Patent Description:
This invention relates generally to self-contained breathing apparatus, and more specifically, a self-contained breathing apparatus with a safety device, e.g., a personal alert safety system.

As is known in the art, a self-contained breathing apparatus (SCBA) is used in a variety of situations and environments where a user requires breathing air, e.g., firefighting situations, low- or no-air environments, emergency applications, and/or the like. One such SCBA is shown and described in the Operating Manual - G1 SCBA of MSA ( a copy of which may be found at the following link: http://s7d9. com/is/content/minesafetyappliances/Operating Manual G1 SCBA NFPA CBRN <NUM> <NUM>). Furthermore, <CIT> discloses a communications network for emergency services personnel.

One known SCBA is illustrated in schematic form in <FIG>. As can be seen, the SCBA includes at least one air cylinder (AC) that is filled with compressed air for delivery to a mask (M), which is donned by a user prior to entering the affected situation or environment. In particular, the air from the air cylinder (AC) is regulated by a first regulator module (RM1) and delivered through an air hose (AH) to a control module (CM) and a second regulator module (RM2) connectable to the mask (M). In this manner, regulated air is supplied to the internal area of the mask (M) for consumption by the user.

Currently, the control module (CM) includes, is integrated with, or is associated with a processor (P), which is programmed or configured to directly or indirectly communicate with and/or control one or more of the components of the SCBA. A power device (PD) is provided to provide power to one or more of the components of the SCBA. Further, data communications and/or electrical power may be distributed to or through the components of the SCBA using a power/communication line (CL). In addition, a communication device (CD), such as a short-range and/or long range radio device, is included and is in direct or indirect communication with the processor (P), and this communication device (CD) is programmed or configured to facilitate direct and/or indirect, wired and/or wireless data communications.

Also included in this known SCBA is a safety device (SD), which may be referred to as a personal alert safety system (PASS), a distress signal unit (DSU), an automatic distress signal unit (ADSU), or the like. This safety device (SD) is used to alert the first responder/firefighter as to the status of their SCBA. Generally, the safety device (SD) provides visual, aural, and/or tactile information regarding the pressure in the air cylinder (AC), available time based upon current usage, alarms warning about low pressure conditions, leaks, and/or other errors or faults in the system. One primary function of the safety device (SD) is entry into an alarm state when the user has not moved for a set period of time. This situation may be considered a "man-down" alarm. Various systems have been used to determine such a "man-down" condition, such that one or more motion sensors, e.g., accelerometers, gyroscopes, rotational sensors, and/or the like, can be integrated or associated with the safety device (SD), such that the "man-down" condition may be determined based upon the motion data provided by or derived from the motion sensors.

In certain applications, e.g., firefighting, the user may also carry a separate portable thermal imaging camera, which allows the user to ascertain the infrared signature of the scene. These units are designed to create an image on an LCD/LED screen to show the user features that are normally not visible to the naked eye, such as "hot spots" behind walls or closed doors, an image of the fire scene that may be obscured by smoke or haze (thereby preventing the scene from being viewed in the visual part of the light wavelength spectrum), and/or the like. In use, the user must first find the separate thermal imaging camera on his/her person (and amongst all of the other equipment that is being worn) in the smoky, hazy, and emergency environment.

Accordingly, there is a need in the art for an improved SCBA and an improved safety device having thermal imaging capabilities.

The Invention is defined by claim <NUM> and the preferred embodiments are defined by the dependent claims. Generally, the present invention provides an improved safety device and an improved self-contained breathing apparatus (SCBA). Preferably, the present invention provides an improved safety device and an improved SCBA that combines or integrates features of a safety (e.g., alarm) device and a thermal imaging camera.

According to one preferred and non-limiting embodiment or aspect, provided is a safety device for a self-contained breathing apparatus having at least one air cylinder configured to deliver regulated air through an air hose via a first regulator module; and a mask configured to be worn by a user, the mask having a second regulator module configured to deliver air from an air hose to an internal area of the mask, the safety device comprising: an air pressure gauge configured to indicate air pressure information or data to the user; a thermal imaging unit comprising: (i) at least one lens having a field-of-view; and (ii) at least one thermal sensor configured to output signals representative of thermal energy; and a user interface programmed or configured to display information or data to the user; wherein at least one local or remote processor is programmed or configured to directly or indirectly communicate with and/or control at least one of the following: the air pressure gauge, the thermal imaging unit, the user interface, or any combination thereof.

