This invention relates to sustainable foam fire protection equipment, in particular, an apparatus for generating and delivering pre-fire suppressant foam for use in fire protection.
Any discussion of prior art throughout the specification should in no way be considered as an admission that such prior art is widely known or forms part of common knowledge in the field.
Making a clear distinction between urban, rural and wildland fire protection responsibilities has been difficult in recent years due to California's rapid population growth and accompanying residential, commercial and industrial development in these diverse geographical settings. As the number of people and structures has grown and spread to areas of flammable vegetation with steeper topography, a fire protection problem of unprecedented magnitude has developed. California between 1984 to 1993 lost 75 people to wildfires and over 7000 structures were destroyed resulting in over 3 billion dollars in damage. And lives, property and natural resources lost to wildfire will continue to increase, paralleling this human migration. The values at risk, represented by people and property sharing the tinder-dry steep slopes of California's “Wildland/Urban Interface” (WUI) illustrates the most difficult, dynamic wildfire protection challenge in the world. With the exception of firefighting professionals (who are often spread to thin) and their equipment (which has difficulty navigating this particular terrain), there are few products available which can adequately protect structures in the path of a wildfire. Federal and State officials claim: “ultimately, property owners are responsible for their own fire protection”. The “Self-Sustaining Compressed Air Foam System” eliminates the product technology gap between the garden hose and the fire department.
It is estimated that 42 million structures are at risk to wildfire across the United States. 5 million structures are at risk in California alone. When wildfire breaks out in the WUI, pushed by high winds and extreme temperatures, available firefighting resources often spend their time saving lives and evacuating people, leaving the fire to burn unchecked until reinforcements arrive.
The fact that water is not the perfect tool for extinguishing fire has long been acknowledged and discussed. It's a cumbersome fluid and it is costly to install water mains large enough for required flow. The installation and maintenance of fire hydrants, procurement and required care of fire engines and all the accompanying apparatus, make water an increasingly valuable natural resource and a very expensive extinguishing agent.
The use of foam additives to fight fire dates back to England in the late 1800's. The British Navy experimented with foam and compressed air in the 1930's. And The U.S. Navy was using compressed air foam (CAF) against flammable liquid fires in the 1940's. In the 1960's do-it-yourself car wash businesses were using compressed air foam systems with low pressure and small diameter hoses and nozzles.
In the mid 1970's the Texas Forest Service developed a water expansion system known as the “Texas Snow Job’, and this pioneering “Class A” compressed air foam system used a pine soap derivative as a foaming agent. By the 1980's, research by the U.S. Bureau of Land Management led to modern design features of rotary air compressors, centrifugal pumps and direct injection foam proportioning systems. The basic premise of compressed air foam technology is the addition of a minute percentage of a soap-like concentrate to water as it runs through a standard pumping system, and then to inject compressed air as the water discharges from the pump. The soap-like concentrate reduces the surface tension of the water, then the air disturbs the solution to create a bubble structure which is an effective barrier against flying embers and flames. CAF systems received national attention in 1988 during the Yellowstone Park wildfires when an applied blanket of compressed air foam successfully protected Old Faithful Lodge.
Today, common design features of CAFS are targeted for the professionally trained firefighter. Those systems require training and maintenance, as well as utilizing diverse foam concentrates for several different fire fighting applications (i.e., wildland vs. liquid fuel fires). Foam from CAFS can also be used as a carrier for both agricultural and hazardous material applications: this means that a pesticide or decontamination agent can be added to the mix of water and foam concentrate to take advantage of foams characteristic to cling to what it is applied to rather than running off as water would. These types of foam applications require very different proportioning rates of water and foam concentrate, and necessitate the need for trained and qualified operators. Even CAFS designed exclusively for wildland fires require training to operate correctly. Moreover, the cost of operating a professionally designed CAF is high. Internal combustion engines running pumps and compressors require fuel and maintenance and discharge large quantities of water very quickly. And the amount of foam concentrate needed is directly proportional to the gallons per minute discharge rate of these systems. Foam concentrate is very expensive. Professional CAFS often run at the rate of 175 gallons per minute (gpm) or more. The Hale HPX 200 is an example of an average professionally designed CAF system with a gpm rate as high as 300 gallons. To produce a structure protection quality foam would require 2.4 gallons per minute of foam concentrate, which would cost nearly 27 dollars per minute to produce foam. Consequently, firefighters use their CAFS on the low end of the proportioning scale (0.2-0.3%), rather than the 0.6 to 0.8% proportioning rate required for long-term structure protection.
