Tornado alarm system

A tornado alarm that monitors humidity, static charge in the air and the barometric pressure. Nothing happens until the level of static electricity increases to a set amount over a stored base level and the humidity reaches 100 percent. At this point the first stage alarm is activated. The device sends out an initial blast followed by a report every 60 seconds during this mode of operation. At this point, the user is awakened by the alert. The user then can turn on news reports to verify danger. Once awake, if danger exists, the user can prepare for a tornado and be ready. When the barometric pressure reaches 28 millibars, the third condition is reached. Under most circumstances, a tornado is then immanent. This sets the device into the second stage alert mode. In this mode, a continuous alarm sounds.

CROSS REFERENCE TO RELATED APPLICATIONS 
Not Applicable 
STATEMENT REGARDING FEDERALLY SPONSORED RESEARCH AND DEVELOPMENT 
Not Applicable 
BACKGROUND OF THE INVENTION 
1. Field of the Invention 
This invention relates to tornado alarm systems and particularly to tornado 
alarm systems that monitor three weather parameters. 
2. Description of Related Art 
Tornadoes are some of the most devastating of all weather phenomena. Part 
of the significance of their power is that they are relatively 
unpredictable. Although forecasters can monitor conditions for a wide 
area, there is no simple way to pinpoint where a tornado may hit. Once on 
the ground, a tornado is easy to monitor, but by then, it is often too 
late for victims in its path. If a tornado hits during waking hours, it is 
much more likely that people's lives may be saved. Warnings can be 
broadcast over the affected area and people will most likely hear them. It 
is at night, when people are sleeping that there is the most danger. 
To help in these efforts, tornado alarms have been invented. Although these 
devices may prove useful, they are not as effective as they could be. Many 
devices monitor a single parameter associated with tornadoes. For example, 
U.S. Pat. Nos. 5,612,667, 3,631,435, 3,646,540, and 4,632,052, all use 
barometric pressure to alert the user to the presence of a tornado. It is 
well known that a sudden drop in barometric pressure occurs just before a 
tornado strike. Unfortunately, the drop occurs at the time of inception of 
the tornado. In other words, when the tornado is already there. Thus, 
these devices do not give enough time for an adequate warning. Moreover, 
by focusing only on the barometric pressure, there are likely to be times 
when the alarm does not really indicate a tornado. Such false alarms 
reduce the usefulness of these devices. 
U.S. Pat. No. 4,812,825 uses a superhetrodyne receiver to detect 
electromagnetic energy produced by a tornado. This device, like the others 
above, only measures one parameter associated with tornadoes, produces an 
alarm only when the tornado is very close, and is subject to confusion 
from other radio signals and noise. 
U.S. Pat. Nos. 5,379,025 and 5,801,636 measure seismic waves generated by 
tornadoes. As before, the problem with these devices is that they only 
measure one parameter, it is a parameter that only exists when a tornado 
is very close, and it is subject to confusion and false signals due to 
other causes of seismic activity. 
U.S. Pat. No. 5,867,805 takes a different approach. This patent uses a 
small computer that monitors all of the essential weather data, 
temperature, static electricity, humidity, barometric pressure, and 
others. It is also linked to an emergency broadcasting radio station. This 
device remains silent until and emergency signal is broadcast. The device 
then begins to monitor local weather conditions (if one chooses that 
mode). These data are then compared to a stored database of weather 
conditions for several years. When the conditions match a previous 
dangerous condition, the computer alerts the user to the danger. Although 
this device is less subject to false alarms, it first requires an 
emergency broadcast signal and then it must find a similar weather pattern 
in the database before it will alert the user. If there is no signal or if 
the perceived pattern is not stored; there is no warning. 
BRIEF SUMMARY OF THE INVENTION 
All of these limitations and problems have been eliminated in the present 
invention. It is an electronic monitor that measures humidity, static 
charge in the air and the barometric pressure. Nothing happens until the 
level of static electricity increases to a set amount over a stored base 
level and the humidity reaches 100 percent. At this point the first stage 
alarm is activated. The device sends out an initial blast followed by a 
report every 60 seconds during this mode of operation. At this point, the 
user is awakened by the alert. The user then can turn on news reports to 
verify danger. Once awake, if danger exists, the user can prepare for a 
tornado and be ready. When the barometric pressure reaches 28 millibars, 
the third condition is reached. Under most circumstances, a tornado is 
then immanent. This sets the device into the second stage alert mode. In 
this mode, a continuous alarm sounds. 
It is an object of this invention to produce a warning system for tornadoes 
that monitors three essential weather parameters. 
It is another object of this invention to produce a warning system for 
tornadoes that has a two stage alert system. 
It is yet another object of this invention to produce a warning system for 
tornadoes that uses two parameters to establish a first stage alert status 
and then uses a third parameter to activate a second stage alarm.

