Ergonomic Spray Can Adapter and Positioning Apparatus

Abstract

An ergonomic adapter for an aerosol spray can. The ergonomic adapter has an elastomeric collar that fits around a body of an aerosol spray paint can such that a front portion of the collar is facing in front of the can just below the interface between the body and the domed top of the spray can. The front of the adapter includes a compartment that houses a polychromatic light source for lighting the surface and/or a light beam arrangement for targeting and positioning the spray can with respect to the surface.

Description

FIELD OF THE INVENTION

The invention relates to spray painting with aerosol spray cans. In particular, the invention is an adapter that facilitates ergonomic gripping and operation of an aerosol spray can, as well as proper positioning of the spray can with respect to the surface being painted, and/or proper lighting of the surface being painted.

BACKGROUND OF THE INVENTION

Common aerosol spray cans have a cylindrical body and a domed top surface with a depressible, finger actuated nozzle located at the top of the dome. The design of the common spray causes finger pain and hand fatigue. To address this problem, the prior art includes many spray can adapters having trigger arrangements intended to alleviate finger pain and hand fatigue. One of the problems with these types of trigger arrangements is that the user tends to lose their intuitive sense of touch or feel for the spray because the index finger is located remote from the push-button nozzle via some type of mechanical mechanism. It may take the user several minutes or more to obtain a comfortable sense of touch, if at all.

Most spray can users employ improper spraying techniques, which leads to overspray, excessive waste, paint runs and generally poor quality. The primary issue in this regard is failure to maintain the spray can at the appropriate standoff distance from the surface being painted. Horan et al. U.S. Pat. No. 6,896,192 describes a spray can targeting and positioning system that uses a light beam or a pair of light beams to help the user maintain the spray can at an appropriate standoff distance. Horan et al. U.S. Pat. No. 6,896,192 issued on May 24, 2005, is entitled “Spray Can Targeting and Positioning System”, assigned to the assignee of the present invention and is incorporated herein by reference. The Horan et al. '192 patent discloses several embodiments. In one embodiment, a light beam targeting and positioning system is mounted to the body of a handle triggering mechanism that attaches to the dome of a spray can. The triggering mechanism depresses the push-button nozzle on the spray can when the user pulls the trigger. The light beam targeting and positioning system in this embodiment is a dual beam type as disclosed in Klein et al. U.S. Pat. No. 5,598,972 issuing on Feb. 4, 1997 and entitled “Optical Spray Paint Optimization System And Method”, which is also assigned to the assignee of the present application, and is also incorporated herein by reference. This light beam targeting and positioning system uses a laser light source and a beam splitter to generate a pair of non-parallel light beams that propagate towards the surface being painted. The first light beam is fixed in its orientation and is often called the reference beam. Typically, the light beam targeting and position system should be mounted to the spray can so that a spot illuminated by the reference beam resides in the center of the spray pattern on the surface being painted. The angular orientation of the other beam, often called the gauge beam, can be adjustable, although this is not always desirable. The angular orientation of the gauge beam is selected so that it converges towards the reference beam. When the spray can is positioned at the proper standoff distance from the surface being painted, the spot illuminated on the surface by the gauge beam converges with the spot illuminated by the reference beam either to form a single point on the surface, or to become aligned either horizontally or vertically on the surface being painted. In this way, the user is provided constant feedback as to whether the spray can is properly positioned with respect to the surface being painted.

In another embodiment shown in the Horan et al. '192 patent, the light beam targeting and positioning system is not associated with a triggered handle assembly. Rather, it is attached to a spray can using a strap-like attachment device. In this embodiment, the user grips the spray can as normal and depresses the push-button nozzle with their index finger to spray paint onto the surface, but with the aid of the light beam targeting and positioning system mounted to the spray can, thereby providing feedback to the user as to the proper targeting and positioning of the spray can with respect to the surface being painted.

Another embodiment disclosed in the Horan et al. '192 patent application uses a single light beam spray gun positioning system as disclosed in U.S. Pat. No. 7,040,546, issuing on May 9, 2006 entitled “A Single Beam Spray Gun Positioning System”, which again is assigned to the assignee of the present application and is incorporated herein by reference. In the single beam system, the orientation of the single light beam is adjusted so that the light beam will illuminate at the center of the spray pattern on the surface when the spray gun is located at the appropriate standoff distance from the surface. The single beam system is a simpler mechanism than the dual beam mechanism, although it is not designed to provide accurate targeting feedback when the spray gun is not positioned at the appropriate standoff distance from the surface, as is provided by the reference beam in the dual beam system discussed above.

While these prior art patents certainly disclose the use of a light beam targeting and positioning system in connection with an aerosol spray can, they do not suitably address the issue of finger pain and hand fatigue in a practical fashion. As mentioned above, it is believed that users shy away from handle trigger arrangements because they loose their intuitive feel for the push-button nozzle. For example, when a user presses a push-button nozzle directly with their index finger, the user can immediately feel subtle rocking and/or pressure changes. Trigger mechanisms, in large part, eliminate this type of tactile feedback. On the other hand, the acute pressure exerted by the push-button nozzle on the index finger as well as the difficulty that some people have in grasping the body of the can for long periods of time can be quite annoying and tends to limit the amount of time that users are willing to paint with aerosol spray paint cans.

