Title of Invention	LIQUID SPRAY GUN WITH MANUALLY SEPARABLE PORTIONS
Abstract	The present invention provides a liquid spray gun with several improved features, including (1) a molded polymeric possibly disposable body assembly through which passes liquid sprayed by the spray gun that is manually releasable from a metal platform portion of the spray gun through which air is fed to passageways through the body assembly to spray the liquid; (2) non-cylindrical air passageways on air horns that provide improved shape and uniformity for the wide elongate stream of liquid formed by the spray gun, and (3) an air cap portion of the body assembly mounted for manual rotation on a nozzle portion of the body assembly between positions defined by stops and retained at those positions by friction.

Title of Invention

LIQUID SPRAY GUN WITH MANUALLY SEPARABLE PORTIONS

Abstract

The present invention provides a liquid spray gun with several improved features, including (1) a molded polymeric possibly disposable body assembly through which passes liquid sprayed by the spray gun that is manually releasable from a metal platform portion of the spray gun through which air is fed to passageways through the body assembly to spray the liquid; (2) non-cylindrical air passageways on air horns that provide improved shape and uniformity for the wide elongate stream of liquid formed by the spray gun, and (3) an air cap portion of the body assembly mounted for manual rotation on a nozzle portion of the body assembly between positions defined by stops and retained at those positions by friction.