In one preferred and non-limiting embodiment or aspect, the safety device further comprises at least one alarm system programmed or configured to generate alarm data based upon input data from at least one of the following: at least one component of the self-contained breathing apparatus, at least one component of the safety device, or any combination thereof. In another preferred and non-limiting embodiment or aspect, the at least one alarm system comprises at least one alarm member comprising at least one of the following: a structural element configured to receive input from at least one user to generate alarm data; a lighting element configured to provide visual alarm data to the at least one user when in an alarm mode, a speaker element configured to provide aural alarm data to the at least one user when in alarm mode, or any combination thereof. In another preferred and non-limiting embodiment or aspect, the safety device further comprises at least one motion sensor programmed or configured to generate motion data, wherein, based at least partially on the motion data, the at least one alarm system at least one of enters the alarm mode and generates alarm data. In another preferred and non-limiting embodiment or aspect, based at least partially on the output signals from the thermal imaging unit, the at least one alarm system at least one of enters the alarm mode and generates alarm data.

In one preferred and non-limiting embodiment or aspect, the safety device further comprises at least one infrared light emitting member configured to emit infrared light, which may be received or sensed by another safety device. In another preferred and non-limiting embodiment or aspect, the infrared light is emitted in at least one of the following: a strobe pattern, a specified pattern, a configurable pattern, a user-controlled pattern, or any combination thereof.

In one preferred and non-limiting embodiment or aspect, the safety device further comprises at least one control element programmed or configured to facilitate direct or indirect interaction with or control of at least one component of the safety device.

In one preferred and non-limiting embodiment or aspect, the safety device further comprises at least one communication interface programmed or configured to transmit, receive, and/or process signals in at least one of the following manners: directly, indirectly, wirelessly, over a communication line, or any combination thereof. In another preferred and non-limiting embodiment or aspect, the at least one processor is local to the safety device and programmed or configured to process and transmit, via the at least one communication interface, at least one of the following: thermal imaging data, alarm data, alarm mode data, motion data, safety device data, user data, or any combination thereof.

In one preferred and non-limiting embodiment or aspect, the safety device further comprises a housing having at least one wall or rim at least partially surrounding at least one of the following: the air pressure gauge, the user interface, at least one control element programmed or configured to facilitate direct or indirect interaction with or control of at least one component of the safety device, or any combination thereof.

In one preferred and non-limiting embodiment or aspect, the at least one lens is oriented in a direction substantially parallel with a longitudinal length of a housing of the safety device.

In one preferred and non-limiting embodiment or aspect, the at least one lens is oriented in a direction of ±X° along a horizontal plane extending through a longitudinal length of a housing of the safety device, wherein X is in the range of about <NUM> to about <NUM>.

In one preferred and non-limiting embodiment or aspect, the orientation of the at least one lens is at least one of the following: manually adjustable by the user, automatically adjustable, automatically adjustable using the user interface, automatically adjustable using at least one control element, or any combination thereof.

In one preferred and non-limiting embodiment or aspect, the at least one lens is adjustable in a direction of ±Y° along a vertical plane extending through a longitudinal length of a housing of the safety device, wherein Y is in the range of about <NUM> to about <NUM>.

In one preferred and non-limiting embodiment or aspect, the safety device further comprises a housing having at least one shield configured to at least partially surround the at least one lens.

In one preferred and non-limiting embodiment or aspect, the information or data displayed on the user interface can be modified by at least one of the following: the user's movement of the safety device, the user's voice command, or any combination thereof.

In one preferred and non-limiting embodiment or aspect, the at least one processor is programmed or configured to initiate at least one of a no-power or low-power state based at least partially on at least one of the following: a specified movement of the user, a voice command of the user, a specified orientation of the safety device, a specified period of a specified orientation, a specified period of non-use or non-interaction, a specified period of non-use or non-interaction of a specified component of the safety device, or any combination thereof.

