Fire suppression system and emergency annunciation system

Abstract

A fire suppression and annunciation system using a flexible conduit and a wire rope is provided. The wire rope may be connected to a knob assembly at a universal pull station and to a release mechanism of the fire suppression system. An operator may pull a handle of the knob assembly at the universal pull station, thereby activating the release mechanism to release fire suppression agent. A flexible conduit may house the wire rope along at least a part of the connection from the universal pull station to the release mechanism. A material on the liner of the flexible conduit and/or on the wire rope may be used to reduce the coefficient of friction of wire rope in the flexible conduit. The fire suppression system may further include a pulley block system connected to the universal pull station. The pulley block system may comprise bearings, and may lower the force necessary to activate the release mechanism.

Claims

1. A pull station comprising: a pull handle assembly comprising a pull handle, whereby pulling of the pull handle is configured to activate a release mechanism for a fire suppression system, the pull handle assembly configured to interface with a break rod; a faceplate; and a locking mechanism configured to lock and unlock at least a portion of the pull handle assembly with at least a portion of the faceplate, wherein when the locking mechanism locks the at least a portion of the pull handle assembly with the at least a part of the faceplate, the faceplate and the pull handle assembly are locked together so that the faceplate and the pull handle assembly are not rotatable; wherein when the locking mechanism is manually unlocked, the at least a portion of the pull handle assembly is rotatable about an axis that is perpendicular to a plane defined by the faceplate in a first direction and a second direction opposite the first direction and the faceplate is not rotatable; wherein the at least a portion of the pull handle assembly is configured to rotate by: rotating, in the first direction, the at least a portion of the pull handle assembly that is configured to interface with the break rod; inserting the break rod; and rotating, in the second direction, the at least a portion of the pull handle assembly that is configured to interface with the break rod; and wherein the pull handle of the pull handle assembly is configured to activate the release mechanism when the pull handle moves along the axis that is perpendicular to the plane defined by the faceplate.

2. The pull station of claim 1, wherein a distance between the pull handle assembly and the plane defined by the faceplate is constant during rotation of the at least a portion of the pull handle assembly.

3. The pull station of claim 1, wherein the locking mechanism comprises a snap lock feature, the snap lock feature configured to lock the pull handle assembly to the faceplate.

4. The pull station of claim 3, wherein the snap lock feature, when unlocked, is compressed.

5. The pull station of claim 4, wherein the snap lock feature remains compressed until it mates with at least a part of the pull handle assembly, thereby locking.

6. The pull station of claim 1, further comprising: a junction box comprising a first opening and a second opening; a pulley; and a pulley block, the pulley in fixed relation to and mounted with the pulley block; wherein the pull handle is connected to a rope, the rope further connected to the release mechanism, wherein the pulley changes a direction of the rope, wherein the faceplate, the pulley block, and the pulley are configured to be positioned relative to one another in a first configuration and a second configuration, wherein, in the first configuration and the second configuration, each of the faceplate, the pulley block and the pulley are connected to the pull station, wherein, in the first configuration, the rope exits the junction box along a centerline of the first opening, wherein, in the second configuration, the rope exits the junction box along a centerline of the second opening, and wherein the pulley is configured to reduce an amount of force necessary to pull the pull handle in order to activate the release mechanism.

7. The pull station of claim 6, further comprising a flexible conduit, the rope disposed to slide axially within the flexible conduit; wherein the flexible conduit comprises a plastic liner; and wherein a lubricant is applied on at least one of an interior of the plastic liner or the rope in order to reduce a coefficient of friction.

8. A pull station comprising: a pull handle assembly configured to activate a release mechanism for a fire suppression system, the pull handle assembly configured to interface with a break rod; a faceplate; and an unlocking mechanism configured to, responsive to manual movement, unlock only one of the pull handle assembly or the faceplate from at least a part of the pull station, wherein, responsive to the manual movement, the only one of the pull handle assembly or the faceplate is rotatable about an axis in a first direction and a second direction opposite the first direction and another of the only one of the pull handle assembly or the faceplate is not rotatable; wherein the only one of the pull handle assembly or the faceplate are configured to rotate by: rotating one of (a) a part of the pull handle assembly that is configured to interface with the break rod and (b) the faceplate in the first direction; inserting the break rod; and rotating the one of (a) the part of the pull handle assembly that is configured to interface with the break rod and (b) the faceplate in the second direction.

9. The pull station of claim 8, wherein the faceplate is configured to be stationary; and wherein the part of the pull handle assembly that is configured to interface with the break rod is configured to be rotated.

10. The pull station of claim 8, wherein the faceplate is configured to be rotated; and wherein the part of the pull handle assembly that is configured to interface with the break rod is configured to be stationary.

11. The pull station of claim 8, wherein the unlocking mechanism is further configured to, responsive to a manual locking movement, lock only one of the pull handle assembly or the faceplate with the at least a part of the pull station.

12. The pull station of claim 11, wherein the unlocking mechanism is configured to lock the pull handle assembly to the faceplate.