Full Text	LIQUID SPRAY GUN WITH MANUALLY SEPARABLE PORTIONS Field of the Invention This invention relates to liquid spray guns of the type comprising a body assembly including a nozzle portion having a liquid passageway extending to an outlet end opening through an outlet end of the nozzle portion, the body assembly having a first air passageway having an outlet end at the outlet end of the nozzle portion that extends around the outlet, end of the liquid outlet passageway and is shaped to direct air under greater than atmospheric pressure against liquid flowing out of the outlet end of the liquid outlet passageway to propel the liquid away from that outlet end while shaping the liquid into a generally conical stream about an axis; the body assembly including horns projecting past the outlet end of the nozzle on opposite sides of the axis, and also having a second air passageway extending to outlet passageways and apertures spaced along the horns from the outlet end of the nozzle portion and facing opposite sides of the axis, which outlet passageways and apertures direct air under greater than atmospheric pressure flowing through the second air passageway against opposite sides of the stream of liquid formed by air flowing through the first air passageway to reshape that stream into a wide elongate stream; the liquid spray gun further including a platform portion having through air distribution passageways including an inlet opening adapted to be connected to a supply of ah under greater than atmospheric pressure, first and second air outlet openings, means for separately regulating the flow of air through the first and second air outlet openings of the air distribution passageways, and manually operated means for stopping or allowing flow of air through the outlet openings of the air distribution passageways; and the platform portion and the nozzle portion having means for mounting the nozzle portion on the platform portion with the first and second air outlet openings of the air distribution passageways communicating with inlet ends of the first and second passageways. Background of the Invention The prior art includes liquid spray guns of the type comprising a body assembly including a nozzle portion having a liquid passageway extending to an outlet end opening through an outlet end of the nozzle portion, the body assembly having a first air passageway extending to an outlet end at the outlet end of the nozzle portion that extends around the outlet end of the liquid outlet passageway and is shaped to direct air under greater than atmospheric pressure against liquid flowing out of the outlet end of the liquid outlet passageway to propel the liquid away from that outlet end while shaping the liquid into a generally conical stream about an axis; the body assembly including horns projecting past the outlet end of the nozzle on opposite sides of the axis, and also having a second air passageway extending to outlet passageways and apertures spaced along the horns from the outlet end of the nozzle portion and facing opposite sides of the axis, which outlet passageways and apertures direct air under greater than atmospheric pressure flowing through the second air passageway against opposite sides of the stream of liquid formed by air flowing through the first air passageway to reshape that stream into a wide elongate stream; the liquid spray gun further including a platform portion having through air distribution passageways including an inlet opening adapted to be connected to a supply of air under greater than atmospheric pressure, first and second air outlet openings, means for separately regulating the flow of air through the first and second air outlet openings of the air distribution passageways, and manually operated means for stopping or allowing flow of air through the outlet openings of the air distribution passageways; and the platform portion and the nozzle portion having means for mounting the nozzle portion on the platform portion with the first and second air outlet openings of the ah' distribution passageways communicating with inlet ends of the first and second passageways. U.S. Patents Nos. 5,090,623 (Burns et al.); 5,102,051 (Smith et al); 5,209,405 (Robinson et al); and 5,322,221 (Anderson) and U.S. Patent Application Publication No. US 2002/0148910 Al published October 17, 2002, provide illustrative examples. In the spray guns described in those U.S. Patents typically the nozzle portions can be removed from the platform portions, however the means for mounting the nozzle portions on the platform portions includes attachment members such as threaded nuts that must be removed with a tool such as a wrench, thereby adding difficulty to that removal process. Disclosure of the Invention The present invention provides a liquid spray gun generally of the type described above that is more easily disassembled between successive uses. According to the present invention there is provided a liquid spray gun comprising a body assembly including a nozzle portion having a liquid passageway extending to an outlet end opening through an outlet end of the nozzle portion, the body assembly having a first air passageway extending to an outlet end at the outlet end of the nozzle portion that extends around the outlet end of the liquid outlet passageway and is shaped to direct air under greater than atmospheric pressure against liquid flowing out of the outlet end of the liquid outlet passageway to propel the liquid away from that outlet end while shaping the liquid into a generally conical stream about an axis; the body assembly including horns projecting past the outlet end of the nozzle on opposite sides of the axis, and also having a second air passageway extending to outlet passageways and apertures spaced along the horns from the outlet end of the nozzle portion and facing opposite sides of the axis, which outlet passageways and apertures direct air under greater than atmospheric pressure flowing through the second air passageway against opposite sides of the stream of liquid formed by air flowing through the first air passageway to reshape that stream into a wide elongate stream; the liquid spray gun further including a platform portion having through air distribution passageways including an inlet opening adapted to be connected to a supply of air under greater than atmospheric pressure, first and second air outlet openings, means for separately regulating the flow of air through the first and second air outlet openings of the air distribution passageways, and manually operated means for stopping or allowing flow of air through the outlet openings of the air distribution passageways; and the platform portion and the nozzle portion having manually releasable means (i.e., means manually operable by a person without the use of tools) for mounting the nozzle portion on the platform portion with the first and second air outlet openings of the air distribution passageways communicating with inlet ends of the first and second passageways. The manually operable means for releasably mounting the nozzle portion on the platform portion can comprise the platform portion including a support wall, an opening through the support wall between inner and outer surfaces of the support wall, and the nozzle portion including a projection from a contact surface on the side of the nozzle portion opposite its outlet end, the projection being received in the support wall opening with the contact surface against the outer surface of the support wall, and a distal part of the projection projecting past the outer surface of support wall, the distal part of the projection having a transverse groove, and the manually operable means further including a latching member releasably engaged in the transverse groove adapted for manual removal from the distal part. The platform portion can be reusable (i.e., made of metal), and the nozzle and air cap portions can be molded of a polymeric material. The molded air cap and nozzle portions can be sufficiently inexpensive that they can be discarded rather than cleaned for some applications. The passageways on the horns opening through the outlet apertures that direct high velocity air flowing through the second air passageway against opposite sides of a stream of liquid formed by air flowing through the first air passageway to reshape that generally conical stream of liquid into a wide elongate stream can have a greater width in a direction at a right angle to the axis than depth in a direction parallel to the axis (e.g., the outlet apertures can be generally rectangular). Such a shape has been found to form a liquid stream that is very uniform in width and in the amount of liquid delivered per unit time along its length to facilitate uniform application of the liquid to a surface. The body assembly can include an air cap including the horns that is molded of polymeric material, with the non-circular passageways leading to the outlet apertures being formed during the molding process. Means are provided for mounting the molded polymeric air cap portion on the nozzle portion, with the molded air cap and the nozzle portion having surfaces forming the first and second air passageways. The means mounting the air cap portion on the nozzle portion can allow rotation of the air cap portion about the axis relative to the nozzle portion, the air cap and nozzle portions can include stops limiting relative rotation of the air cap portion relative to the nozzle portion to rotation through a predetermined angle (e.g., 90 degrees) between first and second relative positions, and the means mounting the air cap portion on the nozzle portion can include surfaces in frictional engagement to restrict relative rotation of the air cap and nozzle portions until a predetermined torque is manually applied between the air cap and nozzle portions. Thus a person wishing to change the relative position of the air cap portion on the nozzle portion need only rotate the air cap portion relative to the nozzle portion, and the air cap portion will remain in that position until it is again repositioned by the operator. Brief Description of the Drawing The present invention will be further described with reference to the accompanying drawings wherein like reference numerals refer to like or corresponding parts throughout the several views, and wherein: Figure 1 is a side view of a liquid spraying device according to the present invention Figure 2 is an opposite side view of the liquid spraying device of Figure 1 in which i a nozzle portion, an air cap portion and a platform portion of the spraying device are separated from each other; Figure 3 is an enlarged front view of the platform portion of the liquid spraying device as seen along line 3-3 of Figure 2; Figure 4 is a enlarged fragmentary vertical cross sectional view of the liquid spraying device of Figure 1; Figure 5 is a sectional view taken approximately along line 5-5 of Figure 4 after the nozzle portion is removed from the platform portion; Figure 6 is a sectional view taken approximately along line 6-6 of Figure 4 after the nozzle portion is removed from the platform portion; Figure 7 is a side view of the platform portion of the liquid spraying device of Figure 1 which has been partially sectioned to show detail; Figure 8 is a rear view of the nozzle portion included in the spraying device of Figure 1; Figure 9 is a sectional view taken approximately along line 9-9 of Figure 8; Figure 10 is a front view of the nozzle portion of figure 2; Figure 11 is an enlarged rear view of the air cap portion included in the spraying device of Figure 1; Figure 12 is a sectional view taken approximately along line 12-12 of Figure 11; Figure 13 is a sectional view taken approximately along line 13-13 of Figure 12; and Figures 14,15, 16, and 17 are enlarged illustrations of alternative shapes that could be used for outlet passageways and apertures in horns on the air cap portion included in the spraying device of Figure 1. Detailed Description of the Invention i Referring now to the drawing there is illustrated a liquid spraying device or spray gun 10 according to the present invention. Generally, the liquid spray gun 10 comprises a body assembly 12 including a nozzle portion 14 with an outlet end 15. The nozzle portion 14 has a liquid passageway 16 extending from an inlet end 17 to an outlet end 18 opening through the outlet end 15 of the nozzle portion 14. The body assembly 12 also has a first air passageway 20 extending from an inlet end 21 to an outlet end 22 at the outlet end 15 of the nozzle portion 14. The outlet end 22 of the first air passageway 20 extends around the outlet end 18 of the liquid passageway 16 and is shaped to direct air under greater than atmospheric pressure against liquid flowing out of the outlet end 18 of the liquid passageway 16 to propel liquid flowing out of the liquid passageway 16 away from the outlet end 15 of the nozzle portion 14 while shaping the liquid into a generally conical stream about an axis 23. The body assembly 12 includes horns 24 projecting past the outlet end 15 of the nozzle portion 14 on opposite sides of that axis 23, and the body assembly 12 has a second air passageway 26 extending from an inlet end 27 through portions of the horns 24 to outlet passageways 28 having outlet apertures spaced along the horns 24 from the outlet end 15 of the nozzle portion 14 and facing opposite sides of the axis 23. The outlet passageways 28 and apertures are non-circular and are shaped to direct air under greater than atmospheric pressure flowing through the second air passageway 26 against opposite sides of a generally conical stream of liquid formed by air flowing through the first air passageway 20 to reshape that generally conical stream of liquid into a wide elongate stream. The outlet passageways 28 and apertures are generally rectangular and have a greater width in a direction at a right angle to the axis 23 than depth in a direction parallel to the axis. As a non-limiting example, as illustrated the outlet passageways 28 and apertures can comprise first and second pairs 28a and 28b of opposed outlet passageways 28 and apertures on the horns 24, the first pair of outlet passageways 28a and apertures each having a width in a direction at a right angle to the axis 23 of about 0.154 inch or 0.39 cm, a depth in a direction parallel to the axis 23 of about 0.35 inch or 0.89 cm, and being spaced about 0.25 inch or 0.64 cm from the outlet end 15 of the nozzle portion 14, with the outlet passageways 28a being disposed at an angle of about 66 degrees with respect to the axis; and the second pair of outlet passageways 28b and apertures each having a width in a direction at a right angle to the axis 23 of about 0.165 inch or 0.42 cm, a depth in a direction parallel to the axis of about 0.050 inch or 0.13 cm, and being spaced about 0.35 inch or 0.89 cm from the outlet end 15 of the nozzle portion 14 with the outlet passageways 28b being disposed at an angle of about 75 degrees with respect to the axis 23. The body assembly 12 includes an air cap portion 30 including the horns 24 that is preferably molded of a polymeric material (e.g., polypropylene, polyethylene, or glass filled nylon), with the outlet passageways 28 and apertures being formed by the molding process. The body assembly 12 also includes means for mounting the air cap portion 30 on the nozzle portion 14 so that adjacent surfaces of the air cap portion 30 and the nozzle portion 14 form parts of the first and second air passageways 20 and 26, The means mounting the air cap portion 30 on the nozzle portion 14 includes a radially outwardly projecting annular ring 32 around the outlet end 15 of the nozzle portion 14 co-axial with the axis 23, and a generally cylindrical collar 33 on the air cap portion 30 having an annular recess 34 from its inner surface adapted to receive the annular ring 32 of the nozzle portion 14. The collar 33 on the air cap portion 30 is sufficiently resiliently flexible that the inner surface of the collar 33 can be pressed over the annular ring 32 to position the ring 32 in the recess 34. A cylindrical part 35 of the inner surface of the air cap portion has a close sliding fit around an outer surface of a cylindrical portion 37 of the nozzle portion 14 to separate the