The present invention pertains to systems for dispensing multi-component coatings, and in particular, paint coatings. The system incorporates multiple reservoirs that combine separate components of the paint coatings into a mixer and subsequently through a nozzle.
Coatings are applied to the surfaces of many products for various reasons. Some coatings are used to lubricate moving parts or reduce glare on optical lenses. Other coatings protect against rust and corrosion while still others are applied purely for decoration. Paint is one example of a coating widely in use today. Typically, paint is applied to a substrate and includes components that cure or harden to form a thin layer of film. Advances over the past few decades have produced paint products that significantly extend the life of a painted article by reducing the effects of corrosion due to ambient conditions.
In many instances, paint consists of multiple components that must be combined prior to its application onto the substrate. In many cases, the components are reactive components (e.g. in solutions or dispersions), which are mixed together and react with each other in a crosslinking reaction to provide a curable coating composition. Up until the point of mixing, none of the individual components alone provides a curable coating composition. Typically, upon mixing, such multi-component coatings react and cure quickly. Thus, it is beneficial to mix the components together and apply the paint to a substrate soon after mixing. Paint may also consist of other ingredients, including but not limited to pigments, solvents catalysts, adhesion promoters, and UV light absorbers. Each of these ingredients can be used to impart various desired properties to the paint composition.
It is an important factor in using multi-component coatings that the components of the coating be mixed in precise quantities, i.e. at predefined ratios. As such, the process of mixing paint requires careful attention on the part of the operator. It may also be important to gauge how much paint is needed for a specific application. Mixing the right amount of paint can minimize material waste and cost.
The embodiments of the present invention pertain to a system for applying coatings and more specifically paint coatings. The system includes a spray gun having a nozzle that dispenses the paint in a spray pattern. Pressurized air is directed through the nozzle from a remote source, like for example an air compressor. A reservoir chamber is also included, which houses separate containers each filled with a different component of the paint. The components are fed through a series of orifices that combine the components at a particular mix ratio. Pressure from an inflatable bladder expels the components under pressure, of which the combined components are channeled into a mixing device that blends the components together just prior to being introduced into the nozzle.
In one aspect of the embodiments of the subject invention, the containers are plastic bags that collapse to expel the paint components into the mixer.
In another aspect of the embodiments of the subject invention, the mixing device is a static mixer having baffles that channel the paint components through a circuitous pathway.
Another aspect of the embodiments of the subject invention includes an orifice plate that covers the collapsible bags.
In even another aspect of the embodiments of the subject invention, the orifice plate may include individual apertures that allow the paint components to be combined in a particular mix ratio.
In still another aspect of the embodiments of the subject invention, the orifice plate is disposable. Additionally, the mixing device may also be disposable.
In even yet another aspect of the embodiments of the subject invention, the orifice plate may be exchanged with another orifice plate that mixes the paint components at a different mix ratio.
In another aspect of the embodiments of the subject invention, air drawn from an air compressor feeds the spray gun to dispense the paint and actuates the bladder to expel the components from the collapsible bags in the mixing device.
Referring now to the drawings wherein the showings are for purposes of illustrating embodiments of the invention only and not for purposes of limiting the same,
With reference to
With reference to
Referencing
With continued reference to
The applicator 10 may further include an orifice plate 34 for metering particular quantities of the paint components into the conduit 31 and mixing device 49. The orifice plate 34 may be generally planar and may cover the reservoirs 20 filled with the respective components of paint 12. In one embodiment, the orifice plate 34 may be concave and may have a monolithic structure. However, any configuration of orifice plate 34 may be chosen as is appropriate for use with the embodiments of the present invention. Additionally, channels 36, which may be holes or apertures 36 fashioned in the orifice plate 34, may be incorporated for directing fluid from the reservoirs 20 into the conduit 31. It is noted here that the orifice plate 34, apart from metering fluids into the mixing device 49, prevents fluid in one reservoir from mixing with fluids from another reservoir. Stating it another way, when assembled, the orifice plate 34 may function to cap the individual reservoirs 20 preventing the intermixing of paint components. Additionally, the orifice plate 34 may incorporate check valves, not shown, that prevent paint 12 once mixed together from flowing back into the reservoirs 20. The check valves may be disposed within or proximate to the apertures 36. However, the check valves may be positioned at any location that prevents the back flow of fluid into the reservoirs 20. In one embodiment, the orifice plate may be equipped with a peripheral extension. Such a peripheral extension may be positioned within the reservoir chamber and/or reservoir(s), or around the outer periphery of the reservoir chamber and/or reservoir(s). The peripheral extension may also be placed within or around the reservoir chamber but not within or around the reservoir(s). In an alternative embodiment, the orifice plate may be positioned on top of, but not within or around, the reservoir chamber and/or reservoir(s).