13. The pull station of claim 11, wherein the unlocking mechanism is configured to lock the faceplate to the pull handle assembly.

14. The pull station of claim 8, wherein a distance between the pull handle assembly and a plane defined by the faceplate is constant during rotation of the part of the pull handle assembly that is configured to interface with the break rod or the faceplate.

15. A pull station comprising: a pull handle assembly comprising a pull handle, the pull handle configured to activate a release mechanism for a fire suppression system, the pull handle assembly configured to interface with a break rod; a faceplate; and a locking mechanism configured to lock and unlock at least a portion of the faceplate with at least a part of the pull handle assembly, wherein when the locking mechanism locks the at least a portion of the faceplate with the at least a part of the pull handle assembly, the faceplate and the pull handle assembly are locked together so that the faceplate and the pull handle assembly are not rotatable; wherein when the locking mechanism is manually unlocked, the faceplate is rotatable relative to the pull handle in a first direction and a second direction opposite the first direction about an axis that is perpendicular to a plane defined by the faceplate; wherein the faceplate is configured to rotate relative to the pull handle by: rotating the faceplate relative to the pull handle in the first direction; inserting the break rod into the pull handle assembly; and rotating the faceplate relative to the pull handle in the second direction; and wherein the pull handle of the pull handle assembly is configured to activate the release mechanism when the pull handle moves along the axis that is perpendicular to the plane defined by the faceplate.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) The system may be better understood with reference to the following drawings and description. The components in the figures are not necessarily to scale, emphasis instead being placed upon illustrating the principles of the invention. Moreover, in the figures, like referenced numerals designate corresponding parts throughout the different views.

(2) FIG. 1 is a representation of a prior art fire suppression system using rigid conduit routing.

(3) FIG. 2 is a cross-section of a prior art pull handle with wire rope connection.

(4) FIG. 3 is a cross-section of a prior art pull handle with wire rope connection that has been activated.

(5) FIGS. 4A-C illustrate a prior art sequence for installing a break rod.

(6) FIG. 5A illustrates a Bowden conduit.

(7) FIG. 5B illustrates a braided conduit with bends.

(8) FIG. 5C illustrates a braided conduit with exploded construction view from FIG. 5B.

(9) FIG. 6 is a representation of the pull station and flexible cable routing.

(10) FIG. 7A is a first cross section of the pull station with integral pulley block and cable compression connection (such as a crimp stop) in a shallow junction box.

(11) FIG. 7B is a second cross section of the pull station with integral pulley block and cable compression connection in a shallow junction box.

(12) FIG. 7C is a first cross section of the pull station with integral pulley block and cable compression connection in a deep junction box.

(13) FIG. 7D is a second cross section of the pull station with integral pulley block and cable compression connection in a deep junction box.

(14) FIG. 8A is a first cross section of the pull station with integral pulley block and cable set screw connection in a shallow junction box.

(15) FIG. 8B is a second cross section of the pull station with integral pulley block and cable set screw connection in a shallow junction box.

(16) FIG. 8C is a first cross section of the pull station with integral pulley block and cable set screw connection in a deep junction box.

(17) FIG. 8D is a second cross section of the pull station with integral pulley block and cable set screw connection in a deep junction box.

(18) FIG. 9A is an exploded view of the pull station with pulley block snap-fit.

(19) FIG. 9B is an exploded view of the pull station with pulley block set screw fit.

(20) FIG. 10A is an exploded view of the pulley block with groove fit features.

(21) FIG. 10B is a front view and side view of the retaining clip and flexible conduit.

(22) FIG. 10C is an exploded view of the pulley block with snap-fit features.

(23) FIG. 10D is a front view of the pull station pull knob rotated relative to the faceplate.

(24) FIG. 10E is a cross-section (E-E) from FIG. 10D.

(25) FIG. 10F is an exploded portion (detail F) from FIG. 10E.

(26) FIG. 10G is a front view of the pull station pull knob of the faceplate assembly not rotated.

(27) FIG. 10H is a cross-section (G-G) from FIG. 10G.

(28) FIG. 10I is an exploded portion (detail H) from FIG. 10H.

(29) FIG. 10J is a perspective view of the pulley block pulley.

(30) FIG. 10K is a front view of the pulley block pulley shown in FIG. 10J.

(31) FIG. 10L is a cross-section (A-A) from FIG. 10K.

(32) FIG. 11A is a front view of the faceplate of the pull station with the pull knob rotated.

(33) FIG. 11B is a front perspective view of the faceplate of the pull station and junction box with the pull knob rotated as depicted FIG. 11A.

(34) FIG. 11C is a front view of the faceplate of the pull station with the pull knob not rotated.

(35) FIG. 11D is a front perspective view of the faceplate of the pull station and junction box with the pull knob not rotated as depicted FIG. 11C.

(36) FIG. 12A is a front view of the faceplate of the pull station with the pull knob rotated and with walls proximate to the pull station.