first and second air passageways 20 and 26. This means for mounting the air cap portion 30 on the nozzle portion allows rotation of the air cap portion 30 about the axis 23 relative to the nozzle portion 14. The air cap and nozzle portions 30 and 14 include stops 36 and 38 respectively that limit relative rotation of the air cap and nozzle portions 30 and 14 to rotation through a predetermined angle (90 degrees as illustrated) between first and second relative positions. This means mounting the air cap portion 30 on the nozzle portion 14 also includes surfaces on the air cap and nozzle portions 30 and 14 in frictional engagement (i.e., such engagement can be with each other as illustrated or, alternatively, could be with a frictional layer, not shown, between the air cap and nozzle portions 30 and 14) to restrict relative rotation of the air cap and nozzle portions 30 and 14 until a predetermined torque is manually applied between the air cap and nozzle portions 30 and 14. That predetermined torque should be enough to restrict rotation of the air cap portion 30 on the nozzle portion 14 by slight contact with the air cap portion, but not so much that it is difficult to manually rotate the nozzle portion 14 on the air cap portion 30. Such torque should thus be in the range of 5 to 40 inch pounds, and more preferably in the range of 10 to 20 inch pounds. An O-ring 39 is positioned between the air cap and nozzle portions 30 and 14 to restrict leakage between the collar 33 and the nozzle portion 14. The outlet end 22 of the first air passageway 20 is shaped to direct a peripheral portion of air exiting the first air passageway 20 in a converging conical pattern (e.g., converging at an angle in the range of about 30 to 45 degrees with respect to the axis 23 against liquid exiting the outlet end 18 of the liquid passageway 16. This converging conical pattern better atomizes the liquid leaving the outlet end 18 of the liquid passageway 16 than would air flowing out of the outlet end 22 of the first air passageway 20 in a direction parallel to the stream of fluid leaving the outlet end 18 of the liquid passageway 16. The liquid spray gun 10 further includes a platform portion 40 including a frame 41 having through air distribution passageways including an inlet passageway 42 (see Figures 3 and 7) with an inlet end 45 adapted to be connected to a supply of air under greater than atmospheric pressure, first and second air outlet openings 43 and 44, means in the form of an adjustable valve member 46 for regulating the portion of air flow through the air distribution passageways that can flow to the second air outlet opening 44, and manually operated valve means 47 for stopping or allowing flow of air from the inlet passageway 42 to the outlet openings 43 and 44 of the air distribution passageways. The platform portion 40 and the nozzle portion 14 have manually operable means for releasably mounting the nozzle portion 14 on the platform portion 40 with the first and second air outlet openings 43 and 44 of the air distribution passageways communicating with the inlet ends 21 and 27 of the first and second air passageways 20 and 26 respectively. That manually operable means (see Figure 4) comprises the platform portion 40 including a support wall 48 having opposite inner and outer surfaces 49 and 50, a cylindrical opening 51 through the support wall 48 between its inner and outer surfaces 49 and 50; and the nozzle portion 14 including a projection 52 beyond a contact surface 53 on the side of the nozzle portion 14 opposite its outlet end 18. The projection 52 is received in the opening 51 through the support wall 48 with the contact surface 53 against its outer surface 50 and a distal part of the projection 52 projecting past the inner surface 49 of the support wall 48. The distal part of the projection 52 has a transverse annular groove 56, and the manually operable means further includes a plate-like latch member 55 mounted on the frame 41 for sliding movement transverse of the opening 51 between (1) an engaged position at which a generally C-shaped portion of the latch member 55 having a latching surface 55a facing away from the support wall 48 that is about normal to the axis of the opening 51 will be positioned in a portion of the transverse groove 56 if the projection 52 is fully engaged in the opening 51 to retain the projection 52 and thereby the nozzle portion 14 in engagement with the platform portion 40, and (2) a release position to which the latch member 55 can be manually slid against the bias of a spring 54 between the latch member 55 and the frame 41 that biases the latch member 55 to its engaged position, at which release position a circular opening 55c through the latch member 55 larger in diameter than the projection 52 is aligned with the projection 52 to allow the nozzle portion 14 to be mounted on or removed from the platform portion 40. The latch member 55 includes a cam surface 55b on its side opposite the latching surface 55a that faces the support wall 48 and is disposed at an angle (e.g., about 45 degrees) with respect to the axis of the opening 51 so that pressing the distal end of the projection 52 against the cam surface 55b will cause the latch member 55 to move to its release position and allow the distal end of the projection 52 to move past the latch member 55 until the projection 52 is fully engaged in the opening 51, whereupon the latching surface 55a will move into engagement with a portion of the transverse groove 56 (the latching position of the latch member 55) under the influence of the spring 54 to retain the projection 52 and thereby the nozzle portion 14 in engagement with the platform portion 40. The platform portion 40 can be made by modifying a metal spray gun that is commercial available under the trade designation "HVLP Gravity feed spray gun" from Graco, Minneapolis, MN, by adding to the frame 41 a portion 41a for mounting the latch member 55 described above and by adding to the frame 41 a plate 58 which provides the outer surface 50 shaped for sealing engagement with the contact surface 53 on the nozzle portion 14, and in which the first and second air outlet openings 43 and 44 are formed. The second air outlet openings 44 are defined by sockets adapted to closely receive projecting tubular portions 59 that are at the inlet ends 27 of the second air passageways 26 in the nozzle portion 14. The plate 55 has an opening 71 adapted to closely receive a projection 57 on the nozzle portion 14 to help locate the nozzle portion 14 on the plate 58, and has a groove 69 around its periphery adapted to receive in sealing engagement a projecting lip 68 around the periphery of the nozzle portion 14. The manually operated valve means 46 (see Figure 7) for stopping or allowing flow of air from the inlet passageway 42 to the outlet openings 43 and 44 of the air distribution passageways includes a valve seat on the frame 41 around an opening 60 between the inlet passageway 42 and a second air passageway 61 included in the air distribution passageways that is parallel to the inlet passageway 42. The valve member 62 is mounted on the frame 41 for movement between (1) a closed position engaging that seat to prevent flow of air through the opening 60 to which closed position the valve member 62 is biased by a spring 63 between the valve member 62 and the frame 41, and (2) positions spaced from the seat around that opening 60 to allow various rates of air to flow from the inlet passageway 42 to the second air passageway 61, and from there to the first outlet openings 43 and to the second outlet openings 44 if the valve member 46 is open. Such movement of the valve member 62 to positions spaced from the seat can be caused by manually pulling a trigger member 64 pivotally mounted on the frame 41 by a pin 65 toward a handle portion 66 of the frame 41. The amount of such movement that can be caused by pulling the trigger member 64 is determined by a stop member 67 in threaded engagement with the frame 41 so that the maximum amount of such movement is adjustable. A fluid flow control needle 70 is attached to the valve member 62. The fluid flow control needle 70 extends through a central bore 72 in the projection 52 and through a seal 74 in the bore 72 around its periphery which separates part of the liquid passageway 16 adjacent its outlet end 18 from the opposite end of that bore 72 (see figure 4). A generally conical end portion 75 of that needle 70 is positioned against the inner surface of and closes the liquid passageway 16 adjacent its outlet end 18 when the valve member 62 is positioned in its closed position to which it is biased by the spring 63. The end portion 75 of that needle 70 moves away from the inner surface of the liquid passageway 16 to allow liquid to flow through it when the trigger member 64 is manually moved toward the handle portion 66 and away from its closed position against the bias of the spring 63. The end portion 75 of the needle is formed of polymeric material and tapered at a much smaller angle than the valve member 62 so that the valve member 62 will open to allow air to flow through the outlet openings 43 and 44 of the air distribution passageways, through the first and second air passageways 20 and 26, out of the outlet end 22 of the first air passageway 20, and out of the outlet passageways 28 of the second air passageway 26 (if the valve member 46 is open) before fluid can flow out of the outlet end 18 of the liquid passageway 16. Liquid can be gravity fed to the outlet end 15 of the liquid passageway 16 from a suitable container at its inlet end 17, which container could be the container described in U.S. Patent No.6,588,681 that includes a portion of a connector adapted for manually releasable engagement with a connector portion 80 illustrated about the inlet end 17 of the liquid passageway 16. Alternatively, smaller volume liquid containers such as those described in U.S. Patent No. 6,752,179 (Schwartz) could be used. Optionally, a pressure tap 77 (see Figure 2) communicating with the second air passageway 26 and closed when not used could be provided to supply air pressure to the pressurized liquid container described in U.S. Patent Application Publication No. US 2004/0084553 Al, published May 6, 2004, which pressurized liquid container could be used to supply liquid to the liquid passageway 16 of the spray gun 10. The pressure tap 77 should communicate with the second air passageway 26 at a position spaced (e.g. over 1 inch or 2.54 cm) from the outlet passageways 28 and outlet apertures in the air horns 24 so that it does not cause air pressure differences between the two horns 24. The body assembly 12 including both the nozzle portion 14 and the air cap portion 30 can be molded of a suitable polymeric material (e.g., polypropylene, polyethylene, or glass filled nylon). The body assembly 12, and particularly its nozzle portion 14 will make most of the contact with a liquid (e.g., paint) being sprayed (i.e., only the needle 70 on the platform portion 40 will contact that liquid), and the molded body assembly 12 can be sufficiently inexpensive that it can be discarded rather than being cleaned for some applications. The present invention has now been described with reference to one embodiment and possible modifications thereof. It will be apparent to those skilled in the art that many changes can be made in the embodiments described without departing from the scope of the present invention. For example, the outlet passageways 28 and apertures in the air horns 24 that have a greater width in a direction at a right angle to the axis 23 than depth in a direction parallel to the axis 23 could have shapes other than rectangular, such as, but not limited to, oval shapes 28a and 28b illustrated in Figures 14 and 15, diamond shapes such as the diamond shape 28c illustrated in Figure 16, or shapes with an enlarged (e.g., generally circular, rectangular or oval) center portions and with more narrow portions extending on opposite sides of the center portion such as the shape 28d illustrated in Figure 17. Thus, the scope of the present invention should not be limited to the structures and methods described in this application, but only by the structures and methods described by the language of the claims and the equivalents thereof. What is claimed is: 1. A contrast media injector system comprising: an injector head; a contrast container holder connected with the injector head, said contrast container holder configured to hold a contrast container in a substantially fixed position while said injector head is oriented substantially vertical. 2. The contrast media injector system according to claim 1 wherein the contrast container holder further comprises: a support arm having a first end and a second end, said first end adapted to couple with the injector head; a securing portion connected to the second end, said securing portion configured to prevent movement of the contrast container substantially in a horizontal plane and a vertical plane. 3. The contrast media injector system according to claim 2, wherein the support arm is integrally formed with the injector head. 4. The contrast media injector system according to claim 2, wherein the first end is removally coupled with the injector head. 5. The contrast media injector system according to claim 3, wherein said support arm further comprises: a control portion mechanically coupled with the first end, said control portion having a first position that prevents the first end from being uncoupled from the injector head and a second position that permits the first end to be uncoupled from the injector head. 6. The contrast media injector system according to claim 1, further comprising: a syringe connected to the injector head; a contrast container; a fill tube coupling the syringe to the contrast container; and wherein the contrast container holder is further configured to hold the contrast container while the injector system operates to fill the syringe with a contrast media from the contrast container. 7. The contrast injector system according to claim 1, wherein the substantially fixed position orients the contrast container so as to be tilted toward the injector head. 8. The contrast injector system according to claim 1, wherein inserting or removing the contrast container relative to the contrast container holder can be accomplished by an operator of the injector system using only one hand. 9. A method for performing a filling sequence in a contrast media injector system having a fill tube coupling a syringe to a contrast media, the method comprising the steps of: expelling substantially ail air from the fill tube; thereafter, filling the syringe at a first rate wherein aeration of the contrast media is prevented, said first rate being faster than a second rate that is a maximum fill rate if air is not previously expelled from the fill tube. 10. The method according to claim 9 wherein the step of expelling includes the steps of: drawing a first amount of contrast media into the syringe; and expelling the first amount out of the syringe and fill tube. 11. The method according to claim 9, wherein the step of expelling includes expelling substantially all air from the syringe. 12. A method for changing contrast media containers during a syringe filling sequence, comprising the steps of. pausing the syringe filling sequence of a syringe when a first contrast container is substantially emptied; replacing the first contrast container with a second contrast container; expelling substantially all air from a fill tube coupled between the syringe and the second contrast container; and thereafter, resuming filling the syringe from the second contrast container at a first rate wherein aeration of the contrast media is prevented, said first rate being faster than a second rate that is a maximum fill rate if air is not previously expelled from the fill tube. 13. The method according to claim 12 wherein the step of expelling further includes the step of: expelling a portion of contrast media in the syringe out of the fill tube into the second contrast container. 14. The method according to claim 12, wherein the step of expelling further includes expelling substantially all air from the syringe. Dated this 30 day of June 2006