Conversely, CAF systems designed with very low (5-20) gpm discharge rates are pre-mixed pressurized vessels that are limited in size and haven't the capacity to protect the average size structure in the WUI. American Fire and Tri-Max are two companies with this design and it is my belief they work on the principle of Cummins' U.S. Pat. No. 4,318,433 and the principle of an ejector tube and aeration/mixing chamber with foam discharged and propelled by an attached compressed air cylinder. They produce a quality foam product intended for immediate fire suppression or the protection of a very limited area in size and, are designed for professionals.
Another company, Intelagard, designed a backpack system U.S. Pat. No. 5,623,995 (Smagac) that required pouring foam concentrate into a tank of water. The two fluids then needed to be stirred for uniformity, and the system could subsequently be activated by the opening of several valves. Intelagard's current design U.S. Pat. No. 6,155,351 (Breedlove, Smagac) appears to have a metering pump attached to a separate foam concentrate tank capable of pumping specific proportioned amounts of concentrate into a water stream to produce a wide spectrum of finished foam types. However, it should be noted that there appears to be an error in that patent's description of that specific component. At one point, under the heading of “Agitation Apparatus” U.S. Pat. No. 6,155,351; column 9, lines 47, 49, 53 the component is referred to as an “agitation apparatus” 118, while at another site in the patent under the heading, “Source of Foam Fluid”; column 6, lines 39, 62 the same component is referred to as a “metering pump” 118. But regardless of that error in Intelagard's patent language, the use of a metering pump is unnecessary and wasteful. The problem with a metering pump is that it uses stored air energy, a needless process if not relying on compressor air to operate the metering pump(s). Property owners untrained in the art of pre-fire suppression equipment need the simplest and most efficient use of stored air energy when engaging a wildfire with a self-contained CAFS.
Venturi type proportioners utilize another engineering principle common in the proportioning of foam concentrate to water in compressed air foam systems. These types of systems offer a mechanical means for adjusting proportioning ratios and are geared to the fire fighting professional as they require training and understanding of the fluid requirements for fighting fire. Teske demonstrates an adjustable venture type in U.S. Pat. No. 5,255,747, as does Kroll in U.S. Pat. No. 4,474,680.
The object of the present invention overcomes the complexities associated with prior art. The present invention eliminates the need for an extra tank for foam concentrate or other amendments. The present invention also eliminates the need for pre-mixing a water/foam concentrate solution with the simple addition of a vacuum-dispensing-closure for tight head pails.
Another object of the present invention eliminates the need for individual (separate) components that proportion and blend foam concentrate within a water stream. The present invention accomplishes that task with the addition of a vacuum-proportioning-blending-console.
Another object of the present invention is to eliminate the need for a self-contained compressed air foam system that either (1) depends solely on a pre-mixed, pressurized vessel; or (2) relies on a fossil fuel run engine to operate a pump required for drawing fluids necessary for producing foam solutions.
Another object of the present invention is to eliminate waste, splash-back and the potential for over application of the foam blanket without having to reduce system pressure when relying on a large diameter single bored nozzle and applying foam in close quarters.
