The present disclosure relates generally to devices and methods for measuring the fill level of liquid or gas in a tank-in-tank container and, more particularly, to devices designed to measure the volume of liquid or gas in a tank-in-tank container in a noninvasive manner.
Restaurants and bars use gas, such as carbon dioxide, to carbonate fountain soft drinks and to preserve and push draught beer. Many restaurants have abandoned high-pressure compressed gas cylinders and are now using liquid bulk carbon dioxide as a safer, low-pressure alternative. Liquid bulk carbon dioxide is stored on the premises at a lower pressure in a holding container, and is often refilled on a regular schedule based on a restaurant or bar's usage pattern. The containers are typically a tank-in-tank design, having a rigid outer tank and a rigid inner tank with some amount of insulating space between the outer and inner tanks, and are permanently installed at their respective locations. Bulk carbon dioxide container systems are available in different sizes, ranging from 200 pounds to almost 800 pounds of carbon dioxide capacity, to fit the needs of the individual restaurant or bar.
Carbon dioxide is a compound formed by the combination of carbon and oxygen atoms in a 1:2 ratio expressed by the chemical symbol CO2. The weight percentages of carbon and oxygen are 27.3% and 72.7% respectively. Carbon dioxide is a gas at normal atmospheric temperature and pressure. It is colorless, essentially odorless, and about one and a half times denser than air. Depending on the temperature and pressure to which it is subjected, carbon dioxide may exist in the form of a solid, a liquid, or a gas. At a temperature of −69.90 degrees Fahrenheit and a pressure of 60.43 psig carbon dioxide can exist simultaneously in all three phases. This condition is known as the triple point. At temperatures above 87.90 degrees Fahrenheit carbon dioxide can exist only as a gas, regardless of the pressure. This is known as its critical temperature. Liquid carbon dioxide can only exist in a sealed container between the triple point and critical point temperatures under pressure. There is a definite pressure-temperature relationship of the liquid and gas in equilibrium. Normal operational pressures should remain above 165 psig to prevent the liquid carbon dioxide temperature from dropping below the minimum vessel design temperature. Liquid carbon dioxide should never be stored at pressures below 60.5 psig to prevent the formation of solid carbon dioxide or dry ice.
Carbon dioxide storage tanks are designed for long-term storage of liquefied carbon dioxide. A typical carbon dioxide storage tank is comprised of a steel inner tank encased in an outer steel vacuum shell. The insulation system between the inner and outer containers consists of multiple layer composite insulation and high vacuum to ensure long holding time. The insulation system, designed for long-term vacuum retention, is permanently sealed to ensure vacuum integrity.
A problem often experienced by bulk-fill providers relates to the scheduling of bulk container filling. Holidays or weekends can affect carbon dioxide consumption rates in an irregular manner, making it difficult to accurately predict an out-of-gas situation. This problem is compounded by a common issue where the pre-existing container fill level gauges are broken or inaccurate, although the tanks themselves are otherwise fully functional. A broken fill level gauge can occur when a given container reaches an empty, or nearly empty, state and the container's mechanical internal float is damaged, for example, from the remaining liquid freezing, rendering the fill level gauge inoperable.
Restaurants and bars need to ensure they are able to continue serving beverages to their customers. Bulk-fill providers need to be able to accurately identify containers that need to be refilled, avoiding unnecessary and costly premature fill runs. Therefore, restaurants, bars, and bulk-fill providers alike have a need to accurately, and in some cases remotely, determine the fill-level of their carbon dioxide containers.
Additionally, the need exists for a non-invasive means of measuring fill levels that can be retrofitted to existing containers and bulk-fill systems. Although invasive measuring devices, located within the volume of a container, are well known, the placement of an invasive measuring device within the container's inner tank is often not feasible due to any number of negative factors, including the cost of drilling into the container, the risk of possibly contaminating the liquid or gas disposed therein, the introduction of a source for a possible leak path of the liquid or gas from within the container, or structural issues that could be created by breaching the inner and outer tank's structural walls.
