Adjustable spray pattern sprinkler

TECHNICAL FIELD

The present invention relates to systems and methods for irrigating soil. More specifically, the present invention relates to a sprinkler head and related methods that distribute water over a variable spray pattern.

BACKGROUND

Irrigation not only permits foodstuffs to be grown, but also enables the cultivation of attractive plant life that otherwise would not have sufficient water to thrive. Many households now utilize sprinkler systems to provide irrigation in a comparatively uniform and trouble-free manner.

Often, a control unit such as a timer is used to regularly initiate operation of the sprinkler system to automatically provide the desired distribution of irrigation water. The timer is electrically connected to a plurality of electrically operated valves, each of which is able to permit water to flow into a corresponding zone of the sprinkler system. Each zone may have a number of sprinklers, each of which is designed to distribute water in a predetermined pattern.

Sprinklers are available in a wide variety of different configurations, depending on the shape of the area to be irrigated. Some sprinklers spray water in a circular or part-circular pattern. For example, some sprinklers are designed to provide a quarter-circle pattern, while others spray water in half circle, three-quarters circle, or full-circle patterns. Additionally, some sprinklers are designed to irrigate a strip between a sidewalk and a street. Such sprinklers typically distribute water within a generally rectangular area. Strip sprinklers include multiple types, including center strip sprinklers, side strip sprinklers, and end strip sprinklers, depending may necessitate additional trips to the store to purchase and/or exchange sprinklers. Some areas, such as those with corners between 90°, 180°, 270°, and 360°, are difficult or impossible to adequately or efficiently irrigate with the limited number of spray angles available. Furthermore, if the irrigation needs within a certain area change over time, one or more sprinklers may need to be replaced with different types.

In order to alleviate some of the foregoing problems, variable arc sprinklers have been developed. Many known variable arc sprinklers have two helical edges that define a slot. The angular width of the slot can be varied by rotating one helical edge with respect to the other to vary the magnitude of the angle within which water is sprayed from the sprinkler.

Unfortunately, known variable arc sprinklers have a number of inherent limitations. For example, many such sprinklers require axial (i.e., vertical) motion of the top end of the sprinkler to provide adjustment. Hence, even if the sprinkler is initially installed at the proper height, subsequent adjustment of the sprinkler may remove the top of the sprinkler from its initial position. Thus, the sprinkler may not have sufficient spray clearance, or may be damaged by lawn care equipment.

Furthermore, many known variable arc sprinklers are unable to provide an even distribution of water across the selected angle. Thus, the corresponding soil is unevenly irrigated. Many known variable arc sprinklers are unable to effectively provide full-circle coverage because the flow of water from the sprinkler head is discontinuous over the adjacent ends of the arc. Hence, even at a “full-circle” setting, there may be 5% or more along which water is not sprayed from the head, or is sprayed at such a low volume that corresponding region is not sufficiently irrigated.

Yet further, many known variable arc sprinklers are relatively complex, and are therefore far more expensive than their fixed-angle counterparts. Some known variable arc dimensions of typical strips. Accordingly, the problems described above have not been fully remedied by existing sprinkler designs.

SUMMARY OF THE INVENTION

[SUMMARY OF THE CLAIMED INVENTION—TO BE COMPLETED AFTER THE CLAIMS ARE FINALIZED]

BRIEF DESCRIPTION OF THE DRAWINGS

A particular description of the invention will be rendered by reference to specific embodiments thereof which are illustrated in the appended drawings. Understanding that these drawings depict only typical embodiments of the invention and are not therefore to be considered to be limiting of its scope, the invention will be described and explained with additional specificity and detail through the use of the accompanying drawings in which:

FIG. 1 is a perspective view of an irrigation system according to one embodiment of the invention;

FIG. 2 is an exploded, perspective view of a spray head of one of the sprinklers of the irrigation system of FIG. 1;

FIG. 3A is a plan view of the housing and the cam of the spray head of FIG. 2, with the housing and cam (shown in phantom lines) relatively positioned for 90° watering;

FIG. 3B is a plan view of the housing and the cam of the spray head of FIG. 2, with the housing and cam (shown in phantom lines) relatively positioned for 180° watering;

FIG. 3C is a plan view of the housing and the cam of the spray head of FIG. 2, with the housing and cam (shown in phantom lines) relatively positioned for full-circle watering;

FIG. 4 is an exploded, perspective view of a spray head of a sprinkler according to

FIG. 7A is a plan view of the housing and the cam of the spray head of FIG. 6, with the housing and cam (shown in phantom lines) relatively positioned for center strip irrigation;

FIG. 7B is a plan view of a strip area in which the spray head of FIG. 6 is installed to provide center strip irrigation;

FIG. 7C is a plan view of the housing and the cam of the spray head of FIG. 6, with the housing and cam (shown in phantom lines) relatively positioned for side strip irrigation;

FIG. 7D is a plan view of a strip area in which the spray head of FIG. 6 is installed to provide side strip irrigation;

FIG. 7E is a plan view of the housing and the cam of the spray head of FIG. 6, with the housing and cam (shown in phantom lines) relatively positioned for side strip irrigation;

FIG. 7F is a plan view of a strip area in which the spray head of FIG. 6 is installed to provide end strip irrigation;

FIG. 8 is an exploded, perspective view of a spray head of a sprinkler according to one alternative embodiment of the invention;

FIG. 9A is a plan view of the housing and the cam of the spray head of FIG. 8, with the housing and cam (shown in phantom lines) relatively positioned for center strip irrigation;

FIG. 9B is a plan view of a strip area in which the spray head of FIG. 8 is installed to provide center strip irrigation;

FIG. 9C is a plan view of the housing and the cam of the spray head of FIG. 8, with the housing and cam (shown in phantom lines) relatively positioned for quarter side strip irrigation;

FIG. 9D is a plan view of a strip area in which the spray head of FIG. 8 is installed

FIG. 9F is a plan view of a strip area in which the spray head of FIG. 8 is installed to provide end strip irrigation.

DETAILED DESCRIPTION

The presently preferred embodiments of the present invention will be best understood by reference to the drawings, wherein like parts are designated by like numerals throughout. It will be readily understood that the components of the present invention, as generally described and illustrated in the figures herein, could be arranged and designed in a wide variety of different configurations. Thus, the following more detailed description of the embodiments of the apparatus, system, and method of the present invention, as represented in FIGS. 1 through 9F, is not intended to limit the scope of the invention, as claimed, but is merely representative of presently preferred embodiments of the invention.

For this application, the phrases “connected to,” “coupled to,” and “in communication with” refer to any form of interaction between two or more entities, including mechanical, electrical, magnetic, electromagnetic, and thermal interaction. The phrase “attached to” refers to a form of mechanical coupling that restricts relative translation or rotation between the attached objects. The phrases “pivotally attached to” and “slidably attached to” refer to forms of mechanical coupling that permit relative rotation or relative translation, respectively, while restricting other relative motion.

