Abstract: The invention provides a drop hammer height adjusting device for high strain detection of a pile foundation, the device comprises: a cross beam support frame, an avoiding hole is opened in the middle of the surface of the cross beam support; a track extending through the avoiding hole, a tooth group is arranged on each of two surfaces of the track bar, and abutting sliding blocks are further arranged at two sides of the track bar. The abutting sliding block is cooperated with the tooth group to limit the position of the track bar. The invention overcomes the significant disadvantages of the existing detection devices, the efficiency of obtaining qualified test signals is improved by the rapid and accurate height adjustment and test, and the precision and efficiency of high strain detection of a foundation pile are greatly improved.

Abstract: A method for producing a living tissue and organ includes: collecting medical image information of a target tissue and organ, and converting the medical image information into three-dimensional image information; performing machine recognition and multiple feature comparisons on the three-dimensional image information, and generating a primary three-dimensional model according to physiological structure data of tissues and organs in a tissue and organ database and a residual profile of the target tissue and organ; generating a complete three-dimensional model by producing an internal microstructure of the primary three-dimensional model with reference to the tissue and organ database; producing a full-scale physical model based on the complete three-dimensional model by an additive manufacturing process; and performing a living cell-based tissue reconstruction in the full-scale physical model to produce a living tissue and organ.

Abstract: A method for producing a living tissue and organ includes: collecting medical image information of a target tissue and organ, and converting the medical image information into three-dimensional image information; performing machine recognition and multiple feature comparisons on the three-dimensional image information, and generating a primary three-dimensional model according to physiological structure data of tissues and organs in a tissue and organ database and a residual profile of the target tissue and organ; generating a complete three-dimensional model by producing an internal microstructure of the primary three-dimensional model with reference to the tissue and organ database; producing a full-scale physical model based on the complete three-dimensional model by an additive manufacturing process; and performing a living cell-based tissue reconstruction in the full-scale physical model to produce a living tissue and organ.

Abstract: The invention provides a drop hammer height adjusting device for high strain detection of a pile foundation, the device comprises: a cross beam support frame, an avoiding hole is opened in the middle of the surface of the cross beam support; a track extending through the avoiding hole, a tooth group is arranged on each of two surfaces of the track bar, and abutting sliding blocks are further arranged at two sides of the track bar. The abutting sliding block is cooperated with the tooth group to limit the position of the track bar. The invention overcomes the significant disadvantages of the existing detection devices, the efficiency of obtaining qualified test signals is improved by the rapid and accurate height adjustment and test, and the precision and efficiency of high strain detection of a foundation pile are greatly improved.

Abstract: A method and a system for constructing prosthesis for defect part of tissues and organs are provided. The method includes the steps of obtaining a tissue defect site of a patient; collecting original image data of the tissue defect site of the patient, restoring an original three-dimensional image of the tissue defect site and a three-dimensional image of a defect part corresponding to the defect site, and generating and storing a three-dimensional model for mending the defect part; performing simulated mending on the basis of the three-dimensional model for mending the defect part and a tissue defect model; obtaining a three-dimensional model for mending the defect part, printing the three-dimensional model for mending the defect part and generating a physical model of the prosthesis.