The need also exists for a non-invasive system that can accurately measure the fill-level of containers utilizing a tank-in-tank design. Previous non-invasive means of measuring container fill level having a single tank wall and a flexible interior bladder and have utilized impactors, solenoids, or vibration generators to vibrate the wall surface of the container, detectors to record the directly resulting response vibrations of the wall surface, and a frequency conversion means to convert the recorded data signal to frequency information and determine the peak resonant frequency response. The fill level of the single-wall container is then determined by comparing the measured peak frequency information to stored frequency and volume information for the container. Although this prior art method may have worked for single-wall containers, a measurement of the direct response of a tank-in-tank container's outer tank to vibration does not provide accurate fill level information regarding the inner tank or tank-in-tank container as a whole. Additionally, direct frequency readings of the prior art are affected by mid-range and high-range frequency ambient noise, including the common occurrence of container venting.
It is, therefore, desired that a retrofittable device and method for using the same be provided that is capable of obtaining an accurate measurement of liquid or gas volume within a tank-in-tank container in a non-invasive manner that is not affected by mid-range or high-range frequency ambient noise.
In one aspect, a tank-in-tank fill level indicator, making use of noninvasive tank-in-tank measuring techniques, is provided. The housing and function of the indicator are optimized for ease of installation and automatic calibration. An electromechanical device, such as a vibration device, resonator, or exciter, vibrates the outer tank, preferably at its natural frequency of vibration, thereby inducing the vibration of the inner tank. A beating effect results from the interaction of the different resonant frequency vibrations of the two tanks. A vibration detection device, such as an accelerometer, detects the resultant beating effect of the two tanks' vibrations. A data processing device, such as a microcontroller, processes the detection data to determine the liquid volume. A display, wired or wireless data transmission device, or combination thereof, is then used to provide container fill-level information according to a reporting schedule. Container fill level information is further processed and reported, including data trending, fill delivery scheduling, fill delivery route optimization, and system troubleshooting.
Thus, the present invention provides a retrofittable device and method for using the same that is capable of accurately measuring liquid volume within a tank-in-tank container in a non-invasive manner.
The components in the figures are not necessarily to scale or proportion, emphasis instead being placed upon illustrating the principals of exemplary embodiments of the invention. Moreover, in the figures, like reference numerals designate corresponding parts throughout the different views.
For the purposes of promoting and understanding the principals of the invention, reference will now be made to one or more illustrative embodiments illustrated in the drawings and specific language will be used to describe the same.
Tank-in-tank fill level indicator system 150, constructed according to the principles of this invention, is constructed for the purpose of enabling an accurate indication of liquid volume 140 within a tank-in-tank liquid container 110 in a non-invasive manner. When two or more sounds or vibrations are present having a frequency difference of less than about 20 or 30 Hz, a beat is formed at the difference frequency. The tank-in-tank fill indicator 200 associated with system 150 operates on the principle that the inner tank's resonant frequency 132 changes as the liquid volume 140 in the rigid inner tank 130 increases, and thus the number of beats present in the beat envelopes 143 per time period, resulting from the interaction of the outer tank's resonant frequency, induced by vibration applied to the rigid outer tank by an electromechanical device such as vibration device 220, and the inner tank's resonant frequency 132, induced by the outer tank's resonant frequency 122, decreases.
For example, as shown in
The tank-in-tank fill level indicator 200 of this invention can be used either to supplement the built-in indicator gauge (not shown) of the container 110, or in the case of a broken indicator gauge, to function as the primary fill-level indicator. The fill-level indicator 200 can include a visual display 316 such as light emitting diodes or a display screen to provide a visual indication of the measured fill level. Alternatively or additionally, the output of the fill level indicator can be transmitted via a wide area network (WAN) 370, including, for example, a wired local area network, WiFi, 900 MHz SCADA and/or cellular broadband. Transmitted data can then be processed by the geographically remote server 380, including, for example, to determine the appropriate time to refill the container.
In an illustrative embodiment, the utilization of a cell-based data connection exceeds the coverage capability of 900 MHz communication systems and eliminates the need to integrate with a WiFi network or other LAN and any associated issues, e.g. firewalls, changing passwords, or different SSIDs. Data trending and analysis is performed by remote server 380, e.g. a cloud based server. The data and associated analysis and other services can be accessed and viewed via a web browser via any user computing device 390, eliminating any need for a specialized computing device. The remote server 380 can also interface with Enterprise Resource Planning (ERP) systems so that information is sent directly to users' computing device 390, for example, handheld devices in the field. In the event that multiple storage containers 110 in the same area are monitored, an illustrative embodiment utilizes 900 MHz wireless transceivers 350 for each of the individual indicators 200 to communicate with a single shared broadband wireless transceiver for connectivity with WAN 370.
