BS IEC 62830-6:2019
$142.49
Semiconductor devices. Semiconductor devices for energy harvesting and generation – Test and evaluation methods for vertical contact mode triboelectric energy harvesting devices
| Published By | Publication Date | Number of Pages |
| BSI | 2019 | 28 |
This part of IEC 62830 defines terms, definitions, symbols, and specifies configurations and test methods to be used to evaluate and determine the performance characteristics of vertical contact mode triboelectric energy harvesting devices for practical use. This document is applicable to energy harvesting devices as power sources for wearable devices and wireless sensors used in healthcare monitoring, consumer electronics, general industries, military and aerospace applications without any limitations on device technology and size.
PDF Catalog
| PDF Pages | PDF Title |
|---|---|
| 2 | National foreword |
| 4 | CONTENTS |
| 6 | FOREWORD |
| 8 | 1 Scope 2 Normative references 3 Terms and definitions 3.1 General terms |
| 9 | 3.2 Triboelectric transducer Figures Figure 1 – Vertical contact mode triboelectric energy harvester |
| 10 | 3.3 Characteristic parameters Figure 2 – Fundamental theories of four working modesof vertical contact mode triboelectric energy harvester |
| 11 | Figure 3 – Equivalent circuit of triboelectric energy harvester |
| 12 | 4 Essential ratings and characteristics 4.1 Identification and type 4.2 Limiting values and operating conditions 4.3 Additional information 5 Test method 5.1 General Table 1 – Specification parameters for vertical contact mode triboelectric energy harvester |
| 13 | Figure 4 – Measurement procedure of verticalcontact mode triboelectric energy harvester |
| 14 | 5.2 Electrical characteristics 5.2.1 Test procedure Figure 5 – Test setup for the electrical characteristicsof vertical contact mode triboelectric energy harvester |
| 15 | 5.2.2 Open-circuit voltage 5.2.3 Short-circuit current Figure 6 – Instantaneous open-circuit output voltage characteristics |
| 16 | 5.2.4 Output voltage 5.2.5 Output current Figure 7 – Instantaneous short-circuit output current characteristics Figure 8 – Output voltage and current of triboelectricenergy harvester under different loads |
| 17 | 5.2.6 Output power 5.2.7 Optimal load impedance 5.2.8 Maximum output power 5.2.9 Stored charge Figure 9 – Output power of triboelectric energy harvester at various external loads |
| 18 | 5.2.10 Capacitance Figure 10 – Stored charging time relationship at differentload capacitances of triboelectric energy harvester Figure 11 – Capacitance between the two electrodes of a triboelectric energy harvester |
| 19 | 5.3 Mechanical characteristics 5.3.1 Test procedure 5.3.2 Contact area Figure 12 – Block diagram of a test setup for evaluatingthe reliability of vertical contact mode triboelectric energy harvester |
| 20 | 5.3.3 Input force Figure 13 – Instantaneous open-circuit voltage characteristics for four differentcontact areas of contact mode triboelectric energy harvester Figure 14 – Output voltage and current under different input forceson vertical contact mode triboelectric energy harvester |
| 21 | 5.3.4 Input frequency 5.3.5 Relative humidity range Figure 15 – Output voltage and current under different working frequencieson vertical contact mode triboelectric energy harvester |
| 22 | 5.3.6 Temperature range Figure 16 – Triboelectric output voltage as a function of relative humidity Figure 17 – Open-circuit voltage of triboelectric energyharvester at different temperatures |
| 23 | Annex A (informative)Vertical contact modes A.1 Double electrode mode A.2 Single electrode mode Figure A.1 – Operation mode of vertical contact mode triboelectric energy harvester |
| 24 | Annex B (informative)Test setup for vertical contact mode triboelectric energy harvester B.1 Example of test setup and characterization B.2 Experimental data Figure B.1 – Measurement setup for vertical contact mode triboelectric energy harvester |
| 25 | Figure B.2 – Electrical characterization results of the pressure-voltage relationship |
| 26 | Bibliography |
