and aging resistance. Since the closed-cell structure can effectively isolate the influence of environmental factors such as ultraviolet rays and oxygen on the material, the service life of the material is extended. Advantages of PVDF foam board closed-cell structure in practical applicationsIn the chemical industry, PVDF foam board is often used to manufacture the lining or shell of various chemical equipment. Its closed-cell structure can effectively prevent the erosion of corrosive chemicals on the equipment, extend the service life of the equipment, and reduce maintenance costs. In storage tanks and pipeline systems, PVDF foam board can be used as an anti-corrosion layer or thermal insulation layer. Its closed-cell structure can prevent corrosive liquids or gases from penetrating into the tank or pipeline through the material, thereby protecting the integrity of the tank and pipeline system and improving the safety and reliability of the system. In the fields of construction and transportation, PVDF foam board can be used to manufacture exterior wall panels, sound insulation boards and other components. Its closed-cell structure can provide good thermal insulation and sound insulation performance, while preventing the penetration of corrosive media such as rainwater and moisture, protecting building structures and transportation facilities from erosion.
How does microporous polypropylene foam efficiently insulate to reduce winter energy consumption?
2025-03-20
The thermal insulation performance of microporous polypropylene foam mainly comes from its dense microporous structure inside. These tiny pores not only significantly reduce the volume density of the material, but more importantly, they effectively hinder the transfer of heat. In winter, the indoor temperature is higher than the outdoor temperature, and heat will dissipate outward through the wall or window gaps. The microporous structure of microporous polypropylene foam can form a "thermal insulation barrier" and significantly reduce the efficiency of heat transfer. Specifically, the micropores in microporous polypropylene foam can be regarded as tiny air layers. Air is a poor conductor of heat, and its thermal conductivity is much lower than that of solid materials. Therefore, when heat tries to transfer outward through the wall or window gaps, it encounters the air layer in these micropores, thereby slowing down the transfer of heat. In addition, the microporous structure of microporous polypropylene foam can also reduce the effects of thermal radiation and thermal convection, further reducing heat loss. In winter, keeping the indoor temperature stable is essential to improving living comfort. As an insulation material, microporous polypropylene foam can effectively prevent indoor heat from dissipating outward through the wall or window gaps, thereby maintaining a stable indoor temperature. This insulation effect not only improves the comfort of the living environment, but also reduces the discomfort caused by temperature fluctuations. Specifically, the thermal insulation performance of microporous polypropylene foam can ensure that the indoor temperature remains within a relatively stable range in winter, avoiding a sharp drop in indoor temperature caused by a sudden drop in outdoor temperature. This stable indoor temperature helps reduce the occurrence of common winter diseases such as colds and coughs, and improves the health level of residents. Stable indoor temperature can also improve the sleep quality of residents and reduce insomnia and dreaming caused by temperature discomfort. In addition, the thermal insulation performance of microporous polypropylene foam can also reduce indoor humidity, reduce the growth of mold and bacteria, and keep indoor air fresh and hygienic. This is of great significance to improving the overall comfort and health level of the living environment. The thermal insulation performance of microporous polypropylene foam not only improves the comfort of the living environment, but also significantly reduces the energy consumption and energy waste of the heating system. In winter, the heating system needs to consume a lot of energy to maintain a stable indoor temperature. The thermal insulation properties of microporous polypropylene foam can reduce heat loss, thereby reducing the operating time and energy consumption of the heating system. Specifically, when the indoor temperature remains stable, the heating system does not need to be frequently started and shut down, thereby reducing energy waste. Since the thermal insulation properties of microporous polypropylene foam can effectively prevent heat loss, the amount of energy required for the heating system is also reduced accordingly. This effect of reducing energy consumption not only helps to reduce heating costs, but also reduces pollution and damage to the environment. In addition, the thermal insulation properties of microporous polypropylene foam can also improve energy efficiency. During the heating process, part of the energy will be converted into heat energy and transferred to the room. The thermal insulation properties of microporous polypropylene foam can reduce the loss of heat energy, thereby improving energy efficiency. This effect of improving energy efficiency not only helps to reduce energy consumption, but also promotes sustainable development and environmental protection. The application of microporous polypropylene foam in the field of building insulation is wide and diverse. It