The statements in this section merely provide background information related to the present disclosure and may not constitute prior art.
The present disclosure relates to a sprinkler assembly and, more particularly, to a sprinkler assembly that exhibits reduced energy losses, which may be used in both residential and commercial applications, including storage applications, and further may be used in a control mode or a suppression mode.
Significant energy losses occur at the sprinkler assemblies where the fluid is dispersed. Conventional sprinkler assemblies include a base with a passageway, an inlet opening, and a discharge opening, which is adapted for connecting to the system piping, and a deflector that is supported spaced from the base, typically by a pair of arms that extend from the base. The arms are often joined at their distal ends by a boss, which is used to mount the deflector to the arms. Pendent sprinklers and upright sprinklers typically include deflectors with a solid central portion and a plurality of tines that extend radially outwardly from the central portion for dispersing the fluid as it flows across the solid central portion, which is mounted to the boss and typically aligned with the discharge opening of the base. Sidewall sprinklers typically include a deflector, also with a solid central portion with tines extending from the central portion and a blade that is positioned above the central portion to direct the fluid that flows above the central portion outwardly and downwardly. In each case, when the fluid flows from the discharge opening of the base the fluid impinges on the boss and on the central portion of the deflector. The boss and deflector disperse the fluid radially outward, and the fluid is thereafter further dispersed by the tines, and in the case of the sidewall sprinklers also by the blade. This results in a sizeable energy or head loss in the fluid at the sprinkler assembly. Significant savings can be realized for a sprinkler system if the supply pressure to the sprinkler assembly can be reduced. As would be understood by those skilled in the art, where the supply pressure to the sprinkler assemblies of a system can be reduced, the size of the piping delivering the fluid to the sprinkler assemblies can be reduced and/or the size of the system pump can be downsized. If comparable performance of a sprinkler assembly can be provided at a lower pressure for any given system, the need for a pump might even be avoided. Any of these modifications could provide significant savings in the installation cost of a fire protection system. Accordingly, a sprinkler assembly that can disperse fluid with a reduced head loss may reduce the required pressure at the sprinkler assembly and, hence, provide cost savings for the installation of a fire protection system incorporating such sprinkler assemblies.
According to the present invention a sprinkler assembly is provided that is adapted to reduce the energy and hence head loss of a fluid as it flows from the sprinkler assembly.
In one form of the invention, a sprinkler assembly includes a body and a support extending from the body. The body includes a passageway, an inlet opening, and a discharge opening. In addition, the sprinkler assembly includes a flow-shaper member and a closure device releasably positioned at the discharge opening to close the passageway. A heat responsive trigger is mounted to releasably retain the closure device at the discharge opening of the body and release the closure device from the discharge opening when the heat responsive trigger is heated to a temperature associated with a fire. The flow-shaper member has at least one contact surface for shaping the flow of fluid from the discharge opening when the closure device is released from the discharge opening. The support and the flow-shaper member are configured so that they do not block the flow of fluid from the discharge opening along the axis of the body to reduce the impediment to the flow of fluid from the discharge opening when the closure device is released from the discharge opening and thereby reduce the head loss in the fluid flowing from the sprinkler assembly.
In one aspect, the support has an opening aligned along the axis of the body wherein at least some of the fluid flowing from the discharge opening flows through the opening. For example, the support's opening may have a diameter of at least 0.4 inch and, more typically, in a range of about 0.5 to 2.0 inches.
In another aspect, the flow-shaper member may be located at the support's opening so that the support's opening is adapted to shape the flow of fluid flowing from the opening. For example, the flow-shaper member may be located at the discharge side of the support's opening. A suitable flow-shaper member may be formed by a tab or a tine.
In further aspects, the flow-shaper member projects from the frame at the support's opening away from the discharge opening. In addition, the sprinkler assembly may include an annular member positioned in the support's opening, which supports the flow-shaper member at the support's opening. For example, the annular member may be located in the support's opening. Where more than one flow-shaper member is provided, the annular member may support all the flow-shaper members at the support's opening to thereby shape the flow of fluid flowing from the support's opening.
