The present disclosure is generally related to fluid spray systems for protecting structures from fire damage, along with related methods.
Homes and other structures can suffer significant damage or destruction from wildfires. As discussed below, currently available systems designed to protect structures from wildfire damage are inadequate.
One conventional method of stopping a grassfire or a wildfire is to create a fire break, a gap in vegetation or other combustible material that acts as a barrier to slow or stop the progress of a bushfire or wildfire. However, fires often create winds that blow embers through the air over long distances and across fire breaks. A fire break can be easily jumped by blowing embers, leaving structures vulnerable to ignition from these embers.
Within the industry, some conventional devices are available to help prevent blowing embers moving past a fire break. One such device, called a water curtain, uses a conventional hose that has many simple holes that are placed close together along the length of the hose. As water is pumped through the hose, it exits each hole and is directed straight up in a vertical column. The resulting overall spray shape is that of a thin curtain, in that, the spraying water is positioned along the length of the hose, but it is only a very thin wall of water. These water curtains are rarely used because they are too thin to significantly reduce radiant heat from a fire, and because the available water is better used to wet the nearby fuels to prevent their ignition.
One technique to protect a structure, such as a building, from a wildfire is to place permanent sprinklers on the roofs or walls of the structures. However, this equipment needs to be manually activated, which is problematic for situations in which evacuation has been ordered. If a homeowner happens to have a spray system available and starts the spray system before leaving, the water supply can quickly be depleted before the fire arrives. Water sprayed before the fire arrives can have some value in wetting the ground and walls of the home, but is not an efficient use of fluid. Thus, a heretofore unaddressed need exists in the industry to address the aforementioned deficiencies and inadequacies in current firefighting technologies.
The present disclosure, and embodiments provided herein, discloses systems for protecting homes and other structures from wildfires. The disclosed automatic fluid spray systems include a water pump fluidly connected to a water source, a return conduit positioned to allow water exiting the water pump to return to the water source, and a spray line comprising a conduit and a plurality of spray elements. The automatic fluid spray systems have a valve that allows water exiting the water pump to either return to the water source or enter the spray line and one or more temperature sensors in electrical communication with a control circuit. The control circuit is electrically connected to the valve and is configured to move the valve to supply water to the spray line when a preselected temperature is detected by the one or more temperature sensors.
The valve has a first position and a second position and when the valve is in the first position, fluid passes through the valve into the return conduit and not into the spray line, and when the valve is in the second position, fluid passes through the valve into the spray line and not into the return conduit. The automatic fluid spray system can be started by a homeowner before evacuating a site. The system is started by turning on the water pump while the valve is in a position to permit water to return to the water source but not enter the spray line. The system then runs for a period of time without dispensing water and, when the temperature sensors detect that the fire is approaching or has arrived, the valve is automatically turned by the system to divert water to the spray line, which releases water onto the house or other structure.
The valve may be an electric two-port valve. In some such embodiments, the system may also include a variable pressure relief valve in the return conduit that prevents water flow from the water pump to the water source when a pressure drop is detected. In some alternative embodiments, the valve may be an electric three-port valve. The system may, in some embodiments, include a low water detector in the water source to detect when the water source has a low water level, and the control circuit may be configured to move the valve to provide water to the return conduit when a low water level is detected in the water source. If the pump does not have water flowing through it, the pump can overheat and be damaged. The system may also include one or more additional spray lines, and, if present, each additional spray line may be independently controlled by a valve.
The present disclosure and figures are directed toward automatic fluid spray systems and related methods. The automatic fluid spray systems include a water pump connected to a water source, a return conduit positioned to allow water exiting the water pump to return to the water source, and a spray line comprising a conduit and a plurality of spray elements. The systems have a valve that allows water exiting the water pump to either return to the water source or enter the spray line and the systems are configured to move the valve to supply water to the spray line when a given temperature threshold is detected. The automatic spray systems can be started by a homeowner before evacuating a site. The system runs for a period of time without dispensing water and, when temperature sensors detect that the fire is approaching or has arrived, the valve is automatically turned by the system to divert water to the spray line, which releases water onto the house or other structure. The presently disclosed systems and methods advantageously allow for the system to be started prior to evacuation but not waste fluids before the fire arrives. The disclosed automatic fluid spray systems are inexpensive, easy to use, and efficiently dispense fluids to minimize wildfire damage to homes or other structures.
