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Singapore
1-10 Employees
2019
PiezoRobotics’ disruptive mindset contributes to the Industry 4.0 with precise solutions based on.
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PiezoRobotics
... PiezoRobotics is a deep tech start-up company specialized in the design and manufacturing of vibration technologies based on smart piezoelectric materials. ...
Waverley, United Kingdom
1-10 Employees
2008
Electrosciences Limited provides specialised scientific and technical consultancy to industry and academia in the technical discipline of multifunctional materials research and development. Our aim is to deliver competent solutions to complex scientific needs. We provide advanced materials research and development services for industry, academia and within consortia. Electrosciences have extensive experience in computer modelling, simulation and visualisation for real data. Improved power and material measurements will enable development of optimised, future-proof electronic devices...
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Piezoelectric Materials d33 Analyser : Electrosciences
... Reliable, accurate method of measuring an important materials property of piezoelectrics, which indicates the piezo materials’ ability to sense forces and loads or to change shape as an actuator. ...
Cranfield, United Kingdom
501-1000 Employees
1970
We develop and produce positioning stages and actuators for linear, rotary and vertical motion or combinations of different axes and also adapt those solutions to customer-specific applications. With three decades of Hexapod six-axis stage design and manufacturing experience, PI electro-mechanical hexapods and piezo hexapod positioners are the most advanced multi- axis precision positioning systems in the world. Piezo tip/tilt mirror systems from PI offer excellent specifications, are tested in space, and can be adapted to customer-specific requirements. Industrial production processes place high demands on automated solutions: Increased productivity and quality, more flexible processes, shorter production times, and lower costs. PI offers both customized and standard solutions for this task. Thanks to its huge transmission capacity and low energy consumption, optical communication is penetrating more and more application areas. Learn how ACS Motion Control products can help you: Improve productivity | Increase the precision of your process | Enhance the quality of what you produce | Improve your Machine’s Accuracy and Throughput. PI is a worldwide leading supplier of solutions in the fields of motion and positioning.
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Piezoelectric Materials
... Soft Piezoelectric Materials ...
Granite Falls, United States
11-50 Employees
In the fall of 1932, Philip Reynold Hoffman built, as a hobby, saws for cutting petrified wood. Over time, ownership changed hands and the company diversified into product lines having similar materials and processing requirements. Hoffman Materials Processing operates under the name Hoffman Materials, LLC. Hoffman Materials, LLC currently operates in Granite Falls, NC. This facility is comprised of two buildings totaling approximately 15,000 square feet of manufacturing space for Czochralski crystal growth and processing of several crystalline materials into sensor elements, wafers and other geometries, as required by customer specification requirements. Hoffman Materials, LLC is a recognized innovator and industry leader in the growth and custom production of single crystal and ceramic materials. HM processes raw material that is provided or supplies the material with in-house grown or purchased product. Hoffman Materials, LLC is a materials company established more than 80 years ago which continues to lead the industry in its field located on the East coast in the USA.
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ABOUT - Hoffman Materials, LLC Operating out of two east coast locations
... Originally founded in 1938 and continuing to diversify with a noteable achievement being entry into the high temperature piezoelectric material market. ...
Pierre-Bénite, France
1-10 Employees
Piezotech® FC is a range of P(VDF-TrFE) fluorinated copolymers. Piezotech® FC copolymers are an excellent choice for sensors, energy harvesting, actuators, speakers, ferroelectric memories. Piezotech® RT is a range of P(VDF-TrFE-CTFE) and P(VDF-TrFE-CFE) terpolymers. Piezotech® RT terpolymers are particularly advantageous for high-k dielectrics in OTFT, actuators, and electrocaloric devices. Join Arkema-Piezotech at LOPEC, the world's leading exhibition for flexible, organic and printed electronics. Arkema produces and markets electroactive polymers Piezotech®, in the form of powders, inks or films. Trade show dedicated to composite materials and their applications.
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Piezoelectric Materials | P(VDF-TRFE) | Arkema Piezotech
... Piezoelectric Materials | P(VDF-TRFE) | Arkema ...
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Under DevelopmentLead-free Piezoelectric Materials
... Under DevelopmentLead-free Piezoelectric Materials ...
