BACKGROUND OF THE INVENTION Structural damage leading to collapse has resulted in injuries and death to rescue workers and others within the vicinity of the collapse. In many rescue operations, the condition of the structure plays a relatively minor role in deciding when and how to enter the structure, particularly if human lives are in danger. The typically complex nature of how damage propagates and may ultimately weaken a structure has made it very difficult to predict imminent collapse. Visual inspections alone, especially during firefighting operations, cannot guarantee detection of mechanisms that could lead to collapse and loss of life. A need exists, therefore, for a technical approach that can monitor structures that are severely damaged and in danger of collapse.

Collapse monitoring, however, is based on the premise that the degree of damage to the structure is so severe that continued exposure to the current loading condition will lead to imminent collapse. A burning structure is, by definition, already damaged due to the fire. The ability to simply detect and track damage mechanism due to fire does not provide a mechanism that will detect impending collapse.

Structural damage detection research is best characterized as using nondestructive testing techniques to determine the behavior of response characteristics under known loading conditions. The selection of the particular testing technique, however, plays a large role in the effectiveness of the detection technique. Prior art damage detection devices and methodologies do not provide nondestructive testing devices and methodologies.

Existing devices that detect damage in structures rely mainly on approaches that induce high frequency or acoustic energy into the structure or that use monitoring devices at critical locations within a structure.

U. S. 5,675, 809 to Hawkins, for example, discloses a passive strain gauge that can be mounted to buildings.

The gauge emits acoustic waves commensurate with load bearing stress exerted on a building in earthquakes and

the like. Similarly, U. S. 5,404, 755 to Olson, et al., disclose a method of testing stress in wood and other products using ultrasonic frequencies.

These types of gauges and methodologies operate over a wide frequency range, well beyond those associated with structural resonances. As such, they are not effective in isolating structural response behavior and do not possess the sensitivity required for collapse monitoring.

U. S. 6,138, 516 (to Tillman) discloses a device that monitors the amount of shock applied to a location on a structure. The device is a shock detector and utilizes an accelerometer adapted to generate a rectified signal that is compared to a threshold level to produce a high voltage state. Detection of shock on a structure, however, cannot be used for monitoring structural response leading to collapse, particularly since Tillman utilizes a set threshold level below which the device remains in a low voltage state The need for determining impending structural failure is significant. The present invention provides a new and unique device and method for determining structural damage and imminent failure, which will help to prevent injuries and save the lives of rescue workers and persons within the realm of a building collapse.

SUMMARY OF THE INVENTION It is, therefore, an objective of this invention to provide a system and method for determining the onset of collapse of a structure, detecting the progression of the collapse mechanism and detecting severely reduced structural integrity in the aftermath of a condition impacting the structure.

It is another objective of this invention to provide a system that utilizes at least one accelerometer that is capable of measuring acceleration responses down to zero Hz.

It is another objective of this invention to provide a system and method for detecting collapse of a structure using at least one accelerometer that is capable of measuring acceleration responses in at least one axial (x, y, or z) direction, utilizing the device of the present invention.

It is another objective of this invention to provide a system that utilizes a device that can be attached on an exterior surface away from damage conditions where the device is attached perpendicular to the direction of the portion of the structure being monitored.

It is yet another objective of this invention to provide a system that utilizes a device that is lightweight, waterproof and capable of withstanding temperatures of up to 1900 °F.

It is yet another objective of this invention to provide a system that utilizes a device that operates on an independent power source.

It is yet another objective of this invention to provide a system that utilizes an outside power source including a building's power source that is being monitored for collapse conditions.

It is yet another objective of this invention to provide a system that utilizes analog and/or digital signals to evaluate data transmitted to a remote receiver of the system.

It is yet another objective of this invention to provide a system that utilizes computer technology to evaluate the transmitted signals to determine and detect collapse situations.

It is yet another objective of this invention to provide a system that utilizes wired and wireless communications to transmit signals from the device to the remote receiver.

These and other objects of this present invention are met by this invention as described herein below.

DESCRIPTION OF THE FIGURES: Figure, 1 shows an analog/through cable/wired system of the present invention.

Figure l (a) shows a front side of the device of the system.

Figure 2 shows an analog/internal power/wired system of the present invention.

Figure 3 shows am analog/internal power/wireless system of the present invention.

Figure 4 shows an analog/building power/wired system of the present invention.

Figure 5 shows an analog/building power/wireless system of the present invention.

Figure 6 shows a digital/through cable/wired system of the present invention.

Figure 7 shows a digital/internal power/wired system of the present invention.

Figure 8 shows a digital/internal power/wireless system of the present invention.

Figure 9 shows a digital/building power/wired system of the present invention.

Figure 10 shows a digital/building power/wireless system of the present invention.

Figure 11 is a graph showing the acceleration signal over time, obtained from the Phoenix, Arizona, burn test.

Figure 12 (a) is a graph showing the acceleration response corresponding to the acceleration signal from the Phoenix, Arizona, burn test.

Figure 12 (b) is a filtered signal of the acceleration response over time, obtained from the Phoenix, Arizona, burn test.

Figure 12 (c) is a graph indicating the breakaway point corresponding to weakened structural support, obtained from the Phoenix, Arizona, burn test.

Figure 13 shows the collapse index corresponding to the measured acceleration responses over time obtained from the Kingston, North Carolina, burn test.

