Patent Grant
6918545
The present invention relates to sprinkler heads used in automatic fire extinguishing systems for buildings and the like, and in particular, relates to a trigger assembly for a quick response automatic sprinkler head.
Sprinkler heads have long been used in automatic fire extinguishing systems in order to controllably disburse a fluid to suppress or extinguish a fire in a designated area. Typically, the fluid utilized in automatic fire extinguishing systems is water, however, systems have also been developed to disburse other fire extinguishing fluids. In one common design, sprinkler heads include a sprinkler body having a central orifice with an inlet connected to a pressurized supply of water or other fire extinguishing fluid, and an outlet through which the fire extinguishing fluid is expelled. A frame extends from the sprinkler body and projects a preselected distance beyond the outlet of the central orifice. The frame carries a deflector designed to alter the water trajectory in an optimum pattern. The sprinkler head may be coupled to a fluid supply line such that the sprinkler head extends in an upward direction towards the ceiling of the structure, in which case it is referred to as an “upright” sprinkler head. Alternatively, sprinkler heads are characterized as “pendent” when the sprinkler head is coupled to a fluid supply line such that the sprinkler head projects towards the floor. Also, a side wall sprinkler head is defined as one which projects substantially orthogonally from a side wall of an enclosure.
In the non-activated state, water flow through the central orifice is prohibited by the presence of a sealing assembly which sealingly engages the outlet. A trigger assembly, positioned between the sealing assembly and the deflector, imparts a force upon the sealing assembly to maintain its sealing position within the orifice outlet. To maintain the sealing assembly within the orifice outlet, a compression screw or other rotatable member is rotatably positioned within a boss formed at the frame's apex. When rotated, the compression screw places a compressive force upon the trigger assembly, which forces the sealing assembly into the orifice outlet.
In one common design, the trigger assembly is composed of a glass bulb filled with a fluid having a known thermal expansion profile. The glass bulb is oriented between the sealing assembly and the frame's apex, and is placed in compression by the compression screw. The glass material employed must be capable of withstanding the substantially axial load placed thereupon by the compression screw. When the glass bulb is exposed to an elevated temperature indicative of a fire, the fluid encased therein will expand, due to an increase in pressure, causing the rupture or fracture of the glass bulb. Once the glass bulb is fractured, the pressurized water residing within the central orifice expels the sealing assembly from the orifice outlet.
In another common design, the trigger assembly includes a pair of lever arms, each of which is in contact with either the compression screw or the sealing assembly. The lever arms are joined by a fusible link normally including a pair of plates joined by a fusible material such as solder. The lever arms are placed in a biased position by the compression screw and are held in place by the presence of the fusible link. In response to a fire, the solder fuses, relaxing the plates of the fusible link, which in turn releases the levers from their biased position, and results in the actuation of the sprinkler head.
In the 1970's, given the advent of new materials and structures frequently utilized in both business and industrial environments, it was recognized by the sprinkler industry that in certain circumstances, standard or normal sprinklers were incapable of adequately controlling fires in areas containing these newer materials and structures. Specifically, it was found that these materials, subsequent to ignition, rapidly spread the conflagration to surrounding areas before the standard sprinkler head could initiate a suppressive water flow. Hence, in many instances, the standard sprinkler trigger assembly failed to have adequate sensitivity necessary to timely activate the sprinkler head and thus, control the fire. Frequently, the trigger assembly lack of thermal sensitivity was attributed to the design utilizing a pair of levers joined by a fusible link.
In response to the inability of standard sprinklers to effectively combat fires having the newer materials which combust and burn at a faster rate, the industry advanced what is commonly known as “quick response sprinkler heads.” The purpose of quick response (“QR”) sprinkler heads is to provide a greater sensitivity in the trigger assembly so as to reduce the time period between ignition of the fuel package and the activation of the sprinkler head and thereby prevent the fire from spreading to surrounding areas. These quick response sprinklers normally utilize a glass bulb trigger assembly.
