Related Application

[0001] This Patent claims the benefit of U.S. Patent Application Serial No. 12/228,174 filed August 11, 2008, which is hereby incorporated herein by reference in its entirety.

Field of the Disclosure

[0002] This patent generally pertains to ceiling fans and, more specifically, to ceiling fans mounted underneath an overhead fire sprinkler head.

Background

[0003] Ceiling mounted fans are often used for circulating air within large buildings such as warehouses, factories, gymnasiums, churches, auditoriums, convention centers, theaters, and other buildings with large open areas. For fire safety, a matrix of overhead sprinklers are usually installed to quench fires that might occur within the building. In the event of a fire, the fans preferably are disabled and the sprinklers are turned on.

[0004] To detect a fire and control the operation of the fans and sprinklers appropriately, various types of fire sensors are available. They usually operate by optical detection (photoelectric), chemical reaction (ionization), or heat detection (fusible link or infrared sensor for radiation).

[0005] Even though a ceiling fan can be de-energized during a fire, various air currents within the building or spray from a nearby sprinkler might keep the fan slowly rotating. Depending on the design of the fan, if the fan blades repeatedly pass underneath and/or come to stop underneath an activated sprinkler head, the fan blades might create interference with the water or other fire-suppressing media spraying from the sprinkler. Brief Description of the Drawings

[0006] Figure 1 is a side view of an example overhead fan system. [0007] Figure 2 is a bottom view of Figure 1.

[0008] Figure 3 is a bottom view similar to Figure 2 but with a certain area crosshatched. [0009] Figure 4 is a side view of another example overhead fan system. [0010] Figure 5A is a side view similar to Figure 4 but showing the fan blades retracted. [0011] Figure 5B is an alternative configuration showing the fan blades retracted. [0012] Figure 6 is a bottom view of another example overhead fan system. [0013] Figure 7 is a bottom view similar to Figure 6 but showing the fan blades retracted. [0014] Figure 8 is a side view of yet another example of an overhead fan system. [0015] Figure 9 is a side view similar to Figure 8 but showing the fan blades retracted. [0016] Figure 10 is a top view on an alternative configuration of an example overhead fan system. [0017] Figure 11 illustrates an example manner of implementing the controller of Figure 1.

Detailed Description

[0018] Certain examples are shown in the above-identified figures and described in detail below. In describing these examples, like or identical reference numbers are used to identify the same or similar elements. The figures are not necessarily to scale and certain features and certain views of the figures may be shown exaggerated in scale or in schematic for clarity and/or conciseness. Additionally, several examples have been described throughout this specification. Any features from any example may be included with, a replacement for, or otherwise combined with other features from other examples.

[0019] Figures 1 - 3 show an example of a ceiling fan system 10 comprising a ceiling fan 12 for circulating air and an overhead sprinkler 14 for extinguishing a fire. Fan 12 includes a motor 16 that rotates a plurality of fan blades 18 about an axis 20. Fan blades 18 are of a size and quantity that provides fan 12 with particularly low fan solidity so that, in the event of a fire, fan 12 poses a minimal obstruction to sprinkler 14. Sprinkler 14 is in proximity with fan 12, which means that fan 12 is sufficiently close to sprinkler 14 that fluid spray from sprinkler 14 could reach fan 12.

[0020] The term, "fire" used herein refers to any burning event or state of combustion including, but not limited to, an open flame and flameless smoldering. [0021] Upon sensing a characteristic associated with a fire, a sensor triggers the operation of sprinkler 14 so that sprinkler 14 sprays a fire-extinguishing fluid (e.g., water) from a supply line 22 onto the fire. Examples of a characteristic associated with a fire include, but are not limited to, heat, smoke, and light. In some examples, an optical or ionization detector senses smoke and activates a solenoid valve that supplies water to sprinkler 14. In another example, a fusible link on a valve portion of sprinkler 14 melts in the presence of heat to activate sprinkler 14. Sprinkler 14 is schematically illustrated to represent the aforementioned examples as well as other sprinkler-activating methods commonly known to those of ordinary skill in the art.

