Abstract:
A self-contained automatic fire extinguishing device that is located within a wall or ceiling and housed within the space between two studs or joists. This unit includes a tank or series of tanks attached via flexible pressurized joints, and held in place by an expanding bracket. This fire extinguisher maintains a constantly high pressure inside a shell of the fire extinguisher through out a shelf-life of the fire extinguisher and which can indicate the charge status of the tank via a visible indicator. A sensor is attached to the unit, which reacts to prolonged exposure to direct heat and which can extend a nozzle beyond the wall or ceiling into the living space when actuated. The self-contained automatic fire extinguishing device is hidden behind a decorative face plate which permits the passage of the sensing device and a tank fill status indicator and which actuates out of the path of the nozzle upon activation. Prior to activation, an audible warning is sounded from the device to indicate the presence of a fire and an impending activation. Once activated, the fire extinguisher contents are dispersed into the space thus significantly retarding or completely extinguishing the fire.

Description:
CLAIM OF PRIORITY 
       [0001]    This application claims the benefit of priority of U.S. provisional application No. 60/901,948 filed Feb. 16, 2007, which is incorporated herein by reference. 
     
    
     FIELD OF THE INVENTION 
       [0002]    The present invention relates to fire extinguishers, and more particularly relates to an automatically operated fire extinguisher for use within a residential or commercial dwelling. 
       BACKGROUND 
       [0003]    The use of automatically activated fire extinguishing devices for commercial purposes is known. Such devices typically disperse fire extinguishing compound into a space, room or area. These devices are typically connected to pipes containing water under pressure. The prior art devices, however, are relatively bulky, unsightly and expensive to retrofit into existing homes. Some prior art automatic fire extinguishing devices store the fire extinguishing compound in a container which is either at a location remote from where the agent is dispersed or within an unsightly compartment which protrudes into the living or working space. 
         [0004]    The prior art automatic fire extinguishing devices have the disadvantage of requiring a significant amount of time for installation, and significant expense over and above that typically required to install the in-wall/in-ceiling unit. This is due to the elaborate piping required to transport the fire extinguishing compound from the storage container to the spraying device. Moreover, the prior art automatic fire extinguishing devices also have the drawback that as the distance between the storage container and the spraying device (e.g. nozzles) is increased, a greater force is required to project the fire extinguishing compound. The in-wall/in-ceiling automatic fire extinguishing unit of the present invention can house one or multiple containers in series behind the drywall of a wall or ceiling with only an oval opening covered by an aesthetically pleasing decorative face plate of any shape or size. 
         [0005]    The prior art storage container is limited by the unsightly appearance of the storage container and, the spray device (i.e., nozzle) typically extends into the room. The spray device and container generally detract from the overall appearance and is thus a deterrent to installation from an aesthetic perspective. 
         [0006]    The prior art automatic fire extinguishing device has the further drawback that it must also have an unsightly fire sensing mechanism, which must protrude into the space, to determine the existence of a fire. The fire sensing mechanism, like the spray device and the self-contained box, is readily visible and detracts from the home&#39;s appearance. 
         [0007]    There is thus a need for a fire extinguishing device which is unobtrusive, aesthetically and architecturally pleasing in appearance, relatively lightweight and streamlined, easy to self-install, self-contained, and does not require a substantial amount of time and money to install yet provides maximal protection to a home&#39;s occupants, heretofore unavailable to existing home owners. 
         [0008]    None of the prior art, taken either singly or in combination, is seen to describe the invention as claimed. 
       SUMMARY OF THE INVENTION 
       [0009]    The present invention is an article of manufacture comprising a self contained automatic fire extinguishing device having an expandable mounting bracket. In addition, the invention may further comprise a self contained automatic fire extinguishing device having at least two or more tanks containing a fire extinguishing agent, wherein said tanks are connected by at least one flexible pressurized joint. Also, the present invention teaches a self contained automatic fire extinguishing device capable of being installed in a wall or ceiling cavity, wherein said fire extinguishing device has an expandable mounting bracket which moves from a closed to an open position after the fire extinguishing device is inserted into said cavity. Finally, the invention teaches a method of installing a self contained automatic fire extinguishing device, comprising creating a hole in a wall or ceiling, inserting said self contained automatic fire extinguishing device into said hole, the self contained automatic fire extinguishing device having at least two or more tanks containing a fire extinguishing agent, wherein said tanks are connected by at least one flexible pressurized joint; and covering said hole with a decorative discharge plate. 