Full Text

LIQUID SPRAY GUN WITH MANUALLY SEPARABLE PORTIONS
Field of the Invention
This invention relates to liquid spray guns of the type comprising a body assembly including a nozzle portion having a liquid passageway extending to an outlet end opening through an outlet end of the nozzle portion, the body assembly having a first air passageway having an outlet end at the outlet end of the nozzle portion that extends around the outlet, end of the liquid outlet passageway and is shaped to direct air under greater than atmospheric pressure against liquid flowing out of the outlet end of the liquid outlet passageway to propel the liquid away from that outlet end while shaping the liquid into a generally conical stream about an axis; the body assembly including horns projecting past the outlet end of the nozzle on opposite sides of the axis, and also having a second air passageway extending to outlet passageways and apertures spaced along the horns from the outlet end of the nozzle portion and facing opposite sides of the axis, which outlet passageways and apertures direct air under greater than atmospheric pressure flowing through the second air passageway against opposite sides of the stream of liquid formed by air flowing through the first air passageway to reshape that stream into a wide elongate stream; the liquid spray gun further including a platform portion having through air distribution passageways including an inlet opening adapted to be connected to a supply of ah under greater than atmospheric pressure, first and second air outlet openings, means for separately regulating the flow of air through the first and second air outlet openings of the air distribution passageways, and manually operated means for stopping or allowing flow of air through the outlet openings of the air distribution passageways; and the platform portion and the nozzle portion having means for mounting the nozzle portion on the platform portion with the first and second air outlet openings of the air distribution passageways communicating with inlet ends of the first and second passageways.
Background of the Invention
The prior art includes liquid spray guns of the type comprising a body assembly including a nozzle portion having a liquid passageway extending to an outlet end opening through an outlet end of the nozzle portion, the body assembly having a first air

