US20110109454A1

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Publication number: US20110109454A1
Application number: US13/008,078
Authority: US
Inventors: John J. McSheffrey, Sr.; John J. McSheffrey, Jr.; Brendan T. McSheffrey
Original assignee: EN-GAUGE Inc
Current assignee: EN-GAUGE Inc
Priority date: 1996-01-23
Filing date: 2011-01-18
Publication date: 2011-05-12
Also published as: CA2532041A1; GB0602555D0; WO2005013227A1; CA2532041C; GB2419719B; GB2419719A; US20040065451A1; US7891435B2

Abstract

An Apparatus for remote inspection of emergency equipment at one or a system of emergency equipment stations includes, e.g., at each emergency equipment station: a detector for detection of the presence of an obstruction to viewing of or access to the emergency equipment station; and an electronic circuit in communication between the detector and a remote central station for issue of a signal to the remote central station upon detection of the obstruction to viewing of or access to the emergency equipment station.

Description

This application is a continuation of U.S. application Ser. No. 10/614,948 filed Jul. 8, 2003 which is a continuation-in-part of U.S. application Ser. No. 10/274,606, filed Oct. 21, 2002, now U.S. Pat. No. 7,188,679 issued Mar. 13, 2007, which is a continuation-in-part of U.S. application Ser. No. 09/832,531, filed Apr. 11, 2001, now U.S. Pat. No. 6,585,055, issued Jul. 1, 2003, which is a continuation-in-part of U.S. application Ser. No. 09/212,121, filed Dec. 15, 1998, now U.S. Pat. No. 6,302,218, issued Oct. 16, 2001, which is a continuation of U.S. application Ser. No. 08/879,445, filed Jun. 20, 1997, now U.S. Pat. No. 5,848,651, issued Dec. 15, 1998, which is a continuation-in-part of U.S. application Ser. No. 08/590,411, filed Jan. 23, 1996, now U.S. Pat. No. 5,775,430, issued Jul. 7, 1998, and a continuation-in-part of International Application No. PCT/US97/01025, with an International Filing Date of Jan. 23, 1997, now abandoned, the complete disclosures of all of which are incorporated herein by reference.

TECHNICAL FIELD

This invention relates to remote inspection of emergency equipment stations, and, more particularly, to remote inspection of fire extinguisher stations, fire alarm pull stations, emergency lighting stations, defibrillator stations, emergency egress stations, and other similar emergency equipment located at one or a system of emergency equipment stations.

BACKGROUND

Portable fire extinguishers are stationed for use in case of a fire in all manner of environments. Typically, the fire extinguishers are placed in standby condition at a system of fire extinguisher stations found throughout a facility at locations selected for reasonably easy access in a fire emergency. Standards and procedures for periodic inspection of fire extinguishers at fire extinguisher stations are set forth by the National Fire Protection Association (NFPA) in “NFPA 10 Standard for Portable Fire Extinguishers” (1998 Edition), the complete disclosure of which is incorporated herein by reference. In its relevant portion 25 (§4-3:2), NFPA 10 sets forth the elements of the inspection of fire extinguishers and fire extinguisher stations required to take place at regular intervals, e.g., approximately every thirty days, as follows:

4-3.2 Procedures Periodic inspection of fire extinguishers shall include a check of at least the following items:

- (a) Location in designated place
- (b) No obstruction to access or visibility
- (c) Operating instructions on nameplate legible and facing outward
- (d) Safety seals and tamper indicators not broken or missing
- (e) Fullness determined by weighing or “hefting”
- (f) Examination for obvious physical damage, corrosion, leakage, or clogged nozzle
- (g) Pressure gauge reading or indicator in the operable range or position
- (h) Condition of tires, wheels, carriage, hose, and nozzle checked (for wheeled units)
- (i) HMIS [“hazardous materials identification system”] label in place

Typically, these inspections are performed manually, and inspection of fire extinguishers at a system of fire extinguisher stations located throughout a facility, e.g., such as a manufacturing plant or an office complex, or throughout an institution, e.g., such as a school campus or a hospital, may occupy one or more employees on a full time basis. Procedures for more frequent inspections are generally considered cost prohibitive, even where it is recognized that a problem of numbers of missing or non-functioning fire extinguishers may not be addressed for days or even weeks at a time, even where manpower may otherwise be available.

SUMMARY

According to one aspect of the invention, an apparatus for remote inspection of emergency equipment in installed positions at one or a system of emergency equipment stations comprises: a detector located at a emergency equipment station for detection of the presence of an obstruction to viewing of or access to the emergency equipment station; and an electronic circuit in communication between the detector and a remote central station for issue of a signal to the remote central station upon detection of the obstruction to viewing of or access to the emergency equipment station.