         [0010]    It is accordingly an object of the present invention to provide an automatic fire extinguishing device for an existing home or other dwelling which is aesthetically pleasing, compact, self-contained and easy to install. 
         [0011]    It is another object of the present invention to provide an automatic fire extinguishing device in which the fire extinguisher container, actuating mechanism and nozzle present no visible or obtrusive appearance other than that of a decorative face plate within a room or space. 
         [0012]    It is an object of the present invention to teach an automatic fire extinguishing device where the sensor assembly and nozzle assembly are substantially flush with the plane of the wall or ceiling. 
         [0013]    It is yet another object of the present invention to provide an automatic fire extinguishing device which does not require an extensive amount of time and expense for installation. 
         [0014]    It is a further object of the present invention to provide an automatic fire extinguishing device which overcomes inherent disadvantages of known automatic fire extinguishing devices. 
         [0015]    It is also an object of the invention to teach a fire extinguishing device having a sprinkler head attached thereto. 
         [0016]    It is an additional object of the invention to provide a self contained automatic fire extinguishing device suitable for use in any dwelling, residential or commercial, in houses, apartments, condominiums, and all types of commercial properties, of any size or of any number of rooms. 
         [0017]    It is a further object of the present invention to provide a self-contained automatic fire extinguishing device that is located within a wall or ceiling and housed within the space between two studs or joists. 
         [0018]    It is a further object of the present invention to provide a unit which includes a container or series of containers attached via flexible pressurized joints, and held in place by an expanding bracket. 
         [0019]    It is a further object of the present invention to provide a fire extinguisher which maintains a constantly high pressure inside a shell of the fire extinguisher through out a shelf-life of the fire extinguisher and which can indicate the charge status of the tank via a visible indicator. 
         [0020]    It is a further object of the present invention to provide a unit which is attached to a sensor which reacts to prolonged exposure to direct heat and which can extend beyond the wall or ceiling into the living space when actuated. 
         [0021]    It is a further object of the present invention to provide a self-contained automatic fire extinguishing device which is hidden behind a decorative face plate which permits the passage of the sensing device and a tank fill status indicator and which actuates out of the path of the sprinkler head upon activation. 
         [0022]    It is a further object of the present invention to provide a self-contained automatic fire extinguishing device which, prior to activation, emits an audible warning sound from the device to indicate the presence of a fire and an impending activation. 
         [0023]    It is a further object of the present invention to provide a self-contained automatic fire extinguishing device which, once activated, can disperse fire extinguisher contents into a living space and thus significantly retarding or completely extinguishing a fire. 
         [0024]    It is also an object of the present invention to teach a method of networking the self contained, automatic fire extinguishers of the present invention together so that if one is actuated in a dwelling, then one or more other extinguishers are actuated. 
         [0025]    It is a further object of the present invention to provide a self-contained automatic fire extinguishing device which, is activated by a heat sensitive actuator connected to a control box. The control box receives and processes the heat signal, emits a warning sound (of user adjustable time period and volume) and then causes the fire extinguisher to disperse its contents into a living space and thus significantly retarding or completely extinguishing a fire. 
     
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
         [0026]      FIG. 1  is a perspective view of a self contained automatic sprinkling device, showing the tank assembly having a primary tank, and intermediate tank, and a lower tank, connected by flexible pressurized joints. Also seen is the nozzle assembly and sensor assembly. 
           [0027]      FIG. 2  is a top view of a preferred embodiment of the invention, showing the primary tank and the nozzle assembly and the sensor assembly. 
           [0028]      FIG. 3  is a left side view of a preferred embodiment of the invention showing the tank assembly having a primary tank, and intermediate tank, and a lower tank, connected by flexible pressurized joints. Also seen is the nozzle assembly and sensor assembly. 
