Nondestructive testing (NDT) on the basis of elastic waves as a perfect solution to monitoring and testing of the quality of reinforced concrete (RC) structures, the transient elastic wave system with the strength of in-situ measurement requires a specialist in charge of signals reading on the basis of precise travel time of wave velocity before further assays can be done. Accordingly, this study proposes a new approach to improve the transient elastic wave system and the author utilized artificial intelligence (AI) to support the transient elastic wave system that detects where surface breaking cracks are in RC structures. Currently, artificial neural networks (ANNs) of deep learning (DL) develop the fastest in the domain of AI where this study employed the ANNs model based on deep neural networks (DNNs) and convolutional neural networks (CNNs). Firstly, to generate the database of the ANNs model, this study obtained the database via the finite-difference methods (FDM) that computed considerable signals in theory. Secondly, normalized the signals and input them in the ANNs model for training and testing, and managed to speed up gradient descent for obtaining the optimum and promoting the convergence rate. Thirdly, how the ANN model was affected by the count of hidden layers and neurons, the distribution of convolution and pooling layers and the size and quantity of filters was gradually investigated. Fourthly, the author developed the optimal neural networks model fitted to the database in this study. Lastly, the ANN model applied to trials that predicted surface breaking cracks in RC structures. Based on the findings, the trial signals processed with windows snapshot helped tackle the impacts of time origin and noise on the model. After adding the new sensor data, the model obtained more characteristics helpful to identify the trial measurement signals. By doing so, the length and angle errors predicted by the model dropped from 0.51cm and 10.79 degrees to 0.17cm and 4.23 degrees. Overall, this study employed the ANNs model of DL to detect surface breaking cracks in RC structures, which not only makes the operator monitor and assess the quality of buildings in a real-time manner but also lets non-professionals operate such system. As the diversified database is broadened to a wider measurement scope for in-situ measurement, such model can be more useful and handy in terms of its application.