An automated apparatus and method for coating medical devices such as an intravascular stent, are disclosed in the method, a 2-D image of a stent is processed to determine (1) paths along the stent skeletal elements by which a stent secured to a rotating support element can be traversed by a dispenser head whose relative motion with respect to the support element is along the support-element axis, such that some or all of the stent skeletal elements will be traversed (2) the relative speeds of the dispenser head and support element as the dispenser head travels along the paths, and (3), and positions of the dispenser head with respect to a centerline of the stent elements as the dispenser head travels along such paths The rotational speed of the support and relative linear speed of the dispenser are controlled to achieve the desired coating thickness and coating coverage on the upper surfaces, and optionally, the side surfaces, of the stent elements.

A driven turret nozzle assembly includes a main body, a turret rotatably coupled to and in fluid communication with the main body, nozzle bodies circumferentially spaced about the turret, and a driver operationally coupled to the turret to effect automated selective rotation of the turret. Actuation of the driver rotates the turret to move an active nozzle body into fluid communication with a fluid path defined through the main body and the turret.

A modulating nozzle controller for an agricultural sprayer includes one or more modulating nozzle assemblies each having a spray tip modulating element and an actuator operatively coupled with the spay tip modulating element. The spray tip modulating element controls an orifice profile of a spray tip. A processor system controls the orifice profiles of the one or more modulating nozzle assemblies and includes an agricultural product input to receive a specified field flow rate and a specified droplet size for an agricultural product and a sprayer speed input to receive an agricultural sprayer speed. A modulating nozzle profiler includes an orifice profile generator configured to generate an orifice profile instruction based on the specified field flow rate, the agricultural sprayer speed and the specified droplet size. The spray tip modulating element and the actuator control the orifice profile according to the orifice profile instruction to achieve the specified droplet size.

Systems and methods can determine a liquid flow in a spraying system. An amount of liquid that is output from the spraying system during a pump cycle is determined. A number of pump cycles that occur within a given amount of time are measured. The number of pump cycles are measured using an electronic speed controller (ESC). Additionally, the ESC indicates the number of pump cycles within a given amount of time within a threshold of precision. The amount of liquid flow in the spraying system is calculated based on the measured number of pump cycles and the determined amount of liquid that is output from the spraying system.

A system and method for applying a fluid to a surface. The method includes the steps of: providing a deposition system; discharging fluid from the deposition system at a first, non-zero rate; detecting movement of the deposition system in proximity to a surface; and discharging fluid at a second rate while the deposition system is moving in proximity to the surface. The system comprises: a MEMS element coupled to a fluid reservoir and adapted to dispense fluid at a plurality of non-zero rates; at least one sensor; and a controller in communication with the MEMS element and at least one sensor and adapted to receive an output from the sensor and to alter the deposition rate of the MEMS element according to the sensor output.

An automated apparatus and method for coating medical devices such as an intravascular stent, are disclosed in the method, a 2-D image of a stent is processed to determine (1) paths along the stent skeletal elements by which a stent secured to a rotating support element can be traversed by a dispenser head whose relative motion with respect to the support element is along the support-element axis, such that some or all of the stent skeletal elements will be traversed (2) the relative speeds of the dispenser head and support element as the dispenser head travels along the paths, and (3), and positions of the dispenser head with respect to a centerline of the stent elements as the dispenser head travels along such paths The rotational speed of the support and relative linear speed of the dispenser are controlled to achieve the desired coating thickness and coating coverage on the upper surfaces, and optionally, the side surfaces, of the stent elements

A system and method for dispensing a fluid within an environment. The method includes the steps of: providing a dispensing system within an environment; discharging fluid from the dispensing system at a first, non-zero rate; detecting a change in the environment; and discharging fluid at a second rate after detecting the environmental change. The system comprises: a MEMS element coupled to a fluid reservoir and adapted to dispense fluid at a plurality of non-zero rates; at least one sensor; and a controller in communication with the MEMS element and at least one sensor and adapted to receive an output from the sensor and to alter the dispensing rate of the MEMS element according to the sensor output.

A system for simulating wet runway conditions by using a liquid container that is placed inside an aircraft. The liquid container is connected to a nozzle that sprays water in front of the wheels of the aircraft. A valve is used to control the flow of water from the nozzle. Systems, such as the braking system of the aircraft, can then be tested in wet runway conditions simulated by the system. The amount of water sprayed from the nozzle can also be electronically controlled in relation to the speed of the aircraft, such that the nozzle sprays a nearly uniform layer of liquid in front of the wheels. The system can also be modified to include two tanks to manipulate the center of gravity of the aircraft.

A dual-cap nozzle comprises a housing having a cavity to receive a liquid; a first nozzle cap attached to the housing, the first nozzle cap defining a first nozzle channel that is fluidly coupled to the cavity; and a second nozzle cap attached to the housing, the second nozzle cap defining a second nozzle channel that is fluidly coupled to the cavity. The first and second nozzle caps extend along first and second axes, respectively. An offset angle between the first and second axes is greater than or equal to about 0 degrees and less than or equal to about 45 degrees.

A hand applicator system (100) for spraying a human or animal body (10), the system comprising: a hand applicator (110); and a travel speed indicator (120) which indicates the optimum travel speed of the hand applicator over a region of the body, wherein the travel speed indicator emits a signal to an operator of the hand applicator, the signal varying during a spraying procedure and being indicative of the appropriate instantaneous travel speed of the hand applicator over the region of the body adjacent the hand applicator at any time.