In one preferred and non-limiting embodiment or aspect, the at least one processor is programmed or configured to initiate a power-on or power-up state based at least partially on at least one of the following: a specified movement of the user, a voice command of the user, a specified orientation of the safety device, a specified period of a specified orientation, use of or interaction with the safety device, use of or interaction with a specified component of the safety device, or any combination thereof.

In one preferred and non-limiting embodiment or aspect, the at least one processer comprises at least one of the following: an existing processor of the safety device, an existing processor of the thermal imaging unit, a remote processor in direct or indirect communication with the safety device, an existing processor of at least one component of the self-contained breathing apparatus, an existing processor of a control module of the self-contained breathing apparatus.

According to one preferred and non-limiting embodiment or aspect, provided is a self-contained breathing apparatus, comprising: at least one air cylinder configured to deliver regulated air through an air hose via a first regulator module; a mask configured to be worn by a user, the mask having a second regulator module configured to deliver air from an air hose to an internal area of the mask; a control module, including: (i) a power device configured to provide power to at least one component of the self-contained breathing apparatus; (ii) a processor programmed or configured to communicate with and/or control at least one component of the self-contained breathing apparatus; and (iii) a communication device programmed or configured to facilitate direct and/or indirect, wired and/or wireless data communications between the processor and the at least one component of the self-contained breathing apparatus; and a safety device comprising: an air pressure gauge configured to indicate air pressure information or data to the user; a thermal imaging unit comprising: (i) at least one lens having a field-of-view; and (ii) at least one thermal sensor configured to output signals representative of thermal energy; and a user interface positioned on a housing of the safety device and programmed or configured to display information or data to the user: wherein at least one local or remote processor is programmed or configured to directly or indirectly communicate with and/or control at least one of the following: the airpressure gauge, the thermal imaging unit, the user interface, or any combination thereof.

In one preferred and non-limiting embodiment or aspect, the at least one local or remote processor comprises the processor of the control module, and wherein the processor of the control module communicates with or controls at least one component of the safety device.

In one preferred and non-limiting embodiment or aspect, at least one component of the safety device is powered by the power device of the control module.

These and other features and characteristics of the present invention, as well as the methods of operation and functions of the related elements of structures and the combination of parts and economies of manufacture, will become more apparent upon consideration of the following description and the appended claims with reference to the accompanying drawings, all of which form a part of this specification, wherein like reference numerals designate corresponding parts in the various figures. As used in the specification and the claims, the singular form of "a", "an", and "the" include plural referents unless the context clearly dictates otherwise.

For purposes of the description hereinafter, the terms "upper", "lower", "right", "left", "vertical", "horizontal", "top", "bottom", "lateral", "longitudinal" and derivatives thereof shall relate to the invention as it is oriented in the drawing figures. However, it is to be understood that the invention may assume various alternative variations and step sequences, except where expressly specified to the contrary. It is also to be understood that the specific devices and processes illustrated in the attached drawings, and described in the following specification, are simply exemplary embodiments of the invention.

As used herein, the terms "communication" and "communicate" refer to the receipt, transmission, or transfer of one or more signals, messages, commands, or other type of data. For one unit or device to be in communication with another unit or device means that the one unit or device is able to receive data from and/or transmit data to the other unit or device. A communication may use a direct or indirect connection, and may be wired and/or wireless in nature. Additionally, two units or devices may be in communication with each other even though the data transmitted may be modified, processed, routed, etc., between the first and second unit or device. For example, a first unit may be in communication with a second unit even though the first unit passively receives data, and does not actively transmit data to the second unit. As another example, a first unit may be in communication with a second unit if an intermediary unit processes data from one unit and transmits processed data to the second unit. It will be appreciated that numerous other arrangements are possible. Any known electronic communication protocols and/or algorithms may be used such as, for example, TCP/IP (including HTTP and other protocols), WLAN (including <NUM> and other radio frequency-based protocols and methods), analog transmissions, and/or the like.