[0022] In addition to activating sprinkler 14 in the event of a fire, fan 12 preferably is de- energized or turned off automatically so as not to aerate the fire or significantly interfere with the spray pattern of sprinkler 14. To automatically turn off fan 12 in the presence of a fire, some examples of ceiling fan system 10 include a control system 24 responsive to a characteristic associated with the fire, wherein control system 24 is operatively connected in communication with sprinkler 14 and fan 12. In some examples, control system 24 includes a water flow sensor 26 in supply line 22, thereby connecting control system 24 in communication with sprinkler 14. When sprinkler 14 is open, sensor 26 provides a signal 28 upon sensing water flowing through supply line 22 to sprinkler 14. In this example, water flowing through supply line 22 is the characteristic associated with a fire. Control system 24 can relay or convey signal 28 to motor 16 to deactivate fan 12, thus control system 24 is connected in communication with fan 12 as well as with sprinkler 14 to coordinate the operation of both.

[0023] Even though fan 12 is turned off while sprinkler 14 is spraying water, to further minimize the fan's potential interference with the operation of sprinkler 14, fan 12 has particularly low fan solidity, as mentioned earlier. Fan solidity is defined herein as a solidity ratio times a diameter adjustment factor. Solidity ratio is defined as a cumulative blade projection area 30 obstructed by fan blades 18 (as viewed in a direction parallel to axis 20) divided by a total circular area 32 within an outer diameter 34 of fan 12. The cumulative blade projection area 30 is the crosshatched area of Figure 3. Outer diameter 34 is defined by a circular path 36 traced by a tip 38 of a distal end 40 of the longest fan blade 18 as fan blades 18 rotate about axis 20. Although sprinkler 14 is shown to be within outer diameter 34, sprinkler 14 could also be just beyond outer diameter 34 and still be considered in proximity with fan 12.

[0024] A fan with extremely long fan blades would naturally have a low solidity ratio, yet such a long-bladed fan would have an exceptionally large outer diameter, thereby still creating a large area of potential interference with a sprinkler, due to such a fan's "long reach." Thus, to account for the negative effect of a fan's overall outer diameter, the solidity ratio is multiplied by a diameter adjustment factor to determine the fan solidity. The diameter adjustment factor is defined herein as fan blade 18 outer diameter 34 divided by a fan blade inner diameter 41. The fan blade 18 inner diameter 41 is the diameter of a circular path 42 traced by a proximal end 44 of the longest fan blade 18 when fan 12 is turned on. Proximal end 44 and distal end 40 are at opposite ends of fan blade 18. Proximal end 44 is where the airfoil portion of the fan blade 18 terminates, thus proximal end 44 is not part of a mechanical coupling 46 that connects fan blade 18 to a rotor shaft 48 of motor 16. [0025] For ample fan airflow with minimal obstruction to sprinkler 14, fan 12 has a fan solidity of less than 0.7 and preferably between 0.4 and 0.6. This can be achieved with a two- blade fan with a solidity ratio of less than 0.2 and a diameter adjustment factor of 2 to 20. Fan solidity, solidity ratio and the diameter adjustment factor are each dimensionless values. [0026] Ample airflow and minimal obstruction to sprinkler 14 can also be achieved with a fan that automatically retracts its fan blades when the fan turns off. Figures 4 and 5A, for example, show a ceiling fan 50 with retractable fan blades 52. Each fan blade 52 is comprised of a distal end 52a pivotally coupled to a proximal end 52b by way of a hinge 54. The hinge 54 is, thus, located at a central location along the length of the fan blade (e.g., near a midpoint of the blade). When fan 50 is turned off, distal end 52a hangs pendant at a first radial distance 56 from the motor's rotational axis 20. When fan 50 turns on, centrifugal and aerodynamic forces urge distal end 52a up and outward to a second radial distance 58 from axis 20.

[0027] If sprinkler 14 is at an intermediate radial distance 60 between the points defined by radial distances 56 and 58, and fan 50 turns off when sprinkler 14 operates, then fan 50 being off provides minimal if any obstruction to sprinkler 14, since distal end 52a is substantially clear of and avoids sprinkler 14 when distal end 52a is hanging pendant. Coordinating the operation of sprinkler 14 and fan 50, e.g., automatically turning fan 50 off when sprinkler 14 operates, can be achieved in the same manner as described with reference to ceiling fan system 10 of Figures 1 - 3. The fan blades could alternatively hand pendant from their inner portions (i.e., the entire blade could hang pendant and the hinges could be eliminated). The example of FIG. 5 A is advantageous over such an approach, however, in that only a distal portion of the blades hang pendant, thus, keeping the lowest portion of the fan blades at a higher position (and creating more head room) when in the pendant position than an approach that omits the hinged blade and instead pivots the entire blade to a pendant position). [0028] Although distal ends 52a swing downward upon de-energizing fan 50 in Figure 5A, in the example ceiling fan system 500 of Figure 5B, the distal ends 502 are hinged so as to swing upward. Specifically, the fan 504 is provided with a plurality of biasing elements 506 to urge distal ends 502 upward when the fan 504 turns off. Examples of such upward biasing elements include, but are not limited to, a spring or counterweight that urges the corresponding distal end 502 upward.