Figure 14 is a graph showing measured acceleration response from test data obtained from the Kingston, North Carolina, burn test.

DETAILED DESCRIPTION OF THE EMBODIMENTS The present invention is directed to the detection of imminent structural collapse. Detection of imminent structural collapse is distinguished from identifying damage detection of structures or buildings. Damage detection is primarily concerned with preventing large scale and sustained damage to a building or structure.

Collapse detection, on the other hand, begins with the assumption that damage is irreversible.

All structures exhibit ambient response behavior when subject to naturally occurring excitations that may stem from wind, wave, operating facilities, or other situation specific responses, commensurate with environmental conditions in and around a structure.

The present invention is directed to detecting and monitoring this collapse mechanism as it grows and reaches maximum levels immediately prior to collapse.

More specifically, this invention is directed to the determination of a threshold value or range of threshold values based upon naturally occurring and situation specific ambient responses identifying the initiation of a collapse, the progression of the collapse to a condition that indicates severely reduced structural integrity.

As it pertains to detecting impending collapse of a structure, the irreversible characteristics of a collapse mechanism, coupled with advances in computer and instrumentation technologies, have led to the present invention.

The system and method of the present invention utilizes ambient acceleration response measurements acquired on the structure due to externally applied excitations of which fire can be one example. The ambient accelerations include information pertaining to response magnitude and frequency content that can be related to the changing integrity of the structure leading to impending collapse. The present invention is capable of detecting low-level structural responses on the order of milli-g's over a frequency range 0-30Hz and particularly in the range of 0-20Hz.

The system and method of the present invention is based upon the inventors'findings that acceleration responses are not impacted by fire conditions in the same manner as other structural responses. A simplified physical interpretation of the acceleration response obtained from a collapsing structural component provides a mechanism for inevitable collapse. The collapsing structural component, i. e. a beam, manifests increasing

vibration levels near the center of the beam during burn, followed by a large increase in acceleration, oriented in the downward direction, as pieces of the beam fall away.

Both the burn and increasing acceleration levels are irreversible processes in the beam. Therefore, detecting the onset of the large increase or change in acceleration is critical to providing sufficient warning of imminent structural collapse. It is important to note that the ability to monitor ambient responses is itself not enough to predict impending collapse. Rather, it is the ability to detect the changes in ambient response levels that distinguishes this present invention.

An example of a situation specific ambient response of a collapse is a burning structure in which fire produces a random excitation that includes spectral energy spanning the traditional structural response range (typically below 100 Hz for most structures). Due to high temperatures and poor signal-to-noise content, detection of structural response under these conditions had previously been difficult.

The present invention provides a system and method for detecting and monitoring a collapse mechanism. The system and method of the present invention is passive.

Embodiments of the present invention are shown in Figures

1 through 10. The present invention is not limited to these specific embodiments and variations of these embodiments are within the scope of the present invention.

The present system and method is also not limited to fire related collapse, but any collapse induced by structures absorbing energy beyond its load bearding capacities.

Figure 1 shows an analog through cable wired system of the present invention. The system (1) of Figure 1 provides a lightweight, portable device (2) and a display apparatus (3) that are utilized to detect and monitor collapse mechanisms at the time of fire or damage.

The device (2) of the system (1) includes at least one accelerometer (4) as a transducer for monitoring structural responses. Accelerometer (4) must be capable of monitoring acceleration in one to three axial directions (i. e., x, y or z axis), preferably oriented perpendicular to a mounting surface, and operates in the range of 0-30 Hz. Accelerometer (4) monitors responses down to DC or zero Hz. This is because accelerometer (4) tracks very low frequency responses corresponding to the changing mean accelerations in the structures.

Accelerometers that are not capable of monitoring DC

responses. will filter or attenuate these responses around 4 Hz, and, therefore, be incapable of detecting changing mean accelerations approaching ultimate collapse. The device (2) also includes a low pass filter and amplifier (5) that is connected to the accelerometer (4) for signal gains equal to 100 over a 0-30 Hz range.

Device (2) also includes at least one transmitter (6) that is connected to the filter and amplifier (5).

Bandwidth capabilities of the transmitter (6) shall be specified by the requirements imposed by environmental conditions and the highest desired frequency content in the signal.

The device (2) also includes a first power source (7) that is connected to the accelerometer (4), the filter and amplifier (5) and the transmitter (6). First power source (7) operates using both dependent and independent power supplies. Independent power supplies for the first power source (7) include batteries. The dependent power for power source (7) will be described herein below. Other sources of power adaptable to the device (2) are also within the scope of this invention.

Transmitter (6) transfers analog response signals obtained from device (2) to the display apparatus (3) through a wired communication line (8). This analog

signal is received by a remote receiver (9). The wired communication line (8) is covered with a fire retardant/heat retardant material suitable for high temperatures. The analog signal is then transferred to an A-D converter (10). The A-D converter then transfers the digitized signal to a computer system (11). The computer system (11) includes a computer processor unit (lla), a memory (llb), a display screen (lie) and a user input (lld). The computer processor unit (lla) compares threshold values relating the acceleration responses to structural conditions. Based on these values, computer processor unit (lla) provides a signal to device (2) that is displayed on the on/off indicator (13b) as shown in figure l (a). The digitized signals can be displayed on display screen (llc) and/or stored onto memory (llb).