The phrase “attached directly to” refers to a form of attachment by which the attached items are either in direct contact, or are only separated by a single fastener, adhesive, or other attachment mechanism. The term “abutting” refers to items that are in direct physical contact with each other, although the items may not be attached together. The terms “integrally formed” refer to a body that is manufactured integrally, i.e., as a single piece, without requiring the lateral direction 14, and a transverse direction 16. The irrigation system 10 incorporates a valving system 20, which will be described in greater detail subsequently.

The irrigation system 10 is designed to receive water 22 via a main line 24. In this application, “water” includes not only pure water, but also water with additives such as fertilizers, pesticides, or the like. The water 22 is distributed by a plurality of water distribution units over a patch of land designated for plant growth.

“Water distribution unit” encompasses a variety of devices used to spread water, such as pop-up sprinkler heads, rotary sprinklers, bubblers, drip irrigation systems, and the like. The irrigation system 10 includes water distribution units in the form of a first sprinkler 26, a second sprinkler 28, and a third sprinkler 30. The sprinklers 26, 28, 30 are arrayed to irrigate an area 32. Of course, an irrigation system 10 may have more or less than three sprinklers. In FIG. 1, each of the sprinklers 26, 28, 30 is a pop-up sprinkler that includes a casing 33, a pop-up stem 34 designed to extend upward from within the casing 32 in response to water pressure, and a spray head 35 disposed on the top end of the corresponding pop-up stem 34 to distribute the water 22.

The first, second and third sprinklers 26, 28, 30 are supplied with water by first, second and third distribution conduits 36, 38, 40, respectively. Each of the distribution conduits 36, 38, 40 may extend further to supply additional water distribution units (not shown). In this application, a “conduit” is any structure capable of conducting a fluid under pressure from one location to another.

Water flow to the first, second, and third distribution conduits 36, 38, 40 is controlled by a first valve assembly 46, a second valve assembly 48, and a third valve assembly 50, respectively. The valve assemblies 46, 48, 50 may optionally operate to permit water flow to only one of the conduits 36, 38, 40 at any given time, so that each conduit 36, 38, 40, in turn, receives the full pressure and flow rate of water from the main line 24. The first, second, and 35 of the first sprinkler 26 is exposed to permit water flow from the spray head 35. The second and third valve assemblies 48, 50 are in the closed configuration so that no significant amount of water flows into the second and third conduits 38, 40, and the second and third sprinklers 28, 30 are inactive. The pop-up stems 34 and spray heads 35 of the second and third sprinklers 28, 30 are retracted into the corresponding casings 32.

Each of the valves 52, 54, 56 has a fluid transfer portion 60 in fluid communication with the associated distribution conduit 36, 38, or 40. The fluid transfer portion 60 contains one or more elements that block or unblock water flow through the fluid transfer portion 60. Thus, each of the valves 52, 54, 56 has a closed configuration, in which water flow is blocked, and an open configuration, in which water flow is comparatively freely permitted.

Each of the valve assemblies 46, 48, 50 also has an actuator portion 62 attached to the fluid transfer portion 60. The actuator portion 62 moves the interior elements of the fluid transfer portion 60 to move the valve assembly 46, 48, 50 between the open and closed configurations. The actuator portion 62 may include an electrically operated device such as a linear or rotary solenoid, piezoelectric actuator, or electric motor. The valve assemblies 46, 48, 50 also include first valve wires 66, second valve wires 68, and third valve wires 70, respectively. Each set of valve wires 66, 68, 70 is coupled to the actuator portion 62 of the corresponding valve 52, 54, 56.

In this application, the term “valve” generally refers to the combination of the fluid transfer portion 60 and the actuator portion 62. The term “valve” is not limited to the embodiment shown, but may include a wide variety of actuator and fluid transfer portion combinations.

The valve assemblies 46, 48, 50 are interconnected to form a manifold 72, to which the main line 24 and the distribution conduits 36, 38, 40 are attached. More precisely, the

A plurality of control unit wires 86 are connected to valve wires 66, 68, 70. Except at the ends, the control unit wires 86 are covered by a sheath 88 designed to gather and protect the control wires 86. The control unit wires 86 extend from the valve wires 66, 68, 70 to a control unit designed to transmit valve activation signals through the control wires 86. As depicted, the valve wires 66, 68, 70 are connected to the control unit wires 86 via conventional wire nuts. If desired, the control wires 86 may alternatively be coupled to the valve wires 66, 68, 70 via some type of electrical junction unit.

The control unit may take the form of a timer 90, as illustrated in FIG. 1. The timer 90 transmits the valve activation signals via the control unit wires 86 according to a schedule established by a user. The phrase “control unit” is not limited to a timer, but may include any other device that transmits a valve activation signal. Such devices include simple switches, remote receivers, control system processors designed to measure variables and control operation of the irrigation system 10 based on those variables, and the like. The timer 90 may be attached to a wall 92 near the manifold box 82, as shown, or may be disposed at a remote location.

The configuration of FIG. 1 is not the only application in which valves according to the invention may be used. Valves such as the valves 52, 54, 56 may be used in other types of irrigation systems. For example, the valves 52, 54, 56 may be incorporated into a hose bib system. Thus, the valves 52, 54, 56 may be attached to a common above-ground garden spigot, either individually or as part of a differently configured manifold. The distribution conduits 36, 38, 40 may be effectively replaced with hoses or other above-ground irrigation water lines. One or more timers may be incorporated into the housings of the valves 52, 54, 56 to provide a simple and compact irrigation control system.

Referring to FIG. 2, an exploded, perspective view illustrates the spray head 35 of one of the sprinklers 26, 28, 30 of FIG. 1 in greater detail. As shown, the spray head 35 pop-up stem 34 below the spray head 35 to filter water entering the spray head 35 and to provide flow rate adjustment in a manner that will be described subsequently.

As shown, the housing 106 has an inlet portion 114 and an outlet portion 116. The housing 106 has an outer wall 118 with a generally tubular shape concentric with a cam axis 120. The outer wall 118 has female threads disposed on an interior surface (not shown) of the inlet portion 114. The outer wall 118 also has indentations 122 distributed about its outer surface, within the inlet portion 114 to facilitate rotation of the housing 106 by hand. More precisely, a user may grip the outer wall 118 with a thumb and forefinger and rotate the housing 106 via the indentations 122 with the thumb and forefinger to rotate the spray head 35 into engagement with the pop-up stem 34.

The outlet portion 116 of the housing 106 has a plate 124 with a substantially flat configuration that extends across the open interior of the outer wall 118, substantially perpendicular to the cam axis 120. In this application, “substantially flat” refers to an element with a face extending substantially along a plane. A “plate” is a substantially flat element with a comparatively small thickness perpendicular to the face. A central hole 126 is formed in the plate 124. The central hole 126 has a lip 128 that steps inward so that the central hole 126 has two distinct diameters. The plate 124 also has a receiving hole 130 that does not extend entirely through the plate 124.

Additionally, the plate 124 has a plurality of outlet apertures, including a first outlet aperture 132, a second outlet aperture 134, a third outlet aperture 136, a fourth outlet aperture 138, a fifth outlet aperture 140, and an sixth outlet aperture 142. As shown, each of the outlet apertures 132, 134, 136, 138, 140, 142 is elongated along a curved path with a radius that gradually increases within an angle, with respect to the cam axis 120.