In order to provide uniformity in what constitutes a quick response sprinkler head, the National Fire Protection Association (hereinafter referred to a the “NFPA”) generates criteria or regulations for the design of fire sprinkler heads, as well as the installation of fire sprinkler systems. The NFPA is comprised of a wide cross-section of companies and organizations having an expertise and interest in fire protection safety. The NFPA regulations or guidelines are based on data gained by over 100 years of experience in the evaluation of sprinkler systems. Compliance with the NFPA guidelines is frequently required by federal and state enforcement agencies, and is accepted by the insurance industry as one of the definitive guidelines concerning sprinkler head design. Consequently, as a commercial reality, failure of a sprinkler head design to operate successfully within the parameters set by the NFPA effectively prohibits the commercial exploitation of the design.
Section 1.4.5.2 of NFPA 13 (1999 Ed.) defines a quick-response (QR) sprinkler as follows:
Section 1-4.5.1 of NFPA 13 (1999 Ed.) states as follows:
Thus as is clear from the above sections of NFPA 13 (1999 Ed.), the ability of a sprinkler head to perform successfully as a quick response sprinkler requires that the trigger assembly have a response time index of 50 (meters-second)1/2 or less. The lower the RTI value of a particular sprinkler head, all other variables being equal, the faster the actuation time of the sprinkler head. That is, as the RTI value decreases, the time period between ignition of the fuel package and the subsequent actuation of the sprinkler head decreases, which, in consequence, increases the ability of the sprinkler head to control or suppress the fire and prevent the conflagration from spreading to adjacent areas. The entire NFPA 13 (1999 Ed.) is hereby incorporated herein by reference.
Another organization which promulgates regulations and guidelines concerning fire sprinkler systems, and performs approval tests for such systems is Underwriter's Laboratory, Inc. (hereinafter referred to as “UL”). UL standards are an additional body of regulations which are commonly accepted and relied upon by the fire sprinkler industry, insurance companies, and many state and federal enforcement agencies. As with the NFPA, conformance of a sprinkler head design with the guidelines promulgated by UL, is a practical necessity for the commercial viability of a sprinkler head design.
Section 3.3.12 of UL 199, Automatic Sprinklers for Fire Protection Service (10th Ed., 1999) defines a QR sprinkler as follows:
Section 19 of UL 199 (10th Ed., 1999) states in pertinent part, the following:
Section 19.2 of UL 199 states as follows:
Sections 19.2.3 through 19.2.5 of UL 199 state as follows:
Sprinklers of each style are to be tested in the sensitivity test oven in the pendent position with the heat responsive element located at least 1 inch (25.4 mm) away from the inside surfaces of the oven as follows:
19.2.4 The samples are to be conditioned at 75±2° F. (24±1° C.) for at least 2 hours. The inlet end of each sprinkler sample is to be connected to a source of air pressure at 4±1 psig (28±7 kPa) and quickly plunged into the sensitivity test oven in a pendent position. Each sprinkler is to be observed to determine if operation occurs as intended within the time specified in 19.2.1.
19.2.5 The sensitivity test oven is to consist of an 8 inch (203 mm) square stainless steel chamber as shown in FIG. 19.1. A constant air velocity of 8.33±0.05 feet per second (2.54±0.01 m/s) and an air temperature as specified in Table 19.1 for each temperature rating and style sprinkler are to be established. Air velocity is to be measured using an orifice plate and a manometer or a bidirectional probe and a velometer. The air temperature is to be measured by use of a No. 30 AWG (0.05 mm2) thermocouple centered upstream from the sprinkler as shown in FIG. 19.1.
FIG. 19.1, referenced in Section 19.2.5 of UL 199 is reproduced herein as FIG. 1.
Section 23 of UL 199 reads as follows:
Table 23.1, referenced in Section 23.1 of UL 199 is set forth herein as FIG. 2.
Section 19.5.1-19.5.5, referenced in Section 23.1, is as follows:
19.5.1 Ordinary or intermediate temperature rated QR sprinklers and QR extended coverage sprinklers for light hazard occupancies shall have an operating time of 75 seconds or less for each sprinkler when tested as specified in 19.5.3-19.5.5. Ordinary or intermediate temperature rated QR extended coverage sprinklers for ordinary hazard occupancies shall have an operating time of 55 seconds or less for each sprinkler when tested as specified in 19.5.3-19.5.5.
19.5.2 A recessed or concealed sprinkler having a vented escutcheon is to be installed and tested in an unblocked manner, that is, in a manner that does not inhibit air flow through the escutcheon.