           [0029]      FIG. 4  is a right side view of a preferred embodiment of the invention showing the tank assembly having a primary tank, and intermediate tank, and a lower tank, connected by flexible pressurized joints. Also seen is the nozzle assembly and sensor assembly. 
           [0030]      FIG. 5  is a front view of a preferred embodiment of the invention showing the tank assembly having a primary tank, and intermediate tank, and a lower tank, connected by flexible pressurized joints. Also seen is the nozzle assembly and sensor assembly. 
           [0031]      FIG. 6  is a rear view of a preferred embodiment of the invention showing the tank assembly having a primary tank, and intermediate tank, and a lower tank, connected by flexible pressurized joints. Also seen is the nozzle assembly and sensor assembly. 
           [0032]      FIG. 7  is a perspective view of a preferred embodiment of the invention, showing an embodiment only having a primary tank and a lower tank. Also shown is the expandable mounting bracket, as well as the nozzle assembly and the sensor assembly. 
           [0033]      FIG. 8  is a perspective view of a preferred embodiment of the invention, showing the invention installed between two parallel surfaces, with the mounting bracket expanded and multiple intermediate tanks. 
           [0034]      FIG. 9  is a side view of the invention, showing the invention being installed in a wall cavity. This figure shows how the flexible joints facilitate installation of the device. 
           [0035]      FIG. 10  is a partial cutaway view of the invention, showing the invention installed in a wall cavity. The drawing shows the decorative mounting plate with hinge and capture. It further shows the sensor and indicator protruding through the decorative plate. 
           [0036]      FIG. 11  is a perspective view of an alternate embodiment of the invention, where multiple tanks are connected to the primary tank by means of a flexible conduit. 
           [0037]      FIG. 12  is a partial side view of the invention in its ready position. 
           [0038]      FIG. 13  is a partial side view of the invention in operation, where the nozzle has extended, the decorative plate opened and the fire extinguishing agent begun dispersing. 
           [0039]      FIG. 14  is a perspective view of another preferred embodiment showing a conventional sprinkler head attached to the nozzle casing. 
       
    
    
     DESCRIPTION OF THE PREFERRED EMBODIMENT 
       [0040]    The preferred embodiments of the present invention will now be described with reference to  FIG. 1-13  of the drawings. Identical elements in the various figures are identified with the same reference numerals. 
         [0041]    The invention is a self contained automatic fire extinguisher that can be placed in a wall or ceiling cavity. By “self contained” it is meant that the components necessary to detect and extinguish or retard a fire are fashioned into a single unit. For example, while the unit may have some components which are powered by battery power, it is not expected that the unit will require external power sources. Also, the unit will operate without external connections to piping, etc. for extinguishing agent or pressure. By “automatic” it is meant the extinguishing device can react to a fire without human intervention. 
         [0042]    Referring now to the figures,  FIG. 1-5  show the automatic fire extinguisher  10  of the present invention in perspective, top, left and right side views, and front and rear views respectively. Automatic fire extinguisher  10  has tank assembly  100 , nozzle assembly  200  and sensor assembly  300 . 
         [0043]    Primary tank  120  has dome  122 , optional divider  124  (not shown), wall  126 , bottom  128 , bottom edge  130 , and bottom opening  132 . Optional intermediate tank or tanks  140 , have top  142 , top opening  144 , top edge  146 , wall  148 , bottom  150 , bottom edge  152 , and bottom opening  154 . Optional lower tank  160 , has top  162 , top opening  164 , top edge  166 , wall  168 , bottom  170 , and bottom edge  172 . 