Computer processor unit (lla) also provides on-site data reduction and analysis through designed software that allows for visual and audible characterizations of the measured responses on display (llc). The remote receiver (9), the A-D converter (10) and the computer system (11) are connected to a second power source (12). The second power source (12) can operate utilizing an internal power supply such as batteries. The second power source (12) is also capable of supplying power to first power source

(7) when necessary. Other sources of power adaptable to the display apparatus (3) are also within the scope of this invention.

As shown in figure (la), the device (2) is housed within a thermal casing (13) that protects the device (2) from heat damage up to 1900 °F. The casing (13) includes a face plate (13a) having an on/off indicator (13b). The on/off indicator (13b) may incorporate a switch mechanism and/or an audio signal indicator and/or a visual signal indicator that is capable of mean tracking. The dimensions of device (2) are dependent upon the size of the various components listed above. However, the largest dimension of device (2) will not exceed 4 inches.

Figure 2 shows another embodiment of the present invention. System (101) of Figure 2 provides a lightweight, portable device (102) and a display apparatus (103) that are utilized to detect and monitor collapse conditions at the time of fire or damage. The device (102) of the system (101) includes at least one accelerometer (104) as a transducer for monitoring structural responses. Accelerometer (104) must be capable of monitoring acceleration in one to three axial <BR> <BR> directions (i. e. , x, y or z axis), preferably oriented perpendicular to a mounting surface, and operates in the

range of 0-30 Hz. Accelerometer (104) monitors responses down to DC or zero Hz. This is because accelerometer (104) tracks very low frequency responses corresponding to the changing mean accelerations in the structures.

Accelerometers that are not capable of monitoring DC responses will filter or attenuate these responses around 4 Hz, and, therefore, be incapable of detecting changing mean accelerations approaching ultimate collapse. The device (102) also includes a low pass filter and amplifier (105) that is connected to the accelerometer (104) for signal gains equal to 100 over a 0-30 Hz range.

Device (102) also includes at least one transmitter (106) that is connected to the filter and amplifier (105). Bandwidth capabilities of the transmitter (106) shall be specified by the requirements imposed by environmental conditions and the highest desired frequency content in the signal.

The device (102) also includes an independent first power source (107) that is connected to the accelerometer (104), the filter and amplifier (105) and the transmitter (106). The first independent power source (107) includes batteries. However, other sources of power adaptable to the device (102) are also within the scope of this invention.

Transmitter (106) transfers analog response signals obtained from device (102) to the display apparatus (103) through a wired communication line (108). This analog signal is received by a remote receiver (109). The wired communication line (108) is covered with a fire retardant/heat retardant material suitable for high temperatures. The analog signal is then transferred to an A-D converter (110). The A-D converter (110) then transfers the digitized signal to a computer system (111). The computer system (111) includes a computer processor unit (llla), a memory (lllb), a display screen (lllc) and a user input (llld). The computer processor unit (Illa) compares threshold values relating the acceleration responses to structural conditions. Based on these values, computer processor unit (llla) provides a signal to device (102) that is displayed on the on/off indicator (13b) as shown in figure l (a). The digitized signals can be displayed on display screen (lllc) and/or stored onto memory (lllb). Computer processor unit (llla) also provides on-site data reduction and analysis through designed software that allows for visual and audible characterizations of the measured responses on display (lllc). The remote receiver (109), the A-D converter (110) and the computer system (111) are connected to a

second independent power source (112). The second power source (112) can operate utilizing an internal power supply such as batteries. Other sources of power adaptable to the display apparatus (103) are also within the scope of this invention. The exterior casing and housing for device (102) is as shown in figure (la).

Figure 3 shows another embodiment of the present invention. Figure 3 of the present invention shows a wireless analog internal power system. System (201) of Figure 3 provides a lightweight, portable device (202) and a display apparatus (203) that are utilized to detect and monitor collapse conditions at the time of fire or damage. The device (202) of the system (201) includes at least one accelerometer (204) as a transducer for monitoring structural responses. Accelerometer (204) must be capable of monitoring acceleration in one to three axial directions (i. e. , x, y or z axis), preferably oriented perpendicular to a mounting surface, and operates in the range of 0-30 Hz. Accelerometer (204) monitors responses down to DC or zero Hz. This is because accelerometer (204) tracks very low frequency responses corresponding to the changing mean accelerations in the structures. Accelerometers that are not capable of monitoring DC responses will filter or

attenuate these responses around 4 Hz, and, therefore, be incapable of detecting changing mean accelerations approaching ultimate collapse. The device (202) also includes a low pass filter and amplifier (205) that is connected to the accelerometer (204) for signal gains equal to 100 over a 0-30 Hz range.

Device (202) also includes at least one transmitter (206) that is connected to the filter and amplifier (205). Bandwidth capabilities of the transmitter (206) shall be specified by the requirements imposed by environmental conditions and the highest desired frequency content in the signal.

The device (202) also includes an independent first power source (207) that is connected to the accelerometer (204), the filter and amplifier (205) and the transmitter (206). The first independent power source (207) includes batteries. However, other sources of power adaptable to the device (202) are also within the scope of this invention.

Transmitter (206) transfers analog response signals obtained from device (202) to the display apparatus (203) through a wireless communication line (208). This analog signal is received by a remote receiver (209). The analog signal is then transferred to an A-D converter (210). The

A-D converter (210) then transfers the digitized signal to a computer system (211). The computer system (211) includes a computer processing unit (211a), a memory (211b), a display screen (211c) and a user input (211d).