The invention thus provides an apparatus for remote inspection of emergency equipment stations such as fire extinguisher stations, fire alarm pull stations, defibrillator stations, emergency lighting stations, etc., permitting at least more frequent, and, if desired, continuous, monitoring and inspection of the emergency equipment located at the emergency equipment stations. By remotely inspecting and/or monitoring the emergency equipment stations, the frequency with which safety personnel must physically inspect each station is markedly reduced, which correspondingly reduces inspection time and cost. Furthermore, by monitoring for obstructions to the visibility of and access to the emergency equipment stations, safety personnel are alerted to the potential hazard that an employee or passerby might be unable to locate, or to gain access to, the emergency equipment station during an emergency such as a fire or other life-threatening event.

The details of one or more embodiments of the invention are set forth in the accompanying drawings and the description below. Other features, objects, and advantages of the invention will be apparent from the description and drawings, and from the claims.

DESCRIPTION OF DRAWINGS

FIG. 1 is a somewhat diagrammatic view of an apparatus of the invention for remote inspection of fire extinguishers at a system of fire extinguisher stations.

FIG. 2 is a perspective view of a fire extinguisher mounted at a fire extinguisher station for remote inspection according to the invention.

FIG. 3 is a perspective view of a fire extinguisher mounted at another fire extinguisher station for remote inspection according to the invention.

FIG. 4 is a block diagram of the electronics and communications circuit for one embodiment of a remote inspection apparatus of the invention that are depicted inFIGS. 4aand4b.

FIG. 5 is a perspective view of elements of another embodiment of the apparatus of the invention for remote inspection of a fire extinguisher station with components of a docking station mounted to the fire extinguisher for communication with a remote central station by wireless signal.

FIG. 6 is a perspective view of a fire alarm pull station for remote inspection according to the invention.

FIG. 7 is a perspective view of another embodiment of a fire alarm pull station for remote inspection according to the invention.

FIG. 8. is a perspective view of a defibrillator mounted at a defibrillator station for remote inspection according to the invention.

FIG. 9 is a perspective view of an emergency lighting station for remote inspection according to the invention.

FIG. 10 is a perspective view of an emergency egress station for remote inspection according to the invention.

FIG. 11 is a somewhat diagrammatic view of an apparatus of the invention for remote inspection of emergency equipment stations distributed throughout a facility.

Like reference symbols in the various drawings indicate like elements.

DETAILED DESCRIPTION

Referring toFIG. 1, in one embodiment, anapparatus10 of the invention for remote inspection ofportable fire extinguishers12 installed at one or asystem14 offire extinguisher stations16 includesmeans18 for detecting lack of presence of afire extinguisher12 in its installed position at afire extinguisher station16, means20 for detecting out-of-range pressure of the contents of afire extinguisher12 at afire extinguisher station16, means22 for detecting an obstruction to viewing of or access to afire extinguisher station16, and means24 for transmission of inspection report information for each of thefire extinguisher stations16 to a remotecentral station26. Theapparatus10 may further include means28 for maintaining a record of inspection report information.

As an example of aremote inspection apparatus10 of the invention, inFIG. 2, aportable fire extinguisher12 is shown mounted to a wall, post, or other support surface, W, at afire extinguisher station16 in a system offire extinguisher stations14, and inFIG. 3, anotherportable fire extinguisher12 is shown mounted within a wall box or cabinet, C, at anotherfire extinguisher station16 in the system offire extinguisher stations14. In this embodiment, thefire extinguisher12 at eachfire extinguisher station16 is releasably connected to adocking station30 by an electronics andcommunications tether32 to provide a releasable engagement for electronics and/or communications connection between thedocking station30 and the portable fire extinguisher(s)12 at each of thefire extinguisher stations16. Typically signals issued from or to thefire extinguisher12 are transmitted over the electronics andcommunication tether32. For example, a signal, initiated by one or more Hall Effect sensors included in thefire extinguisher12, which is indicative of out-of-range (low or high) pressure of the fire extinguishing material contained within the tank volume, is transmitted from thefire extinguisher12 across thetether32 to thedocking station30 and then to the remotecentral station26.

