IDTechEx Research finds that the electroactive polymer (EAP) market will be US$ 245 million in 2013. The materials have been used for some time in actuators, capacitors and nanocomposites
but, with new recent technical progress, come new growth opportunities - despite several decades of R&D and first applications, the EAP field is still far from mature. Why is this? Challenges, such as performance, long-term stability and reliable mass production, need further development to tailor the properties to the requirements of each target application. The market potential as forcasted by IDTechEx Research is as high as US$ 2.25 billion by 2018, dominated by consumer electronics, actuators and sensors applications. The new IDTechEx Research report "Electroactive Polymers and Devices 2013-2018: Forecasts, Technologies, Players" (www.IDTechEx.com/eap
) explores the market fully for the next six years, but what will the next couple of years bring?
EAPs are part of the broad group of smart materials. The use of polymers with electroactive response has only emerged in the last decade with the introduction of new materials which have significant displacement levels. These materials are highly attractive for their low-density, large strain capability, superior spectral response, and resilience. In general, the biggest advantages over conventionally used systems in most application fields are the intermittent displacement they can provide, an adaptable stiffness combined with variable size and form factors from micrometers to meters. Companies like Artificial Muscle (AMI) of Bayer
MaterialsScience and Strategic Polymers (SPS
) have been able to tune the properties even further. AMI's were able to eliminate the issues with high driving electric fields. Their dielectric
EAP based actuator has an average power consumption of just 1.5mW and already passed mobile qualification tests. And SPS' PVDF terpolymer based EMP actuators show comparable high deformation strain in the range of 0.5-2.5%.
The following matrix shows a comparison of the main EAP types by maximum strain, pressure and efficiency, as well as the driving electric field and cycle time.
Table 1. Electronic vs. Ionic EAP
The market potential is large - EAPs can be used in various applications including actuators and sensors, biomimetics and robotics, energy harvesting
and storage devices etc. Dielectric
sensors are already in use for a wide range of applications, eg. surface or bulk measurements sensors. Especially in the actuators segment vast R&D activity can be seen for specialized applications such as medical devices and biomimetic-robotics. Here the features of electroactive polymers are used to enable movement and generate force as well as electrically control surface properties. However, these are very demanding makets, with high performance requirements and also restrictions especially in the medical field, which is why it will take at least five more years before revenues grow significantly.
Already in fairly high production are dielectric
elastomer materials commercially available from sources like 3M
, and also piezoelectric
fluoropolymer (PVDF), that is used in actuators, nanocomposites
, capacitors etc. However, these materials are not universally suitable. Especially for dielectric elastomers the main issue hindering the wide-spread application is the high operating voltage required. New growth needs to come from new innovation - improved materials suitable for less demanding high-volume applications, such as consumer electronics and large-area thin-tilm sensors.
Today, with touchscreens everywhere it almost seems natural to expand the user experience with better feedback. Implementation of EAPs for haptic feedback, especially for handheld touchscreen devices and peripherals, is the current new market focus. First prototypes have been introduced by Strategic Polymers and Artificial Muscle of Bayer
MaterialsScience. Compared to inertial actuators currently the standard, EAP ones have the advantage of being able to just move the touch screen, and having a high bandwidth necessary for high-fidelity touch feedback. One of the biggest challenges at the moment however is the cost of EAP devices in consumer electronics. This is why high-fidelity and large screen applications will come first.
Research is on-going in this medium to longer term opportunity, where EAP based systems can be used to harvest the energy from sea waves. In comparison to conventionally used hydraulic systems, electroactive polymer ones offer lower production costs and higher durability.
IDTechEx estimates the electroactive polymer market volume to grow almost tenfold in the next 5 years, dominated by consumer electronics (38%), actuators and sensors applications. The most prominent application is haptics for portable consumer devices with a touch screen. Sensors, i.e. large-area ones and medical applications will come next. For energy harvesting
applications, especially from ocean waves, it will take another decade until the market will see first commercial penetration. The following chart gives the market size by value of the finished device (including driving components etc).
Figure 1. Division of revenue by application in 2013
Actuators and sensors are the most common application for electroactive polymers today and will remain prominent in the next five years. The highest potential lies in new application fields, such as consumer electronics, where first prototypes and evaluation studies have been just recently demonstrated. For medical and energy harvesting
applications the next 5-10 years are crucial. Intensive R&D towards better efficiency, long-term stability, salt-water resistance and up-scale of production from laboratory state to commercial production is needed.
For the full forecasts and more detailed information on electroactive polymers, global players and applications, such as actuators, sensors and energy harvesting, please see the new IDTechEx report "Electroactive Polymers and Devices 2013-2018: Forecasts, Technologies, Players" (www.IDTechEx.com/eap
). The report covers the wide range of EAP materials and form factors available, from thin films to different shapes and sizes. It profiles the latest work commercially and academically. Additionally, the report provides detailed interviews with the international market leaders.
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