passageway extending to an outlet end at the outlet end of the nozzle portion that extends around the outlet end of the liquid outlet passageway and is shaped to direct air under greater than atmospheric pressure against liquid flowing out of the outlet end of the liquid outlet passageway to propel the liquid away from that outlet end while shaping the liquid into a generally conical stream about an axis; the body assembly including horns projecting past the outlet end of the nozzle on opposite sides of the axis, and also having a second air passageway extending to outlet passageways and apertures spaced along the horns from the outlet end of the nozzle portion and facing opposite sides of the axis, which outlet passageways and apertures direct air under greater than atmospheric pressure flowing through the second air passageway against opposite sides of the stream of liquid formed by air flowing through the first air passageway to reshape that stream into a wide elongate stream; the liquid spray gun further including a platform portion having through air distribution passageways including an inlet opening adapted to be connected to a supply of air under greater than atmospheric pressure, first and second air outlet openings, means for separately regulating the flow of air through the first and second air outlet openings of the air distribution passageways, and manually operated means for stopping or allowing flow of air through the outlet openings of the air distribution passageways; and the platform portion and the nozzle portion having means for mounting the nozzle portion on the platform portion with the first and second air outlet openings of the ah' distribution passageways communicating with inlet ends of the first and second passageways. U.S. Patents Nos. 5,090,623 (Burns et al.); 5,102,051 (Smith et al); 5,209,405 (Robinson et al); and 5,322,221 (Anderson) and U.S. Patent Application Publication No. US 2002/0148910 Al published October 17, 2002, provide illustrative examples. In the spray guns described in those U.S. Patents typically the nozzle portions can be removed from the platform portions, however the means for mounting the nozzle portions on the platform portions includes attachment members such as threaded nuts that must be removed with a tool such as a wrench, thereby adding difficulty to that removal process.
Disclosure of the Invention
The present invention provides a liquid spray gun generally of the type described above that is more easily disassembled between successive uses.

According to the present invention there is provided a liquid spray gun comprising a body assembly including a nozzle portion having a liquid passageway extending to an outlet end opening through an outlet end of the nozzle portion, the body assembly having a first air passageway extending to an outlet end at the outlet end of the nozzle portion that extends around the outlet end of the liquid outlet passageway and is shaped to direct air under greater than atmospheric pressure against liquid flowing out of the outlet end of the liquid outlet passageway to propel the liquid away from that outlet end while shaping the liquid into a generally conical stream about an axis; the body assembly including horns projecting past the outlet end of the nozzle on opposite sides of the axis, and also having a second air passageway extending to outlet passageways and apertures spaced along the horns from the outlet end of the nozzle portion and facing opposite sides of the axis, which outlet passageways and apertures direct air under greater than atmospheric pressure flowing through the second air passageway against opposite sides of the stream of liquid formed by air flowing through the first air passageway to reshape that stream into a wide elongate stream; the liquid spray gun further including a platform portion having through air distribution passageways including an inlet opening adapted to be connected to a supply of air under greater than atmospheric pressure, first and second air outlet openings, means for separately regulating the flow of air through the first and second air outlet openings of the air distribution passageways, and manually operated means for stopping or allowing flow of air through the outlet openings of the air distribution passageways; and the platform portion and the nozzle portion having manually releasable means (i.e., means manually operable by a person without the use of tools) for mounting the nozzle portion on the platform portion with the first and second air outlet openings of the air distribution passageways communicating with inlet ends of the first and second passageways.
The manually operable means for releasably mounting the nozzle portion on the platform portion can comprise the platform portion including a support wall, an opening through the support wall between inner and outer surfaces of the support wall, and the nozzle portion including a projection from a contact surface on the side of the nozzle portion opposite its outlet end, the projection being received in the support wall opening with the contact surface against the outer surface of the support wall, and a distal part of the projection projecting past the outer surface of support wall, the distal part of the

projection having a transverse groove, and the manually operable means further including a latching member releasably engaged in the transverse groove adapted for manual removal from the distal part.
The platform portion can be reusable (i.e., made of metal), and the nozzle and air cap portions can be molded of a polymeric material. The molded air cap and nozzle portions can be sufficiently inexpensive that they can be discarded rather than cleaned for some applications.
The passageways on the horns opening through the outlet apertures that direct high velocity air flowing through the second air passageway against opposite sides of a stream of liquid formed by air flowing through the first air passageway to reshape that generally conical stream of liquid into a wide elongate stream can have a greater width in a direction at a right angle to the axis than depth in a direction parallel to the axis (e.g., the outlet apertures can be generally rectangular). Such a shape has been found to form a liquid stream that is very uniform in width and in the amount of liquid delivered per unit time along its length to facilitate uniform application of the liquid to a surface.
The body assembly can include an air cap including the horns that is molded of polymeric material, with the non-circular passageways leading to the outlet apertures being formed during the molding process. Means are provided for mounting the molded polymeric air cap portion on the nozzle portion, with the molded air cap and the nozzle portion having surfaces forming the first and second air passageways.
The means mounting the air cap portion on the nozzle portion can allow rotation of the air cap portion about the axis relative to the nozzle portion, the air cap and nozzle portions can include stops limiting relative rotation of the air cap portion relative to the nozzle portion to rotation through a predetermined angle (e.g., 90 degrees) between first and second relative positions, and the means mounting the air cap portion on the nozzle portion can include surfaces in frictional engagement to restrict relative rotation of the air cap and nozzle portions until a predetermined torque is manually applied between the air cap and nozzle portions. Thus a person wishing to change the relative position of the air cap portion on the nozzle portion need only rotate the air cap portion relative to the nozzle portion, and the air cap portion will remain in that position until it is again repositioned by the operator.