[0029] In another example, shown in Figures 6 and 7, a ceiling fan 62 includes a plurality of fan blades 64, wherein each fan blade 64 is comprised of a distal end 64a pivotally connected to a proximal end 64b by way of a hinge 66. In this example, hinge 66 allows distal end 64a to retract by pivoting generally horizontally toward axis 20. When fan 62 turns off, a tension spring 68 (e.g., an elastic cord) and/or rotational deceleration of distal end 64a urges distal end 64a to the retracted position of Figure 7. When fan 62 turns on and begins rotating in the direction indicated by arrow 70, centrifugal force, rotational acceleration and aerodynamic forces overcome the force of spring 68 to urge distal end 64a back out to its extended position of Figure 6. Thus, fan blades 64 are fully extended and operational underneath sprinkler 14 when fan 62 is turned on, and fan blades 64 are clear of and purposely avoid sprinkler 14 when fan 62 is turned off.

[0030] In yet another example, shown in Figures 8 and 9, a ceiling fan 72 includes a plurality of fan blades 74, wherein each fan blade 74 is comprised of a distal end 74a telescopically connected to a proximal end 74b. The telescopic connection between ends 74a and 74b allow distal end 74a to retract by sliding into a hollow interior of proximal end 74b. When fan 72 turns off, a tension spring 76 draws distal end 74a into proximal end 74b so that distal end 74a moves from an extended position (Figure 8) to a retracted position (Figure 9). When fan 72 turns on, centrifugal force overcomes the force of spring 76 to urge distal end 74a from its retracted position of Figure 9 to its extended position of Figure 8. Thus, fan blades 74 are fully extended and operational underneath sprinkler 14 when fan 72 is turned on, and fan blades 74 are clear of and avoid sprinkler 14 when fan 72 is turned off. [0031] Having fan blades comprised of a distal end coupled to a proximal end, as shown in Figures 4 - 9, can provide a significant benefit to the manufacturer and/or supplier of such fans. Such fans can be offered to end users as a standard base unit with fan blades each having a common proximal end to which distal ends of various length can be added selectively to create various diameter fans. A base unit fan, for instance, could be an 8-foot diameter fan with 3 -foot long proximal end fan blades (i.e., 8-foot outer diameter and 2-foot inner diameter). To such a base unit, 3 -foot long distal ends can be added to create a 14-foot diameter fan, or 5-foot long distal ends could instead be added to create an 18-foot diameter fan using the same 8-foot diameter base unit. In the case where no additional distal end is added to the standard 8-foot diameter base unit, then the outer tip of the proximal end is considered the distal end of an 8-foot diameter fan.

[0032] Figure 10 depicts an alternative ceiling fan system 1000 that includes a fan 1002 having a plurality of fan blades 1004 that are disposed in a rest position (e.g., a position in which the fan blades 1004 are not rotating in a circular path 1006 about an axis 1008). Specifically, in the illustrated example, the fan blades 1004 are rotationally coupled to a mechanical coupling 1012 that enables the fan blades 1004 to rotate about their longitudinal axes toward a non-use position in which the fan blades 1004 are oriented at substantially 90 degrees to a horizontal plane (e.g., the ground surface) when the fan 1002 is turned off. In particular, the fan 1002 may be provided with a plurality of biasing elements 1014. Each of the biasing elements 1014 is assigned to a corresponding one of the fan blades 1004. Each biasing element 1014 urges its corresponding fan blade 1004 to rotate about a longitudinal axis 1016 of the fan blade 1004 toward the non-use position when the fan 1002 is turned off. Positioning the fan blades 1004 in this non-use position ensures that the major surface of each fan blade 1004 is disposed in a generally vertical plane and the edge of each fan blade 1004 is pointed upward to purposely decrease the cross-sectional area of the fan blades 1004 presented between the sprinkler 1018 and a ground surface, thereby reducing interference with sprinkler 1018 operation. When the fan 1002 is turned on, centrifugal and aerodynamic forces over come the force from the plurality of biasing elements 1014 and urge the fan blades 1004 into the use position (e.g., in a substantially horizontal plane 1010 which is substantially parallel to a ground surface). In the above example, it is assumed that the fan 1002 is mounted such that the fan blades 1004 are intended to rotate in a generally horizontal plane parallel to, for example a floor. In some instances, a pitch of the fan blade 1004 may change over a length of the fan blade 1004 (e.g., there may be inconsistencies in the shape of the fan blade 1004 and/or the fan blade 1004 might not be flat relative to the ground). In examples where the fan 1002 is mounted at an angle, the principle of operation would be the same (i.e., the fan blades 1004 would rotate about their longitudinal axes to reduce interference with overhead sprinklers 1018, but the plane of operation of the fan blades 1004 might not be parallel to the ground).