19.5.3 Sprinklers of each type are to be installed in a test room (see 19.5.4) in the following position and orientation:
19.5.4 The sprinkler is to be mounted as specified in 19.5.3 on a ceiling or a wall of a closed room having an 8 foot (2.4 m) high ceiling. For a QR sprinkler, the room is to be 15 by 15 feet (4.6 by 4.6 m). For a QR extended coverage sprinkler, the room size is to be as specified by the manufacturer and be the same dimensions used for the extended coverage tests in these requirements. The sprinkler inlet waterway is to be filled with water having a temperature of 70±3° F.(21±1.6° C.). The water is to be pressurized to 4½±½ psig (31±3.4 kPa), when required for sprinkler operation.
19.5.5 The fire source is to consist of a 1 by 1 by 1 foot (305 by 305 by 305 mm) sand burner located in one corner of the room with a flow of natural gas of 500 standard cubic feet (14.2 m3) per hour for ordinary temperature rated sprinklers and 600 standard cubic feet (17.0 m3) per hour for intermediate temperature rated sprinklers. A pendent, upright, or ceiling type sprinkler is to be installed along a diagonal line on the ceiling at a distance of 16 feet, 9 inches (5.1 m) from the corner of the room where the sand burner is located. A pendent, upright, or ceiling type extended coverage sprinkler is to be installed in the intended position at a point where a diagonal line from the corner having the burner to the opposite corner intersects an arc having a radius equal to the distance from the corner having the burner to the midpoint of the opposite wall. A sidewall sprinkler is to be installed on the midpoint of the furthest wall furthest the corner having the sand burner. The test is to be started when the ambient temperature is 87±2° F. (31±1° C.) for ordinary temperature rated sprinklers and 120±2° F. (49±1.1° C.) for intermediate temperature rated sprinklers, as measured in the center of the room 10 inches (254 mm) below the ceiling. The gas burner is to be ignited, and the operation time of the sprinkler is to be recorded.
The leakage test of Section 14 of UL 199, referenced in Section 23 is as follows:
Table 14.1, referenced in Section 14.1 is reproduced herein as FIG. 4.
Section 26, entitled Impact Resistance Test states as follows:
FIG. 26.1, referenced in § 26.1 is reproduced herein as FIG. 5.
Section 28 of UL 199 is as follows:
Section 35 is as follows:
Sections 36.1.4 through 36.5.1 referenced in Section 35.1 is as follows:
The entire UL 199 (10th Ed., 1999) is hereby incorporated herein by reference.
Still another organization recognized by the sprinkler industry, and various insurance and government bodies as providing definitive guidelines for the design of automatic sprinklers is the Factory Mutual Research Corporation (“FMRC”). FMRC's Approval Standard for Automatic Sprinklers for Fire Protection, Class Series 2000, May 1998, Section 1.9 defines a QR sprinkler as follows:
A C-factor is defined as:
Section 4.30, referenced in the definition of a quick response sprinkler is as follows:
Tables 4.30.2(a) and 4.30.2(b) referenced in Section 4.30.2(A) are reproduced herein as
The entire FMRC Approval Standard for Automatic Sprinklers for Fire Protection, Class Series 2000, May 1998, is hereby incorporated herein by reference. Foreign countries have similar organizations which provide guidelines and criteria for the design and installation of sprinkler heads such as, for example, BRE Certification Limited in the United Kingdom, and Verband der Sachuersicherer in Germany.
As the foregoing guidelines make clear, a quick response sprinkler head must exhibit an increased thermal sensitivity. In most instances, because of the unacceptable response times of fusible links, the industry has been relegated to using a frangible glass bulb trigger assembly. The glass bulb trigger assembly, in contrast to most lever type trigger assemblies, is capable of exhibiting the sensitivity necessary to identify the sprinkler head in which it is used as a quick response sprinkler head. The manufacturing complexity of encasing a fluid with a known thermal expansion profile within a glass bulb having sufficient strength to withstand a compressive load imparted by the compression screw makes the glass bulb trigger assembly relatively expensive to manufacture. Furthermore, the materials necessary to manufacture the glass bulb trigger assembly also increases the cost of manufacturing.
Consequently, there exists a need within the industry for a trigger assembly capable of withstanding the direct compressive load imparted by the compression screw which is cost effective to manufacture, and exhibits the requisite performance characteristics necessary to be classified as a quick response sprinkler head.