In one preferred and non-limiting embodiment or aspect, and as illustrated in schematic form in <FIG>, provided is safety device <NUM> that can be used in connection and/or integrated with a self-contained breathing apparatus (SCBA), such as the SCBA discussed above and illustrated in <FIG>. As shown in the preferred and non-limiting embodiment or aspect of <FIG>, the safety device <NUM> includes an air pressure gauge <NUM> configured to indicate air pressure information or data to the user, such as the air pressure (or "air level") in the air cylinder (AC). The air pressure is determined by connecting the air hose (AH) to the safety device <NUM>, either directly or indirectly from the air cylinder (AC) and/or a fitting on the control module (CM). In this manner, the safety device <NUM> receives or determines the air pressure in the air cylinder (AC) and displays this information to the user, preferably on the air pressure gauge <NUM>.

Further, and in another preferred and non-limiting embodiment or aspect, the safety device <NUM> includes a user interface <NUM> (e.g., a LCD screen, a LED screen, an interactive screen, a touch screen, a display mechanism, a display device, and/or the like) programmed or configured to display information or data to the user. This user interface may be positioned in a variety of locations or positions on a housing <NUM> of the safety device <NUM>.

In another preferred and non-limiting embodiment or aspect, the safety device <NUM> includes a thermal imaging unit <NUM> having at least one lens <NUM> with a field-of-view <NUM> and at least one thermal sensor <NUM> configured to output signals representative of thermal energy. Accordingly, the signals output from the thermal sensor <NUM> can be used to generate thermal imaging data for display on the user interface <NUM>. As is known, this thermal imaging data provides a color (or other graphical element) based image of the thermal energy in the field-of-view <NUM>. The at least one thermal sensor may include or be in the form of at least one of the following: at least one array, at least one focal plane array, at least one pixel array, at least one thermal imaging sensor, at least one thermocouple, at least one thermal image device, at least one thermal imaging unit, at least one temperature sensor, or any combination thereof.

In another preferred and non-limiting embodiment or aspect, at least one local or remote processor <NUM> (e.g., a computer, a computing device, a PLC, a circuit, and/or the like) is provided and programmed or configured to directly or indirectly communicate with and/or control at least one of the following: the air pressure gauge <NUM>, the user interface <NUM>, the thermal imaging unit <NUM>, or any combination thereof. In particular, with continued reference to <FIG>, and in one preferred and non-limiting embodiment or aspect, the processor <NUM> may be located in the safety device <NUM> (i.e., a "local" processor), and in another preferred and non-limiting embodiment or aspect, the processor <NUM> may be located remotely from the safety device <NUM>, such as by using the processor (P) of the control module (CM) communicating over the power/communication line (CL) (or alternatively, communicating wirelessly with the control module (CM), or even wirelessly with some central unit or processor). Further, and in another preferred and non-limiting embodiment or aspect, the at least one processer <NUM> includes or is in the form of: an existing processor of the safety device <NUM> (e.g., the existing processor of an alarm/safety device with which the thermal imaging unit <NUM> is integrated), an existing processor of the thermal imaging unit <NUM> (e.g., an existing processor included with the at least one thermal sensor <NUM> and at least one lens <NUM> as a pre-packaged unit), a remote processor in direct or indirect communication with the safety device <NUM>, an existing processor of at least one component of the SCBA, an existing processor (P) of the control module (CM) of the SCBA, and/or the like.

In one preferred and non-limiting embodiment or aspect, the safety device <NUM> includes or is in the form of at least one alarm system <NUM>, which is programmed or configured to generate alarm data based upon input data from at least one component of the SCBA and/or at least one component of the safety device <NUM>. Accordingly, the at least one alarm system <NUM> is controlled by or integrated with the processor <NUM> (or processor (P)). In one preferred and non-limiting embodiment or aspect, the alarm system <NUM> includes one or more alarm members <NUM>, which may be in the form of one or more of the following: a structural element that can be actuated or engaged by the user to generate alarm data (e.g., a visual alarm, an aural alarm, a tactile alarm, a transmittal of at least a portion of the alarm data, and/or the like); a lighting element that provides visual alarm data to the user when in alarm mode; a speaker element that provides aural alarm data and/or signals to another device, e.g., a device in the mask (M) of the user, or any combination thereof.