The computer processor unit (211a) compares threshold values relating the acceleration responses to structural conditions. Based on these values, computer processor unit (211a) provides a signal to device (202) that is displayed on the on/off indicator (13b) as shown in figure l (a). The digitized signals can be displayed on display screen (211c) and/or stored onto memory (211b).

Computer processor unit (211a) also provides on-site data reduction and analysis through designed software that allows for visual and audible characterizations of the measured responses on display (211c). The remote receiver (209), the A-D converter (210) and the computer system (211) are connected to a second independent power source (212). The second power source (212) can operate utilizing an internal power supply such as batteries.

Other sources of power adaptable to the display apparatus (203) are also within the scope of this invention. The exterior casing and housing for device (202) is as shown in figure (la).

Figure 4 depicts another embodiment of the present invention. Figure 4 shows a wired analog internal power system having an alternate power source. System (301), shown in Figure 4, provides a lightweight, portable device (302) and a display apparatus (303) that are utilized to detect and monitor collapse conditions at the time of fire or damage. The device (302) of the system (301) includes at least one accelerometer (304) as a transducer for monitoring structural responses.

Accelerometer (304) must be capable of monitoring acceleration in one to three axial directions (i. e. , x, y or z axis), preferably oriented perpendicular to a mounting surface, and operates in the range of 0-30 Hz.

Accelerometer (304) monitors responses down to DC or zero Hz. This is because accelerometer (304) tracks very low frequency responses corresponding to the changing mean accelerations in the structures. Accelerometers that are not capable of monitoring DC responses will filter or attenuate these responses around 4 Hz, and, therefore, be incapable of detecting changing mean accelerations approaching ultimate collapse. The device (302) also includes a low pass filter and amplifier (305) that is connected to the accelerometer (304) for signal gains equal to 100 over a 0-30 Hz range.

Device (302) also includes at least one transmitter (306) that is connected to the filter and amplifier (305). Bandwidth capabilities of the transmitter (306) shall be specified by the requirements imposed by environmental conditions and the highest desired frequency content in the signal.

The device (302) also includes a first power source (307) that is connected to the accelerometer (304), the filter and amplifier (305) and the transmitter (306). The first power source (307) is capable of operating independently, utilizing an independent power supply such as internal batteries. Alternatively, first power source (307) may also obtain power from the building power supply (308) onto which the device (302) is attached.

However, other sources of power adaptable to the device (302) are also within the scope of this invention.

Transmitter (306) transfers analog response signals obtained from device (302) to the display apparatus (303) through a wired communication line (309). The wired communication line (309) is covered with a fire retardant/heat retardant material suitable for high temperatures. This analog signal is received by a remote receiver (310). The analog signal is then transferred to an A-D converter (311). The A-D converter (311) then

transfers the digitized signal to a computer system (312). The computer system (312) includes a computer processor unit (312a), a memory (312b), a display screen (312c) and a user input (312d). The computer processor unit (312a) compares threshold values relating the acceleration responses to structural conditions. Based on these values, computer processor unit (312a) provides a signal to device (302) that is displayed on the on/off indicator (13b) as shown in figure l (a). The digitized signals can be displayed on display screen (312c) and/or stored onto memory (312b). Computer processor unit (312a) also provides on-site data reduction and analysis through designed software that allows for visual and audible characterizations of the measured responses on display (312c). The remote receiver (310), the A-D converter (311) and the computer system (312) are connected to a second power source (313). The second power source (313) can operate utilizing an internal power supply such as batteries. Other sources of power adaptable to the display apparatus (303) are also within the scope of this invention. The exterior casing and housing for device (302) is as shown in figure (la).

Figure 5 depicts a wireless analog internal power system having an alternate power source. System (401),

shown in Figure 5, provides a lightweight, portable device (402) and a display apparatus (403) that are utilized to detect and monitor collapse conditions at the time of fire or damage. The device (402) of the system (401) includes at least one accelerometer (404) as a transducer for monitoring structural responses.

Accelerometer (404) must be capable of monitoring acceleration in one to three axial directions (i. e. , x, y or z axis), preferably oriented perpendicular to a mounting surface, and operates in the range of 0-30 Hz.

Accelerometer (404) monitors responses down to DC or zero Hz. This is because accelerometer (404) tracks very low frequency responses corresponding to the changing mean accelerations in the structures. Accelerometers that are not capable of monitoring DC responses will filter or attenuate these responses around 4 Hz, and, therefore, be incapable of detecting changing mean accelerations approaching ultimate collapse. The device (402) also includes a low pass filter and amplifier (405) that is connected to the accelerometer (404) for signal gains equal to 100 over a 0-30 Hz range.

Device (402) also includes at least one transmitter (406) that is connected to the filter and amplifier (405). Bandwidth capabilities of the transmitter (406)

shall be specified by the requirements imposed by environmental conditions and the highest desired frequency content in the signal.

The device (402) also includes a first power source (407) that is connected to the accelerometer (404), the filter and amplifier (405) and the transmitter (406). The first power source (407) is capable of operating independently, utilizing an independent power supply such as internal batteries. Alternatively, first power source (407) may also obtain power from the building power supply (408) onto which the device (402) is attached.

However, other sources of power adaptable to the device (402) are also within the scope of this invention.