The present invention overcomes the problems confronted by the sprinkler industry by advancing a cost effective trigger assembly which utilizes no glass or fluid components, which is direct loaded, and includes a minimum number of components to reduce the cost and complexity of manufacturing. Although the trigger assembly of the present invention may be used in conjunction with any sprinkler head, it is particularly suited for use in conjunction with quick response sprinkler heads, as its configuration results in a thermal sensitivity sufficient to classify the sprinkler head as quick response.
According to one aspect of the invention, a trigger assembly for an automatic sprinkler head includes a compression element positioned between a frame and a sealing assembly of the automatic sprinkler head. The trigger assembly also includes a thermally sensitive element surrounding at least in part the compression element and joined at least in part to the compression element by a fusible material. The thermally sensitive element includes at least two portions, each of which includes an attachment section shaped to substantially correspond to at least a section of the compression element, at least one connection section projecting from the attachment section in a direction away from the compression element, and at least one fin projecting from the distal end of the at least one connection section. The fin has a portion thereof defining a plane which forms an angular relationship to at least a portion of the connection section. The thermally sensitive element enhances the magnitude of compression of the compression element when joined thereto, and releases the sealing assembly when the thermally sensitive element is removed from the compression element. The fins of the thermally sensitive element increases the strength of the trigger assembly and the efficient retention and transportation of heat to the fusible material, which in turn increases the thermal sensitivity of the sprinkler head.
According to another aspect of the invention, a trigger assembly for an automatic sprinkler head comprises a compression element positioned between a sealing assembly and a compression member of the sprinkler head which is mounted on a frame of the sprinkler head to adjustably exert compression on the trigger assembly. The compression element extends longitudinally with respect to the frame of the sprinkler head and has a center axis. The compression element is inherently unstable when subjected to a compressive force along its center axis by adjustment of the compression member. The trigger assembly also includes a thermally sensitive element, which has an attachment section surrounding at least a portion of the compression element and is joined at least in part to the compression element by a fusible material. The thermally sensitive element is configured to maintain the compression element in a stable position between the compression member and the sealing assembly when the fusible material is below the fusing temperature and release the compression element to an unstable condition when the fusible material is above the fusing temperature. Additionally, the thermally sensitive element has at least one heat gathering member spaced from the attachment section. The heat gathering member defines at least one plane which is not co-planar with a plane defined by the center axis of the compression element. The combination of a compression element which is inherently unstable unless maintained in position by a thermally sensitive element eliminates the need for the use of a glass bulb trigger assembly. Furthermore, the heat gathering member spaced from the attachment section of the thermally sensitive element increases the heat receptive surface area, and results in a trigger assembly having a faster response time.
According to yet another aspect of the invention, a quick response sprinkler head comprises a sprinkler body having a central orifice defining a fluid outlet. A sealing assembly releasably seals the outlet to prevent fluid flow through the outlet, while a frame extending from the sprinkler body beyond the outlet carries a boss having an aperture dimensioned to receive a compression member. A direct load trigger assembly for releasably retaining the sealing assembly at the outlet includes a compression element, which extends longitudinally with respect to the sprinkler head and has a first end abutting the compression member and a second end abutting the sealing assembly. A thermally sensitive element is attached, at least in part, to the exterior of the compression element by a fusible material and has an attachment section surrounding at least a section of the compression element, at least one heat gathering member extending in a direction away from the compression element, and at least a portion forming a plane angularly related to the longitudinal axis of the compression element. The thermally sensitive element maintains the compression element in compression between the compression member and the sealing assembly when the fusible material is below the fusing temperature. Employing a heat gathering member spaced from the attachment section of a thermally sensitive element exposes the trigger assembly to a greater quantity of heat and thus decreases the response time index of the sprinkler head.
According to still yet another aspect of the invention, a quick response sprinkler head includes a sprinkler body having a central orifice forming an outlet, a frame extending from the sprinkler body and beyond the outlet, and a compression member movably mounted to the frame. An externally activated direct load trigger assembly is disposed between the compression member and the sealing assembly and releasably retains the sealing assembly at the orifice outlet and has a response time index (RTI) of less than, or equal to, approximately 90 (ft·s)1/2[50 (meters—second)1/2]. Providing an externally activated direct load trigger assembly having a response time index of less than, or equal to, approximately 90 (ft·s)1/2[50 (meters—second)1/2] greatly reduces the manufacturing costs associated with a quick response sprinkler head by eliminating the reliance on glass bulb trigger assemblies.