can be used as a wall insulation material to improve the thermal insulation performance of the wall; it can also be used as a filling material for window gaps to reduce heat loss; it can also be used as a roof insulation layer to maintain the stability of indoor temperature. In terms of wall insulation, microporous polypropylene foam can be used as a material for exterior wall insulation board or interior wall insulation layer. By sticking or fixing it to the wall, an effective thermal insulation barrier can be formed to reduce heat loss. At the same time, microporous polypropylene foam also has the advantages of light weight and easy construction, which can meet the needs of different architectural styles and construction requirements. In terms of window gap filling, microporous polypropylene foam can be used as a sealing material. By filling it in the window gap, it can effectively prevent heat loss and cold wind from invading. This sealing effect not only improves the thermal insulation performance of the window, but also enhances the sound insulation effect of the window, and improves the overall comfort of the living environment. In terms of roof insulation, microporous polypropylene foam can be used as an insulation layer material. By laying it on the roof, an effective thermal insulation barrier can be formed to reduce heat loss and the impact of the external environment on the indoor temperature. This thermal insulation effect not only improves the thermal insulation performance of the roof, but also extends the service life of the roof. With the continuous improvement of people's awareness of living comfort, energy consumption and environmental protection, the application prospects of microporous polypropylene foam in the field of building insulation will be broader. In the future, microporous polypropylene foam will develop in a more efficient, environmentally friendly and intelligent direction. On the one hand, scientific researchers will continue to optimize the preparation process and formula of microporous polypropylene foam to improve its thermal insulation performance and durability. By introducing new additives and modification technologies, the thermal insulation effect and anti-aging performance of microporous polypropylene foam can be further improved, and its service life can be extended. On the other hand, with the development of intelligent technology, microporous polypropylene foam will develop in an intelligent direction. For example, by combining it with intelligent sensors and control systems, intelligent adjustment and monitoring of indoor temperature can be achieved. This intelligent technology not only improves the comfort of the living environment, but also reduces energy consumption and energy waste. With the improvement of people's awareness of environmental protection, the recycling and reuse of microporous polypropylene foam will also become a future development trend. By recycling and reusing waste microporous polypropylene foam materials, resource waste and environmental pollution can be reduced, and sustainable development and environmental protection can be promoted.
Metal-free, safer? The pure life philosophy of MTPU adult yoga mats
2025-03-13
In the production process of traditional yoga mats, in order to enhance the durability or color stability of the mats, some manufacturers may add metal components such as lead and mercury. Although these metal elements can improve certain performance of the product to a certain extent, long-term contact or inhalation of these metal elements may cause harm to human health. Harm of lead: Lead is a toxic heavy metal. Long-term exposure to a lead environment may cause damage to the nervous system, kidneys, digestive system and immune system. For children, lead poisoning may also affect their intellectual development. Yoga mats are items that come into direct contact with the skin. If they contain lead, long-term use will undoubtedly increase health risks. Hazards of mercury: Mercury is also a heavy metal that is harmful to the human body, mainly affecting the nervous system, digestive system and kidneys. Long-term exposure to mercury may cause symptoms such as memory loss and neurasthenia. If mercury is contained in the production or use of yoga mats, it may enter the human body through skin contact or inhalation, posing a potential threat to health. Faced with the potential risks of metal components in traditional yoga mats, MTPU yoga mats, with their metal-free design, provide yoga enthusiasts with a safer and healthier choice. MTPU materials themselves do not contain harmful metal components such as lead and mercury, avoiding the harm of metal elements to the human body and the environment from the source.Safe and non-toxic: During the production process, MTPU yoga mats strictly follow environmental protection standards and do not add any toxic and harmful substances, including metal components. This means that both beginners and veteran yoga enthusiasts can use MTPU yoga mats with confidence and enjoy a pure yoga experience.Environmentally friendly: In addition to the metal-free design, MTPU yoga mats also have good recyclability. After the life cycle of the yoga mat is over, MTPU materials can be recycled and reused, reducing environmental pollution caused by landfill and incineration. This feature not only extends the life cycle of the material, but also promotes the development of the circular economy, which is in line with the modern people's pursuit of