Abstract:
A thermal imaging camera having improved durability and ergonomic features including generally a seamless housing encompassing a thermal imaging core, a first handle, and a battery compartment. The housing is preferably positioned at a first end of the first handle and the battery compartment is positioned at the opposite end of the first handle. By positioning the first handle intermediate between the housing and the battery compartment, the center of gravity of the thermal imaging camera coincides generally with the handle when the thermal imaging camera is in use, that is when batteries are present within the battery compartment. The camera can also include a second handle positioned between the housing and the battery compartment, the second handle is preferably oriented generally parallel to and spaced apart from the first handle to facilitate passing of the thermal imaging camera between users. The camera also has improved water resistance, shock-resistance and other operational features.

Description:
This application claims the benefit of provisional applications Nos. 60/222,775, filed Aug. 3, 2000 and 60/186,509, filed Mar. 2, 2000. 
    
    
     FIELD OF THE INVENTION 
     The present invention relates to thermal imaging cameras and, especially, to thermal imaging cameras having improved durability and ergonomic features. 
     BACKGROUND OF THE INVENTION 
     Thermal imaging cameras (“TICs”)are a relatively new tool used, for example, by firefighters and other safety personnel to provide the ability to see heat sources in situations of limited visibility (for example in heavy smoke or darkness). Thermal imaging cameras find use in many scenarios including, but not limited to, executing search and rescue missions, assessing fire scenes, locating the seat of fires, determining the size and location of hot spots, identifying potential flashover situations, determining entry and ventilation points, evaluating hazardous material situations, providing an incident command “eye in the sky”, providing vehicle navigation, preplanning fire code inspections and assisting law enforcement officers. 
     Many thermal imaging cameras use ferroelectric thermal imaging. Ferroelectric cameras are solid-state infrared imagers that measure changes in heat by sensing changes in capacitance. The focal plane includes a plurality of small ceramic pixels that are made of sensing materials such as barium strontium titanate. An example of such a camera is the Argus 2 TIC sold by MSA and shown in MSA Bulletin No. 0119-23 (1999). 
     Pyroelectric vidicon tube cameras also detect changes in capacitance. Because the capacitance of a fixed scene on the focal plane does not change, the visible scene temperature must be artificially manipulated to generate an image in the case of pyroelectric and ferroelectric cameras. In such cameras, the blades of a chopper pass in front of the detector and effectively change the scene temperature with each pass. Each pass of a chopper blade causes a change in capacitance and allows the detector to see an infrared image. Examples of pyroelectric vidicon tube cameras are the Argus TIC and the Argus Plus TIC, previously sold by MSA and shown in MSA Bulletin Nos. 0105-16 (1997) and 0105-16 (1998), respectively. 
     Recently, microbolometers have been used in thermal imaging cameras. A microbolometer thermal detector is a sensor that measures changes in heat and infrared energy. It measures heat by sensing the changes in resistance of each pixel in the focal plane. The microbolometer detector is constructed of an array of pixels that are made of sensing materials such as vanadium oxide. Pixel resistance changes are directly related to temperature and allow the camera to produce an infrared image without the use of a chopper as is required with pyroelectric and ferroelectric cameras. 
     Because of the harsh conditions in which thermal imaging cameras are used, such cameras are preferably very durable. In the case of thermal imaging cameras used by firefighters, for example, the cameras can be exposed to extremely high temperatures as well as very wet conditions. Moreover, these cameras must also be adapted to dissipate any excess heat generated inside the camera due to its internal electronics. Although thermal imaging cameras should be durable, they should also be suitable for use by individuals having somewhat limited mobility and dexterity. In that regard, firefighters are equipped with protective clothing, including thick gloves, that limit their ability to accomplish certain tasks. Currently available thermal imaging cameras satisfy the above criteria to differing degrees. It, therefore, remains very desirable to develop thermal imaging cameras having improved ergonomics and durability. 
     SUMMARY OF THE INVENTION 
     The present invention provides a thermal imaging camera including generally a housing encompassing a thermal imaging core, a first handle, and a battery compartment. The housing is preferably positioned at a first end of the first handle and the battery compartment is positioned at the opposite end of the first handle. By positioning the first handle intermediate between the housing and the battery compartment, the center of gravity of the thermal imaging camera coincides generally with the handle when the thermal imaging camera is in use (that is, when batteries are present within the battery compartment). The camera can also include a second handle positioned between the housing and the battery compartment, the second handle is preferably oriented generally parallel to and spaced part from the first handle and facilitates the passing of the thermal imaging camera between two users. 
     In another aspect, the present invention provides a thermal imaging camera including resilient material placed over or around all projecting portions of the thermal imaging camera such that when the thermal imaging camera is contacted with a plane, the resilient material will first contact the plane regardless of the orientation of the thermal imaging camera relative to the plane. In other words, if the thermal imaging camera is dropped on a generally flat surface, the resilient material contacts the surface first, thereby reducing the likelihood of damage to the camera due to the shock-absorbing properties of the resilient material. 