According to a further aspect of the invention, a quick response sprinkler head includes a sprinkler body having a central orifice forming an outlet, a frame extending from the sprinkler body beyond the outlet, and a boss, carried by the frame, which includes an aperture into which the compression member is moveably positioned. An externally activated direct load trigger assembly, disposed between the compression member and the sealing assembly, releasably retains a sealing assembly at the orifice. Further, the sprinkler head complies with Sections 19.2.1 and 19.5.1 of UL 199, 10th Ed. 1999.
According to yet another aspect, the quick response sprinkler head has a RTI value equal to or less than approximatey 90(ft·s)1/2[50(m·s)1/2] and a C factor equal to or less than 1.8(ft·s)1/2[1.0(m·s)1/2], and complies with the criteria outlined in Section 4.30 of Approval Standard, Automatic Sprinklers for Fire Protection, Factory Mutual Research Corporation, May 1998. Providing a sprinkler head which satisfies the criteria promulgated by various industry recognized organizations, and employs an externally activated, direct load trigger assembly greatly reduces manufacturing costs, while enabling the sprinkler head to be classified as quick response.
These and other features and advantages of the present invention will be further understood and appreciated by those skilled in the art by reference to the following specification, claims and drawings.
The present invention is a quick response, externally activated direct load trigger assembly for a sprinkler head. The trigger assembly of the present invention is manufactured with a minimum number of components, and by its configuration, reduces the response time index of the sprinkler head to which it is attached. Although the trigger assembly of the present invention is suitable for use with any sprinkler head, it finds particular application in sprinkler heads that must be classified as quick response. The trigger assembly utilizes no glass or expandable fluids, and thus drastically reduces the cost of manufacturing.
Referring now to Figures, wherein like reference numerals correspond to like elements in the several drawings, a quick response sprinkler head 10 includes a sprinkler frame or body 20 and a fluid deflector 30 positioned a preselected distance from top region 22 of sprinkler body 20 by a frame 40 (FIG. 8). A quick response, externally activated, direct load trigger assembly 80 is mounted between sprinkler body 20 and deflector 30. As used herein, “externally activated” shall mean that no fluid or thermally expandable material is encased within the trigger assembly such that the thermally responsive fluid causes the shattering or cracking of the material in which it is encased. Sprinkler body 20 includes an externally threaded bottom region 24, permitting sprinkler body 20 to be rotatably attached to a fire extinguishing fluid supply line or pipe. A central orifice 26 is formed in sprinkler body 20. Central orifice 26 provides a fluid flow passageway, enabling the expulsion of fire extinguishing fluid from outlet 27 of central orifice 26 in response to a fire.
Frame 40 is defined by a pair of frame arms 42 and 44, which extend from exterior surface 21 of sprinkler body 20 and project beyond top region 22. Frame arms 42, 44 each have an angled section 45 which meet to define an apex 46. Apex 46 of frame 40 is formed with a central member or boss 48 having formed therethrough an internally threaded bore 49. Bore 49 is dimensioned to threadably receive a compression member or screw 52, which applies a compressive force onto actuator 82, which will be more fully described below. Outlet 27 is formed with a counter bore 28, which defines an annular shoulder 29, which provides a bearing surface for an annular spring 70, also more fully described below.