In further aspects, the heat responsive trigger includes a heat sensitive member that extends between the support and the body. For example, the heat sensitive member may have a longitudinal axis that extends between the support and the body, with the longitudinal axis angled with respect and non-parallel to the axis to thereby further reduce impediments to the flow of fluid flowing from the discharge opening of the body.
In another aspect, the discharge coefficient or “K” factor of the sprinkler assembly, which equals the flow of fluid, such as water, in gallons per minute through the passageway divided by the square root of the pressure of fluid fed into the body in pounds per square inch gauge, may be in a range of about 2.8 to 50.4 so that the sprinkler assembly may be suitable for use in residential or commercial applications, including storage applications.
In yet another aspect, the Response Time Index (RTI) of the sprinkler may be 50 (m-s)1/2 or less, and optionally may be in a range of 50 to 300 (m-s)1/2.
In another form of the invention, a sprinkler assembly includes a body and a support that extends from the body. The support has a transverse member with an opening at least generally aligned along the axis of the body that is larger in diameter than the discharge opening of the sprinkler body wherein at least some, and preferably most, of the fluid flowing from the discharge opening flows through the support.
In one aspect, the opening is adapted to shape the flow of fluid flowing from the opening. For example, the sprinkler assembly may include a flow-shaper with one or more flow-shaper members at or near the opening of the support.
According to another form of the invention, a sprinkler assembly includes a body and a frame that extends from the body. The frame has an opening at least generally aligned along the axis of the body that is larger in diameter than the discharge opening of the sprinkler body wherein at least some, and preferably most, of the fluid flowing from the discharge opening flows through the opening of the frame. In addition, the sprinkler assembly includes a flow-shaper member provided at the discharge side of the frame's opening, which shapes the flow of fluid flowing from the opening of the frame.
In yet another form of the invention, a sprinkler assembly includes a body, a support, which extends from the body, and a heat sensitive trigger. The body includes an inlet opening, a passageway extending from the inlet opening to a discharge opening, and an axis that extends from the discharge opening. The trigger includes a heat sensitive member that extends between a mounting surface of the support and the body, with the mounting surface being offset from the axis of the body. In this manner, the heat sensitive member is offset from the axis to reduce the impediment to the flow of fluid flowing from the discharge opening when the discharge opening is opened and thereby reduce the energy loss in the fluid flowing from the discharge opening.
In one aspect, the support comprises a frame with a pair of arms. The frame includes an opening that is aligned along the axis wherein fluid flows through the frame. In a further aspect, the frame's opening is sized so that most, if not all, the fluid flows from the discharge opening of the body flows through the frame. For example, the frame's opening may be sized so that its diameter is at least as large as the diameter of the discharge opening.
In another aspect, the axis comprises a central axis that extends through the centers of each of the inlet and discharge openings.
In other aspects, the sprinkler assembly includes at least one fluid flow-shaper member at the frame, which shapes the flow of fluid passing through the frame. Optionally, the flow-shaper member is provided at the frame's opening and, further, optionally mounted in the opening of the frame. For example, the flow-shaper member may comprise a tab, which is located adjacent the opening of the frame to thereby shape the flow of fluid flowing from the opening of the frame. In a further aspect, the sprinkler assembly includes a pair of flow-shaper members. For example, the flow-shaper members may be generally aligned on opposed sides of the frame's opening and offset from the axis of the body to thereby at least partially envelop the flow of fluid as it flows from the frame's opening.
In further aspects, the sprinkler assembly includes an annular member and a pair of tabs that extend from the annular member. The tabs form a pair of flow-shaper members. For example, the annular member may be mounted in the frame's opening wherein fluid flowing through the frame's opening flows through the annular member.
According to yet another aspect, the body of the sprinkler includes an insert, which forms the discharge opening. For example, the insert may include a support surface for supporting the heat sensitive member and, preferably, a support surface that is angled with respect to the axis of the body. In this manner, when the heat sensitive member is compressed between the body and the mounting surface, the compression forces will be aligned along the longitudinal axis of the heat sensitive member. Suitable heat sensitive members include a frangible bulb or the like.