(37) FIG. 12B is a front view of the faceplate of the pull station with the pull knob not rotated and with walls proximate to the pull station.

(38) FIG. 12C is a front perspective view of the faceplate of the pull station and junction box with the pull knob not rotated as depicted FIG. 12B.

(39) FIG. 13A is a perspective cross-section of the pull knob, wire rope, and the set screws holding the wire rope.

(40) FIG. 13B is a cross-section of the pull knob, wire rope, and the set screws holding the wire rope as depicted in FIG. 13A.

(41) FIG. 13C is an exploded view of the pull knob, wire rope, and the set screws holding the wire rope as depicted in FIG. 13A.

(42) FIG. 13D is a top perspective exploded view of the pull knob, wire rope, and compression fitting capturing the wire rope.

(43) FIG. 13E is a bottom perspective exploded view of the pull knob, and wire rope capturing the wire rope as depicted in FIG. 13D.

(44) FIG. 13F is a cross-section of the pull knob, wire rope, and compression fitting capturing the wire rope as depicted in FIG. 13D.

(45) FIG. 14 is a representation of the pull station, flexible cable routing, and auto wire rope tensioning mechanism.

(46) FIG. 15A is an exploded view of the auto wire rope tensioning mechanism illustrated in FIG. 14.

(47) FIG. 15B is an illustration of the auto wire rope tensioning mechanism compressed.

(48) FIG. 15C is an illustration of the auto wire rope tensioning mechanism extended fully.

(49) FIG. 15D is an illustration of the auto wire rope tensioning mechanism with partial movement pull testing from the pull station.

(50) FIG. 16A is an exploded bottom perspective view of the junction box and faceplate with break rod storage mechanism.

(51) FIG. 16B is a top perspective view of the faceplate.

(52) FIG. 16C is a bottom perspective view of the faceplate illustrating storage of the additional break rods.

(53) FIG. 16D is a front perspective view of a portion of the faceplate.

(54) FIG. 16E is a front perspective view of a portion of the faceplate illustrating the snap cleat.

(55) FIG. 17A is a side cross-section of the pull station with rigid conduit wire rope connection.

(56) FIG. 17B is a side cross-section of the pull station with flexible conduit wire rope connection.

(57) FIG. 17C is a front view of the pull station with wire rope routing on-center to the junction box interface hole.

(58) FIG. 17D is a side view of the pull station with wire rope routing on-center to the junction box interface hole.

(59) FIG. 18A depicts a perspective view of a PG9 cap.

(60) FIG. 18B depicts a perspective view of the compression fitting.

(61) FIG. 18C depicts an exploded view of the compression fitting and the PG9 cap depicted in FIGS. 18A-B.

(62) FIG. 18D depicts a perspective view of the strain relief.

(63) FIG. 18E depicts a side view of the strain relief and the compression fitting prior to attachment of the strain relief.

DETAILED DESCRIPTION OF THE INVENTION

(64) FIG. 6 is a block diagram illustrating a mechanical system for connecting the pull handle 416 of pull station 400 to the release mechanism 160 of the fire suppression system using a wire rope 140 contained within a flexible conduit 220. An example of the release mechanism 160 is a panel, such as the Ansul AUTOMAN panel. Another example of the release mechanism 160 is a valve. Alternatively, flexible conduit 220 may be used to connect pull station 110 (shown in FIG. 1) with the release mechanism 160.

(65) The flexible conduit 220 may be composed of a variety of types of conduits, such as a Bowden conduit and a braided conduit, as shown in more detail in FIGS. 5A-C. However, the flexible conduit is not limited to these types of conduits. The flexible conduit 220 may include a liner, a liner wrap, and an outer jacket. Though, the flexible conduit 220 does not need to include each of the liner, the liner wrap and the outer jacket. For example, the outer jacket need not be included in the flexible conduit. The flexible conduit 220 and wire rope 140 are coaxial mechanical devices whereby the wire rope 140 is disposed to slide axially within the liner of the flexible conduit 220. The flexible conduit 220 may be routed in non-standard configurations 221 as shown in FIG. 6. Further, the flexible conduit 220 may be used in combination EMT 130 and/or pulley elbows 150 to couple wire rope 140 between, for example, structures such as the pull station 400 and release mechanism 160. The wire rope 140 may be composed of a metal, such as an aircraft quality stainless steel braided wire rope with, for example, 77 braiding. The braiding of the wire rope may allow for the wire rope to be more bendable. Alternatively, the wire rope may have different braiding or no braiding at all.

(66) The liner may comprise a material with a low coefficient of friction. For example, the liner may be composed of in part or whole a plastic material such as, for example, an acetal polymer, a polyethylene polymer, a PVC polymer, or a Teflon fluoropolymer. In this manner, the liner may reduce the coefficient of friction between the liner and the wire rope whereby reducing the force required to slide the wire rope through the flexible conduit.

