Patent Application
20230381559
The invention relates to fire prevention and mitigation, and more particularly, to preventing and recovering from fires in heavily vegetated areas such as forests.
The prevention and minimization of fires, and the recovery from fires, in heavily vegetated areas that are unpopulated, or only sparsely populated, has always been a challenge. Furthermore, recent trends in global climate change have resulted in consistently higher temperatures and persistent droughts in many areas, which in turn have increased the risks and the occurrences of major fires in wilderness and other sparsely populated areas. In particular, fifteen of the largest wildfires that have ever been recorded in the United States have occurred within the past ten years.
For ease of expression, the term “forest fire” is used generically herein to refer to any fire in any heavily vegetated area that is a wilderness area, an otherwise unpopulated area, or a sparsely populated area, and the term “forest” is used generically herein to refer to any such heavily vegetated area, whether or not the vegetation is primarily trees. The terms “trees” and “ground cover” refer to any type of vegetation that is relatively tall and relatively short, respectively.
Often, in the aftermath of a forest fire, an effort is made to apply “reforestation” to the damaged area. With reference to
In addition, reforestation typically includes the creation of firebreaks 100, which are strips of land, usually between 15 and 20 feet wide, where all indigenous organic matter and vegetation has been removed, leaving a mineral or soil base. The intent is to deny fuel to any future forest fire, so that a fire will have difficulty crossing the firebreak. Often, the firebreaks 100 also serve as roads that can be traversed by fire service personnel, thereby providing a means of access to otherwise remote areas for fire fighters and their equipment.
Frequently, fuel-breaks 104 are provided adjacent to one or both sides of a firebreak 100. A fuel-break 104 is a strip of land where fuel for a potential fire (living or dead trees, brush, dead branches, etc.) has been reduced so as to limit the spread of fire near the firebreak 100. This is sometimes accomplished by thinning and/or pruning of trees or, in the case of reforestation, spacing the replacement trees apart, so that embers from fires will tend to fall to the ground rather than onto other trees, thereby allowing firefighters to more easily extinguish the flames.
With reference to
Often, grass is planted within fuel breaks 104 to minimize erosion and to exclude other vegetation from taking root in the fuel breaks 104. With reference to
What is needed, therefore, is an apparatus and method for reducing the likelihood of forest fires, and for recovering from forest fires while minimizing the likelihood of future forest fires in the same area.
The present invention is an apparatus and method for reducing the likelihood of forest fires, and for recovering from forest fires such that the likelihood of future forest fires in the same area is minimized. According to the present invention, a watering system is included in a fuel break, and is used to provide water to grass and/or other vegetation within the fuel break when a fire is approaching. In embodiments, the disclosed method further includes applying water to the fuel break during periods of drought, so as to maintain living vegetation within the fuel break, and thereby reduce the accumulation of deceased vegetation in the fuel break. Embodiments further include applying water to the fuel break in anticipation of a planned backfire that may be deliberately set so as to clear the firebreak and/or adjacent fuel breaks of dead vegetation.
The disclosed watering system includes at least one watering tower that rises above grade, as well as a pump, a water conduit, and a water distribution outlet, such as a sprinkler head, that are configured to bring water up the watering tower and distribute it onto the fuel break. In embodiments, watering “towers” are provided having differing heights and/or other characteristics. For example, in some embodiments the towers are configured to apply water both to trees and to ground vegetation. In other embodiments, taller towers are provided to reduce the dryness of trees that are within or near the fuel-break, while shorter towers are configured to provide water to grass and/or other ground covering vegetation that is included in the fuel-break. In various embodiments, reforested trees are planted in bunches, and at least some of the water towers are concentrated proximal to the bunches.
The water that is applied to the fuel break by the present invention can come from any combination of several possible sources, depending on the embodiment. Some embodiments include supply pipes that deliver water to the watering tower from remote water sources, which can be any combination of sources such as municipal water systems, wells, streams, rivers, lakes, and ponds.
Embodiments further include a water reservoir that extends beneath grade, for example beneath at least one of the watering towers. The water reservoir can be filled by water delivery pipes from the above-mentioned water sources, and/or by manual delivery of water, for example by water tanker trucks that periodically traverse the firebreak system. The water reservoir can also be replenished by run-off water from local rain that is collected through drain openings at or near grade and filtered to remove any dirt and debris. The runoff water can include excess water that is applied by the watering system but is not absorbed by the vegetation or surrounding soil, thereby improving the water efficiency of the system.
Level sensors can be included in the water reservoir, and embodiments include moisture sensors that sense the humidity and/or moisture content of the surrounding soil and vegetation. Any or all of the sensors can report their measurements to a central controller by wired and/or wireless communication.
Electricity for the pump and local controller can be provided via wired electrical conduits, and/or by solar panels included with the watering towers that provide electricity to a rechargeable battery. The pumps can be activated under local control, for example in response to measurements made by the moisture sensors. In embodiments, the sensors can be monitored and/or the pump can be remotely controlled by wired or wireless communications from a remote, central control center.