Uppsala, Sweden
11-50 Employees
1998
Email: Phone: Country —Please choose an option—AustraliaAustriaBelgiumBrazilCanadaChinaCzech RepublicDenmarkFinlandFranceGermanyIndiaIsraelItalyJapanMalaysiaNetherlandsNew ZealandNorwayPolandRussiaSingaporeSlovakiaSouth AfricaSouth KoreaSpainSwedenSwitzerlandTaiwanTurkeyUnited KingdomUnited States of AmericaOther country.
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About PiezoMotor PiezoMotor
... PiezoMotor is a world-leading developer and producer of groundbreaking micro motors based on piezoelectric materials. The technology enables compact ...
Cambridge, United Kingdom
11-50 Employees
2011
Cambridge Touch Technologies (CTT) was spun out from the University of Cambridge, the world leading engineering and research centre. CTT’s team of sales and support engineers are located close to our customers, ready to serve them any time, and at a moment’s notice. Corbin Church is an experienced executive with a nearly 20-year track record... Corbin Church is an experienced executive with a nearly 20-year track record of successfully building businesses, driving revenue and executing on the strategies of innovative technology companies and start-ups. As the CEO of CTT, he develops and leads the vision and direction of the company, while forming key customer and strategic partner relationships that drive growth.
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Home - Cambridge Touch Technologies, Ltd - UltraTouch
... Combining advanced piezoelectric materials with sophisticated ...
Brunswick, United States
1-10 Employees
Graco stocks the parts you need to keep your production lines running efficiently.
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Piezo | Piezobygraco | United States
... Solutions for Piezoelectric materials and products from across the ...
Mumbai, India
11-50 Employees
1978
We empower Manufacturing Industries in IOT, Automation, Healthcare, and Robotics by distributing 5000+ Industrial Electronic Components, Soldering Accessories, Sensors & Modules since 1978.
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18.432MHz Crystal Oscillators HC49/US Package
... It uses the mechanical resonance of a vibrating crystal of piezoelectric material. And then create an electrical signal with a precise frequency. This frequency is often used to keep track of time to provide a stable clock signal. Technical Specification: Frequency Range: 18. ...
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Some interesting numbers and facts about the results you have just received for Piezoelectric Materials
| Country with most fitting companies | United Kingdom |
| Amount of fitting manufacturers | 28 |
| Amount of suitable service providers | 18 |
| Average amount of employees | 11-50 |
| Oldest suiting company | 1970 |
| Youngest suiting company | 2019 |
Piezoelectric materials are substances that exhibit the piezoelectric effect, a phenomenon where mechanical stress applied to the material generates an electric charge or voltage across it, and conversely, when an electric field is applied, it leads to mechanical deformation of the material. This unique property is inherent in certain crystalline substances including quartz, Rochelle salt, and various types of ceramics. The application of piezoelectric materials spans across multiple fields, significantly impacting technology and innovation. In the realm of electronics, they are pivotal in the creation of precise frequency generation and detection components, such as resonators and filters found in mobile phones and other communication devices. In the medical field, piezoelectric materials play a crucial role in ultrasonic imaging by transforming electrical energy into sound waves, and then back into electrical signals to create images of internal body structures. Additionally, their ability to generate electricity from mechanical stress is harnessed in energy harvesting devices, converting vibrations or movements into electrical power for small electronic devices. The versatility and efficiency of piezoelectric materials have thus cemented their position as a cornerstone in the advancement of modern technology, enabling developments that range from everyday conveniences to critical medical diagnostics tools.
1. High Energy Efficiency
Piezoelectric materials are renowned for their ability to convert mechanical stress into electrical energy and vice versa with minimal energy loss. This characteristic makes them particularly suitable for applications requiring precise control and high efficiency, such as in medical devices and industrial sensors.
2. Compact and Lightweight
Another advantage of piezoelectric materials is their compactness and light weight. This property allows them to be integrated into a wide range of devices without significantly affecting the device's size or weight, making them ideal for portable and space-constrained applications.
3. Wide Range of Applications
Piezoelectric materials have a versatile range of applications, from generating electric sparks for lighters and gas stoves to advanced applications in robotics, automotive systems, and renewable energy. Their ability to operate under various conditions and convert energy efficiently makes them superior to many alternative materials.
4. Environmentally Friendly
Lastly, piezoelectric materials are environmentally friendly. They do not require external power sources to function and can generate electricity from mechanical movements, such as vibrations and pressure changes, contributing to sustainable energy solutions.