In order to alleviate finger pain, some aerosol can manufacturers are providing contoured push-button nozzles at the top of the spray can dome. While contoured push-button nozzles can help alleviate finger pain, they do not otherwise provide ergonomic gripping assistance to the user. In particular, the orientation of the user's hands while gripping an aerosol spray can with the thumb on one side of the can, the index finger on the push-button nozzle and the other fingers on the other side of the can, leads to hand fatigue, especially since the cylindrical surface of the typical spray can tends to be hard and somewhat slippery.

Another problem frequently facing spray can users is the lack of sufficient lighting for the surface being painted. This has been addressed in the prior art, for example, by placing a light on the front end of a trigger handle mechanism that is attached to a spray can. This feature can be particularly helpful in circumstances where lighting is poor and it is inconvenient or impractical to set up ancillary lighting.

SUMMARY OF THE INVENTION

In a broad sense, the invention is an ergonomic adapter for a conventional aerosol spray paint can having a push-button nozzle that extends upward from a top surface of the can. The ergonomic adapter has a collar that fits around the body of the aerosol spray can.

One embodiment of the invention is designed to be used with aerosol spray cans that do not have a cushioned push-button nozzle. In this embodiment of the invention, an arcuate finger strip made of a resilient, flexible material extends from a rear side of the collar upward and over the push-button nozzle on the spray can when the adapter is fitted onto the body of the spray can. The arcuate finger strip preferably has a concave upper surface within which the user's index finger rests. A bottom surface of the finger strip engages the push-button nozzle, preferably at a location defined by a stop extending downwardly from the finger strip. In order to commence spraying, the user grasps the collar in their palm and rests their index finger on top of the arcuate finger strip, in a manner quite similar to how one would normally grab an aerosol spray can. The user then pushes downward on the push-button nozzle with the resilient, flexible arcuate finger strip between the user's index finger and the push-button nozzle. Such an arrangement provides cushioning to the user's index finger and also redistributes the pressure load on the user's finger. At the same time, use of an ergonomic adapter does not substantially interfere with the tactile feedback from the push-button nozzle to the user's index finger. The user thus maintains an intuitive sense of touch and feel even when the ergonomic adapter is used.

In this embodiment, the collar may include two arcuate arms extending forward from the location that the finger strip attaches to the rear of the collar, as well as a rigid connecting piece that connects together the front ends of the collar arms in the front of the spray can. Alternatively, the resilient flexible collar can be designed to completely encompass the body of the spray can. Preferably, the arms of the collar and the arcuate finger strip are made of the same elastomeric material. The preferred elastomeric material is silicone rubber having a durometer of 80, although a durometer of between 30 and 90 may be suitable depending on the thickness of the collar. The thickness of the finger strip at the location where the index finger depresses downward on the push-button nozzle is preferably about ⅛ inch.

The inside diameter of the collar is preferably slightly smaller than the diameter of a typical, standard-sized aerosol spray can, i.e. the preferred inside diameter of the collar is slightly greater than 2½ inches. The resilient, flexible collar is stretched slightly to fit onto the body of the can and friction serves to hold the collar in place on the can.

In some embodiments of the invention, the outer surface of the collar includes two enlarged traction pads, one on each side, for ergonomic gripping purposes. If desired, gripping knurls can be molded into the collar as well. It has been found that the overall configuration of the adapter fosters proper spray technique by placing the user's hand in a proper position with respect to the spray can. Moreover, it has been found that the use of the adapter reduces the tendency of users to over-grip, and therefore reduces hand fatigue. The enlarged traction pads are preferably located symmetrically rearward of the push-button nozzle. The ergonomic adapter is thus equally well suited for right handed users as it is for left handed users. Preferably, the material of the collar and the arcuate finger strip has a rough finish, such as an aggressive EDM finish, in part to facilitate improved friction fitting as well as ergonomic gripability.

In some versions of the invention, the ergonomic adapter does not include the arcuate finger strip. These versions are nominally designed to be used with aerosol spray cans that have a contoured push-button nozzle, although can also be used with aerosol spray cans having a conventional, push-button nozzle. Even without the arcuate finger strip, the improved traction provided by the collar reduces the user's tendency to over grip the can and therefore reduces hand fatigue.

As mentioned, it is desirable in some circumstances to design the resilient flexible collar to completely encompass the body of the spray can with the collar passing through the rigid housing at the front of the can. This arrangement is somewhat more durable for repeated stretching to fit over aerosol spray cans. Typical aerosol sprays have a diameter about 2.7 inches. For an elastomeric collar made of butyl rubber having an 80 durometer with a constant 0.25 inch thickness, the relaxed diameter of the collar should be slightly greater than 2.5 inches such that the collar has the ability to stretch in order to fit with relative ease over the larger standard sized aerosol spray can. The collar can optionally include recessed griping regions for the users thumb and fingers, forward of the location of the push-button nozzle on the can.

