Dublin, March 21, 2017 (GLOBE NEWSWIRE) -- Research and Markets has announced the addition of the "Energy Harvesting: Off-Grid Microwatt to Megawatt 2017-2027" report to their offering.

The report has an introduction looking critically at the successes and failures, the overall situation and the companies and universities involved. An extensive chapter on applications reveals how an aircraft or a house for example, has need of energy harvesting producing a whisper of electricity for small electronic devices such as MEMS up to large power levels for moving, cooking, heating etc.

The commonality is revealed by the technologies and companies involved. We consider the four leading technologies - electrodynamics, photovoltaics, piezoelectrics and thermoelectrics - forecasting them by numbers and market value to 2027. The report explains how curiosities such as electret, capacitive, triboelectric and magnetostriction forms of EH now looks good in trials for many uses.

"Energy Harvesting: Off-grid Microwatt to Megawatt 2017-2027" predicts winners and losers in applications and technologies for EH and lists many companies involved with critical assessment of where the billion dollar business will emerge and what are the dead ends.

Key Questions Answered

• What EH will be adopted in for wearable technology?
• Why are the Internet of Things, microgrids, Energy Independent Electric Vehicles EIV and other emerging hot topics impacted?
  
• How is multimode energy harvesting and energy harvesting without energy storage progressing?
  
• What hope is there of avoiding the many toxic materials involved in EH?
  
• What EH is powered by legal push and what is reverting back to batteries?
  
• What are the radically new forms of photovoltaics and electrodynamics all about such as solar roads and Airborne Wind Energy AWE?
  

There are huge opportunities for materials companies in all this, from inorganics to composites and organics as we move to structural electronics - a materials play - instead of "components in a box". The report explains how, why, where and when.

Key Topics Covered:

1. EXECUTIVE SUMMARY AND CONCLUSIONS
1.1. Definition
1.2. Features of EH
1.3. Low power vs high power off-grid
1.4. Types of EH energy source
1.5. Ford and EPA assessment of regeneration potential in a car
1.6. EH by power level
1.7. EH transducer options compared
1.8. Energy storage technologies in comparison
1.9. EH system architecture
1.10. Energy Harvesting Maturity
1.11. Market forecasts 2017-2027
1.12. Popularity by technology 2017-2027

2. INTRODUCTION
2.1. Market drivers
2.2. History of energy harvesting
2.3. Problems that are opportunities

3. APPLICATIONS NOW AND IN FUTURE
3.1. Introduction
3.2. Where is EH used in general?
3.3. Regional differences
3.4. EH is sometimes introduced then abandoned
3.5. Lower power ICs and different design approach facilitate low power EH adoption
3.6. Building control, BIPV, IOT for communities, local grid
3.7. Uses in vehicles
3.8. Manufacturers

4. TECHNOLOGIES AND SYSTEMS
4.1. Overview
4.2. Comparison of options
4.2.1. Technology choice by intermittent power generated
4.2.2. Roadmap for low power EH: Bosch
4.2.3. EH transducer options compared
4.2.4. Potential efficiency
4.2.5. Hype and success - technology
4.2.6. Parameters
4.2.7. Multi-modal harvesting today
4.2.8. Integrated multi-modal:
4.2.9. Wi-Fi harvesting

5. TECHNOLOGY: ELECTRODYNAMIC
5.1. Overview
5.2. Choices of rotating electrical machine technology
5.3. Airborne Wind Energy AWE
5.3.1. TwingTec Switzerland 10 kW+, Ampyx Power
5.3.2. Google Makhani AWE 600kW trial, Enerkite
5.4. Typical powertrain components and regenerative braking
5.5. Trend to integration in vehicles
5.6. Human-powered electrodynamic harvesting
5.6.1. Knee Power
5.7. Electrodynamic vibration energy harvesting
5.7.1. Overview
5.8. Electrodynamic regenerative shock absorbers and self-powered active suspension
5.9. Flywheel KERS vs motor regen. braking
5.10. 3D and 6D movement
5.11. Next generation motor generators, turbine EH in vehicles

6. TECHNOLOGY: PHOTOVOLTAICS
6.1. Overview
6.2. pn junction vs alternatives
6.3. Wafer vs thin film
6.4. Important photovoltaic parameters
6.5. Some choices beyond silicon compared
6.6. Tightly rollable, foldable, stretchable PV will come
6.7. Organic Photovoltaics (OPV)

7. TECHNOLOGY: THERMOELECTRICS
7.1. Basis and fabrication of thermoelectric generators TEG
7.2. Choice of active materials
7.3. Benefits of Thin Film TE
7.4. TEG systems
7.5. Automotive TEG
7.6. Powering sensor transceivers on bus bars and hot pipes
7.7. High power thermoelectrics: tens of watts
7.8. High power thermoelectrics: kilowatt

8. TECHNOLOGY: PIEZOELECTRICS
8.1. Overview
8.2. Active materials
8.2.1. Overview
8.2.2. Exceptional piezo performance announced 2016
8.3. Piezo Effect - Direct
8.4. Piezo Effect - Converse
8.5. Piezo Options Compared
8.6. Piezo in cars - potential
8.6.1. Piezo EH powered tyre sensor
8.7. Piezo EH in helicopter
8.8. Consumer Electronics
8.9. Benefits of Thin Film
8.10. Benefits of elastomer: KAIST Korea
8.11. Vibration energy harvester (Joule Thief)
8.12. Challenges with high power piezoelectrics

9. CAPACITIVE ELECTROSTATIC
9.1. Principle
9.2. Interdigitated to elastomer
9.3. Capacitive flexible
9.3.1. Dielectric elastomer generators
9.4. MEMS Electrostatic Scavengers
9.4.1. Advanced MEMS capacitive vibration harvester in 2016

10. MAGNETOSTRICTIVE, MICROBIAL, NANTENNA
10.1. Magnetostrictive
10.2. Microbial fuel cells
10.3. Nantenna-diode

11. TRIBOELECTRIC
11.1. Definition
11.2. Triboelectric dielectric series
11.3. Triboelectric dielectric series examples showing wide choice of properties
11.4. Triboelectric nanogenerator (TENG)
11.5. Achievement
11.6. Four ways to make a TENG
11.6.1. Overview
11.6.2. TENG modes with advantages, potential uses
11.6.3. Research focus on the four modes
11.6.4. Parametric advantages and challenges of triboelectric EH

For more information about this report visit http://www.researchandmarkets.com/research/662dp3/energy

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