Aspects of the present disclosure generally relate to attenuating the effects of slugging based on one or more measurements of parameters from one or more locations in one or more wells. In some cases, a controller may be configured to attenuate the effects of slugging based on the one or more parameters, for example, by controlling a choke or an artificial lift. In certain aspects, the one or more locations may include downhole or at the surface of the one or more wells.

A remote adhesive monitoring system is used in connection with adhesive applied to workpieces moving along a production line. A reservoir, pump, and applicator apply the adhesive to the workpieces. A monitor control computer has an associated data processing program. A pump cycle sensor senses pump cycles. An applicator sensor senses when the adhesive is applied to the workpieces. A workpiece sensor senses the workpieces moving along the line. The monitor control uses input from the applicator sensing means and the workpiece sensor to determine an ON time per each workpiece at a predetermined speed. The monitor control uses input from the workpiece sensor and the pump cycle sensor to determine the number of workpieces per pump cycle. The monitor control calculates an ON time to TOTAL time ratio per each workpiece. The monitor control will then calculate an amount of adhesive used for the given ON time to TOTAL time ratio.

At least a part of at least one body is coated. At least one processor determines a respective resulting coating layer based on simulating moving the respective body at least partially through a coating fluid of a dipping bath along different trajectories. The at least one processor determines a first trajectory out of the different simulated trajectories fulfilling one or more pre-defined conditions and causes at least one drive component for moving the respective body to move the respective body at least partially through the coating fluid of the dipping bath along the first trajectory.

A remote adhesive monitoring system is used in connection with adhesive applied to workpieces moving along a production line. A reservoir, pump, and applicator apply the adhesive to the workpieces. A monitor control computer has an associated data processing program. A pump cycle sensor senses pump cycles. An applicator sensor senses when the adhesive is applied to the workpieces. A workpiece sensor senses the workpieces moving along the line. The monitor control uses input from the applicator sensing means and the workpiece sensor to determine an ON time per each workpiece at a predetermined speed. The monitor control uses input from the workpiece sensor and the pump cycle sensor to determine the number of workpieces per pump cycle. The monitor control calculates an ON time to TOTAL time ratio per each workpiece. The monitor control will then calculate an amount of adhesive used for the given ON time to TOTAL time ratio.

A liquid material application device can alleviate programming work for drawing a line. The device includes a discharge head (50) for discharging a liquid material, a worktable (25) on which a workpiece is placed, a robot (20) for moving the discharge head and the worktable relative to each other in XYZ directions, and a control unit including an arithmetic device and a storage device for storing an application program, the liquid material application device applying the liquid material to be drawn in the form of a line on the workpiece while the workpiece and the discharge head are moved relative to each other, the control unit includes a first control unit (30) for moving the workpiece and the discharge head relative to each other in accordance with the application program, and a second control unit (40) for controlling a discharge amount of the discharge head.

An object of the invention is to provide a flow rate control valve assembly capable of preventing a flow rate from varying in a direction opposite to the desired direction upon flow rate control As shown in FIG. 1, the flow rate control valve assembly comprises a sliding shaft and a sliding cylindrical surface which fit slidably in with each other in an axial direction, and a moving mechanism for moving the sliding shaft in an axial direction. At least one of the sliding surface of the sliding shaft and the sliding cylindrical surface is provided with one or a plurality of tapered grooves having its specific area defining a fluid passage. The tapered groove is configured such that flow passage resistance increases or decreases gradually along a lengthwise direction, and a cavity formed at an end of the sliding shaft for making sure of a sliding area is formed at a site isolated or shut off from the fluid passage.

A single point sensing system may include a microscope having a field of view, a single-point sensor having a focal point, a stage to support a substance, an actuator to move at least one of the single-point sensor and the stage relative to one another, and in alignment controller. The alignment controller is to identify a location of the substance on the stage based upon signals from the microscope and output sensor alignment signals to the actuator to align the location of the substance on the stage with the focal point of the single-point sensor based upon the identified location of the substance.

A simulation method for a coating installation including: a) specification of geometric data of the component to be coated, b) specification of general coating parameters, c) specification of starting values of coating parameters to be adjusted, including a coating path and current spray patterns for the individual path points of the coating path, whereby the current spray patterns represent the coating thickness distribution on the component, d) program-controlled execution of a simulation loop, including: calculation of a simulated coating result by computational superimposition of the current spray patterns provided for the individual path points of the coating path, taking into account the degree of wetness, testing the simulated coating result, taking into account the degree of wetness, adjusting the coating parameters to be optimized and repeat the simulation loop if the simulated coating result is not satisfactory,. terminating the simulation loop if the simulated coating result is satisfactory.

A supply system (1) and process supply a medical device with a fluid. A fluid supply port (3, 4, 5) of a supply unit (2) provides a fluid. An actuating unit (6a, 6b) detects an actuation of an actuating element (7a, 7b) and generates a message containing actuation information, which identifies the actuation. The message is transmitted via a wireless data connection (Dv) from a transmitter (8) of the actuating unit (6a, 6b) to a receiver (9) of the supply unit (2). The supply unit (2) changes a parameter of the fluid supply port (3, 4, 5), which influences the provision of fluid, in response to the reception of this message.

A supply system (1) and process supply a medical device with a fluid. A fluid supply port (3, 4, 5) of a supply unit (2) provides a fluid. An actuating unit (6a, 6b) detects an actuation of an actuating element (7a, 7b) and generates a message containing actuation information, which identifies the actuation. The message is transmitted via a wireless data connection (Dv) from a transmitter (8) of the actuating unit (6a, 6b) to a receiver (9) of the supply unit (2). The supply unit (2) changes a parameter of the fluid supply port (3, 4, 5), which influences the provision of fluid, in response to the reception of this message.