An illustrative embodiment is shown in
As an illustration of the formation of a resultant beating effect at a beat frequency,
Unlike a loudspeaker that uses a frame and a cone diaphragm to couple vibrations to the surrounding air, the vibration device 220 uses the movement of the device itself to apply force from an exciter voice coil to the mounting surface, which is usually flexible enough to vibrate. In an illustrative embodiment, the vibration device 220 includes a coupling plate 224 that is directly coupled to the outer tank 120, and transmits vibrations from the vibration device 220 to the surface of the outer tank 120; therefore, the coil or vibrating element does not necessarily directly contact and strike the surface of the outer tank 120. Alternatively, a frame, housing, or coupling plate of the vibration device 220 can be mechanically coupled to the tank 110 using a material with preferably high compressive strength and moderate to high bending strength.
Although vibration of the outer tank 120 can be induced at any number of frequencies, it is preferable to vibrate the outer tank 120 at its natural or resonant frequency 122 to increase the efficiency of the vibration device 220. The resonant frequency 122 of the outer tank 120 can be predetermined by tapping the outer tank 120 and analyzing the resulting sound waves induced by resonant vibration using a sound frequency analyzer to identify the outer tank's resonant frequency 122. Alternatively, the outer tank 120 can be vibrated across a range of frequencies that includes the outer tank's resonant frequency 122 and the resonant frequency can be determined by analyzing the response. In an illustrative embodiment, the natural frequency of the outer tank 120 of a 750 pound bulk carbon dioxide container 110 is approximately 200 Hertz. The natural frequency 122 of the outer tank 120 remains constant and is independent of the fill-level 140 of the inner tank 130.
Similarly, vibration can be induced in the outer tank 120 at any number of physical locations of the outer tank 120 surface and it is preferable to identify and vibrate the outer tank 120 in a particularly responsive physical location of the outer tank 120 surface to increase the efficiency of the vibration device 220. A responsive physical location can be predetermined by tapping the outer tank 120 and analyzing the resulting sound or vibration waves using a sound frequency analyzer to identify the most responsive physical location. In an illustrative embodiment, the most responsive location of a 750 pound carbon dioxide container 110 was determined to be about 10 inches below the tank's upper horizontal seam.
The natural frequency of the outer tank 120, most responsive physical location of the outer tank 120, and beat characteristics can vary with different forms of tank-in-tank construction, including tank materials, size, and shape, as well as with different contained liquids. Within common application, there are a reasonably limited number of particular container manufacturers and variations, with a relatively small number of container designs covering a majority of the market; therefore, the characteristics of a particular tank and contained liquid, including corresponding beat and fill-level data typically can be predetermined.
A brief resonant frequency pulse is applied to the outer tank 120 by a vibration device 220, causing a vibration in the outer tank 122 and inducing a vibration of the inner tank 130. The vibratory forces of the inner 130 and outer 120 tanks transfer to one another, resulting in a beating effect signal 142 as the waveforms alternately reinforce one another at some times and cancel one another at other times. During times when the vibration from each source adds constructively, the amplitude of the vibration increases; during times when the vibration adds destructively, the amplitude of the vibration decreases. Because the natural or resonant frequency 122 of the outer tank 120 remains constant and the natural or resonant frequency 132 of the inner tank 130 changes with fill level 140, the number of beats or number of beat envelopes 143 occurring in the beating effect signal 142 in a given timeframe also changes based on fill level 140. In an illustrative embodiment, a class-D amplifier or switching amplifier 222 is used to control the voltage applied to an exciter 220. A class D amplifier is an electronic amplifier in which the amplifying devices operate as electronic switches instead of as linear gain devices as in other amplifiers, thereby providing a high level of efficiency and very little power loss to heat.
Because the beat frequency of amplitude envelope 143 is a very low frequency, the need for traditional frequency conversion methods, such as Fourier transforms, is eliminated. The vibration detection device 230 simply detects the resultant beating effect signal 142 and a data processing device 332 counts the number of beats in a given timeframe. In an illustrative embodiment, a simple microcontroller 332 is used to count the number of beats occurring in a 1-second time period. Data processing device 332 can be any control device, including a processor, discrete logic and/or analog devices, or an ASIC, implemented with or without software.