Transmitter (406) transfers analog response signals obtained from device (402) to the display apparatus (403) through a wireless communication line (409). This analog signal is received by a remote receiver (410). The analog signal is then transferred to an A-D converter (411). The A-D converter (411) then transfers the digitized signal to a computer processor system (412). The computer system (412) includes a computer processor unit (412a), a memory (412b), a display screen (412c) and a user input (412d). The computer processor unit (412a) compares threshold values relating the acceleration responses to

structural conditions. Based on these values, computer processor unit (412a) provides a signal to device (402) that is displayed on the on/off indicator (13b) as shown in figure l (a). The digitized signals can be displayed on display screen (412c) and/or stored onto memory (412b).

Computer processor unit (412a) also provides on-site data reduction and analysis through designed software that allows for visual and audible characterizations of the measured responses on display (412c). The remote receiver (410), the A-D converter (411) and the computer system (412) are connected to a second power source (413). The second power source (413) can operate utilizing an internal power supply such as batteries.

Other sources of power adaptable to the display apparatus (403) are also within the scope of this invention. The exterior casing and housing for device (402) is as shown in figure (la).

Figure 6 depicts a wired digital through cable system. System (501), shown in Figure 6, provides a lightweight, portable device (502) and a display apparatus (503) that are utilized to detect and monitor collapse conditions at the time of fire or damage. The device (502) of the system (501) includes at least one accelerometer (504) as a transducer for monitoring

structural responses. Accelerometer (504) must be capable of monitoring acceleration in one to three axial directions (i. e. , x, y or z axis), preferably oriented perpendicular to a mounting surface, and operates in the range of 0-30 Hz. Accelerometer (504) monitors responses down to DC or zero Hz. This is because accelerometer (504) tracks very low frequency responses corresponding to the changing mean accelerations in the structures.

Accelerometers that are not capable of monitoring DC responses will filter or attenuate these responses around 4 Hz, and, therefore, be incapable of detecting changing mean accelerations approaching ultimate collapse. The device (502) also includes a low pass filter and amplifier (505) that is connected to the accelerometer (504) for signal gains equal to 100 over a 0-30 Hz range.

An A-D converter (506) is connected to the filter and amplifier (505) to convert the incoming analog signal into a digital one. This signal is processed in signal processor (507) and passed onto identifier (508). The identifier (508) stamps the data as specific to the device (502) of the system (501).

Device (502) also includes at least one transmitter (509) that is connected to the identifier (508).

Bandwidth capabilities of the transmitter (509) shall be

specified by the requirements imposed by environmental conditions and the highest desired frequency content in the signal.

The device (502) also includes a first power source (510) that is connected to the accelerometer (504), the filter and amplifier (505), the A-D converter (506), the processor (507), the identifier (508) and the transmitter (509). The first power source (510) is capable of operating independently, utilizing an independent power supply such as internal batteries. The first power source (510) may also obtain power from an alternate power supply as described herein below. Other sources of power adaptable to the device (402) are also within the scope of this invention.

Transmitter (509) transfers analog response signals obtained from device (502) to the display apparatus (503) through a wired communication line (511). The wired communication line (511) is covered with a fire retardant/heat retardant material suitable for high temperatures. This signal is received by a remote receiver (512). The remote receiver (512) transfers the digitized signal to a computer system (513). The computer system (513) includes a computer processor unit (513a), a memory (513b), a display screen (513c) and a

user input (513d). The computer processor unit (513a) compares threshold values relating the acceleration responses to structural conditions. Based on these values, computer processor unit (513a) provides a signal to device (502) that is displayed on the on/off indicator (13b) as shown in figure l (a). The digitized signals can be displayed on display screen (513c) and/or stored onto memory (513b). Computer processor unit (513a) also provides on-site data reduction and analysis through designed software that allows for visual and audible characterizations of the measured responses on display (513c). The remote receiver (512) and the computer system (513) are connected to a second power source (514). The second power source (514) is also capable of providing power to the first power source (510) of the device (502). The second power source (514) can operate utilizing an internal power supply such as batteries.

Other sources of power adaptable to the display apparatus (503) are also within the scope of this invention. The exterior casing and housing for device (502) is as shown in figure (la).

Figure 7 shows another embodiment of a wired digital through cable system. The system (601), shown in Figure 7, provides a lightweight, portable device (602) and a

display apparatus (603) that are utilized to detect and monitor collapse conditions at the time of fire or damage. The device (602) of the system (601) includes at least one accelerometer (604) as a transducer for monitoring structural responses. Accelerometer (604) must be capable of monitoring acceleration in one to three axial directions (i. e. , x, y or z axis), preferably oriented perpendicular to a mounting surface, and operates in the range of 0-30 Hz. Accelerometer (604) monitors responses down to DC or zero Hz. This is because accelerometer (604) tracks very low frequency responses corresponding to the changing mean accelerations in the structures. Accelerometers that are not capable of monitoring DC responses will filter or attenuate these responses around 4 Hz, and, therefore, be incapable of detecting changing mean accelerations approaching ultimate collapse. The device (602) also includes a low pass filter and amplifier (605) that is connected to the accelerometer (604) for signal gains equal to 100 over a 0-30 Hz range. An A-D converter (606) is connected to the filter and amplifier (605) to convert the incoming analog signal into a digital one. This signal is processed in signal processor (607) and passed onto identifier (608).