Accordingly, the present disclosure provides a sprinkler assembly that is adapted to reduce the head loss of the fluid as it flows from the sprinkler assembly, thus, potentially reducing the required supply pressure to the sprinkler assembly or increasing the pressure of the fluid as it is dispersed from the fire suppressant system or a combination of both. As would be understood by those skilled in the art, where the supply pressure to the discharge devices of the system can be reduced, the size of the piping delivering the fire suppressant fluid to the discharge devices can be reduced and/or the size of the pump can be downsized. In some cases, the pump may be eliminated. Thus, the sprinkler assembly of the present disclosure potentially provides for significant savings in the cost of the system.
Further areas of applicability will become apparent from the description provided herein. It should be understood that the description and specific examples are intended for purposes of illustration only and are not intended to limit the scope of the present disclosure.
The drawings described herein are for illustration purposes only and are not intended to limit the scope of the present disclosure in any way.
The following description is merely exemplary in nature and is not intended to limit the present disclosure, application, or uses. It should be understood that throughout the drawings, corresponding reference numerals indicate like or corresponding parts and features.
Referring to
Further, any one of the sprinkler assemblies of the present invention may be configured as a fast response sprinkler as defined by the response time index. The response time index of a sprinkler is referred to as “RTI”, which is a measure of the sensitivity of the thermal element of a sprinkler. RTI is usually determined by plunging a sprinkler into a heated laminar airflow within a test oven. RTI is calculated using operating time of the sprinkler, operating temperature of the sprinkler's heat-responsive element (as determined in a bath test), air temperature of the test oven, air velocity of the test oven, and the sprinkler's conductivity. Fast response sprinklers have an RTI typically less than 50 (m-s)1/2.
As will be more fully described below, the sprinkler assemblies of the present invention reduce the friction between the fluid and the sprinkler assembly and, hence, the energy loss of the fluid as it flows from the sprinkler assembly. Consequently, a sprinkler assembly of the present invention provides an optimally-sized sprinkler that will be able to cover greater areas for a given pressure than conventional sprinklers of the same size.
As best seen in
As best seen in
To reduce the energy loss of the fluid as it flows from sprinkler assembly 10, support 13 is configured to allow at least a portion and, optionally most, if not all, of the fluid to flow through support 13 rather than into and around the support 13. In addition, as will be more fully described below, at least a portion, and optionally most of the fluid flows between one or more flow-shaper members 28, which direct and shape the fluid in a desired pattern in contrast to conventional sprinkler assemblies that typically include frames and deflectors that deflect and redirect the fluid and form barriers around which the fluid must flow.
In the illustrated embodiment, support 13 comprises a frame that includes a pair of arms 14a and 14b and a transverse member 23 that joins the ends of arms 14a and 14b and which is spaced from discharge opening 20. Arms 14a and 14b extend generally away from discharge opening 20 on opposed sides of body 12 and, as noted, are joined by transverse member 23. While two symmetrically positioned arms are illustrated, it should be understood that support 13 may include one, two, three, or four or more arms, for example three or four arms that are all symmetrically positioned around and spaced away from axis 26. As would be understood by those skilled in the art, support 13 is substantially rigid so as to provide support for the flow-shaper members and, further, support for a heat responsive trigger, as will be more fully described below.
In the illustrated embodiment, transverse member 23 of support 13 comprises an annular member and a pair of bosses 23a that align and mount the annular member 23 between arms 14a and 14b. The annular member provides an opening 24 with a center 24a (
The opening or the inner diameter 24 of the annular member is at least 0.4 inches in diameter and, more typically, in a range of about 0.5 to 2.5 in diameter. Further, opening 24 may be at least as large in diameter as discharge opening 20 and, further, may be larger in diameter than discharge opening 20. In this manner, the flow of fluid from body 12 is substantially unimpeded by support 13 and, instead, may flow through support 13 through opening 24. As a result, the flow of fluid is directed and shaped rather than redirected. Consequently, the energy loss of the fluid as it flows through the frame is reduced, if not eliminated. Furthermore, although opening 24 is depicted as a right cylindrical opening with straight sides, the inner surface of opening 24 may be tapered inwardly or outwardly. In addition, opening 24 may have a non-circular cross-section.
