A method for controlling a filling process, wherein a predetermined filling quantity of a medium is filled into a container, the flow rate of the medium flowing into the container is measured as a time series of measured values for the instantaneous flow rate and a filling quantity already filled is estimated from the time series, wherein at least one current measured value of the time series is corrected on the basis of at least one earlier measured value of an earlier time series of measured values of the flow rate of an earlier filling process.

An apparatus, method and system providing for calibration and/or control of a liquid dispensing system is disclosed. The hand-held calibration auditing tool includes a flow meter (36-37) with inlets adapted for quick connection to one or more liquid inputs and/or liquid outputs of a liquid dispensing system (10). A sensor (94-95) having a data output of liquid flow information for a liquid input to the dispensing system (10) is operably connected to a controller (12) to receive the liquid flow information for the liquid input. The controller (12) provides a dilution rate and other liquid flow information for a liquid product input to a dispenser. The tool may include any number of flow meters, and may also include a flow meter connected to an outlet of a dispenser (22) for providing flow information.

An example method of filling epoxy in a fiber optic connector includes: applying the epoxy to a ferrule of a first connector at a first pressure for a first period of time; applying the epoxy to the first connector at a second pressure for a second period of time until the epoxy is sensed to exit a hole defined by the ferrule of the first connector; comparing the second period of time to a threshold; when the second period of time is greater than the threshold, increasing the first pressure, the first period of time, or the second pressure; and when the second period of time is less than the threshold, decreasing the first pressure, the first period of time, or the second pressure.

A method for operating a flowmeter is disclosed. The flowmeter has a sensor for capturing a measured variable indicating the flow, and for converting the measured variable into a signal. The flowmeter also has a control and evaluation unit that determines a flow measurement value for the flow from the signal and outputs an output value representing the flow measurement value. The method includes: determining flow measurement values; forming smoothed flow measurement values over a plurality of flow measurement values, respectively; and activating a low flow cut-off. When the low flow cut-off is activated, the output value is set to zero if: the current smoothed flow measurement value is below a first predetermined limit value; and a predetermined number of flow measurement values has been determined with deactivated low flow cut-off or a predetermined number of smoothed flow measurement values has been formed with deactivated low flow cut-off.

Systems and methods for closed loop fluid velocity control for jetting are disclosed. A method includes dispensing a first volume of viscous fluid from a nozzle of a dispensing device according to a first value of an operating parameter that affects the exit velocity of the first volume. A characteristic of the first volume is measured using a sensor. The characteristic of the first volume is then compared to a range of values to determine whether the characteristic of the first volume is outside of the range. The value of the operating parameter is adjusted to a second value in response to determining that the characteristic of the first volume is outside the range. A second volume of viscous fluid is dispensed according to the second value of the operating parameter. The exit velocity of the second volume is different than the first volume.

A system for delivery of a volume of infusible fluid. The system includes a controller configured to calculate a trajectory for delivering infusible fluid, the trajectory comprising at least one volume of fluid, and determine a schedule for delivering the at least one volume of fluid according to the trajectory, wherein the schedule comprising an interval and a volume of infusible fluid for delivery. The system also includes a volume sensor assembly for determining the at least one volume of fluid delivered, wherein the controller recalculates the trajectory based on the volume of fluid delivered.

A liquid evaluation system can include a cartridge including a channel configured to pull a liquid into the channel by capillary action. The cartridge can include a first plate and a second plate located in close proximity to the first plate. An internal facing surface of each plate can include a corresponding region forming the channel. Each of the regions can have an affinity for the liquid. The close proximity of the plates and the regions having an affinity for the liquid cause the liquid to be pulled into the channel by capillary action. The cartridge can include one or more additional attributes and/or the system can include one or more additional components for performing the evaluation.

A chemical delivery system connects to a chemical tank and includes a union connected to the tank outlet and providing an antirotation feature, in addition to threads, to prevent rotation of the assembly in response to asymmetric loads. A measuring tube alternately receives liquid from the tank and is isolated from the tank. While isolated from the tank, liquid is withdrawn from the tube by a pump under conditions allowing the pump to be calibrated. The assembly is cantilevered from the tank outlet and is of reduced length and weight producing a device which is not prone to overstress the tank outlet.

A method is provided for the real time calibration of a pump that is part of a reusable hardware component having a programmable controller during a blood separation procedure where fluid is flowed through a tubing in a tubing set by action of the pump. The method comprises programming the controller with a continuous function defining a relationship between pump inlet pressure and pump stroke volume; commencing the fluid processing procedure to operate the pump to draw fluid through the tubing; measuring fluid pressure in the tubing at the inlet of the pump; calculating a current pump stroke volume with the controller based on the continuous function and the pump rotational rate; and adjusting the pump rotational rate utilized by the controller to control the procedure to achieve a target fluid flow rate. The continuous function defining the relationship between pump inlet pressure and the pump stroke volume may be empirically determined over a predetermined range of inlet pressures.

A dispensing system comprises a main base with a hopper insertion hole. An upper base, fixed above the main base by spacers, comprises a stirrer insertion hole. A lower base, below the main base, has a hopper insertion hole with an aperture larger than a diameter of a hopper, and is coupled to the main base by a guide. A rotatable hopper, disposed in the insertion hole of the main base, comprises a bottom surface with metering holes. A stirrer, inside the hopper and fixed to the upper base, feeds material into the metering holes. A gate, on a bottom surface of the lower base, comprises a bottom surface with a dispensing hole. The gate diameter is greater than the hopper. A gate spring, between the bottom of the main base and an upper surface of the lower base, is mounted parallel to a sliding motion of the lower base. A vibration device agitates the assembly on the main base.