Brief Description of the Drawing
The present invention will be further described with reference to the accompanying drawings wherein like reference numerals refer to like or corresponding parts throughout the several views, and wherein:
Figure 1 is a side view of a liquid spraying device according to the present invention
Figure 2 is an opposite side view of the liquid spraying device of Figure 1 in which
i
a nozzle portion, an air cap portion and a platform portion of the spraying device are separated from each other;
Figure 3 is an enlarged front view of the platform portion of the liquid spraying device as seen along line 3-3 of Figure 2;
Figure 4 is a enlarged fragmentary vertical cross sectional view of the liquid spraying device of Figure 1;
Figure 5 is a sectional view taken approximately along line 5-5 of Figure 4 after the nozzle portion is removed from the platform portion;
Figure 6 is a sectional view taken approximately along line 6-6 of Figure 4 after the nozzle portion is removed from the platform portion;
Figure 7 is a side view of the platform portion of the liquid spraying device of Figure 1 which has been partially sectioned to show detail;
Figure 8 is a rear view of the nozzle portion included in the spraying device of Figure 1;
Figure 9 is a sectional view taken approximately along line 9-9 of Figure 8;
Figure 10 is a front view of the nozzle portion of figure 2;
Figure 11 is an enlarged rear view of the air cap portion included in the spraying device of Figure 1;
Figure 12 is a sectional view taken approximately along line 12-12 of Figure 11;
Figure 13 is a sectional view taken approximately along line 13-13 of Figure 12; and
Figures 14,15, 16, and 17 are enlarged illustrations of alternative shapes that could be used for outlet passageways and apertures in horns on the air cap portion included in the spraying device of Figure 1.

Detailed Description of the Invention
i
Referring now to the drawing there is illustrated a liquid spraying device or spray gun 10 according to the present invention. Generally, the liquid spray gun 10 comprises a body assembly 12 including a nozzle portion 14 with an outlet end 15. The nozzle portion 14 has a liquid passageway 16 extending from an inlet end 17 to an outlet end 18 opening through the outlet end 15 of the nozzle portion 14. The body assembly 12 also has a first air passageway 20 extending from an inlet end 21 to an outlet end 22 at the outlet end 15 of the nozzle portion 14. The outlet end 22 of the first air passageway 20 extends around the outlet end 18 of the liquid passageway 16 and is shaped to direct air under greater than atmospheric pressure against liquid flowing out of the outlet end 18 of the liquid passageway 16 to propel liquid flowing out of the liquid passageway 16 away from the outlet end 15 of the nozzle portion 14 while shaping the liquid into a generally conical stream about an axis 23. The body assembly 12 includes horns 24 projecting past the outlet end 15 of the nozzle portion 14 on opposite sides of that axis 23, and the body assembly 12 has a second air passageway 26 extending from an inlet end 27 through portions of the horns 24 to outlet passageways 28 having outlet apertures spaced along the horns 24 from the outlet end 15 of the nozzle portion 14 and facing opposite sides of the axis 23. The outlet passageways 28 and apertures are non-circular and are shaped to direct air under greater than atmospheric pressure flowing through the second air passageway 26 against opposite sides of a generally conical stream of liquid formed by air flowing through the first air passageway 20 to reshape that generally conical stream of liquid into a wide elongate stream. The outlet passageways 28 and apertures are generally rectangular and have a greater width in a direction at a right angle to the axis 23 than depth in a direction parallel to the axis.
As a non-limiting example, as illustrated the outlet passageways 28 and apertures can comprise first and second pairs 28a and 28b of opposed outlet passageways 28 and apertures on the horns 24, the first pair of outlet passageways 28a and apertures each having a width in a direction at a right angle to the axis 23 of about 0.154 inch or 0.39 cm, a depth in a direction parallel to the axis 23 of about 0.35 inch or 0.89 cm, and being spaced about 0.25 inch or 0.64 cm from the outlet end 15 of the nozzle portion 14, with the outlet passageways 28a being disposed at an angle of about 66 degrees with respect to the

axis; and the second pair of outlet passageways 28b and apertures each having a width in a direction at a right angle to the axis 23 of about 0.165 inch or 0.42 cm, a depth in a direction parallel to the axis of about 0.050 inch or 0.13 cm, and being spaced about 0.35 inch or 0.89 cm from the outlet end 15 of the nozzle portion 14 with the outlet passageways 28b being disposed at an angle of about 75 degrees with respect to the axis 23.
The body assembly 12 includes an air cap portion 30 including the horns 24 that is preferably molded of a polymeric material (e.g., polypropylene, polyethylene, or glass filled nylon), with the outlet passageways 28 and apertures being formed by the molding process. The body assembly 12 also includes means for mounting the air cap portion 30 on the nozzle portion 14 so that adjacent surfaces of the air cap portion 30 and the nozzle portion 14 form parts of the first and second air passageways 20 and 26, The means mounting the air cap portion 30 on the nozzle portion 14 includes a radially outwardly projecting annular ring 32 around the outlet end 15 of the nozzle portion 14 co-axial with the axis 23, and a generally cylindrical collar 33 on the air cap portion 30 having an annular recess 34 from its inner surface adapted to receive the annular ring 32 of the nozzle portion 14. The collar 33 on the air cap portion 30 is sufficiently resiliently flexible that the inner surface of the collar 33 can be pressed over the annular ring 32 to position the ring 32 in the recess 34. A cylindrical part 35 of the inner surface of the air cap portion has a close sliding fit around an outer surface of a cylindrical portion 37 of the nozzle portion 14 to separate the first and second air passageways 20 and 26. This means for mounting the air cap portion 30 on the nozzle portion allows rotation of the air cap portion 30 about the axis 23 relative to the nozzle portion 14. The air cap and nozzle portions 30 and 14 include stops 36 and 38 respectively that limit relative rotation of the air cap and nozzle portions 30 and 14 to rotation through a predetermined angle (90 degrees as illustrated) between first and second relative positions. This means mounting the air cap portion 30 on the nozzle portion 14 also includes surfaces on the air cap and nozzle portions 30 and 14 in frictional engagement (i.e., such engagement can be with each other as illustrated or, alternatively, could be with a frictional layer, not shown, between the air cap and nozzle portions 30 and 14) to restrict relative rotation of the air cap and nozzle portions 30 and 14 until a predetermined torque is manually applied between the air cap

and nozzle portions 30 and 14. That predetermined torque should be enough to restrict rotation of the air cap portion 30 on the nozzle portion 14 by slight contact with the air cap portion, but not so much that it is difficult to manually rotate the nozzle portion 14 on the air cap portion 30. Such torque should thus be in the range of 5 to 40 inch pounds, and more preferably in the range of 10 to 20 inch pounds. An O-ring 39 is positioned between the air cap and nozzle portions 30 and 14 to restrict leakage between the collar 33 and the nozzle portion 14.
The outlet end 22 of the first air passageway 20 is shaped to direct a peripheral portion of air exiting the first air passageway 20 in a converging conical pattern (e.g., converging at an angle in the range of about 30 to 45 degrees with respect to the axis 23 against liquid exiting the outlet end 18 of the liquid passageway 16. This converging conical pattern better atomizes the liquid leaving the outlet end 18 of the liquid passageway 16 than would air flowing out of the outlet end 22 of the first air passageway 20 in a direction parallel to the stream of fluid leaving the outlet end 18 of the liquid passageway 16.
The liquid spray gun 10 further includes a platform portion 40 including a frame 41 having through air distribution passageways including an inlet passageway 42 (see Figures 3 and 7) with an inlet end 45 adapted to be connected to a supply of air under greater than atmospheric pressure, first and second air outlet openings 43 and 44, means in the form of an adjustable valve member 46 for regulating the portion of air flow through the air distribution passageways that can flow to the second air outlet opening 44, and manually operated valve means 47 for stopping or allowing flow of air from the inlet passageway 42 to the outlet openings 43 and 44 of the air distribution passageways. The platform portion 40 and the nozzle portion 14 have manually operable means for releasably mounting the nozzle portion 14 on the platform portion 40 with the first and second air outlet openings 43 and 44 of the air distribution passageways communicating with the inlet ends 21 and 27 of the first and second air passageways 20 and 26 respectively. That manually operable means (see Figure 4) comprises the platform portion 40 including a support wall 48 having opposite inner and outer surfaces 49 and 50, a cylindrical opening 51 through the support wall 48 between its inner and outer surfaces 49 and 50; and the nozzle portion 14 including a projection 52 beyond a contact surface 53 on