More precisely, as each of the outlet apertures 132, 134, 136, 138, 140, 142 extends substantially circular pattern) about the cam axis 120, with a radius that gradually increases throughout the 360° angle of rotation of the path.

The outlet apertures 132, 134, 136, 138, 140, 142 are separated from each other by bridges 144. In alternative embodiments, the bridges 144 may be omitted to provide one single outlet aperture that provides the entire range of adjustability for a spray head. In the embodiment of FIG. 2, the bridges 144 are included as an optional feature to avoid undesired flexure of the portion of the plate 124 that lies within the outlet apertures 132, 134, 136, 138, 140, 142. Such flexure may alter the width of the corresponding outlet aperture(s), thereby adversely affecting the consistency of water distribution from the spray head.

In the embodiment of FIG. 2, the housing 106 is integrally formed. In alternative embodiments, the housing 106 may include multiple parts. For example, the inlet and outlet portions 114, 116 may be separately formed, or the outer wall 118 may be formed separately from the plate 124.

The deflector 104 has a lip 150 that has a diameter approximately equal to the outer diameter of the outer wall 118 of the housing 106. A central hole 152 is formed in the deflector 104, concentric with the cam axis 120. The deflector 104 also has a conical portion 154 that extends from the lip 150 toward the housing 106. The conical portion 154 is centered on the cam axis 120 and is angled such that water impinging against the conical portion 154 from the housing 106 will generally be directed outward and upward from the cam axis 120. In this application, a “generally conical shape” may include protrusions, curves, or other departures from the conical shape. Also, a truncated cone or frusto-conical shape has a “generally conical shape.”

The deflector 104 also has a skirt 156 extending from the conical portion 154 toward the housing 106. The skirt 156 has a gradually increasing radius within the same angle through The skirt 156 has a flat edge 158 aligned with the space between the first and sixth outlet apertures 132, 142.

The deflector 104 also has a hub (not visible) and an orientation post (not visible) that extend toward the housing 106 from the skirt 156. The hub and the orientation post are inserted into the central hole 126 and the receiving hole 130, respectively, of the plate 124. The engagement of the hub and the central hole 126 and the engagement of the orientation post and the receiving hole 130 keep the deflector 104 from rotating with respect to the housing 106. Thus, during operation of the spray head 35, the skirt 156 is always properly oriented with respect to the outlet apertures 132, 134, 136, 138, 140, 142.

The cam 108 has an outer edge 160. Like the skirt 156, the outer edge 160 has a gradually increasing radius within the same angle through which the outlet apertures 132, 134, 136, 138, 140, 142 collectively extend (e.g., full-circle in the embodiment of FIG. 2). The outer edge 160 may also be aligned with the interior edges of the outlet apertures 132, 134, 136, 138, 140, 142, or may extend only just past the interior edges of the outlet apertures 132, 134, 136, 138, 140, 142. Thus, the cam 108 may be rotated to a variety of orientations with respect to the outlet apertures 132, 134, 136, 138, 140, 142 to uncover a variable angular portion of the combined outlet apertures 132, 134, 136, 138, 140, 142. The size of the angle that is uncovered determines the size of the angle through which water is sprayed from the spray head 35, as will be explained in greater detail subsequently.

The cam 108 also has a central hole 162 coaxial with the cam axis 120. The outer edge 160 has a flat edge 164 aligned with the space between the first and sixth outlet apertures 132, 142. The cam 108 may be constructed of a metal or any other suitable rigid material. Rust resistant metals such as stainless steel, aluminum, copper, brass and the like may be used to reduce the likelihood of corrosion. embodiments, a cam may have a hole pattern that provides variable flow through the outlet apertures 132, 134, 136, 138, 140, 142, in place of a spiral-shaped edge.

The adjustment dial 100 may similarly be formed of a rust resistant metal such as stainless steel, aluminum, copper, or brass or any other suitable material. The adjustment dial 100 has an outer edge 170 that extends along a circle. As shown, the outer edge 170 may be knurled or otherwise textured to facilitate rotation of the adjustment dial 100 by hand. The adjustment dial 100 also has a central hole 172 that is coaxial with the cam axis 120.

The adjustment dial 100 may have a diameter slightly larger than that of the remainder of the spray head 35. Accordingly, when the pop-up stem 34 retracts into the casing 33 after completion of watering, the remaining components of the spray head 35 slide into the casing 33, and the edge of the adjustment dial 100 seats against the lip of the opening of the casing 33 from which the pop-up stem 34 emerges. Accordingly, the adjustment dial 100 may be gripped and rotated to adjust the spray pattern of the spray head 35 when the pop-up stem 34 is in the retracted position.

In this application, the word “dial” is to be interpreted broadly. For example, in alternative embodiments, an adjustment dial need not be circular in shape, but may have any shape that is easily rotated by a user, with or without tooling. It may even be beneficial to provide an adjustment dial that must be rotated through the use of tooling to help prevent tampering.

Like the cam 108 and the adjustment dial 100, the shaft 102 may be formed of a rust resistant metal such as stainless steel, aluminum, copper, or brass or any other suitable material. The shaft 108 serves to couple the adjustment dial 100 to the cam 108 in such a manner that rotation of the adjustment dial 100 causes the cam 108 to rotate. More precisely, the shaft 108 has a first end 174 that fits into the central hole 172 of the adjustment dial and a second end 176

The shaft 102 has a bore 178 that is threaded and sized to receive the adjustment screw 110 such that the adjustment screw 110 is able to rotate to move along the transverse direction 16, e.g., upward when the spray head 35 is oriented as in FIG. 1. The outside diameter of the shaft 102 is sized such that clearance exists between the shaft 102 and the central hole 152 of the deflector 104 and between the shaft 102 and the lip 128 of the central hole 126 of the plate 124. Thus, the shaft 102 is able to rotate with respect to the housing 106 and the deflector 104.

The adjustment screw 110 has a head 180 disposed adjacent to the filter 112. The head 180 has a domed shape designed to cooperate with the filter 112 to control the rate at which water enters the spray head 34. Additionally, the adjustment screw 110 has a plurality of threads 182 and a slot 184 disposed on the opposite side of the adjustment screw 110 from the head 180.

The filter 112 has a lip 186 sized to rest on a corresponding shelf (not shown) within the pop-up stem 34. The filter 112 also has a tapered bore 188 that extends inward from the lip 186. The tapered bore 188 has a funnel-like shape through which water flows to enter the spray head 35. The space between the tapered bore 188 and the head 180 of the adjustment screw 110 is the flow path through which water is able to enter the spray head 35. Moving the head 180 with respect to the tapered bore 188 controls the flow rate of water entering the spray head 35, as will be described subsequently. The filter 112 has a mesh 190 through which water must flow to reach the tapered bore 188. The mesh 190 keeps the spray head 35 unclogged by trapping solid matter to keep it from entering the spray head 35.

The adjustment dial 100, shaft 102, deflector 104, housing 106, cam 108, and adjustment screw 110 may be manufactured according to a number of methods. According to one method, the adjustment dial 100 and the cam 108 may be stamped from sheets of metal or any other suitable material. As mentioned above, rust-resistant metals such as aluminum, 104 and the housing 106 may each be formed of plastic via injection molding or other known methods.