In order to then direct the fluid in a desired spray pattern, one or more fluid flow-shaper members 28 are located adjacent or at opening 24. Further, flow-shaper members 28 may be offset from axis 26 of the sprinkler head body. As best seen in
Referring to
In the illustrated embodiment, fluid flow-shaper members 28 are formed as a pair of tabs 30a and 30b that are mounted to or formed with an annular member 32, which together form a flow-shaper. It should be understood that the number of tabs, the size of the tabs, the shape of the tabs, and the location of the tabs may vary depending upon the desired fluid dispersement pattern. Annular member 32 includes an annular wall 32a and central opening 32b. In addition, annular member 32 includes a first and second ends 32c and 32d and is sized to fit and mount in opening 24 of support 13 and, further, configured so that the fluid flows through annular member 32. In this manner, the fluid flow-shaper members are attached to support 13 by mounting annular member 32 in support 13. It should be understood that flow-shaper members 28 may alternatively be attached to support 13 by attaching flow-shaper members 28 to support 13, for example by welding the flow-shaper members to the support, such as to annular member 23, or by integrally forming the support 13 with the flow-shaper members. Flow shaper members 28 can be formed, cut or otherwise machined into the support structure so as to be formed integrally therewith. Alternately, tabs 30a and 30b may be mounted by a member that mounts about support 13 and annular member 23 outwardly of opening 24.
In this application, opening 32b of annular member 32 is preferably at least as large in diameter as discharge opening 20. In this manner, most, if not all, the fluid discharged from discharge opening 20 may flow through support 13 unimpeded by support 13 or annular member 32.
As best seen in
Tab 30b also attaches to or is formed with annular member 32 at first end 32c by a base 31b and comprises a generally rectangular plate with trapezoidal-shaped notches 34b at its opposed edges 35b, as best shown in
In the illustrated embodiment, tabs 30a and 30b extend from end 32c from opposed sides and are generally aligned along an axis 30c that extends through the center axis 32e of annular member 32. However, it should be understood that tabs 30a, 30b or additional tabs may be located at other locations around end 32c depending on the desired spray pattern.
As noted above, trigger 36 is mounted so as to retain closure device 39 in position over discharge opening 20. In the illustrated embodiment, trigger 36 comprises a heat sensitive member 38 that is mounted between support 13 and closure device 39. Heat sensitive member 38 is supported on one end in closure device 39, which includes a generally cup-shaped member or support 40 that supports one end of member 38 at opening 20. In addition, closure device 39 includes an annular spring seal 42 (
The opposed end of heat sensitive member 38 is supported in a recess 44 formed in frame 14 (best shown in
In the illustrated embodiment, boss 23a at the juncture of annular member 23 and arm 14a provides recess 44. As best seen in
As best seen in
In the illustrated embodiment, heat sensitive member 38 comprises a heat sensitive frangible bulb 38a. Furthermore, the wider, rounded end 38b of bulb 38a is seated in support 40. The narrower, reduced neck 38c of bulb 38a is inserted into recess 44. Thus, bulb 38a is inverted from a conventional sprinkler application—where the narrower, reduced neck of the glass bulb is typically inserted into the discharge orifice of the sprinkler head.
As noted above, though illustrated as a sidewall sprinkler assembly, the sprinkler assembly of the present invention may comprise an upright or pendent style sprinkler assembly. In addition, the sprinkler assembly may comprise a residential sprinkler or a commercial sprinkler, including a storage sprinkler. Therefore, the discharge coefficient or “K-factor” of the sprinkler assembly may vary widely from 2.8 to 50.4. For example, for a residential sprinkler, the K-factor normally ranges from about 2.8 to 8. For a commercial non-storage sprinkler, the K-factor will normally range from about 2.8 to 8.0. For a storage sprinkler, the K-factor will be the largest, typically from about 11.2 to 50.4. It should also be noted that annular member 32 with flow-shaper members 28 may be changed to provide different distribution patterns without modifying annular member 23. Thus, the cast component of sprinter 10 can remain unchanged while the annular member 32 and flow-shapers 28 can be modified inexpensively to obtain desired distribution patterns. Furthermore, the orifice size through the seal insert 50 may be inexpensively changed to provide different K-factors while the remaining components can remain unchanged.