environmental protection and sustainable development. Choosing an MTPU yoga mat is not only an investment in personal health, but also a practice of the philosophy of pure life. With the company of a yoga mat, every practice becomes a purification of the body and mind, and a reverence for nature.Pure experience of unity of body and mind: The soft touch and excellent anti-slip performance of MTPU yoga mats allow yoga enthusiasts to focus more on the coordination of breathing and movements during practice, and enjoy the pure experience of unity of body and mind. This experience not only helps to improve the effect of yoga practice, but also helps practitioners relax and relieve stress.A life attitude of harmonious coexistence with nature: The metal-free design of MTPU yoga mats reflects respect and protection for nature. With the company of yoga mats, every practice becomes an opportunity to dialogue with nature, allowing practitioners to cherish natural resources more and pay attention to environmental health. This life attitude not only helps to improve the quality of personal life, but also promotes the development of society in a greener and more sustainable direction. With the continuous improvement of consumers' awareness of environmental protection and health, MTPU yoga mats have received widespread attention and recognition in the market. More and more yoga enthusiasts are beginning to choose MTPU yoga mats as their practice partners to enjoy a pure and healthy yoga experience. Market application: MTPU yoga mats have occupied a place in the yoga supplies market with their metal-free design, excellent durability and environmental performance. Whether it is a professional yoga studio, gym, or home user, you can find MTPU yoga mat products suitable for you. In addition, MTPU yoga mats have become part of the fashion trend due to their unique colors and pattern designs, meeting consumers' dual needs for beauty and practicality.Future development: With the popularization of yoga culture and the growing demand for environmentally friendly and healthy products, the market prospects of MTPU yoga mats are broad. In the future, MTPU yoga mats will pay more attention to product innovation and research and development, improve the comfort and durability of products, and continue to strengthen their environmental performance to meet consumers' pursuit of high-quality yoga mats. In addition, MTPU yoga mats will also expand more application scenarios, such as outdoor yoga, water yoga, etc., to provide more diversified choices for yoga enthusiasts.
How does precision punching technology shape the unique properties of perforated TPU foam sheets?
2025-03-06
Punching holes in TPU foam substrates is a process that requires high precision. This process not only requires the size, shape and distribution of the holes to meet specific design requirements, but also ensures that the impact of the punching process on the material itself is minimized to maintain the overall performance and structural integrity of the material. To achieve this goal, manufacturers usually use methods such as laser punching, mechanical punching or chemical etching. Laser punching technology is an advanced punching method in modern manufacturing. It uses a high-energy-density laser beam to quickly melt, vaporize or evaporate the material to form holes in the material. In the production of perforated TPU foam sheets, laser punching technology has the following significant advantages:High precision: Laser punching technology can achieve micron-level punching accuracy to ensure that the size, shape and position of the holes meet the design requirements. This is especially important for application scenarios that require precise control of breathability.Non-contact processing: During the laser punching process, the laser beam has no direct contact with the material surface, avoiding mechanical stress damage to the material, which is conducive to maintaining the original performance of the TPU foam substrate.Efficiency: Laser drilling is fast and can complete the processing of a large number of holes in a short time, improving production efficiency.Flexibility: Laser drilling technology can easily achieve drilling of complex shapes and patterns to meet diverse design needs.However, laser drilling technology also has some limitations, such as high equipment cost, high operator skill requirements, and possible heat-affected zones on certain materials. In the production of perforated TPU foam sheets, manufacturers need to weigh these factors to choose the most suitable drilling method.Mechanical drilling technology is a traditional drilling method that uses mechanical devices (such as drills, punches, etc.) to impact or squeeze the material to form holes in the material. In the production of perforated TPU foam sheets, mechanical drilling technology has the following characteristics:Cost-effectiveness: Compared with laser drilling, mechanical drilling technology has lower equipment costs and is easy to maintain and operate. This is attractive for application scenarios that require mass production and do not require particularly high drilling accuracy.Wide applicability: Mechanical drilling technology is suitable for a variety of materials, including TPU foam substrates. By adjusting the shape and size of the punching device, holes of different shapes and sizes can be easily processed.Fast processing speed: Mechanical punching technology is usually fast and can complete the processing of a large