The adjustment dial 100, shaft 102, deflector 104, housing 106, cam 108, and adjustment screw 110 may be assembled via a variety of methods. According to one method, the deflector 104 may first be aligned with the housing 106 so that the hub and the orientation post are coaxial with the central hole 126 and the receiving hole 130, respectively, of the plate 124. The deflector 104 and the housing 106 may then be moved toward each other so that the hub and the orientation post are inserted into the central hole 126 and the receiving hole 130, respectively. A press fit may be formed to keep the housing 106 and the deflector 104 together. Alternatively, methods such as RF welding, ultrasonic welding, adhesive bonding, or the like may be used to keep the deflector 104 and the housing 106 together.

The cam 108 may then be aligned with the shaft 102 and the cam 108 and shaft 102 may be moved together so that the second end 176 of the shaft 102 enters the central hole 162 of the cam 108. The second end 176 may be sized to form an interference fit within the central hole 162. Accordingly, some force may be required to insert the second end 176 into the central hole 162. The first end 174 of the shaft 102 may then be inserted through the central hole 126 of the plate 124 and then through the central hole 152 of the deflector 104 in such a manner that the cam 108 is disposed in the inlet portion 114 of the housing. The plate 124 and the deflector 104 are then disposed between the cam 108 and the first end 174, and the cam 108 is disposed upstream of the plate 124 to block water flow through the outlet apertures 132, 134, 136, 138, 140, 142.

The first end 174 of the shaft 102 is then aligned with and inserted into the central hole 172 of the adjustment dial 100 in a manner similar to that of the cam 108. Again, force may be applied to form an interference fit. The cam 108 and/or the adjustment dial 100 may be made adhesive bonding, or the like may be applied in addition to or in the alternative to the press fits described above.

The adjustment screw 110 may then be inserted into engagement with the bore 178 of the shaft 102. More precisely, the slot 184 of the adjustment screw 110 is inserted into the bore 178 proximate the second end 176 of the shaft 102. The adjustment screw 110 is then rotated about the cam axis so that the slot 184 travels through the shaft 102 and emerges from the bore 178 at the first end 174.

The spray head 35 is then fully assembled and ready for installation on the pop-up stem 34. The filter 112 may first be inserted so that the lip 186 rests on a shelf of the pop-up stem 34. Then, the spray head 35 may be rotated in such a manner that the female threads within the inlet portion 114 of the housing 106 engage the male threads of the pop-up stem 34.

In operation, water flows through the pop-up stem 34 and through the mesh 190 of the filter 112 to reach the tapered bore 188. The water passes through the space between the tapered bore 188 and the head 180 of the adjustment screw 110 to reach the inlet portion 114 of the housing 106. The water then passes through the portion of the outlet apertures 132, 134, 136, 138, 140, 142 that is not blocked by the cam 108 and impinges against the conical portion 154 of the deflector 104. The water is deflected outward by the slope of the conical portion 154 so that the water is sprayed outward and upward from the spray head 35.

The flow rate of the water sprayed from the spray head 35 may be limited by the size of the gap between the head 180 of the adjustment screw 110 and the tapered bore 188. A screwdriver or other tool may be used to engage the slot 184 to rotate the adjustment screw 110, thereby moving the head 180 toward or away from the tapered bore 188. The head 180 may be moved to abut the tapered bore 188 to cut off water flow to the spray head 35. Alternatively, the head 180 may be moved far enough from the tapered bore 188 that the flow rate of water through housing 106. The cam 108 rotates about the cam axis 120, but does not move along it. Accordingly, the cam 108 rotates “in-plane,” or without moving from a stationary plane. The manner in which the cam 108 determines the spray pattern will be further illustrated and described in connection with FIGS. 3A, 3B, and 3C, as follows.

Referring to FIG. 3A, a plan view illustrates the housing 106 and the cam 108 in isolation. The housing 106 and the cam 108 (shown in phantom lines) are relatively positioned to provide quarter-circle (i.e., 90°) watering. As illustrated, the first outlet aperture 132 has a radius 192 with respect to the cam axis 120. The radius 192 gradually increases along the length of the first outlet aperture 132.

Each of the outlet apertures 132, 134, 136, 138, 140, 142 extends through an angle of approximately 60°. The outlet apertures 132, 134, 136, 138, 140, 142, collectively, extend substantially full-circle, or through an angle of 360°, within which the radius 192 of the outlet apertures 132, 134, 136, 138, 140, 142, collectively, increases gradually. Thus, as mentioned previously, the outlet apertures 132, 134, 136, 138, 140, 142 form a spiral shape with respect to the cam axis 120, which may accordingly be referred to as a “slot axis” of the outlet apertures 132, 134, 136, 138, 140, 142.

In alternative embodiments, the outlet aperture(s) need not extend full-circle, but may extend through an angle of less than 360°. The corresponding cam need not have a full-circle spiral shape, but may instead have an edge that is spiral shaped through an angle of the same magnitude as the angle through which the outlet aperture(s) extend. A “spiral” shape need not extend full-circle, but must simply have a gradually increasing radius through an angle.

As shown, the cam 108 is oriented such that the flat edge 164 of the cam 108 substantially bisects the fifth outlet aperture 140. Accordingly, the entire sixth outlet aperture 142 and half of the fifth outlet aperture 140 are uncovered by the cam 108 and available to edge 164 extends substantially between the third and fourth outlet apertures 136, 138. Consequently, the first, second and third outlet apertures 132, 134, 136 are blocked by the cam 108, and the fourth, fifth, and sixth outlet apertures 138, 140, 142 are unblocked to conduct water 22 out of the housing 106. The resulting spray pattern is half-circle, or an arc 195 of 180°.

Referring to FIG. 3C, a plan view again illustrates the housing 106 and the cam 108 in isolation. In FIG. 3C, the cam 108 (shown in phantom lines) is oriented such that the flat edge 164 extends substantially between the first and sixth outlet apertures 132, 142. Consequently, all of the outlet apertures 132, 134, 136, 138, 140, 142 are substantially unblocked to conduct water 22 out of the housing 106. The resulting spray pattern is full-circle, or an arc 196 of 360°.

Notably, the spray head 35 may have a minimum spray angle, such as about 20°. Accordingly, the spray head 35 may not be able to spray water through an angle under about 20°. Thus, although the spray head 35 is adjustable to provide substantially full-circle spray, this does not imply that there is no minimum spray angle.

Referring to FIG. 4, an exploded, perspective view illustrates a spray head 198 according to one alternative embodiment of the invention. The spray head 198 has an adjustment dial 100, a shaft 102, a cam 108, and an adjustment screw 110 that may be substantially identical to those of the previous embodiment. The spray head 198 may be used in conjunction with a filter 112, like that illustrated in FIG. 2. Additionally, the spray head 198 has a deflector 204 and a housing 206, which may be different from those of the previous embodiment in a number of respects.

