2023
DOI: 10.3390/mi14051058
|View full text |Cite
|
Sign up to set email alerts
|

A High-Reliability Piezoelectric Tile Transducer for Converting Bridge Vibration to Electrical Energy for Smart Transportation

Abstract: Piezoelectric energy transducers offer great potential for converting the vibrations of pedestrian footsteps or cars moving on a bridge or road into electricity. However, existing piezoelectric energy-harvesting transducers are limited by their poor durability. In this paper, to enhance this durability, a piezoelectric energy transducer with a flexible piezoelectric sensor is fabricated in a tile protype with indirect touch points and a protective spring. The electrical output of the proposed transducer is exa… Show more

Help me understand this report

Search citation statements

Order By: Relevance

Paper Sections

Select...
1

Citation Types

0
1
0

Year Published

2024
2024
2024
2024

Publication Types

Select...
3

Relationship

0
3

Authors

Journals

citations
Cited by 3 publications
(1 citation statement)
references
References 19 publications
0
1
0
Order By: Relevance
“…This LoRa technology transceiver is connected from its RXD (3) and TXD (4) pins to the TXD/GOIO01 and RXD/GOIO02 pins of the TTGO ESP32 SIM800L respectively. The battery with the capacity of 1500 mAh was used to supply energy to the system, as seen in Figure 3(c), and a TP4056 charging circuit to connect to the lithium battery that is charged through a universal micro USB connector [27] as shown in Figure 3(d), this module will be connected to the positive and negative pin of the battery through its pins B+ and B-respectively. The charge supplied by the battery is measured by the analog input 3(e), so that when the patient begins to walk, energy is generated that can be used to increase the discharge time of the battery.…”
Section: Description Of the System Parts 241 Wearable Emittermentioning
confidence: 99%
“…This LoRa technology transceiver is connected from its RXD (3) and TXD (4) pins to the TXD/GOIO01 and RXD/GOIO02 pins of the TTGO ESP32 SIM800L respectively. The battery with the capacity of 1500 mAh was used to supply energy to the system, as seen in Figure 3(c), and a TP4056 charging circuit to connect to the lithium battery that is charged through a universal micro USB connector [27] as shown in Figure 3(d), this module will be connected to the positive and negative pin of the battery through its pins B+ and B-respectively. The charge supplied by the battery is measured by the analog input 3(e), so that when the patient begins to walk, energy is generated that can be used to increase the discharge time of the battery.…”
Section: Description Of the System Parts 241 Wearable Emittermentioning
confidence: 99%