In addition, and with continued reference to <FIG>, the alarm system <NUM> (and/or the processor <NUM> or processor (P)) may include or be in direct or indirect communication with at least one motion sensor <NUM>, which provides or generates motion data that may be used to generate or determine alarm data. This motion data and/or alarm data can be used to place the safety device <NUM> in alarm mode, and further, this motion data and/or alarm data can be transmitted to the control module (CM), such that the communication device (CD) of the control module (CM) can transmit the information or data to a remote unit, such as a central controller, e.g., central command at an incident scene. It is envisioned that the motion sensor <NUM> may be a rotational sensor, an accelerometer, a gyroscope, and/or the like. Further, it is this motion sensor <NUM> that can be used to sense or determine a "man-down" situation, where the alarm system <NUM> can generate the appropriate alarm data for use in a notification function or a rescue operation.

Similarly, the safety device <NUM> and/or the alarm system <NUM> can enter alarm mode (or generate alarm data) based at least partially on the output signals (and/or thermal imaging data) generated by or based upon the thermal imaging unit <NUM>. For example, the output signals or thermal imaging data can be used to determine that the user is too close to or about to enter an extreme temperature environment. The determination of temperature intensity (which is based upon a determination of thermal energy associated with certain pixels or areas in the field-of-view <NUM>) may be used to enter alarm mode, such as where the determined value is above a specified threshold. Further, this information and data may be periodically or automatically transmitted to some remote processor, e.g., a central processor or controller. In one preferred and non-limiting embodiment or aspect, this transmission may occur directly, e.g., wirelessly, between the safety device <NUM> and the remote processor and/or indirectly between the safety device <NUM> and the remote processor, such as by transmission from the safety device <NUM> to the control module (CM) (e.g., over the power/communication line (CL), wherein the control module (CM) transmits this information or data to the remote processor using the communication device (CD) of the control module (CM).

In another preferred and non-limiting embodiment or aspect, the safety device <NUM> includes at least one communication interface <NUM>, which is programmed or configured to transmit, receive, and/or process signals directly, indirectly, wirelessly, over a communication line, e.g., power/communication line (CL), and/or the like. This at least one communication interface <NUM> may be in direct or indirect communication with or controlled by the processor <NUM>, and further, may provide for the communication between the safety device <NUM> and the control module (CM), i.e., the processor (P) of the control module (CM). Accordingly, in one preferred and non-limiting embodiment or aspect, the at least one processor <NUM> is local to the safety device <NUM> and programmed or configured to process and transmit, via the at least one communication interface <NUM>, at least one of the following: thermal imaging data, alarm data, alarm mode data, motion data, safety device data, user data, or any combination thereof. Again, this information and data may be transmitted to the control module (CM) over the power/communication line (CL) and/or to some other remote system.

In addition, some or all of the components of the safety device <NUM> are attached to, located within, integrated with, and/or associated with a housing <NUM>, which is sized and shaped so as to be held and operated by the user while engaged in the desired activity. In one preferred and non-limiting embodiment or aspect, the safety device <NUM> includes at least one control arrangement <NUM> (e.g., a button, a touch interface, a joystick, an actuating member, a scroll member, and/or the like) programmed or configured to facilitate direct or indirect interaction with or control of the user interface <NUM>. For example, the at least one control arrangement <NUM> can be positioned on or associated with the housing <NUM>.