Referring to
In the illustrated embodiment the shape of body 112 and frame arms 114a and 114b have been slightly modified, with arms 114a and 114b having a generally rectangular cross-section; though it should be understood that the shape of the frame and body may be varied. In addition, frame arms 114a and 114b are joined at their respective ends by a transverse member 123 formed from a generally oval-shaped body with an opening 124, which is also at least generally aligned with the discharge opening 120 of body 112. For further general details of body 112, trigger 136, and frame 114, and the size of the openings, reference is made herein to sprinkler assembly 10.
In the illustrated embodiment, flow-shaper members 128 are similarly provided by a pair of tabs 130a and 130b mounted to or formed with an annular member 132 to form a flow-shaper. However, the configuration of tab 130a is modified from tab 30a and includes at its outer free edge 136a a central flat edge 136b bounded by a pair of arcuate-shaped edges 136c and 136d. Arcuate-shaped edges 136c, 136d may be semi-circular, for example, and provide additional dispersion of the fluid as it flows between the two flow-shaper members. The edges 136a through 136d define a finger shape that distributes the water in a desired pattern. It should be noted that multiple fingers may be desired to achieve different distribution patterns.
Similar to the previous embodiment, annular member 132 mounts tabs 130a and 130b in opening 124 so that the flow-shaper members shape the flow of fluid as it flows from frame 114. Further, annular member 132 has an opening that is preferably at least as large and, more preferably, larger than the discharge opening of body 112, similar to the previous embodiment.
Referring to
In the illustrated embodiment, body 212 includes a threaded portion 212a for connecting the sprinkler assembly to a fluid supply line, an inlet opening 218, a discharge opening 220, and a fluid passageway 222. Passageway 222 extends between inlet opening 218 through portion 212a to discharge opening 220, which extends in a plane generally parallel and spaced from the plane of inlet opening 218. In this manner, a conventional body may be employed and, as will be more fully described, retrofit to accommodate the angularly offset heat sensitive member 238.
Trigger 236 includes a heat sensitive member 238, similar to member 38, which is supported in closure device 239 by trigger support 240, which is seated in discharge opening 220 over an annular spring seal 242 (
Similar to the previous embodiments trigger member 238 comprises a heat responsive element such as a frangible bulb, with the larger end of member 238 supported in trigger support 240 by a bracket 250. Bracket 250 adapts closure device 239 to provide an angled support surface for trigger member 238. In the illustrated embodiment, bracket 250 comprises an inverted generally U-shaped flange 250a with three depending arms 250b, 250c, and 250d. Flange 250a includes a recess or opening 252 for forming a seat. Arm 250b rests on annular seat 244c with the other arms (250c, 250d) straddling rim 244b and resting on annular rim 220a of body 212, which extends around opening 220. Recess 252 is angled with respect to axis 226 (
Referring to
In the illustrated embodiment, trigger 336 includes a heat sensitive member 338, which in the illustrated embodiment comprises a frangible bulb that is generally aligned along axis 326 of sprinkler assembly 310. It should be understood that member 338, like members 38, 138, and 238, may be formed from a fused link, such as described in U.S. Pat. No. 6,918,545 which is herein incorporated by reference in its entirety. Heat sensitive member 338 is supported on one end on closure device 339 by a heat sensitive member support 340, which is similar to support 240 except that it supports the narrower end of heat sensitive member 338 in opening 320 of body 312. In addition, an annular spring seal 342 (
Yoke 343 extends between arms 314a and 314b below transverse member 323 and comprises a hollow wedge-shaped member with a slotted recess 343a for holding the larger end of heat sensitive member 338 therein. Yoke 343 is supported in position by heat sensitive member 338 and two compression screws or fasteners 348 that extend through transverse recesses or openings 346 provided in transverse member 323 to thereby compress yoke 343 against trigger member 338. The fasteners 348 can be disposed generally parallel to the axis 326 of the body 312, as shown in
As would be understood, yoke 343, therefore, forms a bridge to support the larger end of heat sensitive member 338 at a distance spaced inwardly from transverse member 323 of frame 314. When compressed and not subject to significant lateral forces, yoke 343 and heat sensitive member 338 are stable and will remain aligned between frame 314 and body 312. However, once heat sensitive member 338 is exposed to a temperature associated with a fire and heat sensitive member 338 no longer maintains its structural integrity, yoke 343 will no longer be stable and will fall away from frame 314 along with the remnants of heat sensitive member 338 and support 340, as would be understood by those skilled in the art. In addition, side walls 343b, 343c include flared central portions 343m, 343n to increase the instability of yoke 343 when heat sensitive member 338 is exposed to a heat sufficient to cause member 338 to break.