In the embodiment shown inFIG. 2, thedocking station30 is fixedly mounted to the wall, W, at a predetermined position spaced generally above thefire extinguisher12. Thedocking station30 consists of ahousing88 containing a sonar module90 (shown inFIG. 4b) and defining spaced apertures orwindows92 through which themodule90 emits and receives ultrasonic signals. In the embodiment ofFIG. 3, where thedocking station30 is disposed with a wall cabinet, C, thesonar module90 is connected, e.g., bycable110, to apertures orwindows112 in the outer surface of thecabinet door114 for emitting and receiving the ultrasonic signals. Also, disposed within thedocking station housing88 is an electronic andcommunications circuit94, as described more fully below with reference toFIG. 4. Extending generally from the base of thedocketing station housing88 is the electronics andcommunications tether32 received by a connector in communication with a value that monitors the internal content pressure of the fire extinguisher. The length of thetether32, and the tenacity of engagement of the connection between the connector and the tether, are preferably selected so that any significant movement of thefire extinguisher12 relative to its installed position, i.e., the position in which it is placed at installation by a fire extinguisher professional, whether removal, or, in a preferred embodiment, merely upon rotation with movement in excess of a predetermined threshold value, will result in dislodgement of thetether32 from the connector, initiating a signal to the remotecentral station26, as discussed more fully below. Thedocking station30 may be powered by alternating current, e.g., by a hardwire connection into a facility's electrical supply, or it may be powered by direct current, e.g., by a battery within thedocking station housing88. If powered by alternating current, an auxiliary power supply, e.g., in the form of a battery, may be provided in case of power outage.

Referring now toFIG. 4, theremote inspection apparatus10 includes an electronics andcommunications circuit94, e.g., disposed primarily within thedocking station30, for initiating signals to the remotecentral station26 upon detection of predetermined internal and/or predetermined external conditions. For example, referring again toFIG. 1, in the preferred embodiment, thecircuit94 issues a signal100 or a signal102 upon detection of a predetermined external condition, e.g., lack of presence of thefire extinguisher12 at its installed position at thefire extinguisher station16, when thefire extinguisher12 is removed from, or moved within, the fire extinguisher station, thereby disengaging thetether32 from the connection with thefire extinguisher12, and disrupting the closed connection80 (signal100), or an obstruction to viewing of or access to a fire extinguisher station16 (signal102). Thecircuit94 also issues a signal104 upon detection of a predetermined internal condition, e.g., existence of an out-of-range, e.g., low, pressure condition of the fire extinguishing material contained within the tank of thefire extinguisher12.

According to one embodiment, the signals100,104 are communicated via an electronics andcommunications connection80 of amale connector element58 of thetether32 with afemale socket56 of thefire extinguisher12 to electronics andcommunications circuit94 withindocking station30. The signal100 indicating lack of presence of thefire extinguisher12 in its installed position at thefire extinguisher station16 and signal104 indicating that pressure of the fire extinguishing material in the tank of thefire extinguisher12 is below a predetermined minimum pressure level, e.g., indicative of a discharge, leak or other malfunction (or, in an embodiment with a pair of Hall Effect sensors74,75, above a predetermined maximum pressure level) are received by a connection and termination stripprocess control board116 and transmitted viahardwire connection118 to the remotecentral station26. In this embodiment, thetether32 includes a two wire connection in normally closed state, signaling the presence of thefire extinguisher12, and a two wire connection in normally open state that signals that pressure in the fire extinguisher tank is above the predetermined minimum level. The signals are received and transmitted over thehardwire connection118. However, it is contemplated that, in other embodiments, signals100,102,104 may be communicated, e.g., via radio frequency (RF), or other, wireless communication circuitry via antenna120 (FIG. 1) to an RF monitoring system receiver, e.g., at the remotecentral station26, or simultaneously, via both hardwire and wireless, to a remotecentral station26, or other monitoring station. As mentioned above, it is also contemplated that theremote inspection apparatus10 may be powered by alternating current, e.g., by a hardwire connection to the facility electric supply system or by direct current, e.g. by battery, or by both, with the battery provided as auxiliary power in case the primary electrical service is disrupted.

Referring toFIG. 5, in another embodiment, components ofdocking station30, as described above, may instead be mounted to thefire extinguisher12, e.g., within ahousing130, thereby allowing the fire extinguisher to be located, if desired, without wall mounting or enclosure. In the embodiment shown,housing130 contains thesonar module90 and defines the apertures orwindows92 for detecting obstructions as previously mentioned. Electronic andcommunications circuitry94 is also disposed within thehousing130, for communication of signals, e.g., wireless signals, between thefire extinguisher station16 and the remotecentral station26.

An electronics andcommunication tether132 may extend between connections to thehousing130 and thefire extinguisher12, as indicated in dashed line, e.g., engaged through an aperture of an I-bolt33 anchored into a wall W, such that any significant movement of thefire extinguisher12 relative to its position at rest, in excess of a predetermined threshold value, results in disengagement of thetether132 from connection with theextinguisher12, thereby to initiate a wireless signal to the remote central station26 (FIG. 1). In another embodiment (not shown), a tether or leash, e.g. in the form of a cord, wire, rope or the like, may extend from a first end secured, e.g., to a wall, to engagement of its second end in a socket defined, e.g., by thehousing130, whereby dislodgement of the tether or leash from the socket initiates a wireless signal.

