An automatic assembling apparatus includes a pair of parallel conveyers for transferring carriers, each carrier having four chassis and parts to be assembled on the chassis; a plurality of assembly stations, each having a movable table on which various assembling operations can be performed with respect to the carriers; a carrier loader associated with each assembly station and movable between a first position in opposing relation to the movable table thereof and a second position in opposing relation to the conveyers, and having a pair of chucking stations in opposing relation to the pair of parallel conveyors, respectively, when the carrier loader is at the second position for simultaneously feeding and discharging the carriers to and from the conveyers and in opposing relation to the respective assembly station when the carrier loader is at the first position for feeding and discharging the carriers to and from the respective assembly station; a plurality of stopping members associated with respective ones of the assembly stations for selectively stopping carriers adjacent respective ones of the assembly stations; and sensing elements for detecting the presence of the carriers on the pair of parallel conveyers for controlling the stopping members in response thereto so as to selectively stop carriers adjacent respective ones of the assembly stations.

An industrial robot control method for use in a system having a machine tool (MAC), a numerical control device (NCU) for controlling the machine tool, an industrial robot (RBT), and a robot control device (RCU) for controlling the industrial robot. In accordance with this industrial robot control method, a plurality of robot programs are stored beforehand in an internal memory (DMR) of the robot control device (RCU), and a plurality of NC programs are stored beforehand in an internal memory (DMN) of the numerical control device (NCU). The size or shape of a workpiece is sensed by a workpiece discriminating unit (WKD) to select the robot program conforming to the particular workpiece. An NC program number, corresponding to the robot program, is transmitted from the robot control device (RCU) to the numerical control device (NCU). The machine tool (MAC) is controlled in accordance with the NC program identified by NC program number, and the robot (RBT) is controlled based on the selected robot program.

A flexible manufacturing system which includes a stack yard, a machine tool and a stacker crane. In the stack yard, a pallet group, formed by stacking a number of pellets, is stored. The pallet group is transferred to a machine tool cell by the stacker crane. Each pallet has a memory, and data of the pallet itself and the member loaded on the pallet are memorized by the pallet. There are various kinds of members such as work-piece, tool and chuck jaw. These members are stored on exclusive pallets made for each kind of the member. Of the members, each tool and chuck jaw has its own memory and memorizes its own data. The data of all the memory can be read and written; therefore, the position of the pallet, tool and chuck jaw can be controlled at all times.

A machining system that has (i) plural machining cells spaced along a path, each having a single-point-tool and a rapid-positioning assembly for positioning the tool for multiple insertions into a workpiece as well as rapid tool exchange at speed rates that approach or exceed one G; (ii) table means for presenting a table surface in a selected plane for each cell; (iii) workpiece means for each table surface having keying surfaces for lockingly mating with a reference point of such table surface; (iv) transfer means for rapidly replacing a machined workpiece with an unmachined workpiece on a table surface, the just-machined workpiece being transferred to the next table surface while the substituted workpiece is undergoing machining; and (v) programmed electrical control means for activating the positioning assemblies and transfer means. A method of machining, comprising: (a) locking a workpiece on a fixture having dimensional keys and releasably securing such fixture on an adjustable worktable in a predetermined first position facilitated by said keys; (b) adjacent each worktable, rapidly positioning a rotary single-point-tool for linear feed into a first of said workpiece surfaces while in a first position, said positioning being carried out at accelerations/decelerations of at least about one G; (c) feeding the rotating tool into the workpiece to carry out machining at speeds of 1-1300 inches per minute for drilling and boring, and at least about 5000 sfm for milling; (d) after withdrawing the tool from the workpiece, repositioning the single-point-tool for another linear feed into other workpiece surfaces or transfer to another tool.

A sequential phase convertible machine comprising at least one machining unit, but preferably two machining units placed opposite each other, a machining table which is provided with an undexable rotary plate and means for fixing the work pieces to be machined and which is disposed opposite the machining unit or between two machining units, conveyors adapted for moving supports on which the work pieces to be machined are fixed a magazine of machining boxes or heads adaptable to the machining units, and transport means adapted for taking said cases from the magazine and bringing them close to the machining unit or units as well as to return them then to the magazine, which machine further comprises means for effecting cyclic sequential or batch machining.