In accordance with another aspect of the invention, the rigid housing connected to the collar includes at least one compartment facing forward which contains one or more light sources for illuminating the surface and/or for facilitating the positioning of the spray can and targeting of the spray on the surface. If a rigid connecting piece is used, it can serve as the rigid housing as well. It is preferred that a light source for a single beam targeting and positioning system as well as the polychromatic light source be located within a common lighting chamber located at the forwardmost point of the rigid connecting piece. In the preferred embodiment, the light sources are vertically aligned within the lighting chamber. The vertical alignment allows the weight of the electronics relating to the lighting sources in the lighting chamber is balanced along the centerline of the rigid connecting piece.

The preferred light source for the light beam targeting and positioning system is an LED class 1, class 1M, class 2 or class 2M laser source which is mounted to a rotatable horizontal axle, located in the lighting chamber. The rotational position of the horizontal axle, and consequently the angular orientation of the light beam source, is preferably adjusted in the factory so that the light beam illuminates a spot in the middle of the spray pattern when the spray can is at the desired standoff distance from the surface, for example, 9 to 12 inches. Preferably, the axle head is adapted to allow manual adjustments of the orientation of the light beam source in the field. The head may include demarcations which correlate the rotational position of the axle to a desired standoff distance. In most circumstances, the light beam system will be set to illuminate spot that on the surface that the user uses as a target for the center of the spray pattern, however, if desired the user can adjust the orientation of the beam in order to provide a target for the edge of the spray pattern on the surface. While the preferred embodiments of the invention uses a single beam targeting and positioning system, the invention also contemplates the use of a dual beam system as described in the above-noted prior art, incorporated patent applications.

The purpose of the polychromatic light source is to flood the surface with white light in order to help the user to better view the area being sprayed. It also helps to bring out the true color of the painted surface and also helps the user conveniently notice coverage and running issues. The preferred polychromatic light source is an LED polychromatic light source having a wide white light spectrum. In order to provide ample lighting to the surface under a variety of conditions, it may be desirable to use a lighting source that includes two or three LED lights linearly aligned and mounted in front of an elongated, curved (e.g. parabolic) reflector plate. In addition, the polychromatic light source as well as the reflector plate may be mounted to a manually adjustable axle so that the orientation of the illuminated light can be adjusted by the user. A removable clear lens, such as a polycarbonate lens, fits into the rigid housing over the common lighting chamber and provides a window through which the light sources illuminate.

The rigid housing also holds batteries and circuitry for operating the light sources. In some embodiments of the invention, the rigid housing includes a pair of battery compartments, each holding elongated cylindrical batteries such as AA batteries. It is desirable that the weight of the batteries be symmetrically balanced. On the other hand, it is desirable that the chamber for the light beam targeting and positioning device and the surface illuminating light not protrude excessively forward of the spray can surface. Therefore, it may desirable to split the battery compartment such that one battery is located on one side of the chamber for the light sources and the other battery is located on the other side of the chamber for the light sources. On the other hand, this may not be possible if additional batteries are needed in order to meet desired power storage requirements. For example, in one preferred embodiment of the invention four AAA batteries are loaded into a battery cartridge, which in turn is placed into a single battery compartment located behind the lighting chamber. The battery compartment is preferably accessible from the top of the housing, and the preferred cartridge also includes a lid that covers not only the battery compartment but also the top of the lighting compartment. The lid preferably includes a conspicuous target line on its top surface that is directed straight forward of the adapter. The target line helps the user align the adapter with the push-button spray nozzle. It also helps the user align the spray can to the surface when in use.

Various other features, objects and advantages of the invention will be made apparent from the following description taken together with the drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is an isometric view showing a first embodiment of an ergonomic adapter made in accordance with the invention being mounted to an aerosol spray can.

FIG. 2 is a schematic drawing illustrating the use of a single beam spray can targeting and positioning system incorporated into the ergonomic adapter shown in FIG. 1.

FIG. 3 is a side view of the first embodiment as shown in FIG. 1 also showing the user's hands gripping the ergonomic adapter with the user's index finger resting along the arcuate finger strip.

FIG. 4 is a top view of the illustration shown in FIG. 3.

FIG. 5 is a perspective view of an ergonomic adapter constructed in accordance with the invention having a front polycarbonate lens broken away from lighting chamber in a rigid connecting piece.

FIG. 6 is a top perspective view of an ergonomic adapter constructed in accordance with the first embodiment of the invention illustrating the battery compartments accessible from the rear of the rigid connecting piece.

FIG. 7 is a longitudinal sectional view taken along line 7-7 in FIG. 4.

FIG. 8 is a horizontal sectional view taken along line 8-8 in FIG. 3.

FIG. 9 is a side elevational view of an ergonomic adapter constructed in accordance with the first embodiment of the invention.

FIG. 10 is a top plan view of the ergonomic adapter constructed in accordance with the first embodiment of the invention.