Referring to
Tab 330b also includes an enlarged inverted U-shaped portion 330c at its outer end, which when formed is angled relative to the base portion 330d of tab 330b. Further, as best seen in
As best seen in
Referring to
In the illustrated embodiment, flow-shaper members 428 are formed by a plurality of fingers or tines 430 that are mounted or formed on an annular member 432, which together form a flow-shaper. Similar to the previous embodiments, annular member 432 is positioned in opening 424 of transverse member 423. Each tine 430 includes a first portion that extends outwardly from annular member 432 (in a direction away from opening 424) and a second portion bent or rolled radially inward toward axis 426 and, further, in a manner so that the end portions 430a of tines 430 generally lie in a common plane spaced from opening 424. In addition, each tine 430 includes tapered side edges 430b, 430c so that when the second portions of tines 430 are bent or rolled toward axis 426, tines 430 are spaced apart to form radially arranged spaces or passageways 431a through which the fluid flowing from discharge opening 420 and through opening 424 can flow. Further, the distal ends 430d of tines 430 are spaced apart so that they are offset from axis 426 and form a central, circular opening 431b there between, in to which passageways 431a open. In this manner flow-shaper members 428, like the flow-shaper members of the previous embodiments, are offset from axis 426 and do not redirect the flow of the fluid, and instead allow the fluid to flow between the flow-shaper members to reduce the friction loss and, further, operate on the column of fluid radially inward from the outer surface of the column of fluid. In the illustrated embodiment tines 430 are trapezoidal in shape and are evenly spaced around opening 431b and, further, generally have the same lengths. Alternately, tines 430 may be rectangular or triangular in shape and/or have different lengths. In addition, tines 430 may be spaced around opening in a non-uniform arrangement.
Trigger 436 includes a heat sensitive member 438 in the form of a fuse plate assembly, which is formed from two plates 438a and 438b that are fused together by a fusible material, which generally liquefies or melts upon exposure to a temperature associated with a fire. Plates 438a and 438b are biased against the retention force of the fusible material by a pair of lever arms 439a and 439b, which urge the plates outwardly from the sprinkler assembly when the fusible material melts. For further details of trigger 436, reference is made herein to U.S. Pat. No. 6,152,236, which is incorporated by reference herein in its entirety.
Similar to trigger member 338 of trigger 336, lever arms 439a and 439b are held in position by a transverse compression member 449, which forms a bridge and supports the ends of the lever arms inwardly from transverse member 423 between frame arms 414a and 414b. Member 449 is similarly compressed against lever arms 439a and 439b by compression screws or fasteners 448. In the illustrated embodiment, lever arm 439a comprises a generally S-shaped arm, with its upper portion urged into contact with transverse compression member 449 by arm 439b, which comprises a generally linear member. The lower portion of each arm is extended through respective opening 438d and 438e formed between plates 438a and 438b and apply outward lateral forces on the respective plates 438a and 438b. In this manner, when the fusible material melts, plates 438a and 438b are urged outwardly by arms 439a and 439b. Further, the lower end of arm 439b is compressed against a closure device 439, which is formed by a circular member 441 that covers opening 420 and is sealed against the discharge opening with an annular seal (not shown).