More precisely, the housing 206 may have an inlet portion 114 like that of the previous embodiment, and an outlet portion 216. The housing 206 has an outer wall 118 with a tubular shape coaxial with a cam axis 120. The outer wall 118 transcends the inlet and outlet like those of the previous embodiment. However, in the spray head 198, no receiving hole 130 need be formed in the plate 224.

The deflector 204 has a lip 150 like that of the previous embodiment and a central hole 252 extending along the cam axis 120. The central hole 252 may be slightly larger in diameter than the central hole 152 of the deflector 108 of the previous embodiment to facilitate rotation of the deflector 204 around the shaft 102. The deflector 204 also has a conical portion 254 that is truncated along a plane perpendicular to the cam axis 120. A plurality of vanes 256 is formed in the resulting circular surface. The vanes 256 operate to induce rotation of the deflector 204 in response to impingement of water exiting the housing 206 against the deflector 204. The vanes 256 will be illustrated with greater detail in FIG. 5.

Referring to FIG. 5, a bottom view illustrates the deflector 204 of FIG. 4 in isolation. As shown, the vanes 256 extend outward with a counterclockwise curvature, with reference to the bottom view of FIG. 5. The deflector 204 also has a hub 258, which may have a generally annular configuration similar to that of the previous embodiment. The hub 258 is insertable into the central hole 126 of the plate 224 in such a manner that the hub 258 rests on the lip 128. The hub 258 may have an outside diameter selected such that the hub 258 is relatively freely rotatable within the central hole 126.

As shown, the vanes 256 are separated from each other by grooves 259 that extend outward from the hub 258 with a counterclockwise curvature like that of the vanes 256. The water impinges against the vanes 258 and flows into the grooves 259. The water then flows outward along the grooves 259. As the water flows along the grooves 259, the water presses against the sides of the vanes 256 to induce rotation of the deflector 204 along the clockwise direction with respect to the view of FIG. 5, or along the counterclockwise direction as viewed from above. Accordingly, the water leaves the deflector 204 with velocity including a tangential 108 with respect to the outlet apertures 132, 134, 136, 138, 140, 142 determines the angle through which water is sprayed from the spray head 198. Accordingly, a user may establish the spray pattern and the flow rate of water distributed by the spray head 198 by rotating the adjustment dial 100 and the adjustment screw 110, as described in connection with the previous embodiment.

The various components of the spray head 198 may be manufactured in a manner similar to that of the previous embodiment. As above, operations such as stamping, injection molding, and the like may be used.

Furthermore, the spray head 198 is assembled in a manner similar to that of the spray head 35 of the previous embodiment. The deflector 204 may first be inserted into engagement with the housing 206 by inserting the hub 258 into the central hole 126 of the plate 224 of the housing 206 in such a manner that the hub 258 is able to rotate within the central hole 126 to permit relative rotation between the deflector 204 and the housing 206. The adjustment dial 100 and the cam 108 are press fit onto the first and second ends 174, 176, respectively, of the shaft 102 in such a manner that the shaft 102 extends through the central holes 124, 252 of the housing 206 and the deflector 204. The adjustment screw 110 is threaded into engagement with the bore 178 of the shaft 102.

In other embodiments, spray heads according to the invention may be used to irrigate in patterns that are not bounded by circular shapes. For example, spray heads according to the present invention may be used to irrigate narrow strips of land, such as the strip commonly positioned between a sidewalk and a street. A strip head according to one exemplary embodiment of the invention will be shown and described in connection with FIGS. 6 and 7.

Referring to FIG. 6, an exploded, perspective view illustrates a spray head 298 according to another alternative embodiment of the invention. The spray head 298 is designed to

As shown, the housing 306 has an inlet portion 114 like those described previously and an outlet portion 316. The housing 306 has an outer wall 118 with a tubular shape coaxial with a cam axis 120. The outer wall 118 transcends the inlet and outlet portions 114, 316 and has indentations 122 to facilitate manual rotation for threaded engagement. The outlet portion 316 has a plate 324 that extends across the outer wall 118, substantially perpendicular to a cam axis 120.

The plate 324 has a central hole 126 with a lip 128 like those of the previous embodiments. The plate 324 also has a receiving hole 130 like that of the plate 124 of the spray head 35 of the first embodiment. Additionally the plate 324 has a first outlet aperture 332, a second outlet aperture 334, and a third outlet aperture 336 that are arranged around the central hole 126. Each of the first and second outlet apertures 332, 334 may comprise a generally circular shape disposed near the outer wall 118. The third outlet aperture 336 may comprise an elongated slot that extends radially. Thus, one end of the third outlet aperture 336 is disposed near the outer wall 118, like the first and second outlet apertures 332, 334, and the other end of the third outlet aperture 336 is disposed near the central hole 126.

As shown, the deflector 304 has a lip 150 like those of the previous embodiments. The deflector 304 also has a central hole 152 like that of the deflector 104 of the first embodiment. A detent mechanism 346 extends from the deflector 304 toward the adjustment dial 100. The detent mechanism 346 has a ball 348 seated within a hole formed in the deflector 304. The ball 348 is urged away from the deflector 304 by a spring disposed within the hole. The adjustment dial 100 has corresponding divots or ridges that are engaged by the ball 348. The engagement of the ball 348 with the adjustment dial 100 tends to keep the adjustment dial 100 in one of a number of discrete positions with respect to the deflector 304. These relative positions correspond to different spray patterns that the spray head 298 may be set to provide via rotation

Returning to the embodiment of FIG. 6, the deflector 304 also has a conical portion 354 that extends from the lip 150 toward the housing 306. An orientation post 355 and a hub 258 like that of the previous embodiment extend toward the housing 306 from the conical portion 354. The orientation post 355 may be inserted into the receiving hole 130 and the hub 258 may be inserted into the central hole 126 of the plate 324 in such a manner that the deflector 304 is unable to rotate with respect to the housing 306.

The conical portion 354 may be uniquely shaped to distribute water along multiple patterns. For example, the conical portion 354 may have a first water distribution feature 356, a second water distribution feature 357, and a third water distribution feature 358. The first water distribution feature 356 and the third water distribution feature 358 may be disposed on opposite sides of the conical portion 354, and the second water distribution feature 357 may be displaced from each of the first and third water distribution features 356, 358 by 90°, for example.

As shown, each of the first, second, and third water distribution features 356, 357, 358 takes the form of a trough formed in the surface of the conical portion 354. The first, second, and third water distribution features 356, 357, 358 may each be shaped to spray water along a substantially consistent pattern. A “water distribution feature” is a feature capable of receiving a water flow and ejecting the water through the air along a desired pattern. In alternative embodiments of the invention, water distribution features may comprise enclosed passageways, elements that protrude into the water stream to control the flow, shaped apertures, and/or other known fluid conduction and control features.

The first and third water distribution features 356, 358 may each be designed to provide end strip irrigation so that the first and third water distribution features 356, 358 may be used together to provide center strip irrigation. The second water distribution feature 357 may be designed to provide side strip irrigation.

