The present invention relates generally to handheld sprayers, and in particular to systems and methods for controlling airflow for integrated handheld sprayers.
Handheld texture sprayers are utilized, for example, to apply coatings to walls, ceilings, and/or other surfaces. These coatings may include, for example, “knockdown” finishes, “popcorn” finishes, and fine “orange peel” finishes. Texture sprayers are supplied a viscous material, such as, for example, drywall mud from a separate tank or an attached hopper. An airflow provided to the sprayer atomizes the fluid into a spray that is applied to a surface in order to create a desired finish.
In the past, the airflow has been provided from, for example, an external air compressor. These air compressors are often bulky and limit the mobility and convenience of the texture sprayer. To provide portability, these external air compressors have been replaced with a local airflow source, such as a turbine that is integrated with the sprayer. One such portable texture sprayer is disclosed in U.S. Pat. No. 7,731,104. While providing portability, these texture sprayers are limited in both the type and quality of finish they can provide. It is desirable to improve the type and quality of spray finishes that can be generated by handheld texture sprayers.
A handheld sprayer includes a housing, a turbine, a spray tip, a hopper, a valve, and a control. An air flow passage extends through the housing. The turbine is configured to generate an airflow within the air flow passage. The spray tip is positioned to receive airflow from the air flow passage. The hopper is connected to the housing and configured to discharge a fluid into the air flow passage. The handheld sprayer further includes means for controlling the airflow within the air flow passage.
Disclosed herein is a handheld texture sprayer that provides control of the airflow provided to the spray tip from a turbine of the texture sprayer. The handheld texture sprayer includes a housing, a turbine, a spray tip, and a hopper. An air flow passage extends through the housing and carries an airflow generated by the turbine. The hopper is connected to the housing and holds fluid that is provided to the air flow passage. Using the generate airflow, the fluid is projected through the spray tip for application to a surface. In one embodiment, the air flow passage includes a valve configured to impede airflow from the turbine to the spray tip. The valve is moveable to control the airflow provided to the spray tip. In another embodiment, an electric circuit is configured to limit voltage to an electric motor of the turbine. The electric circuit is controllable to adjust the speed of the turbine to obtain a desired airflow to the spray tip. In another embodiment, an air intake control device is connected to the turbine to limit the air intake of the turbine. The air intake of the turbine is adjusted to control the airflow from the turbine to the spray tip. Control of the airflow from the turbine to the spray tip allows for greater control of the texture finish created by the sprayer.
Turbine 12 utilizes electrical power from cord 18 to generate a flow of compressed air for pushing liquid from hopper 16 through dispenser 14. Turbine 12 is inserted into housing 20 of dispenser 14 to fluidly interact with spray tip 22. Housing 20 includes handle 24 into which is integrated trigger 26. An operator of sprayer 10 grasps handle 24 with a hand while resting a forearm on pad 28 so that trigger 26 can be actuated with one or more fingers. Turbine 12 is activated via a power switch (
As will be discussed in more detail with reference to
Turbine 12 pushes air into plenum 38 at turbine outlet 44. Piston 40 guides air from plenum 40 to spray tip 22. Spray tip 22 and piston 40 form a seal when engaged in a closed position to prevent air from being in fluid communication with mix chamber 30. Spring 57 pushes between flange 56 and plenum 38 to bias piston 40 to the closed position. In order to move piston 40 to an open position, trigger 26 is translated, such as by an operator of sprayer 10, away from spray tip 22 (to the right in
Moving piston 40 from the closed position to the open position allows fluid from within hopper 16 that is present within mix chamber 30 to enter the air flow path between spray tip 22 and piston 40. In one embodiment, the fluid is pushed into the air flow path primarily via gravity. Additionally, the flow of compressed air between piston 40 and spray tip 22 generates a slight vacuum that pulls in fluid from hopper 16. As such, the flow of air through piston 40 pulls the fluid along through spray tip 22.