Device (602) also includes at least one transmitter (609) that is connected to the identifier (608).

Bandwidth capabilities of the transmitter (609) shall be specified by the requirements imposed by environmental conditions and the highest desired frequency content in the signal.

The device (602) also includes a first power source (610) that is connected to the accelerometer (604), the filter and amplifier (605), the A-D converter (606), the processor (607), the identifier (608) and the transmitter (609). The first power source (610) is capable of operating independently, utilizing an independent power supply such as internal batteries. Other sources of power adaptable to the device (402) are also within the scope of this invention.

Transmitter (609) transfers analog response signals obtained from device (602) to the display apparatus (603) through a wired communication line (611). The wired communication line (611) is covered with a fire retardant/heat retardant material suitable for high temperatures. This signal is received by a remote receiver (612). The remote receiver (612) transfers the digitized signal to a computer processor unit (613). The computer system (613) includes a computer processor unit

(613a), a memory (613b), a display screen (613c) and a user input (613d). The computer processor unit (613a) compares threshold values relating the acceleration responses to structural conditions. Based on these values, computer processor unit (613a) provides a signal to device (602) that is displayed on the on/off indicator (13b) as shown in figure l (a). The digitized signals can be displayed on display screen (613c) and/or stored onto memory (613b). Computer processor unit (613a) also provides on-site data reduction and analysis through designed software that allows for visual and audible characterizations of the measured responses on display (613c). The remote receiver (612) and the computer system (613) are connected to a second power source (614). The second power source (614) can operate utilizing an internal power supply such as batteries. Other sources of power adaptable to the display apparatus (603) are also within the scope of this invention. The exterior casing and housing for device (602) is as shown in figure (la).

Figure 8 shows another embodiment of a wired digital through cable system. The system (701), shown in Figure 8, provides a lightweight, portable device (702) and a display apparatus (703) that are utilized to detect and

monitor collapse conditions at the time of fire or damage. The device (702) of the system (701) includes at least one accelerometer (704) as a transducer for monitoring structural responses. Accelerometer (704) must be capable of monitoring acceleration in one to three axial directions (i. e. , x, y or z axis), preferably oriented perpendicular to a mounting surface, and operates in the range of 0-30 Hz. Accelerometer (704) monitors responses down to DC or zero Hz. This is because accelerometer (704) tracks very low frequency responses corresponding to the changing mean accelerations in the structures. Accelerometers that are not capable of monitoring DC responses will filter or attenuate these responses around 4 Hz, and, therefore, be incapable of detecting changing mean accelerations approaching ultimate collapse. The device (702) also includes a low pass filter and amplifier (705) that is connected to the accelerometer (704) for signal gains equal to 100 over a 0-30 Hz range. An A-D converter (706) is connected to the filter and amplifier (705) to convert the incoming analog signal into a digital one. This signal is processed in signal processor (707)'and passed onto identifier (708).

Device (702) also includes at least one transmitter (709) that is connected tot the identifier (708).

Bandwidth capabilities of the transmitter (709) shall be specified by the requirements imposed by environmental conditions and the highest desired frequency content in the signal.

The device (702) also includes a first power source (710) that is connected to the accelerometer (704), the filter and amplifier (705), the A-D converter (706), the processor (707), the identifier (708) and the transmitter (709). The first power source (710) is capable of operating independently, utilizing an independent power supply such as internal batteries. Other sources of power adaptable to the device (702) are also within the scope of this invention.

Transmitter (709) transfers analog response signals obtained from device (702) to the display apparatus (703) through a wireless communication line (711). This signal is received by a remote receiver (712). The remote receiver (712) transfers the digitized signal to a computer processor unit (713). The computer system (713) includes a computer processor unit (713a), a memory (713b), a display screen (713c) and a user input (713d).

The computer processor unit (713a) compares threshold

values relating the acceleration responses to structural conditions. Based on these values, computer processor unit (713a) provides a signal to device (702) that is displayed on the on/off indicator (13b) as shown in figure l (a). The digitized signals can be displayed on display screen (713c) and/or stored onto memory (713b).

Computer processor unit (713a) also provides on-site data reduction and analysis through designed software that allows for visual and audible characterizations of the measured responses on display (713c). The remote receiver (712) and the computer system (713) are connected to a second power source (714). The second power source (714) can operate utilizing an internal power supply such as batteries. Other sources of power adaptable to the display apparatus (703) are also within the scope of this invention. The exterior casing and housing for device (702) is as shown in figure (la).

Figure 9 shows another embodiment of a wired digital through cable system. The system (801), shown in Figure 9, provides a lightweight, portable device (802) and a display apparatus (803) that are utilized to detect and monitor collapse conditions at the time of fire or damage. The device (802) of the system (801) includes at least one accelerometer (804) as a transducer for

monitoring structural responses. Accelerometer (804) must be capable of monitoring acceleration in one to three axial directions (i. e. , x, y or z axis), preferably oriented perpendicular to a mounting surface, and operates in the range of 0-30 Hz. Accelerometer (804) monitors responses down to DC or zero Hz. This is because accelerometer (804) tracks very low frequency responses corresponding to the changing mean accelerations in the structures. Accelerometers that are not capable of monitoring DC responses will filter or attenuate these responses around 4 Hz, and, therefore, be incapable of detecting changing mean accelerations approaching ultimate collapse. The device (802) also includes a low pass filter and amplifier (805) that is connected to the accelerometer (804) for signal gains equal to 100 over a 0-30 Hz range. An A-D converter (806) is connected to the filter and amplifier (805) to convert the incoming analog signal into a digital one. This signal is processed in signal processor (807) and passed onto. identifier (808).