         [0044]    The fire extinguisher of the present invention can comprise just a primary tank  120 , or, in other embodiments, may include one or more intermediate tanks  140  and or lower tank  160 . The tanks are preferably constructed of metal, such as aluminum, stainless steel or steel, depending on the type of extinguishing agent used, and the walls are of sufficient thickness to maintain the tank&#39;s integrity under pressure. Other materials such as fire resistant plastics or rubber optionally reinforced with cloth or fiber may be used in construction of the tank if they are of sufficient strength and thickness to maintain the tank&#39;s integrity under pressure, and if they can withstand the high heat levels associated with a fire. While it is expected that the tanks will preferably consist of single hollow vessels, it is possible that in other embodiments the tank could have multiple chambers. For example, some fire extinguishing systems rely on liquefied or pressurized gas, and in those cases an additional chamber or cartridge may be necessary. Also, differing extinguishing agents or agents requiring two components, such as in some dry extinguisher systems, must be stored separately and therefore may require separate chambers. 
         [0045]    The tanks should be sized to fit within the space defined by a wall or ceiling. A “wall cavity” or “ceiling cavity” contains one or more substantially parallel surfaces and is the area defined by the wall studs or ceiling joists and the inside surface of the front and back wall covering. The front and back wall covering can be made of typical construction materials such as, but not limited to, plaster, wallboard, ceiling joists, wall studs, plywood and combinations thereof. The studs, joists, etc. can be constructed of typical building materials such as wood, stone, brick, metal, plywood, engineered materials, etc. 
         [0046]    Thus, in a preferred embodiment, the diameter of the tanks would be between 1 and 6 inches, the larger sizes being meant to accommodate deeper walls or ceiling installations, the smaller diameters being preferred for standard wall cavities of about 3.5″. The primary tank will have a height of between 2″ and 12″ while the intermediate tanks and lower tanks will have a height of between 1″ and 12″. The tank(s) will be of sufficient capacity to cover an entire room, yet fit through a small opening in a wall or ceiling. 
         [0047]    The number of tanks can be varied depending on the type of fire extinguishing agent used, the area or size of room to be protected, and the number of fire extinguishing devices that will be installed in a given room. The fire extinguisher of the present invention could be made as a single pre-manufactured unit without variation in the size or number of tanks, or made on a custom basis with each unit individually configured depending on the floor plan of a particular house, or each fire extinguisher being custom configured with the appropriate number of tanks based on the size of the room to be covered. 
         [0048]    Primary tank  120  has dome portion  122  connected to tank wall  126 . Dome portion  122  serves as a support for nozzle assembly  200  and sensor assembly  300 . Dome portion  122  can simply be an extension of wall  126 , wherein it would contain fire extinguishing agent  450  or if primary tank has divider  124  (not shown) then the area under dome portion  122  can house electrical or mechanical components of the invention, such as components for sensor  306 , status indicator  304 , audible alarm or networking device. 
         [0049]    Depending on the type of extinguishing agent used, primary tank  120  may also hold a cartridge filled with liquid carbon dioxide, or other pressurized or liquefied gas or non-toxic extinguishing agent. If this is the case, then there may also be a siphon tube  354  which runs from the nozzle  208  to the bottom of the primary tank  120  or the lower tank  160 . See  FIG. 10 . When the sensor senses a fire, the actuator opens the gas cartridge, the gas evaporates and creates pressure, forcing the fire extinguishing agent out of the siphon tube and through the nozzle into the burning room. 
         [0050]    While the drawings show the primary shape of the tanks as cylindrical, other tank shapes are possible. For example, the automatic fire extinguisher of the present invention could have a bottom tank with an oblate rounded edge (i.e. inverted dome) that will facilitate placement within a wall or ceiling cavity. Tanks with rounded top or dome shaped edges could facilitate the removal of the device from the wall for maintenance or recharging. Other embodiments are possible, such as spheroids (either prolate or oblate), spherical or rectangular shaped tanks. 
         [0051]    The tanks are connected by flexible pressurized joints  180 , having flexible tube  182 , internal diameter  184 , first connection  186  and second connection  188 . 
         [0052]    The flexible pressurized joint  180  connects two tanks. It can be any type of joint that allows the two tanks to move in spatial relation to each other, in order to further the objects of the invention. For example, the flexible pressurized joint could be hinged joint, or other flexible joint. The flexible pressurized joint is preferably a flexible tube created from rubber, vinyl, plastic, flexible steel, flexible steel braid, or any other flexible material that can be pressurized and can withstand the weight of one or more intermediate or bottom tanks. The material selected should be non-reactive with fire extinguishing agent and withstand temperatures consistent with industry standards as well as federal and local regulations and in the case of rubber, vinyl or plastic may be reinforced with fiberglass, fiber, cloth or other material. Composites and combinations of the aforementioned materials may also be used, such as flexible steel having a liner of rubber, vinyl or plastic. 