Wireless communication circuitry and antenna120 (FIG. 1) are located within thehousing130 to communicate by wireless signal between thefire extinguisher12 and the previously mentioned RF monitoring system receiver, e.g., at the remotecentral station26. Signals100,102 are communicated by wireless signal between the remote central station26 (FIG. 1) and thefire extinguisher station16 upon detecting the previously mentioned predetermined external conditions. Signals, such as signal104, are also communicated by wireless signal upon detection of the previously mentioned predetermined internal conditions. In this manner, a system of fire extinguishers, distributed over a considerable area, are maintained in wireless communication with the remotecentral station26.

Along with remote inspection of one or a system of fire extinguisher stations, in another embodiment, theapparatus10 of the invention is used for remote inspection of other emergency equipment installed at one or a system of emergency equipment stations. Referring toFIG. 6, in another embodiment, components ofdocking station30, as described above, may instead be included in ahousing140 that is shown mounted to a wall, post, or other support surface, W, and receives a firealarm pull station142 such that the pull station is positioned on an appropriate location of the support surface, W, for reasonable access. By including the components of thedocking station30 in thehousing140, the firealarm pull station142 is capable of remote inspection similar to thefire extinguisher station16. In the embodiment shown,housing140 contains thesonar module90 and defines the apertures orwindows92 for emitting and receiving ultrasonic signals to detect one or more objects that obstruct viewing of and access to the firealarm pull station142. Additionally, in some embodiments thehousing140 and the fire alarm pull station are in communication for signal transmission and reception. For example, if the firealarm pull station142 is pulled by a passerby in the event of an emergency to sound a fire alarm, a signal is issued by the pull station and passed to thehousing140 for transmission to the remotecentral station26. The firealarm pull station142 may also initiate other signals based on other internal conditions associated within the pull station. For example, a signal may be initiated if a battery included in the firealarm pull station142 needs to be replaced or recharged.

Along with transmitting internal conditions (e.g., battery replacement or recharging, etc.) and external conditions (e.g., detection of an obstruction, etc.) associated with the firealarm pull station142, in some embodiments thehousing140 or the fire alarm pull station provide local indications that the pull station has been operated in the event of an emergency. For example, thehousing140 can include or be in communication with an audible signaling device (e.g., a speaker) for emitting an audible tone or signal (e.g., verbal commands) to alert people in the local vicinity to a detected obstruction of the pull station or other external condition such as the operation of the pull station by a passerby due to a fire. The audible signal may also consist of a recorded information message, e.g., instructions for evacuation or for assisting personnel located near the firealarm pull station142. Also, thehousing140 may include one or more alert lights, strobes, or other similar lighting devices that are driven by circuitry included in thehousing140 such that the alert lights illuminate, flash, or strobe for visually alerting personnel in the vicinity that access to and view of the firealarm pull station142 is obstructed, or that the pull station has been actuated.

Referring toFIG. 7, in another embodiment, components ofdocking station30, as described above, are included within a firealarm pull station146, rather than in a housing that receives the pull station as shown inFIG. 6. In the embodiment ofFIG. 7, the firealarm pull station146 includes thesonar module90 and defines the apertures orwindows92 for emitting and receiving ultrasonic signals for detecting obstructions a ranges e.g., from about 6 inches to about 10 feet dependent upon the environment as previously mentioned. By including thesonar module90 along with the electronic andcommunication circuitry94 within the firealarm pull station146, the pull station is capable of being located on a wall, post, or other support surface, W, that may provide a relatively smaller area for securing the pull station that may be ill-suited for supporting thelarger housing140 shown inFIG. 6.

Referring toFIG. 8, in another embodiment, components ofdocking station30, as described above, are included within adefibrillator station150 that includes one or more mechanical fasteners151 (e.g., a clips, fastening material, etc.) along with a recess for holding adefibrillator152. Typically, thedefibrillator station150 is mounted to a wall, post, or other support surface, W, so that thedefibrillator152 is accessible by trained personnel or the general public for use during an emergency such as a person suffering from sudden cardiac arrest or other life-threatening aliment. By distributing a system of defibrillator stations, for example, throughout an airport, shopping center, or other facility accessible by the public, in the event of an emergency a defibrillator can be removed from a relatively nearby defibrillator station to provide assistance.