Referring to
As best seen in
Similar to tines 430, tines 530 extend from annular member 532 outwardly (away from body 512) and are bent or rolled radially inward toward axis 526 and, further, so that the end portions 530a of tines 530 lie in a common plane spaced outwardly from opening 524 (away from body portion 512). In addition, each tine 530 includes tapered side edges 530b, 530c so that when tines 530 are bent or rolled toward axis 526, tines 530 are spaced apart to form radially arranged spaces or passageways or slots 531a through which the fluid flowing from discharge opening and through opening 524 can flow. As noted, the distal ends 530d of tines 530 are joined by member 531, with a central circular opening 531b. Opening 531b is preferably aligned along axis 526 of body 512. Further, opening 531b preferably has a diameter less than the diameter of discharge opening 520.
Optionally, member 531 may include a plurality of inwardly projecting finger or tines 531c that extend radially inward toward axis 526 into opening 531b. In the illustrated embodiment tines 531c are rectangular in shape and are evenly spaced around opening 531b and, further, have the same or comparable lengths. Alternately, tines 531c may have triangular shapes and/or have different lengths. In addition, tines 531c may be spaced around opening in a non-uniform arrangement.
In this manner flow-shaper 528, like the flow-shaper members of the previous embodiments, generates a lower friction loss in the fluid as the fluid flows from the sprinkler assembly. In addition, some of the fluid flowing from discharge opening 520 may pass through flow-shaper 528 without contacting any structure.
Referring to
Referring to
In the illustrated embodiment, flow-shaper 728 includes an annular member 729a and a plurality of fingers or tines 730 that extend radially outward from annular member 729a. Tines 730 and annular member 729a are supported by a cylindrical wall or annular member 732 that inserts into opening 724 of transverse member 723. Tines 730 and annular member 729a are supported by a cylindrical wall 732 and spaced therefrom by a plurality of radially extending, circumferentially spaced arms 729b. Notably as in the case of any of the flow-shaper members, tines 730, annular member 729a, annular member 732, and arms 729b may be formed as a single member or may be assembled and joined together by, for example, welding.
Similar to the previous embodiments, flow-shaper 728 is mounted to frame 714 by annular member 732, which is positioned in opening 724 of transverse member 723. Tines 730 extend in a common plane from annular member 729a and are radially spaced between arms 729b. Further, tines 730 have generally equal length but terminate inwardly of the inner circumference of annular member 732 to thereby define through passageways 731a between tines 730 and annular member 732 through which the fluid flowing from discharge opening 720 and through opening 724 can flow. Further, annular member 729a includes an opening 731b, which may have a maximum diameter less than the minimum diameter of discharge opening 720. Optionally, flow-shaper 728 includes a second plurality of tines 729d that extend radially inwardly from annular member 729a into central opening 731b. In this manner, flow-shaper 728, like the flow-shapers of the previous embodiments, generates lower friction and results in a lower head loss in the fluid flowing from sprinkler assembly 710.
Referring to
Referring to
Closure device 939 comprises a disk 939a that rests on an annular seal 939b provided at discharge opening 920. In the illustrated embodiment, trigger 936 comprises a pair of plates that are joined by fusible material and are mounted adjacent the discharge opening of body 912 by pair of lever arms 936a and 936b. Arms 936a and 936b extend through a lever support 936c and are biased outwardly from base 912 by a set screw 939d that is threaded into lever support 939c and engages disk 939a. For further details of a suitable trigger, reference is made to U.S. Pat. No. 6,367,559, which is commonly owned by The Viking Corp. and which is incorporated herein by reference in its entirety.
Similar to flow-shaper 728, flow-shaper 928 includes an annular member 1029a and a plurality of fingers or tines 1030 that extend radially outward from annular member 1029a. Tines 1030 extend into a common plane from annular member 1029a and are radially spaced to thereby form a plurality of slotted openings around the periphery of flow-shaper member 928. Tines 1030 and annular member 1029a are supported by a plurality of elongate flanges 1032, which form an annular support that extends downwardly from annular member 1029a for insertion into annular member 923. In addition, flow-shaper 928 includes a second plurality of tines 1029d that extend inwardly from annular member 1029a into central opening 1031b of annular member 1029a. In the illustrated embodiment, the second plurality of tines 1029d comprise triangular-shaped tines, with distal ends 1029e that are spaced inwardly from the central axis 928a of flow-shaper 928 to thereby form a central opening 1031b. Alternately, the distal ends 1029e of tines 1029d may be joined, for example, by a second inner annual member. Second plurality of tines 1029d are radially spaced to form a second plurality of slotted openings inwardly of annular member 1029a and, further, that are in fluid communication with central opening 1031b. In addition, tines 1029d extend in the same plane as tines 1030 and annular member 1029a.