the side of the nozzle portion 14 opposite its outlet end 18. The projection 52 is received in the opening 51 through the support wall 48 with the contact surface 53 against its outer surface 50 and a distal part of the projection 52 projecting past the inner surface 49 of the support wall 48. The distal part of the projection 52 has a transverse annular groove 56, and the manually operable means further includes a plate-like latch member 55 mounted on the frame 41 for sliding movement transverse of the opening 51 between (1) an engaged position at which a generally C-shaped portion of the latch member 55 having a latching surface 55a facing away from the support wall 48 that is about normal to the axis of the opening 51 will be positioned in a portion of the transverse groove 56 if the projection 52 is fully engaged in the opening 51 to retain the projection 52 and thereby the nozzle portion 14 in engagement with the platform portion 40, and (2) a release position to which the latch member 55 can be manually slid against the bias of a spring 54 between the latch member 55 and the frame 41 that biases the latch member 55 to its engaged position, at which release position a circular opening 55c through the latch member 55 larger in diameter than the projection 52 is aligned with the projection 52 to allow the nozzle portion 14 to be mounted on or removed from the platform portion 40. The latch member 55 includes a cam surface 55b on its side opposite the latching surface 55a that faces the support wall 48 and is disposed at an angle (e.g., about 45 degrees) with respect to the axis of the opening 51 so that pressing the distal end of the projection 52 against the cam surface 55b will cause the latch member 55 to move to its release position and allow the distal end of the projection 52 to move past the latch member 55 until the projection 52 is fully engaged in the opening 51, whereupon the latching surface 55a will move into engagement with a portion of the transverse groove 56 (the latching position of the latch member 55) under the influence of the spring 54 to retain the projection 52 and thereby the nozzle portion 14 in engagement with the platform portion 40.
The platform portion 40 can be made by modifying a metal spray gun that is commercial available under the trade designation "HVLP Gravity feed spray gun" from Graco, Minneapolis, MN, by adding to the frame 41 a portion 41a for mounting the latch member 55 described above and by adding to the frame 41 a plate 58 which provides the outer surface 50 shaped for sealing engagement with the contact surface 53 on the nozzle portion 14, and in which the first and second air outlet openings 43 and 44 are formed.

The second air outlet openings 44 are defined by sockets adapted to closely receive projecting tubular portions 59 that are at the inlet ends 27 of the second air passageways 26 in the nozzle portion 14. The plate 55 has an opening 71 adapted to closely receive a projection 57 on the nozzle portion 14 to help locate the nozzle portion 14 on the plate 58, and has a groove 69 around its periphery adapted to receive in sealing engagement a projecting lip 68 around the periphery of the nozzle portion 14.
The manually operated valve means 46 (see Figure 7) for stopping or allowing flow of air from the inlet passageway 42 to the outlet openings 43 and 44 of the air distribution passageways includes a valve seat on the frame 41 around an opening 60 between the inlet passageway 42 and a second air passageway 61 included in the air distribution passageways that is parallel to the inlet passageway 42. The valve member 62 is mounted on the frame 41 for movement between (1) a closed position engaging that seat to prevent flow of air through the opening 60 to which closed position the valve member 62 is biased by a spring 63 between the valve member 62 and the frame 41, and (2) positions spaced from the seat around that opening 60 to allow various rates of air to flow from the inlet passageway 42 to the second air passageway 61, and from there to the first outlet openings 43 and to the second outlet openings 44 if the valve member 46 is open. Such movement of the valve member 62 to positions spaced from the seat can be caused by manually pulling a trigger member 64 pivotally mounted on the frame 41 by a pin 65 toward a handle portion 66 of the frame 41. The amount of such movement that can be caused by pulling the trigger member 64 is determined by a stop member 67 in threaded engagement with the frame 41 so that the maximum amount of such movement is adjustable. A fluid flow control needle 70 is attached to the valve member 62. The fluid flow control needle 70 extends through a central bore 72 in the projection 52 and through a seal 74 in the bore 72 around its periphery which separates part of the liquid passageway 16 adjacent its outlet end 18 from the opposite end of that bore 72 (see figure 4). A generally conical end portion 75 of that needle 70 is positioned against the inner surface of and closes the liquid passageway 16 adjacent its outlet end 18 when the valve member 62 is positioned in its closed position to which it is biased by the spring 63. The end portion 75 of that needle 70 moves away from the inner surface of the liquid passageway 16 to allow liquid to flow through it when the trigger member 64 is manually moved toward the handle portion 66

and away from its closed position against the bias of the spring 63. The end portion 75 of the needle is formed of polymeric material and tapered at a much smaller angle than the valve member 62 so that the valve member 62 will open to allow air to flow through the outlet openings 43 and 44 of the air distribution passageways, through the first and second air passageways 20 and 26, out of the outlet end 22 of the first air passageway 20, and out of the outlet passageways 28 of the second air passageway 26 (if the valve member 46 is open) before fluid can flow out of the outlet end 18 of the liquid passageway 16.
Liquid can be gravity fed to the outlet end 15 of the liquid passageway 16 from a suitable container at its inlet end 17, which container could be the container described in U.S. Patent No.6,588,681 that includes a portion of a connector adapted for manually releasable engagement with a connector portion 80 illustrated about the inlet end 17 of the liquid passageway 16. Alternatively, smaller volume liquid containers such as those described in U.S. Patent No. 6,752,179 (Schwartz) could be used.
Optionally, a pressure tap 77 (see Figure 2) communicating with the second air passageway 26 and closed when not used could be provided to supply air pressure to the pressurized liquid container described in U.S. Patent Application Publication No. US 2004/0084553 Al, published May 6, 2004, which pressurized liquid container could be used to supply liquid to the liquid passageway 16 of the spray gun 10. The pressure tap 77 should communicate with the second air passageway 26 at a position spaced (e.g. over 1 inch or 2.54 cm) from the outlet passageways 28 and outlet apertures in the air horns 24 so that it does not cause air pressure differences between the two horns 24.
The body assembly 12 including both the nozzle portion 14 and the air cap portion 30 can be molded of a suitable polymeric material (e.g., polypropylene, polyethylene, or glass filled nylon). The body assembly 12, and particularly its nozzle portion 14 will make most of the contact with a liquid (e.g., paint) being sprayed (i.e., only the needle 70 on the platform portion 40 will contact that liquid), and the molded body assembly 12 can be sufficiently inexpensive that it can be discarded rather than being cleaned for some applications.
The present invention has now been described with reference to one embodiment and possible modifications thereof. It will be apparent to those skilled in the art that many changes can be made in the embodiments described without departing from the scope of