Thedefibrillator station150 contains the electronic andcommunications circuitry94 along withsonar module90 and the apertures orwindows92 for emitting and receiving ultrasonic signals to detect obstructions as previously mentioned. By including thesonar module90 within thedefibrillator station150, obstructions to the visibility and the accessibility of the defibrillator station are detectable and upon such detection a signal is issued by the electronic andcommunications circuitry94 for transmitting to the remotecentral station26 to provide an alert regarding the obstruction. In this embodiment the signal is transmitted from the electronic andcommunication circuitry94 to aconnection terminal154 and then to ahardwire connection118 that is in communication with the remotecentral station26. Alternatively, the signal indicating the obstruction can be transmitted in a wireless signal to the remotecentral station26 from anantenna120 included on the defibrillator station. Additionally in some embodiments, similar to the fire extinguisher station16 (shown inFIG. 2), a signal that indicates one or more internal conditions of thedefibrillator152 and/or thedefibrillator station150 are transmitted to the remotecentral station26. For example, if thedefibrillator152 is removed from the defibrillator station150 (e.g., in the event of an emergency), or if an internal battery needs attention (e.g., replacing, recharging, etc.), or if another similar or previously mentioned predetermined internal condition occurs, a signal is transmitted in a signal to the remotecentral station26 over thehardwire connection118 and/or in a wireless signal from theantenna120.

Along with providing a signal to the remotecentral station26 indicating internal and/or external conditions of thedefibrillator152 and/or thedefibrillator station150, in some embodiments the defibrillator station includes an audible signaling device (e.g., a speaker) that issues an audible tone, signal, or message for alerting personnel and/or the general public to one or more of the predetermined internal and external conditions. For example, if thedefibrillator station150 is obstructed, or if thedefibrillator152 is removed from the defibrillator station, an audible tone may be emitted by the audible signaling device. Also, thedefibrillator station150 may include one or more alert lights, strobes, or other similar lighting devices for similarly alerting personnel and/or the general public to the one or more of the predetermined internal or external conditions associated with the defibrillator station or thedefibrillator152.

Referring toFIG. 9, in another embodiment, components ofdocking station30, as described above, are included in anemergency lighting station156 that provides, e.g., a pair ofemergency lights158 that provide illumination in the event of an emergency (e.g., a fire, a power outage, etc.). In some embodiments, activation of theemergency lights158 is controlled remotely, e.g., from the remotecentral station26, or controlled locally by circuitry and sensors (e.g., a smoke detector) included in theemergency lighting station156 or positioned in a nearby location (e.g., mounted in a ceiling). Typically, theemergency lighting station156 is mounted to a wall, post, or other support surface (e.g., a ceiling, doorway, etc.), W, for illuminating the local area during an emergency. In some embodiments, a system of emergency lighting stations are distributed throughout a commercial, industrial, educational, or other similar type of facility to provide emergency lighting. Additionally, in this embodiment, theemergency lighting station156 includes an “EMERGENCY EXIT” signal, which may or may not illuminate while directing people to an appropriate egress point (e.g., doorway) during an emergency.

The signal sent from theemergency lighting station156 alerts the remotecentral station26 to one or more predetermined external conditions associated with the station such as an obstruction detected by the sonar module through the apertures orwindows92. The signal may also alert the remotecentral station26 to predetermined internal conditions associated with thestation156 such as if a battery back-up needs replacing or recharging, or if one of theemergency lights158 need to be replaced. Additionally, theemergency lighting station156 may include an audible signaling device (e.g., a speaker) for emitting an audible tone, signal, or message to alert facility personnel and/or the general public in the vicinity that the station is currently obstructed or another predetermined internal or external condition has occurred. Also, theemergency lighting station156 may include one or more alert lights, strobes, or other similar lighting devices, in addition to theemergency lights158, for emitting a visual alert to indicate, e.g., the emergency lighting station is obstructed.

Referring toFIG. 10, in another embodiment, components ofdocking station30, as described above, are included in anemergency egress station162 that includes ahousing164 that is in communication with, e.g., astrobe166 that provides illumination in the event of an emergency (e.g., a fire, a power outage, etc.). In some embodiments, activation of thestrobe166 is controlled remotely, e.g., from the remotecentral station26, or controlled locally by circuitry and sensors (e.g., a smoke detector) included in theemergency egress station162 or positioned in a nearby location (e.g., mounted in a ceiling). Typically, theemergency egress station162 is mounted to a wall, post, or other support surface (e.g., a ceiling, doorway, etc.), W, for illuminating the local area during an emergency. Furthermore, in some embodiments theemergency egress station162 is mounted on the support surface approximately slightly above floor level, such that a person crawling along the floor in the event of an emergency (e.g., fire) can detect the illuminating strobe to be directed to an appropriate egress point such as an emergency exit doorway.

The signal sent from theemergency egress station162 alerts the remotecentral station26 to one or more predetermined external conditions associated with the station such as an obstruction detected by the sonar module through the apertures orwindows92. The signal may also alert the remotecentral station26 to predetermined internal conditions associated with thestation162 such as if a battery needs replacing or recharging, or if thestrobe166 needs to be replaced. Additionally, theemergency egress station162 may include an audible signaling device (e.g., a speaker) for emitting an audible tone, signal, or message to alert facility personnel and/or the general public in the vicinity that the station is currently obstructed or another predetermined internal or external condition has occurred. Also, theemergency egress station162 may include one or more additional strobes, or other similar lighting devices, for emitting a visual alert to indicate, e.g., theemergency egress station162 is obstructed or in the event of an emergency as provided by a signal received on thehardwire connection118 or theantenna120.