Additionally, ambient noise typically found in real-world conditions, including venting that reduces pressure caused by some of the liquid carbon dioxide warming and changing state to a gas, is of a much higher frequency and does not affect the measurement of the resultant beating effect signal 142. If desired, a bandpass filter such as an envelope tracking filter can be used to eliminate higher frequencies. In an illustrative embodiment, a low-frequency accelerometer 222 is used to detect the beating effect signal 142 and an analog envelope tracking circuit 232 eliminates the higher frequency component to provide the resulting low frequency beat envelope 143. An envelope tracking circuit 232 takes the high frequency resultant beating effect signal 142 as an input and provides an output which is the amplitude envelope 143 of the original signal 142. Examples of suitable envelope detectors include diode detectors, mixers, squaring cells, absolute value circuits, logarithmic amplifiers, etc, as are known in the art. An illustrative envelope tracking circuit 232 uses low power, single-supply, rail-to-rail operational amplifiers for envelope detection and processing. Typical measurements of the beat frequency in the beating effect signal 142 in an illustrative embodiment range from approximately 1 hertz to 10 hertz. For example, for an illustrative embodiment, a fill level of 25% resulted in approximately 5 beats per second (5 Hz) and a full container resulted in approximately 1 beat per second (1 Hz).
The fill-level indicator can be battery or 120V ac powered. The frequency of fill-level checks is chosen depending upon the power source used. As few as one check a day can be made to conserve power or multiple checks can be made each day if power consumption is not a concern. Likewise, the fill level indicator can be placed in an inactive battery conserving state, when not actively taking measurements or transmitting data, to conserve battery power. The amount of delay between measurements can be determined based on factors such as power consumption and predicted rate of fluid level change.
In an illustrative embodiment represented by a schematic diagram in
A sound exciter, for example, a compact audio exciter such as part number HiHX14C02-8 available from Hiwave Technologies, which was acquired by Tectonic Elements of Cambridge, U.K., is used as a vibration device 220 in an illustrative embodiment. By vibrating a solid object, an audio exciter essentially turns the solid object into a speaker. A typical Class-D mono audio amplifier 222, such as part number PAM8302A available from a Diodes Inc. of Plano, Tex., is used to turn the vibration device 220 on and off such that the output is pulse width modulated, providing for increased efficiency and accuracy in relation to alternative linear amps. An illustrative microcontroller 330 is part number ATXMEGA256A3U available from Atmel Corp of San Jose, Calif. is used as an because it is simple, inexpensive, and capable of a low-current draw deep sleep state. A low power clock 324, such as part number PCF8563 available from NXP Semiconductors N.V. of Eindhoven, Netherlands, is used to wake up the data processing device 330 at a specified interval. An analog accelerometer 222, such as a 3-axis solid-state accelerometer part number ADXL335 available from Analog Devices of Norwood, Mass., detects vibrations. Alternatively, another sensor type used for vibration measurements can be used to detect vibrations, e.g. velocity sensor, proximity probes, or laser displacement sensors. The z-axis is monitored in an illustrative embodiment since only one direction of vibration detection is of interest. An envelope tracker analog processing circuit 232, as known to one of ordinary skill in the art, tracks the envelope of the output of the accelerometer and strips off any high-frequency component providing simplified measurement of the resulting beat envelope 143.
An analog to digital converter 332, a function performed by the data processing device 330 in an illustrative embodiment, is used to process results from the analog accelerometer 222, in an illustrative embodiment. The data processing device 330 can utilize a high precision voltage reference 334, such as part number REF3030 available from Texas Instruments of Dallas, Tex., to detect extraordinarily small vibrations. In an illustrative embodiment, the voltage reference outputs a precise 3 volts. The digital to analog converter 332 is used to generate a sine wave, such that in an illustrative embodiment, the sine wave is centered at 1.5 volts, modulating between 0 volts and 3 volts.
In an illustrative embodiment, the wireless transceiver 350, such as a part number XB24C RF module available from Digi International Inc., can be turned on or off, as well as reset. The wireless transceiver 350 can be a cellular modem. Additionally, the wireless transceiver 350 can communicate with the server 380 via standard machine to machine protocol. In an illustrative embodiment, a MICROSD™ (trademark of SD-3C LLC of North Hollywood, Calif.) card is used for memory storage 340. Because the illustrative data processing device 330 is inexpensive and includes minimal on-board storage, information received by the wireless transceiver 350 may be stored in memory storage 340 and then loaded to the data processing device 330. Additionally, fill level and other measurements can be stored in memory storage 340 to be transmitted at a later time. For example, battery 132 life can be conserved by taking multiple reading between transmissions and only utilizing the wireless transceiver 350 at specified intervals. Also, in the event that cellular or other communications fail, measurements can be stored and transmitted once wireless communication is restored.