         [0053]    The internal diameter  184  of the flexible pressurized joint  180  should be sufficient size to allow rapid passage of the fire extinguishing agent from one tank to another during charging or discharge. The flexible tube  182  should be of a length sufficient to allow the fire extinguisher to flex in the manner illustrated in  FIG. 9  during installation. 
         [0054]    The flexible pressurized joint has first connection  186  and second connection  188  that allow the end of the flexible pressurized joint to sealably connect with the tank. The joint should be sufficiently sealed so the system remains free of leaks over long periods of time, preferably at least several years. The connections can be male and female threaded connectors, interlocking grommets that create a seal when mated, crimp type joints, flanged connectors, or integrated components during manufacturing. For example, bottom opening  132 ,  154  and/or top opening  144  and  164  could be tapped with female threads and flexible tube  182  could have matching threaded male connectors. See  FIG. 10 . 
         [0055]    The automatic fire extinguisher of the present invention also has nozzle assembly  200 , nozzle support  202 , nozzle casing  204 , nozzle extension  206 , nozzle  208  and aperture  210 . Nozzle support  202  is preferably metal, such as steel, stainless steel or aluminum but could be constructed from plastic or rubber. It can be of any configuration necessary to support the nozzle casing  204 . It is of sufficient diameter to allow fire extinguishing agent to discharge rapidly from the primary tank  120  and into nozzle  208 . It may be desirable in some embodiments to rotatably connect nozzle support  202  to primary tank  120  so that nozzle  208  can rotate laterally, at least during initial installation, in order to provide some adjustability to where the nozzle  208  points during discharge of the fire extinguishing agent. 
         [0056]    Nozzle casing  204  is preferably metal, such as steel, stainless steel or aluminum but could be constructed from fire resistant plastic or rubber. It can be of any configuration necessary to support the nozzle extension  206 . It may be desirable in some embodiments to rotatably connect nozzle casing  204  to nozzle support  202  so that nozzle  208  can rotate laterally or longitudinally, at least during initial installation, in order to provide some adjustability to where the nozzle  208  points during discharge of the fire extinguishing agent. 
         [0057]    In preferred embodiments, nozzle extension  206  allows nozzle to protrude into a room during a fire. During a fire, nozzle extension  206  and nozzle  208  extend past the plane of the wall or ceiling, and nozzle extension  206  can be any mechanical method that allows the movement of nozzle  208  from behind wall  508  past wall  508  and into a room. In one preferred embodiment, nozzle  208  can also be a traditional fire sprinkler head. Nozzle extension  206  is preferably a telescoping mechanism made from successively smaller diameter sections of tubing as seen in  FIG. 1 . Once the discharge of the extinguishing agent begins, pressure forces nozzle  208  forward. Other extension assemblies are possible, such a wound plastic coil or bent tube that expands into a straight tube when filled with fire extinguishing agent under pressure. In the alternative, nozzle extension  206  could be stationary, and nozzle  208  could be designed to spray the fire extinguishing agent into the room. In another preferred embodiment nozzle  208  is a traditional fire sprinkler head, as seen in  FIG. 14 . Thus, a sprinkler head could be attached to the nozzle extension  206  and extend into the room as discussed, or it could be stationary and disposed directly on nozzle extension  206  and/or nozzle casing  204  and/or nozzle support  202 . 
         [0058]    Nozzle  208  has an aperture  210  designed to spray the fire extinguishing agent in an appropriate pattern. For example, with devices that are to be installed in a wall close to a ceiling, it may be desirable to have a dispersement pattern where the extinguishing agent is directed outwards and downwards. For devices that are installed in a wall at roughly midpoint between the ceiling and floor, a desirable dispersement pattern may be upwards, downwards and outwards. Units installed in the center of the ceiling may have radial patterns, whereas units installed in the corner of a ceiling may radiate in a 90 degree pattern. The aperture  210  may be adjustable to different dispersion patterns or nozzle  208  may be fitted with different apertures able to create different dispersion patterns or an installer adjustable nozzle to create a custom dispersion pattern based on room size and shape. 