As just mentioned, the channels 36, or apertures 36, meter fluid from the multiple reservoirs 20 into the conduit 31 and subsequently into mixing device 49. Accordingly, one aperture 36 may be included for each reservoir 20. It will readily seen that the size of apertures 36 will determine the amount of fluid allowed to flow therethrough thus fixing the ratio at which the paint components are combined. In one embodiment, each of the apertures 36 provided may be similar in size. That is to say that each aperture 36 dispenses or directs fluid at substantially the same rate. In another embodiment, the apertures 36 may facilitate flow at different rates as accomplished by providing one aperture 36 having a larger or smaller diameter than another or by providing multiple similarly sized apertures 36 that connect to a single reservoir 20. Still, any manner of metering fluid from the reservoirs 20 into the mixing device 49, in any proportions, may be chosen without departing from the intended scope of coverage of the embodiments of the subject invention. It is noteworthy to mention here that the orifice plate 34, conduit 31 and mixing device 49 may be disposable elements of the applicator 10. This makes it easy for an operator to clean and maintain the spray gun 11 for subsequent use. Additionally, changing the mix ratio of the paint 12 may be easily accomplished simply by exchanging one orifice plate 34 with that of another having a different pattern or size of apertures 36.
Continuing to reference
To expel the fluid, an actuator 40 is provided that engages to apply pressure to the collapsible reservoirs 20. The actuator 40 may be comprised of a bladder 42 that expands when filled with a pressurized medium. In one embodiment, the bladder 42 may be accordion shaped having wall sections that fold one upon another, although other bladder configurations may be implemented as is appropriate for use with the embodiments of the present invention. Moreover, any type of expanding actuator 40, mechanical or otherwise, may be chosen to expel fluid from the reservoirs 20. In this manner, action from engaging the actuator 40 compresses the reservoirs 20 thereby pressurizing the fluid components therein for expulsion through the apertures 36. It will be recognized that the pressure of the paint components entering the conduit 31 may be sufficient to project the fluid through the static mixer 50 thoroughly blending the paint 12 upon contact with the baffles. Thus a substantially homogeneous mixture is provided just prior to introducing the paint 12 into the nozzle 17.
The actuator 40, and in particular the accordion shaped bladder 42, may be actuated by pressurized air supplied from a remote source, which may be an air compressor. The actuator 40 may have a dedicated air line connected directly to the air compressor. However, in one embodiment, air flow for activating the actuator 40 may be diverted from the air stream connected to the spray gun 11. It is to be understood that in either instance, the actuator 40 is activated when the trigger 18 is depressed. It follows that as the trigger 18 is released, the flow of air to the actuator 40, as well as the spray gun 11, stops or is closed off.
With reference now to all of the Figures, operation of the applicator 10 will now be discussed. An operator may respectively fill individual reservoirs 20, i.e. collapsible bags, with components of a paint 12 or coating 12 that is to be dispensed by the applicator 10. The operator may select bags that hold a particular quantity of fluid as determined by the mix ratio of the paint 12 or coating 12. Additionally, the operator may select an orifice plate 34 having a particular number and size of apertures 36 that correspond to the number of bags and to the mix ratio. Subsequently, the bags may be filled and placed into the reservoir chamber 23 for installation into the spray gun 11. Alternatively, pre-filled bags may be provided, which eliminates one step in the setup process. Hoses or other conduit may then be connected that route pressurized medium, which may be pressurized air, to the spray gun 11 and to the actuator 40. Activation of the trigger 18 will then release the flow of pressurized medium through the spray gun 11 discharging fluid from the bags into the mixing device 49 and subsequently into the nozzle 17.
The invention has been described herein with reference to the disclosed embodiments. Obviously, modifications and alterations will occur to others upon a reading and understanding of this specification. It is intended to include all such modifications and alterations insofar as they come within the scope of the appended claims or the equivalence thereof.
This application is a divisional of co-pending application Ser. No. 12/579,491 filed Oct. 15, 2009 which claims priority from Provisional Application No. 61/106,229 filed Oct. 17, 2008, the entirety of both of which is hereby incorporated by reference.
Number | Date | Country | |
---|---|---|---|
61106229 | Oct 2008 | US |
Number | Date | Country | |
---|---|---|---|
Parent | 12579491 | Oct 2009 | US |
Child | 13613524 | US |