基于激光联动扫描的单目动态三维主动热成像研究

Monocular dynamic 3D active thermography based on joint laser scanning thermography

  • 摘要: 为了满足对非平面碳纤维复合材料无损检测的需求,文中提出了一种仅使用一台热像仪对运动试件进行主动三维热成像的系统,称为单目动态三维主动热成像。该系统融合了检测对象的三维轮廓与和主动热成像检测,能够对具有复杂几何形状的复合材料试件进行检测,并给出直观的热成像缺陷检查结果。不同于传统的三维主动热成像检测方法需要额外的三维相机获取检测对象表面轮廓信息;该系统不需要独立的三维传感器,而热像仪同时作为三维传感器与温度传感器。为了实现这一功能,在线激光联动扫描热成像的基础上,文中提出了一个统一联动扫描模型和针孔相机投影模型的数学模型,将线激光作为主动热成像的热激励和三维重建的空间编码。在算法中,该模型实现了对重构热图序列和三维形状点云的无特征配准,该配准方法工作快速、稳健,不需要关键点。标准高度试件标定实验结果表明:在1~150 mm的高度测量范围,平均误差0.16 mm,最大误差不超过0.25 mm。碳纤维进气管实验表明,该方法具有大尺寸碳纤维复合材料三维温度场重建与检测检测能力。文中提出的单目三维动态热成像系统结构简单、工作稳定,可用于在生产线的三维测量、缺陷检测和质量控制。

     

    Abstract:
    Objective In order to improve the defect detection capability of large-sized specimens, line scanning thermography has become an effective non-destructive testing method for building, metal, aircraft components and carbon fiber reinforced composite materials. The current line scanning thermography method is difficult to provide intuitive detection results for specimens with complex morphologies. Therefore, the three-dimensional thermography integrating detection specimen surface contour geometric data is receiving increasing attention. In order to meet the demand for non-destructive testing of non-planar carbon fiber composite plastic specimens with complex morphology, this paper proposes a system that uses only one thermal imager to perform active three-dimensional thermography on moving specimens, called monocular dynamic 3D active thermography. The system integrates the 3D contour of the specimen with an active thermography inspection, and is capable of inspecting composite specimens with complex geometries and giving intuitive thermography defect inspection results.
    Methods This proposed monocular dynamic 3D active thermography system consists of a line laser, a thermal camera, an actuator, and a calibration board and does not require an additional 3D profiler (Fig.1). Compared with traditional 3D active thermography detection methods that require additional 3D cameras to obtain surface contour information of the detection object; This system does not require an independent 3D sensor, and the thermal imager acts as both a three-dimensional sensor and a temperature sensor. To achieve this function, based on laser joint line scanning thermography, this paper proposes a mathematical model that unifies the line scanning model and the pinhole camera projection model, and uses the line laser as the thermal excitation for active thermography and the spatial encoding for 3D reconstruction. The algorithm realizes 3D reconstruction, spatio-temporal reconstruction for nondestructive inspection, and the registration of the reconstructed thermogram sequence and the 3D point cloud (Fig.2).
    Results and Discussions Experimental system of monocular dynamic 3D active thermography used FLIR 6702and a 20 W laser with a center wavelength of 808 nm is established (Fig.3). The standard height specimen calibration experimental results show that, in the height measurement range of 1 mm to 150 mm, the average error is 0.16 mm, and the maximum error does not exceed 0.25 mm (Fig.4). The carbon fiber intake pipe experiment shows that the method has the ability to reconstruct the 3D temperature field of large-size carbon fiber composites and detect the defects (Fig.5). Compared with other 3D thermography techniques, the advantage of the proposed system is its simple structure, which is a single camera, single excitation 3D thermography system without the need for additional 3D measuring instruments or complex feature extraction and matching algorithms. The limitation lies in the fact that only laser can be used as both a thermal excitation for active thermal imaging and a spatial encoding for 3D reconstruction. It can only achieve active thermal imaging with laser excitation and has certain limitations on the wavelength distribution and power of the laser. Therefore, the proposed active 3D thermal imaging technology is specifically designed for the detection of carbon fiber composite.
    Conclusions The monocular dynamic 3D active thermography system is proposed in this paper for 3D measurement, defect detection and 3D temperature filed measurement. Based on the joint line scanning thermography, this paper achieves three-dimensional measurement function by the jointly calibration of the inspected object, laser, and infrared camera. With only one calibration board added, this paper proves that thermal imaging can achieve three-dimensional measurement and the experiment distance measurement error is controlled within 0.25 mm. The proposed system works fast, robust, and can be used for quality control on the production line.

     

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