         [0059]    Also shown are optional mounting assembly  250 , lateral bracket  252 , first expanding arm  254  and second expanding arm  256 . 
         [0060]    Turning now to optional sensor assembly  300 , it has sensor housing  302 , status indicator  304 , sensor  306  and sensor mount  308 . Sensor housing  302  is constructed of metal or heat resistant plastic or rubber. Sensor housing  302  contains status indicator  304  and sensor  306 . The actual size and shape of sensor housing  302  is variable, depending on the components contained therein. 
         [0061]    Sensor  306  is a heat responsive actuating element capable of triggering or activating discharge of the fire extinguishing agent. In a preferred embodiment it is similar to an automatic sprinkler head. In this case it can have of a fusible metal component which melts when exposed to high temperatures. Melting of the metal component causes a mechanical actuator to open a valve, in turn triggering release of the fire extinguishing agent. In one embodiment a liquefied gas expands into the tank assembly  120 , creating pressure which forces the fire extinguishing agent out of the siphon tube  192  and through the nozzle  208  and onto the fire. Fusible metal sensors are well known in the art and have been used for activating sprinkler systems and can be employed in this device. In addition, the sensor  306  may be either an infrared photodetector or a pyroelectric ceramic sensor, or any other type of sensor which generates electrical signals corresponding to the radiated energy sensed by the sensor. The sensor  306  can detect a fire in the room, which then generates electrical signals which can actuate mechanical valves which release the fire extinguishing agent  450 . 
         [0062]    Status indicator  304  can be any device that monitors the pressure inside tank assembly  100 , and indicates if the tank pressure is too low or needs to be recharged. For example, it can consist of a single low voltage electrical light that turns red when the pressure within the tank drops below the appropriate level, or it can switch from green to red. Alternatively, the status indicator can be a mechanical gauge or audible warning that indicates when the pressure is too low and the unit needs to be recharged or replaced. 
         [0063]    A variety of fire extinguishing agents  450  may be used for flame suppression, which use either chemical or physical action, or both. One conventional agent is a pressurized water extinguisher that eliminates fire by thermal energy absorption. Carbon dioxide and dry-chemical extinguishers are another type of fire extinguishing agent and work by displacing oxygen and absorbing thermal energy. Other agents include sodium bicarbonate extinguishers, as well as potassium bicarbonate, urea-based potassium bicarbonate, and potassium chloride extinguishers. Yet another conventional fire extinguisher is the foam (AFFF or FFFP) model, which coats flammable liquids with a chemical to lower the temperature or eliminate oxygen supply. Any of the agents described above, or any other fire extinguishing agent, is a suitable fire extinguishing agent for purposes of the invention. One particularly preferred agent is FE 36, manufactured by DuPont (Wilmington, Del.). 
         [0064]      FIG. 7  shows an embodiment of the invention having tank assembly  100  with only primary tank  120  and lower tank  160 , with a single flexible pressurized joint  180 .  FIG. 7  also shows nozzle assembly  200 , sensor assembly  300 , and mounting assembly  250  attached to nozzle support  202 . The mounting assembly  250  of the present invention can be any type of mount suitable maintaining the invention in a fixed position in a wall or ceiling. For example, an appropriate mounting assembly may constitute brackets or hood that can be screwed, nailed, bolted or otherwise fastened to joists or to the wall or ceiling itself. In a preferred embodiment, mounting assembly  250  is an expandable mounting bracket. As seen in  FIG. 7 , the expandable mounting bracket has lateral bracket  252 , first expanding arm  254  and second expanding arm  256 . The expandable bracket is most likely to be mounted on nozzle support  202 , but could be mounted anywhere and in any manner on primary tank  120  so long as it is configured in a manner consistent with the principles described herein. Expanding arms  254  and  256  are plates that will run parallel to the wall studs and extend out into the wall studs to lock the unit in place and prevent “pitch” of the unit along its longitudinal axis. In addition, the joint for expanding arms  254  and  256  is preferably in line with the lateral most aspect of the tanks. In the retracted position, expanding arms  254  and  256  will be in contact with the sides of primary tank  120 . The expandable mounting bracket, should be sized so that when collapsed, is short enough to negotiate the opening and the space between the dry wall. A Philips head screw or other fastener is located at these joints  258  and  260  to rotate and lock the arms into place when tightened, moving them from the closed to the open position. This bracket may be either the extendable arm as described or a scissoring “X” bracket that extends out from a flat “X” to brace against the studs. Other types of expandable mounting brackets are possible, for example those that would mount to the rear wall, ceiling joists, wall studs, etc. with or without expanding arms, such as those with swinging or twisting parts, and such designs would be within the scope of the present invention. 
