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Tallinn, Estonia
1-10 Employees
2021
Currently, our company provide its customers with nanostructured (1 nm to 100 nm) and ultrafine-structured (0.1 um to 5 um) powder materials & gives consultation in following areas such as ;.
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Shape Memory Polymer NGM9020
... Shape Memory Polymer NGM9020, Ether Type - Nano Powder Online ...
Cambridge, United Kingdom
1-10 Employees
2019
We deliver next-generation adhesives and bonding products to assist additive manufacturers, producing stronger, safer, and lighter products, and offer consulting services to industry more widely on improving their use of modern polymers. We are committed to improving the quality and useful life of plastics, while reducing their environmental impact. We are an equal opportunities employer and we are determined to ensure every employee and applicant receives fair and kind treatment. The overall business development, planning and financing responsibility is with Andrew Terentjev, who is the CEO of CSP. Andrew is a qualified commercial banker, having worked at Barclays, Santander and most recently as a head of corporate risk at Mercedes-Benz Bank AG. The technical team is lead by Mohand Saed, who is a Senior Researcher at the Cavendish Lab and CTO of CSP. We operate from rented lab space in the Physics of Medicine Centre at the Cavendish, a lab with quite some heritage. It is known to be where almost half of all physics discoveries were made, with over 30 Cavendish researchers winning Nobel Prizes for their research.
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Cambridge Smart Plastics
... Smart, self-healing, shape-memory polymer compounds that bring the state-of-the-art in science to mainstream ...
Pune, India
51-100 Employees
2014
Axiom Market Research & Consulting™ is a full-service market research and data analytics company providing key market intelligence to global companies to take informed business decisions pertaining to their marketing strategy, investments, new product launches, market competition, consumer or end users, social media trends etc. Axiom Market Research & Consulting™ offers market research services such as syndicated market research, custom market research, business consulting, and consumer/end user surveys. Under Business to Consumer (B2C) market research offerings, Axiom MRC assists its clients in finding quantitative information/preferences of its brands and services such as, awareness, usages, satisfaction, tracking, ethnicity etc. Axiom MRC offers data collection services through online surveys, social media, data processing and interpretation. Axiom MRC with its experienced team of research and data analysts, has delivered more than 5000+ Market Research Projects, 3800+ Data Analytics Projects, 1200+ Business Support Projects and has a 800+ Global Client Base. Axiom Market Research & Consulting™ offers (B2B) market research reports such as syndicated market research reports, custom….
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Shape Memory Polymers Market Report
... COVID-19 Impact Analysis on Global Shape Memory Polymers ...
Port Washington, United States
1-10 Employees
Nano Research Elements is set up by a group of expert Nanotechnologists to concentrate on giving an answer for each mind boggling complex issue with the assistance of Nanotechnology products and applications. Nanomaterials innovation has the potential to address a number of today’s biggest scientific challenges, ranging from the need for more efficient alternative energy technologies, faster and flexible electronics, and improved disease diagnosis and treatment. Nanotechnologies - to be more particular: nanomaterials - are already used in numerous products and industrial applications. Our Nanotechnology Products and Application database as of now give an outline of how nanomaterials and nanostructure applications are utilized today industrial and commercial applications across industries. Nano Research Elements offer a huge collection of nanomaterials that navigate the Periodic Table including gold, silver, iron oxide, metal and metal composites, oxides, nitrides and ceramics.
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Shape Memory Polymer Resin (Potting)
... Shape Memory Polymer Resin (Potting) - ...
Lafayette, United States
11-50 Employees
1988
We also use different external services like Google Webfonts, Google Maps, and external Video providers. Since these providers may collect personal data like your IP address we allow you to block them here.
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Deployable Space Systems - Composite Technology Development, Inc.
... Composite Lightweight Array with Shape-memory Polymer (CLASP) ...
Geneva, Switzerland
1-10 Employees
2007
Transform your practice with ClearX: Join hundreds of practitioners who are committed to the eco-orthodontic revolution. With fewer aligners required and reduced treatment times, ClearX is a game-changer in the field of orthodontics, offering superior efficiency and faster, more transformative results. Dental professionals can manage a larger patient base while delivering exceptional care. Offer your patients an eco-friendly choice without second thoughts. More important than the magnitude of orthodontic force, is the timing of force application. Our pre-programmed aligners, powered by our exclusive 4D Shape-Shifting Technology, offer precise, eco-friendly treatment solutions that move teeth frequently at ideal intervals to deliver smooth tooth transition to the planned position. ClearX aligners offer more than just orthodontic solutions; they enhance your practice's capabilities. What really sets ClearX apart is the incredibly precise treatment planning.
