A system for post-cure processing a composite workpiece includes a tool. The tool includes a tool surface. The tool surface supports the composite workpiece located on the tool. The system also includes a drill template. The drill template defines a drilling location for drilling a hole through the composite workpiece while the composite workpiece is on the tool.

An assembling device for manufacturing a panel assembly, which includes at least two tooling systems, which both include wooden slat gripping, positioning and securing means, and insulation panel gripping and positioning means, and a tooling controller communicatively coupled to the tooling systems, wherein the tooling systems are instructed so that, if the length of a wooden slat exceeds a predetermined threshold, the wooden slat gripping means grip the wooden slat at different parts, and are moved relatively to each other in order to align their centerlines and to correct the straightness of the wooden slat.

An assembling device for manufacturing a panel assembly, which includes at least two tooling systems, which both include wooden slat gripping, positioning and securing means, and insulation panel gripping and positioning means, and a tooling controller communicatively coupled to the tooling systems, wherein the tooling systems are instructed so that, if the length of a wooden slat exceeds a predetermined threshold, the wooden slat gripping means grip the wooden slat at different parts, and are moved relatively to each other in order to align their centerlines and to correct the straightness of the wooden slat.

A method for analyzing an overcutting defect of a machining process comprises steps as following. A machining code is executed to generate a cutting face, wherein the cutting face comprises a plurality of machining paths. A specified machining path is defined from the plurality of machining paths and a specified node is set on the specified machining path. A sectional plane passing through the specified node is calculated. A plurality of intersection points between the sectional plane and the other machining paths which are different from the specified machining path are obtained. A first adjacent intersection point a second adjacent intersection point are specified from the intersection points. A connection line located between the first adjacent intersection point and the second adjacent intersection point is obtained. A distance between the specified node and connection line is calculate and the distance is defined as an overcutting amount of the specified node.

A method for analyzing an overcutting defect of a machining process comprises steps as following. A machining code is executed to generate a cutting face, wherein the cutting face comprises a plurality of machining paths. A specified machining path is defined from the plurality of machining paths and a specified node is set on the specified machining path. A sectional plane passing through the specified node is calculated. A plurality of intersection points between the sectional plane and the other machining paths which are different from the specified machining path are obtained. A first adjacent intersection point a second adjacent intersection point are specified from the intersection points. A connection line located between the first adjacent intersection point and the second adjacent intersection point is obtained. A distance between the specified node and connection line is calculate and the distance is defined as an overcutting amount of the specified node.

A method for generating a movement path of a tool configured to utilize a virtual path to generate a correct path that fits an allowable error is provided. The method includes a receiving step implemented by receiving the virtual path and a precision data; an auxiliary point establishing step implemented by adding a plurality of auxiliary points in a plurality of arc sections; a moving and detecting step implemented by controlling the tool to sequentially move to a plurality of predetermined points and the auxiliary points according to the virtual path; and a calculating step implemented by amending the predetermined points or the auxiliary points in the virtual path if a difference between a real-time position coordinate and corresponding one of the predetermined points or the auxiliary points is greater than the allowable error to generate the correct path.

A method for generating a movement path of a tool configured to utilize a virtual path to generate a correct path that fits an allowable error is provided. The method includes a receiving step implemented by receiving the virtual path and a precision data; an auxiliary point establishing step implemented by adding a plurality of auxiliary points in a plurality of arc sections; a moving and detecting step implemented by controlling the tool to sequentially move to a plurality of predetermined points and the auxiliary points according to the virtual path; and a calculating step implemented by amending the predetermined points or the auxiliary points in the virtual path if a difference between a real-time position coordinate and corresponding one of the predetermined points or the auxiliary points is greater than the allowable error to generate the correct path.

The invention relates to a transport system, in particular to a multi-carrier system, comprising a central control; a plurality of drive units, wherein the drive units are coupled to the central control by means of a data link; and a plurality of transport elements that are movable by means of the drive units, wherein the central control is configured to communicate control commands to the drive units, with the control commands causing the drive units to make a movement of the transport elements in dependence on the control commands. The transport system in accordance with the invention is characterized in that at least two of the drive units, preferably all the drive units, receive the same control commands.

Plant for additively manufacturing at least one three-dimensional object, comprising at least one process station being configured to perform an additive manufacturing process and/or at least one preprocessing process for an additive manufacturing process and/or at least one postprocessing process for an additive manufacturing process; at least one conveying device configured to convey an item between at least two positions (P1, P2) of the plant, the conveying device comprising at least one conveying element, the at least one conveying element being at least partially bound to ground, and at least one conveying carriage being connectable or connected with the conveying element so as to be moveable between at least two positions (P1, P2) of the plant, the at least one conveying carriage comprising at least one supporting interface for supporting at least one item.

In a quick measurement module provided by the present invention, a first distance sensing unit and a second distance sensing unit are provided individually on a movable seat, so that when the movable seat is displaced along a linear shifting axis, the first distance sensing unit senses the distance from the first reference plane, and meanwhile, the second distance sensing unit senses the distance from the second reference plane, so as to sense the linearity accuracy in movement of the movable seat with respect to the first reference plane and the second reference plane. The first reference plane and the second reference plane are spaced apart by an angle other than a right angle, so that the linearity accuracy in movement in the two different planes, such as the horizontal linearity accuracy and vertical linearity accuracy, of the movable seat can be obtained through sensing.