| Patent application number | Description | Published |
|---|
| 20100037673 | APPARATUS AND METHOD FOR MONITORING TANKS IN AN INVENTORY MANAGEMENT SYSTEM - A method includes lowering a sensor unit in a tank, where the tank is capable of receiving a material. The method also includes determining a first distance between the material and the sensor unit and determining a second distance between the sensor unit and a main unit that lowers the sensor unit. In addition, the method includes determining a level of the material in the tank using the first and second distances. The method could further include calibrating the sensor unit to compensate for variations in a medium within the tank, where the sensor unit transmits wireless signals through the medium to determine the first distance. Determining the first distance could include using an ultrasonic measurement technique, and determining the second distance could include using a non-contact servo measurement technique. | 02-18-2010 |
| 20100066589 | METHOD AND APPARATUS FOR HIGHLY ACCURATE HIGHER FREQUENCY SIGNAL GENERATION AND RELATED LEVEL GAUGE - An apparatus includes a stable local oscillator, which includes a first control loop. The first control loop includes a first voltage-controlled oscillator configured to generate a first output signal and a first phase-locked loop. The apparatus also includes a frequency up-converter configured to increase a frequency of the first output signal. The apparatus further includes a second control loop configured to receive the up-converted first output signal. The second control loop includes a second voltage-controlled oscillator configured to generate a second output signal and a second phase-locked loop. The second control loop may further include a mixer having a first input coupled to the frequency up-converter, a second input coupled to the second voltage-controlled oscillator, and an output coupled to the second phase-locked loop. A reference frequency source may be configured to generate a signal identifying a reference frequency and to provide that signal to the phase-locked loops. | 03-18-2010 |
| 20100070207 | METHOD FOR ROBUST GAUGING ACCURACY FOR LEVEL GAUGES UNDER MISMATCH AND LARGE OPENING EFFECTS IN STILLPIPES AND RELATED APPARATUS - A method includes transmitting wireless signals towards a material in a tank and receiving wireless signals reflected off the material. The method also includes calculating a phase velocity of the wireless signals reflected off the material and identifying a level of the material in the tank using the phase velocity. Calculating the phase velocity of the wireless signals could include identifying a plurality of linearly-spaced frequencies and performing linear interpolation using the data identifying the wireless signals to identify data points at the linearly-spaced frequencies. The identification of the data points at the linearly-spaced frequencies could represent the only interpolation operation performed during the calculation of the phase velocity and the identification of the level of the material. Moreover, a mismatch could exist between an inner diameter of a stillpipe through which the wireless signals are transmitted and a diameter of an antenna used to receive the wireless signals. | 03-18-2010 |
| 20100070208 | APPARATUS AND METHOD FOR DYNAMIC PEAK DETECTION, IDENTIFICATION, AND TRACKING IN LEVEL GAUGING APPLICATIONS - A method includes receiving data identifying wireless signals including wireless signals reflected off a surface of material in a tank and detecting a plurality of reflection peaks associated with the wireless signals. The method also includes classifying at least some of the detected reflection peaks and tracking at least some of the classified reflection peaks. The method further includes identifying a level of the material using at least one of the tracked reflection peaks. The classified peaks could include main-mode and/or high-mode reflection peaks, where the material level is identified using the main-mode peak or using an estimated location of the main-mode peak based on the high-mode peak. The classified peaks could also include level, bottom, and obstruction peaks, where the material level is identified by using a known permittivity, the bottom peak, and a tank height to estimate a location of the level peak when the level peak is lost or obscured. | 03-18-2010 |
| 20100086172 | METHOD AND APPARATUS FOR AUTOMATIC SEDIMENT OR SLUDGE DETECTION, MONITORING, AND INSPECTION IN OIL STORAGE AND OTHER FACILITIES - A method includes receiving an image of a storage tank at a processing system, where the storage tank is capable of storing one or more materials. The method also includes processing the image to identify a level, profile, or amount of sludge or sediment present in the storage tank. Processing the image could include segmenting the image into multiple segments and using the segments to identify a non-linearity in the image. The image could be segmented into segments having different grey levels using grey level values associated with previously-identified sediment or sludge. The identified level or amount of sludge or sediment could be used to automatically schedule maintenance for the storage tank. | 04-08-2010 |