In the non-activated state, outlet 27 of sprinkler head 10 is sealed by a sealing assembly 65. Sealing assembly 65 includes a plug 68 and an annular spring 70. Plug 68 is formed having an internal section 72, which in the assembled position, projects a preselected distance into central orifice 26 through spring 70. Internal section 72 of plug 68 contains a central channel 74. Plug 68 further includes an external section 75, which extends upwardly beyond top region 22 of sprinkler body 20 and between frame arms 42, 44 of frame 40. Annular spring 70 includes a central aperture 71 dimensioned to enable the passage of internal section 72 of plug 68 to pass therethrough. In the assembled position, annular spring 70 is supported by annular shoulder 29 and provides support for external section 75 of plug 68. When sprinkler head 10 is in the assembled condition, annular spring 70 is placed in compression so that once sprinkler head 10 is activated, the annular spring 70 and plug 68 eject from outlet 27. An insert 73 is positioned within plug 68 and is supported by a shoulder 69, formed at the transition between internal section 72 and external section 75. Insert 73 includes a central detent 76 for receiving actuator 82, described in greater detail in reference to
Trigger assembly 80 includes a compression actuator or element 82 and a thermally sensitive element or thermal sensor 84. In one preferred embodiment, as shown in
As shown in
Preferably, angle α of contact end 87 of actuator 86 is in a range of approximately 2° and 10°. Most preferably, angle α is approximately 6°, while rounded end 89 has a radius of approximately 0.040 inches. Also, most preferably, the length of actuator 86 from end to end is approximately 0.410 inches, and actuator 86 has a diameter of 0.125 inches. With respect to actuator 88, most preferably, contact end 90 has a radius of approximately 0.062 inches, and rounded end 91 has a radius of approximately 0.040 inches, while actuator 88 has a length of approximately 0.420 inches. Also preferably, actuators 86 and 88 each have a diameter in a range of approximately 0.080 inches and 0.150 inches. Most preferably, actuators 86 and 88 each have a diameter of approximately 0.125 inches.
With reference
Turning now to
Referring now to
Compression actuator 82 through 82′″ is preferably made of an insulative material. Most preferably, compression actuator 82 through 82′″ is made of a stainless steel alloy, titanium, ceramic, quartz, nickel, or a composite thereof.
Referring to
Second section 116 may be a solid body, or alternatively, as shown in
When in the assembled position, compression actuator 82 through 82′″ extends substantially longitudinally with respect to frame 40. Attachment section 112 of each member 110 surrounds, at least in part, the periphery of compression actuator 82 through 82′″. When two members 110 are utilized to comprise thermal sensor 84 and compression actuator 82 through 82′″ has a substantially cylindrical shape, each second section 116 preferably assumes a half cylinder shape so that when in the assembled position at least a part of the periphery of compression actuator 82 through 82′″ is surrounded by thermal sensor 84. The height 126 of thermal sensor 84 is preferably slightly less than the height of compression actuator 82 through 82′″ such that ends of compression actuator 82 may contact compression screw 52 and sealing assembly 65, respectively.
In the assembled position, each member 110 is positioned about compression actuator 82 through 82′″ such that second sections 116 are in a generally overlapping position (FIGS. 8 and 16). Further, if air flow apertures 120 are utilized, such air flow apertures 120 of each second section 116 and/or fins 118 are in substantial registry. The pair of fins 118 extending from overlapping second sections 116 of members 110 define a heat gathering element 130. Heat gathering element 130, although not wishing to be bound by theory, is thought to be at least partially responsible for the increased responsiveness of trigger assembly 80. Again, although wishing not to be bound by theory, it is believed that the area 119 that is defined between fins 118 traps and maintains heat therebetween such that efficient heat transfer to second sections 116 and attachment sections 112 is achieved. Members 110 are attached to one another and held about compression actuator 82 through 82′″ by a layer of fusible material positioned between second sections 116.
When assembled and when the fusible material is positioned between the respective actuators of compression actuator 82 through 82′, thermal sensor 84 along with the fusible material, which is positioned in notch 104 of compression actuator 82″ or embedded between the wires 106 of compression actuator 82′″, maintains compression actuator 82 through 82′″ in a stable position between sealing assembly 65 and compression screw 52. The fusible material position between or in the component(s) of compression actuator 82 through 82′″ also hold thermal sensor 84 in position.
Most preferably, members 110 have a height of approximately 0.5 inches, while fins 118 have a length in a range of approximately 0.10 inches and 0.200 inches. Also, most preferably, second sections 116 have a length of approximately 0.110 inches, while attachment sections 112 express a radius of approximately 0.065 inches.
In an alternative preferred embodiment, as shown in
Turning now to
Turning now to
In all other respects, thermal sensor 84′ and 84″ are substantially similar to thermal sensor 84. Also, it will be understood by those with ordinary skill in the art that second sections 116 of thermal sensors 84′ and 84″ may include air flow apertures 120 or be defined by flanges 122, and also that fins 118 may include angled ends 124.
Members 110 of thermal sensor 84 through 84″ are made of a conductive material such as, for example, copper alloy, beryllium copper, or beryllium nickel. Also, the external surface of thermal sensor 84 through 84″ may be coated with a heat absorbing coating such as, for example, a dark colored acrylic paint.