the present invention. For example, the outlet passageways 28 and apertures in the air horns 24 that have a greater width in a direction at a right angle to the axis 23 than depth in a direction parallel to the axis 23 could have shapes other than rectangular, such as, but not limited to, oval shapes 28a and 28b illustrated in Figures 14 and 15, diamond shapes such as the diamond shape 28c illustrated in Figure 16, or shapes with an enlarged (e.g., generally circular, rectangular or oval) center portions and with more narrow portions extending on opposite sides of the center portion such as the shape 28d illustrated in Figure 17. Thus, the scope of the present invention should not be limited to the structures and methods described in this application, but only by the structures and methods described by the language of the claims and the equivalents thereof.

What is claimed is:
1. A contrast media injector system comprising:
an injector head;
a contrast container holder connected with the injector head, said contrast container holder configured to hold a contrast container in a substantially fixed position while said injector head is oriented substantially vertical.
2. The contrast media injector system according to claim 1 wherein the contrast
container holder further comprises:
a support arm having a first end and a second end, said first end adapted to couple with the injector head;
a securing portion connected to the second end, said securing portion configured to prevent movement of the contrast container substantially in a horizontal plane and a vertical plane.
3. The contrast media injector system according to claim 2, wherein the support arm is integrally formed with the injector head.
4. The contrast media injector system according to claim 2, wherein the first end is removally coupled with the injector head.

5. The contrast media injector system according to claim 3, wherein said support
arm further comprises:
a control portion mechanically coupled with the first end, said control portion having a first position that prevents the first end from being uncoupled from the injector head and a second position that permits the first end to be uncoupled from the injector head.
6. The contrast media injector system according to claim 1, further comprising:
a syringe connected to the injector head;
a contrast container;
a fill tube coupling the syringe to the contrast container; and
wherein the contrast container holder is further configured to hold the contrast container while the injector system operates to fill the syringe with a contrast media from the contrast container.
7. The contrast injector system according to claim 1, wherein the substantially
fixed position orients the contrast container so as to be tilted toward the injector
head.
8. The contrast injector system according to claim 1, wherein inserting or
removing the contrast container relative to the contrast container holder can be
accomplished by an operator of the injector system using only one hand.

9. A method for performing a filling sequence in a contrast media injector system
having a fill tube coupling a syringe to a contrast media, the method comprising
the steps of:
expelling substantially ail air from the fill tube;
thereafter, filling the syringe at a first rate wherein aeration of the contrast media is prevented, said first rate being faster than a second rate that is a maximum fill rate if air is not previously expelled from the fill tube.
10. The method according to claim 9 wherein the step of expelling includes the
steps of:
drawing a first amount of contrast media into the syringe; and expelling the first amount out of the syringe and fill tube.
11. The method according to claim 9, wherein the step of expelling includes
expelling substantially all air from the syringe.

12. A method for changing contrast media containers during a syringe filling
sequence, comprising the steps of.
pausing the syringe filling sequence of a syringe when a first contrast container is substantially emptied;
replacing the first contrast container with a second contrast container;
expelling substantially all air from a fill tube coupled between the syringe and the second contrast container; and
thereafter, resuming filling the syringe from the second contrast container at a first rate wherein aeration of the contrast media is prevented, said first rate being faster than a second rate that is a maximum fill rate if air is not previously expelled from the fill tube.
13. The method according to claim 12 wherein the step of expelling further
includes the step of:
expelling a portion of contrast media in the syringe out of the fill tube into the second contrast container.
14. The method according to claim 12, wherein the step of expelling further
includes expelling substantially all air from the syringe.
Dated this 30 day of June 2006

Documents:

2401-CHENP-2006 AMENDED PAGES OF SPECIFICATION 06-02-2012.pdf

2401-CHENP-2006 AMENDED CLAIMS 06-02-2012.pdf

2401-CHENP-2006 AMENDED PAGES OF SPECIFICATION 21-02-2012.pdf

2401-CHENP-2006 CORRESPONDENCE OTHERS 13-09-2011.pdf

2401-CHENP-2006 FORM-3 06-02-2012.pdf

2401-CHENP-2006 OTHER PATENT DOCUMENT 06-02-2012.pdf

2401-CHENP-2006 POWER OF ATTORNEY 06-02-2012.pdf

2401-CHENP-2006 CORRESPONDENCE OTHERS 21-02-2012.pdf

2401-CHENP-2006 CORRESPONDENCE PO.pdf

2401-CHENP-2006 EXAMINATION REPORT REPLY RECEIVED 06-02-2012.pdf

2401-CHENP-2006 FORM-18.pdf

2401-chenp-2006 claims.pdf

2401-chenp-2006 correspondence others.pdf

2401-chenp-2006 form-3.pdf

2401-chenp-2006 petition.pdf

2401-chenp-2006-abstract.pdf

2401-chenp-2006-assignement.pdf

2401-chenp-2006-claims.pdf

2401-chenp-2006-correspondnece-others.pdf

2401-chenp-2006-description(complete).pdf

2401-chenp-2006-drawings.pdf

2401-chenp-2006-form 1.pdf

2401-chenp-2006-form 26.pdf

2401-chenp-2006-form 3.pdf

2401-chenp-2006-form 5.pdf

2401-chenp-2006-pct.pdf

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Patent Number

251253

Indian Patent Application Number

2401/CHENP/2006

PG Journal Number

10/2012

Publication Date

09-Mar-2012

Grant Date

05-Mar-2012

Date of Filing

30-Jun-2006

Name of Patentee

3M INNOVATIVE PROPERTIES COMPANY

Applicant Address

3M Center, Post Office Box 33427, Saint Paul, Minnesota 55133-3427

Inventors:

#	Inventor's Name	Inventor's Address
1	BLETTE, Russell, E.,;	Post Office Box 33427, Saint Paul, Minnesota 55133-3427
2	FREDERICKSON, Franklyn, L.;	Post Office Box 33427, Saint Paul, Minnesota 55133-3427
3	JOSEPH, Stephen, C., P.;	Post Office Box 33427, Saint Paul, Minnesota 55133-3427
4	QIBLAWI, Jameel, R.;	Post Office Box 33427, Saint Paul, Minnesota 55133-3427

PCT International Classification Number

B05B7/08,7/24

PCT International Application Number

PCT/US2004/042635

PCT International Filing date

2004-12-16

PCT Conventions:

#	PCT Application Number	Date of Convention	Priority Country
1	10/748,494	2003-12-30	U.S.A.