The cam 308 has an outer edge 360 with a generally circular shape. The cam 308 also has a central hole 162 like those of the previous embodiments. A notch 364 is formed in the outer edge 360. Additionally, a hole 366 is formed in the cam 308, on the side of the cam 308 opposite from the notch 364. The hole 366 is positioned with a displacement from the central hole 162 smaller than the displacement of the notch 364 from the central hole 162. The notch 364 and the hole 366 provide open portions of the cam 308, through which water is able to flow beyond the cam 308.

The adjustment dial 100, shaft 102, deflector 304, housing 306, cam 308, and adjustment screw 110 may be formed via methods similar to those described above, in connection with the spray head 35. For example, the adjustment dial 100 and the cam 308 may be stamped from relatively thin strips of metal, the shaft 102 may be cut from a length of threaded tubular stock, and the deflector 304 and housing 306 may be injection molded. The adjustment screw 110 may be formed via known methods such as casting.

The adjustment dial 100, shaft 102, deflector 304, housing 306, cam 308, and adjustment screw 110 may be assembled in a manner similar to that of the previous embodiments. More precisely, the deflector 304 and the housing 306 may first be aligned and moved together in such a manner that the orientation post 355 is inserted into the receiving hole 130 and the hub 258 is inserted into the central hole 126 of the plate 324. The orientation post 355 and the hub 258 may be attached within the receiving hole 130 and the central hole 126, respectively, via press fitting, adhesive bonding, or the like to prevent disassembly or relative rotation of the deflector 304 and the housing 306.

The adjustment dial 100 and the cam 308 may then be pressed into engagement with the shaft 102 in such a manner that the first end 174 of the shaft 102 is press fit into the central hole 172 of the adjustment dial 100 and the second end 176 of the shaft 102 is press fit into the that the head 180 protrudes from the bore 178 proximate the second end 176 of the shaft 102 and the slot 184 is accessible through the first end 174.

The spray head 298 is then fully assembled. The filter 112 and the spray head 298 may then be attached to the corresponding pop-up stem 34 in the manner described above, in connection with the spray head 35 of FIGS. 1-3.

In operation, water flows into the spray head 298 through the filter 112. Adjustment of the flow rate of water entering the spray head 298 is provided by altering the position of the head 108 of the adjustment screw 110 relative to the tapered bore 188 of the filter 112, as described above. The water flows against the cam 308, and flows through any of the outlet apertures 332, 334, 336 that are exposed through the notch 364 or the hole 366 of the cam 308. The orientation of the cam 308 with respect to the plate 324 determines which of the outlet apertures 332, 334, 336 are exposed to receive water flow.

After moving through the exposed outlet aperture(s) 332, 334, and/or 336, the water impinges against the corresponding one or more of the first, second, and third water distribution features 356, 357, 358. The water is distributed by the corresponding one or more of the water distribution features 356, 357, 358 along a pattern corresponding to the shape of the water distribution feature(s) 356, 357, and/or 358 that receive the water. The manner in which water is distributed will be shown and described with greater detail in connection with FIGS. 7A-7F, as follows.

Referring to FIG. 7A, a plan view illustrates the housing 306 and the cam 308 (shown in phantom lines) of the spray head 298 of FIG. 6. The cam 308 is shown oriented for center strip irrigation. More precisely, the cam 308 is oriented such that the notch 364 is aligned with the first outlet aperture 332 and the hole 366 is aligned with an inwardly disposed portion of the third outlet aperture 336. Accordingly, water flows through the first and third outlet apertures FIG. 7A. The strip area 392 may be a section of a strip disposed between a sidewalk and a street, and may thus have a rectangular shape 394 having two long sides 395 and two short sides 396. The long sides 395 may each be from about twenty to about forty feet in length, and the short sides may each be from about two to about five feet in length.

The spray head 298 is installed in the center of the strip area 392. The first water distribution feature 356 faces toward one of the short sides 396, and the third water distribution feature 358 faces in the opposite direction, toward the opposite short side 396. Each of the first and third water distribution features 356, 358 distributes water over about a 180° arc along a generally rectangular pattern so that each of the first and third water distribution features 356, 358 irrigates half of the strip area 392. Accordingly, the first and third water distribution features 356, 358 cooperate to irrigate substantially the entire strip area 392. Thus, the spray head 298 provides a rectangular spray pattern, or spray that is generally limited to the area within a narrow rectangle. A “spray pattern” is the shape of the area irrigated by a sprinkler head, as viewed from overhead.

Referring to FIG. 7C, a plan view illustrates the housing 306 and the cam 308 of the spray head 298 of FIG. 6. The cam 308 is shown oriented for side strip irrigation. More precisely, the cam 308 is oriented such that the notch 364 is aligned with the second outlet aperture 334 and the hole 366 is not aligned with any of the outlet apertures 332, 334, 336. Accordingly, water flows through the second outlet apertures 334 to impinge against the second water distribution features 357. The second water distribution feature 357 provides water flow from the spray head 298 through 1800 for side strip irrigation.

Referring to FIG. 7D, a plan view illustrates a strip area 392 in which the spray head 298 of FIG. 6 is installed, with the cam 308 and housing 306 relatively positioned as shown in FIG. 7C. As in FIG. 7B, the strip area 392 may be a section of a strip disposed between a distributes water over about a 180° arc along a generally rectangular pattern so that the second water distribution feature 357 irrigates substantially the entire strip area 392.

Referring to FIG. 7E, a plan view illustrates the housing 306 and the cam 308 (shown in phantom lines) of the spray head 298 of FIG. 6. The cam 308 is shown oriented for end strip irrigation. More precisely, the cam 308 is oriented such that the notch 364 is aligned with the outward portion of the third outlet aperture 336 and the hole 366 is not aligned with any of the outlet apertures 332, 334, 336. Accordingly, water flows through the third outlet aperture 336 to impinge against the third water distribution features 358. The third water distribution feature 358 provides water flow from the spray head 298 through 180° for end strip irrigation.

Referring to FIG. 7F, a plan view illustrates a strip area 392 in which the spray head 298 of FIG. 6 is installed, with the cam 308 and housing 306 relatively positioned as shown in FIG. 7E. As in FIG. 7B, the strip area 392 may be a section of a strip disposed between a sidewalk and a street, with a rectangular shape 394 having two long sides 395 and two short sides 396.

The spray head 298 is installed on a side of the strip area 392, proximate the center of one of the short sides 396 of the rectangular shape 394. The third water distribution feature 358 faces toward the center of the strip area 392. The third water distribution feature 357 distributes water over about a 180° arc along a generally rectangular pattern so that the second water distribution feature 357 irrigates about half of the strip area 392.

According to alternative configurations, other watering patterns may be used in place of or in addition to those provided by the spray head 298. For example, quarter-circle, half-circle, and/or full-circle spray patterns may be used. Additional outlet apertures (not shown) may be used in conjunction with additional holes and/or notches in a cam to provide a wider array of spray patterns. conjunction with a filter, like that illustrated in FIGS. 2, 4 and 6. The spray head 498 also has a deflector 404, a housing 406, and a cam 408 that are somewhat different from those described previously.