     In one embodiment, the thermal imaging camera includes a housing encompassing a thermal imaging core, a handle, and a battery compartment. The housing is positioned at a first end of the handle and the battery compartment is positioned at the opposite end of the handle. The housing has resilient material surrounding a front end thereof and a rear end thereof. Likewise, a bottom portion of the battery compartment is also surrounded by resilient material. The resilient material can be in the form of elastomeric (for example, rubber) bumpers having shock-absorbing properties. 
     In another aspect, the present invention provides a thermal imaging camera including a housing encompassing a thermal imaging core, a first handle and a second handle. The first handle and the second handle are positioned to facilitate passing the camera between two people without setting the camera down. Any number of two-handle configurations will work including, for example, a “steering wheel” configuration with the camera located in the center and a plurality of spokes extending from the camera to the outer handles or ring. As described above in one preferred embodiment, the first handle and the second handle can be positioned generally parallel to and spaced apart from each other and can be positioned intermediate between the housing and the battery compartment. When the first handle and the second handle are positioned generally parallel to each other, the handles are preferably spaced at least 2.0 inches apart, more preferably at least approximately 2.25 inches apart, and most preferably at least approximately 2.5 inches apart, over the area in which the handles are to be grasped. 
     The present invention also provides in another aspect a thermal imaging camera including a water-resistant housing to contain the camera components. The housing has only a front opening and a rear opening and is formed without a seam therein such that the seamless housing of the present invention has only about ¼ of the sealing surface found in other TICs. The front opening preferably has a generally flat sealing surface; likewise, the rear opening preferably has a generally flat sealing surface both of which significantly reduce the likelihood or water intrusion into the housing. 
     In another aspect, the present invention provides a thermal imaging camera including a durable housing to contain at least one imaging component and at least one support member to position the imaging component within the housing without attaching or connecting the imaging component to the housing. The support member preferably has an exterior formed generally in the shape of the housing and an interior formed generally in the shape of the imaging component. The support member is preferably shock absorbing and/or thermally insulating. An example of a suitable material for the support member is a foamed polymer. Preferably, a plurality of components comprising the camera engine or camera core are positioned in the housing using such support members. 
     The present invention also provides a thermal imaging camera including a housing to contain at least one imaging component. The imaging component is at least partially abutted by a thermally insulating and shock absorbing material positioned between the housing and the imaging component. As discussed above, the thermally insulating and shock absorbing material can be a foamed polymer. 
     In another aspect, the present invention provides a thermal imaging camera including a power source that has at least a first battery and a second battery. The thermal imaging camera further includes circuitry so that power is first drawn from one of the first battery and the second battery and then from the other of the first battery and the second battery. The first battery and the second battery are preferably replaceable while the thermal imaging camera is operating. For example, the first battery can be drawn down until power is switched to the second battery. The first battery can then be replaced during operation while the camera is being powered by the second battery. Later the second battery can be replaced while the camera is being powered by the other battery and so on. In this manner, the thermal imaging camera can be operated for long periods of time without shutting down the camera to replace batteries. 
     In still a further aspect, the present invention provides a thermal imaging camera including a generally flat surface thereon whereby the thermal imaging camera can be set in an upright position on a generally flat surface. In one embodiment, the thermal imaging camera includes a housing encompassing a thermal imaging camera core, a battery compartment, and at least a first handle positioned between the housing and the battery compartment. In this embodiment, the bottom of the battery compartment is generally flat so that the thermal imaging camera can be set in an upright position on a generally flat surface such that the camera display is easily visible and the image thereon is also in an upright position. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     FIG. 1 is a perspective view of an embodiment of a thermal imaging camera of the present invention. 
     FIG. 2 is a rear elevational view of the camera shown in FIG.  1 . 
     FIG. 3 is a front elevational view of the camera shown in FIG.  1 . 
     FIG. 4 is a side elevational view of the camera shown in FIG.  1 . The left and right side elevational views are mirror images of each other. 
     FIG. 5 is a top plan view of the camera shown in FIG.  1 . 
     FIG. 6 is a bottom plan view of the camera shown in FIG.  1 . 
     FIG. 7 is a perspective view of the camera shown in FIG. 1 in an assembled state with identifying numbers. 
     FIG. 8 is a perspective view of the thermal imaging camera of FIG. 7 in a disassembled state. 
    
    
     DETAILED DESCRIPTION OF THE INVENTION 
     FIGS. 1-6 show various external views of a preferred embodiment of the thermal imaging camera of the present invention. Attached hereto as Appendix 1 is the final version of the Operations and Instruction Manual for the Evolutions™ 4000 Thermal Imaging System, the disclosure of which is incorporated herein by reference. 