Environmental factors affect the beat frequency and thus, in an illustrative embodiment, the corresponding fill volume value for a given beat frequency is determined in light of environmental factors, including ambient temperature, humidity, and barometric pressure. An illustrative fill level indicator also includes environmental sensors, including digital temperature 360, humidity 362, and barometric pressure sensors 364. An illustrative embodiment utilizes a miniature inter-integrated circuit (I2C) digital barometer 364 such as part number MPL140A2, available from Freescale Semiconductor of Austin, Tex., and a Si7021-A20 I2C humidity sensor 362 and temperature sensor 360, available from Silicon Labs of Austin, Tex.
A display screen 316, such as an organic electroluminescence (OEL) display module, for example, part number UG-2864HSWEG01 available from Univision Technology Inc. of Chunan, Taiwan, provides a visual output interface. One or more buttons 318, such as pushbutton power switches, part numbers PV5S64012 and PV5S64017 available from Digi-Key of Thief River Falls, Minn., provide an input interface. Alternative user interfaces known in the art can be used additionally or alternatively.
In an illustrative embodiment, battery life is preserved by utilizing low-power usage components and component sleep states to minimize circuit current and circuit current draw in a sleep state. The battery of an illustrative embodiment is intended to last multiple years, thereby minimizing the need for gas supply drivers to change or replace batteries. In an illustrative embodiment, the wireless transmission device consumes the most power and thus the transmission of wireless reports is performed as infrequently as possible, dependent upon the rate of level change in the tank. In an illustrative embodiment, only the data processing device 330, including analog to digital converter 332, the clock 324, and the buttons 316 have a direct connection to the power supply 320, i.e. are powered all of the time. The remaining components are disconnected from the power supply 320 when not in use by the load switch 322 in order to preserve battery power.
In regards to hardware implementation and circuitry associated with an illustrative embodiment, it is important to note that the same functionality can be accomplished at least in part with software, as will be apparent to one of ordinary skill in the art. In other words, a more expensive processor can accomplish features that would otherwise be implemented with additional circuitry. Additionally or alternatively, in regards to software implementation and the processor and other hardware associated with an illustrative embodiment, it is noteworthy that the same functionality can be accomplished at least in part with hardware, as will be apparent to one of ordinary skill in the art, though at a potential cost or other advantage or disadvantage.
As shown in
In an illustrative embodiment, the sensor head housing 210 is separate from the main housing 310, including only the vibration device 220 and vibration detecting device 222. This keeps the mass of the sensor head 210 low, such that the excitations from the vibration device 220 inducing resonant frequency 122 and 132 and beating effect signal 142 detected by the vibration detecting device 222 are not damped or affected by the mass and weight of the main unit 310. The sensor head 210 of an illustrative embodiment is outdoor rated and is attached to the surface of outer tank 120 of the container 110 by utilizing double-sided tape or some other adhesive 212.
Because tanks are often located outside or subjected to adverse conditions, the housings 210/310 of an illustrative embodiment are outdoor-rated such that they are capable of withstanding snow, rain, and wind. This entails the gasketing of all device openings, seams, and connections. Specifically, an illustrative embodiment is dustproof and waterproof; i.e. can withstand the effect of immersion in water between 15 centimeters and 1 meter, but cannot withstand long periods of immersion under pressure, for example, IP67 rating.
Referring to
An illustrative installation method 600 of the fill level indicator 200 of the present invention provides a significant benefit over the prior art. A known alternative method of identifying tank level required placing scales under the container 110 and communicating with the scales to determine volume based on weight. However, scales that can accurately measure the weight of a full container 110 are cost prohibitive and difficult to install because the container must be lifted onto the scale. In an illustrative embodiment shown in
As shown in
Once identified, the resonant frequency 122 is stored and future excitation of the tank is performed at the particular tank's resonant frequency. If the resonant frequency identification step 720 fails, i.e. the system cannot identify the resonant frequency within the spectrum range of the frequency sweep, the installer is notified via an error message 730 and prompted to select the tank type from the menu at step 725 before the frequency sweep 715 is performed again. Other possible errors that can result in error message 730 include contact between the tank and one or more other objects, thus dampening the vibration signal applied to the outer tank 122 and/or the resultant beating effect signal 142.