         [0065]      FIG. 8 . shows the invention with tank assembly  100 , nozzle assembly  200 , mounting assembly  250 , and sensor assembly  300 . Shown is a typical installation, namely automatic fire extinguisher  10  installed in wall cavity  500 , with first expanding arm  254  and second expanding arm  256  expanded and creating opposing force against parallel surfaces  502  and  504 , i.e., wall joists  502  and  504 .  FIG. 8  also shows automatic fire extinguisher  10  having multiple intermediate tanks  140  and lower tank  160 . 
         [0066]      FIG. 9  shows the installation of the invention into wall cavity  500  with tank assembly  100 , nozzle assembly  200 , mounting assembly  250 , and sensor assembly  300 . Wall opening  506  is created by the user in front wall  508 , and then invention  10  is flexibly inserted through wall opening  506  and into wall cavity  500 . The wall opening may then be covered by a decorative face plate,  400  (not shown). Wall opening  506  can be circular or oval or rectangularly shaped, or in any other shape or configuration. A similar method may be used if the invention is to be installed in a ceiling. The user may be supplied with a template that facilitates the cutting of the shape on the wall or ceiling. Flexible pressurized joints  180  permit the automatic fire extinguisher  10  to conform to space defined by the distance between front wall  508  and back wall  510 , or in the ceiling cavity created by the ceiling and ceiling joists. 
         [0067]      FIG. 10  is a partial side cutaway view of automatic fire extinguisher  10  fully installed in wall cavity  500 . Decorative plate  400  is installed with plate hinge  402  and plate capture  404 . Primary tank  120 , intermediate tanks  140  and lower tank  160  are seen, with flexible pressurized joints  180 . 
         [0068]    Primary tank  120  has dome  122 , optional divider  124 , wall  126 , bottom  128 , bottom edge  130 , and bottom opening  132 . Optional intermediate tank or tanks  140 , have top opening  144  and bottom opening  154 . Lower tank  160 , has top  162 , top opening  164 , wall  168 , and bottom  170 . 
         [0069]    The tanks in  FIG. 10  are connected by flexible pressurized joints  180 , having flexible tube  182 , inside diameter  184 , first connection  186  and second connection  188 . Also shown is optional gas canister  190  and optional siphon tube  192 . Optional siphon tube  192  is flexible so it can bend in the same manner as tank assembly  100  flexes during insertion as seen in  FIG. 9 . 
         [0070]      FIG. 11  shows an alternate embodiment of the automatic fire extinguisher  600  of the present invention. Automatic fire extinguisher  600  has tank assembly  700 , nozzle assembly  800  and sensor assembly  900 . 
         [0071]    Primary tank  720  has dome  722 , wall  726 , bottom  728 , bottom edge  730 , and side opening  732 . Optional intermediate tank or tanks  740 , have top  742 , top opening  744 , top edge  746 , wall  748 , bottom  750 , and bottom edge  752 . 
         [0072]    The tanks in  FIG. 11  are connected by flexible pressurized joints  780 , each having flexible tube  782 , connection  786 . Flexible pressurized joints  780  connect into main conduit  790 , which connects into primary tank  720 . Main conduit  790  is flexible and allows the tank assembly  700  to flexibly orient into a wall or ceiling cavity. 
