Abstract: The invention relates to an automobile drive shaft bushing, comprising a bushing body, wherein, a connecting cavity is arranged in the bushing body, a first annular flange and a second annular flange are arranged in the middle of the bushing body, multiple fixing holes are arranged on the peripheral surface of the first annular flange and the second annular flange, the fixing holes are communicated with the connecting cavity, the bushing body is sleeved on the drive shaft, multiple connecting holes corresponding to the fixing holes are arranged on the peripheral surface of the drive shaft. Thus, the shaft bushing and the drive shaft are connected firmly; meanwhile, two ends of the bushing body are welded to the junction of the drive shaft with a circular welding method, which ensures the sealing property of the connection between the ends of the bushing body and the drive shaft.
Abstract: An automatic machining device for shaft body includes a blank cutting mechanism and an automatic blank feed mechanism arranged at one side of the blank cutting mechanism, wherein, a machining platform is arranged at one side of the automatic blank feed mechanism, and a numerical control machine tool is arranged above the machining platform, thus realizing automatic cutting, feeding and machining of blanks.
Abstract: A process of manufacturing a drive shaft of an explosion-proof motor, the drive shaft having a cylindrical section and a spline section, the process includes the steps of horizontally disposing the drive shaft; continuously forward moving the drive shaft; feeding both a milling cutter and a correction roller toward the drive shaft wherein the correction roller is coaxial with a shaft of a lathe; activating the milling cutter to mill a front end of the drive shaft; and activating the correction roller to correct any deformations generated by the milling. The correction roller is made of diamond. The cylindrical section has a deformation of less than 0.02 mm per 200 mm of length, and the spline section has a deformation of less than 0.02 mm per 250 mm of length.
Abstract: A process of manufacturing a feed screw includes the steps of arranging three dies spaced apart 120-degree each other so as to limit a radial movement of an elongated blank feeding through a space defined by the dies; clockwise rotating the dies to cut threads on the blank; performing a thread grinding on the threads of the blank; and cutting the blank into a finished feed screw per predetermined period of time. The blank is fed through a sleeve for positioning prior to the blank feeding. Cylindrical degree of the finished feed screw is less than 0.1 mm/1,000 mm and its pitch error is 0.05 mm/100 threads.