number of holes in a short time.However, mechanical punching technology also has some limitations, such as relatively low punching accuracy, possible damage to the material surface, and possible debris during the punching process. In the production of perforated TPU foam sheets, manufacturers need to carefully evaluate these factors to ensure the quality and performance of the final product. Chemical etching punching technology is a method of forming holes in a material using chemical reactions. In the production of perforated TPU foam sheets, this method usually involves soaking the material in a specific chemical solution, removing part of the material through chemical reactions, thereby forming holes. Chemical etching punching technology has the following characteristics:High flexibility: Chemical etching punching technology can easily achieve the punching of complex shapes and patterns, and is not limited by the shape and size of the material. This is particularly applicable to perforated TPU foam sheets that require highly customized designs.Lower cost: Compared with laser drilling and mechanical drilling, chemical etching drilling technology usually has lower equipment and material costs. This is attractive to manufacturers with limited budgets.However, chemical etching drilling technology also has some limitations, such as relatively slow processing speed, greater environmental pollution, and possible impact on material performance. In the production of perforated TPU foam sheets, manufacturers need to carefully evaluate these factors to ensure the environmental protection and safety of the final product. Precision drilling technology has a significant impact on the performance of perforated TPU foam sheets. On the one hand, the precise hole size, shape and distribution can ensure that the material has excellent breathability and meets the needs of specific application scenarios. On the other hand, factors such as heat-affected zone, mechanical stress or chemical damage that may be generated during the drilling process may also have a negative impact on the overall performance of the material. In order to optimize the performance of perforated TPU foam sheets, manufacturers need to take a series of measures to reduce the negative impact of the drilling process. For example, when choosing a punching method, a trade-off should be made based on the characteristics of the material and the needs of the application scenario; during the punching process, processing parameters such as laser power, mechanical impact force or concentration of chemical solution should be strictly controlled; after punching, the material should be subjected to necessary post-processing, such as cleaning, drying and curing, to eliminate residues and improve the stability of the material. Precision punching technology plays a vital role in the production of perforated TPU foam sheets. Methods such as laser punching, mechanical punching and chemical corrosion have their own characteristics and are suitable for different application scenarios and needs. By reasonably selecting the punching method and strictly controlling the processing parameters, manufacturers can produce perforated TPU foam sheets with excellent breathability and overall performance.
M-TPU Foam Sheet: Dual innovations in elasticity and wear resistance lead the new trend in the industry
2025-02-27
1. Excellent elasticity: perfect integration from theory to practiceThe elasticity of M-TPU Foam Sheet comes from its unique molecular structure and microporous foaming process. TPU itself is a block copolymer composed of alternating hard segments and soft segments. The hard segments provide the rigidity and strength of the material, while the soft segments give the material good elasticity and toughness. In M-TPU Foam Sheet, this molecular structure has been further optimized. During the foaming process, gases such as supercritical carbon dioxide are injected into the TPU melt to form a large number of tiny bubbles. These bubbles become microporous structures after cooling and solidification, making the material lighter and softer while maintaining its original elasticity. The microporous structure also increases the energy absorption capacity of the material, allowing M-TPU Foam Sheet to better disperse stress when subjected to external forces, thereby improving its resilience and impact resistance. In practical applications, the excellent elasticity of M-TPU Foam Sheet has been fully reflected. In the field of sports shoes, M-TPU Foam Sheet is widely used in sole materials. Its high elasticity and good resilience enable shoes to provide a more comfortable foot feel and cushioning effect when walking or exercising, effectively reducing foot fatigue and the risk of injury. M-TPU Foam Sheet is also used in the fields of car seats, furniture pads, etc. to improve the comfort and durability of products. 