In one preferred and non-limiting embodiment or aspect, and referring to <FIG>, one or more walls <NUM> may be positioned on or integrated with the housing <NUM>, such as the face <NUM> (or front area) of the housing <NUM>. These walls <NUM> may at least partially surround one or more of the components on the face <NUM> of the housing <NUM>, such as the air pressure gauge <NUM>, the user interface <NUM>, one or more of the control arrangements <NUM>, and/or any other component of the safety device <NUM>. In one application, the walls <NUM> provide a projecting rim that can help shield some or all of these components so the user can more easily view the air pressure gauge <NUM>, the user interface <NUM>, and/or the like. In another embodiment, at least a portion of the walls <NUM> are sized, shaped, and/or coated to facilitate viewing through the mask (M) by the user. In some embodiments, the walls <NUM> are sized, shaped, and/or coated to facilitate contact with the face shield of the mask (M), which would provide optimal viewing advantages. Alternatively, some or all of the safety device <NUM> can be positioned in a sleeve or boot (not shown), which would provide additional protection of the various components of the safety device <NUM>, e.g., the air pressure gauge <NUM>, the user interface <NUM>, the control arrangements <NUM>, portions of the thermal imaging unit <NUM>, and/or the like. Such a sleeve or boot would provide a rugged, sealed cover for the safety device <NUM>, which would be beneficial in many environments and applications in which the safety device <NUM> is employed.

It should be recognized that the user interface <NUM> may be used to display any of the information or data that is generated by, related to, or associated with any component of the SCBA, including the safety device <NUM>. Therefore, the user interface <NUM> may display any information or data (in raw and/or processed form) that is generated by or derived from any of the following: the mask (M), the control module (CM), the air cylinder (AC), the safety device <NUM>, the air pressure gauge <NUM>, a control arrangement <NUM>, the alarm system <NUM>, the thermal imaging unit <NUM>, the processor <NUM>, the motion sensor <NUM>, the alarm member <NUM>, or any combination thereof.

As is known, first responders spend at least a portion of their time on their hands and knees while engaged in their activities, e.g., firefighting, because it reduces the exposure of the responder to high temperatures, as well as allows a safer ingress/egress from the scene. When in this position/orientation, the responder is less likely to trip and fall, or encounter unknown obstacles in a dangerous fashion. Accordingly, and in one preferred and non-limiting embodiment, and with reference to <FIG>, the thermal imaging unit <NUM> includes a lens <NUM> that is oriented at an angle that is optimized to allow the user to view the scene, while still maintaining the most beneficial body position to simultaneously view the air pressure gauge <NUM> and/or the user interface <NUM> (which would display the visual data that is generated by the thermal imaging unit <NUM>). In one preferred and non-limiting embodiment or aspect, the lens <NUM> (i.e., the field-of-view <NUM>) is oriented in a direction substantially parallel with a longitudinal length of the housing <NUM>, which provides an optimal orientation when the user is in the crawling position.

In one preferred and non-limiting embodiment or aspect, and as illustrated in <FIG>, the lens <NUM> may be oriented at an angle ±X° with respect to the horizontal (or longitudinal) length (i.e., <NUM>°) of the safety device <NUM>, e.g., the housing <NUM>, where X may be less than or equal to <NUM>, and preferably less than or equal to <NUM>, and more preferably less than or equal to <NUM>. In addition, this optimal angle may be a result of manufacturing or rigidly positioning the thermal imaging unit <NUM> and/or the lens <NUM> in a set, i.e., non-adjustable, position, which requires the user to move the entire safety device <NUM> to change the field-of-view <NUM>. It should also be recognized that the thermal imaging unit <NUM> and/or the lens <NUM> may be rigidly or adjustably oriented at an angle ±Y° with respect to vertical (i.e., <NUM>°), as illustrated in <FIG>, where Y may be less than or equal to <NUM>, and preferably less than or equal to <NUM>, and more preferably less than or equal to <NUM>.

With reference to <FIG>, and in another preferred and non-limiting embodiment or aspect, one or more adjustment members <NUM> may be included that provide the user with the ability to manually adjust the angles X and/or Y to a desired position. These adjustment members <NUM> may take form of a rotatable knob, a ratchet device, a locking arrangement, a push-button arrangement, and/or the like, and further, these adjustment members <NUM> may be positioned at any area or location on the housing <NUM>. Further, it is envisioned that the user may use the user interface <NUM> to move the lens <NUM> and/or adjust the field-of-view <NUM> to a desired position. As also illustrated in <FIG>, a shield <NUM> may be included or integrated with the housing <NUM>, wherein the shield <NUM> is positioned to at least partially surround the lens <NUM>. Accordingly, the shield <NUM> will provide protection to the lens <NUM> as the user traverses a difficult environment, often on his or her hands and knees.