FIG. 11 is a front elevational view of an ergonomic adapter constructed in accordance with the first embodiment of the invention.

FIG. 12 is a rear elevational view of an ergonomic adapter constructed in accordance with the first embodiment of the invention.

FIG. 13 shows a bottom plan view of an ergonomic adapter constructed in accordance with the first embodiment of the invention.

FIG. 14 illustrates an ergonomic adapter constructed in accordance with the second embodiment of the invention being mounted to an aerosol spray can.

FIG. 15 is a perspective view showing another embodiment of an ergonomic adapter made in accordance with the invention being mounted to an aerosol spray can.

FIG. 16 is a side view of the embodiment of the invention shown in FIG. 15 showing the user's hands gripping the ergonomic adapter with the user's index finger resting directly on a push-button nozzle for the aerosol spray can.

FIG. 17 is a top view of the illustration shown in FIG. 16.

FIG. 18 is an exploded view of the ergonomic adapter shown in FIGS. 15-17.

FIG. 19 is a longitudinal sectional view taken along line 19-19 in FIG. 17.

FIG. 20 is a horizontal sectional view taken along line 20-20 in FIG. 16.

DETAILED DESCRIPTION OF THE DRAWINGS

In a first embodiment of the invention, an ergonomic adapter 10 for use in connection with an aerosol spray can 12 includes a single light beam targeting and positioning system 14 as well as a polychromatic light source 16 for illuminating the surface to be painted. This first embodiment is illustrated in FIGS. 1-13. FIG. 14, on the other hand, illustrates a second embodiment of the invention in which the ergonomic adapter 210 does not include a single-beam targeting and positioning system 14 or a polychromatic light source 16. FIGS. 15-20 show another embodiment of the invention in which the ergonomic adapter 310 includes a single light beam targeting and positioning system 314 as well as a polychromatic light source 316 for illuminating the surface to be painted.

Referring generally to FIGS. 1-13, and in particular FIG. 1, the ergonomic adapter 10 includes a collar 18 that fits around a body of the aerosol spray can 12. The collar includes two arms 20, see for example FIGS. 4-6, which extend from the rear of the adapter 10 forward in an arcuate manner. A rigid connecting piece 22, preferably made of molded ABS or nylon, connects together the collar arms 20 at the front of the spray can 12. The collar arms 20 can be manufactured with a barb at their end to facilitate attachment into a slot within the rigid connecting piece 22, or alternatively, an in-molding procedure can be used to attach the collar arms to the rigid connecting piece 22. An arcuate finger strip 24 extends upward from the rear of the collar 18. The arcuate finger strip 24 has a concave upper surface 26 which is designed to comfortably receive the index finger of the user. An alignment marker 28 is molded into the top surface of the rigid collar 22. Preferably, the alignment marker 28 will be painted or printed to be a different color than the color of the rigid collar 22. A power switch 30 for the light sources 14, 16 extends downward from the bottom of the rigid connector 22. While the preferred power switch is simply an on/off switch, it may be desirable to implement the invention with a four function switch. If a four function switch is used, the switch would have a fully off position, a fully on position and a position in which the light beam targeting and positioning system was on, and a position in which the polychromatic light source was on.

As discussed in more detail below, the collars 18 and the arcuate finger strip 24 are preferably made of a resilient elastomeric material such as butyl rubber or silicone.

Referring to FIG. 2, the operation of the single light beam targeting and positioning system is illustrated. The single beam positioning system operates on fundamentally the same principle as that described in U.S. Pat. No. 7,040,546 entitled “Single Beam Spray Gun Positioning System” issuing on May 9, 2006 which is assigned to the assignee of the present application and incorporated herein by reference. Briefly, the user turns on the single beam light source 14 using the switch 30. The single beam light source 14 emits a light beam 32 towards the surface 34 being painted. The user then approximates the known optimal distance of the spray can nozzle 36 from the surface 34, and commences operation of the spray can 12 to discharge spray paint in a spray pattern 38 on the surface 34. The user maintains the nozzle 36 at the optimal distance from the surface 34 by maintaining the illuminated point 40 of light from the single beam light source 14 in the center of the spray pattern 38. As the user moves the spray can 12 and adjusts the pressure and subtle angular adjustments of the push-button nozzle 36, the user is able to visually ascertain the position of the illuminated point 40 and thereby maintain the light beam as close as possible to the center line of the spray pattern 38. The position of the single beam light source 14 is offset from the location of the nozzle 36 and its angular orientation is preferably preset in the factory for a distance of about 9-12 inches, which is the preferred standoff distance for most spray painting applications. If the user is holding the spray can 12 too far from the surface 34 the illuminated point 40 will appear in the top half of the pattern 38. If the user is holding the spray can 12 too close to the surface 34 the illuminated point will appear in the bottom half of the pattern 38.