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ClearX Aligners
... Smart Shape-Memory Polymers ...
Charlton, United States
The main product at that time was making connector molds for the Electronics Industry. This is the year of the first bioabsorbable molding project at MTD as well. MTD remains committed to Dick’s original philosophy to find and commit to a niche as well as to respond quickly, precisely, and efficiently to our customer needs. And so began the mission of educating medical OEMs that smaller, better critical components are possible. The focus was on providing highly specialized products that meet the exact requirements of companies in the medical, electronics, and microfluidics fields. We stopped manufacturing turn-key molding cells for other companies, while keeping all tooling and micromolding operations under one roof at MTD’s facility. This is the sixth consecutive year of being on the list, but the first time ranked #1. MTD is the first micro injection molding company in the world to receive the MedAccred Certification.
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Medical Micro Molding Examples - Bioabsorbable, Drug Delivery
... Shape Memory Polymer Resin “Flower” ...
Stratford-on-Avon, United Kingdom
1-10 Employees
2015
We are based in Shakespeare's Stratford upon Avon. Beauty Goddess is a family business that started selling Cosmetics in February 2015. We try to stock products that are not currently available in the UK. That’s why all of our products have luxury formulas at prices that won’t break the bank. Beauty Goddess is a premier name in the UK bringing together an extensive assortment of best beauty and skin care products. We stand out as the one-stop-destination for top-branded beauty products in the UK. Our main objective is to provide a comprehensive range of contemporary and professional beauty product lines for your personal needs. At Beauty Goddess we analyze the latest trends and deliver superior products – blending innovations with our trademark UK edge and market finesse.
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ISEHAN- Kiss me Heroine Make Volume UP Super Mascara Waterproof + Spee – Beauty Goddess
... . • ALL DAY CURL-HOLDWith Curl-Locking ingredients and Memory-Shape Polymer keeps lashes stay curled upward for a whole ...
Technologies which have been searched by others and may be interesting for you:
Some interesting numbers and facts about the results you have just received for Shape Memory Polymer
Country with most fitting companies | United States |
Amount of fitting manufacturers | 7 |
Amount of suitable service providers | 6 |
Average amount of employees | 1-10 |
Oldest suiting company | 1988 |
Youngest suiting company | 2021 |
A Shape Memory Polymer (SMP) is an advanced material that can return from a deformed state to its original shape upon exposure to an external stimulus, such as temperature change. This unique characteristic is primarily due to the polymer’s molecular architecture, which allows it to "memorize" its initial form. SMPs can be engineered to respond to various stimuli, including heat, light, and magnetic fields, making them highly versatile. In the realm of their application, these polymers have significantly impacted sectors like healthcare, aerospace, and robotics. In healthcare, for example, SMPs are used in self-adjusting implants and devices that can conform to body tissues or activate at body temperature, enhancing patient comfort and recovery times. In aerospace, the ability of SMPs to alter shape with temperature variations is leveraged for adaptive structures that can adjust to environmental conditions, improving aerodynamic efficiency and performance. Similarly, in robotics, SMPs contribute to the development of more flexible and responsive components, leading to advancements in soft robotics. This adaptability not only broadens the scope of potential applications but also paves the way for innovations that could redefine the future of material science and engineering.
1. Flexibility and Versatility
Shape memory polymers (SMPs) exhibit exceptional flexibility, allowing them to be engineered into a vast array of shapes and sizes. This versatility makes them suitable for diverse applications, ranging from medical devices to aerospace components, offering solutions that traditional materials cannot.
2. Biocompatibility
One of the significant advantages of SMPs, especially in medical applications, is their biocompatibility. They can safely interact with biological tissues, making them ideal for use in minimally invasive surgeries and as implants, thereby reducing the risk of adverse reactions within the body.
3. Responsive to Stimuli
SMPs are uniquely responsive to external stimuli such as temperature, light, or magnetic fields. This responsiveness allows them to change shape or recover their original form when exposed to specific conditions. This characteristic enables innovative uses in smart clothing, self-healing materials, and adaptive structures, where traditional materials fall short.
4. Cost-Effectiveness
Compared to other smart materials, SMPs can be more cost-effective to produce and implement. Their manufacturing process allows for scalability without significantly increasing costs, making them a financially viable option for both high-tech and consumer-grade products.