As shown in
Leak detection analysis can also be performed by the indicator 200 or by the remote monitoring system 380 level. Container systems often include multiple opportunities for leaks, such as hoses and junctions. Given that gases in a liquid state go straight to a gaseous state, leaks cannot be detected by simple methods such as examining lines for leaking fluid. The data reporting and trending process 800 also includes steps for leak detection fill level readings 835/840, identify leak 845, and transmit leak detection 850. In an illustrative embodiment, leaks are identified by measuring 835/840 the fill level 140 over a period of time delay 837 while the container is not being used, e.g. during the late night hours. A leak is determined based on a delta in the measurements 845. The requisite delta is specific to the container size and type. For example, if the measurements of an approximately 273 pound empty and approximately 750 pounds full container are taken four hours apart and there is a delta of 4 pounds, a pound an hour is being lost and thus there is a leak in the container system. Given that wireless transceiver 350 usage plays a significant role in diminishing battery life, battery life is preserved by not sending out leak measurement data 850 unless a leak is identified in step 845. If a leak is detected at step 845, then the cell modem is activated and an alarm message is sent to the remote monitoring system 380 in step 850. The alarm message ultimately gets sent out to the drivers and manager or supervisor of the fill supplier.
If a transmission fails at step 820, the fill level indicator system 150 will attempt to retry transmitting the fill level 815 with a time delay between transmissions. For example, a failed transmission may result in the reading being stored 820 and then 4 subsequent transmission attempts at step 820 may be made. If a requisite number of transmission attempts 820 take place with no success, the fill level indicator 150 will attempt to transmit the stored reading per the next normal operation according to the reporting schedule 805.
As shown in
In steps 920 and 925 and as shown in the illustrative screen display of
In an illustrative embodiment, the fill level indicator 200 of an illustrative embodiment can be configured to report back to the server 380 at a specified frequency, e.g. frequency ranges anywhere from once an hour to once a month, Users can customize reporting to view, sort, or filter compiled data in a variety of different ways in steps 920/925. For example, data can be view based on a particular container 110, a particular driver, or a particular driver's route. Users can also define report or event triggers, such as predictive fill dates. An offline alarm function provides user notification that a fill indicator has not reported on schedule in step 905. In an illustrative embodiment, the server sends an alert to a driver in step 925 to check the device and troubleshoot any number of exemplary problems, including dead batteries, vandalism, or environmentally related issues such as a lightning strike.
Data processing 900 can be performed on the indicator 200 or at the server 380 level. In an illustrative embodiment, data is tracked and trended in step 910 at the server level in such a way that users can access the server 380 and see information at step 910, including usage and fill levels. An illustrative typical user may be a fill service provider, but could also be an end user of the container 110. The ability to view this information remotely in steps 920/925 allows users to eliminate wasted trips to check fill level or fill unnecessarily when the level is not low, thereby eliminating associated wasted costs such as driver time, fill equipment time, and any safety or equipment risks that may be associated with the supplier refill process. As an example, a low fill level that would normally trigger a refill based solely on level may be identified by the server 380 as having a low usage rate, therefore not in a critical refill state. Alternatively, a container 110 having a higher level may be identified for refilling based on a history of high usage rate, thereby eliminating a potential situation where a container runs dry. By utilizing usage data, fill levels, and contents of delivery trucks, the server 380 can optimize driver's fill routes at step 915 based on factor such as priority fill sites, minimal number of miles travelled, shortest amount of time, or even smallest number of left turns.
It should be understood that the above description is intended for illustrative purposes only, and is not intended to limit the scope of the present disclosure in any way. Thus, those skilled in the art will appreciate that other aspects of the disclosure can be obtained from a study of the drawings, the disclosure and the appended claims.
The application claims the benefit of U.S. Provisional Patent Application No. 62/167,376, filed May 28, 2015, and titled TANK-IN-TANK CONTAINER FILL LEVEL INDICATOR, and U.S. Provisional Patent Application No. 62/338,166, filed May 18, 2016, and titled TANK-IN-TANK CONTAINER FILL LEVEL INDICATOR, which are incorporated herein by reference.
Number | Date | Country | |
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62167376 | May 2015 | US | |
62338166 | May 2016 | US |