2. Wear resistance: a comprehensive upgrade from microstructure to macroscopic performanceIn addition to its excellent elasticity, M-TPU Foam Sheet is also known for its excellent wear resistance. Wear resistance refers to the ability of a material to resist wear during friction, and is one of the important indicators for evaluating the durability of a material. The wear resistance of M-TPU Foam Sheet is mainly due to its unique microporous structure and the inherent characteristics of TPU materials. During the microporous foaming process, the gas is evenly dispersed in the TPU melt to form a large number of tiny bubbles. These bubbles become microporous structures after cooling and solidification, increasing the surface area and roughness of the material. This change in microstructure enables M-TPU Foam Sheet to better resist wear during friction and extend its service life. TPU material itself has good wear resistance and tear resistance. These properties are further enhanced in M-TPU Foam Sheet. The presence of microporous structure enables the material to better disperse stress when subjected to external force, avoiding local excessive wear. M-TPU Foam Sheet also has excellent anti-aging properties and can maintain its original wear resistance during long-term use. In practical applications, the wear resistance of M-TPU Foam Sheet has been widely recognized. In industrial fields such as conveyor belts and transmission belts, M-TPU Foam Sheet is favored for its excellent wear resistance and tear resistance. In the field of outdoor products, M-TPU Foam Sheet is also widely used in the production of backpacks, tents and other products to improve the durability and service life of the products. 3. Comprehensive advantages of elasticity and wear resistance: promoting industry innovation and developmentM-TPU Foam Sheet's excellent performance in elasticity and wear resistance not only improves the comfort and durability of the product, but also brings innovation and development opportunities to related industries. In the field of sports shoes, the application of M-TPU Foam Sheet has promoted the technological innovation of sole materials, making shoes lighter and more durable while providing comfortable foot feel. In the automotive industry, M-TPU Foam Sheet is used in the production of seat pads and interior parts, improving the comfort and luxury of cars. The environmental protection and sustainability characteristics of M-TPU Foam Sheet also provide broad prospects for its application in many fields. With people's increasing attention to environmental protection and sustainable development, M-TPU Foam Sheet, as a recyclable and reusable material, will gradually become one of the important development directions in the field of materials science in the future.
AURORRA insoles: a milestone in Suzhou Shincell's technological innovation
2025-02-25
As a leader in China's new materials field, Suzhou Shincell has been committed to the research and development and application of high-performance materials. Our star product, Peabax foam, shines in many fields with its light weight, high elasticity and durability. When this excellent material meets ARRIS, an American brand far across the ocean, a revolutionary change in insoles begins. AURORRA By ARRIS carbon fiber insoles are the result of this cooperation. It cleverly integrates ARRIS's carbon fiber technology with Suzhou Shincell's Peabax foam to achieve a perfect balance between strength and comfort. Carbon fiber, with its high strength and low weight, provides stable support and excellent responsiveness for insoles; while Peabax foam, with its excellent resilience and durability, ensures comfort and durability under long-term wear. This innovative material combination not only sets a new benchmark for the insole industry, but also brings consumers an unprecedented wearing experience. Excellent performance is the key to AURORRA By ARRIS carbon fiber insoles winning market recognition. What is even more remarkable is that this insole has also won the seal of approval from the American Podiatric Medical Association (APMA) for its positive contribution to foot health. This honor is not only an affirmation of AURORRA By ARRIS's humanistic care in product design, but also a recognition of Suzhou Shincell's focus on health in material research and development. Through scientific structural design and reasonable matching of materials, AURORRA By ARRIS carbon fiber insoles effectively alleviate the impact of walking, running and other sports on the feet, providing a strong guarantee for the user's foot health. Suzhou Shincell's success in the AURORRA By ARRIS carbon fiber insole project not only demonstrates its deep strength in the field of materials science, but also reflects its keen insight and forward-looking layout under the innovation-driven development strategy. Through in-depth cooperation with international brands, Suzhou Shincell has not only pushed its own technological advantages to a broader stage, but also injected new vitality into the development of China's new materials industry. Looking to the future, Suzhou Shincell will continue to uphold the development concept of "innovation, quality, and health", and be committed to the research and development and application of high-performance materials to promote the continuous innovation of insoles and even the entire footwear industry. In the near future, Suzhou Shincell will join hands with more domestic and foreign partners to jointly create more excellent products like AURORRA By ARRIS carbon fiber insoles, and contribute more to human health and comfortable life. AURORRA By ARRIS carbon fiber insoles have not only won wide acclaim in the market for their excellent performance, but also demonstrated Shincell's profound heritage and innovative spirit in the field of materials science with the technology integration behind them. The success of AURORRA By ARRIS carbon fiber insoles is an important milestone for Suzhou Shincell on the road of technological innovation, and also a gorgeous appearance of China's new materials industry on the world stage.