(67) The liner wrap may comprise metal or composite, and may be a wire braid (such as a cross-weave), a flat wrap, or a wire wrap. The liner wrap may provide structural support to the flexible conduit 220, such as structural support to the liner. The liner wrap may be a mesh-type structure, with a plurality of holes there through. As discussed above, the flexible conduit may include an outer jacket. The outer jacket may comprise a polypropylene material, a PVC material, or other suitable plastics materials. The outer jacket, which may be free of holes, may be used for a variety of purposes. For example, the outer jacket may be used to form an impermeable and ductile outer sheathing for flexible conduit 220. The outer jacket may also be colored (such as red) thereby serving as a visual warning mechanism to identify this flexible conduit as SAFETY RELATED. In addition to the red color, indicia (such as printed text) may be printed on the outer jacket. For example, black text may be printed against the red outer jacket indicating the fire suppression cabledo not disturb.

(68) One example of flexible conduit may include Bowden lined conduit 500, illustrated in FIG. 5A. The Bowden lined conduit 500 may include an outer jacket 502 composed of PVC. The outer jacket 502 may be a 0.197 outer diameter, for example. The Bowden lined conduit 500 may also include a wire wrap 506, acting as a liner wrap. And, the Bowden lined conduit 500 may include a polyethylene liner 504 acting as a liner. The wire rope 140 may be inside of the polyethylene liner 504. Another example of flexible conduit may include a braided conduit 305, illustrated in FIGS. 5B-5C. The braided conduit 305 may include a polypropylene outer jacket 310. The polypropylene outer jacket 310 may have a 0.203 outer diameter. The braided conduit 305 may include a wire braid 330, such as a 12-16 wire braid, acting as a liner wrap. And, the braided conduit 305 may include, an acetal liner 320 acting as a liner. Still another example of flexible conduit may include a long lay conduit with a polyethylene jacket of 0.187 outer diameter, a wire wrap, and a polyethylene liner. The flexible conduits illustrated in FIGS. 5A-5C may easily be bent without the need for permanent deformation (or reshaping) of the liner or liner wrap.

(69) Further, a lubricant may be used to reduce the coefficient of friction between the wire rope 140 and the liner. In particular, a lubricant (such as a Silicone lubricant) may be added to one of, or both, the flexible conduit 220 and the wire rope 140. For example, the interior surface of the liner and/or the exterior surface of the wire rope 140 may be coated with a lubricant to reduce the coefficient of friction between the wire rope 140 and the liner. Alternatively, the liner may be attached to the wire rope 140. For example, the wire rope 140 may be coated with a lubricant that subsequently solidifies (or partly solidifies). In this way, the wire rope 140 and/or the flexible conduit 220 may include a liner. As discussed above, the flexible conduit 220 allows the wire rope 140 to be pulled at the pull station 400 in order to activate the release mechanism 160. The following is an equation of the forces associated with the pull station 400 and the release mechanism 160:
F1=F2e.sup.uskB

(70) where F1 is the force at the pull station 400;

(71) F2 is the force at the release mechanism 160;

(72) usk is the coefficient of friction; and

(73) B is the radians of total flex where 360 degrees=2 pi radians for the flexible conduit 220 routing.

(74) As discussed above, the liner of the flexible conduit 220 may be composed of a Teflon fluoropolymer, which has a usk (coefficient of friction) of 0.040. According to the equation above, a flexible conduit 220 with no bends results in a force F1 at the pull station 400 of 1 pound to generate a 1 pound force at the release mechanism 160 (basically, no loss in the force generated from the pull station 400 to the release mechanism 160). Further, according to the equation shown above, a flexible conduit 220 with a summation of angular curves of 4.7 radians (270 degrees) requires a force F1 at the pull station 400 of 1.21 pounds to generate a 1 pound force at the release mechanism 160. In this way, even though the flexible conduit 220 has considerable bends in it, the amount of force necessary at the pull station 400 to generate a 1 pound force at the release mechanism 160 is substantially the same and not considerably higher than the flexible conduit 220 with no bends in it. Therefore, comparing the low friction flexible conduit to other conduits of higher friction, the flexible conduit 220 does not cause the operator of the pull station 400 to exert an inordinate amount of force to activate the release mechanism 160.

(75) The fire suppression system may also include a pulley block 610 of FIG. 9A or 710 of FIG. 9B. Pulley blocks 610 and 710 may be installed proximate to the pull station 400 such as being connected to the pull station as shown in FIGS. 7A-D, 8A-D, 17A-B. Pulley blocks 610 and 710 may be connected to the pull station so that the wire rope 140 exits from the pulley block in any of multiple directions. For example, if the pull station 400 may be mounted flush to a wall, the wire rope 140 may exit from the pulley block 610 or 710 in any upward direction (toward the ceiling), a downward direction (toward the floor), to the right, and to the left.