| 20100175470 | METHOD AND DEVICE FOR DETERMINING THE LEVEL L OF A LIQUID WITHIN A SPECIFIED MEASURING RANGE BY MEANS OF RADAR SIGNALS TRANSMITTED TO THE LIQUID SURFACE AND RADAR SIGNALS REFLECTED FROM THE LIQUID SURFACE - The invention relates to a method for determining the level L of a liquid within a specified measuring range by means of radar signals transmitted to the liquid surface and radar signals reflected from the liquid surface, comprising the steps of i) transmitting radar signals to the liquid surface in time sequence; ii) receiving radar signals reflected from the liquid surface in time sequence; iii) determining the level L partially on the basis the transmitted radar signals and the reflected radar signals. The invention further relates to a device for determining the level L of a liquid within a specified measuring range, at least comprising a radar antenna disposed above the liquid for transmitting radar signals to the liquid and receiving radar signals reflected from the liquid surface, as well as means for determining the liquid level L on the basis of the transmitted radar signals and the reflected radar signals. | 07-15-2010 |
| 20100241369 | APPARATUS AND METHOD FOR AUTOMATIC GAUGE READING IN AN INVENTORY CONTROL AND MANAGEMENT SYSTEM - A system includes a probe configured to be raised and lowered in a tank capable of receiving a material. The system also includes a connector coupled to the probe and having at least one type of coding encoded on the connector. The system further includes a main unit configured to raise and lower the probe using the connector, digitally capture information associated with the at least one type of coding on the connector, determine a level reading identifying a level of the material in the tank using the captured information, and wirelessly transmit the identified level reading. The main unit could also be configured to determine a confidence level or interval associated with the identified level reading and wirelessly transmit the confidence level or interval. The connector could include a tape, and the at least one type of coding could include visible markings, perforations, and/or magnetic codes. | 09-23-2010 |
| 20100305885 | SYSTEM AND METHOD FOR DETECTING ADULTERATION OF FUEL OR OTHER MATERIAL USING WIRELESS MEASUREMENTS - A method includes transmitting wireless signals toward material in a tank. The method also includes receiving first return wireless signals reflected off a surface of the material and identifying a level of the material in the tank using the first return wireless signals. The method further includes receiving second return wireless signals reflected off a bottom of the tank and determining whether the material has been adulterated using the level of the material in the tank and the second return wireless signals. Determining whether the material has been adulterated could include determining a dielectric constant of the material, determining a density of the material using the dielectric constant of the material, and comparing the determined density of the material against a specified density. Determining the dielectric constant of the material could include using a time between peaks associated with the first and second return wireless signals. | 12-02-2010 |
| 20110102243 | DIGITALLY CONTROLLED UWB MILLIMETER WAVE RADAR - An ultra wide band (UWB) millimeter (mm) wave radar system includes a signal source having a control input, a GHz signal output and a frequency controlled output. A control loop is coupled between the GHz signal output and the control input including a frequency divider and a digitally controlled PLL that provides a locked output coupled to the control input of the signal source to provide frequency locked output signals that are discrete frequency swept or hopped. A frequency multiplier is coupled to the frequency controlled output of the signal source for outputting a plurality of mm-wave frequencies. An antenna transmits the mm-wave frequencies to a surface to be interrogated and receives reflected mm-wave signals therefrom. A mixer mixes the reflected mm-wave signals and mm-wave frequencies and processing circuitry determines at least one parameter relating to the surface from the mixing output. | 05-05-2011 |
| 20110163910 | RADAR LIQUID LEVEL DETECTION USING STEPPED FREQUENCY PULSES - The invention relates to a method for accurately determining the level L of a liquid by means of radar signals emitted to the liquid surface and radar signals reflected from the liquid surface. The invention further relates to a device for accurately determining the level of a liquid by means of the method according to the invention, which device comprises at least a radar antenna disposed above the liquid for emitting radar signals to the liquid and receiving radar signals reflected from the liquid surface, as well as means for determining the liquid level on the basis of the emitted radar signals and the reflected radar signals. | 07-07-2011 |