In this particular embodiment thehousing164 includes a terminal170 that connects ahardwire172 between thehousing164 and thestrobe166 so that the strobe is activated by a signal from the housing. Alternatively,antenna120, or another antenna included in thehousing164, can establish a wireless link between the housing and thestrobe166 such that a wireless signal transmitted from the housing activates the strobe. Also, in some embodiments, thestrobe166 is activated by a signal initiated by another signal received by thehousing164. For example, in some embodiments thehousing164 is in communication with emergency equipment such as a fire alarm pull station, a defibrillator, a smoke detector, or other emergency equipment that provides a signal to activate thestrobe166 in the event of an emergency.

Referring toFIG. 11, in another embodiment, anapparatus174 of the invention for remote inspection of emergency equipment includes means for monitoring the visibility and accessibility of emergency equipment stations distributed throughout locations (e.g., rooms, hallways, etc.) associated with a healthcare facility (e.g., a hospital, assisted living facility, a nursing home, etc.), a commercial facility (e.g., a shopping mall, restaurant, dance club, gymnasium, etc.), an educational institution (e.g., a college campus, dormitory, etc.), a residence (e.g., a residential home, residential development, apartment complex, condominium complex, etc.), or other facility (e.g., an airport, train station, bus station, etc.). In this particular example, emergency equipment stations are distributed throughout two

rooms

176,178 for assisting people in the event of an emergency. For example,room176 includes a wall-mounteddefibrillator station180 that includes a detachable defibrillator for use during a life-threatening event such as a sudden cardiac arrest.Room176 also includes anemergency lighting station182 and anemergency egress station184 that provides lighting to assist egress in the event of an emergency such as fire, a power outage, etc.Room178 includes a firealarm pull station186 for initiating a signal to alert the appropriate personnel (e.g., a fire department, facility management, etc.) along with other people (e.g., the general public) to an emergency such as a fire. In this embodiment ahousing188 is in communication with the firealarm pull station186, and includes a sonar module and apertures rather than the pull station.Room178 also includes anemergency lighting station190 and anemergency egress station192 for assisting egress from the room during times of emergency.

Each of the

emergency equipment stations

emergency lighting stations

182 and190 respectively include sonar modules for detecting obstructions to operation of or accessibility to the stations. Here, when an obstruction is detected by theemergency lighting station182, a signal is transmitted through ahardwire connection204 that is in communication with the remotecentral station202. However, whenemergency lighting station190 detects an obstruction, awireless signal206 is transmitted to thehousing188 that includes circuitry for relaying the signal over ahardwire connection208 to the remotecentral station202. Additionally, thehousing188 includes circuitry for combining (e.g., multiplexing) the receivedsignal206 with one or more signals produced by the firealarm pull station186 for transmitting a combined signal on thehardwire connection208 to the remotecentral station202. Additionally, in this embodiment, theemergency egress station184 transmits a signal though ahardwire connection210 to the remotecentral station202 when an obstruction is detected. Alternatively, theemergency egress station192 transmits awireless signal211 for alerting the remotecentral station202 to a detected obstruction. In this example, thewireless signal211 is transmitted to theemergency lighting station190, which includes circuitry for relaying the signal to the remotecentral station202 via thehousing188. However, in some embodiments thewireless signal211 is transmitted via another pathway. For example, the wireless signal is transmitted directly to thehousing188 for relaying over thehardwire connection208 to the remotecentral station202.

In some embodiments thedefibrillator station180 and/or the

emergency lighting stations

182,190 and/or the

emergency egress station

184,192 also include circuitry for relaying and/or combining (e.g., multiplexing) signals so that a network (e.g., a local area network, LAN, or a wide area network, WAN, etc.) is formed for passing signals among the emergency equipment stations. Additionally, to form a network among the emergency equipment stations, circuitry (e.g., read-only memory, random access memory, etc.) or another a type of memory storage devices (e.g., an radio frequency (RF) tag) are included in each emergency equipment station for storing unique identification information that can be encoded in transmitted signals, thereby permitting the remotecentral station202 to differentiate among the emergency equipment stations as to the source of the transmitted signal. By identifying the transmission source, facility personnel located at the remotecentral station202 are alerted to the particular emergency equipment station associated with internal conditions (e.g., battery replacement needed) and/or external conditions (e.g., obstruction) indicated by in the received signal.