While evaluating the different suppliers make sure to check the following criteria:
1. Material Quality
Ensure the Shape Memory Polymer provided meets industry standards for durability and performance. High-quality materials contribute to the longevity and reliability of applications.
2. Customization Capabilities
Assess the supplier's ability to customize the polymer to fit specific application requirements. This includes variations in shape, size, and memory activation temperatures.
3. Production Capacity
Confirm the supplier has the production capacity to meet your demand without compromising on quality, especially for large-scale or continuous supply needs.
4. Compliance with Regulations
Verify the supplier adheres to relevant environmental and safety regulations, ensuring the polymers are safe for use in intended applications.
5. Cost-Effectiveness
Consider the overall cost, including the price of the polymer, shipping, and any additional fees. Competitive pricing without sacrificing quality is key.
6. Technical Support
Evaluate the level of technical support and customer service offered. Reliable support is crucial for addressing any concerns or questions that may arise.
Shape memory polymers (SMPs) have garnered significant attention for their potential in revolutionizing product designs and functionalities across various industries. In the aerospace sector, SMPs are being explored for self-healing structures. These materials can return to their original shape when exposed to a specific stimulus, such as heat, making them ideal for repairing minor damages on aircraft surfaces without manual intervention, thereby reducing maintenance costs and improving safety. The automotive industry is another area where SMPs are making an impact. Here, they are used in the manufacturing of responsive car components that can adapt to environmental changes. For instance, side mirror positions or air vents that adjust automatically in response to temperature changes, enhancing driver comfort and vehicle performance. In healthcare, SMPs are revolutionizing medical devices and prosthetics. They enable the creation of stents that expand at body temperature to support blood vessels, or casts that conform perfectly to the patient's body shape for optimal support and comfort. This adaptability improves patient outcomes and facilitates more personalized medical care. Additionally, SMPs are finding applications in robotics, specifically in developing soft, flexible robots that can navigate through constrained spaces. These robots mimic biological organisms, advancing fields like search and rescue operations by reaching areas previously inaccessible to rigid robots. Each of these use cases demonstrates the versatility and transformative potential of shape memory polymers, positioning them as a critical material in the future of manufacturing and product development across industries.
Shape memory polymers (SMPs) are at a varied Technology Readiness Level (TRL), predominantly ranging from TRL 4 to TRL 6, depending on the application and the specific polymer composition. This range indicates that SMPs have passed the proof-of-concept phase (TRL 3) where their basic properties and functionalities, such as the ability to return to an original shape after deformation when exposed to an external stimulus (heat, light, or magnetic field), have been validated in a laboratory setting. Progressing into TRL 4 and 5, these materials are now being further developed and tested in more controlled environments, simulating real-world conditions to better understand their durability, recovery accuracy, and potential for commercial applications. The variation in TRL levels largely stems from technical challenges, including optimizing the polymers for specific applications, ensuring consistent performance across multiple cycles of deformation and recovery, and scaling up the production process while maintaining material properties. Additionally, the customization of SMPs for targeted applications, such as biomedical devices, aerospace components, or smart textiles, requires extensive research and development to meet stringent industry-specific standards and regulations, further influencing their current TRL positioning.
In the Short-Term, advancements in shape memory polymers (SMPs) are expected to focus on enhancing their responsiveness to different stimuli such as temperature, light, and magnetic fields. This will lead to the development of SMPs with faster actuation times and more precise control over their shape-changing abilities. Applications in minimally invasive medical devices and self-healing materials are poised for significant growth, leveraging these polymers' ability to change shape at body temperature or in response to specific wavelengths of light. The Mid-Term phase is likely to witness the integration of SMPs with other smart materials to create composite systems that offer multifunctional capabilities. For example, combining SMPs with conductive materials could lead to the development of smart textiles that change their thermal properties or rigidity on demand. Additionally, research will probably advance towards improving the biocompatibility and biodegradability of SMPs, opening up new applications in biomedicine, including drug delivery systems and temporary implants that naturally degrade in the body over time. Looking into the Long-Term, the focus will shift towards the mass production and commercial application of SMPs across various industries. Innovations may include the development of SMPs with programmable and reversible multi-shape memory effects, enabling the creation of highly complex shapes and structures. These advancements could revolutionize fields such as aerospace, automotive, and construction, where materials that can adapt to environmental changes or exhibit self-repairing capabilities are highly valuable. Furthermore, the exploration of environmentally friendly SMPs made from renewable resources will be critical in promoting sustainability and reducing the environmental impact of new materials.