As shown, the housing 406 has an inlet portion 114 like those described previously and an outlet portion 416. The outlet portion 416 is somewhat different from the previously described outlet portions 116. The housing 406 has an outer wall 118 with a tubular shape coaxial with a cam axis 120. The outer wall 118 may transcend the inlet and outlet portions 114, 416. The outer wall 118 may include indentations 422 to facilitate manual threaded assembly. The outlet portion 416 may include a plate 424 that within the outer wall 118, substantially perpendicular to a cam axis 120.

The plate 424 has a central hole 126 like those of the previous embodiments, although without a lip 128. The plate 424 has a first outlet aperture 432, a second outlet aperture 434, a third outlet aperture 436, and a fourth outlet aperture 438 that are arranged around the central hole 126. Each of the outlet apertures 432, 434, 436, 438 may comprise a generally circular shape disposed near the outer wall 118.

As shown, the deflector 404 may include a lip 150 similar to those of the previous embodiments. The deflector 404 also may also include a central hole 152 like that of the deflector 104 of the first embodiment. Though the deflector 404 is not shown with a detent mechanism 346 and ball 348 (shown in FIG. 6), in other embodiments the deflector 404 may include these features.

Returning to the embodiment of FIG. 8, the deflector 404 may be uniquely shaped to distribute water along multiple patterns. For example, the deflector 404 may have a first water distribution feature 456, a second water distribution feature 457, a third water distribution feature 458, and a fourth water distribution feature 459. The first water distribution feature 456 and the second, third, and fourth water distribution features 456, 457, 458, 459 may each be shaped to spray water along a substantially consistent pattern. As described above, a “water distribution feature” is a feature capable of receiving a water flow and ejecting the water through the air along a desired pattern. In alternative embodiments of the invention, water distribution features may comprise enclosed passageways, elements that protrude into the water stream to control the flow, shaped apertures, and/or other known fluid conduction and control features.

The first and second water distribution features 456, 457 may each be designed to provide end strip irrigation so that the first and second water distribution features 456, 457 may be used together to provide center strip irrigation. The third and fourth water distribution features 458, 459 may be designed to provide quarter strip irrigation.

Accordingly, the first, second, third, and fourth water distribution features 456, 457, 458, 459 may be aligned with the first, second, third, and fourth outlet apertures 432, 434, 436, 438, respectively, along the transverse direction 16. These types of irrigation provided by the first, second, third, and fourth water distribution features 456, 457, 458, 459 will be shown and described in greater detail in connection with FIGS. 9B, 9D, and 9F.

The cam 408 has an outer edge 360 with a generally circular shape. Unlike the cams 108 of the previous embodiments, the present cam 408 may be connected to the shaft 402. In the present embodiment, the cam 408 and the shaft 402 may be integrally formed. In other embodiments, the cam 408 and the shaft 402 may be connected by other methods, such as a press fit and/or adhesive bonding.

The cam 408 has a central hole 462. The central hole 462 passes through the shaft 402 and the cam 408. In the present embodiment, the central hole 462 includes the bore of the shaft 402. A first, second, and third hole 464, 465, 466 is formed in the cam 408. The first and second holes 464, 465 are formed in the cam 408 on opposite sides of the cam 408 (i.e., one 408. Other configurations of the additional holes other than and/or including the holes 464, 465, 466, may also be used with the cam 408 to accomplish other flow features.

The adjustment dial 100, deflector 404, housing 406, cam 408, and adjustment screw 110 may be formed via methods similar to those described above in connection with the spray head 35 described in connection with FIG. 1. For example, the adjustment dial 100 may be stamped from a relatively thin strip of metal and the deflector 404, housing 406, and cam 408 may be injection molded. The adjustment screw 110 may be formed via known methods such as casting.

The adjustment dial 100, deflector 404, housing 406, cam 408, and adjustment screw 110 may be assembled in a manner similar to that of the previous embodiments. More precisely, the deflector 404 and the housing 406 may first be aligned and moved together in such a manner that the deflector 404 is inserted into the housing 406 such that the deflector 404 abuts the plate 424. The deflector 404 may be attached within the housing 406 via press fitting, adhesive bonding, or the like to prevent disassembly or relative rotation of the deflector 404 and the housing 406.

The adjustment dial 100 and the cam 408 may then be pressed into engagement in such a manner that the first end 474 of the shaft 402 is press fit into the central hole 472 of the adjustment dial 100. The central hole 472 of the adjustment dial 100 may include engagement features that may allow the first end 474 of the shaft 402 to engage the adjustment dial 100. The shaft 402 also extends through the central hole 126 of the plate 424 and the central hole 152 of the deflector 404 so that the adjustment dial 100 is disposed adjacent to the deflector 404 and the cam 408 is disposed adjacent to the plate 424. The adjustment screw 110 may then be threaded into the central hole 462 of the cam 408 and shaft 402 in such a manner that the head 180 protrudes from the central hole 462 proximate the second end 176 of the shaft 402 and the slot

The spray head 498 is then fully assembled. The filter 112 and the spray head 498 may then be attached to the corresponding pop-up stem 34 in the manner described above, in connection with the spray head 35 of FIG. 1.

In operation, water flows into the spray head 498 through the filter 112. Adjustment of the flow rate of water entering the spray head 498 is provided by altering the position of the head 180 of the adjustment screw 110 relative to the tapered bore 188 of the filter 112, as described above. The filter 112 may include a mesh 190 through which water must flow to reach the tapered bore 188. The mesh 190 may keep the spray head 498 unclogged by trapping solid matter to keep it from entering the spray head 498.

The water flows against the cam 408, and flows through any of the outlet apertures 432, 434, 436, 438 that are aligned with one or more of the holes 464, 465, 466 exposing a flow passageway through the cam 408. The orientation of the cam 408 with respect to the plate 424 determines which of the outlet apertures 432, 434, 436, 438 are exposed to receive water flow. The orientation of the cam 408 with respect to the plate 424 also determines which of the holes 464, 465, 465 are oriented such that water is not directed through the outlet apertures 432, 434, 436, 438.

After moving through the exposed outlet aperture(s) 432, 434, 436, and/or 438 the water impinges against the corresponding one or more of the first, second, third, and/or fourth water distribution features 456, 457, 458, 459. The water is distributed by the corresponding one or more of the water distribution features 456, 457, 458, 459 along a pattern corresponding to the shape of the water distribution feature(s) 456, 457, 458, and/or 459 that receives the water. The manner in which water is distributed will be shown and described with greater detail in connection with FIGS. 9A-9F, as follows.

Referring to FIG. 9A, a plan view illustrates the housing 406 and the cam 408 viewing. In other embodiments, the outer edge 360 of the cam may be larger than shown, such that the outer edge 360 nearly abuts the inside of the outer wall 118 of the housing 406. Similarly, in other embodiments, the holes 464, 465, 466 may be larger or smaller than the outlet apertures 432, 434, 436, 438.