[0033] Figure 11 is a block diagram of an example processor system 1100 that may be used to implement the example control system 24 of Figure 1. As shown in Figure 11, the processor system 1100 includes a processor 1102 that is coupled to an interconnection bus 1104. The processor 1102 may be any suitable processor, processing unit or microprocessor. Although not shown in Figure 11, the processor system 1100 may be a multi-processor system and, thus, may include one or more additional processors that are identical or similar to the processor 1102 and that are communicatively coupled to the interconnection bus 1104.

[0034] The processor 1102 of Figure 11 is coupled to a chipset 1106, which includes a memory controller 1108 and an input/output (VO) controller 1110. The chipset provides I/O and memory management functions as well as a plurality of general purpose and/or special purpose registers, timers, etc. that are accessible or used by one or more processors 1102 coupled to the chipset 1106. The memory controller 1108 performs functions that enable the processor 1102 (or processors if there are multiple processors) to access a system memory 1112 and a mass storage memory 1114, if present.

[0035] The system memory 1112 may include any desired type of volatile and/or nonvolatile memory such as, for example, static random access memory (SRAM), dynamic random access memory (DRAM), flash memory, read-only memory (ROM), etc. The mass storage memory 1114 may include any desired type of mass storage device including hard disk drives, optical drives, tape storage devices, etc.

[0036] The I/O controller 1110 performs functions that enable the processor 1102 to communicate with peripheral input/output (VO) devices 1116 and 1118 and a network interface 1120 via an I/O bus 1122. The VO devices 1116 and 1118 may be any desired type of VO device such as, for example, a keyboard, a video display or monitor, a mouse, etc. The network interface 1120 may be, for example, an Ethernet device, an asynchronous transfer mode (ATM) device, an 802.11 device, a DSL modem, a cable modem, a cellular modem, etc. that enables the processor system 1100 to communicate with another processor system.

[0037] While the memory controller 1108 and the VO controller 1110 are depicted in Figure 11 as separate functional blocks within the chipset 1106, the functions performed by these blocks may be integrated within a single semiconductor circuit or may be implemented using two or more separate integrated circuits.

[0038] At least some of the aforementioned examples include one or more features and/or benefits including, but not limited to, the following:

[0039] In some examples, a ceiling fan minimizes interference with an overhead sprinkler head by virtue of the ceiling fan having a particularly low solidity ratio. [0040] In some examples, a ceiling fan minimizes interference with an overhead sprinkler head by virtue of the ceiling fan having a particularly low fan solidity (solidity ratio times a diameter adjustment factor).

[0041] In some examples, a ceiling fan minimizes interference with an overhead sprinkler head by virtue of the ceiling fan having only two fan blades.

[0042] In some examples, a ceiling fan minimizes interference with an overhead sprinkler head by having the fan blades automatically retract in the event of a fire.

[0043] In some examples, a ceiling fan minimizes interference with an overhead sprinkler head by having the fan blades automatically retract in coordination with the activation of the sprinkler head.

[0044] In some examples, the fan blades of a ceiling fan sweep a circular path underneath an overhead sprinkler head when the fan is turned on and the sprinkler is off, and the fan blades automatically retract out from underneath the sprinkler head when the fan turns off and the sprinkler is on.

[0045] In some examples, a ceiling fan is comprised of a standard base unit with fan blades each having a common proximal end to which distal ends of various length can be added selectively to create various diameter fans.

[0046] Although certain example methods, apparatus and articles of manufacture have been described herein, the scope of the coverage of this patent is not limited thereto. On the contrary, this patent covers all methods, apparatus and articles of manufacture fairly falling within the scope of the appended claims either literally or under the doctrine of equivalents.