(76) The pulley blocks 610 and 710 may allow for installation in a variety of boxes, such as a standard electrical box 440, a deep electrical box 445, or no box. For a standard electrical box, the pulley blocks 610 and 710 may be configured in a first orientation (as shown in FIGS. 7A-B and 8A-B) for a shallow box. In a first configuration for a standard electrical junction box, portion 615 or 715 may be pressed into the faceplate 410 in receiving location 420 of the pull station (shown in FIGS. 9A-B and 16D). The portions 615 or 715 may be multi sided, such as square in shape, and may include a series of grooves 726 or snap fitting features 627 to provide positive engagement of the pulley blocks 610 and 710 into the faceplate 410. In this manner and with a square configuration, the pulley blocks 610 and 710 may be pushed into the faceplate 410 in any one of four positions, thus allowing the cable exit points to exit the junction boxes 440 and 445 in any one of four holes 430 or 431. In a second configuration for a deep electrical junction box, pulley box portions 620 or 720 may be pressed into the faceplate 410 of the pull station (shown in FIGS. 7C-D and 8C-D). The portions 620 or 720 may be multi sided, such as square in shape, and may include a series of grooves 726 or snap fitting features 627. In this manner and with a square configuration, pulley blocks 610 and 710 may be pushed into the faceplate 410 in any one of four positions, thus allowing the cable exit point of pulley blocks 610 and 710 to exit the junction box 440 and 445 in any one of four holes 430 or 431 respectively. The junction box 440 and 445 may include a box bottom 436 and a box screw boss 437. The junction box 440 may interface with EMT 130 using a conduit-to-junction box coupling 131 (as shown in FIG. 17A) or may interface with flexible conduit 220 using a strain relief (not shown in FIG. 17B).

(77) The pulley blocks 610 and 710 are uniquely configured to ensure that field cable entering the shallow or deep electrical junction boxes may enter on centerline of the junction box access holes 430 or 431 as illustrated in FIGS. 17C-D.

(78) The pulley blocks 610 and 710 shown in FIGS. 10A and 10B may include a pulley 640 and 740 with bearings, or a pulley with a low friction bushing, in order to reduce the force necessary to pull the wire rope 140 out of the pull station when activating the pressurizing control cabinet 200, release mechanism 160. The pulley 640 or 740 may be connected to pulley block 610 or 710 using pulley axle screw threaded boss and pulley axle retaining clip 147. An example of the means by which to connect the pulley includes using pulley axle shaft 641 and threaded pulley axle 642 (for pulley 640), or pulley axle shaft 741 and threaded pulley axle 742 (for pulley 740). Alternatively, the pulley axle retaining clip 147 need not be used. For example, threaded pulley axle 742 may be turned into the pulley block to secure the pulley 640 or 740. FIG. 10A further illustrates a pull knob stem receiver 725, a cleat retaining boss for a flexible cable 745, and a cleat retaining boss for a pulley axle 747. FIG. 10C further illustrates a pull knob stem receiver 625, a snap cleat relief 626, a snap cleat locking surface 628, and a cleat retaining boss for a flexible cable 645.

(79) The pulley blocks 610 and 710 may connect to the flexible conduit 220 using an integral or assembly assisting retaining clip 145. The retaining clip 145 may contain teeth or cleats 146 dimensioned such that the inner diameter (ID) of the clip is slightly less than the outer diameter (OD) of the flexible conduit 220 outer jacket 310 to enable positive engagement of the teeth or cleats 146 with the outer jacket 310. The teeth or cleats 146 may be angled in such a way to allow the flexible conduit to be inserted into the pulley blocks 610 or 710 using reasonable force by hand. Based on the predisposed angle of the teeth or cleats 146 as shown in FIGS. 10A and 10B, removal of the flexible conduit 220 from the pulley blocks 610 or 710 is made difficult and thus may require the use of a special tool. Alternatively, a crimp may be used in place of the retaining clip 145 to connect the flexible conduit 220 to the pulley blocks 610 or 710. The pulley blocks 610 or 710 may also include proper circular interface bosses at each wire rope 140 exit point to enable the pulley blocks 610 or 710 to couple directly to EMT conduit compression fittings or other forms of conduit castings or couplings.

(80) The fire suppression system may include a faceplate 410 that is coupled to pulley blocks 610 and 710. The faceplate 410 may include lettering in one or more languages. The faceplate 410 may be coupled to pulley blocks 610 and 710 in several ways, including using one or more set screws 417 or snap lock features 627 (illustrated in FIG. 10C) that may couple the pulley blocks 610 and 710 into engagement with the faceplate 410. Alternatively, instead of set screws 417, a crimp connector may be used. The resulting combination is a faceplate 410/pulley block 610 or 710 coupled as an assembly. When the faceplate 410 is configured with the snap lock feature as shown in FIG. 9A, assembly of the pulley block 610 into the faceplate 410 may be accomplished by hand without tools. The snap lock feature, as described herein and depicted in FIG. 9A, enables a faceplate-to-pull knob snap lock feature 425 to be utilized for locking the pull knob body 418 in a normal rotational orientation as shown in FIGS. 11C-D and 16E. The snap lock feature 425 may be used to engage the pull knob body 418 into place once the pull knob body 418 is rotated into its final position. In this way, the pull knob body 418 may be rotated relative to the faceplate 410. Alternatively, the pull knob body 418 may remain stationary and the faceplate 410 may be rotated. The faceplate 410 may include one or more faceplate center pulley block receiver walls 421 and a faceplate center pulley block receiver step lock 422, as shown in FIG. 16E.