In some embodiments, with reference to thedefibrillator station180 inroom176, thewireless interface200 may receive thewireless signal198 directly from the defibrillator station180 (e.g. via line of site transmission, etc.). However the wireless signal may also be relayed across additional wireless links (e.g., cellular links, satellite links, etc.) prior to being received at thewireless interface200. Also, in some embodiments, a combination of wireless links and hardwire connections can be used to transmit the signals from thedefibrillator station180 or any of the emergency equipment stations or the remotecentral station202.

After signals are received at the remotecentral station202 from the

rooms

176,178, the information included in the received signals is sorted and displayed by acomputer system212 to alert facility personnel (e.g., security, maintenance, fire department, etc.) as to the internal and external conditions associated with the emergency equipment stations. Thecomputer system212 also stores the received and sorted information on a storage device214 (e.g., a hard drive, CD-ROM, etc.) for retrieval at a future time for further processing and reporting. In some embodiments, the remotecentral station202 may include wireless transmission and reception circuitry for transmitting and receiving wireless signals. For example, wireless circuitry (e.g., RF circuitry, antenna, etc.) included in the remotecentral station202 can be used to transmit information over

wireless links

216,218 to wireless devices such as alaptop computer220, a personal digital assistant (PDA)222, or other similar wireless devices (e.g., a cellular phone). Transmission of the information to wireless devices provides facility personnel not located at the remotecentral station202 with information regarding the status of the emergency equipment stations and an alert to any problems (e.g., the firealarm pull station186 inroom178 is being obstructed as detected by housing188) associated with one or more of the emergency equipment stations. By providing wireless access to the information collected at the remotecentral station202, the response time of facility personnel to one or more of emergency equipment stations can be reduced.

Briefly, in summary, in a preferred embodiment, the means for detecting an obstruction to viewing (or operation) of or access to an emergency equipment station (e.g., a fire extinguisher station, a fire alarm pull station, a defibrillator station, an emergency lighting station, etc.) includes asonar module90 mounted within (e.g.,FIG. 7), or mounted in connection to (e.g.,FIG. 10), the emergency equipment station. Thesonar module90 periodically emits an ultrasonic signal through an aperture or window and detects when the signal is returned (reflected) by an obstruction within a predetermined region or range, e.g., from about 6 inches to about 10 feet from the emergency equipment station. Upon detection of an obstruction, a signal is issued to the remotecentral station26 to indicate the presence of an obstruction as required byNFPA 10, §4-3.2(b). Remote inspection information included in the signal received by the remotecentral station26 is communicated to means28, e.g., a computer106 (FIG. 1) located at the remotecentral station26, or other location, where the information is compiled and stored for display and/or print-out in the form of periodic inspection report, e.g., to trigger corrective action. The remotecentral station26 may also send signals122 to the emergency equipment stations (e.g., fire extinguisher stations16) to periodically check for these, and/or other, predetermined internal and external conditions. Theremote inspection apparatus10 of the invention thus provides protection that meets or exceeds the requirements ofNFPA 10, §4-3.2. Surveillance can be provided 24 hours per day, if desired.

In the preferred embodiment, a non-contact ultrasonic sensor (sonar module90) is employed for detecting the presence of an obstruction. Alternatively, a non-contact optical sensor may be employed that has advantages similar to those of the ultrasonic sensor, i.e., low cost and simplicity. Both have sensitivity over wide ranges of distances (e.g., about 6 inches to about 10 feet, or other ranges as may be dictated, e.g., by environmental conditions). As an obstruction may move slowly, or may be relatively stationary, it may not be necessary to have the sensor active at all times; periodic sampling, e.g., once per hour, may be sufficient. On the other hand, thesonar module90 included, for example in the fire alarm pull station140 (FIG. 6) may also be utilized as a proximity or motion sensor, e.g., in a security system, e.g., to issue a signal to a remotecentral station26 and/or to sound an alarm when movement is detected in the vicinity of the firealarm pull station140 while a building is secured, e.g., after business hours or during weekends or vacations. In this case, continuous operation may be dictated, at least during periods when the security system is active. Other features and characteristics that may be optimally employed, as desired, include: wide angle and narrow angle sensitivity, digital output (Is there an obstruction or not?), and/or analog output (e.g., How large an obstruction? and How far away from the docking station?).

A number of embodiments of the invention have been described. Nevertheless, it will be understood that various modifications may be made without departing from the spirit and scope of the invention. For example, other features that might be provided in connection with a remote inspection apparatus of the invention may include, in some instances: an electronic circuit that drives one or more lights included in a emergency equipment station for providing a visual alert to passerby that the visibility or accessibility of the station has been obstructed. Another circuit may optionally drive an audible signaling device (e.g., a speaker) included in the emergency equipment station to for emitting an audible tone or signal (e.g., verbal commands) instead of or in addition to the visual signal to provide an alert that an obstruction to the emergency equipment station has been detected. The audio signal may consist of a recorded information message, e.g., instructions for use of the fire extinguisher including the type of fire for which use is appropriate, e.g., paper, electrical, liquid, all types. The electronic circuit may also include a battery condition sensor to actuate a visual and/or audio signal, e.g., at the remote central station, when a low battery condition is detected.

