According to one embodiment, a liquid cooling leakage abatement system includes a systems manager having executable instructions for obtaining location information for each of a plurality of components of a computing cluster in which at least a portion of the components are cooled by a liquid cooling system via a liquid coolant. When the systems manager receives leakage information associated with a leak in the liquid cooling system used to cool a first component, it infers a second component that is affected by the leak, and generates an alert message indicating that the first and second components that are affected by the leak.

A component shortage detection device detects a component shortage of a tape feeder installed in a component mounting device. The component shortage detection device includes a sensor, configured to detect the tape, and provided at a position that is a midpoint of a tape transportation path of the tape feeder and upstream of a component extraction position by a component mounting head in a tape transportation direction. The component shortage detection device further includes a residual quantity calculation unit configured to calculate a component residual quantity of the tape during a mounting operation; and a determination unit configured to determine whether a component shortage occurs on a basis of output information from the sensor and the component residual quantity when the head fails in extraction of the component.

A case for an electronic cigarette vaporiser, the case including an automatic lifting mechanism that lifts the vaporiser up a few mm from the case to enable a user to easily grasp the vaporiser and withdraw it from the case. The lifting mechanism can be spring- based. The case both re-fills the vaporiser with liquid and also re-charges a battery in the vaporiser.

A system, apparatus and method for cutting battery grids or plates from a continuous strip of a plurality of connected battery grids. The continuous strip moves toward a rotating cutter with at least two cutter blades with cutting edges equally circumferentially spaced apart and extending parallel to the cutter axis of rotation and a rotating cooperating anvil. The cutting edges and the anvil are rotated at the same tangential speed to cut in a nip between them a plate or grid from the continuous strip of connected grids. At a point upstream of the cutter, an electric signal indicative of each lug of the grid of the continuous strip moving past this point is used to control the speed of movement of the strip through the nip to cut a plate or grid from the continuous strip at a longitudinal speed which is essentially the same as the tangential speed of the cutting edges.

A numerical controller, which is capable of controlling an output value without causing delay or the like in feedback control, includes an instruction program analysis unit configured to analyze a program instruction and generate instruction data instructing movement of the axis, and a speed computation unit configured to start speed computation processing to compute a feeding speed of the axis by the instruction data or an override for the feeding speed by feedback control such that the spindle load value becomes constant. The speed computation unit is configured to update a feature amount intended for elimination of deviation between a desired value and a feedback value in the feedback control when another override that is different than the override that has been computed is output. The feature amount is updated to a value obtained by back calculation from the other override that is to be output.

A working machine feed axis control device: disposes a velocity feedback loop and forms a cascade coupling on the inner side of a location feedback loop; comprises a velocity gain setting apparatus (30) which multiplies the output of the velocity feedback look by a first gain (kv), and a location gain setting apparatus (31) which multiplies the output of the location feedback loop by a second gain (kp); subtracts the output of the velocity gain setting apparatus (30) and the output of the location gain setting apparatus (31) from a torque instruction (τ); and outputs the remaining torque instruction (τ) to a subject to be controlled (27).

Disclosed are a method, apparatus and system for presenting a spraying operation, wherein the method comprises: acquiring a spray coefficient of an operating device at an operation position corresponding to a sampling point, wherein the spray coefficient is used for representing a spray quantity of the operating device at the operation position (S102); acquiring color information corresponding to the spray coefficient of the operation position (S104); and presenting the operation position and the color information corresponding to the operation position (S106). The method solves the technical problems that a spray quantity at a specific position in a target region cannot be determined, and spray efficiency is low.

A toolpath topology design method based on vector field in sub-regional processing for the curved surface is disclosed which comprising: finding the functional relationships in feeding direction between the chord error and the normal curvature and between the scallop-height error and the normal curvature; establishing the bi-objective optimization model and calculating the optimal feeding direction at each cutting contact point within the surface through the constructed evaluation function, the space vector field is built; calculating divergence and rotation of the projected vector field and according to whether them are zeros or not to classify different sub-regions, the primary surface segmentation is achieved, etc. The method is applied for the complex curved surface processing, which can reduce the machining error and enhance the feed motion stability.

The invention relates to a container processing system (10A-10U) for processing containers (12). The container processing system (10A-10U) has a plurality of processing units (22) for processing the containers (12) and a planar drive system (14) for transporting the containers (12). The planar drive system (14) is configured to move the plurality of movement devices (18) individually to a selection of the plurality of processing units (22) according to in each case one of a plurality of processing profiles for different container processing, wherein each of the plurality of processing profiles has a different selection of the plurality of processing units (22). The container processing system (10A-10U) advantageously allows flexible processing of different containers (different formats, contents, designs, bundles, packages, etc.) from a lot size of 1.

In one embodiment, an electronic system comprises a display device to display data and processing logic coupled to the display device. The processing logic is configured to determine a duty cycle of at least one sensor for sensing flow of a product or particle through a product or particle line of an agricultural implement and to determine an amount of product or particles flowing through a line of the agricultural implement based on the duty cycle of the at least one sensor.