     In the embodiment shown in FIGS. 7 and 8, thermal imaging camera  10  includes a housing  20 . Housing  20  can, for example, be fabricated from a molded polymeric material. Preferably, housing  20  is fabricated in a manner to provide a good seal against water entering housing  20 . In that regard, housing  20  is preferably formed as a continuous tube or conduit without seams along the length thereof. As shown in FIG. 8, housing  20  includes a first opening  30  at the rear thereof and a second opening  40  at the front thereof. Preferably, each of opening  30  and opening  40  are provided with a generally flat sealing surface (for example, sealing surface  35 ) around the perimeter thereof. Typically, generally flat sealing surfaces are more easily and reliably sealed than a curved surface. Housing  20  can therefore be better sealed (for example, against water damage) than is possible with currently available thermal imaging cameras. Moreover, the length of the sealing surface of the housing of the present invention is about one-fourth that found in currently available TICs. 
     Housing  20  encloses a thermal imaging camera core  100  which is an assembly of camera components that preferably includes imaging components such as a microbolometer thermal detector as described above. An example of a suitable camera core  100  for use in the present invention is the Uncooled Infrared Imaging Module, SIM 200S w/Lens available from Sanders, a British Aerospace company, located in Lexington, Mass. That camera core includes an uncooled microbolometer focal plane array assembly; a focal plane front end printed circuit board assembly (PCBA); a video signal processor PCBA; a power supply/shutter drive PCBA; a shutter drive; a lens assembly and a mounting. Camera core  100  preferably also includes a heat sink  110  to absorb heat generated internal to the camera  10 . Heat sink  110  can, for example, include an aluminum housing that is filled with a phase change material such as the ComforTemp® material available from Frisby Technologies of Winstom-Salem, N.C. 
     Camera core  100  can also include a remote transmitter  120  (for example, an RF transmitter operating at 2.4 Giga Hertz) having an antenna  130  to transmit video produced by camera  10  to a remote receiver/monitor (not shown). A suitable transmitter for use in the present invention is the Minilink 2.4TA transmitter available from MicroTek Electronics, Inc. of Sam Clemente, Calif. 
     Camera core  100  is preferably held in place within housing  20  by, for example, support members  200   a  and  200   b.  The exterior profile of support members  200   a  and  200   b  preferably conforms generally to the shape of the inner wall of housing  20  while the interior profile of support members  200   a  and  200   b  conform generally to the shape of camera core  100 . Such support members are preferably fabricated from a thermally insulating and shock absorbing material such as a foamed polymeric material. An example of a suitable foamed polymeric material for support members  200   a  and  200   b  is E-PAC, an expanded polypropylene foam, available from Tuscarora Incorporated of New Brighton, Pa. E-PAC is described in E-PAC: Electronic Packaging Assembly Concept available from Tuscarora Incorporated at www.tuscarora.com/epac.htm, the disclosure of which is incorporated herein by reference. Use of support members  200   a  and  200   b  instead of rigidly mounting or connecting camera core  100  to housing  20  allows for simple, quick and relatively inexpensive assembly. Moreover, use of support members such as support member  200   a  and  200   b  have been found to improve the thermal resistance and shock resistance of thermal imaging camera  10  as compared to currently available thermal imaging cameras. Preferably, support members for use in the present invention have a thermal conductivity in the range of approximately 0.01 BTU/ft-hr.−°F. to approximately 1.0 BTU/ft -hr.−°F. Such materials can also be shock absorbing by, for example, being compressible or resilient. 
     Camera  10  also includes a display  300  such as an LCD display as known in the art in communication with camera core  100 . As described for camera core  100 , display  300  is preferably held in place within housing  20  by a support member  200   c  of the type discussed above. The exterior perimeter or profile of support member  200   c  preferably generally conforms to the shape of housing  20  while the interior profile thereof generally conforms to display  300 . 
     In general, thermal imaging cameras are operated over a wide range of thermal conditions including, for example, at subfreezing temperatures, at room temperature, and at the highly elevated temperatures experienced by firefighters at a fire scene. Many electronic components are adversely affected by extreme temperatures. The thermally insulating nature of the support members of the present invention enable camera  10  to be operated for extended period of times at elevated temperatures and at subfreezing temperatures. 