The housing 406 is oriented with respect to the same coordinate system shown in FIG. 8, i.e. in the same longitudinal direction 12, lateral direction 14, and transverse direction 16. The cam 408, however, is oriented such that the first hole 464 is aligned with the first outlet aperture 432 and the second hole 465 is aligned with the second outlet aperture 434. Accordingly, water flows through the first and second outlet apertures 432, 434 to impinge against the first and second water distribution features 456, 457 (shown in FIG. 8), respectively. The first and second water distribution features 456, 457 cooperate to provide water flow from the spray head 498 through about three hundred and sixty degrees in a center strip irrigation configuration as shown in FIG. 9B. Water, in the present position, is not directed to flow through the third hole 466 or the third and fourth apertures 436, 438.

Referring to FIG. 9B, a plan view illustrates a strip area 492 in which the spray head 498 of FIG. 8 is installed, with the cam 408 and housing 406 relatively positioned as shown in FIG. 9A. The strip area 492 may be a section of a strip disposed between a sidewalk and a street, and may thus have a rectangular shape 494 having two long sides 495 and two short sides 496. The long sides 495 may each be from about twenty to about forty feet in length, and the short sides may each be from about two to about five feet in length.

The spray head 498 is installed in the center of the strip area 492. The first water distribution feature 456 (shown in FIG. 8) faces toward one of the short sides 496, and the second water distribution feature 457 (shown in FIG. 8) faces in the opposite direction, toward the opposite short side 496. Each of the first and second water distribution features 456, 457

Referring to FIG. 9C, a plan view illustrates the housing 406 and the cam 408 (shown in phantom lines) of the spray head 498 of FIG. 8. The cam 408 is shown oriented for quarter side strip irrigation. The housing 406 is oriented with respect to the same coordinate system shown in FIG. 8, i.e. in the same longitudinal direction 12, lateral direction 14, and transverse direction 16. The cam 408, however, is oriented such that the third hole 466 is aligned with the third outlet aperture 436 and the first and second holes 464, 465 are not aligned with any of the outlet apertures 432, 434, 436, 438. Because neither of the first and second holes 464, 465 align with any of the outlet apertures 432, 434, 436, 438, water 22 is not directed through the first and second holes 464, 465 or the first, second, or fourth outlet apertures 432, 434, 438. Accordingly, water flows through the third outlet aperture 436 to impinge against the third water distribution feature 458 (shown in FIG. 8). The third water distribution feature 458 provides water flow from the spray head 498 through about ninety degrees for a quarter side strip irrigation configuration as shown in FIG. 9D.

Referring to FIG. 9D, a plan view illustrates a strip area 492 in which the spray head 498 of FIG. 8 is installed, with the cam 408 and housing 406 relatively positioned as shown in FIG. 9C. As in FIG. 9B, the strip area 492 may be a section of a strip disposed between a sidewalk and a street, with a rectangular shape 494 having two long sides 495 and two short sides 496.

The spray head 498 is installed in the center of the strip area 492. The third water distribution feature 458 (shown in FIG. 8) faces toward one of the corners of the strip area 492. The third water distribution feature 458 (shown in FIG. 8) distributes water 22 over about a quarter of the strip area 492 toward the corner nearest the third water distribution feature 458 along a generally rectangular pattern so that the third water distribution feature 458 irrigates substantially one quarter of the strip area 492, as shown in FIG. 9D. first, second, or third outlet apertures 432, 434, 436. Accordingly, water 22 may flow through the fourth outlet aperture 438 to impinge against the fourth water distribution feature 459. The fourth water distribution feature 459 may provide water flow from the spray head 498 through ninety degrees for quarter side strip irrigation.

Furthermore, the spray head 498 may be installed in the center of the strip area 492 shown in FIG. 9D. The fourth water distribution feature 459 may distribute water 22 about a quarter of the strip area 492 toward the corner of the strip area 492 nearest the fourth water distribution feature 459 along a generally rectangular pattern so that the fourth water distribution feature 459 irrigates substantially another quarter of the strip area 492.

Referring to FIG. 9E, a plan view illustrates the housing 406 and the cam 408 (shown in phantom lines) of the spray head 498 of FIG. 8. The cam 408 is shown oriented for end strip irrigation. The housing 406 is oriented with respect to the same coordinate system shown in FIG. 8, i.e. in the same longitudinal direction 12, lateral direction 14, and transverse direction 16. The cam 408, however, is oriented such that the third hole 466 is aligned with the first outlet aperture 432 and the other holes 464, 465 are not aligned with any of the outlet apertures 432, 434, 436, 438. Accordingly, water flows through the first outlet aperture 432 to impinge against the first water distribution feature 456 (shown in FIG. 8). Because the first and second holes 464, 465 are not aligned with any of the outlet apertures 432, 434, 436, 438, water 22 is not directed through the first and second holes 464, 465 or the second, third, or fourth outlet apertures 434, 436, 438. The first water distribution feature 456 provides water flow from the spray head 498 through about one hundred and eighty degrees for an end strip irrigation configuration as shown in FIG. 9F.

Referring to FIG. 9F, a plan view illustrates a strip area 492 in which the spray head 498 of FIG. 8 is installed, with the cam 408 and housing 406 relatively positioned as shown in nearest the first water distribution feature 456. The first water distribution feature 456 distributes water 22 over about a one hundred and eighty degree arc along a generally rectangular pattern so that the first water distribution feature 456 irrigates about half of the strip area 492.

In another embodiment, the housing 406 and the cam 408 of the spray head of FIG. 8 may be oriented such that the third hole 466 is aligned with the second outlet aperture 434 while the first and second holes 464, 465 are not aligned with any of the outlet apertures 432, 434, 436, 438. Because the first and second holes 464, 465 are not aligned with any of the outlet apertures 432, 434, 436, 438, water 22 is not directed through the first and second holes 464, 465 or the first, third, or fourth outlet apertures 432, 436, 438. Accordingly, water may flow through the second outlet aperture 434 to impinge against the second water distribution feature 457 (shown in FIG. 8). The second water distribution feature 457 may provide water flow from the spray head 498 through one hundred and eighty degrees for end strip irrigation.

Furthermore, the spray head 498 may be installed in the center of the strip area 492. The second water distribution feature 457 may face toward the short side 496 of the strip area 492 nearest the second water distribution feature 457. The second water distribution feature 457 distributes water 22 over about a one hundred and eighty degree arc along a generally rectangular pattern so that the second water distribution feature 457 irrigates about half of the strip area 492.

According to alternative configurations, other watering patterns may be used in place of and/or in addition to those provided by the spray head 498. Persons skilled in the art know of other watering patterns and how other watering patterns could be implemented from the teachings of the present invention. For example, quarter-circle, half-circle, full-circle, and/or other spray patterns may be used. Additional open portions (not shown) may be used alone or in conjunction with additional holes 464, 465, 466 in the cam 408 to provide a wider array of spray patterns.

The present invention may be embodied in other specific forms without departing from its structures, methods, or other essential characteristics as broadly described herein and claimed hereinafter. The described embodiments are to be considered in all respects only as illustrative, and not restrictive. The scope of the invention is, therefore, indicated by the appended claims, rather than by the foregoing description. All changes that come within the meaning and range of equivalency of the claims are to be embraced within their scope.

	Number	Date	Country
Parent	10770227	Feb 2004	US
Child	11644092	Dec 2006	US

Adjustable spray pattern sprinkler

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Continuation in Parts (1)