製品 業界知識の拡張

軽量ポリマーフォームの主な特徴には次のようなものがあります。
1、低密度: 軽量ポリマーフォーム 材料内に空気ポケットが存在するため密度が低く、軽量で取り扱いが簡単です。
2、高気孔率: 軽量ポリマーフォームの多孔質構造は大きな表面積を提供するため、吸収やろ過が必要な用途に最適です。
3、優れた断熱性:軽量のポリマーフォームは熱伝導率が低く、高温と低温の両方の用途で効果的な断熱材になります。
4、クッション性と衝撃吸収性: 軽量ポリマー フォームの構造により、パッケージングや保護具などの用途におけるクッション性と衝撃吸収性に優れた素材となります。
5、耐湿性:多くの軽量ポリマーフォームは耐湿性に優れているため、湿気の多い環境での使用に適しています。
6、耐薬品性:一部の軽量ポリマーフォームは、化学薬品、酸、および溶剤に耐性があるため、産業用途に役立ちます。
7、費用対効果: 軽量のポリマーフォームは、多くの場合、金属や木材などの他の材料よりも安価であるため、多くの用途で費用対効果の高い選択肢となります。

軽量ポリマーフォームには、次のような幅広い用途があります。
1、パッケージング: 軽量のポリマーフォームは、クッション性と衝撃吸収特性により、パッケージング用途で一般的に使用されています。
2、断熱材: 軽量ポリマーフォーム 建物、冷蔵庫、および熱または冷たさを制御する必要があるその他のアプリケーションで断熱材として使用されます。
3、クッションとパディング: 軽量のポリマーフォームは、スポーツ用品、ヘルメット、その他の保護具にクッションとパディングを提供するために使用されます。
4、防音: 軽量のポリマーフォームを防音材として使用し、建物や輸送車両の騒音レベルを低減します。
5、ろ過: 軽量ポリマーフォームの多孔質構造は、水処理プラントやエアフィルターなどのろ過用途に役立ちます。
6、自動車および航空宇宙: 軽量ポリマーフォームは、自動車および航空宇宙産業で、軽量部品、遮音、およびエネルギー吸収のために使用されています。
7、医療機器: 軽量のポリマーフォームは、軽量で快適な特性により、義肢や装具などの医療機器に使用されています。
8、玩具および工芸品: 軽量のポリマーフォームは、軽量で取り扱いが容易なため、玩具、工芸品、趣味の用途に使用されます。

熱可塑性TPU素材は、次のようないくつかの利点を持つ用途の広い素材です。
1、高い耐久性: 熱可塑性TPU素材は丈夫で耐久性のある素材で、劣化や破損することなく繰り返しのストレスや歪みに耐えることができます。
2、柔軟性: 熱可塑性TPU素材 壊れることなく簡単に曲げたり伸ばしたりできる非常に柔軟な素材で、柔軟性が必要な用途に最適です。
3、耐薬品性:熱可塑性TPU素材は、多くの化学薬品や溶剤に耐性があり、産業および医療用途に最適です。
4、高い耐摩耗性:熱可塑性TPU素材は耐摩耗性が高く、耐摩耗性が必要な用途に最適です。
5、優れた耐候性:熱可塑性TPU素材は紫外線に強く、幅広い温度にさらされることに耐えることができるため、屋外での使用に適しています。
6、加工が簡単:熱可塑性TPU素材は、成形、押し出し、熱成形が容易で、幅広い用途に使用できる汎用性の高い素材です。
7、生体適合性:熱可塑性TPU素材は生体適合性があり、カテーテルや外科用インプラントなどの医療用途でよく使用されます。
8、費用対効果が高い: 熱可塑性 TPU 素材は比較的安価な素材であり、多くの用途で費用対効果の高い選択肢となります.