The automatic fluid spray system 100 shown in
Water from the water pump 110 feeds into a valve 125. The valve 125 allows water exiting the water pump 110 to either return to the water source 120 (via the return conduit 135) or enter the spray line 130. The valve 125 has a first position and a second position and when the valve 125 is in the first position, fluid passes through the valve 125 into the return conduit 135 and not into the spray line 130, and when the valve 125 is in the second position, fluid passes through the valve 125 into the spray line 135 and not into the return conduit 135.
The valve 125 is an electric two-port valve. In other embodiments, however, the valve 125 may be an electric three-port valve. The valve 125 shown in
The spray line 130 supplies water to the home or other structure. Various types of conduits can be used in connection with spray line 130. For example, in some embodiments, a spray hose as disclosed in U.S. Pat. No. 9,561,393 (Shoap) may be used for some or all of spray line 130. In some embodiments, spray line 130 comprises a conduit 132 and a plurality of spray elements 134a, 134b, 134c, as shown in
Valve 125 may be a two-port valve (as shown in
Any suitable type of temperature sensor 140 may be used in system 100, if desired. For example, the one or more temperature sensors 140 may be a thermistor or other type of fire detector. Any number of temperature sensors 140 may be used in connection with the automatic fluid spray system 100. For example, one, two, three, four, five, six, or more than six temperature sensors 140 may be included in the automatic fluid spray system 100. The one or more temperature sensors 140 may be mounted on the outer walls of the home or other structure. If present, the one or more temperature sensors 140 can allow the system 100 to begin spraying fluid at an optimal time, based on when excessive heat is detected from an approaching wildfire. The temperature threshold at which the control circuit 150 opens the valve 125 can be selected such that fluid is deployed from the spray line 130 before the main front of the fire arrives, so that the home or other structure is wetted prior to the arrival of the wildfire, which can prevent burning embers from igniting a fire. The deployed water can also lower radiant energy from a fire, making ignition of the home or structure less likely. In some embodiments, portions of the spray line 130 can also be deployed a substantial distance on the ground away from the house or other structure in order to stop the fire before it gets near the house or structure.
The control circuit 150 may be powered by a battery 160 or other power source. If a battery 160 is used to power the control circuit 150, a float charger 165 connected to house power or solar power may be used. The float charger 165 can ensure that the battery is always fully charged.
As shown in
A shown in
Since a fire may not arrive for many hours after the water pump 110 is started, it may be desirable to provide the water pump 110 with a large amount of fuel. Therefore, in some embodiments, a large gasoline supply may be provided in the form of an additional gasoline tank 180 connected to the water pump 110, as shown in
If desired, a low water detector 185 may be located within the water source 120 and may be configured to detect when the water source 120 has a low water level. As shown in
As previously mentioned, a low water signal detected from the low water detector 185 (if present) can cause the control circuit 150 to move the valve 125 to direct water coming from the water pump 110 back to the water source 120 and not to the spray line 130 to prevent overheating. In embodiments in which valve 125 is a throttling-type of two-port or three-port valve, electric circuits or a microprocessor can be used to set the amount of flow directed to the spray line 130. A minimal flow may be used when the detected temperature is relatively low and when the temperature rises significantly, more water can be supplied to spray line 130. Different water allocation algorithms can be used to ensure efficient use of the available water within the water source 120.
In an alternative design, system 100 may include multiple spray lines that are each independently controlled.
Method 200 continues with evacuating the structure (Block 204). After the structure is evacuated, the water pump 110 will continue to run without spraying any water from the spray line 130 until the system 100 detects a temperature above a threshold level. When a temperature above a threshold level is detected, the control circuit 150 will move the valve 125 to supply water to the spray line 130, which will spray the structure. The system 100 will continue to supply water to the spray line 130 until a low water level is detected in the water source 120.
This application claims the benefit of U.S. Provisional Application Ser. No. 63/205,216, entitled “Low Cost Automatic Spray System” filed Nov. 23, 2020 and U.S. Provisional Application Ser. No. 63/205,616, entitled “Low Cost Automatic Spray System with Pressure Relief Valve” filed Dec. 29, 2020, the entire disclosures of which are incorporated herein by reference.
Number | Date | Country | |
---|---|---|---|
63205216 | Nov 2020 | US |