Applying paint to a workpiece using an electrostatic sprayer increases transfer efficiency between the paint applicator and the workpiece being painted. For a typical electrostatic sprayer application, atomized particles of paint are charged to a very high potential (nominally 80 thousand volts in relation to ground) and grounding the part being painted, charged particles of paint seeking the grounded surface and thereby completing the circuit which consists of ground system, power converter, high voltage generator, paint applicator, gaseous environment (that exists between applicator and part), and the part being painted, current flowing from applicator to the part which is electrically connected to ground, thereby completing the circuit through which current flows. Paint is compelled by the electric charge to flow from applicator to part, maximizing the amount of paint that lands on the part and minimizing the amount that is wasted as overspray. In this way, electrostatic painting has major advantages relative to both coverage and waste minimization.
However, use of electro-static painting comes with multiple challenges, including (1) safety, including fire prevention, (2) downtime associated with fault conditions (momentary excessive current conditions) that stop the application process to mitigate fire risk, where fire could occur in the presence of an arc, and (3) variation in transfer efficiency with variation in electrostatic current as a function of the environment, specifically humidity, which has the potential to manifest in many different defect forms depending on whether humidity is relatively higher or relatively lower than that which is optimal.
A first representative embodiment of a spray system according to the present disclosure includes a sprayer that is configured to impart an electric charge on particles that are discharged from the sprayer. The system further includes a humidity sensor configured to sense humidity in a work area. An electrostatic controller is receives signals from the humidity sensor corresponding to the humidity in the work area. The electrostatic controller is programmed to selectively control the electrostatic charge imparted on the particles by the sprayer according to the signals received from the humidity sensor
A second representative embodiment of a spray system according to the present disclosure includes a sprayer configured to provide an electric charge to particles discharged from the sprayer such that the charge creates a current through the spray system. The spray system further includes current sensor configured to sense the current. An electrostatic controller is operably coupled to the sprayer and to the current sensor. The electrostatic controller receives signals from the current sensor and is programmed to control the sprayer to maintain a constant current in the system.
This summary is provided to introduce a selection of concepts in a simplified form that are further described below in the Detailed Description. This summary is not intended to identify key features of the claimed subject matter, nor is it intended to be used as an aid in determining the scope of the claimed subject matter.
The foregoing aspects and many of the attendant advantages of this invention will become more readily appreciated as the same become better understood by reference to the following detailed description, when taken in conjunction with the accompanying drawings, wherein:
A first representative embodiment of an electrostatic paint system 100 is shown in
A workpiece 50 to be coated is positioned within the paint booth 110. The workpiece 50 has an electrically conductive surface that is grounded through a ground 140. A known electrostatic sprayer 120 is positioned within the booth proximate to the workpiece 50. The sprayer 120 emits a spray of atomized paint particles that are charged to a high potential. The charged paint particles produce an electrostatic field 130 around the workpiece 50 and are drawn to the grounded surface of the workpiece.
An electrostatic controller 160 is operatively associated with the sprayer 120 and selectively controls the electrostatic charge imparted on the paint particles by the sprayer. The electrostatic controller 160 is also operatively associated with a humidity monitor 150. The humidity monitor 150 is a known sensor that senses the humidity within the paint booth 110 and sends signals corresponding to the sensed humidity to the electrostatic controller 160. It will be appreciated that the humidity monitor 150 can be any known sensor to directly sense the humidity. Alternatively, the humidity monitor 150 can sense other environmental conditions to indirectly determine the humidity. In will be appreciated that the disclosed embodiment is not limited to any particular humidity sensor, but can utilize any system or method of determining the humidity within or affecting the paint booth 110.
The electrostatic controller 160 receives signals from the humidity monitor 150 and controls the charge imparted by the electrostatic sprayer 120 on the paint particles accordingly. More specifically, when an increase in humidity is sensed, the electrostatic controller 160 decreases the charge imparted by the electrostatic sprayer 120.
Conversely, when a decrease in humidity is sensed, the electrostatic controller 160 increases the charge imparted by the electrostatic sprayer 120.
It is believed that the electrostatic field effect increases with the humidity inside the paint booth 110, making paint transfer more efficient, this being due to an increase in the conductivity of air as a function of humidity. Consequently, an increase in humidity, such as during rainy weather or during high humidity environmental fault conditions, can result in excess paint being applied to the workpiece, as well as other operational variations. In the disclosed system 100, the electrostatic controller 160 employs humidity data from humidity monitor 150 algorithmically to determine output voltage with the goal of maintaining a consistent current required for optimal transfer efficiency and defect minimization regardless of external climate and the resultant impact on internal environment. By controlling the electrostatic charge according to humidity, the electrostatic paint system 100 provides the following advantages:
A second representative embodiment of an electrostatic paint system 200 is shown in
As shown in
The system 200 of
In one representative embodiment, the voltage may be ramped from 0 to 100,000 volts, for example in 5,000 volt increments, and the current assessed at each moment, yielding comprehensive knowledge of the voltage vs. current relationship that exists in the application environment. The electrostatic controller 220 may then provide the voltage that yields the desired optimal current.
Similarly, the distance d between the electrostatic paint gun 220 and the reference ground object 280 may be varied across the reference range to sense distance related parametric changes. During robotic painting operation, it is desirable that the sprayer maintain a consistent distance from the workpiece, nominally 1 inch per 10,000 volts, this to reduce the potential for arcing and risk of fire, however, in practice this is not always possible—sometimes in order to apply paint to certain aspects of a workpiece, the distance between sprayer and piece must be increased or decreased. Consequently, prior knowledge of how current increases and decreases with proximity between sprayer 120 and workpiece 50 can be taken into account by the electrostatic controller to in order to maintain a constant current during painting operation.
The calibration of electrostatic parameters with the application environment may be performed with human intervention or autonomously by the electrostatic controller 220. The frequency of calibration is a function of external weather conditions and internal environmental control. The disclosed embodiment allows for the frequency of the calibration interval to be programmable.
Advantages provided by the system 200 of
While the preferred embodiment of the invention has been illustrated and described, it will be appreciated that various changes can be made therein without departing from the spirit and scope of the invention.
This application claims the benefit of U.S. Provisional Patent Application No. 62/411,819, filed Oct. 24, 2016, which is incorporated herein by reference in its entirety.
Number | Date | Country | |
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62411819 | Oct 2016 | US |