Device (802) also includes at least one transmitter (809) that is connected to the identifier (808).

Bandwidth capabilities of the transmitter (809) shall be specified by the requirements imposed by environmental

conditions and the highest desired frequency content in the signal.

The device (802) also includes a first power source (810) that is connected to the accelerometer (804), the filter and amplifier (805), the A-D converter (806), the processor (807), the identifier (808) and the transmitter (809). The first power source (810) is capable of operating independently, utilizing an independent power supply such as internal batteries. Alternatively, the first power source (810) can also utilize power obtained from a building power supply (811) onto which the device (802) is attached. Other sources of power adaptable to the device (802) are also within the scope of this invention.

Transmitter (809) transfers analog response signals obtained from device (802) to the display apparatus (803) through a wired communication line (812). The wired communication line (812) is covered with a fire retardant/heat retardant material suitable for high temperatures. This signal is received by a remote receiver (813). The remote receiver (813) transfers the digitized signal to a computer system (814). The computer system (814) includes a computer processor unit (814a), a memory (814b), a display screen (814c) and a

user input (814d). The computer processor unit (814a) compares threshold values relating the acceleration responses to structural conditions. Based on these values, computer processor unit (814a) provides a signal to device (802) that is displayed on the on/off indicator (13b) as shown in figure l (a). The digitized signals can be displayed on display screen (814c) and/or stored onto memory (814b). Computer processor unit (814a) also provides on-site data reduction and analysis through designed software that allows for visual and audible characterizations of the measured responses on display (814c). The remote receiver (813) and the computer system (814) are connected to a second power source (815). The second power source (815) can operate utilizing an internal power supply such as batteries. Other sources of power adaptable to the display apparatus (803) are also within the scope of this invention. The exterior casing and housing for device (802) is as shown in figure (la).

Figure 10 shows another embodiment of a wired digital through cable system. The system (901), shown in Figure 10, provides a lightweight, portable device (902) and a display apparatus (903) that are utilized to detect and monitor collapse conditions at the time of fire or

damage. The device (902) of the system (901) includes at least one accelerometer (904) as a transducer for monitoring structural responses. Accelerometer (904) must be capable of monitoring acceleration in one to three axial directions (i. e. , x, y or z axis), preferably oriented perpendicular to a mounting surface, and operates in the range of 0-30 Hz. Accelerometer (904) monitors responses down to DC or zero Hz. This is because accelerometer (904) tracks very low frequency responses corresponding to the changing mean accelerations in the structures. Accelerometers that are not capable of monitoring DC responses will filter or attenuate these responses around 4 Hz, and, therefore, be incapable of detecting changing mean accelerations approaching ultimate collapse. The device (902) also includes a low pass filter and amplifier (905) that is connected to the accelerometer (904) for signal gains equal to 100 over a 0-30 Hz range. An A-D converter (906) is connected to the filter and amplifier (905) to convert the incoming analog signal into a digital one. This signal is processed in signal processor (907) and passed onto identifier (908).

Device (902) also includes at least one transmitter (909) that is connected to the identifier (908).

Bandwidth capabilities of the transmitter (909) shall be specified by the requirements imposed by environmental conditions and the highest desired frequency content in the signal.

The device (902) also includes a first power source (910) that is connected to the accelerometer (904), the filter and amplifier (905), the A-D converter (906), the processor (907), the identifier (908) and the transmitter (909). The first power source (910) is capable of operating independently, utilizing an independent power supply such as internal batteries. Alternatively, the first power source (910) can also utilize power obtained from a building power supply (911) onto which the device (902) is attached. Other sources of power adaptable to the device (902) are also within the scope of this invention.

Transmitter (909) transfers analog response signals obtained from device (902) to the display apparatus (903) through a wireless communication line (912). This signal is received by a remote receiver (913). The remote receiver (913) transfers the digitized signal to a computer system (914). The computer system (914) includes a computer processor unit (914a), a memory (914b), a display screen. (914c) and a user input (914d).

The computer processor unit (914a) compares threshold values relating the acceleration responses to structural conditions. Based on these values, computer processor unit (914a) provides a signal to device (902) that is displayed on the on/off indicator (13b) as shown in figure l (a). The digitized signals can be displayed on display screen (914c) and/or stored onto memory (914a).

Computer processor unit (914a) also provides on-site data reduction and analysis through designed software that allows for visual and audible characterizations of the measured responses on display (914c). The remote receiver (913) and the computer system (914) are connected to a second power source (915). The second power source (915) can operate utilizing an internal power supply such as batteries. Other sources of power adaptable to the display apparatus (903) are also within the scope of this invention. The exterior casing and housing for device (902) is as shown in figure (la).

The systems of figures 1 through 10 can be attached to the exterior of a structure (not shown) that is under burn or damage conditions and mounted to an exterior surface of the structure, using bolts or adhesives. The optimal mounting location is dependent upon the structure and accessibility by rescue workers. Placing device (2),

(102), (202), (302), (402), (502), (602), (702), (802) or (902) at a truss support height or at a mid span height (the ceiling height midway between the supports) is sufficient. Generally speaking, this placement is at a location of 8 ft from the ground. Placement on a top portion of a beam or truss is generally impractical, and also detrimental to the device (2), (102), (202), (302), (402), (502), (602), (702), (802) or (902) as it exerts added thermal stress. It is also mounted in a manner such that it is used to monitor acceleration responses perpendicular to the surface that it is mounted. And in a manner that does not penetrate the wall through to the drywall and framing.