As mentioned, it may be desirable to use a dual beam targeting and positioning system in lieu of a single beam system. A suitable dual beam system is described in Klein, II et al U.S. Pat. No. 5,598,972 entitled “Optical Spray Paint Optimization System and Method” issuing on Feb. 4, 1997 which is assigned to the assignee of the present invention and is incorporated herein by reference. Of course, in accordance with the present invention, it is desirable to locate the dual beam system in the vertical lighting chamber 42, FIG. 5, which is located in the front of the rigid connector 22.

Referring now to FIGS. 3 and 4, the user's hand 44 grips the ergonomic adapter 10 such that the user's index finger 46 rests on the arcuate finger strip 24, the user's thumb 48 grips a large traction pad 50 on one side of the collar 18 and the user's other fingers 52 grip a traction pad 50 on the other side of the collar 18. The collar 18 and the traction pads 50 are located rather high on the spray can, which requires the user to grip the adapter with the user's thumb 48 and the other fingers 52 rather high relative to the height of the spray can. As mentioned, such an orientation of the hand 44 on the spray can fosters proper spraying techniques. In addition, the tendency to over-grip the spray can is reduced because of the ergonomic traction pads 50. If desired, gripping knurls can be placed on the front side of the traction pads 50 in order to further promote ergonomic gripping of the adapter by people having various hand sizes. Such knurling is not shown in the drawings. The collar 18 and the arcuate finger strip 24 are preferably molded butyl rubber such as sold under the trademark C-FLEX, or silicone rubber, although other elastomeric materials or even appropriate thermoplastic materials may be suitable. Preferably, the collar 18 and the arcuate finger strip 24 have a rough finish, such as an aggressive EDM finish, on all surfaces. The rough finish enhances surface friction which is helpful for holding the adapter 10 to the spray can 12, as well as facilitating gripability by the user's hand 44. The preferred durometer is substantially about 80 (although durometers between 30 and 90 may be suitable as mentioned above), thereby rendering the collar 18 and arcuate finger strip 24 flexible and resilient.

The thickness of the arcuate finger strip is preferably about ⅛ inch although the thickness can vary slightly throughout the strip. The curvature of the concave surface 26 on the arcuate finger strip 24 is preferably about a radius of 0.75 inches at the location where the finger tip resides, but the finger strip 24 flattens as it approaches the collar 18. A stop 54 for engaging the push-button nozzle on the spray can 12 extends downward from the arcuate finger strip 24 near the distal end of the finger strip 24. The stop 54 provides a seating location for the push-button nozzle 36 against the bottom surface of the finger strip 24. The seating location for the push-button nozzle 36 is located substantially directly below the normal position for the user's index finger 46. The stops shown in the Figures have a curvature which is sized to comfortably receive a standard sized push-button nozzle 36. It may be desirable, however, to widen the curvature of the stop 54 in order that the adapter comfortably fit on spray cans having a larger sized push-button nozzle 36.

Referring now to FIGS. 5 and 6, a removable clear polycarbonate lens 56 covers the front opening of the lighting chamber 42 in the rigid connector piece 22. It may be desirable to provide replacement lenses 56 when the unit is sold commercially. The clear polycarbonate lens 56 is designed to snap onto the rigid connector piece 22. As shown best in FIG. 6, the light sources are powered by AA batteries 58, 60. The batteries 58, 60 each reside in a separate battery compartment 62, 64 which are accessible from the rear of the rigid connector 22. A compartment door 66 is removably attached to the rigid connector 22 to cover the battery compartments 62, 64 when the batteries 58, 60 are loaded. The compartment door 66 has an arcuate or partially cylindrical shape in order to accommodate the surface of the spray can 12.

Referring now to FIGS. 7 and 8, as mentioned, the polychromatic white light source 16 and the laser light source 14 for the targeting and positioning system are mounted in the lighting chamber 42 in the rigid connection piece 22. Preferably, battery 60 provides power for the polychromatic light source 16 and the battery 58 provides power for the laser light source 14, both through the electronics board 68. In the preferred embodiment, 1.5V DC power is provided to each of the light sources 14 and 16.

The preferred laser light source 14 is a Class 1, Class 2 or Class 2M LED light source, outputting a red or green beam. A suitable LED operates on a low level of DC current. As illustrated in FIGS. 7 and 8, the LED 14 is mounted to an axle 70. The axle 70 is mounted horizontally to the walls of the rigid connector 22 and spans across the lighting chamber 42. The axle 70 at each end passes through the walls of the rigid connector piece. A hub 72, 74 is attached to either end of the axle 70 to secure the axle 70 in place. The LED 14 is fixed in relation to the axle 70, however, the rotational position of the axle 70 can be adjusted by turning a screw, FIG. 5, associated with the hub 74. The angular orientation of the LED 14 will normally be set in the factory as mentioned above, but the screw 76 allows the user to adjust its position in the field. If desired, the body of the rigid connector 22 can include demarcations (not shown) providing a rough estimate to the user of the standoff distance corresponding to the position of the screw 76.

The polychromatic light 16 is preferably an LED having a wide white light spectrum and drawing a low level DC current. The purpose of the polychromatic light source 16 as mentioned is to effectively light the surface being painted so that the painter can see the true color of the surface and the paint being applied to the surface. Note that the polychromatic light source 16 is supported by a downward extending flange 78 from the top wall of the rigid connector 22.