Some or all of the watering towers can be disguised to resemble trees or other local vegetation, thereby reducing the visual impact of the watering towers and of the fuel break.
In embodiments, the water efficiency of the disclosed system is further enhanced by applying a super-absorbent polymer (SAP) to the fuel break that is able to absorb at least 25 times its weight of water. The SAP functions to increase the ability of the soil in the fuel break to absorb and maintain water, both as delivered by the watering system and by natural rainfall, thereby minimizing wasted water runoff and further reducing plant mortality during droughts.
Embodiments further include reforestation within the fuel break by trees that do not produce and exude an abundance of excess flammable sap, such as hardwood, maple, poplar and cherry, trembling aspen, balsam poplar, and white birch, and/or inclusion in the fuel break of fire-resistant plants and shrubs, such as hedging roses, bush honeysuckles, currant, cotoneaster, sumac and shrub apples.
In embodiments, the towers are also used to moisten ground vegetation in the fuel break in advance of a backfire that is set to remove dead vegetation from the fire break and/or the fuel breaks. In some of these embodiments, the watering towers are configured to apply water both to trees and to ground cover. In other embodiments, separate, relatively taller watering towers apply water to trees, while relatively shorter water towers apply water to ground vegetation. If the trees are planted in bunches, the relatively taller watering towers can be located proximate the bunches, while the relatively shorter watering towers can be located in between the bunches. Embodiments further include relocating below grade any power lines that are present in or near the fire break or fuel break.
A first general aspect of the present invention is a system for impeding a spread of fires within a vegetated area. The system includes a fuel break, a watering tower configured to extend above grade, the watering tower being located within or proximal to the fuel break, a water distribution outlet cooperative with the watering tower, a water conduit configured to provide liquid communication between a water source and the water distribution outlet, and a water pump configured to draw water from the water source and to cause the water to be expelled through the water distribution outlet onto the fuel break.
In embodiments, the water source comprises a source of water that is separated from the watering tower by a distance of at least 10 yards. In some of these embodiments the water source comprises a municipal water source, a stream, a river, a well, a pond, or a lake.
In any of the preceding embodiments, the water source can include a water reservoir provided below grade and located proximal to the watering tower. In some of these embodiments water reservoir is configured to receive water from a water-bearing vehicle. In any of these embodiments, the water reservoir can be configured to receive water from at least one drain inlet located proximal to grade that is positioned to receive run-off water. In some of these embodiments the drain inlet includes a filter configured to remove debris from the run-off water. And any of these embodiments can further include at least one sensor configured to determine a quantity of water contained within the water reservoir.
Any of the preceding embodiments can further include a water-absorbent material applied to the fuel break, said water-absorbent material being able to absorb at least 25 times its weight in water.
Any of the preceding embodiments can further include a solar panel and a rechargeable battery, the rechargeable battery being configured to provide electrical power to the water pump and the solar panel being configured to recharge the rechargeable battery.
Any of the preceding embodiments can further include a local controller configured to activate and deactivate the water pump. In some of these embodiments the local controller is configured to communicate with a central controller that is remote from the watering tower, said communication being at least one of wired and wireless communication.
Any of the preceding embodiments can further include a moisture sensor that is configured to measure a moisture content of at least one of vegetation growing in the fuel break, soil present in the fuel break, and air proximate the fuel break.
In any of the preceding embodiments, the watering tower can be configured to approximate an outward appearance of vegetation that is growing within the fuel break.
In any of the preceding embodiments, the vegetation within the fuel break can include trees that are planted in bunches, and the watering tower can be located proximate one of the bunches.
In any of the preceding embodiments, the watering tower can be configured to apply water both to trees proximate the watering tower and to ground vegetation proximate the watering tower.
In any of the preceding embodiments, the watering tower can be included in a watering system that comprises a plurality of watering towers, and said watering towers can include at least one relatively taller watering tower configured to apply water to trees, and at least one relatively shorter watering tower configured to apply water to ground vegetation.
A second general aspect of the present invention is a method of reforesting a fuel break after occurrence of a fire therein, the fuel break being adjacent to a firebreak. The method includes adding fuel breaks adjacent to each side of the firebreak, if not already present, planting replacement vegetation in the fuel breaks, and installing a watering tower according to any embodiment of the first general aspect proximate the vegetation.
In some of these embodiments the replacement vegetation is fire-resistant. In some of these embodiments, the fire-resistant vegetation includes at least one of hardwood trees, maple trees, poplar trees, cherry trees, trembling aspen trees, balsam poplar trees, white birch hedging roses, bush honeysuckles, currant, cotoneaster, sumac and shrub apples.