(81) The snap lock feature 425 enables the pull knob body 418 to be rotated, such as rotated sufficiently clockwise to allow the break rod 412 to be inserted into the pull knob body 418 in preparation for setting the pull station to a normal orientation as shown in FIGS. 11A-D. Insertion of the break rod 412 may thus be accomplished in areas where there is adequate wall space on each side of the pull station and also within the narrow wall confines. This is illustrated in FIGS. 12A-C in which wall 117 is proximate to the faceplate 410. In order to insert break rod 412, the pull knob body 418 is rotated clockwise (illustrated in FIG. 12A), and after installation of the break rod, rotated counterclockwise (illustrated in FIG. 12B). While the pull knob body 418 is being rotated counterclockwise towards the snap lock position, the snap lock cleat 425 may remain compressed until it moves into the corresponding relief 409 contained within the pull knob body as shown in FIGS. 10D-I and 13E.

(82) The pull station 400 includes pull handle cap 390, cap snap fit boss 391, and cap body snap fit receiving boss 392, as shown in FIG. 9a. A crimp stop 141 may be used to hold pull handle cap 390. The crimp stop 141 is one example of a cable compression connection. Another example of a cable compression connection may comprise a compression fitting, which may be used in place of crimp stop 141. FIG. 9A further shows a cross hole for break rod 401, a relief hole for wire rope stopper 402, a ring handle hole 403, and a tool slot 404.

(83) The faceplate 410 may contain one or more protective side walls 411, such as one on each side of the pull knob body 418 and pull handle 416 assembly as shown in FIGS. 16B and 16D. The protective walls 411 may provide a robust barrier to protect the pull knob body 418 and pull handle 416 against inadvertent side impact by foreign objects. These protective side walls 411 may also provide slots 413 for receiving the ends of the break rods 412 when installed, illustrated in FIG. 17A-C. Further, the faceplate 410 may include a pull handle circular race of faceplate 423 and a pull knob set screw threaded boss 424.

(84) Activation of the pull station may be accomplished by pulling the pull knob body 418 away from the pull station 400. This action may cause the break rod 412 to fracture allowing the pull knob body 418 to move away from the faceplate 410 and thus moving the wire rope 140 through the flexible conduit 220, thereby activating the release mechanism 160. Coupling of the wire rope 140 to the pull knob body 418 may be accomplished in several ways, such as shown in FIG. 9B. Two methods are provided for illustration purposes only. The first method, as illustrated in FIGS. 13A-C, uses one or more set screws 417 to secure the wire rope 140 into fixed or permanent configuration with the pull knob body 418. In this configuration, the wire rope 140 may be threaded into the wire rope recess 426 of the pull handle cable boss 428, such as shown in FIG. 13C. Set screws 417 may be tensioned against the wire rope 140 to cause a sufficient binding on the wire rope to prevent it from being removed, such as shown in FIG. 6. As discussed above, set screws 417 need not be used and alternative methodologies, such as using a crimp connector, may be used. The second method, as illustrated in FIGS. 13D-F, uses a compression fitting 141 to create an oversized end of wire rope coupling to inhibit or prevent the wire rope 140 from being removed from the pull knob body 418. In this configuration, the OD of the compression fitting 141 may be larger than the OD of the wire rope access hole 426 in order that removal of the wire rope 140 from the pull knob body 418 is inhibited or prevented.

(85) The faceplate 410 may also contain containment boundary diaphragms 415 (illustrated in FIG. 16D) located in each faceplate 410 mounting screw boss 414, (illustrated in FIGS. 9A-B and 16D). The containment boundary diaphragms 415 may be used to reduce or minimize any contaminate such as grease, dirt or grime from penetrating the faceplate 410 outer surface and entering into the working components and/or wire rope conduit 140 or 200 sections of the pull station assembly, such as shown in FIG. 11A.

(86) The faceplate 410 and/or the pull handle cap 390 may further include various indicia, such as words, as shown in FIGS. 9A-B and 10D. The indicia may be of a color that is different from another portion of the faceplate 410 and the pull handle cap 390.