Referring now to FIGS. 9-13, many aspects of the design of the ergonomic adapter 10 are ornamental in nature, however, many of the dimensions are chosen for functional purposes. For example, referring specifically to FIGS. 10 and 13, the inside surface of the collar 20 is preferably cylindrical in shape and preferably measures slightly greater than 2½ inches (e.g. substantially about 2.54 inches) across the diameter. This diameter is chosen because it is slightly smaller than the standard aerosol paint can. It should not be greater than 2.7 inches to fit most standard sized spray paint cans. However, some spray paint cans, as well as other types of aerosol spray cans, have a different diameter, and the collars 20 for the adapter should be sized accordingly for these cans. The adapter 10 will normally need to stretch slightly in order to fit over a standard spray can 12. Note that the curvature for the inside wall of the rigid connector 22 should be consistent with the curvature of the inside surface of the collar 18. Referring now to FIGS. 9, 11 and 12, the preferred height of the collar 18 is slightly less than 1.5 inches. This size has been selected because with the preferred collar material, it provides a good balance of friction for holding the adapter 10 to the spray can 12 and also provides significant room for ergonomic gripping of the collar, while at the same time is not inconvenient for the user to fit over a standard spray can.

The traction pads 50 shown in FIGS. 10 and 13 are located rearward of the stop 54, FIG. 13 on the finger strip for the push-button nozzle. The maximum thickness across the collar 18 at the traction pads 50 is preferably about 0.5 inches, although it may be desirable to make the traction pads 50 smaller in order to accommodate users with small hands. It should also be noted that it is important that the rigid connector piece 22 and the contained electronics do not extend too far forward from the push-button nozzle 36 when the adapter 10 is mounted to a spray can 12. In the preferred embodiment of the invention, the distance from of the rear of the adapter 10 to the front portion of the rigid connector piece 22 is slightly greater than 3¾ inches. This distance has been found to be suitable in the preferred configuration, shown in FIGS. 1 and 3, in which the rigid connector 22 does not extend significantly higher than the interface between the can body and the domed top when the adapter 10 is fitted to a standard spray can 12.

Referring now to FIG. 14, a second embodiment of the invention is shown. In FIG. 14, the rigid adapter 222 does not include any electrical components as in the embodiment disclosed in FIGS. 1-13. The purpose of the rigid connector 22 is merely to connect the arms 20 of the collar together. Preferably, the dimensions across the rigid connector 222 shown in FIG. 14 between the arms 20 of the collar 18 are the same as with the rigid connector 22 shown in FIGS. 1-13. In this way, the adapter components molded from resilient elastomeric material, namely the collar and the arcuate finger strip can be used with either adapter 222 (FIG. 14) which contains no electronics or the adapter 22 (FIGS. 1-13) which contains the polychromatic light source 16 and the single beam light source 14. The connector piece 222 in FIG. 14 also preferably includes an alignment guide 228 as described above in the other embodiment.

Another embodiment of the invention is shown in FIGS. 15 through 20. Referring FIGS. 15-20, the ergonomic adapter 310 does not include an arcuate finger strip as described in the earlier embodiments. The ergonomic adapter 310 does however include an elastomeric collar 318 that fits around the cylindrical body of the aerosol spray can 12 and a light beam targeting and the positioning arrangement 314 and polychromatic light source 316. The collar 318 extends completely around the spray can, and passes through the rigid housing 322 to attach the housing 322 to the adapter 310. FIGS. 16 and 17 show a user's hand 14 gripping the collar 318 on the ergonomic adapter 312. As in the earlier embodiments, the collar is made from a resilient elastomeric material which improves traction and the ability of the user to comfortably grip the spray can not having a non-skid surface. The collar 318 shown in FIGS. 15 through 20 is made of butyl rubber having a durometer of about 80, although other elastomeric materials can be used. The collar 318 also has a rough finish to enhance surface frictionagainst both the can and the user's hand.

The collar 318 shown in FIGS. 15-20 has a constant thickness, e.g. 0.25 inches, except for a pair of recessed gripping regions 319. The recessed gripping regions are preferably recessed about 0.125 inches and contain vertical knurls 321. The recessed gripping regions are located symmetrically along the collar 318 ahead of the push-button nozzle 36, i.e., more than 90° from the rear centerline of the collar 318. As shown in FIGS. 16 and 17, the user's thumb 48 resides in one of the recessed gripping regions 319 and one or more the user's fingers 52 resides in the other recessed gripping region 319. The inside diameter of the collar is preferably slightly greater than 2.5 inches such that it needs to stretch in order to fit over standard size aerosol spray can. The preferred height of the collar 318 is slightly less than 1.5 inches. This size as mentioned above is selected because, with the preferred elastomeric collar materials, this size provides a good balance of friction for holding the adapter 310 to the spray can 12 and significant room for ergonomic gripping of the collar, while at the same time is convenient for the user to fit over a spray can.