In one example, the user may view the safety device <NUM> (e.g., the air pressure gauge <NUM>) at about a <NUM>°-<NUM>° angle to the horizontal, while the user interface <NUM> (and, thus, the thermal imaging data) may be substantially planar to the horizontal, which results in a general angle of <NUM>° of slope from the field-of-view <NUM> to the user interface <NUM>. Accordingly, and in one preferred and non-limiting embodiment or aspect, it is the angle of the lens <NUM>, i.e., the field-of-view <NUM>, that can be optimized, whether rigidly (where the optimization is based upon the most typical viewing angles of the safety device <NUM>) or adjustably (where the user may manually and/or automatically adjust the view angle, such as by using the adjustment member <NUM>). Alternatively, the air pressure gauge <NUM> and/or the user interface <NUM> may be sloped or slanted at a specified angle with respect to the face <NUM> of the housing <NUM>.

In another preferred and non-limiting embodiment or aspect, and when the information and data generated by or derived from the thermal imaging unit <NUM> and the information and data generated by or derived from other components of the SCBA (including the other components of the safety device <NUM>) are displayed on the same user interface <NUM> (i.e., the same screen), the safety device <NUM>, itself, may be used to toggle between the type of information and data displayed. For example, the processor <NUM> may be programmed or configured to change the specific information or data displayed (and/or the data stream) based at least partially on the output (or motion data) of the motion sensor <NUM>. For example, the safety device <NUM> may be rotated through its longitudinal axis, which activates or impacts the motion sensor <NUM>, and which movement may be used to switch between displays or modes. Of course, any type of movement of the safety device <NUM> may be sensed and translated into a variety of display changes and/or interactions. Movement between display modes or information- or data-types may be implemented using one or more of the control arrangements <NUM> discussed above. Further, it is envisioned that switching between display modes, interacting with the user interface <NUM>, and/or control any of the components of the safety device <NUM> may occur through voice command, e.g., direct or indirect data communication between a transducer in the mask (M) and the safety device <NUM> and/or the control module (CM), such as through the communication device (CD).

In a still further preferred and non-limiting embodiment or aspect, the motion sensor <NUM> may be used to determine the orientation of the safety device <NUM>. It is recognized that a color user interface <NUM> (which would be beneficial for effectively viewing the thermal imaging data) may increase usage of the power device (PD), e.g., the battery. Accordingly, in this embodiment, and to minimize the loss of power when not in use, the user interface <NUM> may be temporarily shut down (or go in to some "low power" state) when the safety device <NUM> is in a non-use orientation, e.g., pointing down and away from the user. This "shut down" function may also occur only when the safety device <NUM> is in a non-use orientation for a specified period of time. Alternatively, if certain components of the safety device <NUM> are static or unused for a specified period of time, this "shut down" function may also be implemented. Further, a simple movement of the safety device <NUM> (e. g, twisting the device, as discussed above), orientation of the safety device <NUM> (e.g., positioning the device in a "viewing" angle), and/or other specified interaction with the safety device <NUM> (e.g., interacting with the control arrangement <NUM>) may cause the user interface <NUM> to power up. In another preferred and non-limiting embodiment or aspect, the user interface <NUM> can be utilized in both modes simultaneously, such as where the general SCBA information or data is overlaid on the thermal imaging data.

Accordingly, and in one preferred and non-limiting embodiment or aspect, the at least one processor <NUM> is programmed or configured to initiate at least one of a no-power or low-power state based at least partially on at least one of the following: a specified movement of the user, a voice command of the user, a specified orientation of the safety device <NUM>, a specified period of a specified orientation, a specified period of non-use or non-interaction, a specified period of non-use or non-interaction of a specified component of the safety device <NUM>, or any combination thereof. Further, the at least one processor <NUM> may be programmed or configured to initiate a power or power-up state based at least partially on at least one of the following: a specified movement of the user, a voice command of the user, a specified orientation of the safety device <NUM>, a specified period of a specified orientation, use of or interaction with the safety device <NUM>, use of or interaction with a specified component of the safety device <NUM>, or any combination thereof.