The pattern of the sprayed fluid can be adjusted by changing the amount that trigger 26 is actuated. Retracting trigger 26 further into handle 24 allows for more fluid to enter spray tip 22, thereby resulting in a more dense spray pattern. Trigger lock 58 is adjustable to limit the movement of trigger 26. For example, trigger lock 58 can be locked into different positions along the top of handle 24 to provide a barrier to translation of trigger 26 into handle 24. Trigger lock 58 is provided on handle 24 in a location convenient for an operator of sprayer 12 to access, such as with a thumb. Furthermore, the spray pattern can be adjusted by swapping out spray tip 22 for other spray tips having different sized openings that will widen or narrow the pattern of discharged fluid from sprayer 10.
Air is initially brought into turbine 12 through inlet vent 59 to plenum 75 formed within the housing of turbine 12 between inlet vent 59 and turbine inlet 61. Turbine inlet 61 includes air intake port 76 (
Reducing the air intake to turbine 12 reduces the airflow generated by turbine 12 and provided to spray tip 22. Control of airflow from turbine 12 to spray tip 22 is desirable to allow for better control of texture finishes created by texture sprayer 10. For example, less airflow may be desirable for creating heavy “knockdown” finishes while greater airflow may be desirable for creating fine “orange peel” finishes. While illustrated as a knob, screw and plunger, airflow control 60 may be implemented in any way that allows control of the intake air to turbine 12.
Airflow limiting valve 78 is positioned within, for example, plenum 38 to control airflow from turbine 12 to the air flow passage through piston 40. Valve 78 is controllable to impede the airflow from turbine 12 to the air flow passage through piston 40. If in a fully closed position, no air will flow to the air flow passage through piston 40 and thus, no spray will be produced through spray tip 22. As valve 78 is opened, air will begin to flow through the air flow passage of piston 40, producing a texture spray. The amount of airflow through valve 78 dictates the texture finish created by the spray produced through spray tip 22. By controlling the airflow from turbine 12 to spray tip 22, better control of the texture finish produced by texture sprayer 10 is accomplished.
b illustrates sliding gate 78b positioned within a slot in plenum 38. Although illustrated within plenum 38, sliding gate 78b may be positioned at any point within the air flow passage from turbine 12 to spray tip 22 to control airflow. The position of sliding gate 78b is controlled by physically moving sliding gate 78b in the direction illustrated by the arrow in
In one embodiment, voltage control circuit 94 may include a rotary potentiometer and a triode for alternating current (TRIAC). The rotary potentiometer is used to control the TRIAC. The TRIAC provides, for example, phase-fired control for motor 62. This provides voltage control for motor 62, which in turn allows for control of the speed of turbine 12. Controlling the speed of turbine 12 controls the airflow provided by turbine 12 to spray tip 22. This allows for greater control of the texture finish produced by texture sprayer 10. External control 92 may be, for example, a knob of the rotary potentiometer. The knob of the rotary potentiometer may be, for example, located external to turbine 12 in order to provide easy access to an operator of texture sprayer 10.
In another embodiment, voltage control circuit 94 may include variable resistors and a TRIAC and external control 92 may be a rotary wheel. The rotary wheel may be located external to turbine 12 to provide easy access to an operator of texture sprayer 10. The rotary wheel controls variable resistors, which in turn control the TRIAC. The TRIAC provides, for example, phase-fired control for motor 62. The rotary wheel may allow linear control of the variable resistors, and/or may include presets based upon desired speeds of turbine 12. Control of the speed of turbine 12 allows direct control of the finishes produced by texture sprayer 10.
Although the present invention has been described with reference to preferred embodiments, workers skilled in the art will recognize that changes may be made in form and detail without departing from the spirit and scope of the invention.
Filing Document | Filing Date | Country | Kind |
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PCT/US2014/012896 | 1/24/2014 | WO | 00 |
Number | Date | Country | |
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61756103 | Jan 2013 | US |