The rigid housing 322 includes a lighting chamber 342. Referring now in particular to FIGS. 18-20, a single beam light source 314 is located in the lighting chamber 342 above a polychromatic light source 316. The use of the light beam positioning and targeting system is similar as it is described in the other embodiments. Again, it may be desirable to use a suitable dual beam system, in lieu of the single beam system shown in the FIGS. 15-20. The light sources 314 and 316 are each fixed to a respective horizontal axle that is rotatably mounted to the walls of the rigid housing 322. The knobs 315, 317 for the axles use friction against the housing wall to hold the respective axle and light source in position. In order to adjust the orientation of the light sources 314, 316, the user squeezes the respective knobs 315, 317 on either side of the housing to release frictional engagement and turns the respective axle and light source.

The lighting chamber 342 includes a front opening 344. A clear polycarbonate lens 356 covers the front opening 344 in the lighting chamber 342. Note that the walls of the housing 322 include longitudinal notches 345 to facilitate the sliding of the clear lens 356 into place. As mentioned, the lens can be removed in order to facilitate cleaning.

Referring to the light beam source 314, as mentioned above, one of the keys to paint quality is properly targeting and overlapping of the paint pattern on the surface. The adjustable knob 315 allows the user to adjust the light dot on the painted surface in the center of the spray pattern. By visualizing the center of the spray pattern with the targeting dot on the surface, it is easier for the user to properly target, overlap and minimize overspray. This results in significant improvement and transfer efficiency, resulting in less wasted paint and a reduction in volatile organic compounds being admitted in the atmosphere. These advantages of the single beam system apply to a greater or lesser extent even if the user does not use the single beam system to locate the spray can at the proper distance from the painted surface. It has been found that placing the light beam source 314 above the polychromatic light source 316 in the lighting chamber 342 puts the light beam in a more natural targeting orientation for some users.

The preferred polychromatic light source 316 is a white light LED. The light source 316 floods the surface with white light, improving surface visualization. As mentioned, the orientation of the polychromatic light source 316 is also adjustable vertically.

Referring to FIG. 19, a four-way, push-button switch 330 is provided at the bottom of the housing 322 to operate the light sources 314 and 316. The switch 330 is connected to a printed circuit board 332 which is mounted along the floor of the housing 322. The printed circuit board 332 controls power to the light sources from four AAA batteries 360. Reference number 373 shows a representative electrical contact for the batteries. The circuitry on the board 332 regulates voltage to the light sources and provides protection in case a battery is inserted incorrectly, as is known in the art. The first press of the power button 330 turns on the light beam source 314 only. The second push of the button turns on the polychromatic light source 316, and turns off the light beam source 314. The third push of the button 330 turns on both the light sources 314 and 316. The fourth push of the button 330 turns off both light sources 314 and 316.

Referring in particular to FIG. 18, the four batteries 360 are installed into a cartridge 364, and are held in place in between electrical contacts as is known in the art. With the batteries 360 installed, the cartridge 364 is inserted into a rear battery compartment 362 in the housing 322. The cartridge 364 includes a top lid 365. The top lid 365 includes a sliding tab mechanism 367 for locking the cartridge 364 in place after it is inserted. Referring to FIG. 19, the locking tab mechanism 367 has a downwardly extending finger 369 that engages a hole 370 in a wall separating the lighting chamber 342 from the battery chamber 362, see, e.g., FIG. 18.

The lid 365 also includes a forward extending plank 369 that covers the top of the lighting chamber 342 when the cartridge 364 is locked into place. The plank 369 includes a target line 371 that is molded into the top surface of the cover 365, and preferably pad printed or painted in a conspicuous color. The target line 371 provides the user with a convenient reference point for aligning the ergonomic adapter 310 with the spray can push-nozzle 36. Once properly aligned, the target line 371 allows the user to quickly and easily reference the orientation of the spray can and the push-button nozzle 36 with respect to the surface being painted.

While the invention has been described in connection with several embodiments, those skilled in the art should recognize that the various aspects of the invention can be embodied in other configurations than those described specifically in these embodiments. Also, those skilled in the art will recognize that it may be desirable to implement the invention with a polychromatic light source and without the laser guide, or alternatively with the laser guide and without the polychromatic light source. Further, as mentioned, it may be desirable to use a dual beam targeting and positioning technique instead of the single beam technique shown specifically in the drawings. In addition, in a system without the lighting sources, the targeting line can be applied directly to the front of the collar.

Those skilled in the art should appreciate that use of the invention helps users reduce the most common quality problems associated with spray painting, namely running and overspray. It also improves visualization of the painted surface. While embodiments of the ergonomic adapter have been described for use in connection with aerosol spray paint cans, an ergonomic adapter made in accordance with the invention can be used in connection with other types of aerosol spray cans, such as insecticides or industrial lubricants or aerosol spray tanning products, although not all of the features described herein may be particularly useful in those applications.