While evaluating the different suppliers make sure to check the following criteria:
1. Material Quality
Ensure the piezoelectric materials meet industry standards for purity and performance. High-quality materials contribute to better device efficiency and longevity.
2. Customization Capabilities
Assess the supplier's ability to provide customized solutions. Piezoelectric materials often need to be tailored to specific applications, so a supplier's flexibility is key.
3. Supply Chain Reliability
Check the supplier's track record for on-time delivery and their ability to maintain consistent supply, even during market fluctuations.
4. Technical Support
Evaluate the level of technical support offered. Expert guidance on material selection and application can significantly impact the success of your projects.
5. Cost-Effectiveness
While quality should not be compromised, comparing prices can help ensure you are getting the best value for your investment.
6. Compliance and Certification
Ensure the supplier complies with international standards and has the necessary certifications. This is crucial for ensuring the safety and effectiveness of the piezoelectric materials used.
Piezoelectric materials, with their unique ability to convert mechanical stress into electrical energy, find extensive application in the automotive industry for precise control mechanisms. These materials are embedded in sensors and actuators to improve vehicle safety features, such as airbag deployment systems, where their rapid response to mechanical stress ensures timely activation. In the healthcare sector, piezoelectric materials play a pivotal role in diagnostic equipment. They are crucial components of ultrasound transducers, where their ability to generate ultrasonic waves by converting electrical signals into mechanical vibrations enables high-resolution imaging. This technology assists medical professionals in conducting non-invasive examinations, enhancing patient care and diagnostic accuracy. The aerospace industry benefits from piezoelectric materials through enhanced vibration monitoring and control systems. These materials are employed in sensors that detect and measure aircraft vibrations, providing critical data for maintenance and operational safety. Furthermore, they are used in active vibration control devices, helping to mitigate unwanted vibrations and improve passenger comfort and structural integrity. Lastly, in precision manufacturing, piezoelectric materials contribute to the development of advanced positioning systems. Their high precision and responsiveness to electrical signals make them ideal for controlling the movement of tools and components in nanotechnology and semiconductor manufacturing processes, ensuring unparalleled accuracy and efficiency.
Piezoelectric materials, substances that generate an electric charge in response to applied mechanical stress, have reached varying Technology Readiness Levels (TRLs) depending on their application and development stage. Broadly speaking, these materials are situated between TRL 4, where validated lab testing has been conducted, and TRL 6, showcasing models or prototypes demonstrated in relevant environments. This range is attributed to the extensive research and development that has enhanced the understanding and utilization of piezoelectric materials across industries such as aerospace, automotive, and consumer electronics. The technical reasons underpinning their TRL position include the successful integration of piezoelectric components into sensors and actuators, demonstrating effective energy harvesting capabilities in controlled settings. However, challenges related to material stability, energy conversion efficiency, and large-scale manufacturability have hindered their progression to higher TRLs where full-scale commercial deployment is feasible. Additionally, ongoing innovations in material science, particularly in improving the piezoelectric effect in newer materials like PVDF (Polyvinylidene Fluoride), are instrumental in gradually overcoming these barriers, potentially elevating piezoelectric materials to higher TRLs in the future.
In the Short-Term, advancements in piezoelectric materials are expected to focus on enhancing energy efficiency and power density. Researchers are working on developing materials with higher piezoelectric coefficients, which would significantly improve the energy conversion rates of these materials. This phase is likely to see the introduction of new composite materials that combine piezoelectric properties with flexibility and durability, making them ideal for a wide range of applications, from wearable technology to smart infrastructure. The Mid-Term developments are projected to revolve around integration and miniaturization. Piezoelectric materials will be engineered at the nanoscale to create more compact and efficient devices. This period will witness the emergence of piezoelectric nanogenerators capable of powering small electronic devices autonomously. Additionally, the focus will shift towards the seamless integration of piezoelectric elements into everyday objects and materials, thereby expanding their applications into new domains such as biomedical devices and environmental monitoring systems. In the Long-Term, the evolution of piezoelectric materials is anticipated to embrace sustainability and multifunctionality. Researchers will likely develop bio-based piezoelectric materials, reducing reliance on rare and potentially hazardous elements. These sustainable materials will not only be environmentally friendly but also possess self-healing properties, drastically extending their lifespan. Furthermore, advancements in material science could enable the creation of piezoelectric materials that can adapt their properties in real-time, offering unprecedented levels of control and efficiency in energy harvesting and sensor applications.