Turning now to
To assemble trigger assembly 80 (using thermal sensor 84 comprised of two members 110 as an example), compression actuator 82 through 82′″ is first prepared by placing an appropriate amount of fusible material 81 therein. With respect to compression actuator 82, a fusible material is placed in annulus 92. With respect to compression element 82′, the fusible material is positioned between contact ends 98 and 99. Similarly, with respect to compression actuator 82″ an appropriate amount of fusible material is positioned in notch 104. When employing compression actuator 82′″, the fusible material is positioned about the perimeter of wires 106 and/or imbedded therebetween. Thereafter, members 110 are placed about the perimeter of compression actuator 82 through 82′″, with a layer of fusible material positioned between overlapping second sections 116. When employing the annular bands 142 of thermal sensor 84′″ a fusible material is positioned in channels 146 to thereby secure thermal sensor 84′″ about compression actuator 82 through 82″.
Thereafter, sprinkler head 10 may be assembled by first installing sealing assembly 65 in outlet 27 of central orifice 26 by placing annular spring 70 in supporting contact with annular shoulder 29. Thereafter, plug 68 is placed through aperture 71 of annular spring 70 with its external surface resting on the perimeter of annular spring 70. Once sealing assembly 65 is in position, trigger assembly 80 is positioned with end 89 of compression actuator 82 through 82′″ in abutting contact with detent 76 of insert 73. When so positioned, end 91 of compression actuator 82 through 82″ will be positioned a preselected distance below the bottom surface of boss 48. When utilizing compression actuator 82′″, end caps 107 are in contact with sealing assembly 65 and compression screw 52. Once trigger assembly 80 is in position, compression screw 52 is rotated within boss 48 and eventually contacts end 91 or end cap 107 and, as a result, exerts a compression force upon compression actuator 82 substantially along its center axis. Continued rotation of compression screw 52 forces sealing assembly 65 into sealing engagement with outlet 27 of central orifice 26. Once sealing assembly 65 is positioned in sealing contact with outlet 27, deflector 30 is positioned on boss 48 and secured thereto according to any procedure normally utilized in the art.
In operation, under non-activated conditions, thermal sensor 84 through 84′″ maintains compression actuator 82 through 82′″ in a stable position and assures that a sealing engagement is maintained between sealing assembly 65 and outlet 27 of central orifice 26. In response to a fire, the temperature surrounding trigger assembly 80 will increase, while the heat gathering elements 130, defined by fins 118, increase the retention of heat by members 110 to thereby raise the fusible material to its fusing temperature. When the fusible material reaches its fusing temperature, members 110 of thermal sensor 84 will separate. In addition, fusible material contained within compression actuator 82 through 82′″ will liquefy. The release of thermal sensor 84 from the periphery of compression element 82, in combination with the liquefication of the fusible material positioned within compression actuator 82 through 82′″, causes compression actuator 82 through 82′″ to return to its inherently unstable state. This inherent instability coupled with the compressive force along the central axis of compression actuator 82 through 82′″ results in the separation, fracture, or bending of the compression actuator 82 through 82′″. Once the compression actuator 82 through 82′″ loses its structural integrity, it will collapse and fall away from sprinkler body 20. When compression actuator 82 through 82′″ falls away from sprinkler body 20, the compressive force upon sealing assembly 65 is released and the pressure of the water or other fire extinguishing fluid residing within central orifice 26 causes the expulsion of sealing assembly 65 from outlet 27. Water or other fire extinguishing fluid will be expelled from central orifice 26 and subsequently deflected in an optimum pattern by deflector 30 in order to suppress or control a fire.
The trigger assembly of the present invention, due to its configuration, exhibits an increased response time, which in turn enables the sprinkler head to which it is attached to be classified as a quick response sprinkler head and to satisfy the criteria for a quick response sprinkler under FMRC, UL, and NFPA.
It is to be understood that the foregoing is a description of the preferred embodiments only. One skilled in the art will recognize that variations, modifications and improvements may be made without departing from the spirit and scope of the invention disclosed herein. The scope of protection is to be measured by the claims which follow in the breath of interpretation which the law allows, including the doctrine of equivalents.
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| Number | Date | Country | |
|---|---|---|---|
| 20030209353 A1 | Nov 2003 | US |