DETAILED DESCRIPTION OF THE INVENTION 
Referring now to FIG. 1, the elements of the system are shown in block 
diagram. The system 1 has three environmental sensors. The first sensor 
101 monitors humidity. The second sensor 102 measures the level of static 
charge in the air. The third sensor 103 measures the barometric pressure. 
These three inputs are sent to a data-handling unit 104. The data handling 
unit converts the signals received from the sensors into a useable data 
stream. The components of this unit vary depending on the type of sensors 
used. For example, for an analog humidity meter, an analog to digital 
(A/D) converter is used. If the signals are digital, only signal 
conditioning may be required. These circuits are well known in the art and 
are beyond the scope of this patent. A humidity sensor 101 such as model 
Minicap 2/5, manufactured by Panametrics Corporation senses ambient 
humidity. A static charge sensor 102 such as model KML10/B/2, manufactured 
by Phillips Semiconductor senses ambient static potential and a barometric 
pressure sensor 103 such as model MPX200A, manufactured by Motorola 
Corporation senses the ambient air pressure. Of course, any other similar 
type of sensor can be used, with adjustments in the data handling circuits 
as needed. 
The data is fed from the data-handling unit 104 to a central processing 
unit (CPU) 105. The CPU has a memory storage area 106, a power supply 107 
and an alarm device 108 that are connected to the CPU using ordinary 
methods. 
The pressure 103 and humidity 101 sensors provide readouts to the CPU 105 
that are compared to the stored levels of 100 percent humidity and a 
pressure of 28 inches Hg or less. In the case of the static charge meter, 
the level of static charge is set by calibrating the unit during a period 
of normal weather. The controller then measures increases in the level of 
static charge in the air as compared to the base level determined at the 
initialization of the unit. The device can be set to trigger the alarm at 
any setting of static charge over the base. In the preferred embodiment, 
the system is set to trigger an alarm state at a static level between 
about 25 and 50 percent above the base level of static charge. 
Referring now to FIGS. 2 and 3, details of the operation are shown. The CPU 
is set for a two stage alert operation. FIG. 2 shows a flow chart for this 
operation. In this mode, the CPU checks the static charge measurements and 
the humidity measurements against the stored levels. This system operates 
in a continuous loop, checking the parameters until both the humidity and 
static charge reach the alarm levels. Once the two trigger points are 
reached, the first alarm is tripped. In this stage, in the preferred 
embodiment, an initial alert blast is sounded. The signal can be any type 
of signal, but the preferred embodiment uses a tone that begins as a 
continuous note for a number of seconds (e.g., ten seconds) followed by a 
number of timed shorter tones (e.g., a note every 60 seconds). This 
warning alerts people that the potential for tornadoes exists in the area. 
During this stage of the alert, users can verify the threat by tuning into 
weather broadcasts. If danger does exist, the user can prepare shelter. 
As the figure shows, the first step in the loop is the system 
initialization 200. In this step, the static charge is read to determine a 
base level. This base level is then stored in the memory. In the next step 
210, the system checks the humidity, If the humidity is less than 100 
percent, the system moves at block 220 to check the level of static 
charge. At this step, the level is compared to the base level. If the 
system looks for an increase in static charge of between about 125 and 150 
percent of the base level. If this level is not found, the system moves 
back to the top of block 210 and then cycles through the first loop. This 
cycle continues until an alert condition is reached. Note that the order 
of checking is not important. The static charge and humidity blocks can be 
interchanged in this flowchart with no adverse effects. 
If the humidity reaches 100 percent, the system checks the static charge in 
block 230. Similarly, if the static charge increase is found, the system 
checks the humidity in block 240. The system cycles through until both 
conditions are satisfied. At that point, the system signals a first stage 
alert (block 250). 
FIG. 3 shows the flow chart for the second stage alert. Once the first 
stage alert 250 has been tripped, it remains set until reset by the user. 
The CPU then monitors the barometric pressure readings in the area at 
block 260. The system cycles through the first stage alert until the 
barometric pressure drops to or below 28 inches of Hg. At that time, the 
second stage alert is activated at block 270. In the second stage alert, 
the alarm signal becomes a continuous blast. This alerts the user to 
immediate danger and the user should take shelter. 
Of course, numerous modifications are possible. The power supply could be 
batteries, or it can be hard wired to the house current, or both. Many 
different types of alarm device can be used. However, the preferred tone 
is different from other alarm sounds currently in use (such as smoke 
detectors). Finally, many different types of sensors can be used as long 
as the necessary converters and data handlers are used. 
The present disclosure should not be construed in any limited sense other 
than that limited by the scope of the claims having regard to the 
teachings herein and the prior art being apparent with the preferred form 
of the invention disclosed herein and which reveals details of structure 
of a preferred form necessary for a better understanding of the invention 
and may be subject to change by skilled persons within the scope of the 
invention without departing from the concept thereof.