(87) For example, the color may be red, fluorescent, or glow in the dark in order to differentiate the words (and the faceplate) from the surroundings (such as an aluminum background). The break rod 412 may be composed of plastic or glass and therefore may be transparent or opaque. The color on the faceplate 410 may be highlighted when viewed through the break rod 412. Moreover, a part (or all) of the pull handle 416, break rod 412, screw boss 414, or containment boundary diaphragms 415 may be of a color that is different from another portion of the pull handle 416, break rod 412, screw boss 414, or containment boundary diaphragms 415. Or, the pull handle 416, break rod 412, screw boss 414, or containment boundary diaphragms 415 may entirely be red, fluorescent, or glow in the dark in order to differentiate it from an adjacent part. Finally, the colors of two parts that are designed to mate may be selected such that the colors match when installed properly (e.g., continuous color red for screw boss 414 and containment boundary diaphragm 415 if they are installed properly) or such that the colors are different when installed properly (e.g., color red next to color aluminum when screw boss 414 is installed properly with containment boundary diaphragm 415).

(88) The faceplate 410 may further be adapted to serve as a storage mechanism for service items, such as extra break rods 412. One method is shown in FIGS. 16A and 16B. In the event that the pull station 400 needs to be reconfigured or reinitialized, such as by inserting a new break rod, the hardware used for the reinitializing may be stored proximate to the pull station 400, such as storing additional break rods 412 on an underside of the faceplate 410, as shown in FIG. 16A. The break rods 412 may be stored at a 90 angle to that depicted in FIGS. 16A and 16C.

(89) When the pull station 400 is installed in the field, the technician may often leave extra wire rope 140 inside the pressurizing control cabinet 200. This extra length of wire rope 140 may have the effect of allowing the pull knob body 418 to move away from the pull station 410 without activation of the release mechanism 160. A wire rope auto tensioning device may be used to control the dead band of wire rope 140 and maintain the wire rope 140 under tension, though this is not required. One example of an auto tensioning device comprises an auto tensioning spring 142, illustrated in FIGS. 15A-D. The auto tensioning spring 142 may be used to reduce the dead band, as shown in FIGS. 15A-B. The auto tensioning spring 142 may allow the technician the ability to field test the conduit 130 or 220 routing without activating the system, as illustrated in FIG. 15D, by partial movement pull testing from the pull station. For example, a single technician located at the pull station 400 may pull the pull handle 416 in order to test the device. If after pulling the pull handle 416, the handle returns to its position (i.e., springs back), then the technician may determine that the auto tensioning spring 142 is operational and the wire rope is properly configured. The auto tensioning spring 142 may further ensure activation of the system upon deployment of the pull knob body 418, as illustrated in FIG. 15C, by extended full movement.

(90) As shown in FIG. 15A, the auto tensioning device (such as the auto tensioning spring 142) is located proximate to the release mechanism 160. Alternatively, the auto tensioning device may be located at any point along the path of the wire rope 140 from the pull station 400 to the release mechanism 160. The auto tensioning device may comprise a variety of shapes, such as a Z shaped spring, as shown in FIG. 15A.

(91) The equation F.sub.1=F.sub.2e.sup.uskB may be used to describe the characteristics of the flexible conduit system shown in FIGS. 6 and 14. F.sub.1 may be the force at one end of the wire rope (such as where the wire rope 140 is connected to the pull station 400), and F2 may be the force at the other end of the rope (such as where the wire rope 140 is connected to the release mechanism 160 of the pressurizing control station 100 or 200). The coefficient of static or kinetic friction may be represented by usk. The angle B may be expressed in radians.

(92) As discussed above, there are a variety of ways by which the flexible conduit 220 (and the wire rope 140 inside the flexible conduit) may be attached to various structures in the fire suppression system. One example is depicted in FIGS. 18A-E. FIG. 18A depicts a perspective view of a PG9 cap 800. As discussed in more detail below, the PG9 cap 800 works in combination with compression fitting 810 and strain relief 820 to connect the flexible conduit 220 and the wire rope 140 to structures within the fire suppression system, such as junction boxes, valves, AUTOMAN panel, etc.

(93) The PG9 cap 800 includes a hole 802. As discussed in more detail below, the hole 802 may have a radius large enough to pass wire rope 140 through and a radius small enough so that the flexible conduit 220 cannot pass through. For example, the hole 802 may be sufficiently small so that the liner of the flexible conduit 220 (such as polyethylene liner 504 and acetal liner 320) cannot pass through. A further example may be where the hole 802 diameter is equivalent to the outer jacket diameter of the flexible conduit 502 and 310 to create an effective flexible conduit guide into the junction boxes 440 or 445 (as viewed in FIGS. 7B and 7D). Further, the PG9 cap 800 has an interior surface that includes threading 804. As discussed in more detail below, a portion of the strain relief 820 may connect to the threading 804.

(94) FIG. 18B depicts a perspective view of the compression fitting 810. The compression fitting 810 includes compression fitting cap 812 and compression fitting main body 814. The compression fitting main body 814 may be connected to a structure within the fire suppression system, such as junction box 120, using bolt 816.