In any of the preceding embodiments, planting the replacement vegetation can include planting a plurality of trees in bunches, and installing the watering tower can include installing the watering tower proximate one of the bunches. In some of these embodiments, the watering tower is a relatively tall watering tower, the watering tower is part of a watering system that further comprises a relatively short watering tower, and the method further comprises locating the relatively shorter watering tower between two of the bunches.
Any of the preceding embodiments can further include widening the firebreak and/or fuel breaks such that the firebreak has a width of at least 100 ft., and such that the total combined width of the firebreak and adjacent fuel breaks is at least 200 ft. 24. The method of claim 18, further comprising relocating below grade a powerline that was previously located above grade in the firebreak and/or the fuel break.
Any of the preceding embodiments can further include removing all vegetation in the fuel breaks that is within 125 ft. or more of an electrical transformer and/or an electrical power station. 26.
A third general aspect of the present invention is a method of maintaining vegetation within a fuel break that is located adjacent to a firebreak, and that includes a watering tower according to any embodiment of the first general aspect. The method includes at least one of: causing the watering tower to apply water to the vegetation when a fire is approaching the fuel break, causing the watering tower to apply water to the vegetation during a drought, and causing the watering tower to apply water to the vegetation immediately before and/or during application of a backfire to at least one of the firebreak and the fuel break.
The features and advantages described herein are not all-inclusive and, in particular, many additional features and advantages will be apparent to one of ordinary skill in the art in view of the drawings, specification, and claims. Moreover, it should be noted that the language used in the specification has been principally selected for readability and instructional purposes, and not to limit the scope of the inventive subject matter.
The present invention is an apparatus and method for reducing the likelihood of forest fires, and for recovering from forest fires such that the likelihood of future forest fires in the same area is minimized. With reference to
With reference to
The water that is applied to the fuel break 104 by the present invention can come from any combination of several possible sources, depending on the embodiment. The embodiment of
Level sensors 314 can be included in the water reservoir 310 that can be interrogated to determine how much water is in the water reservoir 310. Furthermore, embodiments include moisture sensors 316 that are configured to sense the humidity or moisture content of the surrounding soil, vegetation, and/or air. Any or all of the sensors 314, 316 can report their measurements to a local controller 318, which can forward the information to a remote, central control center by wired and/or wireless communication 320. In embodiments, the local controller 318 is further able to accept commands from the remote central control center via wired or wireless communications 320.
Electricity for the pumps 306 and local controller 318 can be provided by wired electrical conduits, and/or by batteries (not shown) that are recharged by solar panels 322 included with the watering towers 300. The pumps 306 can be activated under local control, for example by the local controller 318 in response to measurements made by the moisture sensors 316. In embodiments, the pump 306 can be remotely controlled by wired or wireless communications from the central control center to the local controller 318.
With reference to
In embodiments, the water efficiency of the disclosed watering system is further enhanced by applying a super-absorbent polymer (SAP) or other superabsorbent material to the fuel break 104, where a superabsorbent material is defined herein as a material that is able to absorb and retain up to 25 times its weight in water. The superabsorbent material functions to increase the ability of the soil in the fuel break to absorb and maintain water, both as delivered by the watering system and by natural rainfall, thereby minimizing wasted water runoff and further reducing plant mortality during droughts.
With reference to
Embodiments further include reforesting the fuel break 104 with fire-resistant trees 500 that do not exude an excess of highly flammable sap, such as hardwood, maple, poplar and cherry, trembling aspen, balsam poplar, and white birch, and/or inclusion in the fuel break of fire-resistant plants and shrubs, such as hedging roses, bush honeysuckles, currant, cotoneaster, sumac and shrub apples. Rather than including separate, shorter towers 202, the towers 200 in the embodiment of
With respect to
With reference to
The foregoing description of the embodiments of the invention has been presented for the purposes of illustration and description. Each and every page of this submission, and all contents thereon, however characterized, identified, or numbered, is considered a substantive part of this application for all purposes, irrespective of form or placement within the application. This specification is not intended to be exhaustive or to limit the invention to the precise form disclosed. Many modifications and variations are possible in light of this disclosure.
Although the present application is shown in a limited number of forms, the scope of the invention is not limited to just these forms, but is amenable to various changes and modifications without departing from the spirit thereof. The disclosure presented herein does not explicitly disclose all possible combinations of features that fall within the scope of the invention. The features disclosed herein for the various embodiments can generally be interchanged and combined into any combinations that are not self-contradictory without departing from the scope of the invention. In particular, the limitations presented in dependent claims below can be combined with their corresponding independent claims in any number and in any order without departing from the scope of this disclosure, unless the dependent claims are logically incompatible with each other.
This application claims the benefit of U.S. Provisional Application No. 63/081,101, filed Sep. 21, 2020, which is herein incorporated by reference in its entirety for all purposes.
| Filing Document | Filing Date | Country | Kind |
|---|---|---|---|
| PCT/US2021/046598 | 8/19/2021 | WO |
| Number | Date | Country | |
|---|---|---|---|
| 63081101 | Sep 2020 | US |