The electronic circuit may also include a sensor adapted to sense other local conditions, e.g., smoke or fire, to actuate illumination of a light and/or audio signal device when smoke or other indications of a fire are sensed, e.g., to signal the location of the emergency equipment station, when visibility is low. The electronic circuit may include a timer set to actuate the visual and/or the audio signal after a predetermined period of time, e.g., the recommended period between inspections, unless the timer is reset. The electronic circuit may be responsive to a signal from an external source, e.g., a system of smoke detectors, another fire extinguisher or fire extinguisher station, a suppression system, or the like, to actuate the visual and/or the audio signal. The electronic circuit may also include an encoded identification specific to each emergency equipment station for identifying the station, to the remote central station and/or to other elements of a home or facility security system. Typically to identify the emergency equipment station the identification information is encoded into one or more of signals or messages transmitted to the remote central station through a hardwire connection or wireless link via communication circuitry (e.g., RF circuitry and an antenna) included in the emergency equipment station.

In other embodiments, two ormore sonar modules90 may be employed in for example, the fire alarm pull station140 (FIG. 6), to provide additional beam coverage. Also, various technologies may be implemented to communicate by wireless signal among the fire alarm pull station and/or other emergency equipment stations (e.g., a defibrillator station) and/or the remotecentral station26. Along with radio frequency (RF) signaling, infrared (IR) signaling, optical signaling, or other similar technologies may provide communication links. RF signaling, IR signaling, optical signaling, or other similar signaling technologies may also be implemented individually or in any suitable combination to communicate by wireless signal among the firealarm pull station12, the emergency equipment stations (e.g., the defibrillator station), and the remotecentral station26.

In other embodiments, wireless signaling technology may incorporate telecommunication schemes (e.g., Bluetooth or similar) to provide point-to-point or multi-point communication connections among e.g., the fire alarm pull station and/or other emergency equipment stations (e.g., a defibrillator station) and/or the remotecentral stations26. These telecommunication schemes may be achieved, for example, with local wireless technology, cellular technology, and/or satellite technology. The wireless signaling technology may further incorporate spread spectrum techniques (e.g., frequency hopping) to allow the extinguishers to communicate in areas containing electromagnetic interference. The wireless signaling may also incorporate identification encoding along with encryption/decryption techniques and verification techniques to provide secure data transfers among the devices.

In other embodiments, the fire alarm pull station and/or other emergency equipment stations (e.g., a defibrillator station) and/or the remotecentral station26 may include or otherwise be associated with a Global Positioning System (GPS). The GPS may be used to determine, for example, the geographic location of each fire alarm pull station and provide location coordinates, via the wireless signaling technology, to the other emergency equipment stations (e.g., the defibrillator station) and/or the remote central stations. Thus, the GPS system may provide the location of the fire alarm pull stations and allow, for example, tracking of the frequency that fire alarm pull stations located in a particular region of a facility are obstructed.

In still other embodiments, various sensing techniques, besides thesonar modules90, may be employed to sense objects obstructing access to and/or view (or operation) of the emergency equipment stations. Passive or active acoustic sensors may be implemented to detect obstructing objects. In other examples, obstructions may be sensed with electromagnetic sensing techniques (e.g., radar, magnetic field sensors), infrared (IR) sensing techniques (e.g., heat sensors, IR sensors), visual sensing techniques (e.g., photo-electric sensors), and/or laser sensing techniques (e.g., LIDAR sensors). These technologies may, for example, be utilized individually or in concert to sense obstructions that block access to and view of the fire alarm pull station.

Also, the signaling may use networking techniques to provide one-directional and/or multi-directional communications among the devices. In one example, signals from emergency equipment stations may be networked asynchronously, such as in an asynchronous transfer mode (ATM). The signals may also be networked synchronously, such as, for example, in a synchronous optical network (SONET). In still another example, the signals may be transmitted over a landline in an integrated services digital network (ISDN), as well as over other similar media, for example, in a broadband ISDN (BISDN).

A remote inspection apparatus of the invention may also be employed for remote inspection of multiple facilities that each include multiple or a system of emergency equipment stations. Communication between the emergency equipment stations and the remote central station, including hard-wire and wireless communication, may be carried on directly, or indirectly, e.g. via relaying devices, including other emergency equipment stations.

Accordingly, other embodiments are within the scope of the following claims.