In another preferred and non-limiting embodiment, the safety device <NUM> is in direct or indirect communication with one or more of the communication devices (CD) (e.g., a short-range radio, a long-range radio, and/or the like). In particular, some or all of the thermal imaging data (whether in raw or processed form) can be transmitted to a central controller, such as a command and control base station. This thermal imaging data may be sent continuously, periodically, on command, as a "live" stream, and/or the like. This would allow a remote user, e.g., the fire chief or other personnel, to view the thermal imaging data from the safety device <NUM> without the need for additional radio communication links, such as would be required for existing handheld thermal imaging cameras. While it is recognized that such a telemetry arrangement would require higher bandwidth than normal existing communications, this embodiment would represent an intrinsically safe and explosion-proof telemetry methodology.

It is further recognized that the environments at or around the scene are often a noisy place, and with additional head protection and communications partially or fully covering the ears of the user, hearing or determining the location or direction of an alarm condition of a specific safety device <NUM> can be difficult. With reference to <FIG>, and in another preferred and non-limiting embodiment or aspect, one or more infrared light emitting members <NUM> (e.g., strobe lights) may be positioned on the housing <NUM> and configured to emit infrared light, which may be received by or sensed by another safety device <NUM> of another user. In this embodiment, the thermal imaging unit <NUM> of another safety device <NUM> of another user can be used to search for the infrared light emitted from these infrared light emitting members <NUM>. Therefore, the safety device <NUM> that is in an alarm condition, e.g., the user is in distress, can be more easily located by other users/rescuers. In addition, it is envisioned that the strength of the infrared signal from the infrared light emitting members <NUM> can be used to determine the distance orproximity to the downed person. Still further, these infrared light emitting members <NUM> may be configured to emit infrared light in a strobe pattern, a specified pattern, a configurable pattern, a user-controlled pattern, and/or the like. By using varying patterns, additional information or data may be conveyed between the safety devices <NUM>, which may be indicative of different states, e.g., in an alarm state, proximity to a dangerous environment, and/or any other information or data generated by or stored on the safety device <NUM>.

One preferred and non-limiting embodiment or aspect of a safety device <NUM> in accordance with the principles of the present invention is illustrated in <FIG>, where the at least one lens <NUM> is oriented at a downward angle with respect to the horizontal length of the housing <NUM>, and another preferred and non-limiting embodiment or aspect of a safety device in accordance with the principles of the present invention is illustrated in <FIG>, where the at least one lens <NUM> is oriented parallel (i.e., <NUM>°) with respect to the horizontal length of the housing <NUM>.

In this manner, provided is an improved safety device <NUM> for an SCBA, as well as an improved SCBA.

Claim 1:
A safety device (<NUM>) for a self-contained breathing apparatus having at least one air cylinder (AC) configured to deliver regulated air through an air hose (AH) via a first regulator module; and a mask (M) configured to be worn by a user, the mask (M) having a second regulator module configured to deliver air from an air hose (AH) to an internal area of the mask (M), the safety device (<NUM>) comprising:
a housing (<NUM>) configured to be held by the user and having at least one wall (<NUM>);
an air pressure gauge (<NUM>) at least partially surrounded by the wall (<NUM>) of the housing (<NUM>) and configured to indicate air pressure information or data to the user;
a thermal imaging unit (<NUM>) comprising: (i) at least one lens (<NUM>) having a field-of-view (<NUM>); and (ii) at least one thermal sensor (<NUM>) configured to output signals representative of thermal energy; and
a user interface (<NUM>) programmed or configured to display information or data to the user;
wherein at least one local or remote processor (<NUM>) is programmed or configured to directly or indirectly communicate with and/or control at least one of the following: the air pressure gauge (<NUM>), the thermal imaging unit (<NUM>), the user interface (<NUM>), or any combination thereof, characterized in that the orientation of the at least one lens (<NUM>) is at least one of the following: manually adjustable relative to the housing (<NUM>) by the user, automatically adjustable relative to the housing (<NUM>), automatically adjustable relative to the housing (<NUM>) using the user interface (<NUM>), automatically adjustable relative to the housing (<NUM>) using at least one control element (CM), or any combination thereof.