Measuring and testing – Liquid level or depth gauge
Reexamination Certificate
1999-08-25
2002-03-26
Williams, Hezron (Department: 2856)
Measuring and testing
Liquid level or depth gauge
C181S124000
Reexamination Certificate
active
06360599
ABSTRACT:
FIELD OF THE INVENTION
The present invention relates to a device for measuring liquid level preferably measuring tide level in sea.
The subject invention relates to an acoustic tide gauge with provisions of in-situ calibration.
The object of the invention is to achieve greater accuracy, reliability, communication flexibility and to obviate the basic problem of variation in sound waves due to temperature fluctuations.
The other object of the invention is to measure the water level in the presence of tides and other waves.
The acoustic tide gauge is used for high accuracy and reliable measurements of tide levels and operates on the principle of acoustic echo ranging.
BACKGROUND OF THE INVENTION
The invention relates to a measuring device for measuring the tide or liquid level preferably measuring water level by using a sound wave, where the axial temperature and humidity varies in large ranges.
The most typically used levelmeter is the float levelmeter. The major problems associated with these levelmeters are that they can be operated only in a downward or upward direction and they require a vertical structure for mounting their own levelmeter. These types of levelmeters are not useful if the water level of the reservoir is changed by several times.
Conventionally, in the acoustic tide gauge, a sounding tube is used to guide the sound pulse towards the water surface. One open end of the tube is vertically immersed in water, while the other top end is provided with an acoustic transducer for the generation and reception of the sound pulses. However, the accuracy of the measurement depends on the velocity of sound, which varies with temperature fluctuations measured by the formula:
C=C
0
·{square root over (1+L +(
T/
273
+L ))}
where
C is the speed of sound in air in meters per second;
C
0
is the speed of sound in air at 0° C. and
T is the temperature in degrees centigrade.
Since one end of the sounding tube is in water and the other end in the air, it has been found not enough to measure the temperature of the air at one point for obtaining the sound velocity and thus the distance. To avoid this, in-situ calibration for each measurement has become necessary.
Conventionally, calibration is done by placing temperature sensors along the length of the tube, to obtain the temperature at select points along the tube.
In this technique, ensuring reliable operation of the sensors under marine conditions is very difficult and moreover the maintenance of the same is equally difficult. Since the sensors are not easily accessible, the data acquisition and signal processing measures are complicated by reason of the increased number of data channels.
The use of ultrasonic liquid level gauging sensors are also known conventionally. Ultrasonic liquid level sensors utilize the fact that ultrasonic vibrations travel freely in a liquid but are rapidly attenuated in air or other gas. If an ultrasonic transducer is mounted on the base of a liquid reservoir so that it directs energy up towards the liquid-air interface, the energy will be reflected back down to the transducer by this interface. By measuring the time taken between the transmission and reception of an energy pulse, it is possible to measure the distance between the transducer and the liquid/air interface and from this, the depth of the liquid.
It is also a common practice for ultrasonic transducers of this kind to be mounted at the lower end of a tube that extends from the bottom to the top of the liquid reservoir. The tube is open at the bottom so that liquid fills the tube to the same depth as in the reservoir outside the tube. The tube serves several purposes: It helps isolate the transducer from other sensors or sources of interference. It also confines the ultrasonic beam, so that it is directed only at the region of the liquid surface directly above the transducer. Furthermore, the tube produces within it a region of liquid surface that is substantially damped of waves.
However, there are various problems associated with these ultrasonic liquid gauging sensors, such as that the amplitude of energy reflected back to the sensor varies considerably with changes in the angle of the liquid surface relative to the axis of the probe, such as caused by a change in attitude of the probe. At angles exceeding about 20 degrees from vertical, the signal return from the liquid surface can be below the lowest signal to noise ratio that is acceptable for reliable measurement of the liquid height. In U.S. Pat. No. 5,357,801, sensors including at least one rod extending within the tube along its length have been provided to increase the range of operational tilt angles over which the sensors can be used, wherein a plurality of calibration reflectors are supported on the rod.
To detect the level of the liquid, the use of a microwave level gauge is also known conventionally as explained in U.S. Pat. No. 5,847,567. The major problem associated with these microwave level gauges is that the changes in temperature results in the expansion or contraction of the length of the waveguide, which results in causing errors in the distance measurement.
U.S. Pat. No. 5,119,676 teaches an apparatus for acoustically measuring the liquid level in a closed vessel comprising an acoustic waveguide attached at a predetermined location to a wall of the vessel, a transducer connected to the acoustic waveguide, a tube having apertures inside the vessel, the tube further including a conical section at one end axially aligned with the acoustic waveguide.
The lower end of the guide tube is provided having the provisions of attachment at several points to provide a water gap around most of its circumference, wherein there is a possibility of the loss of sound velocity from the junction points.
Another calibration technique that is used conventionally consists of providing a hole on the side wall of the sounding tube at a known distance from the transducer, which acts like a partial reflector. A small part of the sound pulse is reflected back towards the transducer by the hole. The drawback associated with this technique is that the hole cannot be provided too far away from the transducer, otherwise it may get submerged at high tide. Besides, the reflected pulses at the hole and the water level get mixed up, if both are too close together. In this process, the other disadvantage is that a part of the signal energy is lost to the surroundings through the hole and also due to the partial reflection at the hole, which leads to reduced signal to noise ratio and hence reduced accuracy.
To overcome the above referenced problems and to attain accuracy in judging tide levels, an apparatus of the subject application has been invented, having provisions for in-situ calibration.
SUMMARY OF THE INVENTION
The measuring device, an acoustic tide gauge of the subject invention, comprises a sounding tube having an open end immersed in water and an acoustic transducer on the other end for generation and reception of sound pulses. The sounding tube is provided with at least one branch tube laterally fixed to the side wall of the sounding tube having a particular length and closed end.
The length of the branch tube “L” in meters equals to
L
=(2
n−
1)&lgr;/4=(2
n
−1)
C/
4
f
where
n=1,2,3 . . . &lgr; is the wavelength of sound (meters)
C is the velocity of sound (meters per second) and
f is the frequency of sound in Hz; and
the diameter of the guide tube is determined by the formula
d<
0.586 &lgr;
The side branches are designed to respond to a specific frequency such that the sound pulse with appropriate center frequency is predominantly reflected by the branch. Thus, estimating the effective velocity of sound for different portions of the tube.
Hence, by using properly tuned resonating side branches and signals of different frequencies for calibration and for measurement of the tidal level, the limitations existing in in-situ calibration are overcome.
The length of the side branch, which plays an important part in the subject invention, is an odd m
Pathak Ardhendu Gajanan
Ramadass Gidugu Ananda
Dickinson Wright PLLC
Garber Charles D.
National Institute of Ocean Technology Department of Ocean Devel
Williams Hezron
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