Once mounted, accelerometer (4), (104), (204), (304), (404), (504), (604), (704), (804), or (904) begins to monitor acceleration responses (A) emitting from the structure at time of burn, and continues to monitor acceleration responses through actual collapse to post collapse.

Multiple devices of (2), (102), (202), (302), (402), (502), (602), (702), (802) or (902) can be mounted in this fashion, so that a plurality of surfaces can be monitored. Alternatively, a single device (2), (102), (202), (302), (402), (502), (602), (702), (802) or (902)

having multiple accelerometers (4), (104), (204), (304), (404), (504), (604), (704), (804), or (904) capable of monitoring and detecting acceleration responses in all directions (x-y-z axis) may be used. In yet another embodiment, a single device (2), (102), (202), (302), (402), (502), (602), (702), (802) or (902) having a single accelerometer (4), (104), (204), (304), (404), (504), (604), (704), (804), or (904) that monitors all three axes is also within the scope of the present invention.

The method and system discussed above, is not limited to detection at the time of collapse. Rather, the systems as shown in figures 1 through 10 of the present invention can be installed at time of structure construction. When the system of the present invention is pre-mounted, data acquisition captures the ignition event and continues past the time of structure collapse.

As a result, the data represent a complete sequence of events beginning prior to ignition, through ignition, structural response during burn, and actual collapse to post collapse response.

Test Data: A series of burn tests were conducted to determine collapse mechanism and to test the system and device of the present invention.

The Phoenix, Arizona test: A test burn of a truss support was conducted in Phoenix, Arizona. Figure 11 shows a graph of the acceleration responses over real-time, during the burn.

Phase 1 of the test was the pre-ignition event (occurring between 0-200 seconds). Phase 2 shows structural vibrations due to the fire (occurring between 200 and 400 seconds). Phase 3 is a transient response (occurring at approximately 500 seconds). Phase 4 shows structural vibrations due to the continued burn (occurring at approximately 700 seconds. Phase 5 shows the increasing structural response due to the fire compromising the structural integrity of the building.

Figure 12 (a) shows the acceleration response over time and corresponding to the graph shown in figure 11 and discussed above. The data points shown in figure 12 (a) were taken from different locations of the burning structure utilizing a second device.

Figure 12 (b) shows a graph of the data of figure 12 (a) subsequent to filtering. The data obtained from

the burn was filtered using a low pass filter to view a clean signal of the structural resonance, without ambient noise. Figure 12 (b) is an expanded view of a discrete time step within figure 12 (a). This view shows the sinusoidal motions occurring within the structure.

Figure 12 (c) shows a curve indicating a distinctive breakaway point that correlates to damage conditions, specifically, weakened structural support due to fire.

The increasing trend beyond 600 seconds is irreversible.

Since this point can be determined, this test provides proof that large increases or changes in acceleration, when detected early enough, as per the system and method of the present invention, will provide warning of impending collapse.

The Kingston, North Carolina test: Five single story wood frame houses were burned' through roof collapse. These structures were built according to post 1970 construction codes in the Kinston, NC area. These structures were restored in the aftermath of hurricanes in the region and were available to local fire fighting agencies for training exercises involving structural fires.

Three of the five houses were monitored for structural collapse. Due to the lightweight construction of these houses, the primary effect of the fire was to "eat away"at the roof and no real collapse mechanism was detected. Subsequently, a 250 gal capacity oil storage tank was placed on top of the roof of the last house.

The storage tank was filled with water to provide an approximate load of 1200 lbs. and strapped onto the roof to ensure a collapse scenario.

Four devices as per the present invention were installed around the perimeter of the house. At each location, the device of the system was mounted at an 8 ft height onto the exterior brick surface. The device was mounted using bolts, and care was taken not to penetrate the wall through to the drywall and wood stud framing.

The devices were oriented so that motion perpendicular to the wall could be monitored. The building was then set on fire.

Data acquisition began prior to ignition and continued past the time of roof collapse. As a result, the data represents a complete sequence of events prior to ignition, ignition, structural response during burn, actual roof collapse and post collapse response. Digital images and video images were also taken to establish a

time sequence. The occurrence of the collapse is substantiated by the video time sequence. All four of the devices survived the burn and the data presented in figure 13 was taken from one of the devices.

Figure 14 is a graph showing measured acceleration response time at the time of roof collapse. Wall response due to weakening roof joist members begins prior to 1880 seconds. The first peak occurs at approximately 1886 seconds, followed by increased dynamic sinusoidal response. Another peak occurs around 1898 seconds followed by another set of dynamic sinusoidal responses (around 1900 seconds). The first peak corresponds to the oil tank collapsing through the roof, while the second spike corresponds to impact of the tank on the hallway floor. The first set of sinusoidal responses are associated with the movement monitored on the exterior wall in the seconds leading up to collapse due to weakening roof joists, followed by the wall response as the tank is falling through the roof. The second set of sinusoidal responses is due to the tank impact on the hallway floor.