Claims

1. For use in connection with an aerosol spray can having a push-button nozzle extending upward from a top surface of the can, an ergonomic adapter comprising: an elastomeric collar that fits around a cylindrical body of the aerosol spray can such that a front portion of the collar is facing in front of the can and in the direction in which contents of the can are expelled from the push-button nozzle on the top of the spray can;a rigid housing connected to the elastomeric collar, the housing including a compartment with a forward facing opening;one or more light sources including at least a light beam targeting arrangement located within the compartment;a transparent lens that covers the front opening in the housing compartment;wherein the height of the elastomeric collar is sufficient to provide ergonomic gripping surface regions such that when the ergonomic adapter is fitted around the aerosol spray can and the user grips the adapter with the user's index finger resting on the push-button nozzle extending upward from the top surface of the can, the user's thumb engages a gripping surface region on side of the collar and the user's other fingers engage a gripping surface region on the other side of the collar.

2. An ergonomic adapter as recited in claim 1 wherein the height of the collar is slightly less than 1.5 inches.

3. The ergonomic adapter as recited in claim 1 wherein the collar extends completely around the aerosol spray can.

4. An ergonomic adapter as recited in claim 2 wherein the collar is made of elastomeric material having a durometer between 30 and 90.

5. An ergonomic adapter as recited in claim 5 wherein the surface of the collar has a rough finish.

6. An ergonomic adapter as recited in claim 1 wherein the collar has a constant thickness except for a pair of recessed gripping regions including vertical knurls located symmetrically along the collar more than 90° from the rear centerline of the collar.

7. An ergonomic adapter as recited in claim 1 wherein a top surface of the housing includes a conspicuous targeting line pointing straight forward which is within the view of a user using the adapter on a spray can.

8. An ergonomic adapter as recited in claim 1 wherein the relaxed diameter of the elastomeric collar is about 2.54 inches and provides adequate ability to stretch the collar to fit over a standard sized aerosol spray can having a cylindrical diameter of approximately 2.7 inches.

9. An ergonomic adapter as recited in claim 1 wherein the light beam targeting arrangement projects at least one light beam towards the surface being painted to facilitate positioning of the spray can and the push-button nozzle on the spray can relative to the surface, and wherein the light beam targeting arrangement includes a light beam generator that generates the linear light beam, and the adapter and the light beam targeting arrangement are configured such that the linear light beam from the light beam generator is directed toward the surface within the spray pattern, and the linear light beam defines a point within the spray pattern upon striking the surface to provide a reference point for the user in determining the position of the spray can relative to the surface.

10. An ergonomic adapter as recited in claim 10 further comprising a manual adjustment mechanism for the light beam source which changes angular orientation of the light beam propagating from the light source, wherein the manual adjustment mechanism comprises a rotatable axle to which the laser source is mounted, a first adjustable axle hub and a second adjustable axle hub that mount the axle to the rigid housing horizontally within the housing compartment.

11. An ergonomic adapter as recited in claim 1 wherein one or more of the light sources in the rigid housing are part of a dual beam targeting and positioning arrangement.

12. An ergonomic adapter as recited in claim 1 wherein the one or more the light sources in the housing includes a polychromatic light source for illuminating the surface tape.

13. An ergonomic adapter as recited in claim 12 wherein the polychromatic light source is located below the light beam light source within the housing compartment.

14. An ergonomic adapter as recited in claim 12 further comprising a manual adjustment mechanism for the polychromatic light source which changes the horizontal angular orientation of the polychromatic light illumination, wherein the manual adjustment mechanism comprises a rotatable axle to which the polychromatic light source is mounted, a first adjustable axle hub and a second adjustable axle hub that mount the axle to the rigid housing horizontal within the housing chamber.

15. For use in connection with an aerosol spray can having a push-button nozzle extending upward from a top surface of the can, an ergonomic adapter comprising: an elastomeric collar that fits around a cylindrical body of the aerosol spray can such that a front portion of the collar is facing in front of the can and in the direction in which contents of the can are expelled from the push-button nozzle on the top of the spray can, wherein the collar is made of an elastomeric material having a durometer of between 30 to 90 and the surface of the collar has a rough finish; wherein the height of the elastomeric collar is sufficient to provide ergonomic gripping surface regions such that when the adapter is fitted on a aerosol spray can and the user grips the adapter with the user's index finger resting on the push-button extending upward from the top surface of the can, the user's thumb engages a recessed gripping surface region on one side of the collar and the user's other fingers engage a recessed gripping surface region on the other side of the collar wherein each recessed gripping surface region is symmetrically located along the collar more than 90° from the rear centerline of the collar, the collar extending completely around the spray can, wherein each gripping surface region is defined by a dimple containing gripping knurls, the dimples being symmetrically located along the collar more than 90° from the rear centerline of the collar; anda conspicuous targeting line pointing straight forward which is within the view of a user using the adapter on a spray can.

16. An ergonomic adapter as recited in claim 16 wherein the relaxed diameter of the elastomeric collar is about 2.54 inches and the collar provides adequate ability to stretch in order to fit over a standard-sized aerosol spray can having a cylindrical body diameter of approximately 2.7 inches.