(95) FIG. 18C depicts an exploded view of the compression fitting 810 and the PG9 cap 800. The PG9 cap 800 may be sandwiched in between the compression fitting cap 812 and the compression fitting main body 814. The compression fitting cap 812 may then be attached to the compression fitting main body 814, such as by screwing the compression fitting cap 812 onto the compression fitting main body 814 via threads 817 on the compression fitting main body 814 and threads on an interior surface of the compression fitting cap 812 (not shown). The outer diameter of the PG9 cap 800 may be less than the inner diameter of the compression fitting cap 812 so that the compression fitting cap 812 may slide onto the PG9 cap 800. Further, the outer diameter of the PG9 cap 800 may be less than or equal to the outer diameter of the compression fitting main body 814. In this way, when the compression fitting cap 812 is screwed onto the compression fitting main body 814, the PG9 cap 800 may be securely compressed in between.

(96) FIG. 18D depicts a perspective view of the strain relief 820. The strain relief 820 includes strain relief cap 822 and strain relief main body 824. The strain relief cap 822 includes a hole 826 by which the flexible conduit 220 may be attached. The strain relief main body 824 includes threading 828 for threading with the threads 804 of the PG9 cap 800. In this way, the strain relief 820 may be attached.

(97) FIG. 18E depicts a side view of the strain relief 820 and the compression fitting 810 prior to attachment of the strain relief 820. As shown, the flexible conduit may be attached to the strain relief 820. And, using PG9 cap 800, the wire rope 140 may be guided into the junction box 120.

(98) Considering Teflon to steel usk=0.04 (such as where the liner 320 is composed of Teflon and the wire rope 140 is composed of steel), F.sub.2=6 lbs and F.sub.1=40 lbs, then B=47.4 radians or 2717 degrees. Without a liner and/or lubricant, the coefficient of friction is higher, such as usk=0.15. Using the same forces of F.sub.2=6 lbs and F.sub.1=40 lbs, the B=12.6 radians or 724 degrees. Comparing these two examples illustrate the significant impact that a lower coefficient of friction has on the flexible conduit constraints. In the example using usk=0.04, the flexible conduit may be bent 30 times at right angles whereas the example using usk=0.15 (without the liner), the flexible conduit may be bent at the same angle only 8 times.

(99) The flexible conduit 220 in the fire suppression system may be easier to install than the EMT 130 and the 90 degree pulley elbows 150 shown in FIG. 1. Further, the flexible conduit 220 still provides a reliable system similar to the fire suppression system shown in FIG. 1. The flexible conduit system was cycled more than 8,000 times without signs of degradation. The system passed a 500 cycle test with 150 feet of lined and coated Bowden conduit, eight 90 degree bends with a 3 radius, 15 pulley elbows, a pull station with a built-in pulley block, and a 6 lb load at one end, the resulting force on the other end being 37.23 lbs on average with a standard deviation of 1.45 lbs. With a similar setup, except with a pull station having an ultrahigh molecular weight polyethylene (UHMW) busing and a three pound load, the resulting force was 30.83 pounds with a standard deviation of 1.25 lbs.

(100) As discussed above, the flexible conduit may be connected to the Ansul AUTOMAN panel, gas valve, corner pulleys, electrical box, EMT conduit, etc. For example, the flexible conduit may be connected between the Ansul AUTOMAN panel and the pull station, up to 140 ft and four 90 bends. When the flexible conduit is used to make 90 bends, these bends may start from the AUTOMAN panel or gas valve, with some or no mechanical 90 elbows being used in between these bends. If more than four 90 bends are used, then mechanical pulleys may be used. The flexible conduit may also be connected between the Ansul AUTOMAN panel and the gas valve, up to 75 ft and four 90 bends and four corner pulleys. The flexible conduit may be placed along the same path as the EMT conduit would normally be run. Stainless steel rope may be routed through the flexible conduit. The flexible conduit may be distanced from hood or other high temperature items by more than 6 inches. These examples are provided for illustration purposes only.

(101) Alternatively, instead of using wire rope 140 to connect the pull handle 416 to the release mechanism 160, other means may be used. For example, activation of the pull handle 416 may in turn activate a circuit (such as a switch) which could send a signal to a releasing mechanism. The signal may be an electrical signal transmitted via an electrical wire. Or, the signal may be a wireless signal, which may be transmitted via a transceiver and received at the release mechanism (such as the Ansul AUTOMAN panel, which may include a wireless receiver and/or transmitter).

(102) Moreover, instead of using wire rope 140, a fiber optic cable may be used. For example, the pull station may be connected between a first fiber optic cable and a second fiber optic cable. Specifically, a light source may be connected to the first fiber optic cable, sending a beam through the first fiber optic cable. A panel may be connected to the second fiber optic cable. In the event that the pull station is not activated, light traveling through the first fiber optic cable may be interrupted, indicating to the panel that the pull station has not been activated. In the event that the pull station is activated (such as by pulling the pull handle 416), light traveling through the first fiber optic cable may not be interrupted, indicating to the panel that the pull station has been activated.

(103) While various embodiments of the invention have been described, it will be apparent to those of ordinary skill in the art that many more embodiments and implementations are possible within the scope of the invention. Accordingly, the invention is not to be restricted except in light of the attached claims and their equivalents.