     A number of the components of camera  10  generate heat during operation. This presents a problem at elevated temperatures. These heat generating components include, for example, components having processors such as camera core  100  and display  300 . Care must be taken to not trap such internally generated heat within camera  10  such that failures occur, even at ambient temperature. For this reason, support members  200   a-c  are preferably designed to insulate the internal components of camera  10  from high external or ambient temperatures while, at the same time, allowing heat generated by these components within camera  10  to dissipate at lower ambient temperatures. For example, support member  200   c  is preferably designed with a profile that is deeper (in the longitudinal direction of housing  20 , that is, front-to-back) than display  300 . This dimensioning of support member  200   c  creates a void behind display  300  into which heat generated by display  300  can be dissipated. Moreover, support members  200   a  and  200   b  are preferably formed with one or more open areas such as areas  205   a,    205   b,    210   a  and  210   b  through which heat generated within camera core  100  can be dissipated. The design of support members  200   a  and  200   c  are preferably optimized to allow dissipation of internally generated heat at ambient temperature and above while protecting the components within housing  20  from external heat at elevated temperatures high above ambient temperature. Because of the many different types of electrical components that can be used within the thermal imaging cameras of the present invention (and the widely varying heat generating and dissipating properties of such components), such optimization is preferably readily performed empirically. For example, the temperature at various points within camera  10  can be measured for various support member designs and for various temperatures. 
     Front opening  30  is preferably enclosed and sealed via, for example, a clear polycarbonate window  400  and an intermediate gasket  410  that cooperates with generally flat sealing surface  35  to produce a substantially waterproof seal. A cover lens  420  can be provided over polycarbonate window  400 . A resilient bumper  430  (for example, a rubber bumper) is preferably provided to surround the perimeter of front opening  30  of housing  20 . Resilient bumper  430  assists in absorbing the shock of an impact if the camera  10  is dropped or bumped. 
     A germanium window  500  is preferably provided on the front end of camera  10 . Front opening  40  is preferably sealed by a front plate  510  and an intermediate gasket  520  that cooperates with a generally flat sealing surface (not shown) of opening  40 . Front plate  510  also seats germanium window  500 . The front end of camera  10  is preferably provided with a resilient bumper  530 . Like resilient bumper  430 , resilient bumper  530  assists in absorbing the shock of an impact in the event that the camera  10  is dropped or bumped. 
     A handle assembly  600  is preferably attached to the bottom of housing  20 . Handle assembly  600  preferably forms a first handle  610  and a second handle  620  (as best illustrated in FIG.  7 ). Generally vertically oriented handles  610  and  620  are preferably spaced sufficiently far apart to facilitate passing of thermal imaging camera  10  from one firefighter to another even while wearing gloves. In the case of generally parallel handles  610  and  620 , the handles are preferably spaced at least 2.0 inches apart, more preferably at least approximately 2.25 inches apart, and most preferably at least approximately 2.5 inches apart, over the area in which handles  610  and  620  are to be grasped by users. Rear handle  610  is used when operating camera  10  while forward handle  620  is used to pass the camera (in an upright position) to another person. 
     A battery compartment  700  is preferably formed at the bottom of handle assembly  600 . Preferably, battery unit  710  and batteries  712  and  714  are easily insertable in and removable from battery compartment  700  even by a user wearing heavy protective gloves. In the embodiment shown in FIG. 8, for example, battery compartment  700  includes a bracket  720  that retains batteries  712  and  714  (via groove  715 ) within battery compartment  700 . Bracket  720  is preferably rotatable out of alignment with battery unit  710  to insert or remove batteries  712  and  714 . Preferably, camera  10  is provided with multiple batteries that are hot swappable. For example, two batteries  712  and  714  can be used serially. In that regard, circuitry is provided so that one battery is used before the second battery. The used battery can preferably be replaced while the second battery is in service without interrupting operation of camera  10 . 
     The bottom of battery compartment  700  is preferably surrounded by a resilient bumper  730  (for example, rubber) to assist in absorbing the shock of an impact if the camera  10  is dropped or bumped. Resilient bumpers  430 ,  530  and  730  cover all the extremities or projecting portions of camera  10  such that if camera  10  is dropped on a flat surface or plane, one of the resilient bumpers will always first contact the surface or plane regardless of the orientation of camera  10 . 
     By placing housing  20  above handle  610  and battery compartment  700  below handle  610 , the center of gravity of camera  10  coincides generally with the location at which the user holds camera  10 . Because the center of gravity of camera  10  coincides with the user&#39;s grip, the camera feels lighter and more balanced than currently available cameras of similar weight. Typically, such cameras place the housing, imaging components and power source above the handle. 
     The bottom of camera  10  is preferably generally flat so that camera  10  can be set upright on a generally flat surface for use without the requirement of a user holding camera  10 . In that regard, the bottom surface of resilient bumper  730  is preferably generally flat. Camera  10  can thus be operated/viewed in an upright position by a user without the user having to hold camera  10 . To facilitate such operation (and general operation), display  300  is preferably larger than is the case with prior thermal imaging cameras. In one embodiment of the present invention, for example, display  300  had a diagonal measurement of approximately five inches. 
     Although the present invention has been described in detail in connection with the above examples, it is to be understood that such detail is solely for that purpose and that variations can be made by those skilled in the art without departing from the spirit of the invention except as it may be limited by the following claims.