The present invention delivers foam concentrate from the 5-gallon tight head pail which is received from the manufacturer. The pail's original cap is replaced with a new cap, comprised of a port (which is connected to a metering valve) and a vent to atmosphere. This allows the pail to be inverted and attached to a compressed air foam system. The inverted pail is then attached to the branch of a tee, a component of the vacuum-blending console. Upstream of the branch of the tee is a constrictive plate. The foam concentrate is introduced downstream of the constrictive plate, via the metering valve, through the branch (vacuum port) of the tee which is adjacent to the vena contracta, created by the constrictive plate. A pressurized air/inert gas operated pump, or solar powered transfer pump, draws the water-foam solution through the vacuum-blending console up through said pump(s) to the pump outlet. At this juncture, a pressurized air/inert gas insertion port is attached to propel the foam solution through an agitator where the foam solution is expanded to its finished foam state to exit at a nozzle.
This unique nozzle is designed to reduce the trajectory of a standard single bore nozzle to which it is attached and divide the stream into four separate streams. This novel construction maintains system-working pressure while eliminating product waste due to splash back and over application of the foam product. This allows the user to apply foam in close proximity to a structure's eaves, or in confined areas such as under decks or carports.
The intention of this invention is to practice sustainability. Therefore, a solar powered transfer pump with necessary photovoltaic panels, inverters, energy storage components and other electrical items can be substituted for the pressurized air operated pump. With the solar powered variant, stored air energy need only be used for inserting pressurized air agitating and propelling the foam solution at the pump outlet to the application nozzle.
In summary the structures and methods comprising the present invention eliminate a component of existing CAFS. The present invention also combines and simplifies the proportioning and blending processes/methods of producing pre-suppression foam, while reducing waste (over application) at the nozzle.
a illustrates in block diagram view the components of the preferred embodiment.
In
Overview:
Control panel: Types and variations of stored energy 40, 110 are channeled to the control panel 20. In the preferred embodiment,
Process Components: Compressed air foam systems in general use one of two methods for producing a foam solution. One is to pre-mix water with a foam concentrate the other is to have a separate or second tank to that of water containing foam concentrate with a pump like device to inject the foam concentrate into a water stream.
As
For the user of this self-sustaining compressed air foam system simplicity is required when needed to produce structure protection quality pre-suppression foam. Panic could lead to misuse if a user needs to think of what ratio of foam concentrate to water is needed with an approaching wildfire. Therefore all components are engineered to deliver a specific ratio of foam concentrate to water that will produce a consistent pre-suppression quality foam. Foam concentrate manufacturers recommend a ratio of concentrate to water to be in the range of greater than 0.5% to less than or equal to 1%
The final component in the process to produce a pre-suppression quality foam product is depicted in
Pressure Reducing Applicator: The design of the pressure-reducing-applicator 90, FIGS. 9,10 eliminates the need for the user of this system to manually reduce the working pressure when applying foam in confined areas (heat traps) such as under decks or in and around carports or where applying foam in close proximity to fuels or structures and the potential for over application and fluff off of foam blanket is possible. The pressure-reducing applicator attaches to a standard inline shutoff adapter 300 for standard firefighting hose. The inline shutoff adapter 300 serves as a nozzle for the system when applying pre-suppression foam to broad areas 50 to 75 feet away such as roofs or in the canopy of trees. When close-up foam application work is required the user simply attaches the pressure-reducing-applicator 90 by hand after shutting down the flow of foam with the lever 302 on the inline shutoff adapter 300. No tool is required and to re-activate the foam stream simply pull the lever handle 302 back on the inline shutoff adapter 300.
This set-up is un-wieldy without the use of a handle or grip.
In summary, the present self-sustaining compressed air foam system makes use of a tight head pail to supply foam concentrate to a vacuum-proportioning-blender attached to a water source and choice of stored energy operated pump(s) that draw water and foam concentrate as a solution to exit the pump(s) where a pressurized inert gas insertion port is attached to set in motion the foam solution through an agitator that expands the foam solution to exit a nozzle as a finished pre-suppression quality foam for the protection of structures in the event of an approaching wildfire.
While I have shown certain embodiments of the present invention, it is to be understood that it is subject to many modifications and changes without departing from the spirit and scope of the appended claims.
This application is based on Provisional Application Ser. No. 61/144,173 filed on Jan. 13, 2009.
Number | Date | Country | |
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61144173 | Jan 2009 | US |