In the illustrated embodiment, annular member 1029a has a larger diameter than annular member 729a described in reference to flow-shaper 728. Further, although tines 1029d generally have equal lengths, they are generally greater in length than tines 729d of flow-shaper 728. Similar to flow-shaper member 728, central opening 1031b has a maximum diameter less than the minimum diameter of discharge opening 920.
As noted, any of the above-described sprinkler assemblies may be configured as a residential sprinkler or a commercial sprinkler, including a storage sprinkler. Hence, their “K” factor may vary, where the “K” factor equals the flow of fluid, such as water, in gallons per minute through the internal passageway divided by the square root of the pressure of fluid fed into the tubular body in pounds per square inch gauge. For example, the sprinkler assemblies may have a “K” factor of 2.8 to 50.4. Further at least sprinkler assemblies 410, 510, 610, 710, and 810 may be configured as suppression or control sprinklers. Hence, their RTI valves may vary from 10 to 300 (m-s)1/2.
As would be understood from the foregoing description, the present disclosure provides a sprinkler assembly that reduces the energy loss in the fluid that flows from the sprinkler assembly. This may be achieved in a number of ways. First, the frame may be adapted to allow the fluid to flow through the frame substantially unimpeded—in other words the fluid is not dispersed and then redirected and, instead, it is directed by flow-shaper members. Though it should be understood in some applications some of the fluid may be redirected. Secondly, the sprinkler assembly may include one or more flow-shaper members that at least partially envelope the column of fluid as it flows from the discharge opening and, further, in most embodiments operates on the outer surface of the column of fluid and radially inward of the column so that the fluid is shaped in its desired direction, in essence, by a single contact with the flow-shaper member or members. This is in stark contrast to a conventional frame/deflector arrangement that requires essentially a two step process: (a) first the fluid is impinged on the frame, such as the conical boss that joins the frame's arms in most sprinkler assemblies, to redirect and disperse the fluid onto the deflector, and thereafter, (b) the fluid flows across and around the deflector, which then disperses the fluid in its final desired pattern. Thirdly, the trigger may be offset from the axis of the sprinkler body. Various combinations of these features are combined in the illustrated embodiments; however, it should be understood that any one or more of the features can be recombined with other features, including conventional features, to achieve an improved sprinkler assembly of the present invention. Further at least sprinkler assemblies 410, 510, 610, 710, and 810 may be configured as suppression or control sprinklers.
While several embodiments of the sprinkler assembly have been shown and described, other changes and modifications will be appreciated by those skilled in the art. For example, as previously noted, the frame and body may be formed as a single cast member. Alternately, the frame and body may be formed from separate components that are then assembled. The number and shape of the flow-shaper members may be varied. Further, as mentioned, the flow-shaper member or shaper members may be formed or mounted as an integral part of the frame. In addition, the sprinkler assembly may employ other types of trigger assemblies. Therefore, it will be understood that the embodiments shown in the drawings and described above are merely for illustrative purposes, and are not intended to limit the scope of the invention that is defined by the claims, which follow as interpreted under the principles of patent law including the doctrine of equivalents.
This application is a divisional of U.S. patent application Ser. No. 12/724,880, filed Mar. 16, 2010, now U.S. Pat. No. 8,151,462, which is a divisional of U.S. patent application Ser. No. 11/388,070, filed on Mar. 23, 2006, now U.S. Pat. No. 7,712,218, which claims the benefit of U.S. Provisional Application No. 60/667,841, filed on Apr. 1, 2005, the disclosures of which are incorporated herein by reference.
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Number | Date | Country | |
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20120159786 A1 | Jun 2012 | US |
Number | Date | Country | |
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60667841 | Apr 2005 | US |
Number | Date | Country | |
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Parent | 12724880 | Mar 2010 | US |
Child | 13415361 | US | |
Parent | 11388070 | Mar 2006 | US |
Child | 12724880 | US |