# Design and Study of a PVDF Piezoelectric Film Force Sensor Based on Interface Force Field Reconstruction and Surface Domain Segmentation

**Authors:** Kaiqiang Yan, Wenge Wu, Xinyi Wu, Yunping Cheng, Lijuan Liu, Yongjuan Zhao, Yicheng Zhang, Pengcheng Liu, Zhi Wang

PMC · DOI: 10.3390/mi17020262 · 2026-02-19

## TL;DR

This paper presents a new PVDF piezoelectric film sensor design that can accurately measure three-dimensional forces with high sensitivity and linearity.

## Contribution

A novel sensor design using interface force field reconstruction and surface domain segmentation to enable multi-dimensional force measurement with PVDF film.

## Key findings

- The sensor achieved charge sensitivities of 52.63 pC/N (X), 55.96 pC/N (Y), and 9.02 pC/N (Z) with linearity ≤4.6%.
- The sensor has a natural frequency of 4675.5 Hz, indicating good dynamic performance.
- The sensor successfully captured triaxial cutting forces under varying machining parameters.

## Abstract

The accurate measurement of dynamic forces is pivotal for advancing manufacturing process monitoring and enhancing equipment intelligence. To address the challenges of contact interface force field nonlinearity in existing PVDF piezoelectric film force sensors and the inability of a monolithic PVDF piezoelectric film to measure multi-dimensional forces, this study designs a uniform-load double-bossed elastic force-transmitting diaphragm to achieve contact interface force field reconstruction between the sensor’s elastic sensing structure and the sensitive element group. Building upon the load-bearing surface domain segmentation technique, the silver ink electrode on the front surface of a complete circular PVDF piezoelectric film is segmented into four independent sector-shaped rings. Each sector ring, together with its underlying PVDF piezoelectric film, constitutes a sensitive element, and these four sensitive elements are integrated to form the sensitive element group. The three-dimensional force measurement method of this sensitive element group in the Cartesian coordinate system is investigated. The measurement of three-dimensional force is realized by leveraging the tensile-compressive piezoelectric effect of each sensitive element in conjunction with a pre-stressed assembly structure. Quasi-static calibration test results indicate that the charge sensitivities of the force sensor in the X-, Y-, and Z-directions are 52.63 pC/N, 55.96 pC/N, and 9.02 pC/N, respectively, with a linearity ≤4.6%. Dynamic calibration test results reveal that the force measurement module exhibits a natural frequency of 4675.5 Hz. Experimental investigations into the response of triaxial cutting forces to variations in cutting speed, feed rate, and cutting depth were conducted, which verified the sensor’s ability to capture dynamic three-dimensional cutting forces. This study provides an effective solution for the structural design and three-dimensional force measurement methodology of PVDF piezoelectric film force sensors.

## Full-text entities

- **Diseases:** injury to (MESH:D014947)
- **Chemicals:** PVDF (MESH:C024865), Silver Ink (-), Silver (MESH:D012834), PI (MESH:D010716)
- **Species:** Homo sapiens (human, species) [taxon 9606]

## Figures

15 figures with captions in the complete paper: https://tomesphere.com/paper/PMC12943619/full.md

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Source: https://tomesphere.com/paper/PMC12943619