         [0073]    The automatic fire extinguisher of the present invention also has nozzle assembly  800 , nozzle support  802 , nozzle casing  804 , nozzle extension  806  and nozzle  808 . 
         [0074]    Sensor assembly  900 , it has sensor housing  902 , status indicator  904 , sensor  906  and sensor mount  908 . In addition alternate embodiment  600  also may have optional mounting assembly  950  (not shown) similar to mounting assembly  250 . 
         [0075]      FIGS. 12 and 13  show self contained automatic fire extinguisher device  10  in operation.  FIG. 12  shows the invention in the ready position. Nozzle extension  206  is in the fully retracted position. Sensor  306  and status indicator  304  protrude through decorative plate access  406 . It is important to note that nozzle assembly  200  and status assembly  300  do not substantially extend past the plane of wall  508 , and are therefore substantially flush with wall  508 . Preferably, nozzle assembly  200  and status assembly  300  do not extend more than 1″, and more preferably less than 0.5″ past the plane of wall  508 . Decorative plate  400  is movably suspended on hinge  402  and decorative plate capture  404  prevents decorative plate  400  from falling to the open position when the fire extinguisher is not discharging fire extinguishing agent  450 . The decorative plate  400  can be made of any material, such as plastic, metal, paper, glass, or a building material such as wall board, plaster or plywood. In addition, there may be an insert plate  410  that fits into the rough opening and which will lock into place on the dry wall. The decorative plate  400  may be hinged off of insert plate  410 . Insert plate  410  could have arms that help support the unit while the expandable mounting brackets are being extended during installation. 
         [0076]    The decorative plate could also be part of or affixed to the nozzle  208 , and/or not be a separate piece.  FIG. 13  shows the fire extinguisher  10  of the present invention in use, where the sensor  306  has activated the actuating valve (not shown), releasing the fire extinguishing agent  450 . The pressure exerted by the discharging agent  450  extends nozzle  208  forward, exerting force against decorative plate  400 , disengaging the decorative plate capture and moving decorative plate  400  to the open position as seen in  FIG. 13 . Alternative methods of “moving” decorative plate  400  are possible, for example, the plate could melt away during a fire, or simply fall to the ground. It could also be moved by a mechanism that operates independently of the discharge tube activating. 
         [0077]      FIG. 14  shows a highly preferred embodiment of the invention, with tank assembly  100 , nozzle assembly  200 , and mounting assembly  250 . Mounting assembly  250  has first expanding arm  254  and second expanding arm  256  expanded, which can create an opposing force against parallel surfaces.  FIG. 14  also shows automatic fire extinguisher  10  having multiple intermediate tanks  140  and lower tank  160 .  FIG. 14  shows that nozzle  208  is a traditional fire sprinkler head  205 . Sprinkler head  205  could be any conventional sprinkler head used in fire protection systems and can be disposed on tank assembly  10  in any manner, and can be extending or stationary. Thus, a sprinkler head  205  could be attached to the nozzle extension  206  and extend into the room as discussed, or it could be stationary and disposed directly on nozzle extension  206  and/or nozzle casing  204  and/or nozzle support  202  in which case it would remain stationary relative to wall  508 . 
         [0078]    The present invention may also have an audible or visible warning system located in dome  122  or sensor housing  302 . The audible alarm, preferably similar to those used in fire detectors, creates a loud signal after sensor  306  detects a fire. In addition it is possible that multiple devices could be networked together, so that if one extinguishing system is activated, then others in the same or adjoining rooms are activated. The activation of one unit by another can take place using audible sensors, which react to the alarm signal of the first, or are networked using a wireless connection or could be hard wired together. 
         [0079]    In general, all of the components of the invention should be able to withstand temperatures consistent with industry standards as well as federal and local regulations. 
         [0080]    Although this invention has been described with a certain degree of particularity, it is to be understood that the present disclosure has been made only by way of illustration and that numerous changes in the details of construction and arrangement of parts may be resorted to without departing from the spirit and the scope of the invention.